Isolation and partial characterization of cellulose-degrading strain of Streptomyces sp. LX from soil

X. LI AND P. GAO. 1996. A new bacterium, Streptomyces sp. LX, was isolated from soil, which was aerobic Gram-positive and could decompose crystalline cellulose completely. Endo-cellulase with CMC-liquefying activity was detected when α-cellulose, Avicel, Whatman CF₁₁ or CMC was used as carbon source, and its production varied with nature of the carbon source. Only traces of reducing sugar were found in cultures during incubation. This strain could produce FPase, β-glucanase and short fibre generating activity. Exo- and endo-cellulase were detected in cultures by measuring formation of total sugar but were not detected by determining release of reducing sugar.     

The processive endoglucanase EngZ is active in crystalline cellulose degradation as a cellulosomal subunit of Clostridium cellulovorans

Clostridium cellulovorans produces an efficient enzyme complex for the degradation of lignocellulosic biomass. In our previous study, we detected and identified protein spots that interacted with a fluorescently labeled cohesin biomarker via two-dimensional gel electrophoresis. One novel, putative cellulosomal protein (referred to as endoglucanase Z) contains a catalytic module from the glycosyl hydrolase family (GH9) and demonstrated higher levels of expression than other cellulosomal cellulases in Avicel-containing cultures. Purified EngZ had optimal activity at pH 7.0, 40°C, and the major hydrolysis product from the cellooligosaccharides was cellobiose. EngZ's specific activity toward crystalline cellulose (Avicel and acid-swollen cellulose) was 10-20-fold higher than other cellulosomal cellulase activities. A large percentage of the reducing ends that were produced by this enzyme from acid-swollen cellulose were released as soluble sugar. EngZ has the capability of reducing the viscosity of Avicel at an intermediate-level between exo- and endo-typing cellulases, suggesting that it is a processive endoglucanase. In conclusion, EngZ was highly expressed in cellulolytic systems and demonstrated processive endoglucanase activity, suggesting that it plays a major role in the hydrolysis of crystalline cellulose and acts as a cellulosomal enzyme in C. cellulovorans.     

Cellulase biosynthesis during degradation of cellulose derivatives by Thermomonospora curvata

A variety of commercially used cellulose derivatives were compared with crystalline cellulose as substrates for induction of cellulase biosynthesis in the actinomycete Thermomonospora curvata. Cellulase induction during growth on uncoated cellophane was as rapid as that on crystalline cellulose, but on coated cellophanes, induction was delayed. Susceptibility to enzymatic attack determined the inductive potential of the substrate. Cellulose acetate was a poor substrate because of its extreme recalcitrance to attack. With other cellulose derivatives, soluble sugar accumulation caused a transient repression of cellulase biosynthesis, but the ratio of cellobiose (a cellulase inducer) to glucose (a cellulase repressor) was not a controlling factor. Crystalline cellulose yielded the lowest inducer/repressor sugar ratio (1.1:1 compared to 3.8–4.0:1 for cellulose derivatives), but supported the highest cellulase production. Glucose could not repress cellulase biosynthesis in the presence of cellobiose due to the strong preference for uptake of the disaccharide even by glucose-grown cells.     

