Fermentation of Peptides by Bacteroides ruminicola B(1)4

The maximum growth rate of Bacteroides ruminicola B(1)4 was significantly improved when either Trypticase or acetate and C(4)-C(5) fatty acids were added to defined medium containing macrominerals, microminerals, vitamins, hemin, cysteine hydrochloride, and glucose. The organism was unable to grow with peptides as the sole energy source, but growth yields from glucose were significantly improved when Trypticase was added to batch cultures containing basal medium, acetate, and C(4)-C(5) volatile fatty acids. During periods of rapid growth, very little peptide was deaminated to ammonia, but after growth ceased there was a linear increase in ammonia. Fifteen grams of Trypticase per liter resulted in maximum ammonia production. In glucose-limited chemostats, ammonia production from peptides was inversely proportional to the dilution rate, and 87% of the variation in ammonia production could be explained by retention time in the culture vessel. Chemostats receiving Trypticase had higher theoretical maximum growth yields and lower maintenance energy expenditures than similar cultures not receiving peptide. Cells from the Trypticase cultures contained more carbohydrate, and this difference was most evident at rapid dilution rates. When corrections were made for cell composition and the amount of peptides that were fermented, it appeared that peptide carbon skeletons could be used for maintenance energy. B. ruminicola B(1)4 was unable to grow on peptides alone because it was unable to utilize peptides at a fast enough rate to meet its maintenance requirement.     

The effect of carbohydrates on the expression of the Prevotella ruminicola 1,4-β-D-endoglucanase ☆

The β-1,4-endoglucanase of the ruminai bacterium, Prevotella ruminicola B₁4, hydrolysed carboxymethylcellulose and barley glucan but not xylan or mannan. Endoglucanase activity was present in 88- and 82-kDa proteins, and there was at least a 20-fold variation in endoglucanase activity when P. ruminicola B₁4 was grown on different sugars. The highest activities were observed with mannose, cellobiose or xylose and little activity was observed with sucrose, arabinose or rhamnose. P. ruminicola B₁4 also had significant xylanase and mannanase activities, but these activities were present in proteins that had lower molecular masses than the endoglucanase and these proteins did not cross-react with antibody made against the endoglucanase. Mannanase activity has a similar pattern of expression to the endoglucanase, while the xylanase was not induced or repressed by the same sugars or combinations of sugars. The xylanase activity was greatest when xylan was the energy source for growth, but xylose was a very poor inducer of xylanase activity.     

De Novo Synthesis of Amino Acids by the Ruminal Bacteria Prevotella bryantii B14, Selenomonas ruminantium HD4, and Streptococcus bovis ES1

The influence of peptides and amino acids on ammonia assimilation and de novo synthesis of amino acids by three predominant noncellulolytic species of ruminal bacteria, Prevotella bryantii B₁4, Selenomonas ruminantium HD4, and Streptococcus bovis ES1, was determined by growing these bacteria in media containing ¹⁵NH₄Cl and various additions of pancreatic hydrolysates of casein (peptides) or amino acids. The proportion of cell N and amino acids formed de novo decreased as the concentration of peptides increased. At high concentrations of peptides (10 and 30 g/liter), the incorporation of ammonia accounted for less than 0.16 of bacterial amino acid N and less than 0.30 of total N. At 1 g/liter, which is more similar to peptide concentrations found in the rumen, 0.68, 0.87, and 0.46 of bacterial amino acid N and 0.83, 0.89, and 0.64 of total N were derived from ammonia by P. bryantii, S. ruminantium, and S. bovis, respectively. Concentration-dependent responses were also obtained with amino acids. No individual amino acid was exhausted in any incubation medium. For cultures of P. bryantii, peptides were incorporated and stimulated growth more effectively than amino acids, while cultures of the other species showed no preference for peptides or amino acids. Apparent growth yields increased by between 8 and 57%, depending on the species, when 1 g of peptides or amino acids per liter was added to the medium. Proline synthesis was greatly decreased when peptides or amino acids were added to the medium, while glutamate and aspartate were enriched to a greater extent than other amino acids under all conditions. Thus, the proportion of bacterial protein formed de novo in noncellulolytic ruminal bacteria varies according to species and the form and identity of the amino acid and in a concentration-dependent manner.     

