Journal of Anthropological Archaeology 18, 29 –78 (1999)
Article ID jaar.1998.0332, available online at http:/ / www.idealibrary.com on
Botai and the Origins of Horse Domestication
Marsha A. Levine
McDonald Institute for Archaeological Research, University of Cambridge, Downing Street,
Cambridge, CB2 3ER, United Kingdom
Received April 22, 1997; revision received April 27, 1998; accepted July 28, 1998
This paper explores some issues related to the origins of horse domestication. First, it focuses
on methodological problems relevant to existing work. Then, ethnoarchaeological and archaeozoological methods are used to provide an alternative approach to the subject. Ethnological,
ethological, and archaeological data are used to construct a series of population structure
models illustrating a range of human– horse relationships. Analysis of assemblages from the
Eneolithic sites of Botai (northern Kazakhstan) and Dereivka (Ukraine) suggests that horses at
these sites were obtained largely by hunting. © 1999 Academic Press
Key Words: archaeology; Eurasian steppe; horse; domestication.
1.0. INTRODUCTION
ently intensified. For a long time archaeologists assumed that intensification meant
domestication. However, there are other
explanations for this kind of change which
must also be explored. It is important to
be aware that human– horse relationships varied widely over time and space
and that multiple relationships could be
relevant at a single site. Furthermore, behavioral patterns for which we have no
modern or ethnographic analogues are
likely to have been important in the past.
Whatever else is involved, it is clear that
there was an important change in steppe
ecodynamics at this time (from around
5000 to 3000 B.C.). Horses were becoming
much more common in archaeological deposits. Important cultural, social, and economic changes were taking place. It was
also a period of significant climatic change
(Schnirelman 1992). Until we can understand the development of the human– horse
relationship we cannot know how all these
factors were related (Levine 1993). If we are
to make sense of events during this period,
we must understand the structure of the
archaeozoological data.
The study of human– horse relationships has been bedeviled by both concep-
The impact on human society of the
earliest domestication of the horse must
have been as profound as that of the invention of the steam engine and yet we
know very little about when, where, or
how it came about. The increased mobility
provided by the horse would have enabled people to move further and faster
and to take more with them than ever
before. They could exploit larger and
more diverse landscapes, maintain larger
families, increase the range of their trade
contacts. They could move into previously
uninhabitable regions. And, since a man
on foot is no match for a man on horseback, the military implications of horse
domestication would have been revolutionary. John Ewers has shown how profoundly the introduction of the horse into
North America changed Blackfoot culture
(Ewers 1955). We should expect no less of
its early domestication in central Eurasia.
However, until recently relatively little attention had been paid to this problem (see
also Levine 1990, 1993).
Around 7000 years ago the relationship between people and horses appar29
0278-4165/ 99 $30.00
Copyright © 1999 by Academic Press
All rights of reproduction in any form reserved.
30
MARSHA A. LEVINE
tual and methodological weaknesses. This
paper explores some of the relevant issues
from two perspectives. First, it focuses on
some of the problems relevant to existing
work, in particular, the confusion of domestication with intensification and the
use of a single criterion to classify complex
human–animal relationships. Then, ethnoarchaeological and archaeozoological
methods are used to provide an alternative approach. A range of behaviors,
based on archaeological, ethological, and
ethnographic data, are drawn on to develop a series of models describing a
range of possible strategies and tactics
against which the archaeological data can
be tested.
1.1. The Concept of the Earliest Date
1.1.1. Biogeographic Range
C. Grigson’s paper, “The Earliest Domestic Horses in the Levant? New finds
from the Fourth Millennium of the Negev” (1993), illustrates what is probably
the most fundamental problem associated
with the study of early horse domestication—the search for the earliest date. She
might well be correct, on the basis of its
large size relative to the ass (Equus asinus)
and the onager (Equus hemionus), that
Equus caballus was present in the Levant
earlier than had been believed. However,
her conviction that this horse must have
been domesticated is apparently based
solely on the assumption that the geographical range of the wild horse could
not have extended into the Levant: “Although the horse (Equus caballus) was a
member of the Pleistocene fauna of the
Levant, it died out before the end of the
period” (Grigson 1993, p. 646). In fact, recent research suggests that the natural
distribution of the Holocene horse might
have been much wider than had been formerly believed (Azzaroli 1985; Clason
1988; Clutton-Brock 1992; Groves 1986;
Uerpmann 1990). In any case, the absence
of horse remains from archaeological de-
posits should not be taken as proof that
they were extinct. Grigson would have
been on firmer ground had she entitled
her paper: The Earliest Horses in the Levant? New Finds from the Fourth Millennium of the Negev.
1.1.2. The Search for the Earliest Date
This kind of problem arises partly out of
the tendency of archaeologists and archaeozoologists to ask certain kinds of
questions, for example, when and where
was the horse (or, for that matter, cow,
sheep, goat, pig, etc.) first domesticated?
Which came first: the invention of the
wheel or the bit (Anthony and Brown
1991)? The whole issue of earliest dates is
a red herring, especially in a situation
such as this, in which the number of wellexcavated and absolutely dated sites is
very small and the criteria used to prove
domestication are not very convincing.
Factors completely unrelated to ancient
human behavior that will significantly influence identification of the “earliest” site
include the following:
natural taphonomic factors: the destruction or preservation of sites, bones, and
artifacts made from organic materials;
decisions, which may be political, financial, or strategic, about where and how
carefully to excavate;
decisions about whether bones should
be studied or discarded;
decisions about who will study the
bones, whether their primary training is
as an archaeologist, zoologist, veterinarian, etc.;
the specialist’s country of origin, since
educational traditions influence the analytical methods used;
criteria chosen by the specialist as evidence of domestication.
Scholars looking for earliest dates commonly use only one line of evidence (e.g.,
biogeography, size, morphology, bitwear)
from which to draw their conclusions.
ORIGINS OF HORSE DOMESTICATION
This approach, simplifying human and
animal behavior, as it does, is ultimately
unsatisfying.
1.1.3. Size and Homogeneity
Setting the search for the “earliest date”
as a primary research goal makes it rather
easy to use inadequate criteria for the determination of domestication. This is because the search for a date does not require anything to be said about the actual
relationship between animals and people.
For instance, a decrease in size and an
increase in heterogeneity are taken as
proof of domestication by many scholars.
Uerpmann claims that “Grössenreduktion
einerseits und Zunahme der Variabilität
andererseits sind klassische Domestikationsindikatoren” (Uerpmann 1990, p.
127). 1, * Such factors as age and sex structure are rarely taken into account. However, a size change could also result from
a change in the technique of exploitation.
For example, a hunting method that
culled primarily stallions from family
groups would take larger horses than one
that focused on bachelor groups, which
might well be epiphyseally mature but not
yet full grown, or one that focused on
females, which are smaller than equal-age
males. Environmental change, geographical isolation, and genetic drift are all connected with size change. Moreover, taphonomic factors can also influence size
range and variability. For example, as an
animal ages, even after its epiphyses are
fully fused, the bones continue to increase
in density. All other things being equal,
the denser the bone, the better its chances
of surviving in an archaeological context.
Poor preservation conditions therefore
tend to result in an assemblage of relatively homogeneous and large bones. At
the French Upper Palaeolithic site of Solutré, both the Aurignacian and the Mag* See Notes section at end of paper for all footnotes.
31
dalenian horses were smaller than those
from the intervening Upper Perigordian
level. No one could seriously suggest that
this is evidence that the former were domesticated while the latter were wild (Levine 1979, 1983).
A decrease in size accompanied by an
increase in heterogeneity might be associated with domestication, but it could
have other causes. It is, on its own, insufficient as an explanation. Other corroborative evidence must be obtained. Even if
too few teeth were available for a fullblown population analysis, a study that
compared aging data from a series of relatively small samples would surely be just
as meaningful as one comparing morphometric data from a series of small samples.
The latter, but not the former, are used by
Uerpmann and others (e.g., Uerpmann
1990; Benecke 1993).
1.1.4. Bitwear
Another example of this commitment to
an earliest date is Anthony’s argument
that the domesticated horse was present
in the Ukraine earlier than in Kazakhstan.
His evidence for this comes from bitwear
studies of two samples of lower second
premolars from two Eneolithic sites, Botai
in northern Kazakhstan (5 from a total of
19 teeth) and Dereivka in the Ukraine (2
from a total of 6 teeth). He implies from
this that horse domestication spread from
west to east (Anthony 1995).
Relatively little archaeozoological research has been carried out in the
former Soviet Union, including both Kazakhstan and the Ukraine, and relatively
few absolute dates are available (regarding the Ukraine, see Levine and Rassamakin 1996). Botai and Dereivka do not
constitute representative samples of
sites within the vast regions in question.
They cannot, therefore, be used to answer questions about origins and earliest dates. Moreover, serious doubts have
been raised about the stratigraphic loca-
32
MARSHA A. LEVINE
tion of the “ritual” skull from Dereivka,
the basis of Anthony and Brown’s theory
of the origins of early horse domestication (Rassamakin 1994). These doubts
seem to be confirmed by the mean calibrated radiocarbon date recently obtained for that skull, 2915 B.C., more
than 1000 years later than most of the
other dates for that site (Table 1) (Telegin 1986).
1.2. METHODOLOGICAL PROBLEMS
1.2.1. Conventional Approaches
The theoretical framework used until
recently for interpreting the archaeozoological data was seriously flawed (for a
more detailed discussion see Levine 1990,
1993). For example, the criteria used by
various researchers as evidence that the
horses from Dereivka were domesticated
included the following: (1) the absence of
old horses; (2) the presence of a large proportion of male skulls; (3) the presence of
objects identified as bridle cheekpieces;
(4) the results of a morphological analysis
comparing the Dereivka horses with other
equid material; (5) their association with
other domesticates— cattle, sheep, goat,
pig, and dog; (6) the relatively large percentage of horse bones and teeth in the
deposit (Bökönyi 1978, 1984; Bibikova
1967, 1970, 1969; Telegin 1986). However,
on the basis of archaeological, ethnographic, and ethological comparisons, the
absence of old individuals is much more
likely to indicate hunting than herding
(Levine 1982, 1990). Males would outnumber females if either bachelor groups or
stallions protecting their harems were targeted in the hunt. The cheekpieces might
not have been cheekpieces at all (Dietz
1992; Levine and Rassamakin 1996). The
morphological study involved very small
and disparate samples and produced contradictory results. The association of
horses with other assumed domesticates
is not evidence of horse domestication. In
TABLE 1
Dereivka Radiocarbon Dates
KI 5488: 4330 6 120 years B.P. (“ritual” skull)
Mean calibrated date: 2915 B.C.
1 s; range 3092–2784 B.C.
3293 (0.03) 3277 3268 (0.05) 3240 3105 (0.75) 2865
2809 (0.12) 2750 2724 (0.05) 2699
2 s; range 3347–2610 B.C.
3339 (0.78) 2838 2828 (0.02) 2650
2650 (0.02) 2619
UCLA 1671A: 4900 6 100 years B.P. (bone)
Mean calibrated dates: 3692, 3670 B.C.
1 s; range 3783–3548 B.C.
3892 (0.01) 3889 3796 (0.86) 2633 3577 (0.14) 3535
2 s; range 3946–3383 B.C.
3946 (0.13) 3832 3829 (0.84) 3503
3417 (0.03) 3383
KI 2197: 5230 6 95 years B.P. (shell)
Mean calibrated dates: 4033, 4025, 3998, B.C.
1 s; range 4221–3959 B.C.
4221 (0.11) 4193 4154 (0.89) 3959
2 s; range 4320–3799 B.C.
4317 (0.02) 4292 4256 (0.89) 3902
3882 (0.09) 3802
OXA 5030: 5380 6 90 years B.P. (bone from
cemetery)
Mean calibrated date: 4237 B.C.
1 s; range 4337–4048 B.C.
4334 (0.58) 4216 4201 (0.28) 4141 4120 (0.14) 4087
2 s; range 4435–3985 B.C.
4362 (1.00) 3988
KI 2193: 5400 6 100 years B.P. (shell)
mean calibrated dates: 4310, 309, 4249 B.C.
1 s; range 4346–4086 B.C.
4345 (0.63) 4216 4201 (0.25) 4141 4120 (0.12) 4087
2 s; range 4456–3985 B.C.
4451 (0.03) 4420 4396 (0.02) 4374
4030 4030 (0.04) 3994
4369 (0.92)
UCLA 1466a: 5515 6 90 BP (bone)
Mean calibrated date: 4350 BC
1 sigma; Range 4457–4260 BC
4458 (.83) 4317 4291 (0.17) 4256
2 sigma; Range 4527–4155 BC
4540 (.94) 4218 4198 (0.4) 4145
4115 (.01) 4093
Source. Dates from Telegin, personal communication, and conference abstract from Telegin (1995).
Calibration from Stuiver and Reimer (1993).
any case, they were also found with the
remains of wild animals (Levine 1990,
1993). The only species from Dereivka to
ORIGINS OF HORSE DOMESTICATION
be studied in detail was the horse. Because almost all the bones and teeth from
this site have unfortunately been discarded, it is impossible for them to be
reassessed. However, a preliminary examination of the faunal assemblage from the
new excavations at Molukhov Bugor, another Dereivka culture site, 2 has produced
some interesting, but extremely tentative
results. No bones that could only have
come from domesticated animals and
many that must have come from wild
ones, for example, birds, tortoise, beaver,
deer, have been identified, while the cattle
and pigs were suggestively enormous.
Much more work needs to be done on this
assemblage, but the initial results lend
support to the far more detailed analyses
already carried out on the material from
Dereivka (Levine 1990, 1993). On the one
hand, there is little or no evidence that the
Dereivka culture people were pastoralists,
while on the other hand, there is a good
reason to believe that they were huntergatherers (Levine and Rassamakin 1996).
Horses are relatively uncommon in
European Mesolithic and Neolithic archaeological deposits. It has, therefore,
commonly been held to be the case that
they could not have been domesticated
during those periods. On the other
hand, relatively large quantities of horse
bones and teeth have been recovered
from Eneolithic sites on the central Eurasian Steppe. Characteristics of tooth
morphology, population structure, taphonomy, and taxonomic distinctions
based on measurements, have been
credited as evidence for horse domestication. Until recently, however, the most
important criterion had been that of increased relative abundance, which could
be explained as well, or even better, by
increased hunting rather than by
domestication (Bökönyi 1978, 1984;
Bibikova 1967, 1970, 1969; Petrenko 1984;
Levine 1990, 1993).
33
1.2.2. The Identification and Significance of
Bitwear
As an analytical method, bitwear analysis should make a valuable contribution
to the study of horse domestication (Anthony and Brown 1991). However, it has
important limitations:
1. Tamed, as well as domesticated,
horses could wear bits.
2. A horse can be ridden without a bit.
3. Anthony and Brown have themselves
observed that bitwear traces will wear off
if a horse is not bitted regularly over a
relatively long period recently before its
death.
4. The question of whether the wear
pattern described by Anthony and Brown
could have had other causes has not been
adequately addressed. Their unbitted
sample of feral horses consisted of 20 individuals from two North American populations (mustangs from the mountains of
Nevada and barrier island ponies from
the Atlantic Coast). They have generalized
from this small sample that unbitted
horses could not manifest the wear pattern they describe as unique to bitwear.
On the other hand, Angela von den Driesch (personal communication) has observed that similar, if not identical, wear
on the lower second premolar can result
from abnormal occlusion with the upper
second premolar.
As far as we know, then, beveling on the
anterior part of the lower P2 masticatory
surface could be caused by bitwear or abnormal occlusion. Either a domesticated
horse or a wild one that had been tamed
could be bitted. The absence of bitwear
could indicate that a horse had not been
ridden recently or regularly before its
death, that it was ridden unbitted, or that
it never was ridden. We must conclude
from this that bitwear should not be used
without corroboration as proof of domestication. This is not to say that bitwear
studies should not be carried out. On the
34
MARSHA A. LEVINE
contrary, their use should be much more
widespread, but in conjunction with other
methods of analysis.
