羊草茎在奶牛瘤胃中降解特性及其对食糜纤维分解菌数量的影响

本试验旨在研究羊草茎降解特性和紧密吸附于茎的3种主要纤维分解菌的动态变化。选用羊草茎为试验材料,将其纵切6份后装入尼龙袋投入瘤胃中,分别在6,12,24,48和72 h取出,利用扫描电子显微镜观察超微结构变化;取粉碎后羊草茎进行尼龙袋试验,分别在0.5,2,6、12,24,48和72 h取出,测定不同时间点中性洗涤纤维(neutral detergent fiber,NDF)降解率和吸附在茎中3种主要纤维分解菌的数量变化。结果表明,薄壁组织和韧皮部可被瘤胃微生物降解,维管束会伴随薄壁组织的降解而发生脱落。羊草茎和食糜不同时间点纤维分解菌数量均为产琥珀酸丝状杆菌>白色瘤胃球菌>黄色瘤胃球菌,茎中产琥珀酸丝状杆菌和黄色瘤胃球菌数量在24 h达峰值,分别为10⁹和10⁵ copy/g羊草茎,白色瘤胃球菌在12 h达峰值,为10⁸ copy/g羊草茎。瘤胃食糜中3种纤维分解菌的数量在24 h内基本处在一个恒定的水平,而羊草茎NDF降解率在72 h内逐渐提高,羊草NDF降解率与瘤胃食糜中3种纤维分解菌数量不同步,这可能与纤维分解菌分泌的酶活力存在滞后有关。     

Ruminal distribution of the cellulolytic bacterium Fibrobacter succinogenes in relation to its phylogenetic grouping

To investigate the ecological importance of the cellulolytic bacterium Fibrobacter succinogenes in fiber digestion, ruminal distribution of F. succinogenes was determined in relation to its phylogenetic grouping. Rumen digesta from wethers and steers fed orchardgrass hay, rice straw or fresh orchardgrass were employed as the materials for the analyses. Orchardgrass hay stem incubated in the rumen was also used. By using total DNA extracted from these materials, population sizes of total F. succinogenes and of four different phylogenetic groups of this species were quantitated through competitive polymerase chain reaction (PCR), and restriction fragment length polymorphism analysis of PCR products targeted the bacterial 16S rDNA. Rumen digesta and ruminally incubated hay stems had a reasonably high population size of F. succinogenes (×10^7?8/g) that was composed of strains belonging to the phylogenetic groups 1 and 3. The relative abundance of each group was different among the samples; group 1 dominated on the ruminally incubated hay stem and in the rumen of wethers fed fresh orchardgrass, while group 3 was major in the rumen of wethers and steers on hay diet. These results suggest that there could be phenotypic differences among the phylogenetic groups of F. succinogenes, and group 1 dominating on hay stem might contribute to rumen fiber digestion more than the other groups.     

Determination of bacteria constituting ruminal fibrolytic consortia developed on orchard grass hay stem

To determine the relationship between Fibrobacter succinogenes and other rumen bacteria, the bacterial community structure on fiber was analyzed by using two different materials. These were ruminally incubated orchard grass hay stems without and with preincubation with F. succinogenes (natural and artificial consortia, respectively). The natural consortium mainly consisted of Firmicutes (56.6%) and Bacteroidetes (33.1%), while the artificial consortium showed a significantly higher proportion of Firmicutes (85.5%) and a lower proportion of Bacteroidetes (4.6%). At species or genus level, Butyrivibrio fibrisolvens, the U2 group, Ruminococcus albus and Lachnospiraceae incertae sedis made up a higher proportion in the artificial consortium. The most dominant bacterial group was the Butyrivibrio‐Pseudobutyrivibrio‐Lachnospiraceae incertae sedis group, which accounted for 19.7% in the natural and 29.5% in the artificial consortium. Within the genus Butyrivibrio, the phylogenetic groups SA and VA2 and phylogeny‐undefined Butyribivrio, but not VA1, were detected at high frequency in the artificial consortium. These results suggest that ecological and possibly functional relationships exist in the rumen among F. succinogenes, a subset of B. fibrisolvens, the U2 group, R. albus and Lachnospiraceae incertae sedis.     

