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Abstract

When a fistulated cow was fed an all forage diet, ruminal pH remained more or less constant (6.7 to 6.9). The ruminal pH of a concentrate-fed cow decreased dramatically in the period soon after feeding, and the pH was as low as 5.45. Mixed ruminal bacteria from the forage-fed cow converted CO2 and H2 to methane, but the ruminal fluid from the concentrate-fed cow did not produce methane. When the pH of the ruminal fluid from the concentrate-fed cow was adjusted to pH 7.0, methane was eventually detected, and the absolute rate constant of methane production was as high as the one observed with ruminal fluid from the forage fed cow (0.32 h−1). Based on the zero-time intercepts of methane production, it appeared that the concentrate-fed cow had fewer methanogens than the forage-fed cow. When the mixed ruminal bacteria were incubated in a basal medium containing 100 mM acetate, methanogenesis was pH-dependent, and no methane was detected at pH values less than 6.0. Because the removal of acetic acid completely reversed the inhibition of methanogenesis, it appeared that volatile fatty acids were causing the pH-dependent inhibition. Based on these results, concentrate diets that lower ruminal pH may provide a practical means of decreasing ruminal methane production.

Rumen, Methanogenesis, pH, Volatile fatty acid

References

[1]

Hungate
R.E.
(
1966
)
The Rumen and Its Microbes
Academic Press
,
New York
.

Google Scholar

OpenURL Placeholder Text

 
[2]

Blaxter
K.L.
(
1962
)
The Energy Metabolism of Ruminants
Hutchinson and Co Ltd
,
London
.

Google Scholar

OpenURL Placeholder Text

 
[3]

Wolin
M.J.
(
1975
)
Interactions between the bacterial species of the rumen
In:
Digestion and Metabolism in the Ruminant
McDonald
I.W.
Warner
A.C.I.
, Eds) pp
134
148
University of New England Publishing Unit
,
Armidale, Australia
.

Google Scholar

OpenURL Placeholder Text

 
[4]

Gottschalk
G.
(
1986
)
Bacterial Metabolism
2nd Edn.
Springer-Verlag
,
New York
.

Google Scholar

OpenURL Placeholder Text

 
[5]

Czerkawski
J.W.
(
1986
)
An Introduction to Rumen Studies
Pergamon Press
,
New York
.

Google Scholar

OpenURL Placeholder Text

 
[6]

Mackie
R.I.
Gilchrist
F.M.C.
Robberts
A.M.
Hannah
P.E.
Schwartz
H.M.
(
1978
)
Microbiological and chemical changes in the rumen during the stepwise adaptation of sheep to high concentrate diets
J. Agric. Sci., Camb.
,
90
,
241
254
.

Google Scholar

Crossref
Search ADS

 
[7]

Cotta
M.A.
Russell
J.B.
(
1982
)
Effect of peptides and amino acids on efficiency of rumen bacterial protein synthesis in continuous culture
J. Dairy Sci.
,
65
,
226
234
.

Google Scholar

Crossref
Search ADS

 
[8]

Russell
J.B.
Wallace
R.J.
(
1988
)
Energy yielding and consuming reactions
In:
The Rumen Microbial Ecosystem
Hobson
P.N.
, Ed) pp
185
216
Elsevier Science Publishers Ltd
,
London, England
.

Google Scholar

OpenURL Placeholder Text

 
[9]

Hungate
R.E.
Smith
W.
Bauchop
T.
Yu
I.
Rabinowitz
J.C.
(
1970
)
Formate as an intermediate in the bovine rumen fermentation
J. Bacteriol.
,
102
,
389
397
.

Google Scholar

PubMed
OpenURL Placeholder Text

 
[10]

Wolin
M.J.
(
1960
)
A theoretical rumen fermentation balance
J. Dairy Sci.
,
43
,
1349
1452
.

Google Scholar

OpenURL Placeholder Text

 
[11]

Reichl
J.R.
Baldwin
R.L.
(
1975
)
Rumen modeling: Rumen input-output balance models
J. Dairy Sci.
,
58
,
879
890
.

Google Scholar

Crossref
Search ADS
PubMed

 
[12]

van Nevel
C.
Demeyer
D.
Henderickx
H.K.
(
1970
)
Effect of chlorinated methane analogues on methane and propionic acid production in the rumen in vitro
Overdruk Uit: Mededelingen Fakulteit Landbouw-Wetenschappen Gent
,
XXXV
,
(1)
,
145
152
.

Google Scholar

OpenURL Placeholder Text

 
[13]

Wolin
M.J.
Miller
T.L.
(
1988
)
Microbe-microbe interactions
In:
The Rumen Microbial Ecosystem
Hobson
P.N.
, Ed) pp
343
359
Elsevier Science Publishers Ltd
,
London, England
.