Relationship between Intracellular Phosphate, Proton Motive Force, and Rate of Nongrowth Energy Dissipation (Energy Spilling) in Streptococcus bovis JB1

When the rate of glucose addition to nongrowing Streptococcus bovis cell suspensions was increased, the fermentation was homolactic, fructose-1,6-diphosphate (FDP) increased, intracellular inorganic phosphate (P_i) declined, and the energy-spilling rate increased. ATP and ADP were not significantly affected by glucose consumption rate, but the decrease in P_i was sufficient to cause an increase in the free energy of ATP hydrolysis (ΔG′p). The increase in ΔG′p was correlated with an increase in proton motive force (Δp). S. bovis continuous cultures (dilution rate of 0.65 h⁻¹) that were provided with ammonia as the sole nitrogen source also had high rates of lactate production and energy spilling. When Trypticase was added as a source of amino acids, lactate production decreased; a greater fraction of the glucose was converted to acetate, formate, and ethanol; and the energy-spilling rate decreased. Trypticase also caused a decrease in FDP, an increase in P_i, and a decrease in Δp. The change in Δp could be explained by P_i-dependent changes in the ΔG′p. When P_i declined, ΔG′p and Δp increased. The ratio of ΔG′p to Δp (millivolt per millivolt) was always high (>4) at low rates of energy spilling but declined when the energy-spilling rate increased. Based on these results, it appears that Δp and the energy-spilling rate are responsive to fluctuations in the intracellular P_i concentration.     

Breakdown of different peptides byPrevotella (Bacteroides) ruminicola and mixed microorganisms from the sheep rumen

Several di-, tri-, and oligopeptides were incubated individually in vitro with rumen fluid from two sheep receiving a mixed grass hay/concentrate diet and with washed cells ofPrevotella (formerlyBacteroides)ruminicola M384 andP. ruminicola B₁4. The rates of breakdown of most peptides were similar in the rumen fluid from the two sheep. Acidic and proline-containing peptides tended to be more slowly degraded than neutral or basic peptides. The dipeptide at the N-terminus of higher peptides was observed as an early product of hydrolysis, confirming that a dipeptidyl aminopeptidase type of activity was present. The relative rates of breakdown of dipeptides byP. ruminicola were different from that of rumen fluid, but the hydrolysis of higher peptides followed a similar pattern, and dipeptides from the N-terminus were detected as early products.     

Interrupted catalytic domain structures in xylanases from two distantly related strains of Prevotella ruminicola

Two xylanases from the rumen anaerobic bacterium Prevotella ruminicola were found to possess highly unusual structures in which family 10 catalytic domains are interrupted by unrelated sequences. XynC from P. ruminicola B₁4 carries a 160 amino-acid insertion, while a P. ruminicola D31d xylanase carries an unrelated region of 280 amino acids, containing an imperfect 130 amino-acid duplication. Both regions of family 10 similarity were shown to be essential for activity of the D31d enzyme.     

INTERACTION OF NITROGEN FIXATION AND PHOSPHORUS LIMITATION IN APHANIZOMENON FLOS-AQUAE (CYANOPHYCEAE)1

The effect of simultaneous nitrogen fixation and phosphorus limitation on the physiological adaptation and growth performance of Aphanizomenon flos-aquae (L.) Ralfs PCC 7905 was studied in continuous culture. In the absence of ammonia, N₂ fixation occurred and the maximum growth rate (as determined in diluted batch cultures) was lower. However, no distinction could be made between the steady-state N uptake rates (based on cellular N contents) of N₂-fixing cells and cells grown with ammonia. At the higher dilution rates, the residual P concentration increased with increasing dilution rate, more so under N₂-fixing conditions, compared to the cultures grown in the presence of ammonia. More generally, the yield of biomass per consumed P, as the biomass concentration itself, decreased with increasing dilution rate, and both were lower under N₂-fixing conditions. The restricted biomass production under N₂-fixing conditions suggests that reduction of N loading may benefit lake restoration projects. The influence of N₂-fixation on the severity of P limitation is discussed in terms of metabolic control analysis. From the increase of the residual P concentration on switching from ammonium to N₂-fixing conditions, it is deduced that under N₂-fixing and P-limited conditions, control of growth is shared by N and P metabolism.     

