APPLIED AND ENVIRONMENTAL MICROBIOLOGY, Sept. 1998, p. 3429–3436
0099-2240/98/$04.0010
Copyright © 1998, American Society for Microbiology. All Rights Reserved.
Vol. 64, No. 9
Assessment of Reductive Acetogenesis with Indigenous Ruminal
Bacterium Populations and Acetitomaculum ruminis
TRICIA D. LE VAN,1,2† JOSEPH A. ROBINSON,3 JOHN RALPH,4,5 RICHARD C. GREENING,3
WALTER J. SMOLENSKI,3 JANE A. Z. LEEDLE,3‡ AND DANIEL M. SCHAEFER1,2*
Departments of Bacteriology,1 Animal Sciences,2 and Forestry,4 University of Wisconsin—Madison,
and U.S. Dairy Forage Research Center,5 Madison, Wisconsin 53706, and Microbiology
and Nutrition Research, Pharmacia & Upjohn Inc., Kalamazoo, Michigan 490013
Received 30 March 1998/Accepted 24 June 1998
In the rumen, methanogenic bacteria utilize hydrogen (H2)
to reduce carbon dioxide (CO2) and/or formate to methane
(CH4) as follows: CO2 1 4H2 3 CH4 1 2H2O. Eructation of
methane constitutes a 3 to 12% loss of gross energy intake for
ruminants (4, 5, 17, 27) and contributes to atmospheric methane concentrations implicated in global warming (24). Johnson
and Johnson (29) recently estimated that beef cattle account
for 67% of methane emissions by the U.S. cattle herd. Beef
cows account for 21% of the herd and 40% of the herd’s methane emissions. Feedlot cattle are principally steers and account
for 15% of the herd and 6% of methane emissions. These two
classes of cattle are widely divergent in their dietary management and tractability for fermentative modification. Previous
efforts to minimize digestible energy loss by suppressing ruminal methanogenesis have included the use of antibiotics, ionophores, or halogenated methane analogs (15, 43). Short-duration experiments with these analogs succeeded in suppressing
CH4 production, but H2 and formate accumulated (16) and
food consumption by sheep was adversely affected (13). The
accumulation of H2 indicated that halogenated CH4 analogs
disrupted interspecies H2 transfer and thus were not sufficiently selective in suppression of methanogenesis. As a consequence, it is now realized that minimization of ruminal methane production needs to involve a strategy whereby electron
disposal via interspecies H2 transfer is not disrupted, and it
would be advantageous if reducing equivalents were deposited
in a metabolite(s) which serves as a substrate for ruminant
tissue metabolism. One novel approach is the involvement of
reductive acetogenesis. Reductive acetogenic bacteria reduce
2 mol of CO2 to acetate by oxidation of H2 as follows: 2CO2 1
4H2 3 CH3COOH 1 2H2O. Diversion of energy from eructated CH4 to acetate by H2/CO2-consuming acetogenic bacteria could potentially enhance the energetic efficiency of ruminants and decrease methane emissions (34).
The potential importance of H2/CO2-utilizing acetogenic
bacteria in the rumen has been described; however, their capacity to effect a total synthesis of acetate from H2 and CO2 in
ruminal contents and the factors influencing the magnitude of
this activity have not been investigated. The presence of H2/
CO2-utilizing acetogenic bacteria in the rumen has been shown
(22, 25). Acetitomaculum ruminis produces acetate via heterotrophic growth on, for example, glucose and ferulic acid and
via autotrophic growth on formate, carbon monoxide (CO),
and H2/CO2 (30). Acetate produced via autotrophic growth
would constitute a competition with methanogenesis for hydrogen. While reductive acetogenesis is quantitatively important in the termite hindgut (6), there are apparently no reports
of nonmethanogenic ruminants. On the basis of data for nonruminal isolates, it has been hypothesized that ruminal acetogenic bacteria are not able to compete with ruminal methanogenic bacteria due to a less effective H2-scavenging ability, yet
there is a paucity of evidence to support this hypothesis.
Recent efforts to study ruminal acetogens and acetogenesis
have hinged on the use of 2-bromoethanesulfonic acid (BES),
an analog for coenzyme M (21). This coenzyme is essential for
the growth of some of the ruminal Methanobrevibacter species
* Corresponding author. Mailing address: Department of Animal
Sciences, 1675 Observatory Dr., University of Wisconsin—Madison,
Madison, WI 53706-1284. Phone: (608) 263-4317. Fax: (608) 262-5157.
E-mail: dmschaef@facstaff.wisc.edu.
† Present address: Respiratory Sciences Center, University of Arizona, Tucson, AZ 85724.
‡ Present address: Chr. Hansen, Inc., Milwaukee, WI 53214.
3429
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The objective of this study was to evaluate the role of reductive acetogenesis as an alternative H2 disposal
mechanism in the rumen. H2/CO2-supported acetogenic ruminal bacteria were enumerated by using a selective
inhibitor of methanogenesis, 2-bromoethanesulfonic acid (BES). Acetogenic bacteria ranged in density from
2.5 3 105 cells/ml in beef cows fed a high-forage diet to 75 cells/ml in finishing steers fed a high-grain diet.