Cellulolytic Activity of Clostridium acetobutylicum

Clostridium acetobutylicum NRRL B527 and ATCC 824 exhibited extracellular and cell-bound endoglucanase and cellobiase activities during growth in a chemically defined medium with cellobiose as the sole source of carbohydrate. For both strains, the endoglucanase was found to be mainly extracellular (70 to 90%) during growth in continuous or batch cultures with the pH maintained at 5.2, whereas the cellobiase was mainly cell associated (60 to 90%). During continuous cultivation of strain B527 with cellobiose as the limiting nutrient, maximum production of the endoglucanase and cellobiase occurred at pH values of 5.2 and 4.8, respectively. In the carbon-limited continuous cultures, strain 824 produced similar levels of endoglucanase, cellobiosidase, and cellobiase activities regardless of the carbon source used. However, in ammonium- or phosphate-limited cultures, with an excess of glucose, only 1/10 of the endoglucanase was produced, and neither cellobiosidase nor cellobiase activities were detectable. A crude extracellular enzyme preparation from strain B527 hydrolyzed carboxymethylcellulose and phosphoric acid-swollen cellulose readily and microcrystalline cellulose (A vicel) to a lesser extent. Glucose accounted for more than 90% of the reducing sugar produced by the hydrolysis of acid-swollen cellulose and Avicel. Strain B527 did not grow in medium with acid-swollen cellulose as the sole source of carbohydrate, although it grew readily on the products obtained by hydrolyzing the cellulose in vitro with a preparation of extracellular cellulase derived from the same organism.     

Regulation of xylanase activity in cellulomonas sp. IIbc

The regulation mechanism governing the xylanolytic activity in the strain Cellulomonas sp. IIbc was studied. High levels of activity were detected during the cultivation on cellulose as the only carbon source. No activity was produced with glucose, xylose or cellobiose cultures, but in the last one, the synthesis was de-repressed when the sugar concentration dropped to 0.2%. The activity was not inhibited by glucose, cellobiose and xylose up to 1% concentration. A basal constitutive synthesis was detected in nutrient broth cultures. At the same time, xylose and cellobiose acted as inducers of the xylanase activity.     

Kinetics of Cellulose Digestion by Fibrobacter succinogenes S85

Growing cultures of Fibrobacter succinogenes S85 digested cellulose at a rapid rate, but nongrowing cells and cell extracts did not have detectable crystalline cellulase activity. Cells that had been growing exponentially on cellobiose initiated cellulose digestion and succinate production immediately, and cellulose-dependent succinate production could be used as an index of enzyme activity against crystalline cellulose. Cells incubated with cellulose never produced detectable cellobiose, and cells that were preincubated for a short time with thiocellobiose lost their ability to digest cellulose (competitive inhibition [K(infi)] of only 0.2 mg/ml or 0.56 mM). Based on these results, the crystalline cellulases of F. succinogenes were very sensitive to feedback inhibition. Different cellulose sources bound different amounts of Congo red, and the binding capacity was HCl-regenerated cellulose > ball-milled cellulose > Sigmacel > Avicel > filter paper. Congo red binding capacity was highly correlated with the maximum rates of metabolism of cellulose digestion and inversely related to K(infm). Congo red (250 (mu)g/ml) did not inhibit the growth of F. succinogenes S85 on cellobiose, but this concentration of Congo red inhibited the rate of ball-milled cellulose digestion. A Lineweaver-Burk plot of ball-milled cellulose digestion rate versus the amount of cellulose indicated that Congo red was a competitive inhibitor of cellulose digestion (K(infi) was 250 (mu)g/ml).     

Characterization of the extracellular cellulase from a mesophilic clostridium (strain C7).

