Mediterranean temporary ponds are endangered habitats that support many endemic species. They vary greatly in size, hydroperiod, and water quality. Despite their small size, they are important for sheltering rare species and maintaining biodiversity. The ponds face high degradation and loss rates due to threats from human activities like agriculture and water exploitation. Conservation requires classifying ponds based on habitat and conditions to design effective management strategies. Restoration is urgently needed to reestablish natural hydroperiods and water quality to protect the unique and adapted communities.
2. Journal of Environmental Biology January, 2007
Zacharias et al.
Table – 1: Various names for temporary aquatic habitats
Temporary aquatic habitats
Amphibious Mediterranean grasslands
Artificial/semi-natural temporary pools
Brumal pools
Cupular pools
Dayas
Ephemeral waters
Mediterranean temporary ponds
Padule
Poljes and dolines
Rain pools
Riparian pools
Seasonal wetlands
Vernal pools or potholes
Description of the habitat value: Mediterranean temporary
ponds are of major conservation importance, regardless of their
relatively small size, theyoften sheltermany rareand endangered
species.Anotherimportant reason for their protection isthat these
pondshave analarming rate of loss and degradation, despite their
importance (Blausteinand Schwartz, 2001; Collinson et al., 1995).
They support a diversity of species including vascular plants,
amphibians, many microorganismsand macroinvertebrates some
of whichare endemic.Temporary pondsareisolatedhabitats, which
are also important environments for many migratory birds (Grillas
et al., 2004a; Madhyastha et al., 2000).The flora and fauna are
uniquely adapted and as a result can cope in a great variety of
environmental changes. In some cases, species even depend on
the hydrological changes of these ponds for their reproduction or
forthe completionof theirlife cycle.Thereisalsoastrongprobability
that temporary ponds contribute to maximizing the gene pool of
specieswhich exist in permanent, as well as, intemporary waters.
This increased diversity may be crucial to the survival of species
facing possible future changes of global environments (Beja and
Alcazar, 2003; Grillas et al., 2004b; Madhyastha et al., 2000;
Warwick andBrock, 2003; Williams, 1997).
Hydrology: Mediterranean temporaryponds present a significant
variability regarding the length of their hydroperiod (the period
during which ponds are flooded) and the initiation of their
inundation period. Temporary ponds exhibit a self regulating
hydrology. They often occur in shallow depressions with an
impermeable ground and have a relatively small catchment area.
However, they can be also found in karstic areas, where
preferential groundwaterflow originatesoutside of their catchment
area, which can result in water level rise.
The substrates’ permeability and slope determines the
amount of water reaching the pond via surface runoff and
groundwater. This affects the length of the hydroperiod and
therewith the ecosystem composition.
According to Williams (1997)there are, two different
types of temporary ponds:
1. Intermittent ponds – which are following a seasonal cyclic
pattern of dryness and flooding
2. Episodic ponds- which will be flooded unpredictably
Grillas et al. (2004a and 2004b) reported that the
seasonal and annual differencesin the volume of water ina pond
result from temporal differences in the water balance of inflows
and outflows. Inflows can be direct precipitation, surface runoff,
melting snow and inflows of groundwater. Outflows can be
infiltration, overflow and evapotranspiration (Grillas et al., 2004a;
Keeley and Zedler, 1996).
Keely and Zedler (1996) mentioned that a temporary (vernal)
pond consist of four stages;
1. Awetting phase
2. An aquatic or inundation phase
3. Awaterlogged terrestrial phase
4. Adrought phase
The length of the hydroperiod is a criterion for
determining flora and fauna (Grillas et al., 2004a; Keeley and
Zedler, 1996; Spencer and Blaustein, 2001; Spencer et al., 1999).
These hydrological changes are completely natural and as water
quantity changes, so do both the aquatic/ emergent vegetation
and the invertebrate fauna. During flooding, an aquatic habitat
with limited trophic resources becomes available and predation
is low. During drying a higher density of fauna leads to greater
competition and predation (Brendonck et al., 2002; Grillas et al.,
2004a; Spencer et al., 1999). From hydrologic observations of
Cretan MTP habitats in Greece, the aforementioned concept of
the significant variability in the length of hydroperiod, even within
a few kilometers scale can be accredited. Particularly, the
measured hydroperiods fluctuated from less than 5 days to
several months in various MTP sites that exist in different
altitudinal, geologic and meteorologic conditions.