Negligible endogenous acetogenic activity was demonstrated in incubations containing ruminal contents,
NaH13CO3, and 100% H2 gas phase since [U-13C]acetate, as measured by mass spectroscopy, did not accumulate. Enhancement of acetogenesis was observed in these incubations when methanogenesis was inhibited by
BES and/or by the addition of an axenic culture of the rumen acetogen Acetitomaculum ruminis 190A4 (107 CFU/
ml). To assess the relative importance of population density and/or H2 concentration for reductive acetogenesis
in ruminal contents, incubations as described above were performed under a 100% N2 gas phase. Both selective
inhibition of methanogenesis and A. ruminis 190A4 fortification (>105 CFU/ml) were necessary for the
detection of reductive acetogenesis under H2-limiting conditions. Under these conditions, H2 accumulated to
4,800 ppm. In contrast, H2 accumulated to 400 ppm in incubations with active methanogenesis (without BES).
These H2 concentrations correlated well with the pure culture H2 threshold concentrations determined for A.
ruminis 190A4 (3,830 ppm) and the ruminal methanogen 10-16B (126 ppm). The data demonstrate that ruminal methanogenic bacteria limited reductive acetogenesis by lowering the H2 partial pressure below the level
necessary for H2 utilization by A. ruminis 190A4.
3430
LEVAN ET AL.
MATERIALS AND METHODS
Media and growth conditions. For enumeration studies, AC-11 medium, used
for the cultivation of acetogenic bacteria from the termite hindgut (6), was
modified for the cultivation of acetogenic bacteria from the rumen. AC-B1 contained (per liter) the following: KH2PO4, 0.28 g; K2HPO4, 0.94 g; NaCl, 0.14 g;
KCl, 0.16 g; MgSO4 z 7H2O, 0.02 g; NH4Cl, 0.5 g; CaCl2 z 2H2O, 0.001 g; trace
mineral solution (25), 10 ml; vitamin solution (25), 10 ml; yeast extract, 0.5 g;
NaHCO3, 6.0 g; reducing agent (2.5% [wt/vol] each cysteine hydrochloride z H2O
and Na2S z 9H2O, pH 10.0), 10 ml; clarified bovine rumen fluid, 100 ml; BES
(sodium salt; filter sterilized) as indicated, 20 ml; and resazurin, 0.001 g. Broth
media were boiled and cooled under a flow of 80% N2–20% CO2 (vol%) prior
to addition of reducing agent and NaHCO3. The final volume per tube was 5 ml.
The final pH of the medium was approximately 6.8, with a headspace gas of 304
kPa of 80% N2–20% CO2 (vol%). Serum tubes were incubated horizontally with
304 kPa of 80% H2–20% CO2 (vol%) or 80% N2–20% CO2 (vol%) at 39°C and
200 rpm.
For pure-culture H2 threshold studies, A. ruminis strains (provided by the
Upjohn Co., Kalamazoo, Mich.) (25) and Acetobacterium woodii (ATCC 29683)
were grown on BSW-1 medium. BSW-1 medium contained (per liter) the following: KH2PO4, 0.2 g; NH4Cl, 0.3 g; KCl, 0.5 g; NaCl, 7.0 g; Na2SO4, 0.1 g;
MgCl2 z 6H2O, 1.2 g; CaCl2 z 2H2O, 0.15 g; yeast extract, 1.5 g; resazurin, 0.001
g; trace mineral solution (25), 10.0 ml; and vitamin solution (25). The medium
was boiled and cooled under a flow of 80% N2–20% CO2 (vol%), and then 6.0 g
of NaHCO3 and 10.0 ml of reducing agent (2.5% [wt/vol] each cysteine hydrochloride z H2O and Na2S z 9H2O, pH 10) were added. Final pH of this medium
was 7.4. Ruminal methanogen 10-16B (32) was grown in pure culture on M1
medium, which contained (per liter) the following: minerals 1 and 2 (9), 25 ml of
each; resazurin, 0.001 g; yeast extract, 2.0 g; Trypticase, 2.0 g; sodium acetate,
2.5 g; Tween 80, 0.0125 g; volatile fatty acid (VFA) solution (12), 5.0 ml; vitamin
solution (25), 10.0 ml; and trace mineral solution (25), 10.0 ml. Final preparations were done as described for AC-B1 but under a flow of 100% CO2 and
resulted in a medium with pH 7.0. Sporomusa termitida was provided by
J. A. Breznak (Michigan State University, East Lansing) and was grown on
AC-20 medium (7). Microorganisms for pure-culture H2 threshold studies were
incubated horizontally with 304 kPa of 80% H2–20% CO2 (vol%) at 200 rpm.
A. ruminis and methanogen 10-16B were grown at 38°C. S. termitida and A. woodii were grown at 30°C.
A. ruminis 190A4 was enumerated on AC-B1 agar plates (without BES). Total
viable anaerobes were enumerated on AC-B1 agar plates (without BES) supplemented with 0.05% (wt/vol) each soluble starch, cellobiose, and glucose. Agar
plates were incubated at 39°C in a 2.5-gal paint can (25, 28) for 14 days with 304
kPa of 80% H2–20% CO2 (vol%). Rumen methanogenic bacteria were enumerated by the three-tube most-probable-number (MPN) technique on AC-B1 medium (without BES) supplemented with 2 g of Trypticase per liter. Serum tubes
were incubated horizontally with 304 kPa of 80% H2–20% CO2 (vol%) at 39°C
and 200 rpm.
Animal diets and rumen samples. For enumeration studies, a rumen sample
was obtained via stomach tube 1.5 h postfeeding from each of four beef steers fed
once daily a typical finishing, i.e., high-grain (90 corn and supplement:10 corn
silage [dry matter basis]) diet containing 0.03 g of monensin/kg of dry matter. The
average rumen sample pH for animals on the high-grain diet was 6.2 6 0.2
(standard error of the mean [SEM]). A high-forage rumen sample was obtained
2 to 4 h postfeeding from each of four beef cows fed alfalfa-grass hay once daily.