An extracellular, 700,000-Mr multiprotein complex that catalyzed the hydrolysis of crystalline cellulose (Avicel) was isolated from cultures of Clostridium sp. strain C7, a mesophile from freshwater sediment. In addition to cellulose (Avicel, ball-milled filter paper), the multiprotein complex hydrolyzed carboxymethylcellulose, cellodextrins, xylan, and xylooligosaccharides. Hydrolysis of cellulose or cellotetraose by the complex yielded cellobiose as the main product. Cellopentaose or cellohexaose was hydrolyzed by the complex to cellotriose or cellotetraose, respectively, in addition to cellobiose. Xylobiose was the main product of xylan hydrolysis, and xylobiose and xylotriose were the major products of xylooligosaccharide hydrolysis. Activity (Avicelase) resulting in hydrolysis of crystalline cellulose required Ca2+ and a reducing agent. The multiprotein complex had temperature optima for Avicelase, carboxymethylcellulase, and xylanase activities at 45, 55, and 55 degrees C, respectively, and pH optima at 5.6 to 5.8, 5.5, and 6.55, respectively. Electron microscopy of the 700,000-Mr enzyme complex revealed particles relatively uniform in size (12 to 15 nm wide) and apparently composed of subunit structures. Elution of strain C7 concentrated culture fluid from Sephacryl S-300 columns yielded an A280 peak in the 130,000-Mr region. Pooled fractions from the 130,000-Mr peak had carboxymethylcellulase activity but lacked Avicelase activity. Except for the inability to hydrolyze cellulose, the 130,000-Mr preparation had a substrate specificity identical to that of the 700,000-Mr protein complex. A comparison by immunoblotting techniques of proteins in the 130,000- and 700,000-Mr preparations, indicated that the two enzyme preparations had cross-reacting antigenic determinants.     

Characterization of a multi-function processive endoglucanase CHU_2103 from Cytophaga hutchinsonii

Cytophaga hutchinsonii is a Gram-negative gliding bacterium which can efficiently degrade crystalline cellulose by an unknown strategy. Genomic analysis suggests the C. hutchinsonii genome lacks homologs to an obvious exoglucanase that previously seemed essential for cellulose degradation. One of the putative endoglucanases, CHU_2103, was successfully expressed in Escherichia coli JM109 and identified as a processive endoglucanase with transglycosylation activity. It could hydrolyze carboxymethyl cellulose (CMC) into cellodextrins and rapidly decrease the viscosity of CMC. When regenerated amorphous cellulose (RAC) was degraded by CHU_2103, the ratio of the soluble to insoluble reducing sugars was 3.72 after 3 h with cellobiose and cellotriose as the main products, indicating that CHU_2103 was a processive endoglucanase. CHU_2103 could degrade cellodextrins of degree of polymerization ≥3. It hydrolyzed p-nitrophenyl β-d-cellodextrins by cutting glucose or cellobiose from the non-reducing end. Meanwhile, some larger-molecular-weight cellodextrins could be detected, indicating it also had transglycosylation activity. Without carbohydrate-binding module (CBM), CHU_2103 could bind to crystalline cellulose and acted processively on it. Site-directed mutation of CHU_2103 demonstrated that the conserved aromatic amino acid W197 in the catalytic domain was essential not only for its processive activity, but also its cellulose binding ability.     

Production of cellobiose by enzymatic hydrolysis: removal of beta-glucosidase from cellulase by affinity precipitation using chitosan

Removal of beta-glucosidase (BG) from cellulase is essential to the enzymatic production of cellobiose from cellulose because of the high reactivity of BG with cellobiose to form glucose. Chitosan is a reversibly soluble-insoluble polymer depending on pH, and it has an affinity with the other components, endo-beta-1,4-glucanase and cellobiohydrolase, or cellulase. The affinity precipitation technique using chitosan is an effective way to fractionate cellulase for the above purpose. Hydrolysis experiments of cellulose with the residual fractionated enzyme gave higher cellobiose contents in the soluble sugar products. (c) 1993 John Wiley & Sons, Inc.     

Cellobiose-oxidizing enzyme from a newly isolated cellulolytic bacterium Cytophaga sp. LX-7

Summary The cellobiose oxidizing enzyme of the newly isolated cellulolytic bacterium Cytophaga sp. LX-7 was produced extracellularly when grown on cellulose or other saccharides, which was previously noted only in fungi. The enzyme could use not only cellobiose, maltose, glucose and other saccharides but also cellulose as substrates, and use dichlorophenol indophenol and oxygen as electron acceptors.     

