Identification of proteolytic rumen bacteria isolated from New Zealand cattle

The protease activities of 212 strains of rumen bacteria isolated from New Zealand cattle grazing pasture were measured. Thirty-seven per cent of strains had activity greater than or equal to the proteolytic rumen bacterium Prevotella ruminicola and 43 of these isolates were identified by morphology, carbon source utilization, Gram stain, biochemical tests and fermentation end-product analysis. Hierarchical Cluster Analysis showed that the strains formed four clusters: cluster A contained 26 strains and clustered with a reference strain of Streptococcus bovis; cluster C contained three strains and clustered with a reference strain of Butyrivibrio fibrisolvens , while clusters B (10 strains) and D (three strains) did not cluster with any of the remaining rumen bacterial type strains. Further tests identified strains of cluster B as Eubacterium budayi , while cluster D strains most closely resembled B. fibrisolvens and were described as B. fibrisolvens -like. An unclustered strain, C21a, was identified as P. ruminicola. The significance of these proteolytic bacterial populations is discussed in relation to protein breakdown in New Zealand ruminants.     

Bacterial Population Adherent to the Epithelium on the Roo of the Dorsal Rumen of Sheep

By anaerobic procedures, the total number of adherent bacteria was determined on tissue samples obtained from the roof of the dorsal rumen of three sheep. After four washings, 1.91 × 10⁷, 0.34 × 10⁷, and 1.23 × 10⁷ bacteria per cm² were still attached to the rumen epithelium in sheep 1, 2, and 3, respectively. A total of 95 strains of bacteria were isolated from these three samples. Based on morphology, Gram stain, anaerobiosis, motility, and fermentation end products, they were presumptively identified as follows: Butyrivibrio fibrisolvens, 30 strains; atypical Butyrivibrio, 5 strains; Bacteroides ruminicola, 22 strains; Lactobacillus, 1 strain; and unknown Bacteroides species, 37 strains. For sheep 3, washing the rumen epithelium a total of 10 times reduced the adherent bacterial population by 93% (8.4 × 10⁵ bacteria per cm²). Of 30 strains isolated from this sample, 22 were presumptively identified as Butyrivibrio and Bacteroides types. These results suggest that the epithelium on the roof of the dorsal rumen is primarily colonized by two genera of bacteria, Butyrivibrio and Bacteroides. Most Butyrivibrio and Bacteroides ruminicola strains appeared to be similar to previously isolated rumen strains. However, the unknown Bacteroides species differed considerably from the three species of this genus which are commonly isolated from rumen contents.     

Characterization of several bovine rumen bacteria isolated with a xylan medium

Dehority, B. A. (Ohio Agricultural Research and Development Center, Wooster). Characterization of several bovine rumen bacteria isolated with a xylan medium. J. Bacteriol. 91:1724-1729. 1966.-Studies were conducted to characterize eight strains of bacteria isolated from bovine rumen contents, by use of a medium containing xylan as the only added carbohydrate source. Based on morphology, biochemical reactions, nutritional requirements, and fermentation products, five of the eight strains were identified as Butyrivibrio fibrisolvens. Many properties of the remaining three strains resembled Bacteroides ruminicola; however, propionic acid was consistently found as a fermentation product. When the type strains for B. ruminicola subsp. ruminicola and B. ruminicola subsp. brevis were compared with the present isolates, it was found that propionic acid was a normal fermentation product for the type strain B. ruminicola subsp. ruminicola when grown in a 40% rumen fluid-0.5% glucose broth. Production of propionic acid was markedly reduced for all strains when grown in a 20% rumen fluid-1% glucose broth. The three remaining strains were thus placed in the species B. ruminicola, and further classified into the subspecies ruminicola (one strain) and brevis (two strains) on the basis of their requirement for hemin. Although the type strain of B. ruminicola subsp. brevis did not produce propionic acid, both of the present isolates classified as this subspecies produced substantial amounts. One strain of B. ruminicola subsp. brevis had an absolute requirement for volatile fatty acids. Either isobutyric or dl-2-methylbutyric acid would satisfy this requirement, whereas isovaleric acid was ineffective. It is of interest that xylan-fermenting bacteria isolated from 10(-7) and 10(-8) dilutions of rumen contents by use of a xylan medium are similar to the xylan fermenters isolated at the same dilutions with a nonselective medium.     