Average rumen sample pH for animals on the high-forage diet was 7.1 6 0.1
(SEM). For in vitro competition studies, beef cows described above were sub-
sequently fistulated and fed alfalfa-grass hay. A ventral rumen sample from each
animal was obtained 2 h postfeeding and passed through a 2-mm-mesh screen in
an anaerobic glove box. Samples were pooled across three cattle to incorporate
animal variation into the rumen sample. The pooled rumen sample pH was
adjusted to 6.1 since addition of NaH13CO3 for in vitro incubations excessively
increased the pH of unadjusted samples.
Enrichment and enumeration studies. H2/CO2-supported acetogenic bacteria
were enumerated by the three-tube MPN method. Rumen fluid was transferred
to an anaerobic chamber (gas phase, 78% N2–17% CO2–5% H2 [vol%]) for
preparation of serial dilutions. Six tubes of AC-B1 medium with 2.5 mM BES
were inoculated with each dilution. The tubes were evacuated and pressurized to
304 kPa with a gassing manifold (1), three tubes with 80% H2–20% CO2 (vol%)
and three with 80% N2–20% CO2 (vol%) for controls. Tubes were incubated for
8 to 12 days at 39°C and 200 rpm. Optical density of the enrichment cultures was
monitored every other day, with periodic repressurization with the appropriate
gas mixtures. H2/CO2-incubated cultures were considered positive for acetogenic
bacteria when the optical density at 600 nm was $0.3 over that in the N2/CO2incubated tubes, methane was not detected in the headspace gas, and the pH was
#6.1.
Aliquots from each H2/CO2-incubated tube which showed no growth were
transferred to duplicate tubes of fresh AC-B1 medium. One tube was pressurized
with 80% H2–20% CO2 (vol%), the other tube was pressurized with 80% N2–
20% CO2 (vol%), and both were incubated in the presence of BES as described
for an additional 8 to 12 days. A third and final transfer was done for the
remaining H2/CO2-incubated tubes, which showed no growth. This incubation
protocol for the enumeration of acetogenic bacteria was adopted since an 8- to
12-day incubation for each of three transfers resulted in maximum enrichment of
acetogenic bacteria (31a). The MPN was calculated from the tables of deMan
(19). Our detection limit for the MPN was calculated to be less than 15 cells/ml
(31a). Positive MPN tubes were confirmed to be acetogenic when acetate concentrations were significantly greater in the H2/CO2-incubated tubes than in the
control tubes.
13
CO2 fixation studies. Serum vials (70 ml) containing 60 mM potassium
phosphate buffer were maintained in an anaerobic chamber (gas phase, 78%
N2–17% CO2–5% H2 [vol%]) for at least 1 h prior to autoclaving. After cooling,
sterile BES (5.0 mM, final concentration; sparged with 100% N2) was added to
vials in the anaerobic chamber followed by 9 ml of a freshly strained, pooled
rumen sample. Vials were evacuated for 5 min while being shaken at 200 rpm and
were then pressurized with 124 kPa of 100% H2 or 100 kPa of 100% N2 with a
gassing manifold (1). Residual CO2 remaining after evacuation was less than 0.01
mmol as measured by the BaCO3 method (31). Gas volumes were measured with
a pressure transducer (model PX126-015DV; Omega Engineering, Stamford,
Conn.) (20). The volume of gas was calculated from the measured internal
pressure and with reference to a standard curve. Initial H2 concentration in the
headspace gas was approximately 6.0 mmol per vial. NaH13CO3 solution (75 mM
[final concentration] as determined by the BaCO3 method [31]) was added to all
vials followed immediately by addition of an A. ruminis 190A4 inoculum as
indicated. NaH13CO3 solution was prepared by dissolving NaH13CO3 (greater
than 98% 13C enriched; Isotec Inc., Miamisburg, Ohio) in sterile CO2-free water
containing 1% (vol/vol) reducing agent (described above). The final volume in
the vials was 10.7 ml, and the initial and final pH of the reaction mixture were
approximately 7.1 and 6.9, respectively. Vials were incubated at 39°C with shaking at 200 rpm for approximately 48 h. Reactions were terminated by addition of
0.4 ml of concentrated HCl. After mixing and allowing CO2 equilibration for 15
min, final gas volumes were measured. Headspace gas and liquid phase were
sampled for gas chromatographic (GC), liquid chromatographic, and GC-mass
spectometry (MS) analyses.
For experiments simulating physiological H2 concentrations in the rumen, vials
were prepared as described above, with the following exceptions: vials contained
80 mM potassium phosphate buffer and 40 mM 3-[N-morpholino]-2-hydroxypropanesulfonic acid (MOPSO; sodium salt) for increased buffering capacity; 0.38 g
of alfalfa (ground through a 2-mm-mesh screen) was added as a slowly degradable carbohydrate and a source of H2; and vials were evacuated and pressurized
with 6.9 kPa of 100% N2. Initial and final pHs after 48 h of incubation were
approximately 7.3 and 6.6, respectively. MOPSO was found to have no effect on
H2/CO2-consuming methanogenic activity in ruminal contents and A. ruminis
190A4 acetogenic activity (31a).
