Isolation of Cellulolytic Anaerobic Extreme Thermophiles from New Zealand Thermal Sites

Avicel enrichment cultures from 47 thermal-pool sites in the New Zealand Rotorua-Taupo region were screened for growth and carboxymethyl cellulase activity at 75°C. Eight anaerobic cellulolytic cultures were obtained. The effect of temperature on carboxymethyl cellulase activity was measured, and bacteria were isolated from the five best cultures. Bacteria from two sources designated TP8 and TP10 grew at 75°C, accumulated reducing sugar in the growth medium and gave free cellulases with avicelase activity. Bacteria from sources designated Tok4, Tok8, and Wai21 grew at 75°C, accumulated no free sugars in the medium, and gave free carboxymethyl cellulases with virtually no avicelase activity. All were obligate anaerobic nonsporeforming rods which stained gram negative, grew on pentoses as well as hexoses, and gave ethanol and acetate as major fermentation end products. The isolated strain which produced the most active and stable cellulases (trivially designated TP8.T) had lower rates of free endocellulase accumulation at 75°C than did Clostridium thermocellum at 60°C, but its cellulase activity against avicel and filter paper in culture supernatants was comparable. Tested at 85°C, TP8.T carboxymethyl cellulases included components which were very stable, whereas C. thermocellum carboxymethyl cellulases were all rapidly inactivated. The TP8.T avicelase activity was relatively unaffected by Triton X-100, EDTA, and dithiothreitol. Evidence was obtained for the existence of unisolated, cellulolytic extreme thermophiles producing cellulases which were more stable and active than those from TP8.T.     

Isolation, characterization and fibre degradation potential of anaerobic rumen fungi from cattle

A total of 20 fungal cultures were isolated from the rumen of cattle fed a high fibre-containing diet. All of the isolates showed polycentric growth patterns and were identified as different strains of Orpinomyces and Anaeromyces. Enzyme assays of most of the isolates showed the highest carboxymethylcellulase (CMCase) and xylanase activities after 96 h of growth and highest avicelase activity after 120 h. Among all enzymes tested, xylanase activity was the highest, followed by CMCase and avicelase. The results of the in vitro fibre digestibility and rumen fermentation analyses revealed that the addition of fungal cultures significantly increased acetate, in vitro dry matter digestibility, partition factor values and microbial biomass synthesis levels. Overall, Orpinomyces spp. were found to be the better enzyme producers and fibre degraders than Anaeromyces spp.     

Cellulolytic enzymes for the hydrolysis of leached beet cosette

Summary Cellulolytic fungi were isolated from rotting leaves and tested for extra-cellular cellulase activities (CMCase, avicelase, cellobiase and xylanase). The effect of the proportion of the enzyme activities on the rate of degradation of leached beet cosette was observed using a range of supernatant fluids in appropriate combinations. At low cosette concentrations (1.5–3.0 g/l), avicelase and cellobiase were the rate limiting enzymes; avicelase in the initial stages of reaction and cellobiase after 6–8 hours, when cellobiose inhibition becomes important. A ratio of celiobiase to avicelase of approx 2.0 was established as appropriate. At higher substrate concentrations (10 g/l, 40 g/l) the best cellobiase to avicelase ratio was maintained and up to 40% hydrolysis was obtained in the 10 g/l incubation with 10 Uav/l and 20 Ucellob/l. At 100 g/l cosette concentration, substrate inhibition was observed.     

Effect of Host Diet and Hindgut Microbial Composition on Cellulolytic Activity in the Hindgut of the American Cockroach, Periplaneta americana

Cellulase activity measured as filter paper digesting activity (FPase) and carboxymethyl cellulase (CMCase) was demonstrated in hindgut extracts of the cockroach Periplaneta americana. The highest activities measured amounted to 0.89 and 0.12 U · ml^-1 for CMCase and FPase, respectively. The cellulolytic capacity of the hindgut population increased dramatically when protozoa were present, and the activities were found to vary depending on the feeding regimen. Cellulose-rich diets induced high protozoal numbers, resulting in a high cellulase activity. A close correlation was found between the number of Nyctotherus ovalis organisms, the major protozoans in the hindgut, and both FPase and CMCase activity. Since the numbers of this protozoan also correlated with the methane production of the insect, it appears that N. ovalis is responsible for the major part of cellulolytic and methanogenic activity found in the hindgut of P. americana.     

Characterization of a novel thermophilic, cellulose-degrading bacterium Paenibacillus sp. strain B39

Aims:  The aims of this study were to identify and characterize the novel thermophilic, cellulose-degrading bacterium Paenibacillus sp. strain B39.
Methods and Results:  Strain B39 was closely related to Paenibacillus cookii in 16S rRNA gene sequence. Nonetheless, this isolate can be identified as a novel Paenibacillus sp. with respect to its physiological characteristics, biochemical reactions, and profiles of fatty acid compositions. A cellulase with both CMCase and avicelase activities was secreted from strain B39 and purified by ion-exchange chromatography. By sodium dodecyl sulfate–polyacrylamide gel electrophoresis analysis, the molecular weight of B39 cellulase was determined as 148 kDa, which was much higher than other cellulases currently reported from Paenibacillus species. The enzyme showed a maximum CMCase activity at 60°C and pH 6·5. Addition of 1 mmol l⁻¹ of Ca²⁺ markedly enhanced both CMCase and avicelase activities of the enzyme.
Conclusions:  We have identified and characterized a novel thermophilic Paenibacillus sp. strain B39 which produced a high-molecular weight cellulase with both CMCase and avicelase activities.
Significance and Impact of the Study:  Based on the ability to hydrolyse CMC and avicel, the cellulase produced by Paenibacillus sp. strain B39 would have potential applications in cellulose biodegradation.     