Component-specific stimulation of cellulase secretion in Thermomonospora curvata by the surfactant Tween 80

The non-ionic surfactant, Tween 80, stimulated the secretion of extracellular proteins by 35–140% in Thermomonospora curvata during growth on a variety of substrates. Cellulase secretion was also stimulated but fractionation of extracellular proteins by ion-exchange high performance liquid chromatography showed that this stimulation was largely confined to a single enzymatic component (or group of closely related components) active against crystalline cellulose. The surfactant's effect was more pronounced during growth on cellobiose octaacetate than on the soluble sugar, cellobiose, or on crystalline cellulose.     

新分离菌Streptomyces产小分子CMC液化酶的研究

新分离纤维素分解菌经鉴定为链霉菌属中的新种,暂定名为ＳｔｒｅｐｔｏｍｙｃｅｓｓｐＬＸ,革兰氏阳性,产气生孢子,好氧生长,最适生长温度和ＰＨ为３０℃和７．２。该菌能够完全降解纤维素且不产生还原糖,并分泌一种分子量为９．２ｋｕ的液化性质的内切纤维素液化酶,亦即ＣＭＣ液化酶,该酶在裂解滤纸为短纤维的过程中既没有还原糖生成,也没有失重现象发生,而且纤维素的聚合度也几乎没有明显变化,推测可能是一种能打开氢键的小分子解链酶。     

The characteristics of a new non-spore-forming cellulolytic mesophilic anaerobe strain CM126 isolated from municipal sewage sludge

A new mesophilic anaerobic cellulolytic bacterium, CM126, was isolated from an anaerobic sewage sludge digester. The organism was non-spore-forming, rod-shaped, Gram-negative and motile with peritrichous flagella. It fermented microcrystalline Avicel cellulose, xylan, Solka floc cellulose, filter paper, L-arabinose, D-xylose, beta-methyl xyloside, D-glucose, cellobiose and xylitol and produced indole. The % G + C content was 36. Acetic acid, ethanol, lactic acid, pyruvic acid, carbon dioxide and hydrogen were produced as metabolic products. This strain could grow at 20-44.5 degrees C and at pH values 5.2-7.4 with optimal growth at 37-41.5 degrees C and pH 7. Both endoglucanase and xylanase were detected in the supernatant fluid of a culture grown on medium containing Avicel cellulose and cellobiose. Exoglucanase could not be found in either supernatant fluid or the cell lysate. When cellulose and cellobiose fermentation were compared, the enzyme production rate in cellobiose fermentation was higher than in cellulose fermentation. The optimum pH for both enzyme activities was 5.0, the optimum temperature was 40 degrees C for the endoglucanase and 50 degrees C for the xylanase. Both enzyme activities were inhibited at 70 degrees C Co-culture of this organism with a Methanosarcina sp. (A145) had no effect on cellulose degradation and both endoglucanase and xylanase were stable in the co-culture.     

The brown-rot basidiomycete Fomitopsis palustris has the endo-glucanases capable of degrading microcrystalline cellulose

Two endoglucanases with processive cellulase activities, produced from Fomitopsis palustris grown on 2% microcrystalline cellulose (Avicel), were purified to homogeneity by anion-exchange and gel filtration column chromatography systems. SDS-PAGE analysis indicated that the molecular masses of the purified enzymes were 47 kDa and 35 kDa, respectively. The amino acid sequence analysis of the 47-kDa protein (EG47) showed a sequence similarity with fungal glycoside hydrolase family 5 endoglucanase from the white-rot fungus Phanerochaete chrysosporium. N-terminal and internal amino acid sequences of the 35-kDa protein (EG35), however, had no homology with any other glycosylhydrolases, although the enzyme had high specific activity against carboxymethyl cellulose, which is a typical substrate for endoglucanases. The initial rate of Avicel hydrolysis by EG35 was relatively fast for 48 h, and the amount of soluble reducing sugar released after 96 h was 100 microg/ml. Although EG47 also hydrolyzed Avicel, the hydrolysis rate was lower than that of EG35. Thin layer chromatography analysis of the hydrolysis products released from Avicel indicated that the main product was cellobiose, suggesting that the brown-rot fungus possesses processive EGs capable of degrading crystalline cellulose.     