Pure-culture H2 threshold studies. Bacteria were cultured in 125-ml serum
bottles each containing 25 ml of medium under 232 kPa of 80% H2–20% CO2
(vol%). After incubation, the bottles were flushed with sterile 80% N2–20% CO2
(vol%) and evacuated three times, and the contents were pooled. To the pooled
cultures, an equal volume of sterile medium was added under a flow of 80%
N2–20% CO2 (vol%). Aliquots of 5 ml of suspension were distributed into sterile
tubes under a flow of 80% N2–20% CO2 (vol%). Tubes were sealed with butyl
rubber stoppers held in place with aluminum seals. Ten milliliters of 80% N2–
20% CO2 (vol%) was added to some of the tubes to serve as controls for
endogenous H2 production. Four of these tubes immediately were analyzed for
H2 so that the initial background concentration of H2 could be estimated. Finally,
10 ml of 1.2% H2–75.2% N2–23.6% CO2 (vol%) was added to another set of
tubes to provide 6,000 ppm of H2 as the substrate for estimation of the H2
thresholds. The initial H2 concentration was in excess of the H2 threshold values
measured for all selected microorganisms. Additional tubes of medium only
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(35). Whereas chloroform was a nonselective inhibitor of
methanogenesis and other metabolisms dependent on transmethylation (23), BES has been used as a selective inhibitor of
ruminal methanogenic bacteria because it is a methylreductase
inhibitor (44).
In this study, a series of experiments were conducted to
assess the presence, endogenous activity, and competitiveness
of reductive acetogenesis in the bovine rumen. When cattle were
the source of inocula, their nutritional management was intended to simulate the beef cow and feedlot sectors of the U.S.
beef cattle industry. The principal energy source in beef cow
diets is forage (10), whereas feedlot cattle are fed a high-grain
diet containing an ionophore (11). Specifically, the population
size of reductive acetogenic bacteria was determined for cattle
in these two scenarios, and endogenous reductive acetogenic
activity was quantified in rumen-like incubations by using mass
spectroscopy (MS). We also investigated the ability of A. ruminis 190A4 to compete with rumen methanogens by altering
the concentration of this acetogen or H2 in ruminal contents
and measurement of its threshold for H2.
APPL. ENVIRON. MICROBIOL.
VOL. 64, 1998
REDUCTIVE RUMINAL ACETOGENESIS
3431
H2 threshold (ppm) 5
F
ppm H2 3 (22.2 ml 1 ml of gas vented)
22.2 ml
G
where 22.2 ml is the gas-phase volume of the tube. The detection limit was
dependent on flow rate; therefore, the detection limits were ,1 ppm for methanogens and ,10 ppm for the acetogens.
MS analysis. Mass spectra of VFAs were determined by GC-MS to calculate
the ratio of 13C- to 12C-labeled acetate, propionate, and butyrate. Samples for
GC-MS were derivatized to butyl esters and extracted from an aqueous phase
into hexane as described by Salanitro and Muirhead (40). The mass spectrum
fragmentation pattern for butyl acetate compared well with published spectra
and the fragment ion peak for [U-12C]acetate. Derivatization yielded an average
98.5% recovery for VFA compounds. GC-MS samples were carried onto a DB-1
column (0.25 mm by 12 m; J&W Scientific, Folsom, Calif.) fitted in an HP 5890
gas chromatograph operating in split mode (1:50). Helium was the carrier gas,
with a mean linear velocity of 0.8 ml/min. The temperature was held at 40°C for
2 min, programmed to increase to 70°C at 5°C/min, then incremented to a final
temperature of 120°C at 20°C/min and held at that temperature for 1 min, for a
total run time of 11.5 min. Eluting compounds were volatilized into an HP 5970
mass selective detector (70-eV ionization) controlled by an HP UNIX data
station, and total ion chromatograms were reconstructed. From abundance ratios
of fragment ions, e.g., 2O12C12CH3 (mass 5 43), 2O13C12CH3 or 2O12C13CH3
(mass 5 44), and 2O13C13CH3 (mass 5 45) for butyl acetate species, and
quantitation of total VFAs by liquid chromatography, the concentration of a 13C
isotope was calculated. Recovery of [U-13C]acetate was 101.0%, which indicated
that the method was sufficiently accurate to use in quantitative fermentation
studies.
RESULTS
Enumeration of H2/CO2-supported acetogenic bacteria from
the rumen. H2/CO2-supported acetogenic bacteria in the rumen were enumerated by using a selective inhibitor of methanogenesis, BES. For cattle receiving a high-forage diet, H2/
CO2-supported acetogenic bacteria ranged in population density from 3.5 3 101 to 2.6 3 105 cells/ml of rumen fluid (Fig.
1A). The total viable anaerobe concentration was between
1.5 3 108 and 4.8 3 108 CFU/ml of rumen fluid for all highforage enrichments. For cattle receiving a typical finishing
(high-grain) diet, H2/CO2-supported acetogenic bacteria were
less numerous (P , 0.05) than for the high-forage diet and
ranged in population density from 2 to 75 cells/ml of rumen
fluid (Fig. 1B). Total viable anaerobic population for this diet
was 1.4 3 109 to 4.7 3 109 CFU/ml of rumen fluid. Additional
enrichments from the high-grain diet rumen samples were
done on AC-B1 medium at pH 6.1. The medium at pH 6.1 was
FIG. 1. Enumeration of acetogenic and total viable anaerobic bacteria from
the bovine rumen. Acetogenic bacteria were enriched on a rumen fluid-based
medium containing 2.5 mM BES and enumerated by the MPN method. (A)
Enumeration from ruminal contents of cattle fed a high-forage diet. Bars of the
same pattern represent duplicate enumeration from the same animal done within
1 to 5 months. (B) Enumeration from ruminal contents of cattle fed a high-grain
diet. Each bar represents one enumeration from one animal.
expected to be more habitat simulating (for high-grain diet)
than the medium at pH 6.8; however, no H2/CO2-supported
acetogenic bacteria were detected (data not shown). H2/CO2supported acetogenic cultures were confirmed to be acetogenic. Acetate accumulated in the H2/CO2-incubated tubes
(58.6 mM 6 6.3) over that in the N2/CO2-incubated tubes (16.7
mM 6 0.6) for all 45 positive MPN cultures analyzed in duplicate (mean 6 SEM, P , 0.001). Repressurization was done
during the enumeration protocol, which precluded the evaluation of the reaction stoichiometry. Cell morphologies observed in enrichment broths were similar to that of A. ruminis
190A4 in addition to a long rod and a coccus.