Influence of Environmental Factors and Medium Composition on Vibrio gazogenes Growth and Prodigiosin Production

Vibrio gazogenes ATCC 29988 growth and prodigiosin synthesis were studied in batch culture on complex and defined media and in chemostat cultures on defined medium. In batch culture on complex medium, a maximum growth rate of 0.75 h⁻¹ and a maximum prodigiosin concentration of 80 ng of prodigiosin · mg of cell protein⁻¹ were observed. In batch culture on defined medium, maximum growth rates were lower (maximum growth rate, 0.40 h⁻¹), and maximum prodigiosin concentrations were higher (1,500 ng · mg of protein⁻¹). In batch culture on either complex or defined medium, growth was characterized by a period of logarithmic growth followed by a period of linear growth; on either medium, prodigiosin biosynthesis was maximum during linear growth. In batch culture on defined medium, the initial concentration of glucose optimal for growth and pigment production was 3.0%; higher levels of glucose suppressed synthesis of the pigment. V. gazogenes had an absolute requirement for Na⁺; optimal growth occurred in the presence of 100 mM NaCl. Increases in the concentration of Na⁺ up to 600 mM resulted in further increases in the concentration of pigment in the broth. Prodigiosin was synthesized at a maximum level in the presence of inorganic phosphate concentrations suboptimal for growth. Concentrations of KH₂PO₄ above 0.4 mM caused decreased pigment synthesis, whereas maximum cell growth occurred at 1.0 mM. Optimal growth and pigment production occurred in the presence of 8 to 16 mg of ferric ion · liter⁻¹, with higher concentrations proving inhibitory to both growth and pigment production. Both growth and pigment production were found to decrease with increased concentrations of p-aminobenzoic acid. The highest specific concentration of prodigiosin (3,480 ng · mg protein⁻¹) was observed in chemostat cultures at a dilution rate of 0.057 h⁻¹. The specific rate of prodigiosin production at this dilution rate was approximately 80% greater than that observed in batch culture on defined medium. At dilution rates greater than 0.057 h⁻¹, the concentration of cells decreased with increasing dilution rate, resulting in a profile comparable to that expected for linear growth kinetics. No explanation could be found for the linear growth profiles obtained for both batch and chemostat cultures.     

Enrichment and isolation of a ruminal bacterium with a very high specific activity of ammonia production.

When mixed ruminal bacteria were inoculated into semicontinuous cultures (25% transfer every other day) containing lactate, dulcitol, pectin, or xylose and Trypticase (1 g/liter) as the sole nitrogen source, the specific activity of ammonia production increased. The greatest enrichment was observed with lactate and xylose, and in these cases the specific rate of ammonia production was eightfold higher than that of the ruminal fluid control (approximately 35 nmol of ammonia per mg of protein per min). Isolates with different morphologies were obtained from each of the enrichments, but in no case did the specific activity of any isolate exceed that of the mixed ruminal bacteria. If Trypticase (15 g/liter) was used as the only energy and nitrogen source, there was an even greater increase in ammonia production, and two monensin-sensitive bacteria, a Peptostreptococcus species and a Clostridium species, were obtained. The Peptostreptococcus species was unable to grow on any of 25 carbohydrate or carbohydrate derivatives tested; but the Clostridium species was able to use glucose, maltose, fructose, cellobiose, trehalose, sorbitol, and salicin as energy sources. Neither organism was able to grow in the absence of an amino acid source, but growth rates on Trypticase were greater than 0.35/h. The specific activities of ammonia production were 346 and 427 nmol/mg of protein per min for strains of Peptostreptococcus and Clostridium, respectively. Megasphaera elsdenii and Bacteroides ruminicola, previously isolated ruminal ammonia producers, had specific activities of only 11 and 19 nmol of ammonia per mg of protein per min, respectively. The most probable number of Clostridium species in ruminal fluid was less than 10(3)/ml, but the Peptostreptococcus species was present at 10(8)/ml.(ABSTRACT TRUNCATED AT 250 WORDS)     

Formation of polysaccharide depolymerase and glycoside hydrolase enzymes byBacteroides ruminicola subsp.ruminicola grown in batch and continuous culture

The activity of ten polysaccharide depolymerase and glycoside hydrolase enzymes was monitored inBacteroides ruminicola subsp.ruminicola throughout the growth cycle and over a range of dilution rates in carbon-limited continuous (chemostat) culture. The enzymes were principally cell associated, and the specific activities increased throughout the growth cycle to reach maximum levels in the late exponential and stationary growth phases. In chemostat-grown cells the activities were growth rate dependent and were highest at the lowest dilution rates examined (0.025/h), but remained constant over a wide range of growth rates (D=0.05–0.15/h). The specific activities were lower in cells with a generation time of 3 h (D=0.225/h). The major metabolites formed from xylose, in batch and continuous culture, were lactic, acetic, and succinic acids, with traces (1%–2% of total acid production) of branched and straight-chain C₃–C₅ volatile fatty acids. The proportions of the metabolites produced varied with the stage and rate of growth.     