Google Scholar

OpenURL Placeholder Text

 
[14]

Burrin
D.G.
Britton
R.A.
(
1986
)
Response to monensin in cattle during subacute acidosis
J. Anim. Sci.
,
63
,
888
893
.

Google Scholar

Crossref
Search ADS
PubMed

 
[15]

Hollowell
C.A.
Wolin
M.J.
(
1965
)
Basis of the exclusion of Escherichia coli from the rumen ecosystem
Appl. Microbiol.
,
13
,
918
924
.

Google Scholar

PubMed
OpenURL Placeholder Text

 
[16]

Wolin
M.J.
(
1969
)
Volatile fatty acids and the inhibition of Escherichia coli growth by rumen fluid
Appl. Microbiol.
,
17
,
83
87
.

Google Scholar

PubMed
OpenURL Placeholder Text

 
[17]

Wallace
R.J.
Falconer
M.L.
Bhargava
P.K.
(
1989
)
Toxicity of volatile fatty acids at rumen pH prevents enrichment of Escherichia coli by sorbitol in rumen contents
Curr. Microbiol.
,
19
,
277
281
.

Google Scholar

Crossref
Search ADS

 
[18]

Jay
J.M.
(
1986
)
Modern Food Microbiology
3rd Edn.
Van Nostrand Reinhold Co
,
New York
.

Google Scholar

OpenURL Placeholder Text

 
[19]

Russell
J.B.
(
1991
)
Resistance of Streptococcus bovis to acetic acid at low pH: Relationship between intracellular pH and anion accumulation
Appl. Environ. Microbiol.
,
57
,
255
259
.

Google Scholar

PubMed
OpenURL Placeholder Text

 
[20]

Russell
J.B.
(
1992
)
Another explanation for the toxicity of fermentation acids at low pH: Anion accumulation versus uncoupling
J. Appl. Bacteriol.
,
73
,
363
370
.

Google Scholar

Crossref
Search ADS

 
[21]

Williams
R.T.
Crawford
R.L.
(
1984
)
Methane production in Minnesota peatlands
Appl. Environ. Microbiol.
,
47
,
1266
1271
.

Google Scholar

PubMed
OpenURL Placeholder Text

 
[22]

Jarrell
K.J.
Sprott
G.D.
(
1983
)
The effects of ionophores and metabolic inhibitors on methanogenesis and energy-related properties of Methanobacterium bryantii
Arch. Biochem. Biophys.
,
225
,
33
41
.

Google Scholar

Crossref
Search ADS
PubMed

 
[23]

Sprott
G.D.
Jarrell
K.J.
(
1984
)
Electrochemical potential and membrane properties of methanogenic bacteria
In:
Microbial Chemoautotrophy
Strohl
W.R.
Tuovinen
O.H.
, Eds) pp
255
273
Ohio State University Press
,
Columbus
.

Google Scholar

OpenURL Placeholder Text

 
[24]

Duxbury
J.M.
Harper
L.A.
Mosier
A.R.
(
1993
)
Contributions of agroecosystems to global climate change
In:
Agricultural Ecosystem Effects on Trace Gases and Global Climate Change
Harper
L.A.
Mosier
A.R.
Duxbury
J.M.
Rolston
D.E.
, Eds) pp
1
18
American Society of Agronomy, Inc., Crop Science Society of America, Inc., Soil Science Society of America, Inc
,
Denver, CO
.

Google Scholar

OpenURL Placeholder Text

 
[25]

Burke
L.M.
Lashof
D.A.
(
1990
)
Greenhouse gas emissions related to agriculture and land-use practices
In:
Impact of Carbon Dioxide, Trace Gases, and Climate Change in Global Agriculture
Kimball
B.A.
Rosenberg
N.J.
Allen
L.H.
Jr.
, pp
27
44
American Society of Agronomy, Inc., Crop Science Society of America, Inc., Soil Science Society of America, Inc
,
Anaheim, CA
.

Google Scholar

OpenURL Placeholder Text

 
[26]

Lerner
J.
Matthews
E.
Fung
I.
(
1988
)
Methane emission from animals: a global high-resolution data base
Global Biogeochemical Cycles
,
2
,
139
156
.

Google Scholar

Crossref
Search ADS

 
[27]

Johnson
K.A.
Johnson
D.E.
(
1995
)
Methane emissions from cattle
J. Anim. Sci.
,
73
,
2483
2492
.

Google Scholar

Crossref
Search ADS
PubMed

 
[28]

Jarvis
S.C.
Pain
B.F.
(
1994
)
Greenhouse gas emissions from intensive livestock systems: their estimation and technologies for reduction
Climatic Change
,
27
,
27
38
.

Google Scholar

Crossref
Search ADS

 
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© 1996 Federation of European Microbiological Societies. Published by Elsevier Science B.V.
Issue Section:
Research article
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