1.2.3. Sample Size and Innovation
Archaeologists and archaeozoologists
continually lament the inadequacy of
their samples. The assumption being
that if only large enough datasets were
available, they would be able to find the
answer to any practically any question.
However, this might not be the case.
Considering the skills needed for managing large numbers of horses and considering the small-scale nature of taming, from which, as will be argued later,
domestication is most likely to have
evolved, the key to the origins of horse
domestication might well lie with small
samples. Archaeozoologists must face
up to this and develop methodologies
that can cope with this reality. To regard
small samples only as a problem is to
miss an opportunity.
1.3. A MULTIDIMENSIONAL
APPROACH
The common thread, connecting all aspects of the project, out of which this paper has evolved is the question of the origins and evolution of horse husbandry,
its social and ecological implications—
whether, for example, it arose out of agricultural, pastoral, or foraging communities— how the domestication of the horse
altered the balance of power in ancient
communities, and its impact on forest–
steppe and steppe ecosystems. In the
broadest sense, my goal is to evaluate the
ways in which environmental, social, and
economic changes are interrelated and to
try to understand the role of the horse in
the equation. Such a complex problem
requires a multidimensional attack with
ammunition provided through the development of new analytical methods. Interdisciplinary collaboration, including, for
example, biomolecular analyses, stable
isotope studies, paleopathology, ethnoarchaeology, ethology, and paleoenvironment research as well as more conventional archaeological methods, is crucial to
this approach. The goal of this paper is to
take a step in that direction by using a
combination of ethnoarchaeological, ethological, and archaeological analyses to
look at the archaeological and archaeozoological data. But this is only the beginning.
2. POPULATION STRUCTURE AND
MODELS OF HORSE EXPLOITATION
The particular aspect of horse husbandry to be examined here is population
structure. Survivorship and mortality patterns of recent horse herds are compared
with various models and with assemblages from Eneolithic and Iron Age/ Roman archaeological sites. The methodology used integrates taphonomy and
butchery evidence with morphometrical,
paleopathological, and population structure analyses. All of these are interpreted
with reference to ecological, ethological,
ethnoarchaeological, and contextual data
(Levine 1979, 1982, 1983, 1990).
2.1. Relationships between Horses
and People
People can have a wide variety of different types of relationships with horses.
Horses can be wild, feral, 3 or domesticated. Wild or feral horses can be hunted
for their meat and other body parts, or
tamed as pets or beasts of burden. Domesticated animals can be raised for
riding, traction, meat, milk, and other
products. Moreover, even within one society any combination of these relationships can coexist.
Though customarily defined as the controlled breeding of plants or animals by
humans, the real distinctiveness of domestication lies in the fact that it involves
ownership and thus results in a com-
ORIGINS OF HORSE DOMESTICATION
35
pletely different level of human commitment than does hunting (Levine 1979).
Horse taming also involves ownership,
but it seems likely from the historical and
ethnographic evidence so far available
that the social and economic implications
of horse taming would have been, at most,
relatively superficial and localized and
would have disappeared with the death of
the animals involved, while the repercussions of domestication would have reverberated throughout the whole society.
Our goal should not, therefore, be simply
to identify horse riding, traction, milking,
and meat eating in the archaeological
record, but, additionally, to find evidence
of horse breeding and taming, which are,
as such, archaeologically invisible. However, they may be approached indirectly
through investigations of population structure, archaeological context, and other
characteristics of the data.
Historical and ethnographic accounts,
as well as new ethnoarchaeological research, are all employed here to gain access to that variability. However, it is important to observe at the very outset of
this discussion that these kinds of data
sources have their own particular problems. For example:
have a good laugh. There is no reason why
the motivations of the informant should
be any less complicated than those of the
interviewer.
3. Which brings us to the distortions
arising from the interviewer’s shortcomings. For example, phrasing a question
clearly, but not leadingly, can be particularly difficult. Imperfect knowledge of the
informant’s native language is a serious
problem. The horse husbandry and
butchery vocabularies of most interpreters are not ideal. Moreover, it is impossible to ask about everything. Certain limits
must be placed in respect for the time and
patience of the informant. Therefore, the
choice of which questions to ask is critical.
They need to be unambiguous and directed specifically toward solving archaeological problems.
4. Then, assuming that we have taken
into account and minimized all these difficulties, we still have to deal with problems associated with the use and misuse
of ethnographic analogy, by its nature
highly complicated and potentially biased, to interpret the archaeological evidence— equally complex and probably
even more biased, for example, by taphonomic factors.
1. Inaccuracy. Particularly in the case of
interviews relating to past practices, we
can expect lapses of memory to distort
events that took place in the past. For example, in the case of interviews dealing
with the period before collectivization, 4
my informants could not recall details of
herd population structure.
2. Distortions resulting from the informant’s own personal agenda. It is well
known among anthropologists that informants may have their own reasons for
what they say. For example, they may under- or overestimate the size of their
herds, if they think that there is an economic or political advantage to do so.
Moreover, many people will say what is
expected of them to please or simply to
Archaeologists have been known to
throw up their arms in despair at the difficulties encountered with ethnographic
analogy and, indeed, some say that it can
only lead to tears. However, to interpret
archaeological data we must have some
understanding of how human beings actually behave. The unsatisfactory nature
of the work carried out until recently regarding horse domestication has clearly
demonstrated this problem (Levine 1990,
1993). Without minimizing the difficulties
involved, it is therefore necessary to learn
how to use ethnographic and historical
data. Consequently, the objective of this
ethnoarchaeological study is not the direct
interpretation of archaeological data from
ethnographic and historical accounts, but
36
MARSHA A. LEVINE
rather, an exploration of the range of extant possibilities, without assuming that
no others could have existed in the past.
2.1.1. Capturing and Taming Horses
According to Clutton-Brock, “A tame
animal differs from a wild one in that it is
dependent on man and will stay close to
him of its own free will” (1987, p. 12).
Aboriginal hunter-gatherers and horticulturists throughout the world are known to
tame all kinds of wild animals to keep as
pets (Serpell 1986, 1989). 5 There is no reason to think that this would not have been
the case at least from the time of the earliest anatomically modern Homo sapiens,
and when the need arose, taming could
well have been the first step toward domestication (Galton 1883; Clutton-Brock
1987; Serpell 1989). Wild horses, particularly as foals, can be captured and tamed
and, as such, ridden or harnessed and, at
the end of their lives, if necessary, slaughtered and eaten.
2.1.1.1. Taming the Przewalski’s horse. Historical records also show that the capture,
taming, and eventual captive breeding of
wild horses was dependent on the accumulation of knowledge about their behavior and on the development of techniques
to exploit that behavior. Perhaps the earliest record of a horse captured by these
means dates from 113 B.C.:
A Chinese . . . near Tun-huang, on the northwest frontier, frequently saw a horse . . . drinking in the river along with a number of wild
horses. He tamed the strange horse by putting at
the water-side a dummy figure of a man in
whose hands were bridle and halter. When the
horse was used to this sight he substituted himself for the dummy, captured the horse. (Waley
1955, pp. 98 –9)
In another example Mohr refers to the
description by John Bell, an 18th-century
Scottish doctor and traveler, of Przewalski’s horse hunting from horseback: “these
animals are often surprised by the Kalmucks; who ride in among them, well
mounted on swift horses, and kill them
with broad lances. Their flesh they esteem
excellent food; and use their skins to sleep
upon” (Mohr 1971, p. 27).
According to 19th-century records,
there were two methods of capturing Przewalski’s horse foals. One was to trap
them in pits dug near waterholes. The
other was for mounted men to chase and
capture them with the arkan (a long pole
with a noose fastened to one end). When
the pursuer came close enough to his target, he would drop the noose over its head
and neck (Mohr 1971). Grum-Grshimailo
documents another method: “During the
foaling season the Kalmucks take two
horses into the desert. As soon as they
have found a herd, they chase them until
the exhausted foals fall over. These foals
are picked up and placed in the domesticated herd” (Mohr 1971, p. 68). Przewalski’s horses were also captured by driving,
though it is not clear whether the beaters
were on foot or horseback: “Even in 1750 it
was said: ‘The entire land around Lyautong is a wilderness; the emperor hunts
there with three thousand beaters, who
put up the game and drive it towards him,
so that in one day 200 to 300 horses,
amongst others may be caught’” (Mohr
1971, p. 27).
The early 20th-century collectors found
that their greatest difficulty was not in
catching the horses, but rather in keeping
them alive in captivity. Attempts to feed
unweaned foals on sheep and goat milk
were not successful. The solution to this
problem was to foster them with domesticated mares (Bouman and Bouman
1994). According to Frederick von FalzFein, one of the early collectors:
In 1897 a number of young wild horses were
captured, but they all died because the catch
was not done as it should have been. I worked
out the fullest details of the method and laid
much stress on the importance of the animals
not being chased before capture, but rather by
shooting their mothers. As we could not get
milking mares from the Mongolians living in the
ORIGINS OF HORSE DOMESTICATION
area, we had to buy them in Bijsk, and have
them covered so that they foaled at the same
time as the wild mares.. . . Since these rules were
not obeyed—the catch was again unsuccessful
and all the animals died. We told Assanoff again
to stick to the rules and thereafter there were no
more failures. (Mohr 1971, 95–96)
Przewalski’s horse mares currently in
captivity usually wean their young from
the age of 1 year until just before the birth
of their next foal, or even for several years
if they do not give birth every year (Houpt
and Boyd 1994). Berger observed of the
Great Basin feral horses that 34 of 40 (85%)
were weaned before the age of 1 year and
27 (79%) of those were not observed to
suckle after their ninth month. “Because
of winter-related stresses and because the
last trimester of pregnancy demands the
most nutritionally . . . mothers weaned their
offspring during winters” (Berger 1986, p.
116). Foals can be weaned much earlier.
However, there is a cost to pay: “Evidence
for the importance of milk versus highly
nutritious food for early growth rates is
still sparse, but animal scientists have
found that orphaned foals experience
stunted development despite provisioning with high planes of nutrition” (Berger,
1986, p. 119). Berger mentions a mustang
from the Granite Range (Nevada), orphaned at the age of 2 months. Despite
access to good-quality grazing, even at the
age of 3 years, he was only the size of a
yearling. Similarly a captive Przewalski
foal, orphaned at the age of 221 months,
survived but lagged in growth behind his
unorphaned paternal half-siblings until
the age of 3 years despite supplemental
feeding (Houpt and Boyd 1994).
Taming and riding Przewalski’s horses
captured from the wild was at one time
considered to be practically impossible
(Mohr 1971). However, Erna Mohr refers
to a 6-month-old Przewalski horse that
“had become so far tame that it was easily
led and went quietly up the granite staircase to the second story of the castle, was
led into a room and allowed the 7– 8 year
37
old son . . . to sit on his back” (Mohr 1971,
p. 69). She also describes how an “untamable” wild stallion was tamed and ridden:
“In Askania Nova however, he found his
master and within a month he was being
ridden by his south Russian groom and on
the command would lie down like a Circassian horse” (Mohr 1971, p. 69).
This has important implications for theories concerning early horse taming. It
seems likely that before the availability of
domesticated mares to foster captured
foals, there would have been both lower
and upper limits to the ages at which taming would have been successful. Although
very few data relevant to this question
seem to be available, the lower limit might
have been at around the age of 2 months.
We can only speculate about a possible
upper limit on the basis of comments in
the literature referring to the difficulty or
impossibility of taming adults (Mohr 1971).
However, other factors, which would also
have been critical, include the skills of the
captor and the personality of the horse.
2.1.1.2. Taming North American feral
horses. Some parallels between central
Eurasian and North American aboriginal
horse capture and taming techniques are
particularly interesting because they suggest that certain aspects of the human–
horse relationship are not culture-bound,
but are rather mediated by both species’
natural patterns of behavior in a much
more fundamental way. For example, according to Ewers (1955), northern Plains
peoples such as the Blackfoot and the
Cree were not very skilled at taming mustangs, the North American feral horses.
Most of the few adult feral horses captured by them died after they reached
camp. However, some colts and yearlings
were caught by “horse medicine men,”
specialist feral horse tamers, whose taming technique was described as follows:
A man who possessed horse medicine for use in
catching wild horses rubbed it on his hands, feet,
and rope. Then he circled the wild horse up wind
so that the odour of the medicine would be carried
38
MARSHA A. LEVINE
to the nostrils of the wild one. When the wild
horse smelled the medicine it came to him. He
roped it by the front feet and threw it down. Only
horse medicine men were said to have had success
in capturing wild horses. (Ewers 1955, p. 274)
According to Ewers, the southern and
central Plains tribes were much more
skilled than the northern tribes at capturing mustangs. The former had more and
earlier experience of horses and they had
bigger herds, which suggests that they
were more familiar with horse behavior.
However, all the Plains groups were in
agreement that mustangs were difficult to
catch. According to George Catlin:
There is no other animal on the prairies so wild
and so sagacious as the horse; and none other so
difficult to come up with. So remarkably keen is
their eye, that they will generally run “at the
sight,” when they are a mile distant; being, no
doubt, able to distinguish the character of the
enemy that is approaching when at that distance; and when in motion, will seldom stop
short of three or four miles. (Catlin 1841, Vol. 1,
p. 57).
The two main tools used for capturing
feral horses were the lasso with a running
loop and the lasso loop fixed to a long
stick, very much like the Mongol arkan
(Ewers 1955). In conjunction with an intimate knowledge of horse behavior and a
fit, well-trained mount, these could be
used successfully to capture and break
mustangs (Catlin 1841; Ewers 1955; Grinnell 1923; James 1823; Wallace and Hoebel
1952). A number of methods of capturing
horses have been described in the ethnographic literature:
1. Corralling: This method was used extensively by the Kiowa and occasionally
by the Commanche 6 and Cheyenne. Wallace and Hoebel (1952) speculate that it
could have evolved out of antelope and
bison hunts, but the same technique was
also used by the Spanish for hunting
horses. On one occasion in 1852, 400 to 500
horses were driven into an enclosure by
the Commanches (Wallace and Hoebel
1952). Grinnell gives a detailed descrip-
tion of a corral apparently used by the
Cheyenne:
[I]n the year 1836, members of Cheyenne war
parties . . . in what is now Oklahoma, found a
great corral which had been used for catching
horses. This pen was situated in a park or opening in the black-jack timber . . . This pen was not
circular in shape, but was oval, the opening being at one end. The fence . . . was a stockade
formed of black-jack posts set on end in the
ground and close together. On the outside of the
fence brush and the limbs of trees were piled
against the stockade. The wings of underbrush
were heaped up high and wide, so that a horse
could neither see through nor jump over
them . . .
. . . the Kiowas explained to the Cheyennes the
purpose and the manner of use of the structure.
Of the horses driven into this corral the best
young ones were roped and dragged out to be
used, while the older and otherwise less useful
animals were butchered for their flesh and
hides. The Kiowas used horse-hide for all purposes for which the skins of large animals are
employed. (Grinnell 1923, p. 292)
2. The Chase: All other things being
equal a man on horseback is no match for
a free-running mustang. Therefore, the
Indians developed variations on the chase
theme that would enable them to capture
strong, healthy animals.
a. Chasing animals in a weakened
state: The ethnographic literature is not
always clear about details of how horses
were captured. However, the most widespread method seems to have involved
running down the mustangs on horseback
and dropping a noose over their head.
This method was employed by the Mandan and the Osage (Catlin 1841), the Commanche (Wallace and Hoebel 1952), and
the Cheyenne (Grinnell 1923). As observed by Wallace and Hoebel, all other
things being equal, this method could be
successful only for weak animals, for example, foals and pregnant or suckling
mares, since a strong horse should be able
to run faster than a horse and rider. However, things were not always equal. For
example, using a well-fed riding horse
gave the captor an advantage in the winter
ORIGINS OF HORSE DOMESTICATION
or early spring when most feral horses
were in poor condition. On the other
hand, a fit horse could be used to run
down fat horses in summer or to chase
“waterlogged” horses just leaving the waterhole (Wallace and Hoebel 1952; Grinnell 1923).
b. Chasing in relays: This method was
expensive in terms of energy consumption, but would have resulted in the capture of the very best animals, including
stallions. It was used by the Osage (James
1823) and the Commanche (Wallace and
Hoebel 1952).