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(uninoculated) were prepared as described above to serve as controls for abiological consumption and production of H2.
All tubes except those used for immediate H2 analysis were incubated for 5 to
7 days with constant agitation. Initial observations revealed that the threshold
was approached after 2 days of incubation. We allowed 5 to 7 days of incubation
to ensure enough time for the threshold concentration to be reached. Subsequently, headspace gas pressure in tubes was measured with a pressure transducer (model PX102-006 GV; Omega Engineering), and the concentration of H2
remaining in the headspace gas was determined with a mercury reduction detector as described below.
Liquid and gas chromatographic analyses. The concentration of VFAs (formate, acetate, propionate, and butyrate) was measured by liquid chromatography. Samples were prepared and analyzed as described by Barlaz et al. (2). The
gas phase of the enrichment cultures and in vitro incubations was analyzed for
H2, CH4, and CO2 by GC by injecting the sample into a Packard 438 gas
chromatograph (Chrompack, Raritan, N.J.) equipped with a model 914 thermal
conductivity detector and HP 3390A integrator (Hewlett-Packard, Avondale,
Pa.) for data acquisition. The column used was 120/140 Carbosieve S2 (2.7 m by
3.2 mm [outside diameter]; Supelco, Bellefonte, Pa.). Operating conditions for
the gas chromatograph were as follows: N2 carrier gas, 30 ml/min; column
temperature, 200°C; injector and detector temperature, 210°C; and injection
volume, 0.4 ml.
For pure-culture H2 threshold studies, H2 was measured with a mercury
reduction detector (Trace Analytical, Menlo Park, Calif.) and expressed as parts
per million. Headspace gas was vented through a 20-ml sample loop and injected
onto an 80/100-mesh molecular sieve 5A chromatography column (3.2 mm by
1.8 m). Chromatographic conditions were as follows: column temperature, 50°C;
carrier gas, chromatographic-grade helium with flow rates of 60 ml/min for
A. ruminis strains, 20 ml/min for the methanogen, and 40 ml/min for S. termitida
and A. woodii. The H2 concentration in a tube was calculated after adjustment
for the gas pressure as follows:
3432
LEVAN ET AL.
APPL. ENVIRON. MICROBIOL.
TABLE 1. Endogenous ruminal acetogenic activity
Concn (mM) of BES
added to ruminal
contentsa
5
0
Gas
phase
H2
N2
H2
N2
Mean concn (mmol) 6 SEM (n 5 3)
[1- or 2-13C]acetatecarbon
[U-13C]acetatecarbon
0.26 6 0.018
0.08 6 0.004
0.06 6 0.003
0.06 6 0.000
0.24 6 0.002
0.04 6 0.001
0.04 6 0.003
0.02 6 0.001
a
Reaction mixtures contained 9 ml of ruminal contents, 5 mM BES, 0.8 mmol
of NaH13CO3, 100% H2 (6.0 mmol) or 100% N2 gas phase, and other reagents
as indicated in Materials and Methods. Ruminal contents were incubated for
45 h. At time zero, the [1- or 2-13C]acetate-carbon concentration was 0.04 6 0.001
mmol and the [U-13C]acetate-carbon concentration was 0.02 6 0.001 mmol.
FIG. 2. H2-dependent [13C]acetate accumulation in rumen-like incubations
amended with A. ruminis 190A4 and BES. Reaction mixtures contained 9 ml of
ruminal contents, 5 mM BES, 0.8 mmol of NaH13CO3, A. ruminis 190A4 inoculum, 100% H2 gas phase (6.0 mmol), and other reagents as indicated in Materials and Methods. Vials were incubated for 48 h at 200 rpm and 39°C prior to
sample collection for [13C]acetate analysis by MS. Means of the same bar pattern
with different letters are different (P , 0.025). Data are presented as means 1
SEMs for three determinations.
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Endogenous rumen acetogenic activity. Activity of endogenous rumen acetogenic bacteria was investigated by incubating
ruminal contents with 100% H2 gas phase and NaH13CO3.
When methanogenic bacteria were inhibited by BES, 0.18
mmol of net [1- or 2-13C]acetate-carbon and 0.2 mmol of net
[U-13C]acetate-carbon accumulated, indicating ruminal acetogenic activity (Table 1). H2 and CO2 were in excess during the
entire incubation period, and methane was not detected in the
headspace gas (data not shown). The concentration of residual
gas was not determined. There was a specific enhancement of
acetogenesis, as shown by 13C incorporation into acetate under
H2 compared to N2, presumably due to limiting endogenous
reducing equivalents (i.e., H2 or formate). Only trace amounts
of 13C were associated with propionate and butyrate (,0.02
mmol).
Activity of endogenous ruminal acetogenic bacteria was dissipated in H2-incubated vials which did not receive BES. Zero
net [1- or 2-13C]acetate and 0.02 mmol of net [U-13C]acetate
accumulated (Table 1). CO2 was completely utilized during the
incubation of ruminal contents without BES; however, the fate
of NaH13CO3 was not determined. These vials contained residual H2 and methane in the gas phase after the 45 h of
incubation. Quantitation of H2 and methane was not assessed
in these vials. There was a specific enhancement of methane
accumulation under H2 compared to N2 gas phase, implying a
limitation in available reducing equivalents (data not shown).
