Effects of glycerol on the growth,adhesion, and cellulolytic activity of rumen cellulolytic bacteria and anaerobic fungi

The effect of glycerol on the growth, adhesion, and cellulolytic activity of two rumen cellulolytic bacterial species,Ruminococcus flavefaciens andFibrobacter succinogenes subsp.succinogenes, and of an anaerobic fungal species,Neocallimastix frontalis, was studied. At low concentrations (0.1–1%), glycerol had no effect on the growth, adhesion, and cellulolytic activity of the two bacterial species. However, at a concentration of 5%, it greatly inhibited their growth and cellulolytic activity. Glycerol did not affect the adhesion of bacteria to cellulose. The growth and cellulolytic activity ofN. frontalis were inhibited by glycerol, increasingly so at higher concentrations. At a concentration of 5%, glycerol totally inhibited the cellulolytic activity of the fungus. Thus, glycerol can be added to animal feed at low concentrations.     

The rumen anaerobic fungi

The anaerobic fungi represent a new group of organisms inhabiting the rumen ecosystem and possess a life cycle alternating between a motile flagellated form (zoospore) and a non-motile vegetative reproductive form (thallus). In vivo studies show extensive colonization of plant material suspended in the rumen indicating the fungi have a role in fiber digestion. Pure cultures of anaerobic fungi ferment cellulose to give lactate, acetate, CO₂ and H₂ as the major products. Ethanol and formate may also be produced. Fermentation of cellulose by the fungi in coculture with H₂-utilizing methanogens results in a shift in the fermentation pattern favouring the production of H₂ (utilized in the formation of CH₄) and acetate at the expense of the electron-sink products, lactate and ethanol. It is postulated that the methanogens in reducing the partial pressure of H₂, facilitate an increased passage of reducing equivalents towards the production of H₂ via a pyridine-nucleotide (PN)-linked hydrogenase reaction. H₂ is believed to be produced in microbodies of the fungi called hydrogenosomes which possess all of the enzymes necessary for this function including PN-linked hydrogenase. Absence of mitochondria and key electron transport components in these organisms indicate a dependence wholly on fermentative processes for growth. Anaerobic fungi also participate in hemicellulose and starch degredation but it is not yet clear whether they have a role in the degradation of lignin. Simple sugars (mono- and disaccharides) are readily utilized and their uptake is subject to similar regulatory constraints such as is found with other micro-organisms.Enzymological studies have revealed that anaerobic fungi release substantial amounts of endo-acting cellulase and protease, possibly giving them a competitive advantage over rumen bacteria in the degradation of plant structural material.     

Degradation and fermentation of cellulose by the rumen anaerobic fungi in axenic cultures or in association with cellulolytic bacteria

Three rumen anaerobic fungi—Neocallinastix frontalis MCH3,Piromyces (Piromonas) communis FL, andCaecomyces (Sphaeromonas) communis FG10—were cultured on cellulose filter paper alone or in association with one of two rumen cellulolytic bacteria,Ruminococcus flavefaciens 007 andFibrobacter succinogenes S85. Cocultures ofN. frontalis orP. communis andR. flavefaciens were markedly less effective than the fungal monocultures in degrading cellulose but more effective than the bacterial monocultures.R. flavefaciens had an antagonistic effect against both of the fungal species. In contrast, no interaction was observed between the two fungal species andF. succinogenes. Cellulose was more effectively degraded by the cocultureC. communis-R. flavefaciens than by the corresponding fungal and bacterial monocultures. The effectiveness of degradation of the cocultureC. communis-F. succinogenes was comparable to that of the bacterial strains but greater than that of the fungi; no interaction was observed between these two microorganisms.     

The fermentative characteristics of anaerobic rumen fungi

Substrate utilization and fermentation characteristics of rumen fungi of the genus Neocallimastix are described. Preliminary observations on the removal of monosaccharides from plant cell walls and the effect of fermentation products on growth of Neocallimastix sp. (isolate R1) are presented. The properties of rumen fungi are discussed in relation to their role in the rumen.     

Enumeration of cellulolytic anaerobic bacteria from the bovine rumen: Comparison of three methods

Three methods—the most probable number technique, a cellulose agar overlay on basal carbohydrate plates, and carboxymethylcellulose in basal carbohydrate plates—were compared for ease of preparation, interpretation of results, and agreement in estimation of size of the cellulolytic bacterial population in digesta samples from the rumen. The most probable number method yielded consistent detection of cellulose hydrolysis in liquid medium but required at least a 10-day incubation, and its mean was associated with wide 95% confidence intervals. The cellulose overlay method was the least consistent, and zones of hydrolysis often were difficult to see. The carboxymethylcellulose method was the easiest method for preparation and required only a 2-day incubation. The three methods estimated the same population size (all within one-half log unit of each other), but the carboxymethylcellulose method had the lowest coefficient of variation.     