In capturing the hard-to-take stallions . . . the
best way was to stalk them with a team of cooperating hunters. Each herd tended to move
about within a limited range of territory; when
flushed, it was likely to travel in a circle, returning eventually to or near the spot where it was
originally found. To accomplish this end, one or
more horsemen kept the herd continuously on
the move without allowing it either to eat or to
drink . . . the stalkers, by remaining on the inside of the circle, travelled a much shorter distance than the herd. When their own mounts
wearied, the riders were replaced by others or
were supplied with fresh mounts. This procedure was continued without let-up for two or
three days or until the herd became exhausted,
when a number of riders on fresh mounts rode
in and lassoed their pick of the wild horses.”
(Wallace and Hoebel 1952, p. 44)
c. The surround: On the open plains,
mustangs would be surrounded by a
group of riders. When a horse would try to
break away, a noose was dropped over its
head (Wallace and Hoebel 1952).
d. Chasing on foot: According to Catlin,
the Cheyenne, who captured more mustangs than any other tribe, frequently
used this method. A horseman would
start out by “plunging” into a band of wild
horses, forcing one animal out of the
group, whereupon he would dismount
from his own animal and set out on foot
after the panicked individual. This is another method that exploits the horse’s ten-
39
dency to circle to the left when being followed:
The Indian seeing the direction in which the
horse is “leaning,” knows just about the point
where the animal will stop, and steers in a
straight line to it, where they arrive nearly at the
same instant, the horse having run a mile, while
his pursuer has gone but half or three-quarters
of the distance. (Catlin 1875, p. 113).
He would thus keep it on the move until it
was so exhausted that he could throw a
lasso over its head.
3. Capturing with decoys: Both the
Cheyenne and the Commanches targeted
bachelor groups by sending out a few old,
gentle mares as decoys (Wallace and
Hoebel 1952; Grinnell, 1923). According to
Grinnell, “after a time the herd could be
approached, driven together, and perhaps
many of the young horses caught” (Grinnell 1923, p. 295).
2.1.1.3. Taming captured mustangs. Some
of the ethnographic reports are rather
self-contradictory in that they suggest, on
the one hand, that taming feral horses was
very difficult while, on the other hand,
they describe the process as if it were very
simple. For example, regarding the aboriginal inhabitants of the Great Plains,
Catlin states that “Scarcely a man in these
regions is to be found, who is not the
owner of one or more of these horses; and
in many instances of eight, ten or even
twenty, which he values as his own personal property” (Catlin 1841a, p. 142).
Moreover, with regard to the acquisition
of a mustang by a Frenchman, raised in an
Osage village, he remarks: “the whole
thing, the capture, and breaking, all having been accomplished within the space of
one hour, our usual and daily halt at midday” (Catlin 1841b, p. 60). This paradox is
partly explained by the diverse origins of
the sources referred to here, but perhaps
also by the talent that experts have to
make the most difficult activities appear
simple. In other words, it is possible that
the European observers overstated their
40
MARSHA A. LEVINE
understanding of the events taking place
around them. This ignorance is well illustrated by Catlin’s account of his own misbegotten attempt to capture a feral horse:
[W]e would try the experiment of “creasing”
one . . . which is done by shooting them through
the gristle on the top of the neck, which stuns
them so that they fall, and are secured with
hobbles on the feet; after which they rise again
without fatal injury. This is a practice often resorted to by expert hunters. . . . My friend Joe
and I . . . having both levelled our pieces at the
withers of a noble, fine-looking iron grey, we
pulled trigger, and the poor creature fell. . . .We
advanced speedily to him, and had the most
inexpressible mortification . . . to find that one of
our shots had broken the poor creature’s neck,
and that he was quite dead. (Catlin 1841b, p. 58)
Despite its shortcomings, it is useful to
consider some of the documentation referring to the process of breaking and
taming feral horses. According to Catlin,
the affect of the lasso on the horse was to
constrict its air passage until it fell over,
whereupon its captor hobbled its forefeet
together, fitted a halter with a noose that
tied under its jaw, and loosened the lasso
so that it could breathe. Then,
by a great many useless struggles to rise, the
horse remaining yet in its sitting posture, and
the Indian approaching nearer and nearer (inch
by inch) to its nose, on the shortened halter, and
yelling as loud as he can, the animal’s fear is
increased to the highest degree. The Indian still
advances nearer on the tightened halter, and at
length begins patting the horse on the nose, and
gradually slipping his hand over its eyes, begins
breathing in its nostrils, their noses being together.
After a few breaths exchanged in this manner,
the relaxation of the horse’s muscles and its
other motions, show that its fears are at an end—
that it recognises a friend instead of a foe, in its
captor; and this compromise being effected, the
Indian is seen stroking down its mane, and otherwise caressing it; and in fifteen or twenty minutes he is seen riding it quietly off!
. . . the excess of fatigue, of fright, and actual
pain, followed by soothing and kindness, seems
to disarm the spirited animal, and to attach it at
once, in a mysterious way, to its new master.
(Catlin 1875, p. 109 –110)
Interestingly this method employs the
same kind of psychological approach as
that recently developed by Monty Robert
in which the safe space or “comfort zone,”
occupied by the gentle but dominant
trainer, is opposed to the dangerous space
away from him, in which the horse feels
threatened and isolated (Bayley and Maxwell 1996). This training method takes advantage both of the horse’s instinctive
flight response and of its natural sociability.
One Commanche and Cheyenne method
of taming involved tying the choked captive to the tail of a gentle mare (Wallace
and Hoebel 1952; Grinnell 1923):
Three or four days later . . . it was set free, and
thereafter followed her about wherever she
went. The mare was then used to tame another
horse, and if the party was out for a long time
some mares might have eight or ten captured
horses following them about. These wild horses
were readily broken to the saddle. While they
were “tailed” to the mare, the owner would occasionally go up to the mare, pat her for a little
while, and then pass on to the young horse,
handling it and gentling it. In this way it became
accustomed to the sight and smell of man, and
no longer feared him. Sometimes after the horse
had become somewhat gentle, a young man
would spring on its back and at once jump off
again. The wild horse soon learned that it was
not to be hurt. The man who mounted would
presently sit on the horse for a little while, and
then the old mare might be led about by someone while the young man was sitting on the wild
horse’s back. Thus the work of breaking it to ride
was not long. (Grinnell 1923, pp. 294 –295)
Unfortunately, no survival rates are
available for any of these methods. But
some were, apparently, brutal enough to
explain the difficulty some groups experienced in keeping captives alive. Other relevant factors could well have been the
age, sex, constitution, and personality of
the horse as well as the skill of the captor.
2.1.2. Modelling Horse Use
During historical times both the North
American Plains tribes and the Mongols
ORIGINS OF HORSE DOMESTICATION
used the arkan, lasso, or herd drive to capture wild or feral horses to eat or to tame.
Horses taming was regarded as a skill
most successfully carried out by specialists, whose most important tool was their
intimate knowledge of horse behavior. On
this basis I would like to propose a possible scenario for the development of horse
husbandry.
As a working hypothesis, I would like to
suggest that horse taming probably first
arose as a by-product of horse hunting for
meat. Orphaned foals, captured between
the ages of perhaps 2 months and 1 year,
or possibly somewhat later, would sometimes have been adopted and raised as
pets. Eventually, and perhaps repeatedly,
the discovery was made that these pets
could be put to work. This knowledge
could have been acquired and lost many
times from the Pleistocene onward. But it
was, apparently, only during the Holocene—possibly between the Neolithic and
the Early Bronze Age—that it began to
influence human social developments.
Initially the difficulties involved in
keeping captured wild horses alive would
have set limits to their impact as work
animals on human society. Furthermore,
considering the problems encountered by
modern collectors trying to breed Przewalski’s horses, it seems likely that horsekeeping would have had to have been
relatively advanced before controlled
breeding, and thus domestication, would
have been possible: “Failure to consider
the typical social organization of the species can result in problems such as pacing,
excessive rates of aggression, impotence
and infanticide” (Boyd and Houpt 1994, p.
222). To breed wild horses successfully in
captivity, their environmental, nutritional,
and social requirements must be met:
In zoos, juvenile male Przewalski’s horses
should be left in their natal bands for at least a
year so that they can observe mating behaviour.
They should be placed in bachelor herds when
removed from the natural band, and not given
harems until they are at least four or five years of
41
age. The first mares placed with the stallion
should be younger than he and the harem size
should be kept small until the stallion gains age
and experience. (Boyd and Houpt 1994, p. 226)
That capturing wild horses and stealing
tamed or domesticated ones were regarded by the Plains tribes as preferable
to breeding them supports the scenario
proposed here. If it is correct, it seems
likely that there would have been a relatively long period when new horses would
have been recruited from wild populations. This could have been carried out by
trapping, driving, and chasing, as documented for the Mongols and North American Plains tribes.
This leads me to hypothesize that horse
domestication could have taken a relatively long time to develop and might well
have depended on the taming of individuals predisposed to breed in captivity.
Horse domestication would thus, in a
sense, have been initiated by the horses
themselves. Also significant is the possibility that human understanding of horse
behavior had developed to such a degree
that horses finally could breed in captivity. Perhaps the most likely scenario is
that the human and equine parts of the
equation would have evolved together.
The development of horse breeding
would, of course, have had particular significance outside the natural range of the
wild horse.
2.2. An Ethnoarchaeological
Investigation of Equine Pastoralism
Scholars from Russia and other parts of
Eastern Europe have carried out immensely valuable ethnographic research
on central Eurasian equine pastoralism.
However, this work does not usually directly address the questions of particular
relevance to the study of the origins of
horse domestication. The project to be
discussed below has been designed specifically to deal with issues connected with
that problem. It presents some results
from an ongoing ethnoarchaeological
42
MARSHA A. LEVINE
TABLE 2
Informant’s Background Information
Informant
Location
Ecosystem
Husbandry
type
Economic
system
Damdin
Jambalsuren
Mursabaev
Shavardak
Kozakhmetov
E. Mongolia
C. Mongolia
N. Kazakhstan
N. Kazakhstan
N. Kazakhstan
Steppe
Mountains
Forest–steppe
Forest–steppe
Forest–steppe
Traditional
Traditional
Modern
Modern
Traditional
Nomadic
Settled
Ranching
Settled
Semi-nomadic
study of equine pastoralism on the Eurasian steppe. The data have arisen principally in the course of five interviews, conducted between 1989 and 1992, with
people involved with horse husbandry in
Mongolia and northern Kazakhstan in the
recent past or present.
2.2.1. The Interviews
Although the interviews covered all aspects of horse husbandry—from those
related to riding and traction to those connected with milk, meat, and hide production—this paper concentrates on those
associated with population structure. It attempts to demonstrate how certain archaeozoologically visible characteristics of
horse husbandry, such as age and sex
structure, fit into the overall picture of
pastoral life. It also gives some indication
of the variability of possible behaviors related to equine pastoralism. Although the
data collected are not generally appropriate for direct translation into life tables,
they can be used for the development of
models and in general comparisons.
The word traditional is used here primarily to describe precollectivization
methods of horse husbandry. Collectivization took place— or perhaps more significantly, took hold—in different places at
different times. In northern Kazakhstan it
is dated to the 1930s, but it was not imposed on Mongolia until 1955. Since my
informants’ accounts are entirely dependent on their memories, the earliest pe-
riod discussed here will be that of their
childhood or as far back as their parents’
reminiscences. Thus, traditional, as defined here, extends from the end of the
19th century to the 1930s in the case of
Kazakhstan and to the 1950s in the case of
Mongolia.
2.2.1.1. Background information (Table
2). The first two interviews were carried
out in Cambridge in 1989 and 1990. The
informants, Damdin and Jambalsuren, were
visiting scholars at the Mongolian and Inner Asian Studies Unit (Cambridge).
Damdin, a senior lecturer in the Department of Foreign Languages (Ulan Bator
University, Mongolia), grew up on the
steppe in the extreme eastern part of
Mongolia, in the Jargalant district of the
Dornod province during the late 1930s
and 1940s. He was from a family of pastoral nomads belonging to the Khalkha clan.
Since collectivization did not take place in
Dornod until 1955, the way of life he describes was still rather traditional. Important characteristics of this lifestyle include
the absence of permanent dwellings (they
lived in felt tents, known as yurts), and
year-round migrations, seasonal in character, in search of grazing for their herds
of horses, sheep, goats, cattle, and camels.
Jambalsuren (Academy of Sciences, Institute of Language, Ulan Bator, Mongolia) grew up in the mountainous region of
central Mongolia during the 1950s. His father was a carpenter and his family was
settled. Until the age of 16 years Jambalsuren was a yak herder. Because his father
43
ORIGINS OF HORSE DOMESTICATION
was a craftsman and because of the mountainous terrain, his family did not have
many horses. He, therefore, had only a
limited knowledge of horse husbandry.
The next three interviews took place in
1992 in the forest–steppe zone of northern
Kazakhstan, where the informants live.
Dastan Chalievich Murzabaev, president
of the trade union at the Kirov sovkhoz in
the Dzhambul region of North Kazakhstan,
discussed contemporary horse ranching at
the state farm where he worked.
Yurii Ivanovich Shavardak works for
the Burlukskii sovkhoz (Volodarovskii
district, North Kazakhstan). He herds all
the horses from Nikolskoe, a village near
the archaeological site of Botai. Most of
the horses are owned privately by the Kazakh inhabitants of the village, but some
belong to the sovkhoz. Shavardak grew up
in Nikolskoe and, although he is Russian,
he was trained to herd and butcher horses
using a mixture of modern, that is, postcollectivization, and traditional Kazakh
methods. Collectivization took place in
this region during the 1930s.
Mamet Kozhakhmetovich Kozhakhmetov, born in 1915, is a former herdsmen,
then schoolteacher, and finally, at the time
of the interview, a pensioner. He was born
and brought up at Botai aul7 (Karatalskii
sovkhoz, Volodarovskii district, North Kazakhstan). With the help of Eslyambey
Zakir’yanovich Zakir’yanov, his relative
and headmaster of the school in Nikolskoe, he described horse husbandry as it
was in his childhood, before collectivization. The people from Botai aul are permanently settled now, but before collectivization they were seminomadic. They
spent the cold months of the year in the
permanent dwellings of the aul. In the
summer, however, they moved onto the
steppe. Each household had traditional
rights to a particular territory and to a plot
of land where they could set their yurt
each year.
A relatively wide variety of ecosystems
TABLE 3
Number of Horses per Household
Informant
Minimum
Average
Maximum
Damdin
10
Jambalsuren
1/ person
Mursabaev
1
Shavardak
1
Kozhakhmetov
4–10
20–301
40
—
—
40
100s–1000s
3000
—
10
300
(steppe and forest–steppe) and husbandry
strategies (nomadic, semi-nomadic, and
settled) are represented in these interviews. The diversity of the data gives
some idea of the range of possible strategies available to horse herders in the
steppe and forest–steppe regions of central Eurasia. It is hypothesized that similarities and differences arising from that
diversity might have some value in elucidating some of the fundamental elements
of equine pastoralism. Of course, care
must be taken in generalizing from such a
small sample. Moreover, throughout the
millennia waves of change have repeatedly swept across Eurasia, drawing people
together and tearing them apart, reminding us that history is no bit player in this
story.