Chemical characteristics: Temporary ponds differ from
permanent waters in many ways. Physical and chemical
characteristics often fluctuate considerably and may temporarily
approach or exceed the biological limits that organisms can
endure (Angélibert et al., 2004; Eitam et al., 2004; Lahr, 1997;
Rhazi et al., 2001b). The nitrate concentrations and the total
phosphate vary significantly throughout the year but their
concentration levelsare relatively low. Salinitycan bean important
factor towards the end of wet periods in some temporary ponds,
due tothe concentration of dissolvedions byevaporation. Salinity
tolerances vary between different groups of organisms found in
temporary ponds (Keeley and Zedler, 1996; Lahr, 1997). These
waters often undergo extreme changes in pH and levels of
dissolved carbon dioxide, as well as oxygen. The pH is largely
controlled by the carbon dioxide-bicarbonate system and thus,
when waters experience photosynthetically-driven depletion of
CO2
, pH may raise 2-3 units within few hours (Angélibert et al.,
2004; Keeleyand Zedler, 1996; Rowe et al., 1992). Oxygen levels
are fluctuating and are frequently very low while due to the very
2
3. Journal of Environmental Biology January, 2007
Overview of temporary ponds in Mediterranean region
high surface to volume ratio of these shallow depressions, most
experience extreme changes in temperature. Thus, early in the
day they may present relatively rich growing conditions, but as
light increases, photosynthesis is inhibited by carbon dioxide
limitation, andpotentially oxygenavailability isreduced asa result
of photorespiration (Keeley and Busch, 1984). The persistence
of temporary ponds seems likely to be the result of rapid decay
of organic matter during the dry phase, which largely reduces
t h e r a t e o f s e d i m e n t a c c u m u l a t i o n ( C o l l i n s o n et al., 1995). The
research of the chemical characteristics of Mediterranean
temporary ponds is limited. Specifically, little is known about the
chemical changes occurring as ponds go through different
succession stages (Angélibert et al., 2004). Furthermore, the
substrate of the MTPs plays a significant role in their chemical
conditions. Particularly, in Greece 39% of the MTPs sites are
located on silty and sandy sediments, 17% lay on calcareous
rocks while the remaining sites’ substrate consists of siliceous
and volcanic formations.
Ecological status :
Temporary aquatic communities: Temporary ponds support
groups that clearly differ from those of permanent ponds, and, in
some cases, species of great conservation importance. Although
many major taxonomic groups of aquatic animals can be found
in temporary ponds, they are usually represented by only few,
specialized species. The fauna of these ponds can be
distinguished by their high colonization rates. Another
characteristic of the fauna of temporary ponds is that many taxa
can survive in the dry sediments and revive rapidly when
temporary ponds are flooded (Graham, 2002; Jakob et al., 2003;
Ryan and Winne, 2001; Thiery 1997). Because of their relatively
isolated status in comparison to permanent water bodies (rivers,
marshes and lakes), their unpredictable date of flooding and their
small size and shallow conditions, biodiversity in these ponds is
high. Nevertheless, even though they have simple food webs
(Beja andAlcazar, 2003; Eitam et al., 2004; Nicolet et al., 2004;
Rhazi et al., 2004), many temporary pond taxaremain unidentified
and not adequately described. There is relatively little overlap
between species in temporary ponds and permanent waters,
although the degree of overlap may vary in different geographic
locations (Williams, 1997). Recent studies have pointed out that
the length of the hydroperiod and the seasonality are the main
factors in determining the faunal composition and the structure
of temporary aquatic communities (Boix et al., 2001). The most
influential factor affecting biota is the desiccation of the habitat
during the dry season. Species richness normally increases as
the length of the flooded period in ponds increases (Beja and
Alcazar, 2003; Blaustein and Schwartz, 2001; Boix et al., 2004;
Eitam et al., 2004; Nicolet et al., 2004; Rhazi et al., 2004).