Rate of isolated hemicellulose degradation and utilization by pure cultures of rumen bacteria

Rate studies on the utilization or degradation (or both) of isolated hemicelluloses were conducted with six strains of rumen cellulolytic bacteria. Utilization was estimated by total pentose loss, and degradation values were based on solubilization of the hemicellulose in acidified 80% ethyl alcohol. With the various strains of ruminococci, degradation of flax and fescue grass hemicellulose was near the maximum within the first 12 hr of incubation. However, where applicable, the rates of utilization were considerably slower. Both degradation and utilization of corn hull hemicellulose occurred at much slower rates than observed with the other two substrates. With flax and fescue grass hemicellulose, the rates of degradation did not appear to be influenced by the organism's ability, or inability, to utilize the substrate as an energy source. The rates and extent of isolated hemicellulose degradation and utilization were compared between the cellulolytic ruminococci and three strains of bacteria isolated from the rumen with a xylan medium. Similar values were obtained with both types of bacteria. These observations would suggest that the cellulolytic ruminococci may be important in the overall fermentation of forage hemicelluloses in the rumen. The acidified 80% ethyl alcohol supernatant fluids, obtained from fermentations of isolated fescue grass hemicellulose by two strains of Ruminococcus flavefaciens, of which only one was able eventually to utilize the substrate, were investigated by thin-layer chromatography. Results indicated that soluble oligosaccharides were produced, which were observed to disappear gradually with time in fermentations with the utilizing strain and to accumulate in fermentations with the nonutilizing strain. Examination of the acidified 80% ethyl alcohol-insoluble residue hydrolysates, obtained from fermentations with the utilizing strain, revealed that the concentration of all the constituent sugars decreased uniformly.     

耐60℃高温乳酸菌的驯化及鉴定

目的对本实验室保存的ATCC 4356菌株进行温度梯度诱变,从而获得1株耐高温乳酸菌。方法采用温度梯度方法诱变菌株;通过革兰染色和原子力显微镜观察诱变前后菌株革兰染色特性和形态及表面结构的变化;通过生理生化特性鉴定,判断诱变前后菌株是否发生种属变化。结果在45~60℃诱变过程中,随温度升高传代次数递增,但最终均能成功驯化和稳定传代。驯化前后菌株在产酸能力、形态特征、革兰染色和生理生化特性方面无显著性变化,表明该诱导菌株未发生种属变化;原子力显微镜观察结果表明诱导前后菌株表面形态存在差异。结论温度梯度诱变技术能够成功驯化耐60℃高温乳酸菌,从而扩大其应用范围。     

Enumeration and presumptive identification of some functional groups of bacteria in the rumen of dairy cows fed grass silage-based diets

Abstract Samples of rumen ingesta from two rumen-fistulated dairy cows fed grass silage-based diets were examined for numbers and types of bacteria that developed colonies on rumen fluid-agar media designated to support the growth of (a) a wide range of species, (b) cellulolytic bacteria, (c) lactate-fermenting bacteria, (d) non-fermentative bacteria. The most numerous species was Bacteroides ruminicola followed by Butyrivibrio fibrisolvens . The most abundant cellulolytic species were Eubacterium cellulosolvens and Ruminococcus flavefaciens. Megasphaera elsdenii and Selenomonas ruminantium were important lactate fermenters but an unidentified bacterium that grew poorly on maintenance medium was by far the most numerous among bacteria isolated from lactate-containing medium. One strain remained sufficiently viable to show that it fermented lactate to propionate and acetate.     