2.2.1.2. Number of horses per household
(Table 3). Generalizations about the
quantity of horses in settled households
are not very useful, but it is quite interesting to compare figures obtained from
Damdin and Kozhakhmetov concerning
the period before collectivization. Taking
care not to read too much into a sample of
2, it does seem that concepts relating to
herd size were very similar for both the
nomadic Mongols and semi-nomadic Kazakhs interviewed. To carry out seasonal
migrations at least 10 horses were necessary. An average household had about 20
to 40 and a rich household might have
kept hundreds or even thousands of
horses. These figures are in line with
those given by Khazanov (1984), Toktabaev (1992), and Krader (1955). Shavard-
44
MARSHA A. LEVINE
TABLE 4
Herd Population Structure
Herd sex composition
Informant
Reproductive unit
Gelding structure
Stallions
Mares
Foals
Geldings
Damdin
Jambalsuren
Family group
Family group
With family group
Near family group
Mursabaev
Shavardak
Kozhakhmetov
Stallions 1 mares
Family group
Family group
In separate group
In separate group
In separate group
1
1
(0) a
1
1
1
15–20
15
(1)
25
45
15–20
15–20
15
(0)
?
45
20
15–20
10
(4)
?
15
?
a
Figures in parentheses refer to his own family’s horses.
ak’s herd comprises about 100 horses,
around 15 of which belong to the state
farm, while the rest are privately owned.
Nearly all the Kazakh households in Nikolskoe have at least one horse, while
some have as many as 10.
2.2.1.3. Population structure (Table 4). The
natural reproductive unit of the
horse is the family group, composed of a
stallion, his mares, and their young up to
the age of about 2 to 4 years. It may comprise up to 21 mares, although the average
is usually much less, perhaps around 2 to
4 and usually no more than 5 or 6 (Berger
1986; Klingel 1969, 1974; Bouman and Bouman 1994, Houpt and Boyd 1994). The stallion normally starts his own family group
at the age of 5 or 6 years, although he
might not be successful at holding one
against attacks from other males until the
age of 7 (Klingel 1969; Berger 1986; Monfort et al. 1994; Houpt and Boyd 1994). The
second natural type of horse social unit is
the bachelor group, made up entirely of
males from the age of 2 years until their
departure from the group to form their
own bands and, less commonly, of older
males who have lost theirs to stronger
stallions. The bachelor group may comprise up to 15 individuals, but the average
is much lower, about 2 to 4 (Klingel 1969;
Berger 1986).
The structure of the wild herd is relevant here because all the horse husbandry
patterns, described by my informants, ex-
ploit to some extent the natural tendency
of horses to structure themselves into
family groups. That is, the pastoralist reproductive unit mimics the natural family
group, composed of a stallion, his mares,
and their young. However, the structure
of the pastoralist herd is, in all cases, distorted by the artificially large number of
mares assigned to each stallion. This is
most extreme for the nontraditional herders. The ratio of 1 stallion to 15 to 20 mares
is remarkably constant in the traditional
context. This is particularly interesting in
the light of an observation by Houpt and
Boyd that “Przewalski’s stallions with harems of thirteen to eighteen females have
become overly aggressive toward their
mares or apathetic about breeding” (Boyd
and Houpt 1994, p. 226). That the domestic
mare:stallion ratio is only a little greater
than the Przewalski ratio, attests both to
the consistency of horse behavior and to
the herders’ knowledge. Geldings are the
domestic equivalent of equine bachelors.
All males surplus to breeding requirements are castrated.
In the Mongolian cases all age and sex
classes graze more or less together. In
Damdin’s pastoral nomadic example, the
geldings graze in their natal family
groups. According to Jambalsuren, geldings graze together near the family group
but apart from it. The Kazakh herd structure seems generally to be more complicated. According to Murzabaev’s ranching
45
ORIGINS OF HORSE DOMESTICATION
TABLE 5
Shavardak’s Herd: Population Structure
Age
(years)
Frequency
Sex
0–1
1–2
2–3
40
30
2–3
3–5
5–10
10–15
15–20
.20
30
8–10
10
10
8
10
1
120.5
Male:female ratio approx 1:1
Male:female ratio approx 1:1
Females only
Females only, have had first
birth
Females only
Females only
Females only
Females only
Stallion
Excludes geldings
example, all foals are taken from their
mothers at the age of about 6 or 7 months,
when they are weaned. They are then kept
in a separate herd, composed entirely of
young horses. The family group described
by Shavardak is composed of the stallion,
mares, young of the year, yearlings, and a
few 2- to 3-year-olds (Table 5). In Kozhakhmetov’s semi-nomadic herd, foals under 1 year and yearlings were left with
their mothers in the family group. All the
2- to 3-year-olds from the aul grazed together in a separate herd. The geldings
would graze with the 2- to 3-year-olds unless there were too many, in which case
they constituted a herd of their own.
2.2.1.4. Reproduction (Table 6). The fecundity of the horse is, at its most basic
level, controlled by its biology and its
ethology, so that divergence from the natural situation is of considerable interest.
Horses are generally most productive between the ages of 4 and 15 years.
Przewalski’s mares are capable of conceiving by 2 years of age; however, most
do not breed until their fourth year. They
usually remain fertile until around the age
of 20 years, though one is known to have
given birth at 24 years (Montfort et al.
1994). Granite Range feral mares have
been known to bear their first young at the
age of 2 years, which means that some
became pregnant as yearlings. They can
continue to produce foals at least until the
age of 22 years; however, the period of
greatest productivity is between the ages
of 5 and 17 years:
About 37% of the two-year-olds and 40% of the
three-year-olds produced foals, while females
four years and older were more successful at
producing foals . . . for the most part, females
between five to seventeen years of age enjoyed
the greatest success in foal production . . . At
least 83% of (p.79) females within this age cohort
gave birth to four foals over a five year period.
(Berger 1986, p. 80 – 81)
When he looked at some other mustang
populations, Berger discovered that 2-yearolds did not produce young. The 3-yearolds did, but percentages ranged from 11
to 25%. Five-year-olds were found to be
more fecund than 4-year-olds in all populations. The rates for each cohort were
TABLE 6
Reproduction
Age begin breeding
(years)
Informant
Damdin
Jambalsuren
Mursbaev
Shavardak
Kozhakhmetov
a
Age cease breeding
(years)
Stallions
Mares
Stallions
Mares
Foals/ year/ mare
4–5
4 (?)
2
4
4
4–5
4
2
2–3 a
3–4
Old
10–15 (?)
15
30
20
14–16
101 (?)
15
30 –35
20 –30
Almost 1
Around 1 (?)
1
Almost 1
1
The most frequent age is in boldface.
46
MARSHA A. LEVINE
TABLE 7
Riding
Which ridden?
Informant
Geldings
Stallions
Mares
Age broken for riding
(years)
Damdin
Jambalsuren
Mursabaev
Shavardak
Kozhakhmetov
Ya
Y
y
Y
Y (3–5 c)
y
?
?
n
n
y
y
y
n
y
1 (2 b)–3
1–3
2
3
2
a
Y, most frequently ridden; y, ridden not as frequently as Y; n, not usually ridden.
Age most usually broken.
c
Number of riding horses/ household.
b
lower than those in the Granite population, which is growing. Berger also observed that foaling rates for North American feral horses were generally higher
than those of South African thoroughbreds (Berger 1986).
Wild and feral stallions usually start
breeding later than mares, at around 5
years of age, but can continue longer. The
oldest known successfully breeding Przewalski stallion was 36 years old. Experience with breeding captive Przewalski
males suggests that “immature males (up
to four years of age) may be incapable of
breeding because they either are subordinate to older stallions/ mares or exhibit incompetent sexual behaviour” (Montfort et
al. 1994, p. 188). Apparently none of the
Granite Range males under 5 years of age
succeeded in producing young. Of those 5
years old or less, 71% (5 of 7) lost their first
mares, while none 6 years or older did.
The stallions that fathered the greatest
numbers of offspring were 7 to 10 years
old and the next most productive were 11
to 13 years old. The oldest stallion that
succeeding in siring offspring was about
22 years of age (Berger 1986).
Domesticated Mongol and Kazakh stallions begin breeding earlier than the wild
and feral ones. Moreover, while all the
domesticated females begin to breed at
around the same age as free-living ones,
the Mongol mares start later than those of
the Kazakhs. According to Berger, the
causes of this kind of variability are unknown (Berger 1986). However, such factors
as the availability of high-quality forage
and favorable environmental conditions
are probably important.
The age at which stallions cease breeding is similar in all the populations discussed here. For mares, however, it is
much more variable. Kazakh mares may
continue producing young until the age of
20 to 35 years. However, according to
Damdin, after the age of 15 or 16 years,
Mongol mares are no longer able to produce strong enough foals. They are therefore slaughtered at that age. Since most of
the foals from the Kazakh populations discussed here are raised for meat rather
than to ride, their quality is not as important as their quantity. It might also be
significant that environmental conditions
in northern Kazakhstan are generally less
harsh than those in eastern Mongolia.
2.2.1.5. Riding (Table 7). Generalizing
from the five interviews discussed here, it
is clear that, although stallions and mares
as well as geldings are ridden, the latter
are most important for this purpose.
Horses are usually broken at around 2–3
years of age, but are not ridden hard until
they are approximately 3– 4 years old. The
particular arrangements described by
each of the informants relate to the ways
47
ORIGINS OF HORSE DOMESTICATION
in which horse husbandry fits into their
local environments and economies.
The nomadic pastoralists described by
Damdin ride mainly geldings; however,
mares and stallions are also broken and
trained. It is the attitude of these people
that all the horses in a herd must be ridden; otherwise they might as well be wild.
It is only a bad herdsman who does not
use all his animals. This is, no doubt, a
response to the harshness of the eastern
Mongolian steppe environment. Important as they are for meat and other purposes, survival depends on having enough
mounts. Breaking horses here is a relatively gradual process. At the age of 1 the
foal is trained to wear a halter and is broken to the saddle when it is 2 to 3 years of
age. This job is carried out by boys from 10
to 16 years of age. Initially the young
horses are ridden only near the yurt by
children.
Settled Mongols like Jambalsuren apparently rode both male and female horses,
though geldings again were most important. Jambalsuran’s family did not breed
horses and kept them mainly for riding.
Their three mounts, one for each member
of the family, were purchased from friends
and neighbors.
According to Shavardak, the riding
horses in Nikolskoe are almost exclusively
geldings. Mares are used almost entirely
for breeding, milk, and meat production,
while the stallion was used only for breeding. Likewise in Kozhakhmetov’s seminomadic pastoralist example, the individuals selected for riding or traction were
most usually geldings. It was not considered necessary to break all horses for
riding. Three to five mounts would usually be enough for a household. Mares
could be broken as work animals, but it
was regarded as better to save them for
breeding. The difference between these
Kazakhs and the Mongols, described by
Damdin, is probably at least partly referable to the shorter distances traveled and
TABLE 8
Milk, Meat, and Fat
Informant
Milk
Meat
Fat valued?
Damdin
Jambalsuren
Mursabaev
Shavardak
Kozhakhmetov
No
Yes
Yes
Yes
Yes
Yes
Rarely
Yes
Yes
Yes
Highly
Highly
As bovidae
Highly
Highly
less extreme climatic conditions in northern Kazakhstan by comparison with eastern Mongolia.
2.2.1.6. Milk, meat, fat, and other products
(Table 8). In both northern Kazakhstan
and Mongolia horses are slaughtered
from late November to late December or
January, while their fat content is still
high. Because of the long and intensely
cold winters in this region, meat can be
stored outdoors without refrigeration. Except for special occasions like weddings
and funerals, horses are almost never
slaughtered during the rest of the year.
According to Damdin, unlike beef, horsemeat cannot be dried, so that in his region
it is always eaten fresh. However, in
northern Kazakhstan the usual practice is
to smoke any fresh meat left over at the
end of the winter.
Horse milk, meat, and fat are valuable
and highly valued resources for the Turkic
(including Kazakh) and Mongolian inhabitants of the Asiatic steppe (Levine 1998a).
Medicinal as well as nutritional properties
are attributed to them. These traditional
beliefs are, in fact, supported by scientific
research. Horse flesh is an important source
of vitamins, minerals, essential amino acids, and essential fatty acids (Gunga 1976;
Rossier and Berger 1988). By comparison
with that of ruminants such as cattle and
sheep, equid flesh is high in protein and
low in fat (particularly saturated and
mono-unsaturated fat) (Gade 1976). Table
9 shows that horse meat and milk are proportionately much richer in essential fatty
acids (particularly linoleic and a-linolenic
48
MARSHA A. LEVINE
TABLE 9
Fatty Acid Composition of Some Animals
Depot fat (% by weight)
Fatty acid
Saturated
C 14 and below
Palmitic (C 16 )
Stearic (C 18 )
C 20 and above
Mono-unsaturated
Palmitoleic (C 16 :1)
Oleic (C 18 :1)
Polyunsaturated:
Linoleic (C 18 :2)
Linolenic (C 18 :3)
Arachidonic (C 20 :4)
C 22 and above
Milk (% by weight)
Cow
Sheep
Horse
Human
Pig
Chicken
Whale
Cow
Horse
Human
Whale
3
29
21
1
3
25
28
0
5
26
5
Trace
6
25
6
1
1
30
16
0
1
25
4
0
9
15
4
1
25
25
9
1
22
16
3
0
15
23
7
1
8
17
2
0
3
41 a
1
37 a
7
34
7
45
3
41
7
43
14
33
4
30 a
7
19
5
36
6
18 (?)
2a
0
Trace
Trace
5a
0
1
1
5
16
2
2
8
0
2
2
7
0
2
2
18
0
1
1
0
4
12
8
4a
0
Trace
Trace
8
16
5
5
8
0
3
3
?
9 (?)
26 (?)
13
a
Mainly trans-isomers in linoleic acid and partly in oleic acid.
Source. Reprinted, with permission, from Sinclair (1964).
acid) than ruminant meat and milk (Sinclair 1964; Williams and Crawford 1987;
Rossier and Berger 1988). Even the meat of
old horses is relatively tender and, by
comparison with ruminant flesh, highly
digestible (Gade 1976; Rossier and Berger
1988). This difference is also reflected in
the behavior of the Hadza, hunter-gatherers from Tanzania (James Woodburn, personal communication). According to Woodburn, traditionally the Hadza hunted a
wide variety of herbivores of which the
most important numerically were impala
and zebra. Zebra was preferred, because
of the nature and abundance of its fat. The
Hadza, like many other traditional hunters, value fat more highly than protein
(Speth 1983). They classify fat as either
hard (high in saturated fat, as in the case
of bovids) or soft (high in polyunsaturated
fat, as in the case of equids). Because of
the importance of soft fat as a weaning
food, an adult male zebra is an ideal
Hadza prey.
Horse flesh is regarded by both Kazakhs and Mongols as especially important
in winter or when they must travel. According to Damdin, a person who eats
horse flesh for breakfast can work
throughout the whole day. Animal fat is
considered by steppe pastoralists to be
very good for human health and, of all the
domesticates, that of the horse is regarded
as best. Horse fat is eaten on its own or
with meat, boiled or in sausages. In Kazakhstan it is thought to be good for treating
tuberculosis and is of particular importance as a weaning food for babies. According to Bulat Kanafin, a Kazakh from
Petropavlovsk, babies were traditionally
weaned on pasta mixed with fat from one
of three sources: (1) fat from the hump of
a camel is used in the south, (2) ram’s tail
fat boiled in milk is used everywhere, (3)
fat from over the horse’s sternum or cervical vertebrae is also used everywhere.
Of the three, camel fat and horse fat are
considered by both children and adults to
be the best by far because of their superior
taste and digestibility. The horse fat overlying the cervical vertebrae is regarded by
all my Kazakh informants as a great delicacy to be given to honored guests. According to Damdin, in eastern Mongolia
the fat skimmed off boiled horse meat can
be added to the fodder of exhausted livestock or fed to dogs. It is also used as a
ORIGINS OF HORSE DOMESTICATION
49
FIG. 1. Milking at Botai aul. The foal must be present for the mare to let down her milk.
face ointment to protect against the cold
and wind.