The characteristics of a new non-spore-forming cellulolytic mesophilic anaerobe strain CM126 isolated from municipal sewage sludge

A new mesophilic anaerobic cellulolytic bacterium, CM126, was isolated from an anaerobic sewage sludge digester. The organism was non-spore-forming, rod-shaped, Gram-negative and motile with peritrichous flagella. It fermented microcrystalline Avicel cellulose, xylan, Solka floc cellulose, filter paper, L-arabinose, D-xylose, β-methyl xyloside, D-glucose, cellobiose and xylitol and produced indole. The % G + C content was 36. Acetic acid, ethanol, lactic acid, pyruvic acid, carbon dioxide and hydrogen were produced as metabolic products. This strain could grow at 20–44·5°C and at pH values 5·2–7·4 with optimal growth at 37–41·5°C and pH 7. Both endoglucanase and xylanase were detected in the supernatant fluid of a culture grown on medium containing Avicel cellulose and cellobiose. Exoglucanase could not be found in either supernatant fluid or the cell lysate. When cellulose and cellobiose fermentation were compared, the enzyme production rate in cellobiose fermentation was higher than in cellulose fermentation. The optimum pH for both enzyme activities was 5·0, the optimum temperature was 40°C for the endoglucanase and 50°C for the xylanase. Both enzyme activities were inhibited at 70°C. Co-culture of this organism with a Methanosarcina sp. (A145) had no effect on cellulose degradation and both endoglucanase and xylanase were stable in the co-culture.     

Penicillium verruculosum WA 30 a new source of cellulase

Summary Of fungi 110 strains were screened for extracellular cellulase production in shake flask experiments. Twelve strains produced the enzyme in significant quantity. Since the enzyme activity was assayed by different methods (liberation of reducing sugar from cotton, filter paper, carboxymethylcellulose and cellobiose), the estimation of the productivity of the strains differed according to the substrate used. The best cotton degrading activity per fermentation volume as well as per mg of secreted soluble protein was achieved by Penicillium verruculosum WA 30, a wild-type strain, for which the cellulase productivity has not yet been published. The cotton degrading (so-called C₁) activity was successfully enhanced nearly threefold in medium experiments. Analyses of saccharification digests showed that glucose was the predominant product, with negligible amounts of cellobiose. The pH and temperature optima for WA 30 cellulase complex were pH 4.2 and 60°C.     

The Effect of Cellobiose,Glucose, and Cellulose on the Survival of <Emphasis Type="Italic">Fibrobacter succinogenes</Emphasis> A3C Cultures Grown Under Ammonia Limitation

The ruminal, cellulolytic bacterium, Fibrobacter succinogenes A3C, grew rapidly on cellulose, cellobiose, or glucose, but it could not withstand long periods of energy source starvation. If ammonia was limiting and either cellobiose or glucose was in excess, the viability declined even faster. The carbohydrate-excess, ammonia-limited cultures did not spill energy, but they accumulated large amounts of cellular polysaccharide. Cultures that were carbohydrate-limited had approximately 4 nmol ATP mg cell protein^–1, but ATP could not be detected in cultures that had an excess of soluble carbohydrates. However, if F. succinogenes A3C was provided with excess cellulose and ammonia was limiting, ATP did not decline, and the cultures digested the cellulose soon after additional nitrogen sources were added. From these results, it appears that excess soluble carbohydrates can promote the death of F. succinogenes, but cellulose does not.     