Treponema bryantii sp. nov., a rumen spirochete that interacts with cellulolytic bacteria

A saccharolytic spirochete that associated and interacted with cellulolytic bacteria was isolated from bovine rumen fluid. Isolation was accomplished by means of a procedure involving serial dilution of a sample of rumen fluid into a cellulose-containing agar medium. Clear zones appeared within the medium as a result of cellulose hydrolysis by rumen bacteria. The saccharolytic spirochete and a cellulolytic bacterium later identified as a strain of Bacteroides succinogenes were isolated from the clear zones. The spirochete did not utilize cellulose, but grew in coculture with the cellulolytic bacterium in cellulose-containing media. When cocultured in these media the spirochete used, as fermentable substrates, soluble sugars released from cellulose by the cellulolytic bacterium. In cellulosecontaining agar medium the spirochete enhanced cellulose breakdown by the B. succinogenes strain. Electron microscopy showed that the helical spirochete cells possessed an outer sheath, a protoplasmic cylinder, and two periplasmic fibrils. Under a CO₂ atmosphere, in a reduced medium containing inorganic salts, rumen fluid, glucose, and NaHCO₃, the spirochete grew to a final density of 1.9×10⁹ cells/ml. Succinate, acetate, and formate were products of the fermentation of glucose by growing cells. CO₂ (HCO₃ ^-), branched short-chain fatty acids, folic acid, biotin, niacinamide, thiamine, pyridoxal, and a carbohydrate were required for growth of the spirochete. The results of this study indicated that the rumen spirochete represents a new species of Treponema. It is proposed that the new species be named Treponema bryantii.Abbreviations cpm counts per minute - GC guanine plus cytosine - T_m melting temperature - PC protoplasmic cylinder - PF pertplasmic fibrils (axial fibrils) - OS outer sheath - ID insertion disk     

Growth Factor Requirements of Ruminococcus flavefaciens Isolated from the Rumen of Cattle Fed Purified Diets

Eight strains of cellulolytic cocci were isolated from a 10^-8 dilution of rumen ingesta and were presumptively identified as Ruminococcus flavefaciens. Four strains were isolated from a steer fed a purified diet which contained isolated soy protein, and four strains were isolated from a steer fed a purified diet which contained urea. Certain growth factor requirements of these bacteria were determined. All strains grew with clarified rumen fluid added to the medium. However, fatty acids could substitute for rumen fluid in four strains. Two strains isolated from each steer either required or their growth was stimulated by isobutyric and/or isovaleric and/or 2-methyl-butyric acid. These results indicate that, even when a diet was fed which contained no branched-chain amino acids, the carbon skeleton precursors of branched-chain fatty acids, the cattle were still able to maintain a large population of cellulolytic bacteria that require fatty acids for growth. Therefore, the fatty acids appear to be provided by other bacteria, by protozoa, or by the host animal.     

Mechanism of Isolated Hemicellulose and Xylan Degradation by Cellulolytic Rumen Bacteria

Although certain strains of cellulolytic rumen bacteria cannot utilize isolated hemicelluloses or xylan as a source of energy, all strains examined can degrade or solubilize these materials from an 80% ethyl alcohol insoluble to a soluble form. Centrifugation and washing of the cellobiose-grown bacterial cells did not affect the rate or extent of utilization or degradation or both. When the level of a nonutilizing culture inoculum (either normal or washed) was doubled, a corresponding increase in the initial rate of degradation was observed. With a nitrogen-free medium, utilization of xylan was almost completely inhibited for a utilizing strain, whereas degradation by either type of organism was not markedly affected. Cellobiose medium cell-free culture filtrates from a nonutilizing strain were able to degrade or solubilize xylan. The percentage of degradation increased with the volume of cell-free filtrate, and all activity was lost when the filtrate was boiled. No utilization (loss in total pentose) was observed with cell-free filtrates from utilizing or nonutilizing strains. The release of free hexose from insoluble cellulose by culture filtrates from a nonutilizing strain was very limited. On the other hand, carboxymethylcellulose (CMC-70L) and cellulodextrins were degraded to an 80% ethyl alcohol soluble form by filtrates from both types of organisms. Similar enzyme activity was obtained in cell-free culture filtrates from four additional strains of cellulolytic rumen bacteria (one xylan utilizer and three nonutilizers). When the assays were carried out aerobically, CMC-70L solubilization was reduced to a much greater extent than xylan or cellulodextrin solubilization. The enzyme or enzymes responsible for the degradation of hemicellulose by cellololytic rumen bacteria unable to utilize the hemicellulose as an energy source appear to be constitutive in nature, and this activity may be a nonspecific action of a beta-1, 4-glucosidase or -cellulase.     