The flora of temporary ponds survives during dry
periods by building up alarge seed bank inthe soil during periods
when water is available. Preservation of a seed bank is the main
factor in the persistence of many temporary pond plants (Rhazi
et al., 2001a; Warwick and Brock, 2003). Several fauna species
in these ponds survive by building up an egg bank. Egg banks
are very important in the Mediterranean region, because the
conditions might not be favourable to generate offspring every
year. Thus, these banks do not only exist to bridge periods of
drought but also as a buffer for the effect of environmental
variability. The hatching success when the water level rises and
the survival during the inundation phase mean that these
organisms often dominate the existing fauna in the water column
(Belk, 1998; Brendonck and Williams, 2000; Schwartz and
Jenkins, 2000; Spencer and Blaustein, 2001; Williams, 1997).
Temporary waters usually have low oxygen levels and
this causes many species to possess oxygen binding blood
pigments, such as haemoglobin (phyllopods, cladocerans and
notonectidae). Abehavioral response to oxygen depletion, such
as swimming near the air water interface is also a method to
survive low oxygen levels (fairy shrimps). Another way to cope
with a low oxygen level is an increase in the ventilation activity,
which is common among chironomid larvae (Lahr, 1997).
Flora: MTPs support plant communities that are very rich in rare
and threatened species. There are temporary ponds which
maintain a diverse assemblage of pteridophytes, which means
that they have variable water requirements, like the Isoetes,
Marsilea and Pilularia. Some plants, on theother hand, are strictly
dependent on flooding, e.g. species of Callitriche, Ranunculus,
Lythrum, Eryngium and Solenopsis (Grillas et al., 2004a, Rhazi
et al., 2004; Warwick andBrock, 2003).Afewof theseare endemic
species, e.g. Eryngium atlanticum inMorocco, Isoetesheldreichii
in Greece, Ranunculus revelieri in Corsica and Provence,
Artemisia molinieri in Provence and Marsilea bartardae and
Ranunculus longpipes in the Iberian Peninsula. Isoetes setacea
is a western Mediterranean species, found in Portugal, Spain
UK and France and recently discovered in Morocco (Grillas et
al., 2004a; Rhazi et al., 2004). In the Mediterranean region there
are 38 of the rarest and most threatened plants of temporary
ponds, forexample Benedictella benoistii, endemic to north west
Morocco, which has not been seenfor several decades. Callitriche
and Elatine arethe most threatened plant species inMTPs (Grillas
et al., 2004a; Keeley and Zedler, 1996). In Greece, 95 plant
species have been found and the most commonly encountered
of them (Callitriche brutia Petagna, Tillaea vaillantii Willd., Elatine
macropoda Guss, Pilularia minuta Durieu , Isoetes hystrix Bory)
belong to the Isoetion phytocommunity. The Thero-
Brachypodietalia community (Plantago weldenii Reichb. and
Trifolium tomentosum L.) has the lowest occurrence in the
particular MTPs habitats. The most commonly observed species
in a site specific basis is the Juncus bufonius (Juncaceae) which
is followed by Lythrum hyssopifolia L. (Lythraceae), Plantago
weldenii (Plantaginaceae) and Callitriche brutia (Callitrichaceae).
However, there is a significant variability in the species
composition at each MTP site in Greece that can be assigned in
3
4. Journal of Environmental Biology January, 2007
the substantial spatial fluctuation of geomorphologic, geologic
and meteorological parameters.
Plants of temporary ponds are still subject to very
limited and insufficient protection measures. Many pond species
develop during either the wetting or the inundation phase. The
key factor for determining community composition is the timing,
as well as the duration of these phases. Also, during the
inundation phase some taxa, e.g., Marsilea vestita, Alopecuris
howellii, Callictriche spp., and Orcuttia spp., produce floating
leaves that have a cuticula and are structurally distinct from the
submerged parts. As the water level drops and the pools enter
the waterlogged/ terrestrial phase, the soilsare humid and plants
endure in a terrestrial environment. For the majority of species,
flowering is initiated during this phase (Keeley and Zedler, 1996).