Enrichment and isolation of a ruminal bacterium with a very high specific activity of ammonia production

When mixed ruminal bacteria were inoculated into semicontinuous cultures (25% transfer every other day) containing lactate, dulcitol, pectin, or xylose and Trypticase (1 g/liter) as the sole nitrogen source, the specific activity of ammonia production increased. The greatest enrichment was observed with lactate and xylose, and in these cases the specific rate of ammonia production was eightfold higher than that of the ruminal fluid control (approximately 35 nmol of ammonia per mg of protein per min). Isolates with different morphologies were obtained from each of the enrichments, but in no case did the specific activity of any isolate exceed that of the mixed ruminal bacteria. If Trypticase (15 g/liter) was used as the only energy and nitrogen source, there was an even greater increase in ammonia production, and two monensin-sensitive bacteria, a Peptostreptococcus species and a Clostridium species, were obtained. The Peptostreptococcus species was unable to grow on any of 25 carbohydrate or carbohydrate derivatives tested; but the Clostridium species was able to use glucose, maltose, fructose, cellobiose, trehalose, sorbitol, and salicin as energy sources. Neither organism was able to grow in the absence of an amino acid source, but growth rates on Trypticase were greater than 0.35/h. The specific activities of ammonia production were 346 and 427 nmol/mg of protein per min for strains of Peptostreptococcus and Clostridium, respectively. Megasphaera elsdenii and Bacteroides ruminicola, previously isolated ruminal ammonia producers, had specific activities of only 11 and 19 nmol of ammonia per mg of protein per min, respectively. The most probable number of Clostridium species in ruminal fluid was less than 10(3)/ml, but the Peptostreptococcus species was present at 10(8)/ml.(ABSTRACT TRUNCATED AT 250 WORDS)     

Kinetic study of Lactococcus lactis strains (SLT6 and SLT10) growth on papain-hydrolysed whey

The effect of controlled whey hydrolysis by papain on growth of two lactic acid bacteria isolated from artisanal Leben: Lactococcus lactis var. diacetylactis (SLT6 and SLT10) was investigated. The higher biomass and maximum specific growth rate (μ _max) were obtained after 30 min of hydrolysis. HPLC analysis of peptides showed that whey hydrolysis reduced the amount of peptides of MW > 400 Da and increased those peptides of MW < 400 Da. The two studied strains exhibited different peptide requirements. The pH-controlled batch cultures in 30 min hydrolysed whey followed the Monod kinetic for growth and for lactate production. The values of the key kinetic constants were: maximum specific growth rate (μ _max), 1.08 and 0.56 h^?1; yield biomass on lactose (Y _x/s), 0.20 and 0.18 g g^?1 and saturation constant K _s, 4.2 and 2.8 g L^?1 for SLT6 and SLT10, respectively. When compared with batch experimental data, the model provided good predictions for growth, lactose utilisation and lactate production profiles.     

Maintenance energy: a general model for energy-limited and energy-sufficient growth

The new model proposed to account for the energy requirement for growth includes both a constant maintenance energy term (m) independent of the specific growth rate and a term (m′) which decreases linearly with increase in specific growth rate and becomes zero at the maximum specific growth rate. The available data for testing the model do not deviate significantly from the relations predicted. Consistent values of the maximum growth yield (Y _G) can be derived, irrespective of whether the cultures are energy limited or energy sufficient. Attention is drawn to the possibility that the constant maintenance energy term may be estimated from the maximum specific growth rate.     

Effect of mercuric ion on the growth, photosynthesis, and nitrogenase activity of Anabaena inaequalis.

Maintenance energy expenditures were mesured for five rumen bacteria, Selenomonas ruminantium, Butyrivibrio fibrisolvens, Bacteroides ruminicola, Megasphaera elsdenii, and Streptococcus bovis, by using a complex medium with glucose as the carbon source. Large differences (as high as 8.5-fold) in maintenance energy expenditures were seen among these bacteria. The suggestion is made that maintenance requirements could be a significant determinant of bacterial competition in the rumen. Theoretical maximum growth yields, calculated from double reciprocal plots of yield versus dilution rate, were compared to theoretical Y_ATP^max values in order to estimate minimum molar adenosine 5′-triphosphate yields from glucose for each bacterium. Results showed that relative yield among the bacteria was growth rate dependent. At high dilution rates, both S. ruminantium and S. bovis produced lactate as their principal fermentation product. At lower dilution rates very little lactate was formed and growth yields increased. Acetate and ethanol were the predominant fermentation products of S. bovis at low dilution rates. Other workers have shown that S. ruminantium produces acetate and propionate at low growth rates.     