Degradation and Utilization of Hemicellulose from Intact Forages by Pure Cultures of Rumen Bacteria

Several pure strains of rumen bacteria have previously been shown to degrade isolated hemicelluloses from a form insoluble in 80% acidified ethanol to a soluble form, regardless of the eventual ability of the organism to utilize the end products as energy sources. This study was undertaken to determine whether similar hemicellulose degradation or utilization, or both, occurs from intact forages. Fermentations by pure cultures were run to completion by using three maturity stages of alfalfa and two maturity stages of bromegrass as individual substrates. Organisms capable of utilizing xylan or isolated hemicelluloses could degrade and utilize intact forage hemicellulose, with the exception of two strains of Bacteroides ruminicola which were unable to degrade or utilize hemicellulose from grass hays. Intact forage hemicelluloses were extensively degraded by three cellulolytic strains that were unable to use the end products; in general, these strains degraded a considerably greater amount of hemicelluloses than the hemicellulolytic organisms. Hemicellulose degradation or utilization, or both, varied markedly with the different species and strains of bacteria, as well as with the type and maturity stage of the forage. Definite synergism was observed when a degrading nonutilizer was combined with either one of two hemicellulolytic strains on the bromegrass substrates. One hemicellulolytic strain, which could not degrade or utilize any of the intact bromegrass hemicellulose alone, almost completely utilized the end products solubilized by the nonutilizer. Similar synergism, although of lesser magnitude, was observed when alfalfa was used as a substrate.     

Anaerobic cellulolytic bacteria from wetwood of living trees

Obligately anaerobic, mesophilic, cellulolytic bacteria were isolated from the wetwood of elm and maple trees. The isolation of these bacteria involved inoculation of selective enrichment cultures with increment cores taken from trees showing evidence of wetwood. Cellulolytic bacteria were present in the cores from seven of nine trees sampled, as indicated by the disappearance of cellulose from enrichment cultures. With two exceptions, cellulolytic activity was confined to the darker, wetter, inner section of the cores. Cellulolytic bacteria were also present in the fluid from core holes. The cellulolytic isolates were motile rods that stained gram negative. Endospores were formed by some strains. The physiology of one of the cellulolytic isolates (strain JW2) was studied in detail. Strain JW2 fermented cellobiose, d-glucose, glycerol, l-arabinose, d-xylose, and xylan in addition to cellulose. In a defined medium, p-aminobenzoic acid and biotin were the only exogenous growth factors required by strain JW2 for the fermentation of cellobiose or cellulose. Acetate and ethanol were the major nongaseous end products of cellulose fermentation. The guanine-plus-cytosine content of the DNA of strain JW2 was 33.7 mol%. Cellulolytic bacteria have not previously been reported to occur in wetwood. The isolation of such bacteria indicates that cellulolytic bacteria are inhabitants of wetwood environments and suggests that they may be involved in wetwood development.     

Characterization of rat cecum cellulolytic bacteria.