Role of population density in reductive ruminal acetogenic
activity: in vitro incubations with nonlimiting concentration of
H2. Whether endogenous ruminal acetogenesis could be limited by the population density of acetogenic bacteria was addressed in the following experiments. Ruminal contents were
incubated with 100% H2 gas phase, NaH13CO3, BES, and an
A. ruminis 190A4 inoculum. When methanogenic bacteria
were inhibited by BES, accumulation of acetate-carbon was
positively correlated with the population density of added
A. ruminis 190A4 from 103 to 106 CFU/ml (Fig. 2). Maximum
levels of 13CO2 fixed into acetate, as indicated by the final
concentration of carbon in singly and doubly labeled acetate,
were observed when the final concentration of A. ruminis
190A4 added to ruminal contents was 105 to 107 CFU/ml of
ruminal contents. An average of 0.39 mmol of total acetate
(equivalent to 0.78 mmol of acetate-carbon) accumulated from
the utilization of approximately 1.7 mmol of H2. Based on
accumulation of doubly and singly labeled acetate, levels of
acetogenic activity for these levels of inoculation were approximately 50% greater than that found for H2-supported, net
endogenous acetogenic activity in the presence of BES (Table
1). The concentration of A. ruminis 190A4 required for enhancement of rumen acetogenic activity was equal to or greater than the acetogen population enumerated in animals fed the
high-forage diet (Fig. 1A). Growth of A. ruminis 190A4 was not
negatively affected by a BES concentration of #5 mM (data
not shown). Methane was not detected in these vials which
contained BES (data not shown). Low levels of propionate and
butyrate accumulated; however, only trace amounts (,0.02
mmol) of 13C were associated with propionate and butyrate.
All values in Fig. 2 represent strictly H2-dependent fixation
products since the amount of CO2 incorporated into a particular product under H2 was corrected for the accumulation of
the same product under an N2 atmosphere.
When BES was not present in the incubation vials containing excess H2 as described above, acetogenesis was stimulated
only at the highest concentration of A. ruminis 190A4 tested
(Fig. 3). An increase in [1- or 2-13C]- and [U-13C]acetatecarbon at the expense of methane accumulation was observed
when the concentration of A. ruminis 190A4 added to rumenlike incubations was 2.2 3 107 CFU/ml of ruminal contents
(P , 0.05). This acetogen concentration was 100-fold greater
than that found by enumeration studies (Fig. 1A). Reduction
in methane concentration presumably resulted from diminished availability of CO2 due to its fixation into acetate. CO2
was completely utilized in all incubations, while H2 was present
in excess in all vials (data not shown). Approximately 0.8 mmol
of NaH13CO3 was utilized for the production of 0.6 mmol of
methane and 0.3 mmol of acetate-carbon. Low levels of formate, propionate, and butyrate accumulated during the incubation; however, only trace amounts of 13C were associated
with propionate and butyrate (,0.02 mmol). Initial methanogenic (1.7 3 108 cells/ml) and total viable anaerobic (8.4 3 108
CFU/ml) population densities were at least 10-fold higher than
the highest concentration of A. ruminis 190A4 added to rumenlike incubations.
Role of H2 concentration in ruminal reductive acetogenic
activity: in vitro incubations with limiting concentration of H2.
To assess the competitiveness of acetogenic bacteria in rumen-
VOL. 64, 1998
REDUCTIVE RUMINAL ACETOGENESIS
3433
amended with BES (Table 2). In vials containing BES and 108
A. ruminis 190A4 CFU/ml, the H2 equilibrium concentration in
the headspace gas was approximately 4,800 ppm throughout
the 43-h incubation (Fig. 4A). Accumulation of H2 was inversely proportional to the concentration of A. ruminis 190A4 up to
106 CFU/ml, indicating that the H2-consuming capacity of ruminal contents was dependent on the population density of
A. ruminis 190A4 (data not shown). With A. ruminis 190A4
densities greater than or equal to 106 CFU/ml in vials amended
with BES, the headspace contained 0.023 mmol of H2 (equivalent to approximately 4,800 ppm of H2), and gas production
was independent of A. ruminis 190A4 concentration (P . 0.2).
This result suggests a saturation of A. ruminis 190A4 capacity
for H2 utilization.
In contrast, H2 accumulated over time in vials which re-
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FIG. 3. H2-dependent [13C]acetate and methane accumulation in rumen-like
incubations with A. ruminis 190A4 and active methanogenic bacteria (without
BES). Reaction mixtures contained 9 ml of ruminal contents, 0.8 mmol of
NaH13CO3, A. ruminis 190A4 inoculum, 100% H2 gas phase (6.0 mmol), and
other reagents as indicated in Materials and Methods. Vials were incubated for
48 h at 200 rpm and 39°C prior to sample collection for methane and [13C]acetate
analysis by GC and MS, respectively. [13C]acetate-carbon is the summation of [1or 2-13C]- and [U-13C]acetate-carbon. Each point represents the mean 6 SEM
for three determinations.