In the terrestrial phase most plants are not capable of surviving
because of insufficient water availability.
Amphibians: Mediterranean temporary ponds have favourable
characteristics for amphibians, because they are rich in phyto
and zooplankton, which are consumed by larvae. Most species
that breed in temporary ponds prefer an open or lightly wooded
habitat. Because of the rich aquatic vegetation in temporary
ponds, they also provide an advantage to egg laying. The
hydroperiod isa key gradient for the offspring(Grillas et al.,2004a;
Jakob et al., 2003; Ryan and Winne, 2001; Snodgrass et al.,
2000). If the pond dries up too early or when there is water
shortage conditions, the offspring cannot survive and there is a
greater risk of reproduction failure. Therefore, reproductive
success depends on the length of the hydroperiod and the delay
or lack of annual rainfall. Most temporary ponds of the
Mediterranean region dry out during spring, and amphibian
terrestrial activity during summer is reduced (Beja and Alcazar,
2003; Boix et al., 2001; Grillas et al., 2004a; Jakob et al., 2003).
Inthe Mediterraneanregion few amphibian species are common,
these include the natterjack toad (Bufo calamita), the painted
frog (Discoglossus), true salamanders (Chioglossa), the brook
salamander (Euproctus), the Mediterranean treefrog (Hyla
meridionalis), the spectacled salamanders (Salamandrina),
spadefoot toads (Pelobates), parsley frogs (Pelodytes), sharp-
ribbed newts (Pleurodeles), cave salamanders (Speleomantes),
mid-wifetoads (Alytes), the caucasiansalamander (Merntensiella)
and the marbled newts (Triturus) (Beja and Alcazar, 2003; Boix
et al., 2001; Grillas et al., 2004a; Jakob et al., 2003; Rowe et al.,
1992; Ryan and Winne 2001). On a global scale, a rapid and
worrying decline of certain amphibian populations has been
observedsince the1980s. Thecause of the declineis unexplained
(Beja and Alcazar, 2003; Boix et al., 2001; Grillas et al., 2004a;
Rowe et al., 1992).
Invertebrates: Insects are an important part of the aquatic
environment. In Morocco or Provence region of France, they
constitute 60-70% of the total number of species, present over a
complete hydrological cycle (Angélibert and Giani, 2003; Grillas
et al., 2004a). Because insect species richness depends on many
characteristics, such as the development of macrophytes, the
amount of dissolved organic material and the development of
microbial populations, they need particular adaptations in order
to survive. Some species burrow, in adult or larval form, in the
substrate. Thereby they reduce their activity, in order to survive
the drought periods (Grillas et al., 2004a). Mayflies
(Ephemeroptera), dragonflies and damselflies (Odonata),
caddisflies (Trichoptera) and flies (Diptera) are only present in
water in their larval form; water bugs (Heroptera) and beetles
(Coleoptera), on the other hand, also use the habitat in the adult
state. The composition of the insect taxa fluctuates significantly
and is determined to a large amount by the hydrology of their
environment.
Crustaceans are the largest group of
macroinvertebrates of temporary habitats. The species richness
of the crustacean fauna is often higher in temporary waters than
in permanent waters in the Mediterranean region. Many
temporary pond faunas include large Branchiopods, such as the
phyllopods, which includes large fairy shrimps (Anostraca),
tadpole shrimps (Notostraca) and clam shrimps (Conchostraca).
Among those phyllopods there are some endemic species, such
as the Chirocephalus ruffoi (Anostraca), the Triops cancriformis
(Notostraca), Cyzicus bucheti, Cyzicus grubei, Maghrebestheria
maroccana (Conchostraca, Spinicaudata), etc.
Endemic species of this class are the Ctenodaphnia
chevreuxi. These species, which have survived various climate
crises without significant degradation, are currently under threat
by anthropogenic activities (Belk, 1998; Keeley and Zedler, 1996;
Kiflawi et al., 2003; Lahr et al., 2000; Nicolet et al., 2004).