Cellulose-degrading bacteria previously isolated from the ceca of rats have been characterized and identified. The most commonly isolated type was rods identified as Bacteroides succinogenes. These bacteria fermented only cellulose (e.g., pebble-milled Whatman no. 1 filter paper), cellobiose, and in 43 of 47 strains, glucose, with succinic and acetic acids as the major products. The only organic growth factors found to be required by selected strains were p-aminobenzoic acid, cyanocobalamine, thiamine, and a straight-chain and a branched-chain volatile fatty acid. These vitamin requirements differ from those of rumen strains of B. succinogenes, indicating the rat strains may form a distinct subgroup within the species. The mole percent guanine plus cytosine was 45%, a value lower than those (48 to 51%) found for three rumen strains of B. succinogenes included in this study. Cellulolytic cocci were isolated less frequently than the rods and were identified as Rumminococcus flavefaciens. Most strains fermented only cellulose and cellobiose, and their major fermentation products were also succinic and acetic acids. Their required growth factors were not identified but were supplied by rumen fluid.     

Fiber-degrading systems of different strains of the genus Fibrobacter

The S85 type strain of Fibrobacter succinogenes, a major ruminal fibrolytic species, was isolated 49 years ago from a bovine rumen and has been used since then as a model for extensive studies. To assess the validity of this model, we compared the cellulase- and xylanase-degrading activities of several other F. succinogenes strains originating from different ruminants, including recently isolated strains, and looked for the presence of 10 glycoside hydrolase genes previously identified in S85. The NR9 F. intestinalis type strain, representative of the second species of the genus, was also included in this study. DNA-DNA hybridization and 16S rRNA gene sequencing first classified the strains and provided the phylogenetic positions of isolates of both species. Cellulase and xylanase activity analyses revealed similar activity profiles for all F. succinogenes strains. However, the F(E) strain, phylogenetically close to S85, presented a poor xylanolytic system and weak specific activities. Furthermore, the HM2 strain, genetically distant from the other F. succinogenes isolates, displayed a larger cellulolytic profile on zymograms and higher cellulolytic specific activity. F. intestinalis NR9 presented a higher cellulolytic specific activity and a stronger extracellular xylanolytic activity. Almost all glycoside hydrolase genes studied were found in the F. succinogenes isolates by PCR, except in the HM2 strain, and few of them were detected in F. intestinalis NR9. As expected, the fibrolytic genes of strains of the genus Fibrobacter as well as the cellulase and xylanase activities are better conserved in closely related phylogenetic isolates.     

Effects of Long-Chain Fatty Acids on Growth of Rumen Bacteria

The effects of low concentrations of long-chain fatty acids (palmitic, stearic, oleic, and vaccenic) on the growth of seven species (13 strains) of rumen bacteria were investigated. Except for Bacteroides ruminicola and several strains of Butyrivibrio fibrisolvens, bacterial growth was not greatly affected by either palmitic or stearic acids. In contrast, growth of Selenomonas ruminantium, B. ruminicola, and one strain of B. fibrisolvens was stimulated by oleic acid, whereas the cellulolytic species were markedly inhibited by this acid. Vaccenic acid (trans Δ11 18:1) had far less inhibitory effect on the cellulolytic species than oleic acid (cis Δ9 18:1). Inclusion of powdered cellulose in the medium appeared to reverse both inhibitory and stimulatory effects of added fatty acids. However, there was little carry-over effect observed when cells were transferred from a medium with fatty acids to one without. Considerable variation in response to added fatty acids was noted among five strains of B. fibrisolvens. In general, exogenous long-chain fatty acids appear to have little, if any, energy-sparing effect on the growth of rumen bacteria.     

Bacteriophages that infect the cellulolytic ruminal bacterium Ruminococcus albus AR67

AIM: To isolate bacterial viruses that infect the ruminal cellulolytic bacterium Ruminococcus albus. METHODS: Four phages infecting R. albus AR67 were isolated under anaerobic conditions using the soft-agar overlay technique. The phages were characterized on morphology, solvent stability, nucleic acid type and digestion characteristics. Two phages, phiRa02 and phiRa04 comprised icosahedral virions with linear double-stranded DNA and appeared to belong to the family Podoviridae [corrected] The other two phages are most likely filamentous phages with circular single-stranded DNA of the family Inoviridae. SIGNIFICANCE OF THE STUDY: Viruses of the family Inoviridae [corrected] have not previously been isolated from rumen bacteria. The phages isolated in this study are the first phages shown to infect the cellulolytic bacteria of the rumen. This suggests that the cellulolytic populations of the rumen are subject to lytic events that may impact on the ability of these bacteria to degrade plant fibre and on the nutrition of the animal.     