like conditions, in vitro incubations were conducted with an
ecologically common source of H2. The accumulation of H2 in
the headspace gas over time was measured in vials containing ruminal contents incubated with 100% N2 gas phase,
NaH13CO3, and alfalfa in the presence or absence of BES
and/or A. ruminis 190A4. Alfalfa was added as a slowly degradable carbohydrate source for the production of a rumen-like
H2 concentration. Under conditions with active methanogenesis (without BES), H2 was generated from the alfalfa fermentation and utilized for methanogenesis (Fig. 4). These vials
which supported methanogenic activity contained approximately 0.002 mmol of gaseous H2, which was equivalent to an
H2 equilibrium concentration in the headspace gas of less than
400 ppm during the entire 43-h incubation. This H2 concentration was independent of added A. ruminis 190A4 (Fig. 4A;
P . 0.95). The H2 equilibrium concentration was considered to
be the balance between H2 production and utilization. Methanogenic activity was evidenced by the accumulation of headspace methane and also found to be similar for vials with or
without 4.1 3 108 A. ruminis 190A4 CFU/ml (Fig. 4B; P . 0.9),
suggesting minimal H2/CO2-supported activity of A. ruminis
190A4 in methanogenesis-supportive incubations. Furthermore, singly or doubly labeled acetate-carbon did not accumulate in vials with active methanogenesis and added A. ruminis
190A4 to levels above those measured in control vials without
the addition of A. ruminis 190A4 (Table 2; P . 0.2).
Vials containing ruminal contents in which methane production was inhibited (with BES) had significantly higher H2 equilibrium concentrations in the headspace gas than methanogenesis-supportive vials (Fig. 4A; P , 0.001). Singly and doubly
labeled acetate accumulated in these vials to levels above those
in vials without the addition of A. ruminis 190A4, indicating
CO2 fixation activity of A. ruminis 190A4 in ruminal contents
FIG. 4. Hydrogen and methane concentrations over time in vials with ruminal contents incubated with alfalfa and 100% N2. Reaction mixtures contained 9
ml of ruminal contents, with or without 5 mM BES, 0.82 mmol of NaH13CO3,
A. ruminis 190A4 inoculum, 0.38 g of alfalfa, and other reagents as indicated in
Materials and Methods. When added, the final concentration of A. ruminis was
4.1 3 108 CFU/ml. Symbols: open circles, with BES; closed circles, with BES and
added A. ruminis 190A4; open triangles, without BES and without addition of
A. ruminis 190A4; closed triangles, without BES and with added A. ruminis
190A4. Each point represents the mean 6 SEM for three determinations. Standard errors were plotted but are too small to be visible on the graph.
3434
LEVAN ET AL.
APPL. ENVIRON. MICROBIOL.
TABLE 2. [13C]acetate accumulation in ruminal contents
incubated with alfalfa and 100% N2a
Addition to ruminal contents
BES
1
2
Mean concn (mmol) 6 SEM (n 5 3)
A. ruminis 190A4
(CFU/ml)
[1- or 2-13C]acetatecarbon
[U-13C]acetatecarbon
4.1 3 108
None
4.1 3 108
None
0.35 6 0.008b
0.17 6 0.008c
0.13 6 0.002
0.14 6 0.004
0.08 6 0.000b
0.04 6 0.002c
0.04 6 0.002
0.03 6 0.002
a
Reaction mixtures were as described in the legend to Fig. 4.
Means for BES treatment and 13C-labeling pattern with different superscripts are different (P , 0.001).
b,c
DISCUSSION
In this study, we have demonstrated that reductive acetogenic bacteria are inhabitants of the rumen ecosystem yet have
negligible endogenous H2/CO2-consuming activity. Reductive
acetogenic activity was enhanced in rumen-like incubations
when (i) an axenic culture of the rumen acetogen A. ruminis
190A4 was added under conditions of H2 excess or (ii) methanogenesis was selectively inhibited by BES and A. ruminis
190A4 was added to incubations with a limiting concentration
of H2. These data, in addition to those from pure-culture H2
threshold studies, confirm that ruminal methanogenic bacteria
limit reductive acetogenesis by lowering the H2 partial pressure
TABLE 3. Thresholds for hydrogen of selected
H2-consuming bacteria
Microorganism
A. ruminis 139B
A. ruminis 190A4
Methanogen 10-16B
S. termitida
A. woodii
Incubation
(temp [°C])
Gas composition
No. of
determinations
Mean H2
(ppm)a 6
SEM
1 (38)
1 (38)
2
1 (38)
1 (38)
2
1 (38)
1 (38)
1 (30)
1 (30)
2
1 (30)
1 (30)
2
H2-N2-CO2b
N2-CO2c
N2-CO2
H2-N2-CO2
N2-CO2
N2-CO2
H2-N2-CO2
N2-CO2
H2-N2-CO2
N2-CO2
N2-CO2
H2-N2-CO2
N2-CO2
N2-CO2
33
18
4d
34
13
4d
32
NDe
20
15
4d
33
17
4d
4,660 6 39
147 6 15
39 6 3
3,830 6 69
68 6 22
41 6 1
126 6 4
ND
871 6 88
1,200 6 95
12 6 1
362 6 9
328 6 14
35 6 3
a
Gas-phase concentration at the end of incubation. To convert to micromolar
H2 in the liquid phase, multiply parts per million of H2 by 7.62 3 1024 and 7.36 3
24
10 for tubes incubated at 30 and 38°C, respectively (45).
b
1.2:75.2:23.6 (vol%).
c
80:20 (vol%).
d
Analyzed for H2 immediately after initial pressurization with N2-CO2.
e
ND, not determined.