Macroinvertebrates, such as phyllopods, survive seasonally
through resistant resting stages, such as diapausing eggs and
cysts. For most species, the first stage larvae emerge soon after
pond filling (Keeley and Zedler, 1996). Reproductive success in
temporary pond invertebrates is influenced by the presence of
predators and drought (Spencer and Blaustein, 2001).The main
threat to all temporary pond invertebrates, globally, ishabitat loss
caused by land use impacts that destroy or severely damage
this ecosystems (Belk, 1998). Mediterranean temporary ponds
have generally a high productivity and low predation (Boix et al.,
2001). In many temporary ponds, the predators are mainly
insects, which colonize the ponds very slowly in contrast to
aquatic organisms emerging from resting stages.As a result, the
proportion of predatory species will increase in time (Blaustein
et al., 2004; Brendonck et al., 2002; Eitam et al., 2004; Spencer
et al., 1999). The predation of invertebrates is animportant biotic
stress factor, which regulates the temporary pond community.
The most common invertebrate predators in temporary ponds
are turbellarians (Brendonck et al., 2002; Eitam et al., 2004),
notonectids, diving beetles (Coleoptera) and dragonfly
larvae (Odonata) (Spencer et al., 1999). From these predators,
only the turbellarian is able to produce resting eggs that survive
Zacharias et al.4
5. Journal of Environmental Biology January, 2007
the dry periods (Brendonck et al., 2002). Pond type is the key
factorto determine which predatoris themost efficient (e.g. turbid
versus clear ponds, ponds with or without vegetation, etc.). If
there is a lack of larger predators the main advantage will be for
the open water invertebrate species as the phyllopods (i.e the
Conchostraca, the Notostraca and theAnostraca, Spencer et al.,
1999). Phyllopods are not well equipped to avoid fast swimming
predators. These crustaceans, therefore, are not often
encountered in waters with fish (Brendonck et al., 2002; Eitam et
al., 2004; Lahr, 1997; Spencer et al., 1999). Examples of
microinvertebrate predators are flatworms and cyclopoid
copepods.
Threats: Mediterranean temporary pond habitats are very
vulnerable to human activities, due to their special physical and
ecological characteristics. Their value is frequently overlooked
(Beja and Alcazar, 2003; Rhazi et al., 2001b; Schwatrz and
Jenkins, 2000) because of the habitat’s small size, its seasonal
occurrence and its unique appearance, which differs from most
natural landscapes.
Even though in the Mediterranean region human
influenceswere alwayspresent, MTPs’ high biodiversityhas been
preserved for centuries in equilibrium with human activities (Beja
and Alcazar, 2003; Grillas et al., 2004a; Rhazi et al., 2001b).
There is no current research enabling the decline of temporary
ponds to be measured (Grillas et al., 2004a), but as agriculture
and urban development play an increasing role in the
Mediterranean region, numerous sites with temporary ponds are
in danger of degradation (Beja andAlcazar, 2003; Blaustein and
Schwartz, 2001; Brendonck and Williams, 2000; King, 1996).
Increasedurbanisation in the Mediterranean region has
led, through housing or road development projects, to the
extinction of numerous temporary ponds, which also face less
obvious threats (Fig. 1). Water from the ponds is often used for
various purposes, such as irrigation of agricultural land, watering
of livestock and domestic use. This can occur by direct extraction
or by pumping close to the ponds frequently resulting in the
premature drying off of the ponds (Brendonck andWilliams, 2000;
Serrano and Serrano, 1996). Artificial drainage of the ponds
Fig. 1: Threats of the Mediterranean temporary pond habitat
Overview of temporary ponds in Mediterranean region 5
6. Journal of Environmental Biology January, 2007
catchment for human purposes in the dry season also shortens
the inundation period, which is known to affect organisms that
depend on the aquatic phase of the ponds for their reproduction
and development (e.g. amphibians and Odonata species),
(Grillas et al., 2004a; Serrano and Serrano, 1996).