Interactions between anaerobic cellulolytic bacteria and fungi in the presence of Methanobrevibacter smithii

A mixed inoculum of cellulolytic rumen bacteria depressed straw degradation by a mixed culture of cellulolytic fungi grown in the presence of Methanobrevibacter smithii. The inhibitory effect appeared to be caused by Ruminococcus albus strain JI and R. flavefaciens strain 007. Ruminococcus albus strain J1 also depressed straw degradation by the fungi, but R. albus strain SY3 and three strains of Bacteroides (Fibrobacter) succinogenes tested showed little or no inhibitory activity. It seems that some ruminococci show competitive or antagonistic activity towards certain rumen fungi.     

Dinitrogen fixation by obligate and facultative anaerobic bacteria in association with cellulolytic fungi

The anaerobic bacteriumClostridium butyricum is the major contributor to nitrogen gains by a cellulolytic/nitrogen-fixing population isolated from straw. Growth of the anaerobe is supported by the products of fungal cellulases. The facultative anaerobeEnterobacter cloacae does not make a significant direct contribution to nitrogen fixation but in association withC. butyricum allows the anaerobe to grow under aerobic conditions. The major function ofE. cloacae is though to be provision of oxygen-depleted microsites.     

不同精粗比底物下瘤胃真菌和纤维降解细菌共培养发酵特性及菌群变化

采用体外厌氧共培养技术,研究了瘤胃真菌和纤维降解细菌在不同精粗比(A组为全粗料,B组3∶7,C组5∶5,D组7∶3,E组为全精料)底物下菌群变化及其共培养发酵特性。结果表明:与0h相比,发酵至24h时B组和C组的厌氧真菌数量有较大幅度的上升,A组和D组则有所下降,E组未检测到真菌生长;纤维降解细菌随精粗比的增加呈上升趋势。发酵至48h时,各组均未检测到真菌生长;从A组到C组细菌数量呈上升趋势,此后急剧下降。DGGE结果表明,A、B和C组(精粗比低于5∶5)的DGGE图谱相似,有11条共有条带,但是当精粗比上升到7:3时,条带数目显著下降。随精料比例的增加,整个发酵期共培养系统中pH值显著下降(P<0.05)。整个发酵期间,共培养系统发酵产生的VFA主要为乙酸,丙酸和丁酸的量较少,乙酸与丙酸比值从A组到C组呈下降趋势,此后呈上升趋势。随精料比例的上升,发酵48h时总挥发性脂肪酸浓度从A组到C组呈上升趋势,此后呈下降趋势。发酵48h的羧甲基纤维素酶活和木聚糖酶活均以A组最高,而α-淀粉酶活从A组到D组逐渐增大,而E组最低,仅为B、C、D组的1/4~1/3。     

The effect of ammonia treatment on the solubilization of straw and the growth of cellulolytic rumen bacteria

Pre-treatment of straw with anhydrous ammonia increased its susceptibility to solubilization by the predominant cellulolytic bacteria from the rumen, Bacteroides succinogenes, Ruminococcus albus and R. flavefaciens. Ammonia treatment also increased the production of microbial protein and fermentation products by all three species. Scanning electron microscope observations of straw during digestion suggested that the attack of straw by these bacteria was accompanied by the formation of substantial numbers of adherent microcolonies.     

Unravelling carbon metabolism in anaerobic cellulolytic bacteria

Carbon metabolism in anaerobic cellulolytic bacteria has been investigated essentially in Clostridium thermocellum, Clostridium cellulolyticum, Fibrobacter succinogenes, Ruminococcus flavefaciens, and Ruminococcus albus. While cellulose depolymerization into soluble sugars by various cellulases is undoubtedly the first step in bacterial metabolisation of cellulose, it is not the only one to consider. Among anaerobic cellulolytic bacteria, C. cellulolyticum has been investigated metabolically the most in the past few years. Summarizing metabolic flux analyses in continuous culture using either cellobiose (a soluble cellodextrin resulting from cellulose hydrolysis) or cellulose (an insoluble biopolymer), this review aims to stress the importance of the insoluble nature of a carbon source on bacterial metabolism. Furthermore, some general and specific traits of anaerobic cellulolytic bacteria trends, namely, the importance and benefits of (i) cellodextrins with degree of polymerization higher than 2, (ii) intracellular phosphorolytic cleavage, (iii) glycogen cycling on cell bioenergetics, and (iv) carbon overflows in regulation of carbon metabolism, as well as detrimental effects of (i) soluble sugars and (ii) acidic environment on bacterial growth. Future directions for improving bacterial cellulose degradation are discussed.     

The effect of ammonia treatment on the solubilization of straw and the growth of cellulolytic rumen bacteria

Pre-treatment of straw with anhydrous ammonia increased its susceptibility to solubilization by the predominant cellulolytic bacteria from the rumen, Bacteroides succinogenes, Ruminococcus albus and R. flavefaciens. Ammonia treatment also increased the production of microbial protein and fermentation products by all three species. Scanning electron microscope observations of straw during digestion suggested that the attack of straw by these bacteria was accompanied by the formation of substantial numbers of adherent microcolonies.     