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ceived BES but no added A. ruminis 190A4, suggesting minimal nonmethanogenic H2-consuming activity in ruminal contents (Fig. 4A). In these vials, H2 consumption finally exceeded
production after 27 h of incubation, indicating increased H2
consumption by, presumably, endogenous H2/CO2-supported
acetogenic bacteria or decreased production of H2 from the
alfalfa fermentation. Increased H2 consumption may be related to an increase in population density of endogenous H2/CO2consuming acetogenic bacteria during the fermentation. H2/
CO2-consuming acetogenic bacteria were not enumerated in
ruminal contents at the time of this experiment but were previously found to be present at a density of 3.5 3 101 to 2.6 3
105 cells/ml for the same animals fed a high-forage diet (Fig.
1A). All values in Fig. 4 represent accumulation of fermentation products under a 100% N2 gas phase and are not confirmed to be H2-dependent fixation products since it was not
possible to have a control incubation in which the alfalfa fermentation did not produce H2.
Pure-culture H2 threshold studies. Competition for H2 can
be partially explained by the threshold model, which states that
the successful organism keeps the H2 partial pressure below
the level necessary to allow H2 oxidation by competitors. For
this reason, hydrogen threshold values for selected acetogens
and a methanogen were determined (Table 3). The H2 threshold concentrations for A. ruminis 190A4 and the methanogen
were consistent with the equilibrium concentrations found in in
vitro incubations with an alfalfa fermentation providing H2 in
the presence and absence of BES, respectively (Fig. 4A). When
S. termitida was incubated under N2-CO2, H2 was produced to
a level of 1,200 ppm. It appears that S. termitida produces H2
to a level near its threshold. As with S. termitida, A. woodii can
produce H2 (328 ppm) up to its threshold level. Approximately
40 ppm of H2 was found in all inoculated tubes analyzed just
after initial pressurization with N2-CO2. This value is at most
only 35% of the lowest threshold value presented. In incubated, uninoculated tubes pressurized with N2-CO2, there was
no abiological production of H2 (data not shown).
below the minimum level necessary for H2 consumption by a
ruminal acetogen, A. ruminis 190A4.
H2/CO2-supported acetogenic bacteria in the rumen were
enumerated (Fig. 1A and B) and found to be present at concentrations greater than those found in the feed and water
(31a). Bryant suggested that the number of a given species
present in the rumen compared to its numbers in the feed and
water consumed is probably the best measure of whether an
organism is a true rumen microorganism (8). A large variability
was observed within duplicate enrichments from animals 05,
134, 6305, and 69, which was believed to be due to sample
variation instead of the MPN technique, since good repeatability was associated with the latter (31a). Leedle and Greening
found H2/CO2-utilizing acidogenic bacteria in the rumens of
steers fed a high-forage (3.9 3 108 cells per g of ruminal contents) or a high-grain (8.7 3 108 cells per g of ruminal contents) diet (30). In contrast, we found H2/CO2-supported ruminal acetogenic bacteria at a concentration at least 1,000-fold
lower than that found by Leedle and Greening (30). This discrepancy could be explained by sample variation due to a rumen sample obtained via stomach tube versus through a cannula (30) or an overestimation of H2/CO2-consuming acidogens
due to enumeration via bromocresol green-staining colonies.
We found that beef cows fed a hay diet supported a greater
population density of ruminal reductive acetogenic bacteria
than did steers fed a finishing diet. Some of the determinants
affecting the population density of H2/CO2-consuming ruminal
acetogenic bacteria may be the presence of alternate energy
sources in the hay diet, inhibition by monensin in the highgrain diet, and/or lower rumen pH with the high-grain diet.
The rumen pH of animals fed the high-grain diet (,6.0) was
lower than that found for animals fed the high-forage diet
(,6.5) because starch is a readily fermentable substrate (3).
H2/CO2-consuming acetogenic bacteria have pH optima close
to 7.0. Optimal pHs for A. ruminis and Eubacterium limosum
are pH 6.8 and 7.2, respectively; therefore, a lower rumen pH
would likely be inhibitory to the growth of acetogenic bacteria
(22, 30). The lack of H2/CO2-supported acetogenic bacteria in
enrichments from high-grain diet rumen samples done in pH
6.1 medium support this hypothesis. Also, monensin disrupts
VOL. 64, 1998
3435
A. ruminis 190A4 maintained H2 concentrations of approximately 400 and 4,800 ppm, respectively (Fig. 4), which are similar to their H2 thresholds. This finding demonstrated that
ruminal methanogenic bacteria limited acetogenesis by lowering the H2 partial pressure to a level insufficient for H2 utilization by A. ruminis 190A4. This observation agrees well with
our understanding of methanogenesis as the predominant H2
sink in the rumen (26, 27). Redirection of ruminal H2 disposal
seems to require a strategy for compromising H2 consumption
by ruminal methanogens and selection of a ruminal acetogen
with a H2-scavenging ability approaching that of ruminal methanogens. Failure of an alternative H2 disposal strategy to
achieve equally low ruminal in situ H2 concentrations could be
deleterious to the thermodynamics of interspecies H2 transfer
and, hence, degradative activity of ruminal fermentative bacteria.
In summary, the coexistence of methanogenic and reductive
acetogenic bacteria in the rumen suggests that the acetogens
grow on substrates other than H2 and CO2 (i.e., noncompetitive substrates such as organic compounds) in situ or there is
an abundance of competitive substrates (i.e., H2) in the rumen
(33, 37) due to diurnal fluctuations of H2 and/or juxtapositioning between H2-producing and H2-consuming microorganisms
(3, 18, 38, 42).
ACKNOWLEDGMENTS
Funds for this research were provided by the College of Agricultural
and Life Sciences and a generous grant from the Upjohn Company,
Kalamazoo, Mich.
We thank Q. Liu for statistical assistance and Kris Scheller for
providing help with animal management. Enthusiastic technical support was provided by Barbara Myers and Conrad Vispo.
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