Of all the people discussed here, only
Jambalsuren’s settled yak breeders do not
value horse flesh as food. Sheep and yak
are their preferred meat animals. Moreover, their whole approach to horse meat
consumption is at variance with that of all
the other groups discussed here. Horse
meat in this non-horsebreeding region is
relatively cheap. Therefore, it is eaten
mainly by poor families. Moreover, while
in the other regions, the ratio of males to
females slaughtered for meat is either
equal or favoring males, in this mountainous region it is primarily females that are
slaughtered. Geldings are not eaten at all.
Jambalsuran said that he himself would
not eat horse meat, that the smell was
terrible, and that people in this region
preferred not to eat horse meat out of
respect for horses. Those who did eat it, to
avoid its bad smell, did so in winter when
the weather was cold. This prejudice
against horse meat consumption seems
most likely to be referable to the need in
this non-horsebreeding region to keep
horses as much as possible for riding and,
where this is not possible, to slaughter
animals least used for riding, that is, females.
Horse milk production apparently takes
place everywhere on the steppe wherever
ecological conditions are favorable (Fig. 1).
(Dakhshleiger 1980). Of all my informants
only Damdin came from a place where
very little milk was produced. He said that
the milk from his region is of very poor
quality: it does not ferment well, perhaps
because of the climate or grazing conditions. Unfortunately he could not elaborate further on the ecological conditions
necessary for horse milk production. According to Krystyna Chabros (personal
communication) horse milk production is
particularly important in central Mongolia. Horses are sometimes milked in the
west, but not in the semi-desert regions,
where there are relatively few horses. Fermented horse milk, kumys, “plays an extremely important role in Kazakh everyday life. It is to Kazakhs what bread is to
Russian peasants. It is not only a palatable
drink, but also sometimes their only food”
(Toktabaev 1992, p. 11). According to a
Kazakh proverb, “Kumys cures 40 dis-
50
MARSHA A. LEVINE
TABLE 10
Usual Cause of Death
Informant
Stallions/
consecrated
geldings
Damdin
Natural causes
Jambalsuren
Mursabaev
Shavardak
Kozhakhmetov
Natural causes
Slaughter
Slaughter
Slaughter
a
Geldings/ male
foals
Mares
Slaughter
Natural causes a/
slaughter
Slaughter
Slaughter
Slaughter
Season of slaughter
Slaughter
Late autumn to winter
Natural causes
Slaughter
Slaughter
Slaughter
Late November to December
Especially December
Late autumn to early winter
November to December
The most probable cause is in boldface.
eases” (Toktabaev 1992, p. 12). In fact,
mare’s milk is much higher than that of
cow in linoleic, a-linolenic, and arachidonic acid (Table 9). For this reason donkey milk, which has a similar composition,
has been used in France in preference to
cow’s milk for feeding preterm human babies (Michael A. Crawford, personal communication).
The horse is used extensively in Kazakh
folk medicine (Toktabaev 1992). Horse fat,
excrement, bone, hair, liver, kidney, and
stomach are used in the treatment of
many ailments. Horse sweat is said to cure
gastric diseases, ulcers, typhoid fever,
plague, fever, and cancer of the gullet.
Back problems were treated by wrapping
the sufferer in a fresh horse skin.
Horse milk, fat, and meat are important
foods in central Eurasia (Levine 1998a).
However, they are not consumed everywhere within that region. Some curbs are
clearly ecological; in Damdin’s region milk
cannot be produced for human consumption. Others are apparently cultural; in Jambulsuren’s region horse meat is regarded as
disgusting. However, this reaction might
have an ecological origin. In the mountains,
horses cannot be bred in large numbers;
their most important use is for transport.
The British taboo against eating horse meat
probably combines religious, cultural, historical, and ultimately ecological factors
(Gade 1976). Although this subject is of
great relevance to our understanding of the
dynamics of human adaptations, it has, with
the notable exception of Gade (1976), as yet
received little attention.
2.2.1.7. Mortality (Tables 10 and 11). According to my informants, horses not used
TABLE 11
Age at Death
Age at death (years) a
Informant
Damdin
Jambalsuren
Mursabaev
Shavardak
Kozhakhmetov
a
Stallions/ consecrated
geldings
Mares
Geldings/ male foals
Maximum age
161
301
15–20 ?
25–30
201
14–16
4/ 301
1–1.5/ 15–20 ?
2–5/ 25–30
1–3/ 201
15–16 or more
301
1–1.5/ 15–20 ?
2–5/ 25–30
1–3/ 251
271
33
30
35–40
30
Age/ sex classes preferred for slaughter are in boldface.
ORIGINS OF HORSE DOMESTICATION
for meat are allowed to die of old age, but
on the steppe this is clearly exceptional.
There are two main periods of slaughter,
relevant in varying degrees to both Kazakhstan and Mongolia. The first extends
from the ages of around 2 to 4 years and is
usually biased toward males. The second
period usually takes place between the
ages of 14 and 20 years and is biased toward females.
In the pastoral nomadic context described by Damdin, geldings consecrated
to the spirits and all stallions die of natural
causes. Other horses are slaughtered only
when they are no longer productive, usually after the age of 14 to 16 years. Because
the main use of mares is for producing
young and (in some regions) milk, after
they have been barren for 2 or 3 years
running, they are slaughtered. Geldings
are usually killed later than mares since
they are productive longer. In the modern
situation 2- to 3-year-old horses might be
slaughtered because their meat is more
tender than that of older animals, but that
is not usually the case traditionally. In
Jambulsuren’s region horses are usually
allowed to die of natural causes, which
might be after the age of 30 years. In that
context, only females, around 4 years of
age, are slaughtered for meat.
All my Kazakh informants described
two culling periods for horses. The first
includes young animals between the ages
of 1 and 4 years, surplus to breeding and
work requirements, and is biased toward
males. The second comprises individuals
that are no longer productive, between
the ages of 15 and 30 years, and is biased
toward females. The relative longevity of
Kazakh horses by comparison with both
free-living horses and Mongol ponies
might be at least partly explained by the
fact that the horses in a Kazakh breeding
herd are not normally exposed to the
stresses of being ridden or used for traction. The less extreme environmental conditions of northern Kazakhstan, from the
51
point of view of both human and beast,
might also be a relevant factor.
According to Murzabaev, in the modern
context horses are butchered either at 1 to
112 years, when horse meat is most tender,
or at around 15 to 20 years. Young horses
are usually slaughtered for family needs,
while old ones are sold to the meat factory. As far as young animals are concerned, males are selected in preference
to females for slaughter.
The structure of Shavardak’s herd is not
traditional. The horses he cares for are not
his own, but rather, belong to the various
Kazakh households of Nikolskoe and to
the collective farm. His aim is not to increase the size of the herd, but rather to
provide meat for its owners. Since the mature horses in the herd are not used for
riding or traction, but only for breeding,
they have a relatively long life span, although they rarely die of natural causes.
Breeding animals are usually slaughtered
at about 25 years of age, but some live
until around the age of 30 years. Geldings
are usually slaughtered when they can no
longer be used for riding and traction, by
25 years of age. Most horses used for
meat, both male and female, are slaughtered between the ages of 2 and 5 years.
By their third year, only 2 to 3 individuals
had survived out of a cohort into which
approximately 40 foals had been born (Table 5). Meat from young horses is usually
consumed by its owners, while that from
old ones is usually sold to state farms. For
example, the meat from Nikolskoe’s old
horses is sold to a nearby polar fox farm.
However, in earlier years this meat would
also have been consumed by the family.
In the traditional pastoralist context, described by Kozhakhmetov, horses did not
normally die of natural causes. Sometimes, of course, they died of illness or
from an injury and, very seldom, were
killed by wolves. However, they were usually slaughtered either after the age of 20
years, when they were no longer useful
52
MARSHA A. LEVINE
for breeding or for work, or between the
ages of 1 and 3 years, when their meat was
most tender. The decision to slaughter a
horse was based on a household’s need
for meat. Although the meat and fat from
all slaughtered horses were consumed,
those from young horses were preferred
and were served in particular on special
occasions, for example, when guests came
to the house. Males were culled before
females, since far fewer of them were
needed for breeding and milk production.
2.2.2. Importance of the Horse in Mongol
and Kazakh Life
Of all the livestock species available to
steppe pastoralists, none is as well
adapted to the human and natural environment as the horse and none is held in
such high esteem. The horse can move
rapidly and easily long distances over
hard ground, providing its owners with
both mobility (riding, packing, traction)
and nourishment (milk, meat, fat). Other
products, such as bone, hoof, hair, hide,
excrement, and even sweat, are also valued, for example, as fuel, raw materials for
the fabrication of tools, utensils, musical
instruments, and other objects, and for
medicinal purposes.
The horse occupies a position in the
grazing succession that complements that
of other steppe livestock: cattle, sheep,
goats, camels, yaks. It can subsist on long,
dry, relatively poor-quality herbage, thus
encouraging the growth of the shorter,
more nutritious grasses, on which bovids
(cattle, sheep, goats) depend (Bell 1969). It
does not need as much water as cattle.
Moreover, it can find its own food under
deep snow by digging to it with its hoofs,
thereby making it available to the bovids,
which cannot do so for themselves (Mohr
1971).
2.3. Population Structure Models
As regards relationships between people and horses, each pattern of behavior
or method of exploitation is characterized
by its own typical, though not necessarily
unique, sex and age structure. These
structures can be used as models to which
the archaeological data can be compared.
The development of these models—from
ethnographic, ethological, and archaeological data— has been detailed in Levine
(1979, 1983, 1990). Although the information obtained from the interviews described above is by no means complete, it
does partly fill some gaps in the data used
in the construction of the models. In conjunction with information from ethological, ethnological, archaeological, and historical sources, the ethnoarchaeological
data thus facilitate interpretation of target
archaeological equid assemblages in terms
of human behavior.
The raw material for this method of
analysis is the aged horse teeth from archaeological deposits. Determination of
an individual’s age at death is based on an
analytical technique that employs measurements of crown height and assessments of eruption and wear. The method
has been described in considerable detail
elsewhere (Levine 1979, 1982, 1990). Once
the teeth from a deposit have been aged,
the next step is to determine what the age
distribution of that whole assemblage
means in terms of human behavior. The
age at which an individual animal dies is
in itself of limited interest. What is important is the pattern manifested by the population as a whole and how it compares
with the various population structure
models to be discussed below.
2.3.1. The Attritional Assemblage Model
The mortality distributions for natural
attrition, scavenging, and livestock husbandry, where meat production is of secondary importance, are all similar to the
attritional assemblage model (Fig. 2).
Mortality is low for adults during their
reproductive years, and high for juveniles
and senescent individuals (Caughley 1966;
ORIGINS OF HORSE DOMESTICATION
53
FIG. 2. Attritional assemblage model. The purpose of the broken line is to suggest how the shape
of the curve might be biased by the differential destruction of immature teeth.
Dahl and Hjort 1976). This is essentially
the pastoral nomad kill-off pattern revealed to me by Damdin. As explained
earlier, where meat production is of secondary importance, individuals not dying
of natural causes will probably not be
slaughtered until after the age of 15 or 16
years.
As yet, no equid assemblage from a pastoral nomadic context has become available for analysis. However, it has been
possible to study an assemblage from another kind of context in which mobility,
rather than meat production, was of primary importance: Thornhill Farm, an Iron
Age and early Roman settlement, from the
Thames Valley (Gloucestershire) (Fig. 3).
From the relatively undamaged condition
of the bones, it is pretty clear that horses
from this site were not eaten, but were
certainly used as riding, traction, or pack
animals. The assemblage is small, with
only 160 ageable horse (and possibly some
mule) cheek teeth and a dental minimum
number of individuals (MNI) of 17 (Fig. 4).
This includes 53 loose cheek teeth and 20
jaw fragments with ageable teeth. The
small size of the assemblage probably accounts for the jaggedness of the distribution. An initially disconcerting feature of
the assemblage is the relatively large proportion of horses dying during their apparently prime reproductive years, at least
by comparison with the pattern described
by my Kazakh and Mongol informants.
Roman horses were broken at about the
same age as Mongol and Kazakh horses,
and as with the Mongols, the most important use the Romans made of them was for
transport. However, it seems that the Roman horses had a much shorter expected
life span than the Mongol ponies (Hyland
1990). The explanation for this might lie in
the different attitude of the Romano-British agriculturalists toward their horses.
Ann Hyland, in Equus, the Horse in the
Roman World, argues that Roman equids
commonly sustained injuries that would
have been caused by poor living conditions and gross overwork (Hyland 1990, p.
59). She estimates that a horse was expected to last only about 3 years in active
54
MARSHA A. LEVINE
FIG. 3. Map showing location of Thornhill Farm.
military service and, on average, 4 years as
a post horse (Hyland 1990, p. 86, 88).
Moreover, the breeding period was also
comparatively abbreviated, with mares
being considered past their prime at 10
years of age, though some did breed until
15 (Hyland 1990, p. 238). The relatively
high incidence of pathology, as well as the
population structure, seems to confirm
this pattern at Thornhill Farm. A similar,
but even more extreme, distribution has
been revealed for the Roman cemetery at
Kesteren in The Netherlands, dated from
the first to the third centuries A.D. 8 (Fig. 5)
(Lauwerier and Hessing 1992).
These differences might be referable to
ecology. That is, unlike the Romans, nomadic pastoralist Mongols depend on
horses for their hour-to-hour survival.
Horses permeate every aspect of their existence. As a result of this, they are held in
high respect and treated with great care.
For the Romans, horse production was
largely a commercial enterprise and any
loss was for the most part financial. However, the possibility that the picture described to me by Damdin might have been
somewhat idealized must be recognized
and awaits further investigation.
2.3.2. The Carnivorous Husbandry Model
A mortality curve resembling the carnivorous husbandry model (Fig. 6) might
be generated if the slaughter of individuals at around the age of 2 to 4 years were
superimposed on Damdin’s pastoral nomadic attritional pattern (Levine 1990). At
ORIGINS OF HORSE DOMESTICATION
55
FIG. 4. Thornhill Farm age structure: adjusted and unadjusted. A hypothetical adjustment factor
has been applied to compensate for the probable underrepresentation of immature animals (for
details see Levine 1979, 1983). To obtain the average adjusted frequency of teeth for each age class
from birth to the age of 5 years, the frequency of teeth in each age class (from 0 to 5 years) is
multiplied by 1/ 0.23 1 0.17 (age). “Age” refers to average age; for example, 0.5 is used for 0 –1 year).
that age the meat is still at its most tender
(Rossier and Berger 1988). Moreover, by
that time a horse’s growth rate would
have decreased substantially, while its energy needs would continue to increase
(Fig. 7) (Willoughby 1975, pp. 40 – 43). It
would, therefore, be most efficient to
slaughter horses, surplus to a herd’s
breeding and work requirements, between the ages of 2 and 4 years. This was
the pattern described by my informants
from Kazakhstan and by Jambalsuran.
Such a slaughter pattern has also been
observed for modern Mongolia (Damdin,
personal communication).
A very similar age distribution was produced from information provided by Yuri
Shavardak, the semi-traditional horse
herder from northern Kazakhstan (Table
5). Unfortunately, the data on which the
FIG. 5. Thornhill Farm and Kesteren age structure.
56
MARSHA A. LEVINE
FIG. 6. Carnivorous husbandry model.
distribution is based are incomplete.
There is almost no information about infant mortality. The ages given are approx-
imate and the eight geldings, associated
with the herd, are excluded from the distribution. Moreover, it is not clear either
FIG. 7. Horse growth rate.
ORIGINS OF HORSE DOMESTICATION
57
FIG. 8. Age structure of Shavardak’s herd.
that the population was stable or the age
structure static. On the other hand, its
similarity to the carnivorous husbandry
model is noteworthy, as is its difference
from the life assemblage model (Fig. 8).
2.3.3. The Life Assemblage or Catastrophe Model
The life assemblage model (Fig. 9) is
representative either of a living population, a catastrophe assemblage, or an as-
FIG. 9. Life assemblage model.