Insertion of Endocellulase Catalytic Domains into Thermostable Consensus Ankyrin Scaffolds: Effects on Stability and Cellulolytic Activity

Degradation of cellulose for biofuels production holds promise in solving important environmental and economic problems. However, the low activities (and thus high enzyme-to-substrate ratios needed) of hydrolytic cellulase enzymes, which convert cellulose into simple sugars, remain a major barrier. As a potential strategy to stabilize cellulases and enhance their activities, we have embedded cellulases of extremophiles into hyperstable α-helical consensus ankyrin domain scaffolds. We found the catalytic domains CelA (CA, GH8; Clostridium thermocellum) and Cel12A (C12A, GH12; Thermotoga maritima) to be stable in the context of the ankyrin scaffold and to be active against both soluble and insoluble substrates. The ankyrin repeats in each fusion are folded, although it appears that for the C12A catalytic domain (CD; where the N and C termini are distant in the crystal structure), the two flanking ankyrin domains are independent, whereas for CA (where termini are close), the flanking ankyrin domains stabilize each other. Although the activity of CA is unchanged in the context of the ankyrin scaffold, the activity of C12A is increased between 2- and 6-fold (for regenerated amorphous cellulose and carboxymethyl cellulose substrates) at high temperatures. For C12A, activity increases with the number of flanking ankyrin repeats. These results showed ankyrin arrays to be a promising scaffold for constructing designer cellulosomes, preserving or enhancing enzymatic activity and retaining thermostability. This modular architecture will make it possible to arrange multiple cellulase domains at a precise spacing within a single polypeptide, allowing us to search for spacings that may optimize reactivity toward the repetitive cellulose lattice.     

Prospects for ethanol production from cellulose withClostridium thermocellum-Bacillus stearothermophilus co-cultures

Summary A lactate dehydrogenase deficient, high ethanol yielding mutant ofB. stearothermophilus was successfully co-cultured withC. thermocellum on cellulose. The co-culture produced 50% more ethanol and a 75% higher level of CMCase activity than theC. thermocellum mono-culture.     

Characteristics of Clostridium thermocellum strain SS8: A broad saccharolytic thermophile

Clostridium thermocellum SS8 produced both carboxymethylcellulase (CMCase) and Avicelase when grown on cellulose. CMCase activity was unaffected by Ca²⁺, Mg²⁺, dithionate or dithiothreitol (DTT). Avicelase activity increased 2-fold with 5 mM DTT and 10 mM Ca²⁺. Cellulase and amylase were produced when a celluloseadapted culture was grown on starch. The mould grew best on sucrose and was inhibited by NaCl above 10 g/l.     

Characterization of Clostridium thermocellum Isolates Grown on Cellulose and Sugarcane Bagasse

Although plant cell walls may be degraded by microbial free enzymes, many bacteria degrade cellulose via enzyme complexes called cellulosomes. The study of the structures and mechanisms of these large macromolecular complexes is an active and ongoing research topic, with the goal of developing methods to improve lignocellulosic biomass conversion using cellulosomes. The aim of the present work was to evaluate and characterize the holocellulolytic activities produced by two new isolates (ISO1 and ISO2) of the spore-forming thermophilic anaerobic bacterium Clostridium thermocellum, during growth on crystalline cellulose and sugarcane bagasse, in comparison with activities obtained from the C. thermocellum strain CthJW. The pH and temperature values for optimal growth of the isolates were pH 7 and 60 °C, respectively. The isolates produced cellulolytic, xylanolytic, and pectinolytic activities when cultured on crystalline cellulose or sugarcane bagasse, which have never been used previously as the sole carbon source for these bacteria. The profiles of secreted proteins for these isolates, ISO1 and ISO2, were quite different from those obtained for the standard strain CthJW and from each other, as shown by 2D gel electrophoresis maps, and these profiles also depend on the carbon source used. Different protein isoforms were also detected in the maps for all growth conditions and bacterial strains. MALDI-TOF mass spectrometry was used to identify the differentially expressed proteins for ISO1 and ISO2 under growth in the presence of cellulose as carbon source. Twenty-five differentially expressed spots were identified and grouped into 8 functional categories: metabolism (20 %), motor function (20 %), protein synthesis (12 %), oxidative stress (16 %), secretory pathway (12 %), cellulose hydrolysis (4 %), protein folding (4 %), and defense (12 %). Spots 200 and 197, identified as a glycosyl hydrolase family member 9 and as a chaperone GroEL, respectively, were detected for all isolates and are potentially related to cellulosome architecture.     