In some cases, there is also artificial recharge of
temporary ponds as a restoration practice, which often results in
extended flooding and can even make the ponds permanent.
The effect of extendedflooding maysometimes bepositive; ponds
that hold water for a longer period can support early, as well as
late breeding fauna species (Beja andAlcazar, 2003). However,
the extension of flooding period can also lead to a more intense
competition of aquatic common plant species, replacing rare
species that are characteristicfor Mediterraneantemporary ponds
(Warwick and Brock, 2003).
Some of the ponds are deepened by farmers and used
as reservoirs, which are water fed by irrigation channels. Exotic
predators, such as certain fish and crayfish species (e.g. Small
mouth bass (Micropterus salmoides) and American crayfish
(Procambarus clarkia) are common in irrigation channels and
frequently colonize the permanent reservoirs. These predators
are known to eat amphibian eggs and larvae, thus reducing their
populations (Beja and Alcazar, 2003; Grillas et al., 2004a). A
different reason for temporary ponds being transformed into
permanent ponds is the extraction of minerals, such as clay and
fertile soils from temporary ponds’ surroundings. This has a
destructive effect on pond seedbanks, reducing diversity of plant
species. Yet another reason for shorter hydroperiods is the
invasion of woody species, which will increase the
evapotranspiration rate locally. Invasion of woody species can
be a natural process, but it is considerably amplified by
eutrophication and other processes which favour species with
greater ability tocompete (Grillas et al., 2004a; Rhazi et al.,2004).
Pollution levels of temporary ponds are generally
increasing by intensified agricultural activities with extensive use
of pesticides and fertilizers and by domestic and industrial waste
and airborne pollutants (Everts, 1997; Lahr, 1997). Several
ponds, e.g. in Morocco, are also used for washing, which adds
phosphates from detergents to the ponds’ water. Industrial
activities and solid waste disposal may lead to increased
wastewater dischargeand acidification of waterbodies. Exposure
to (sub) lethal doses of pollutants will reduce the populations of
vulnerable organisms by mortality or decreasing growth rates
(Grillas et al., 2004a, Lahr 1997; Rowe et al., 1992). Significant
pressure from agricultural effluents is also very common in the
Greek MTPs that are usually located close to cropland areas
where the excessive use of fertilizers leads to the eutrophication
of surface waters. Furthermore, water abstractions directly from
the ponds or from other water bodies that are hydrologically
related to the MTPs often cause significant degradation in their
hydroperiod, especially in the semi arid Greek islands.
Approximately, 29% of the Greek MTP sites are impacted from
agricultural pressures while in 19% of the sites hydrologic
disturbances are observed and 16% of the MTPs habitats are
overgrazed.
In addition, the increasing number of tourists visiting
the Mediterranean region often raises the stress applied to the
habitat by activities, such as horseback riding, 4x4 vehicles
crossing, picnic events and establishment of temporary car park
areas during the dry season (Grillas et al., 2004a, Serrano and
Serrano, 1996). Visitor pressure in the dry season, as well as
trampling by cattle, also changes the geomorphologic
characteristics of the ponds’ bed. This can make it impossible for
some plants to germinate. Species like Elatine brochonii for
example, are unable to germinate if their seeds have been
covered with just a thin layer of soil (Grillas et al., 2004b).
Fires can cause direct damage by burning vegetation
anddiminishing the seedbank and animal populations.The effect
of burned vegetation may sometimes be positive in the sense
that the destruction of woody species and the opening-up of the
habitat favors Mediterranean species but fire in the catchment
area is also known to have a significant impact on pond
ecosystems, causing increased erosion and adding nutrients to
the pond (Grillas et al., 2004a).
Finally, future climate changes could affect the
existence of Mediterranean temporary ponds. If these changes
result in a reduced amount of precipitation in the Mediterranean
region the hydroperiods of temporary ponds might become
shorter, or might not even occur, because of falling groundwater
levels and reduced input through rain and surface runoff water.