A comparison of enzymatic and molecular approaches to characterize the cellulolytic microbial ecosystems of the rumen and the cecum

We used RNA probes and enzyme activities to compare the cellulolytic microbial ecosystems of the rumen and the cecum. Four rumen- and cecum-cannulated wethers were fed a diet of barley plus hay (60:40). Digesta samples were collected 1 h before feeding and 3, 6, and 9 h after feeding for measurements on microbial populations, and 1 h before feeding and 3 and 6 h after feeding for digestion measurements, pH, and VFA. Polysaccharidase and glycosidase specific activities of solid-adherent microorganisms were measured respectively by the amount of reducing sugars released from xylan or avicel or p-nitrophenol from the p-nitrophenol derivatives of xylose and glucose. The distribution and amounts of the three main cellulolytic bacterial species (Fibrobacter succinogenes, Ruminococcus albus, and Ruminococcus flavefaciens) were determined by dot-blot hybridization using specific 16SrRNA-targeting probes. Enzyme activities were higher in the rumen than in the cecum and before feeding than at 3 h after feeding. The sum of the three cellulolytic bacterial species represented, on average, 4.5% of the total bacterial RNA in the two compartments and did not vary with sampling time. The cellulolytic bacterial community structure was different in the two compartments, with F. succinogenes as the main species in the rumen and R. flavefaciens in the cecum. The lower cellulolytic activity in the cecum than in the rumen could not be ascribed to any difference in the structure of the cellulolytic bacterial community between these two compartments, and other hypotheses related to digestion are proposed.     

Long-term defaunation increases the abundance of cellulolytic ruminococci and methanogens but does not affect the bacterial and methanogen diversity in the rumen of sheep

Protozoa are commensal eukaryotes in the rumen of herbivores. Protozoa are large producers of hydrogen, which is utilized by methanogenic archaea to produce methane, a greenhouse gas. The removal of protozoa from the rumen (defaunation) decreases methanogenesis, but also negatively affects fiber digestion, which is the main function of the rumen. The aim of this study was to examine the effect of long-term defaunation on the structure of the microbiota and particularly methanogenic archaea and fibrolytic bacteria to better understand the microbial mechanisms responsible for the decrease in methanogenesis and fibrolysis. The trial was conducted in 5 adult sheep subjected successively to long-term defaunation (2 yr), refaunation (12 wk), and short-term defaunation (10 wk). Methanogens were enumerated by quantitative PCR targeting the rrs (16S ribosomal RNA subunit) and mcrA (methyl coenzyme-M reductase) genes. The rrs gene was used to quantify the 3 major culturable rumen cellulolytic bacterial species (i.e., Fibrobacter succinogenes, Ruminococcus albus, and Ruminococcus flavefaciens) and total bacteria. Bacterial and methanogen diversity was also examined by PCR-DGGE (PCR-denaturing gradient gel electrophoresis) analysis targeting the rrs and mcrA genes, respectively. Total rumen bacterial density estimated as rrs copies per gram of DM of rumen content increased in response to long- and short-term defaunation (+1 log, P < 0.001), but without noticeable shifts in diversity. Defaunation increased the rrs copies per gram of DM of rumen content of R. albus and R. flavefaciens (+2 log, P < 0 0.001), but did not affect that of F. succinogenes. Despite a 20% reduction in methane emission in the 2 defaunated periods, the mcrA and rrs copies of methanogens per gram of DM of rumen content increased (+1 log, P < 0.001) in the absence of protozoa, whereas the diversity of the dominant methanogenic community was not modified. This study shows no major difference between long- and short-term defaunation in abundance and diversity of bacteria and archaea. It also provides evidence that monitoring the abundance and diversity of methanogens is not sufficient to comprehend the microbial mechanisms leading to a reduction in methane emissions by ruminants. This study also reports for the first time in sheep a selective effect of defaunation on the abundance of cellulolytic bacterial species.     