58
MARSHA A. LEVINE
FIG. 10. Family group model.
semblage in which all age classes are represented as they would be in the living
population because of completely random
sampling (Caughley 1966; Dahl and Hjort
1976). This would also be the age structure
of a living Khalkha Mongol herd. Herd
driving or any hunting technique that
would randomly sample a wild-living
horse population would probably produce
this mortality pattern or that of the family
group variant.
2.3.4. Social Group Models (Variants of the
Life Assemblage Model)
2.3.4.1. The family group model. The
main difference between the life assemblage model and the family group model
(Fig. 10) is the relatively small proportion
in the latter of individuals 3 to 6 years of
age, marking the absence of bachelor
males (Levine 1979, 1983).
This is the kind of pattern produced
by the western European, Upper Pleistocene material previously studied, particularly when an adjustment factor has
been applied to compensate for the
probable under-representation of immature animals (Levine 1979, 1983). Figure 11 shows the population structure of
the horse teeth from Jaurens, a natural
deposit, formed when a catastrophic
event or series of events, probably
floods, overcame and swept its victims
into a cave. Figure 12 shows the age
distribution of the pooled assemblages
from 10 Paleolithic sites. Some of the
deposits included, for example, those at
Solutré, were formed by herd drives,
and others, probably by the hunting of
single family groups or random individuals.
2.3.4.2. The bachelor group model. The
most important characteristic of the horse
bachelor group, the absence of females,
may be difficult to detect in the archeaological record, since few anatomical elements
show much sexual dimorphism (Levine
1979, 1983). The most archaeologically visible feature of the bachelor group model
might, therefore, be the absence of individuals less than about 2 years of age (Fig. 13).
From the age of about 5 or 6 years, some
leave the bachelor group to build up their
ORIGINS OF HORSE DOMESTICATION
FIG. 11. Jaurens age distribution.
FIG. 12. Pooled Paleolithic sites age distribution.
59
60
MARSHA A. LEVINE
FIG. 13. Bachelor group model.
own family groups (Berger 1986). Stallions
that have lost their harems will either rejoin
a bachelor group or remain solitary. Bachelor group hunting might, in the archaeological context, be indistinguishable from the
stalking of prime adults.
2.3.5. The Stalking Model
Stalking (Fig. 14) is a selective hunting
technique in which the prey is approached
by stealth and killed (Levine 1983). Chasing
individual prey from horseback would also
FIG. 14. Stalking model.
ORIGINS OF HORSE DOMESTICATION
61
FIG. 15. Map of the Ukraine.
be included in this category, since the initial
approach would be by stealth and the selection based on the preferred rather than the
most vulnerable individual. Hunting mainly
prime adults should produce a distribution
approximating a bell-shaped curve. This is
the kind of pattern that would result from
the Hadza decision to select large fat male
zebra as their preferred prey (see Section
2.2.1.6).
The population structure of the horses
from the Ukrainian settlement site, Dereivka, best fits the stalking model (Fig.
15)(Levine 1990, 1993). The relevant deposits are Eneolithic (Sredni Stog IIa), 9
with calibrated radiocarbon dates ranging
from around 3095 to 4570 BC, of which the
majority fit within the second half of the
fifth millennium BC (Table 1) (Telegin
1986). The mortality distribution of the
horses from Dereivka is characterized by
very small percentages of individuals less
than 4 years old and more than 8 or 10
years old (Fig. 16). More than half died
between the ages of 5 and 8 years (50.1%,
unadjusted), when they would have been
most useful, both reproductively and as
work animals, had they been domesticated. It is most unlikely that herders
would have slaughtered their horses at
that age.
It therefore seems reasonable to conclude that the vast majority, if not the
totality, of the horses from Dereivka were
wild and, because of the relatively large
proportion dying during their most pro-
62
MARSHA A. LEVINE
FIG. 16. Dereivka age structure.
ductive years, the mortality distribution
that they best fit is the stalking model or a
mixture of the stalking and random individual or family group models. The fact
that 9 of 10 sexable tooth rows came from
males might indicate that bachelor groups
were hunted or that somewhat inexperienced stallions with family groups were
relatively easy to kill. Studies of equid behavior have shown that when a family
group is attacked, the stallion will turn
and fight to protect his mares and young
(Damdin, personal communication; Mohr
1971; Kruuk 1972).
According to G. and M. Grshimailo (in
Mohr 1971, p. 67),
a wild stallion when he scented danger, he informed his herd by snorting and at once they
were off in single file, a young colt in the lead
and the foals in the middle between the mares.
As long as the herd was on the move and the
hunters were to the side, so the stallion stayed to
that side and kept his herd going in the direction
he had chosen . . . As soon as the horses had
broken through the chain of hunters who now
hunted them from behind, so the stallion
changed his position and was now on guard in
the van and in the way of those following him.
Clemenz (1903) observed (as reported
by Mohr 1971, p. 68) that
the stallion remains behind and watches his
pursuers. . . . The nearer the hunters approach
the more uneasy is the stallion and he keeps
between the herd and those pursuing it . . . But
when the terrible enemy horses with their twolegged riders press the herd, then the stallion
turns to attack his pursuers and is the first to fall
to a bullet.
Hunters from Dereivka might well have
taken advantage of the tendency of stallions to defend their bands. It is also possible that the inhabitants of the settlement
already had domesticated or tamed horses
and that they were used for hunting wild
ones, as has been recorded for the Central
Asian Kalmucks and some of the North
American, central, and southern Plains
tribes (Mohr 1971; Ewers 1955). This possibility seemed to have been supported by
Anthony and Brown’s (1991) apparent discovery of bitwear on the teeth of the socalled ritual skull from Dereivka. However, it is worth reaffirming that there is
considerable doubt now about the dating
and stratigraphic position of that skull
(Rassamakin 1994; Telegin, personal communication).
That being said, it must be emphasized
that interpretation of population structure
should not be made with reference to
mortality data alone. For example, according to Fig. 17, the age distribution of the
horses from the Roman site of Kesteren is
ORIGINS OF HORSE DOMESTICATION
63
FIG. 17. Kesteren and Dereivka age structure.
rather similar to that at Dereivka. The proportions of horses dying between the ages
of 5 and 8 years are particularly close,
50.1% at Dereivka and 46.3% at Kesteren,
whereas at Thornhill Farm it is only 26.2%.
However, a much larger proportion at
both Kesteren (31.5%) and Thornhill Farm
(49.9%) die between the ages of 8 and 14
years than at Dereivka (18.6%). The average life expectancy is lower at Dereivka
(7.7 years) than at either Thornhill Farm
(9.3 years) or Kesteren (8.3 years). Moreover, contextual data leave little doubt
that the horses from Kesteren were domesticated and suggest that they might
well have been used for military purposes
(Lauwerier and Hessing 1992). Although
Dereivka’s context is less straightforward,
it nevertheless seems to support the proposition that horses from that site were predominantly, if not entirely, wild (Levine
1990, 1993 and below).
3. BOTAI
Botai is an Eneolithic settlement site located in Kokchetau Oblast in the forest–
steppe region of northern Kazakhstan 10
(Fig. 18) (Zaibert 1993; Kislenko 1993). The
site covers approximately 15 hectares,
around 10,000 m 2 of which have been excavated, on the high, right bank of the
Iman-Burluk, a tributary of the river Ishim
(Fig. 18). Although some remains of Pleistocene mammals have been discovered
eroding out of the river bank, the prehistoric human occupation of Botai apparently extended only from the Mesolithic to
the Eneolithic. Substantial Neolithic remains are probably present, but excavation has so far been confined largely to the
Eneolithic occupation, dated to around
3500 B.C. (Table 12) Levine and Kislenko
1997).
Botai comprises around 300 polygonal
“dwellings,” which show up on the surface of the ground as rows of shallow depressions. They are packed close together
in a kind of honeycomb pattern, and are
oriented in parallel rows on either side of
“streets,” 4 to 8 m wide. More than 140 of
these structures, each ranging in area
from 30 to 70 m 2 , have been excavated so
far (Kislenko 1993). More than 40 first phalanges, mainly of horse, polished and covered with geometric designs, have been
found in various dwellings, as has a
carved human figurine. Although no cemetery has been discovered at Botai, some
64
MARSHA A. LEVINE
FIG. 18. Map showing location of Botai.
human remains have been recovered
from the settlement, including a trepanned human skull covered with ochre,
found in a niche in a wall; a sawn piece of
occipital bone; and a skeleton in a pit surrounded by horse skulls. It has been estimated that, during the 15 years of Botai’s
excavation, more than 300,000 artifacts
and 10 tons of bones (99.9% of which belonged to horse) have been uncovered
(V. F. Zaibert, personal communication).
Two short papers have been published
about the bones, one by Kuz’mina (1993)
and the other by Ermolova (1993). The
former concludes from a morphometrical
analysis of 428 bones and teeth that the
horses from Botai were domesticated,
while the latter maintains in her very
short, though broadly based, study of
more than 300,000 anatomical elements,
that they were wild.
3.1. Site 31
During July and August 1992, the North
Kazakhstan Archaeological Expedition, under the overall direction of V. F. Zaibert (A.
Kh. Margulana Institute of Archaeology,
Petropavlovsk), excavated Botai, Site 31 (Fig.
19). A. M. Kislenko (A. Kh. Margulana Institute of Archaeology) and N. S. Tataryntseva
(North Kazakhstan Regional History and
Ethnography Museum) directed the excavation. 11 Its aim was to provide me with a
faunal assemblage to which my analytical
methods could be applied.
Site 31 is situated in the southwestern
part of Botai, adjacent to the present river
bank. This locality was chosen because of
its very high density of cultural remains
by comparison with other parts of the settlement, resulting from its longer period
of use. It includes two structures, the hex-
ORIGINS OF HORSE DOMESTICATION
65
TABLE 12
Botai Radiocarbon Dates
Oxford Accelerator Laboratory
OxA-4315 Botai: 4630 6 75 years B.P. (bone)
1s
3611 B.C. (0.02) 3602 B.C. 3512 B.C. (0.56) 3397 B.C. 3391 B.C. (0.28) 3332 B.C.
3221 B.C. (0.07) 3193 B.C. 3156 B.C. (0.06) 3134 B.C.
2s
3625 B.C. (0.07) 3572 B.C.
3538 B.C. (0.71) 3262 B.C.
OxA-4316 Botai: 4620 6 80 years B.P. (bone)
1s
3508 BC (0.46) 3403 B.C. 3386 B.C. (0.27) 3327 B.C.
3228 BC (0.13) 3186 B.C. 3159 (0.11) 3125 B.C.
2s
3625 BC (0.06) 3572 B.C.
3321 B.C. (0.03) 3309 B.C.
3538 B.C. (0.94) 3095 B.C.
OxA-4317 Botai: 4630 6 80 years B.P. (bone)
1s
3613 B.C. (0.03) 3601 B.C. 3513 B.C. (0.54) 3396 B.C.
3224 B.C. (0.09) 3190 B.C. 3157 B.C. (0.07) 3133 B.C.
2s
3628 B.C. (0.08) 3566 B.C. 3540 B.C. (0.69) 3258 B.C.
Other Dates a
IGAN-432 4340 6 120 years B.P. (bone)
IGAN-449 3530 6 160 years B.P. (charcoal)
IGAN-4234 4900 6 50 years B.P. (bone)
IGAN-4235 4160 6 40 years B.P. (bone)
IGAN-4236 4540 6 60 years B.P. (bone)
IGAN-4237 4430 6 60 years B.P. (bone)
a
3242 B.C. (0.22) 3101 B.C.
3392 B.C. (0.27) 3331 B.C.
3245 B.C. (0.23) 3099 B.C.
From Zaibert and Kislenko (personal communication).
agonal Dwellings 26 and 29 (the latter partially dug in 1981); a possible earlier, rectangular structure, Dwelling 29a; and
various ditches and pits, both inside and
outside of the structures (Fig. 20). The 1992
excavation covered 96 m 2 , of which about
18 m 2 had been eroded away by a gully.
The site was divided into 2 3 2-m squares,
which were further subdivided into meter
squares. These were dug in arbitrary
10-cm spits and all finds, including bones
and teeth, were located within these units.
All osteological material, including vertebrae and unidentifiable bone fragments,
was collected.
Large concentrations of bones were
found within Dwellings 26, 29, and 29a: on
their floors and in the post-occupational fill,
and between the dwellings and within pits
and trenches both inside and outside of
them. Around 40,000 anatomical elements
and almost 5000 artifacts—including ceramics, bone, and stone tools, and an engraved
horse first phalange—were recovered from
Site 31 (Figs. 21 and 22). More than 99% of
the bones and teeth recovered were from
horse. A cursory glance at the rest of the
fauna suggests that the other bones were
largely if not wholly from wild taxa. Herbivores, carnivores, and birds were present.
Several fragments of human bone were also
recovered, including a piece of sawn cranium.
Such dense bone concentrations are
characteristic in particular of the dwellings located near the river bank. Various
66
MARSHA A. LEVINE
FIG. 19. Plan of Botai, showing location of Site 31.
theories have been proposed to explain
the formation processes involved. For the
moment, I believe that the best explanation is that, as a “dwelling” fell into decay
and was abandoned, it was converted into
a dump for the bones and carcass parts of
horses butchered for consumption. This
would explain why the bone concentra-
tions were found at various levels above
the floor, mixed with the clay of which
walls were apparently constructed. It is
hoped that new light will be thrown on
this problem by a micromorphological
analysis of the deposits being carried out
by C. A. I. French (Department of Archaeology, Cambridge).
ORIGINS OF HORSE DOMESTICATION
3.2. Botai Age Structure
The analysis of the osteological material
from Site 31 has so far been concerned
mainly with the population structure of
the assemblage, based on tooth eruption
and wear. Because a detailed stratigraphic
study of the site has not yet been completed, for the purposes of this paper, all
osteological data have been pooled. The
remains studied to date come almost entirely from F, X, CH 35-37, and T 38, that is,
from Dwellings 26, 29, 29a, pit 4, and the
deposits between the dwellings (Fig. 20).
5556 bones and teeth (excluding ribs and
unidentifiable bones) have been examined and constitute all the equid material
recovered from those units.
The age structure of the material examine from Botai so far is based on the study
of 526 cheek teeth, 12 some loose, some in
jaws, with an MNI of 29, based on upper
D2s and P2s. Table 13 shows that the teeth
from Botai, Thornhill Farm, and Dereivka
are all very similar in size to those used in
the design of the aging system employed
here. The age distributions produced by
this means should, therefore, be comparable (for details of aging method see Levine 1979, 1982, 1983, 1990).
As in the case of Jaurens and the pooled
Palaeolithic data previously described, the
mortality distribution of the teeth from
Botai is comparable with the life assemblage or catastrophe model, particularly
when it is adjusted to compensate for the
under-representation of immature individuals (Figs. 11, 12, 23). That is, all age
classes are represented approximately as
they would have been in the living population.
A comparison of the data from Botai
with those from Dereivka and Thornhill
Farm (Fig. 24) shows that the horses from
Thornhill Farm, despite the probable ill
treatment as manifested by high incidences of bone pathology, had a longer
average life expectancy (9.3 years) than
those from Dereivka (7.7 years) and Botai
67
(6.5 years). 13 Only about 33% of the horses
at Thornhill Farm died between the ages
of 3 and 8 years, while the figure for Dereivka was 63% and that for Botai was
55%. Approximately 55% of the horses
from Thornhill Farm died between the
ages of 8 and 16 years, as against 20% for
Dereivka and 24% for Botai.
The age distributions for both Botai and
Dereivka fit hunting models, but the differences between them strongly suggest
that different hunting techniques were
used (Fig. 24). For example, although the
mortality rates for both Botai and Dereivka are very similar from the age of 8
years and onward, the rates for younger
horses are distinctly divergent. At Dereivka mortality is concentrated between
the ages of 5 and 8 years, while at Botai it
extends back at least to 3 years. The difference is even greater when the distribution is adjusted. While the horses from
Dereivka were probably stalked, it seems
that those from Botai were killed in herd
drives.
3.3. Other Supporting Data
This interpretation is supported by
other characteristics of the assemblages.