Isolation and Characterization of Proteolytic Ruminal Bacteria from Sheep and Goats Fed the Tannin-Containing Shrub Legume Calliandra calothyrsus

Tannins in forages complex with protein and reduce the availability of nitrogen to ruminants. Ruminal bacteria that ferment protein or peptides in the presence of tannins may benefit digestion of these diets. Bacteria from the rumina of sheep and goats fed Calliandra calothyrsus (3.6% N and 6% condensed tannin) were isolated on proteinaceous agar medium overlaid with either condensed (calliandra tannin) or hydrolyzable (tannic acid) tannin. Fifteen genotypes were identified, based on 16S ribosomal DNA-restriction fragment length polymorphism analysis, and all were proteolytic and fermented peptides to ammonia. Ten of the isolates grew to high optical density (OD) on carbohydrates (glucose, cellobiose, xylose, xylan, starch, and maltose), while the other isolates did not utilize or had low growth on these substrates. In pure culture, representative isolates were unable to ferment protein that was present in calliandra or had been complexed with tannin. One isolate, Lp1284, had high protease activity (80 U), a high specific growth rate (0.28), and a high rate of ammonia production (734 nmol/min/ml/OD unit) on Casamino Acids and Trypticase Peptone. Phylogenetic analysis of the 16S ribosomal DNA sequence showed that Lp1284 was related (97.6%) to Clostridium botulinum NCTC 7273. Purified plant protein and casein also supported growth of Lp1284 and were fermented to ammonia. This is the first report of a proteolytic, ammonia-hyperproducing bacterium from the rumen. In conclusion, a diverse group of proteolytic and peptidolytic bacteria were present in the rumen, but the isolates could not digest protein that was complexed with condensed tannin.     

Fermentation of peptides and amino acids by a monensin-sensitive ruminal Peptostreptococcus.

A monensin-sensitive ruminal peptostreptococcus was able to grow rapidly (growth rate of 0.5/h) on an enzymatic hydrolysate of casein, but less than 23% of the amino acid nitrogen was ever utilized. When an acid hydrolysate was substituted for the enzymatic digest, more than 31% of the nitrogen was converted to ammonia and cell protein. Coculture experiments and synergisms with peptide-degrading strains of Bacteroides ruminicola and Streptococcus bovis indicated that the peptostreptococcus was unable to transport certain peptides or hydrolyze them extracellularly. Leucine, serine, phenylalanine, threonine, and glutamine were deaminated at rates of 349, 258, 102, 95, and 91 nmol/mg of protein per min, respectively. Deamination rates for some other amino acids were increased when the amino acids were provided as pairs of oxidized and reduced amino acids (Stickland reactions), but these rates were still less than 80 nmol/mg of protein per min. In continuous culture (dilution rate of 0.1/h), bacterial dry matter and ammonia production decreased dramatically at a pH of less than 6.0. When dilution rates were increased from 0.08 to 0.32/h (pH 7.0), ammonia production increased while production of bacterial dry matter and protein decreased. These rather peculiar kinetics resulted in a slightly negative estimate of maintenance energy and could not be explained by a change in fermentation products. Approximately 80% of the cell dry matter was protein. When corrections were made for cell composition, the yield of ATP was higher than the theoretical maximum value. It is possible that mechanisms other than substrate-level phosphorylation contributed to the energetics of growth.     