Use of bean husk as an easily digestible fiber source for activating the fibrolytic rumen bacterium Fibrobacter succinogenes and rice straw digestion

A series of in sacco and in vitro studies were carried out to evaluate bean husks for activation of fibrolytic rumen bacteria and rice straw digestion. First, lablab bean husk, chickpea husk and rice straw were suspended in the rumen of sheep to analyze the bacterial consortium developed on each fiber source. Known members of fiber‐associating bacteria were found on both lablab bean husk and rice straw, but some of these bacteria were lacking on chickpea husk. Second, a pure culture study was carried out using six strains of Fibrobacter succinogenes. Both husks stimulated the growth of all tested strains, including a strain that did not grow on rice straw. The strain OS128 that showed the highest growth on rice straw displayed even higher growth on lablab bean husk without a time lag. Finally, two‐step incubations were carried out to determine whether prior incubation of rumen fluid with husks stimulates subsequent rice straw digestion. Higher digestibility of rice straw was recorded in the second‐round incubation following the first incubation with bean husks. These results suggest that the tested bean husks improve the digestion of rice straw by activating fibrolytic F. succinogenes and other associated bacteria.     

饲粮中燕麦干草含量对绵羊瘤胃液pH及微生物区系的影响

本试验旨在研究饲粮燕麦干草含量对绵羊瘤胃液p H及微生物区系的影响。选取9只体况和体重[(70.32±2.14)kg]相近、装有永久性瘘管的德国美利奴与蒙古羊杂种公羊,采用3×3拉丁方设计,随机分为3组,每组3只,各组分别采用全株玉米青贮、全株玉米青贮+燕麦干草(1∶1)(混合组)、燕麦干草为粗饲料。饲粮精粗比34.50∶65.50。进行3期饲养试验,每期20 d,15 d预试期,5 d采样期。采集饲喂前(0 h)和饲喂后1、3、5和7 h的瘤胃液,测定p H,采用实时定量PCR方法测定微生物相对含量。结果表明:1)全株玉米青贮组的瘤胃液p H在1、5 h均显著低于燕麦干草组(P0.05),在3 h极显著低于混合组(P0.01);2)混合组和燕麦干草组瘤胃液真菌的相对含量在0 h均极显著高于全株玉米青贮组(P0.01),燕麦干草组在5 h真菌相对含量显著高于全株玉米青贮组(P0.05);3)混合组原虫的相对含量在1、5 h显著低于全株玉米青贮组(P0.05);4)饲喂后5 h,混合组和燕麦干草组的纤维分解菌相对含量均较高,其中燕麦干草组黄色瘤胃球菌相对含量显著高于全株玉米青贮组(P0.05),白色瘤胃球菌和产琥珀酸丝状杆菌的相对含量极显著高于全株玉米青贮组(P0.01)。综上所述,在精粗比为34.50∶65.50的饲粮中采用全株玉米青贮+燕麦干草(1∶1)的粗饲料,有利于维持绵羊瘤胃内环境的稳态及瘤胃微生物的生长,白色瘤胃球菌和产琥珀酸丝状杆菌为优势菌。     

Quantitative comparisons of select cultured and uncultured microbial populations in the rumen of cattle fed different diets