Typology: During the last 4 decades there has been a large
number of publicationswithin the context of ecosystem functions,
services and structures but a respective systematic typology for
most habitat types is missing (Groot et al., 2002). Using a
systematic classification contributes to assessing the variability
of natural resources and selecting representative areas for
conservation, so that diversity is captured and protected. Today,
wetland classification is mainly based on the Ramsar Convention
classificationsystem,which comprisesa general classification tool
for facilitating communication between scientists and
environmental managers. However, several inadequacies exist
in this system, since it does not include all the types of wetlands
and uses a large number of mixed criteria such as genetic,
vegetative, climatic and geothermal, to separate the various
habitats. Mediterranean temporary ponds are seasonal wetlands
that largely depend on hydrology and thus many scientists have
proposed classification systems that depend on hydrological
aspects of the habitat including the source of the ponds water,
the duration of inundation and dry periods and the timing of these
stages(Keeley andZedler, 1996). Other scientistshave presented
a combined geomorphic and hydrologic approach to the
temporary pond classification based on the landform setting and
Zacharias et al.6
7. Journal of Environmental Biology January, 2007
the hydroperiod, which are considered to be the major factors
that differentiate the various types of ponds.
In this paper a slightly different approach is suggested
for the classification of MTPsthat incorporatesall themain abiotic
factors determining the ecological regime of the habitat. This
approach follows the concept of European Commission’s 2000/
60 Directive that promotes the development of simple, unified
classification systems for the assessment of water quality based
on ecological indicators. Thus, morphological conditions such as
altitude, geology setting, size and depth are considered, the
aforementioned hydrologic aspects are also included, as well as
water quality parameters (temperature, dissolved oxygen, pH,
salinity, conductivity) and the habitat’s trophic status (Table 2).
This classification system covers all the key characteristics of
the temporary pond habitat and discriminates adequately the
many different types observed globally. Nevertheless, the
development of a detailed and widely applicable classification
system, as well as a respective effort to classify the temporary
water habitats, in order to clarify the genuine differences and the
unique characteristics of each type, is nowadays essential. Such
aneffort will contribute to designing the appropriate management
activities and applying effective conservation measures on these
important habitats.
Conservation and management:
Broad consensus among the stakeholders should be
achieved regarding the protection and conservation of the
ecologically important areas of temporary ponds and
consequently effective implementation of conservation activities
and relevant institutional measures should immediately initiate
(Angélibert and Giani, 2003; Angélibert et al., 2004; Boix et al.,
2001; Brendonck and Williams, 2000).
In general, there are some issues to be considered
with regard to (Mediterranean) temporary pond management:
- Management should particularly aim at the protection of the
pond water regime (hydroperiod characteristics) and water
quality by preventing, for example, attempts to increase water
abstraction or drainage of the area (Collinson et al.,
1995,Nicolet et al., 2004). In the short term, vegetation of
temporary ponds will react more to changes in the
hydrological regime thanto chemical changes inwater quality
(Rhazi et al., 2001b).Therefore, management actions should
be primarily focused on restoring or preserving the natural
hydroperiod of the pond. Additionally, conservation measures
should also include efforts to reduce polluting substances,
becausethese will certainly havea negative effect, especially
on the aquatic fauna and flora, in the long term.
- Actions such as deepening, removing decaying vegetation
and leaf litter during the dry period (this may provide a refuge
for macro invertebrates or plants that lack desiccation
resistant life-stages, Nicolet et al., 2004) often have a
damaging effect on these fragile ecosystems.
- Conservation actions should focus on a number of small
ponds, which provide a variety of different microhabitats, and
therefore a diversity of species,
- Rather than one large pond (Grillas et al., 2004a). When
planning aconservation strategyfor waterbodies in any area,
it istherefore important to protect ponds witha rangeof depths
and water regimes.
- In areas with a high density of temporary ponds, an average
of ten ponds is needed to “capture” all the species of this
area (Grillas et al., 2004a).
- Particular attention should be paid to the presence of
uncommon species (Collinson et al., 1995, Nicolet et al.,
2004).
In orderto implement the management plans inan area,
increasing public awareness is necessary. Therefore,
management measures should include actions to publicize the
conservation value of temporary ponds (Angélibert et al., 2004;
Belk, 1998).