Fermentation of woods by rumen anaerobic fungi

Abstract The potential of rumen anaerobic fungi for fermenting untreated woods has been assessed using two Neocallimastix species isolated from sheep. When a strain of N. frontalis was incubated for 11 days with wood from 12 hardwood (angiosperm) species, many woods were measurably fermented, with wood from Populus tremuloides (32%) and Fagus sylvatica (21%) being the most highly degraded. This N. frontalis solubilised celulose, hemicellulose and lignin in P. tremuloides wood. Lower degradation (17%) of P. tremuloides wood by a different species of Neocallimastix showed that the choice of fungus as well as the structure and chemistry of the wood influenced the amount of wood cell wall degraded by anaerobic fungi. The amount of degradation was not related to the length of fungal rhizoids.     

Fermentation of cellodextrins by cellulolytic and noncellulolytic rumen bacteria

Water-soluble cellodextrins were prepared from microcrystalline cellulose by using fuming hydrochloric acid and acetone precipitation. This cellodextrin preparation contained only trace amounts of glucose and cellobiose and was primarily composed of cellotetraose and cellopentaose. When various species of cellulolytic and noncellulolytic bacteria were cultured with cellodextrins, their growth rates and maximal optical densities were in most cases similar to those observed with cellobiose. Time course samplings and analyses of cellodextrins by high-pressure liquid chromatography indicated that longer-chain cellodextrins were hydrolyzed extracellularly to cellobiose and cellotriose. Cellodextrin utilization by noncellulolytic rumen bacteria and extracellular hydrolysis of cellodextrins increase the possibility that cross-feeding occurs in the rumen and help to explain the high numbers of noncellulolytic bacteria in ruminants fed fibrous diets.     

Interactions among cellulolytic bacteria from an anaerobic digester

High cellulolytic activity of particular strains did not cause dominance of one, or a few, species of fiber-digesting bacteria in a cattlewaste anaerobic digester. The population contained a large number of species and varieties with different cellulolytic and fiber-digesting activities. Although mixed cultures of some of these bacteria showed no intereffects, with others, cellulolysis was less or in some cases greater than that shown by individual components of the cultures. The interactions were probably related to effects on growth of the bacteria rather than on activities of components of the cellulase enzyme complex, and culture filtrates of two of the more numerous cellulolytic species ofClostridium affected growth of other cellulolytic bacteria. The inhibitory factor(s) appeared to be of bacteriocin type, but the stimulatory factor(s) was unknown. It was suggested that these interactions are localized or short-lived in the digester, and so the population remains in a dynamic steady state.Some inhibitions of growth of rumen cellulolytic bacteria were caused by the digester bacteria, but it was suggested that factors other than these inhibitions are responsible for the absence of rumen bacteria from anaerobic digesters.     

Characterization of chitinases of polycentric anaerobic rumen fungi

Chitinolytic systems of anaerobic polycentric rumen fungi of genera Orpinomyces and Anaeromyces were investigated in three crude enzyme fractions - extracellular, cytosolic and cell-wall. Endochitinase was found as a dominant enzyme with highest activity in the cytosolic fraction. Endochitinases of both genera were stable at pH 4.5-7.0 with optimum at 6.5. The Orpinomyces endochitinase was stable up to 50 degrees C with an optimum for enzyme activity at 50 degrees C; similarly, Anaeromyces endochitinase was stable up to 40 degrees C with optimum at 40 degrees C. The most suitable substrate for both endochitinases was fungal cell-wall chitin. Enzyme activities were inhibited by Hg(2+) and Mn(2+), and activated by Mg(2+) and Fe(3+). Both endochitinases were inhibited by 10 mmol/L SDS and activated by iodoacetamide.     

Magnesium requirement of some of the principal rumen cellulolytic bacteria

Information available on the role of Mg for growth and cellulose degradation by rumen bacteria is both limited and inconsistent. In this study, the Mg requirements for two strains each of the cellulolytic rumen species Fibrobacter succinogenes (A3c and S85), Ruminococcus albus (7 and 8) and Ruminococcus flavefaciens (B34b and C94) were investigated. Maximum growth, rate of growth and lag time were all measured using a complete factorial design, 2(3)×6; factors were: strains (2), within species (3) and Mg concentrations (6). R. flavefaciens was the only species that did not grow when Mg was singly deleted from the media, and both strains exhibited a linear growth response to increasing Mg concentrations (P<0.001). The requirement for R. flavefaciens B34b was estimated as 0.54 mM; whereas the requirement for R. flavefaciens C94 was >0.82 as there was no plateau in growth. Although not an absolute requirement for growth, strains of the two other species of cellulolytic bacteria all responded to increasing Mg concentrations. For F. succinogenes S85, R. albus 7 and R. albus 8, their requirement estimated from maximum growth was 0.56, 0.52 and 0.51, respectively. A requirement for F. succinogenes A3c could not be calculated because there was no solution for contrasts. Whether R. flavefaciens had a Mg requirement for cellulose degradation was determined in NH₃-free cellulose media, using a 2×4 factorial design, 2 strains and 4 treatments. Both strains of R. flavefaciens were found to have an absolute Mg requirement for cellulose degradation. Based on reported concentrations of Mg in the rumen, 1.0 to 10.1 mM, it seems unlikely that an in vivo deficiency of this element would occur.