ABSTRACT: BACKGROUND: The number and diversity of uncultured ruminal bacterial and archaeal species revealed by 16S rRNA gene (rrs) sequences greatly exceeds that of cultured bacteria and archaea. However, the significance of uncultured microbes remains undetermined. The objective of this study was to assess the numeric importance of select uncultured bacteria and cultured bacteria and the impact of diets and microenvironments within cow rumen in a comparative manner. RESULTS: Liquid and adherent fractions were obtained from the rumen of Jersey cattle fed hay alone and Holstein cattle fed hay plus grain. The populations of cultured and uncultured bacteria present in each fraction were quantified using specific real-time PCR assays. The population of total bacteria was similar between fractions or diets, while total archaea was numerically higher in the hay-fed Jersey cattle than in the hay-grain-fed Holstein cattle. The population of the genus Prevotella was about one log smaller than that of total bacteria. The populations of Fibrobacter succinogenes, Ruminococcus flavefaciens, the genus Butyrivibrio, and R. albus was at least one log smaller than that of genus Prevotella. Four of the six uncultured bacteria quantified were as abundant as F. succinogenes, R. flavefaciens and the genus Butyrivibrio. In addition, the populations of several uncultured bacteria were significantly higher in the adherent fractions than in the liquid fractions. These uncultured bacteria may be associated with fiber degradation. CONCLUSIONS: Some uncultured bacteria are as abundant as those of major cultured bacteria in the rumen. Uncultured bacteria may have important contribution to ruminal fermentation. Population dynamic studies of uncultured bacteria in a comparative manner can help reveal their ecological features and importance to rumen functions.     

Influence of direct-fed fibrolytic enzymes on diet digestibility and ruminal activity in sheep fed a grass hay-based diet

Six rumen-fistulated Merino sheep were used in a crossover design experiment to evaluate the effects of an exogenous fibrolytic enzyme preparation (12 g/d; ENZ), delivered directly into the rumen, on diet digestibility, ruminal fermentation, and microbial protein synthesis. The enzyme contained endoglucanase and xylanase activities. Sheep were fed a mixed grass hay:concentrate (70:30; DM basis) diet at a daily rate of 46.1 g/kg of BW(0.75). Samples of grass hay were incubated in situ in the rumen of each sheep to measure DM and NDF degradation. The supplementation with ENZ did not affect diet digestibility (P = 0.30 to 0.66), urinary excretion of purine derivatives (P = 0.34), ruminal pH (P = 0.46), or concentrations of NH(3)-N (P = 0.69) and total VFA (P = 0.97). In contrast, molar proportion of propionate were greater (P = 0.001) and acetate:propionate ratio was lower (P < 0.001) in ENZ-supplemented sheep. In addition, ENZ supplementation tended to increase (P = 0.06) numbers of cellulolytic bacteria at 4 h after feeding. Both the ruminally insoluble potentially degradable fraction of grass hay DM and its fractional rate of degradation were increased (P = 0.002 and 0.05, respectively) by ENZ treatment. Supplementation with ENZ also increased (P = 0.01 to 0.02) effective and potential degradability of grass hay DM and NDF. Ruminal fluid endoglucanase and xylanase activities were greater (P < 0.001 and 0.03, respectively) in ENZ-supplemented sheep than in control animals. It was found that ENZ supplementation did not affect either exoglucanase (P = 0.12) or amylase (P = 0.83) activity. The results indicate that supplementing ENZ directly into the rumen increased the fibrolytic activity and stimulated the growth of cellulolytic bacteria without a prefeeding feed-enzyme interaction.     

Inclusion of novel bacteria in rumen microbiology: Need for basic and applied science

Rumen microbiology has made a significant contribution to the understanding of ruminant nutrition. However, further progress in research has been hindered by the incomplete analysis of the rumen microbiota comprised of bacteria, protozoa and fungi, most of which remain uncharacterized due to the difficulties in their isolation and cultivation. In order to maximize rumen fiber digestion, it is necessary to understand the community structure of rumen microbes, especially bacteria, and the factors that influence their composition. Recent advances in molecular biology techniques allow the analysis of such bacteria without cultivation, thereby identifying many functional, but uncultured, bacteria as new targets for basic and applied research. Specific uncultured bacterial groups are being considered as important members of a fibrolytic consortium in the rumen, judging by their ecologic distribution. The inclusion of such uncharacterized bacteria in analyses is crucial for understanding the rumen microbial community and its manipulation. In addition, these bacteria could potentially be candidates as probiotics and sources of enzymes for animal feed and other industrial uses.     