Overview of temporary ponds in Mediterranean region
Table - 2: Typology system for Mediterranean temporary ponds
Morphological Water quality
Altitude high: > 800 m Temperature < 3o
C
midaltitude: 200-800m 3-10o
C
lowland: < 200 m 10-30o
C
> 30o
C
Geology Calcareous Dissolved < 5 mg/l
siliceous oxygen 5-15 mg/l
organic >15 mg/l
Size < 0,5 m2
pH < 5
0,5 m2
- 500 m2
05-Aug
500 m2
– 1 ha > 8
> 1 ha
Depth < 10 cm Salinity < 0.1 g/l
10 - 50 cm 0.1 - 1 g/l
50 – 100 cm 1 – 3 g/l
> 100 cm saline > 3 g/l
Hydroperiod < 20 days/ year Conductivity < 200 µS/cm
20 - 50 days/ year 200-500 µS/cm
50 – 100 days/year 500-1000µS/cm
> 100 days/year >1000µS/cm
irregular
Water supply Entirely from rainfall Trophic Oligotrophic
Rainfall and levels Mesotrophic
groundwater Eutrophic
Rainfall and melting
snow
Rainfall, melting snow
and groundwater
Period of Autumn
flooding Winter early spring
7
8. Journal of Environmental Biology January, 2007
Temporary ponds are globally known under more than
30 different names; vernal pools, daya’s, brumal pools, cupular
pools, ephemeral waters, etc. (Table 1). The use of numerous
names indicates the lack of unique classification system for
temporary ponds, which has possibly led to the deficiency of
information about the main characteristics and therewith the
differences between the various types of these habitats. In the
particular study a simple and comprehensive typology approach
is suggested including a combination of hydromorphologic and
water quality parameters that characterize the different types of
temporary ponds.
Mediterranean temporary ponds incorporate unique
and local hydrological conditions. The main characteristics of
these ponds are the length and variationof the hydroperiod which
is also closely connected to chemical conditions because when
the pond dries out, the chemical characteristics fluctuate
considerably.
Insects and other macroinvertebrates are the largest
groups in these habitats while their reproduction success is
influenced by predation and drought. Predation is low in
comparison to permanent waters and occurs mainly by insects.
As a result of colonization and emergence from resting stages,
predation increases during the inundation phase. Temporary
ponds that are not considerably impacted by anthropogenic
activities comprise favourable conditions for amphibian species
and therefore these constitute good parameters to describe the
quality of the habitat.
Temporaryponds are more threatened than permanent
waters. Relatively small changes in the regional hydrologic
conditions can lead to major changes in the ecological regime of
temporary ponds in that area. In addition, pollution through
surface runoff can be a significant degradation factor and
acidification is also encountered in many cases.
In Greece the most common threat of the habitat
originates from intensive agriculture which either expands over
the MTPs or pollutes their water with fertilizers. Hydroperiod
destabilization is also another significant problem through direct
water abstractions for human demands as well as in a long-term
basisfrom thedecrease in precipitation (climate change). Tourism
can also be a harmful activity for MTPs if no precautionary
measures are undertaken since most of the habitat sites are
located in recreational areas.
For effective management of the temporary pond
habitat, tackling the prevailing threats on a site specific basis, as
well as protecting a wide range of microhabitats, hydroperiods
and successional stages is very important. Such an approach
will lead to the conservation of the maximum environmental
variability possible and therefore the highest biodiversity in this
habitat.
Mediterranean temporary ponds are one of the most
threatened types of temporary ponds. They are located in many
countries of the Mediterranean region, many of which do not
belong to the EU and therefore the aforementioned Habitat
Directive is not applicable there. However, conservation of the
ponds outside the European Union is also very important and
appropriate political and managerial measures should be
immediately taken to avoid potential ecological degradation.
Acknowledgments
This study was supported by the LIFE Nature project
entitled: Actions for the conservation of Mediterranean Temporary
Ponds in Crete.
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Overview of temporary ponds in Mediterranean region 9