利用基本培养基初步筛选牛瘤胃中纤维素降解菌

目的初步筛选牛瘤胃中纤维素降解菌。方法分别采用基本培养基（牛肉膏蛋白胨培养基、马丁培养基）,利用好氧、兼性和厌氧3种不同的培养方法进行初选,初步分离牛瘤胃中的细菌与真菌,再通过复选培养基（加入微晶纤维素）,筛选降解纤维素的菌种。结果筛选分离出降解纤维素的1株厌氧细菌和1株厌氧真菌。结论此实验方法简单易行,能够有效地从牛瘤胃中筛选出生长良好的纤维素降解菌。     

Characteristics of a new cellulolytic Clostridium sp. isolated from pig intestinal tract.

Gram-positive, spore-forming, motile, cellulolytic rods were isolated from 10(7) dilutions of pig fecal samples. The pigs had previously been fed pure cultures of the ruminal cellulolytic organism Clostridium longisporum. Isolates formed terminal to subterminal spores, and a fermentable carbohydrate was required for growth. Besides cellulose, the isolates utilized cellobiose, glycogen, maltose, and starch. However, glucose, fructose, sucrose, pectin, and xylose were not used as energy sources. Major fermentation products included formate and butyrate. The isolates did not digest proteins from gelatin or milk. Unlike C. longisporum, which has limited ability to degrade cell wall components from grasses (switchgrass, bromegrass, and ryegrass), the swine isolates were equally effective in degrading these components from both alfalfa and grasses. The extent of degradation was equal to or better than that observed with the predominant ruminal cellulolytic organisms. On the basis of morphology, motility, spore formation, fermentation products, and the ability to hydrolyze cellulose, the isolates are considered to be a new species of the genus Clostridium. It is unclear whether C. longisporum played a role in the establishment or occurrence of this newly described cellulolytic species. This is the first report of a cellulolytic Clostridium sp. isolated from the pig intestinal tract.     

Characteristics of a new cellulolytic Clostridium sp. isolated from pig intestinal tract.

Gram-positive, spore-forming, motile, cellulolytic rods were isolated from 10(7) dilutions of pig fecal samples. The pigs had previously been fed pure cultures of the ruminal cellulolytic organism Clostridium longisporum. Isolates formed terminal to subterminal spores, and a fermentable carbohydrate was required for growth. Besides cellulose, the isolates utilized cellobiose, glycogen, maltose, and starch. However, glucose, fructose, sucrose, pectin, and xylose were not used as energy sources. Major fermentation products included formate and butyrate. The isolates did not digest proteins from gelatin or milk. Unlike C. longisporum, which has limited ability to degrade cell wall components from grasses (switchgrass, bromegrass, and ryegrass), the swine isolates were equally effective in degrading these components from both alfalfa and grasses. The extent of degradation was equal to or better than that observed with the predominant ruminal cellulolytic organisms. On the basis of morphology, motility, spore formation, fermentation products, and the ability to hydrolyze cellulose, the isolates are considered to be a new species of the genus Clostridium. It is unclear whether C. longisporum played a role in the establishment or occurrence of this newly described cellulolytic species. This is the first report of a cellulolytic Clostridium sp. isolated from the pig intestinal tract.     

Isolation and characterization of large treponemes from the bovine rumen.

Ten strains of strictly anaerobic spiral organisms were isolated in pure culture from a 10(-7) dilution of bovine rumen contents. Three strains were studied in detail. These strains morphologically resembled previously isolated and described rumen treponemes except the new isolates were larger, 0.7 micrometer wide and 12 to 25 micrometer long. They rapidly fermented pectin and, less readily, L-arabinose, inulin, and sucrose. Acetic and formic acid were the main fermentation products from pectin; small amounts of succinic acid were also formed.