Influence of sampling site on concentrations and carbohydrate-degrading enzyme activities of protozoa and bacteria in the rumen.

Four ruminally cannulated cows were used to assess the distribution of the concentrations and carbohydrate-degrading enzyme activities of the liquid-associated protozoa (LAP) and solid-associated bacteria (SAB) in the rumen. The cows were fed diets (7 kg of DM/d) of 100% hay (Diet F) or 60% barley plus 40% hay (Diet C) in a 2 x 2 crossover experimental design. Samples of ruminal digesta were collected successively from the dorsal (DS), ventral (VS), and anterior (AS) sacs 1h before and 3 h after the morning feeding on two sampling days with a 2-d interval. Irrespective of diet and sampling time, the greatest proportion of entodiniomorphs, representing the main population of protozoa, was found in the DS (40% mean; P < .05). Low pH values observed in the DS (P < .05) indicated higher fermentative activity in this site than in the other parts of the rumen. Protozoa may contribute more than previously thought to the high digestive potential present at the top of the rumen that has classically been attributed to bacteria. The specific activity of plant cell wall polysaccharide-degrading enzymes in the LAP was correspondingly greater (P < .05) for DS than for VS or AS. For the two diets and sampling times, specific activity of fibrolytic enzymes in the SAB tended to be less in the upper than in the lower parts of the rumen, and less in the VS than in the AS. This tendency became significant (P < .05) for total fibrolytic enzyme activity. Differences in bacterial colonization of particles among the three sampling sites may explain such differences in fibrolytic activity of the SAB. Data suggest a spatio-temporal complementary action of the bacteria and protozoa in ruminal plant cell wall degradation, at least with the barley diet, for which the number of protozoa was highest.     

16S rRNA定量分析技术对绵羊瘤胃固相纤维降解菌的研究

本试验选择3只安装永久性瘤胃瘘管、体重25￣30kg的羯羊,使用特异性16SrRNA目标探针进行斑点杂交研究绵羊瘤胃固相纤维降解菌的动态变化规律。结果表明:3种纤维分解菌的RNA占总菌数RNA的15.76%;在各时间点产琥珀酸拟杆菌的相对含量均高于黄化瘤胃球菌和白色瘤胃球菌相对含量。     

甘露寡糖、果寡糖和大豆寡糖组合对锦江黄牛瘤胃液细菌多样性的影响

本试验旨在研究功能性寡糖(甘露寡糖、果寡糖和大豆寡糖)组合对锦江黄牛的瘤胃液细菌多样性的影响.选择3头健康且体重相近的安装有永久性瘤胃瘘管的锦江黄牛,采用自身对照方法,试验分2期进行,第1期:对照期,饲喂基础饲粮,不添加任何寡糖;第2期:添加期,饲喂基础饲粮+功能性寡糖(0.8％甘露寡糖+1.0％果寡糖+0.8％大豆寡糖),每期持续14 d.利用PCR-变性梯度凝胶电泳(DGGE)方法研究分析牛瘤胃液细菌多样性.结果表明:添加功能性寡糖组合后,牛瘤胃液细菌PCR-DGGE图谱条带数明显增加,3头牛增加了5个共同条带.经测序,其中2个是产琥珀酸丝状杆菌属,3个是未鉴定细菌.饲粮中添加功能性寡糖组合可使瘤胃液细菌菌群种类明显增加.结果提示,饲粮添加功能性寡糖组合能够影响瘤胃菌群区系,增强其稳定性.     