Fermentation of peptides and amino acids by a monensin-sensitive ruminal Peptostreptococcus

A monensin-sensitive ruminal peptostreptococcus was able to grow rapidly (growth rate of 0.5/h) on an enzymatic hydrolysate of casein, but less than 23% of the amino acid nitrogen was ever utilized. When an acid hydrolysate was substituted for the enzymatic digest, more than 31% of the nitrogen was converted to ammonia and cell protein. Coculture experiments and synergisms with peptide-degrading strains of Bacteroides ruminicola and Streptococcus bovis indicated that the peptostreptococcus was unable to transport certain peptides or hydrolyze them extracellularly. Leucine, serine, phenylalanine, threonine, and glutamine were deaminated at rates of 349, 258, 102, 95, and 91 nmol/mg of protein per min, respectively. Deamination rates for some other amino acids were increased when the amino acids were provided as pairs of oxidized and reduced amino acids (Stickland reactions), but these rates were still less than 80 nmol/mg of protein per min. In continuous culture (dilution rate of 0.1/h), bacterial dry matter and ammonia production decreased dramatically at a pH of less than 6.0. When dilution rates were increased from 0.08 to 0.32/h (pH 7.0), ammonia production increased while production of bacterial dry matter and protein decreased. These rather peculiar kinetics resulted in a slightly negative estimate of maintenance energy and could not be explained by a change in fermentation products. Approximately 80% of the cell dry matter was protein. When corrections were made for cell composition, the yield of ATP was higher than the theoretical maximum value. It is possible that mechanisms other than substrate-level phosphorylation contributed to the energetics of growth.     

Combinatorial Cellulose-Bound Peptide Libraries: Screening Tools for the Identification of Peptides That Bind Ligands with Predefined Specificity

We describe the synthesis of structurally different types of combinatorial peptide libraries on continuous cellulose membrane supports. These libraries consisting of tens of millions of different peptides were screened for their ability to bind given ligands such as the monoclonal antibody Tab2, transforming growth factor-β (TGFβ), nickel(II) (Ni²⁺), and technetium-99m (^99mTc). We were thus able to detect the linear transforming growth factor-α (TFGα) epitope SHFND recognized by Tab2. Other peptides that also bound Tab2 were identified within the same experiment. A first screening step for identification of peptide mixtures that bind to other ligands of biological interest is shown for peptide mixtures XB₁XB₂XX (B = defined amino acid, X = randomized position) that bind to Ni²⁺ and ^99mTc. A combinatorial linear all L- or all D-library XXB₁B₂XX and two libraries conformationally restrained either via a disulfide bridge between a C-and an N-terminal cysteine [cyclo(C¹-C⁸)-C¹XXB₁B₂XXC⁸] or an amide bond between the alpha amino group of the N-terminus and the gamma carboxyl group of a C-terminal glutamic acid [cyclo(X¹-E⁷)-X¹XB₁B₂XXE⁷] were screened with transforming growth factor-β, resulting in structurally different peptides mixtures that bound to this ligand. The results obtained indicate that chemically different types of cellulose-bound combinatorial libraries can be prepared easily, allowing the rapid and inexpensive screening of millions of peptides for selection of single molecules with predefined specificity that bind to given ligands such as proteins, metals, nucleic acids, and other molecules of biological interest.     

Synergism in Degradation and Utilization of Intact Forage Cellulose, Hemicellulose, and Pectin by Three Pure Cultures of Ruminal Bacteria

Pure cultures of ruminal bacteria characterized as using only a single forage polysaccharide (Fibrobacter succinogenes A3c, cellulolytic; Bacteroides ruminicola H2b, hemicellulolytic; Lachnospira multiparus D15d, pectinolytic) were inoculated separately and in all possible combinations into fermentation tubes containing orchard grass as the sole substrate. Fermentations were run to completion, and then cultures were analyzed for digestion of cellulose plus degradation and utilization of hemicellulose and pectin. Addition of the noncellulolytic organisms, in any combination, to the cellulolytic organism F. succinogenes had little effect on overall cellulose utilization. F. succinogenes degraded but could not utilize hemicellulose; however, when it was combined with B. ruminicola, total utilization of hemicellulose increased markedly over that by B. ruminicola alone. L. multiparus was inactive in hemicellulose digestion, alone or in any combination. Although unable to degrade and utilize purified pectin, B. ruminicola degraded and utilized considerable quantities of the forage pectin. In contrast, L. multiparus was very active against purified pectin, but had extremely limited ability to degrade and utilize pectin from the intact forage. Both degradation and utilization of forage pectin increased when F. succinogenes was combined with B. ruminicola. Sequential addition of two cultures, allowing one to complete its fermentation before adding the second, was used to study synergism between cultures on forage pectin digestion. In general, synergistic effects did not appear to be related to a particular sequence of utilization. The ability of F. succinogenes to degrade and B. ruminicola to degrade and utilize forage pectin contradicts both previous and present data obtained with purified pectin. Thus, isolation and characterization of ruminal bacteria on purified substrates may be misleading with regard to their role in the overall ruminal fermentation.