Saccharification of cellulose by the cellulolytic enzyme system of Thermomonospora sp. II. Hydrolysis of cellulosic substrates

A saccharification of cellulosic material using culture filtrate from the stationary phase of a culture of Thermomonospora sp. produced primarily cellobiose up to levels inhibitory to further saccharification, while the use of whole broth resulted in the production of glucose as well. Glucose production was enhanced and continued throughout the saccharification (24–36 hr) by several additions of cellobiase activity in the form of culture solids. Using Solka-Floc as substrate, the “difference sugar” level (total soluble sugar minus glucose) rapidly rose to the same relatively stable concentration under various hydrolysis conditions, which was independent of the total sugar and glucose concentrations. A rapid hydrolusis rate was observed initially during saccharification, followed by a much slower rate of sugar production. Repeated centrifugation of the reaction mixture and replacement of the supernatant with fresh enzyme solution resulted each time in the reinitiation of a rapid hydrolysis rate. Saccharifications using A vicel microcrystalline cellulose, acid-swollen cellulose, and cotton as substrates were also studied. A modified method of making phosphoric-acid swollen cellulose is described. Saccharification of this substrate by culture filtrate and sequential additions of culture solids resulted in an inverse relationship between the attained glucose concentration and cellobiose-cellotriose concentrations.     

Cellulases: Biosynthesis and applications

Strains of Trichoderma, particularly T. reesei and its mutants, are good sources of extracellular cellulase suitable for practical saccharification. They secrete a complete cellulase complex containing endo- and exo-glucanases plus β-glucosidase (cellobiase) which act syngergistically to degrade totally even highly resistant crystalline cellulose to soluble sugars. All strains investigated to date are inducible by cellulose, lactose, or sophorose, and all are repressible by glucose. Induction, synthesis and secretion of the β-glucanase enzymes appear to be closely associated. The composition and properties of the enzyme complex are similar regardless of the strain or inducing substrate although quantities of the enzyme secreted by the mutants are higher. Enzyme yields are proportional to initial cellulose concentration. Up to 15 filter paper cellulase units (20 mg of cellulase protein) per ml and productivities up to 80 cellulase units (130 mg cellulase protein) per litre per hour have been attained on 6% cellulose. The economics of glucose production are not yet competitive due to the low specific activity of cellulase (0.6 filter paper cellulase units/mg protein) and poor efficiency (about 15% of predicted sugar levels in 24 h hydrolyses of 10–25% substrate). As hydrolysis proceeds, the enzyme reaction slows due to increasing resistance of the residue, product inhibition, and enzyme inactivation. These problems are being attacked by use of pretreatments to increase the quantity of amorphous cellulose, addition of β-glucosidase to reduce cellobiose inhibition, and studies of means to overcome instability and increase efficiency of the cellulases. Indications are that carbon compounds derived from enzymatic hydrolysis of cellulose will be used as fermentation and chemical feedstocks as soon as the process economics are favourable for such application.     

Characterization of the cellulolytic activity of a Bacillus isolate

A group I Bacillus strain, DLG, was isolated and characterized as being most closely related to Bacillus subtilis. When grown on any of a variety of sugars, the culture supernatant of this isolate was found to possess cellulolytic activity, as demonstrated by degradation of trinitrophenyl-carboxymethyl cellulose. Growth in medium containing cellobiose or glucose resulted in the greatest production of cellulolytic activity. The cellulolytic activity was not produced until the stationary phase of growth, and the addition of glucose or cellobiose to a culture in this phase had no apparent effect on enzyme production. Fractionation of the culture supernatant showed that the molecular weight of the enzymatic activity was less than 100,000. Maximum cellulolytic activity in assays was observed at pH 4.8 and at 58C, although maximum thermal stability of the activity. Kinetic experiments suggested that more than one enzyme was acting upon trinitrophenyl-carboxymethyl cellulose. Exocellular protein produced by this Bacillus isolate showed roughly one-fifth the cellulolytic activity displayed by Trichoderma reesei C30 on noncrystalline, cellulosic substrates. In contrast to T. reesei cellulase, the Bacillus enzymatic activity showed no ability to degrade crystalline forms of cellulose, nor was cellobiase activity detectable.