柴胡中草药对奶牛瘤胃菌群多样性及纤维分解菌的影响

通过DGGE和RT-PCR技术研究日粮中添加不同剂量的柴胡中草药对奶牛瘤胃细菌多样性和主要纤维分解菌(琥珀酸丝状杆菌、黄色瘤胃球菌和白色瘤胃球菌)的影响。根据产奶量(37.5±1.8) kg/d、泌乳天数(75±15) d以及胎次(1.7±0.4)等相近的原则,将40头健康的中国荷斯坦泌乳奶牛随机分为4组(n=10),分别饲喂4种不同的处理日粮,即在基础日粮中分别添加0,0.25,0.50和1.00 g/kg的柴胡中草药(DM基础)。试验持续10周,并在第6周口腔采集瘤胃液,通过变性梯度凝胶电泳(DGGE)和实时定量PCR(RT-PCR)对瘤胃细菌进行分析。DGGE图谱显示,中草药添加组和空白对照组并没有显著的差异条带,但其指纹图谱相似性并不高,均低于0.54,且1.00 g/kg的添加量显著降低了瘤胃液细菌香农多样性指数,而0.50和1.00 g/kg的添加量则提高了菌群优势度指数(P<0.05);RT-PCR结果显示,柴胡中草药对奶牛瘤胃主要纤维分解菌并没有显著的影响。因此,柴胡中草药在一定程度上影响了瘤胃细菌的多样性,但差异并不显著,可能由于瘤胃微生物适应了柴胡中草药的添加。     

酵母发酵饲料对瘤胃菌群数量及多样性的影响

本试验研究日粮中添加酵母发酵饲料对蒙古绵羊瘤胃菌群数量及多样性的影响。选用10只安装永久性瘤胃瘘管且体重约40 kg的14月龄蒙古羯羊,分为对照组和试验组,每组各5只。对照组饲喂基础日粮,试验组饲喂基础日粮+酵母发酵饲料(13.37%)。预试期15 d,正试期5 d。于正试期晨饲后0、3、6、9、12 h依次采集瘤胃液,每天采集一个时间点,共采集5次。实时荧光定量PCR(探针法)检测9种瘤胃菌群的数量,并用16S rRNA高通量测序技术分析菌群多样性。结果表明:试验组溶纤维丁酸弧菌、黄色瘤胃球菌、产琥珀酸丝状杆菌、埃氏巨球型菌、牛链球菌和栖瘤胃普雷沃氏菌数量均高于对照组(P<0.05),反刍兽甲烷短杆菌数量低于对照组(P<0.05),嗜淀粉瘤胃杆菌和白色瘤胃球菌在两组间差异不显著;试验组中菌群多样性低于对照组(P<0.05),拟杆菌门、纤维杆菌门、密螺旋体门含量升高,厚壁菌门含量降低(P>0.05);理研菌科_RC9菌属含量升高,克里斯滕森菌属_R-7含量降低(P<0.05)。综上,酵母发酵饲料能够影响瘤胃菌群数量,改善瘤胃菌群结构,降低瘤胃菌群的多样性。     

Ecological characterization of three different phylogenetic groups belonging to the cellulolytic bacterial species Fibrobacter succinogenes in the rumen

To study the group‐dependent ecology of Fibrobacter succinogenes in the rumen, real‐time polymerase chain reaction assays for two phylogenetic groups (groups 2 and 3) of F. succinogenes were newly established and applied to rumen samples. Both the assays targeting the bacterial 16S rDNA were sensitive and accurate, showing wide quantifiable ranges (10⁴?10⁹ and 10²?10⁹ copies of 16S rDNA) and high recoveries of known amounts of added DNA (96.9 and 98.0%). The quantity of group 1 was confirmed to be numerable by subtracting assay values of groups 2 and 3 from that of F. succinogenes species (groups 1–3). By using the developed assays and the above subtractive calculation, the quantities of all three groups were evaluated in solid and liquid fractions of the rumen content and also on hay stems. In the solid fraction, groups 1 and 2 were abundantly present, compared with group 3 (P < 0.05). On untreated hay stems, group 1 was dominant throughout 48 h. In addition, group 1 showed growth even on the cellulase‐treated hay stems, unlike the other two groups. These results suggest that F. succinogenes group 1 greatly contributes to rumen fiber digestion, even for less degradable materials.     