For example, the sex ratios at the two
sites are very different. At Dereivka the
ratio of males to females is 9:1 (on the
basis of jaw bones), which is compatible
with stalking; while at Botai the ratio is
almost 1:1 (7:6 for jaw bones and 17:20
for pelves), which is best explained by a
non-selective technique, such as herd
driving. The small proportions of pathological bones at Dereivka and Botai by
comparison with Thornhill Farm also
support the theory that the horses at the
former two sites were wild (Levine, in
preparation).
Herd driving is a better paradigm for
what was happening at Botai than other
non-selective hunting techniques for various reasons. Herd drives necessitate
large-scale human cooperation and at
68
MARSHA A. LEVINE
FIG. 20. Plan of excavation, F-X-Ch-T. Redrawn from Kislenko and Tataryntseva (unpublished).
ORIGINS OF HORSE DOMESTICATION
69
FIG. 21. Botai bone concentration.
least seasonal aggregation. Although the
size of the population at Botai at any one
time is not known, available evidence suggests that it probably was relatively large.
Herd drives usually result in the deaths of
large numbers of animals. The quantity of
horses killed at Botai was immense. Additionally, such a large-scale slaughter, according to ethnographic and archaeological evidence, often results in very wasteful
under-utilization of carcasses. The relatively high incidences of articulated limb
bones and vertebrae at Botai, the large
concentrations of bones apparently discarded together, the undamaged state of
many anatomical elements, and the relatively small proportion of unidentifiable
fragments suggest that large numbers of
animals were killed more or less simultaneously and that flesh was plentiful
enough to be wasted.
Dereivka was, by comparison, a small
settlement, comprising probably three
dwellings at most. Fewer than 5000
bones and teeth of all taxa were recovered, about 60% of which were from
horse. Its population, almost certainly
never consisting of more than a few fam-
ilies, would not have been sufficient for
the huge kills sustained at Botai. The
relatively small size of the settlement
and faunal assemblage at Dereivka, as
well as its age and sex structure, is compatible with the stalking model.
4. DISCUSSION
4.1. Speculating about the Social
Implications of Horse Hunting Methods
There is, according to Anthony (1995),
evidence of bitwear on some of the teeth
from Botai. Leaving methodological questions aside, in view of the important archaeological and osteological differences
between the two sites, it is interesting to
speculate about the social implications of
stalking and chasing from horseback versus herd driving at Botai and Dereivka.
Care must, of course, be taken when invoking ethnographic parallels to interpret
archaeological data. Nevertheless, even
taking into account the behavioral differences between horses and bison, an examination of Ewer’s study of the Blackfoot
can take us down some interesting and
70
MARSHA A. LEVINE
FIG. 22. Engraved phalange from Botai 31.
unexpected paths into Eneolithic central
Eurasia (Ewers 1955).
According to Ewers, there were basically two methods of bison hunting from
horseback, the surround and the chase:
The surround method employed a considerable
number of horsemen to encircle a herd of buffalo, start them milling in a circle, and shoot
down the frightened and confused animals as
they rode around them.
The chase was a straightaway rush by
mounted men, each hunter singling out an animal from the herd, riding alongside it and killing
it at close quarters, then moving on to another
animal and killing it in like manner. The Blackfoot seem to have virtually abandoned the surround in favor of the chase around the middle of
the 19th century. During the last two decades of
buffalo hunting the chase alone was employed
as a method of killing buffalo from horseback.
(Ewers 1955, p. 154)
Ewers hypothesized that the surround
method had evolved out of the pre-horse
communal herd drive. This hunting technique was dependent both on the seasonal aggregation of usually small scattered bands into large camps and on the
bison’s high population density, particu-
larly in early winter. The whole community would have cooperated in driving the
bison herd down V-shaped approaches into
corrals or pounds or over cliffs. When successful, it could produce huge surpluses,
permitting inefficient exploitation of the
carcasses. However, “buffalo hunting on
foot in the Pedestrian Culture Period must
have been exceedingly dangerous, arduous, time consuming, and sometimes unsuccessful” (Ewers 1955, p. 304).
According to Ewers, the acquisition of
the horse eventually transformed the
communal herd drive into the surround:
“In the mounted surround the Indians
simply took advantage of the horse’s
greater mobility to expedite the kill.
Horsemen also replaced footmen in driving and luring buffalo into pounds or over
cliffs” (Ewers 1955, p. 304).
The chase represented a further step in
the development of bison hunting. It was
more flexible, efficient, and less hazardous than the surround; any number of
hunters could participate; it was less time
consuming; and it facilitated the slaughter
71
ORIGINS OF HORSE DOMESTICATION
TABLE 13
Tooth Size Comparison
Height
(1mm)
Mean
M-D
Pal.(X)
SD
Pal.
No.
Pal.
250–300
350–400
377
374
11.9
26.7
5
14
550–600
389
23.3
17
250–300
339
18.2
16
300–350
450–500
340
335
18.6
18.7
23
25
500–550
350–400
325
299
16.6
14
11
9
450–500
302
12.8
17
650–700
700–750
314
314
13.5
15
10
8
U
450–500
287
11.4
12
L
750–800
350–400
400–450
298
273
293
15.7
13.4
3.6
10
4
3
350–400
400–450
258
257
11.7
21.8
7
16
264
650–700
274
10.8
16
700–750
283
25.3
5
259
266
268
21.39
20.74
20.59
700–750
270
12.4
9
750–800
280
18
258
259
273
20.97
20.89
20.39
L
400–450
279
20.3
4
750–800
400–450
288
300
6.3
25.8
4
9
284
20.63
U
L
350–400
322
21.7
32
332
317
309
Tooth
Jaw
P2
U
L
P3
P4
M1
M2
M3
U
U
U
16
M-D
Der
(x)
293
307
344
z Der
22.53
21.50
0.48
M-D
Bot
(x)
z Bot
406
1.20
368
383
37
333
347
344
340
335
331
309
307
277
301
312
295
297
324
294
266
287
267
20.90
20.26
20.52
20.33
0.44
0.22
0.27
0.00
0.36
0.71
0.57
21.57
20.08
0.78
21.41
21.13
0.67
0.61
21.84
20.70
20.45
M-D
FTF
(x)
z FTF
323
362
361
347
354
20.45
20.04
20.05
20.18
20.15
343
328
290
303
20.02
20.04
20.24
0.06
282
281
258
259
20.21
20.22
20.25
20.25
242
247
21.42
21.28
229
231
20.13
20.12
275
274
20.04
20.04
268
267
232
241
20.07
20.07
20.23
20.19
295
286
301
325
20.02
20.05
20.1
20.01
0.51
0.46
20.23
20.60
a
Measurements to 0.1 mm. Der, Dereivka; FTF, Thornhill Farm; Bot, Botai. No. Pal., number of specimens in
Paleolithic sample; SD Pal., standard deviation of Paleolithic sample; height 5 tooth height from division of the
root; M-D, mesio-distal diameter of tooth; X, sample mean of the Paleolithic teeth; x, the sample (individual teeth
from Bot, FTF or Der) mesio-distal diameter to be compared with the Paleolithic mean; z, number of standard
deviations x is from the sample mean (z 5 x 2 X/SD) (61.0 SD indicates that x is not significantly different in size
from X, 62.0 SD indicates that they might belong to two separate populations, 63.0 SD indicates that they are
significantly different). None of the z scores from Der, FTF, or Bot are more than 3 SD from the mean of the
Paleolithic material and only one is more than 2SD, which means that, for the purposes of aging, they can be
treated as if they belonged to one population.
72
MARSHA A. LEVINE
FIG. 23. Botai age structure: adjusted and unadjusted.
of selected individuals. According to Ewer’s informants, in the course of a single
chase, no more than four or five bison
cows would have been killed. Less skilled
hunters or those with inferior horses
would capture no more than one or two
(Ewers 1955, p. 159).
4.2. Botai and Dereivka
Although Ewers was talking about the
bison hunt, we know (Section 2.1.1.2) that
feral horses can be captured by driving,
surrounding, chasing, or stalking. There
are obvious parallels between Botai and
the herd drive or surround and between
Dereivka and the chase or the stalk. This
interpretation is supported not only by the
population structures of the two sites, but
also by other features, such as the settlement and assemblage size and the sex
structure. However, it would be foolhardy
to try to draw too many conclusions from
a sample of only two sites, particularly in
view of the fact that Botai is roughly 2400
km away from and, apparently, 1000 years
FIG. 24. Botai, Dereivka, and Thornhill Farm age structure.
ORIGINS OF HORSE DOMESTICATION
later than Dereivka. However, new research suggests that the Eneolithic level at
Dereivka, in fact, extends from Tripolye
B-II/ C-I to C-II and therefore should be
dated to 3700 –3150 B.C., not 4000 – 4500
B.C. as suggested by Telegin (Rassamain
1994; personal communication). If this is
true, then Botai (at around 3500 B.C.)
could be contemporary with or even earlier than Dereivka. The archaeology of
these two regions is still open to revision
so that it would be a unwise to take any of
this too seriously. Nevertheless, it is worth
considering for a moment why one hunting method rather than another might
have been selected.
Perhaps Ewers was wrong in concluding that the herd drive was more dangerous, time consuming, and generally inefficient than the chase. Maybe these were
not the prime considerations determining
which method of hunting should be employed. Possibly the horses at Dereivka
were stalked on foot rather than chased
from horseback. Factors quite different—
ecological, social, economic, or cultural—
than those inspiring the Blackfoot could
have been crucial to the decision about
which method to use. For example, the
herd drive could have been the magnet
used to draw together the large numbers
of people needed for other activities. The
advantages thus obtained might well have
outweighed those derived from the more
individualistic chase. Social or environmental instability might well have favored
such a scenario. Tradition could have
acted as a brake to progress, maintaining
technologically obsolete, but culturally
useful practices. In other words, it seems
most likely that horse hunting did not so
much evolve as adapt.
5. CONCLUSION
The results of the analyses carried out
on the data from Dereivka and Botai suggest that the vast majority of the horses
from those sites were killed in the hunt.
73
Different hunting techniques were employed at each of them: stalking or chasing at Dereivka and driving or surrounding at Botai. The possibility that some of
the horses might have been tamed or domesticated, as suggested by Anthony and
Brown’s bitwear studies, is certainly not
excluded. However, the possibility that
the wear pattern they define as bitwear
could have other causes has not been disproved.
Although the study of population structure is a crucial step in the analysis of
almost any faunal assemblage, it should
not be the only step. If, as is often the case,
an assemblage were composed of a palimpsest of exploitation methods, it might
not be possible by means of the population structure alone to disentangle the
whole range of component patterns. If, for
example, a relatively small number of
horses at Botai or Dereivka were ridden,
their age distribution would be swamped
by that of the much larger number of
hunted animals. Complementary analytical methods must, in that case, be selected
that will identify, out of the whole assemblage, poorly represented but important
activities.
Some such methods are quite simple,
just requiring application of known techniques. For example, the presence of shed
deciduous teeth within, and contemporary with, enclosures might suggest that
young animals were being raised and possibly that controlled breeding had been
taking place. But unless careful sieving
were carried out, it is unlikely that these
elements would be recovered. Various scientific methods, currently being developed, could also be applicable to the study
of horse exploitation. For instance, the
current hope is that it will be possible to
use ancient DNA to distinguish populations and to identify genetic variability
and change. One application of this
method would be to determine whether
specimens with “bitwear” belonged to the
74
MARSHA A. LEVINE
same population as those without it.
Lipid, stable isotope, and trace element
analyses could be used to look at another
aspect of population variability— diet. 14 It
has been hypothesized that a homogeneous horse population would have had a
homogeneous diet. Different methods of
exploitation could affect the natural pattern either, for example, by mixing together individuals from various populations or by controlling access to food so
that domesticated or tamed animals
would have a different isotopic signature
than wild ones (Henry Schwarcz, personal
communication). Micromorphological
analyses of site formation processes can
also contribute to our understanding of
human– horse relationships. Since wild
and feral horses are notoriously shy of
human begins, the identification of ancient horse dung heaps within a settlement could indicate that tamed or domesticated horses had been living at the site
or nearby. The dung, a by-product of intimacy between people and horses, could
have been collected as a building material,
for fuel, or for fertilizer (C. A. I. French,
personal communication 15 ). Another approach is the study of horse paleopathology. On the one hand, the incidence of
pathology among wild horses is likely to
be lower than that among domesticates.
On the other hand, the kinds of pathologies found in horses ridden or used for
traction should also be indicative of the
kind of work to which they were put. Preliminary work on the osteological material
from Botai, Dereivka, Thornhill Farm, and
a sample of modern and Scythian comparative material supports these hypotheses 16
(Levine 1998b).
As new analytical techniques become
available, we must consider how we can
exploit them to suit the purposes of our
research. The potential for the study of the
beginnings of horse domestication and
pastoral nomadism to yield new and exciting results is almost unlimited, if ap-
proached with an open mind and a sense
of adventure.
ACKNOWLEDGMENTS
I could not possibly name all the people, particularly from the former Soviet Union, whose support
and hospitality contributed to the production of this
paper. Those to whom I am most indebted include
A. M. Kislenko, N. S. Tataryntseva, V. F., Zaibert, A.
Bayov, and V. Rutter for their help in Kazakhstan;
and D. Y. Telegin, Y. Y. Rassamakin, and the late
N. G. Belan for their help in Kiev. I also acknowledge
the kindness and patience of my informants: Damdin, Jambalsuran, D. Ch. Murzabaev, Y. I. Shavardak, M. K. Kozhakhmetov, E. Z. Zakir’yanov, and
B. Kanafin. From my small army of interpreters and
translators I, in particular, thank N. Musina, N.
Zhabrovets, G. Zerova, G. L. Barnes, K. Chabros, and
H. Lewis. I am particularly grateful to M. K. Jones for
his unfailing support of this project and for reading
and commenting on this paper. I also thank, for their
support, A. C. Renfrew, P. A. Jewell, A. G., Sherratt,
G. N. Bailey, L. B. Jeffcott, J. Clutton-Brock, M. Leggatt, and J. Rippengal. I am grateful to the Oxford
Accelerator Laboratory for providing me with radiocarbon dates. I thank G. Owen and A. Baker (Haddon Library, Cambridge) for their help with the photography. I also thank John O’Shea and my
reviewers, particularly R. W. Redding, for their valuable comments and suggestions. I gratefully acknowledge the following organizations for funding
this research: the McDonald Institute for Archaeological Research, the Wenner–Gren Foundation, the
British Academy, the Leakey Foundation, the Oxford
Archaeological Unit, and the Natural Environmental
Research Council.
REFERENCES CITES
Anthony, D. W.
1995 Horse, wagon and chariot: Indo-European
languages and archaeology. Antiquity 69(264):
554 –565.
Anthony, D. W., and D. R. Brown
1991 The origins of horseback riding. Antiquity,
65(246):22–38.
Azzaroli, A.
1985 An Early History of Horsemanship. E. J. Brill,
Leiden.
Bayley, L., and R. Maxwell
1996 Understanding Your Horse.
Charles, Newton Abbot.
David
and
Bell, R. H. V.
1969 The Use of the Herb Layer by Grazing Ungulates
in the Serengeti National Park, Tanzania. Ph.D.
thesis, University of Manchester.
ORIGINS OF HORSE DOMESTICATION
Benecke, N.
1993 Tierdomestikationen in Europa in vor- und
frühgeschichtlicher Zeit - Neue Daten zu
einem alten Thema, aus Bericht der Römisch-Germanischen Kommission 74, 1993
[Vortrag zur Jahressitzung 1993 RömischGermanischen Kommission], pp. 5– 47. Verlag Phillipp von Zabern, Mainz am Rhein.
Berger, J.
1986 Wild Horses of the Great Basin, Social Competition and Population Size. Univ. of Chicago
Press, Chicago.
Bibikova, V. I.
1967/ A study of the earliest domestic horses of
1970 Eastern Europe, parts 1 and 2. Reprinted in
Dereivka, a Settlement and Cemetery of Copper
Age Horse Keepers on the Middle Dnieper, by
D. Y. Telegin. BAR International Series 287,
pp. 135–162.