Oral administration of Lactobacillus plantarum and Bacillus subtilis on rumen fermentation and the bacterial community in calves

The objective of this study was to assess the effect of dietary probiotics on rumen fermentation and the bacterial community in dairy calves. Twelve Holstein calves were randomly allocated to three treatments: a basal diet, the basal diet supplemented with Lactobacillus plantarum GF103 (LB) or basal diet supplemented with a mixture of Lactobacillus plantarum GF103 and Bacillus subtilis B27 (LBS). A milk replacer was fed to calves from 8 days of age. A starter and alfalfa hay was offered ad libitum from 21 and 28 days of age, respectively, and the orts were weighted daily. The ruminal fluid was sampled at 56 and 83 days of age to determine the rumen fermentation characteristics. The bacterial community was analyzed by denaturing gradient gel electrophoresis (DGGE) and the number of certain bacteria was quantified by real‐time polymerase chain reaction. The ratio of total dry matter intake to average body wieght was higher in the control (P < 0.05). The DGGE fingerprint of the 16S ribosomal RNA gene was affected by the blended probiotics at 83 days of age. The number of Ruminococcus albus was lower in the LB and LBS treatment (P < 0.05). Oral administration of the probiotics affected the rumen bacterial community and the numbers of cellulolytic bacteria decreased.     

Degradation of cellulose and forage fiber fractions by ruminal cellulolytic bacteria alone and in coculture with phenolic monomer-degrading bacteria.

We hypothesized that bacterial species capable of metabolizing phenolic monomers may act as catalysts for forage fiber breakdown by increasing microbial access to cell wall polysaccharides. Ruminal cellulolytic bacteria alone and in combination with phenolic-degrading bacteria were examined for differences in their ability to degrade fiber fractions of alfalfa or bromegrass. Electron micrographs of Fibrobacter succinogenes S85 cultured in combination with the ruminal phenolic-degrading organisms Eubacterium oxidoreducens G41 and Syntrophococcus sucromutans S195 indicated that bromegrass was degraded more extensively by the triculture than by the monoculture. The sequential detergent system was used to quantify the digestibility of fiber components from alfalfa and bromegrass. F. succinogenes incubated with the two phenolic-degrading organisms did not degrade more cell wall material than did F. succinogenes alone. However, with two other ruminal cellulolytic organisms, Clostridium longisporum B6405 and Ruminococcus albus B6403, greater (P less than .05, P less than .10, respectively) amounts of hemicellulose were degraded (72 h in vitro fermentation) from whole-plant alfalfa when E. oxidoreducens and S. sucromutants were combined with the cellulolytic species than when their monocultures were tested. Similar increases were not observed using a NDF preparation of alfalfa as the substrate. Based on these in vitro experiments, it does not seem that E. oxidoreducens and S. sucromutans play an important role in improving forage fiber degradation by cellulolytic ruminal bacteria.     

DAP-decarboxylase activity and lysine production by rumen bacteria.

The last step of pathway of lysine biosynthesis by rumen bacteria was tested. The first measurements of DAP-decarboxylase activity and of lysine production by Megasphera elsdenii, Selenomonas ruminantium, Clostridium spp., Butyrivibrio fibrisolvens and Bacteroides succinogenes as well as the first attempts to increase the lysine production by ruminal streptococci by mutation are described. The highest values were measured in Selenomonas ruminantium (DAP-decarboxylase activity = 146 micrograms DAP.min-1.mg-1 protein and lysine production was 390 micrograms.mg-1 protein) and the lowest values were ascertained in Butyrivibrio fibrisolvens (DAP-decarboxylase activity = 27 micrograms DAP.min-1.mg-1 protein and lysine production was 32 micrograms.mg-1 protein). DAP-decarboxylase activity was increased by mutation especially in Streptococcus bovis, the lysine production in both of tested ruminal streptococci. The potential use of lysine-excreting mutants in calves in future is suggested.