1969 On the history of horse domestication in
south-east Europe. Reprinted in Dereivka, a
Settlement and Cemetery of Copper Age Horse
Keepers on the Middle Dnieper, by D. Y. Telegin. BAR International Series 287, pp. 163–
182.
Bökönyi, S.
1978 The earliest waves of domestic horses in
East Europe, Journal of Indo-European Studies,
6: 17–73.
1984 Horse. In Evolution of Domesticated Animals,
edited by I. L. Mason, pp. 162–173. Longman, London.
Bouman, I., and J. Bouman
1994 The history of Przewalski’s horse. In Przewalski’s Horse, the History and Biology of an
Endangered Species, edited by L. Boyd and
K. A. Houpt, pp. 5–38. State Univ. of New
York Press, Albany.
Boyd, L., and K. A. Houpt
1994 Activity patterns. In Przewalski’s Horse, the
History and Biology of an Endangered Species,
edited by L. Boyd and K. A. Houpt, pp. 195–
228. State Univ. of New York Press, Albany.
Catlin, G.
1841 Letters and Notes on the Manners, Customs, and
Conditions of the North American Indians,
Written during Eight Years’ Travel (1832–1839)
amongst the Wildest Tribes of Indians in North
America, reprinted in 1973, Vols. 1 and 2.
Dover, New York.
1875 Life Among the Indians, reprinted in 1996.
Bracken Books, London.
1875 Illustrations of the Manners, Customs and Conditions of the North American Indians, Vols. I
and II. Chatto and Windus, London.
75
Caughley, G.
1966 Mortality patterns in mammals. Ecology 47:
906 –918.
1977 Analysis of Vertebrate Populations. Wiley,
Chichester.
Clason, A. T.
1988 The equids of Gomolava. In Gomolava, Cronologie und Stratigraphie der Vorgeschichtlichen und Antiken Kulturen der Donauniderung
und Südosteruopas, edited by N. Tasic and J.
Petrovic. Novi Sad.
Clutton-Brock, J.
1987 A Natural History of Domesticated Mammals.
British Museum of Natural History, London.
1992 Horse Power: a History of the Horse and the
Donkey in Human Societies. Harvard Univ.
Press, Boston, MA.
Dahl, G., and A. Hjort
1976 Having Herds, Pastoral Herd Growth and
Household Economy, Stockholm Studies in
Social Anthropology, 2.
Dakhshleiger, G. F.
1980 The Household Economy of the Kazakhs on the
Boundary of the 19th–20th centuries [Khoziaistvo Kazakhov na Rubezhe XIX-XX Vekov].
‘Nauka’ Kazakhskoi SSR, Alma-Ata.
Dietz, U. L.
1992 Zur Frage vorbronzezeitlicher Trensenbelege in Europa. Germania 70:17–36.
Ermolova, N. M.
1993 Mammal remains from the site of Botai
(from the 1982 excavation) [Ostatki mlekopitayushchikh iz poselenya Botai (po raskopkam 1982 g.]. In Problems in the Reconstruction of Economy and Technology from
Archaeological Data [Problemi Rekonstruktsii
Khozyaistba i Tekhnologii po Dannim
Arkheologii], edited by V. F. Zaibert, H. A.
Aleksashenko, and O. V. Myaksheva, p. 87–
89. Petropavlovsk.
Ewers, J. C.
1955 The Horse in Blackfoot Culture. Bureau of
American Ethnology Bulletin 159, Smithsonian Institution, Washington, DC.
Gade, D. W.
1976 Horsemeat as human food in France. Ecology
of Food and Nutrition 5:1–11.
Galton, F.
1883 Inquiries into Human Faculty and Its Development. Macmillan, New York.
Grigson, C.
1993 The earliest domestic horses in the Levant?
New finds from the fourth millennium of
the Negev. Journal of Archaeological Science
20:645– 655.
76
MARSHA A. LEVINE
Grinnell, G. B.
1923 The Cheyenne Indians, Their History and Ways
of Life, Vol. 1. Yale Univ. Press, New Haven,
CT.
Rekonstruktsii Khozyaistba i Tekhnologii po
Dannim Arkheologii], edited by V. F. Zaibert,
H. A. Aleksashenko, and O. V. Myaksheva,
pp. 178 –188. Petropavlovsk.
Groves, C. P.
1986 The taxonomy, distribution and adaptations
of recent equids. In Equids in the Ancient
World, edited by R. H. Meadows and H.-P.
Uerpmann, pp. 11– 65. Dr. Ludwig Reichert
Verlag, Wiesbaden.
Lauwerier, R. C. G. M., and W. A. M. Hessing
1992 Men, horses and the Miss Blanche effect:
Roman horse burials in a cemetery at Kesteren, the Netherlands. Helinium 32(1/ 2):78 –
109.
Gunga, Zh.
1976 In what is the value of horse-flesh [V chem
tsennost’ Koniny?]. Mongoliia 31(Pt.2):206.
Houpt, K. A., and L. Boyd
1994 Social behavior. In Przewalski’s Horse, the
History and Biology of an Endangered Species,
edited by L. Boyd and K. A. Houpt, pp. 229 –
254. State Univ. of New York Press, Albany.
Hyland, A.
1990 Equus, the Horse in the Roman World. Batsford, London.
James, Edwin, Ed.
1823 Account of an Expedition from Pittsburgh to the
Rocky Mountains Performed in the Years 1819,
1820, vol. 3, pp. 107–108. London.
Khazanov, A. M.
1984 Nomads and the Outside World. Cambridge
Univ. Press, Cambridge.
Kislenko, A. M.
1993 An experimental reconstruction of an Eneolithic dwelling [Opit rekonstruktsii eneoliticheskovo zhilishcha]. In Problems in the Reconstruction of Economy and Technology from
Archaeological Data [Problemi Rekonstruktsii i
Tekhnologii po Dannim Arkheologii], edited by
V. F. Zaibert, H. A. Aleksashenko, and O. V.
Myaksheva, pp. 117–137. Petropavlovsk.
Klingel, H.
1969 The social organisation and population ecology of the Plains Zebra (Equus quagga). Zoologica Africana 4(2):249 –263.
1974 A comparison of the social behaviour of the
Equidae. In The Behaviour of Ungulates and Its
Relation to Management, edited by V. Geist
and F. Walther, 2 vols., pp. 124 –132. IUCN
Publications, N.S., 24, Morges, Switzerland.
Krader, L.
1955 Ecology of Central Asian pastoralism. Southwestern Journal of Anthropology 11(4):301–326.
Kruuk, H.
1972 The Spotted Hyena. Univ. of Chicago Press,
Chicago.
Kuz’mina, I. E.
1993 The horse of Botai [Loshadi Botaya]. In Problems in the Reconstruction of Economy and
Technology from Archaeological Data [Problemi
Levine, M. A.
1979 Archaeozoological Analysis of Some Upper
Pleistocene Horse Bone Assemblages in Western
Europe. Ph.D. dissertation, Cambridge, 1979.
1982 The use of crown height measurements and
eruption-wear sequences to age horse teeth.
In Ageing and Sexing Animal Bones from Archaeological Sites, edited by B. Wilson, C.
Grigson, and S. Payne, (B.A.R.) British Series 109, pp. 223–250.
1983 Mortality models and the interpretation of
horse population structure. In Hunter–Gatherer Economy in Prehistory, edited by G. N.
Bailey, pp. 23– 46. Cambridge Univ. Press,
Cambridge.
1990 Dereivka and the problem of horse domestication. Antiquity 64:727–740.
1993 Social evolution and horse domestication. In
Trade and Exchange in Prehistoric Europe, edited by C. Scarre and F. Healy, pp. 135–141.
Oxbow, Oxford.
1996 Domestication of the horse. In The Oxford
Companion to Archaeology, edited by B. M.
Fagan, C. Beck, G. Michaels, C. Scarre, and
N. A. Silberman, pp. 315–317. Oxford Univ.
Press, New York.
1998a Eating horses: The evolutionary significance
of hippophagy. Antiquity 72(275):90 –100.
1998b A preliminary examination of early Iron Age
horse palaeopathology at Ak-Alakha 5, Kurgan 3. In The Phenomenon of the Altai Mummies, edited by V. I. Molodin and N. V.
Polos’mak. Novosibirsk.
Levine, M. A., and A. M. Kislenko
1997 New Eneolithic and Early Bronze Age radiocarbon dates for North Kazakhstan and
South Siberia. Cambridge Archaeological Journal 7(2):297–300.
Levine, M. A., and T. Y. Rassamakin
1996 Problems related to archaeozoological research on Ukrainian Neolithic to Bronze
Age sites [O probleme arkheozoologicheskikh issledovanii pamiatnikov Neolita-Bronzy Ukrainy]. In The Don-Donets
Region in the Bronze Age System of the East
European Steppe and Forest Steppe [DonoDonetskii Region v Sisteme Drevnoctei Epokhi
Bronzy Vostochnoevropeiskoi Stepi i Lesostepi].
77
ORIGINS OF HORSE DOMESTICATION
Russian-Ukrainian Conference and Ukrainian-Russian Field Seminar, Vol. 2, Voronezh.
Mohr, E.
1971 The Asiatic Wild Horse. J. A. Allen, London.
Montfort, S. L., N. P. Arthur, and D. E. Wildt
1994 Reproduction in the Przewalski’s Horse. In
Przewalski’s Horse, the History and Biology of
an Endangered Species, edited by L. Boyd and
K. A. Houpt, pp. 173–194. State Univ. of New
York Press, Albany.
Petrenko, A. G.
1984 Ancient and Medieval Animal Husbandry in the
Volga and Ural regions, [Drevnee i Srednevekovoe Zhivotnovodstvo Srednevo Povolzh’ia i
Predural’ia]. Academy of Sciences Moscow.
Rassamakin, Y. Y.
1994 The main directions of the development of
early pastoral societies of the northern Pontic zone: 4500 –2450 BC (Pre-Yamnaya cultures and Yamnaya culture). In Nomadism
and Pastoralism in the Circle of Baltic–Pontic
Early Agrarian Cultures: 5000 –1650 BC, edited
by A. Kosko, Baltic-Pontic Studies, Vol. 2,
pp. 29 –70.
Rossier, E., and C. Berger
1988 La viande de cheval: Des qualités indiscutables et pourtant méconnes. Cahiers de
Nutrition et de Diétologie 23(1):35– 40.
Schnirelman, V. A.
1992 The emergence of a food-producing economy in the steppe and forest–steppe zones
of Eastern Europe. Journal of Indo-European
Studies 20:123–143.
Serpell, J. A.
1986 In the Company of Animals. Basil Blackwell,
Oxford.
1989 Pet-keeping and animal domestication: A
reappraisal. In The Walking Larder: Patterns of
Domestication, Pastoralism, and Predation, edited by J. Clutton-Brock, pp. 10 –21, Unwin
Hyman, London.
Sinclair, H. M.
1964 Carbohydrates and fats. In Nutrition, a Comprehensive Treatise, Vol. I: Macronutrients and
Nutrient Elements, edited by G. H. Beaton,
and E. W. McHenry, pp. 59 –114. Academic
Press, New York.
Speth, J. D.
1983 Bison kills and bone counts. Univ. of Chicago
Press, Chicago.
Stuiver, M., and P. J. Reimer
1993 Extended 14 C database and revised CALIB
radiocarbon calibration program. Radiocarbon 35:215–230.
Telegin, D. Y.
1986 Dereivka, a Settlement and Cemetery of Copper
Age Horse Keepers on the Middle Dnieper. BAR
International Series 287.
1995 The absolute date of Dereivka settlement and
cemetery on the middle Dnieper. Abstract for
conference: Early horse keepers of the Eurasian steppes, Petropavlovsk, June 18 –24.
Toktabaev, A.
1992 Kazakh Horse-Breeding in the XIX c. to the Beginning of the XX c., Historical and Ethnographic Research [Konevodstvo Kazakhov v
XIX–Nachalye XX vv. (istoriko-etnograficheskoye issledovaniye)]. Unpublished dissertation summary, Almati.
Uerpmann, H.-P.
1990 Die Domestikation des Pferdes im Chalkolithikum West-und Mitteleuropas. Madrider
Mitteilungen 31:110 –153.
Waley, A.
1955 The heavenly horses of Ferghana, a new
view. History Today 5:95–103.
Wallace, E., and E. A. Hoebel
1952 The Comanches, Lords of the South Plains.
Univ. of Oklahoma Press, Norman.
Williams, G., and M. A. Crawford
1987 Comparison of the fatty acid component in
structural lipids from dolphins, zebra and
giraffe: Possible evolutionary implications
Journal of Zoology, London 213:673– 684.
Willoughby, D. P.
1975 Growth and Nutrition in the Horse. A. S. Barnes, South Brunswick.
Zaibert, V. F.
1993 The Eneolithic of the Ural-Irtish Interfluve [Eneolit Uralo-Irtishskovo Mezhdurech’ya]. Academy of Sciences, Republic of Kazakhstan,
Petropavlovsk.
Zaleski, E.
1984 The collectivization drive and agricultural
planning in the Soviet Union. In The Soviet
Rural Economy, edited by R. C. Stuart, pp.
79 –106. Rowman and Allanheld, Totowa.
NOTES
1
“Reduction in size on the one hand and increase
in variability on the other are classic indicators of
domestication” (Uerpmann 1990, p. 127).
2
Excavated in 1994 and 1995 by Tatiana Nerudenko, Scientific Director of the Chigirin State Historical Park, Ukraine.
3
Clutton-Brock (1992, p. 19) defines feral animals
“as those that live in a self-sustained population
after a history of domestication.”
4
Collectivization refers to the socialisation of ag-
78
MARSHA A. LEVINE
riculture, by which food production was transferred
from private farms to collective and state farms (respectively, kolkhozes and sovkhozes). This process
began in Russia in 1927 (Zaleski 1984).
5
Following Serpell, “The Oxford English Dictionary (OED) defines a pet as “Any animal that is
domesticated or tamed and kept as a favourite, or
treated with indulgence and fondness.” In practice,
however, the word tends to be used more loosely as
a blanket description for animals that are kept for no
obvious practical or economic purpose” (Serpell
1989, p. 10). Since the former definition may be impossible to apply to archaeological and ethnographic
contexts, the latter is be used here.
6
Also written as “Comanche.”
7
An aul is a Kazakh village.
8
Age determinations from Lauwerier and Hessing
(1992).
9
According to a new typology, it belongs to the
Dereivka culture within the Sredni Stog region (Rassamakin 1994).
10
Botai is located at 53°109 north latitude, 67°409
east longitude. The central part of the settlement is
238 m above sea level.
11
All the site information presented here is from
the excavation notes of A. M Kislenko and N. S.
Tataryntseva.
12
Teeth less than half complete are excluded from
the population structure analysis.
13
Although increased age is associated with increased incidences of certain types of pathologies,
the age difference between the horse populations at
these two sites is unlikely to be great enough to
account for the observed pathological differences.
This is the subject of ongoing research by M. A.
Levine, G. N. Bailey, and L. B. Jeffcott.
14
I am collaborating with R. P. Evershed and S.
Vaughan (Organic Geochemistry Unit, School of
Chemistry, Bristol) on an analysis of lipids in pot
residues and bone from Botai and from bones and
flesh from Ak-Alakha 3; and with T. O’Connell and
R. E. M. Hedges (Research Laboratory for Archaeology and the History of Art, Oxford) on a stable isotope study of material from Ak-Alakha 3, Botai, Molukov Bugor, and other Ukrainian sites.
15
C. A. I. French (Department of Archaeology,
Cambridge) is carrying out a micromorphological
analysis of sediments from Botai.
16
In collaboration with G. N. Bailey (Department
of Archaeology, Newcastle) and L. B. Jeffcott (Department of Clinical Veterinary Medicine, Cambridge), I am working on a NERC funded project
concerned with horse palaeopathology.