Enhanced production of cellulases byCellulomonas strains grown on different cellulosic residues

Cellulomonas strains consumed commercial cellulose, cellulosic residues, xylan, cellobiose and carboxymethyl cellulose (CMC) as carbon sources in liquid culture, the growth being the most on cellobiose medium. All three components of the cellulase complex ofCellulomonas were produced when the organisms utilized all substrates as sole carbon and energy sources. The filter-paper cellulase (FPase) and endo-glucanase (CMCase) activities were higher in media containing α-cellulose and cellulosic residues than in media containing CMC, cellobiose, and xylan. Cell-free supernatants of all organisms exhibited greater CMC hydrolyzing activity than filter paper and β-glucoside hydrolyzing activities. All strains synthesized β-glucosidase maximally on cellobiose followed by commercial cellulose and cellulosic residues.C. biazotea produced the highest FPase and CMCase activity during growth on α-cellulose. It was followed byC. flavigena, C. cellasea, andC. fimi. Endo-glucanase and FPase from all organisms were secreted into the medium; 10–13 % became adsorbed on the surface of the insoluble substrates and could be successfully eluted using Tween 80. β-Glucosidase was located in cell extracts from all organisms.C. biazotea produced FPase and β-glucosidase activities several-fold greater than those produced by many other strains ofCellulomonas and some other cellulolytic bacteria and fungi. These studies were supported byPakistan Atomic Energy Commission. Some chemicals were purchased from funds allocated byUnited States Agency for International Development, Washington (DC, USA), under PSTC proposal 6.163.     

Cellulolytic and physiological properties of Clostridium thermocellum

Three strains of Clostridium thermocellum obtained from various sources were found to have nearly identical deoxyribonucleic acid guanosine plus cytosine contents that ranged from 38.1–39.5 mole-%. All strain examined fermented only cellulose and cellulose derivatives, but not glucose, or xylose or other sugars. The principal cellulose fermentation products were ethanol, lactate, acetate, hydrogen and carbon dioxide. Growth of C. thermocellum on cellulose resulted in the production of extracellular cellulase that was non-oxygen labile, was thermally stable at 70° C for 45 min and adsorbed strongly on cellulose. Production of cellulase during fermentation correlated linearly with growth and cellulose degradation. Both the yield and specific activity of crude cellulase varied considerably with the specific growth substrates. Highest cellulase yield was obtained when grown on native cellulose, -cellulose and low degree of polymerization cellulose but not carboxymethylcellulose or other carbohydrate sources. Cellulase activity was not detected when cells were grown on cellobiose. Crude extracellular protein preparations lacked proteolytic and cellobiase activity. The pH and temperafure optima for endoglucanase activity were 5.2 and 65° C, respectively, while that of the exoglucanase activity were 5.4 and 64° C, respectively. The specific activity at 60° c for exoglucanase and endoglucanase of crude cellulase obtained from cells grown on cellulose (MN 300) was 3.6 moles reducing sugar equivalents released per h (unit)/mg of protein and 1.5 mole reducing sugar equivalent released per min (unit)/mg of protein, respectively. The yield of endoglucanase was 125 units per g of cellulose MN 300 degraded and that of exoglucanase was 300 units per g of cellulose MN 300 degraded. Glucose and cellobiose were the hydrolytic end products of crude cellulase action on cellulose, cellotraose and cellotriose in vitro.     

Enzyme activities of aerobic lignocellulolytic bacteria isolated from wet tropical forest soils

Lignocellulolytic bacteria have promised to be a fruitful source of new enzymes for next-generation lignocellulosic biofuel production. Puerto Rican tropical forest soils were targeted because the resident microbes decompose biomass quickly and to near-completion. Isolates were initially screened based on growth on cellulose or lignin in minimal media. 75 Isolates were further tested for the following lignocellulolytic enzyme activities: phenol oxidase, peroxidase, β-d-glucosidase, cellobiohydrolase, β-xylopyranosidase, chitinase, CMCase, and xylanase. Cellulose-derived isolates possessed elevated β-d-glucosidase, CMCase, and cellobiohydrolase activity but depressed phenol oxidase and peroxidase activity, while the contrary was true of lignin isolates, suggesting that these bacteria are specialized to subsist on cellulose or lignin. Cellobiohydrolase and phenol oxidase activity rates could classify lignin and cellulose isolates with 61% accuracy, which demonstrates the utility of model degradation assays. Based on 16S rRNA gene sequencing, all isolates belonged to phyla dominant in the Puerto Rican soils, Proteobacteria, Firmicutes, and Actinobacteria, suggesting that many dominant taxa are capable of the rapid lignocellulose degradation characteristic of these soils. The isolated genera Aquitalea, Bacillus, Burkholderia, Cupriavidus, Gordonia, and Paenibacillus represent rarely or never before studied lignolytic or cellulolytic species and were undetected by metagenomic analysis of the soils. The study revealed a relationship between phylogeny and lignocellulose-degrading potential, supported by Kruskal–Wallis statistics which showed that enzyme activities of cultivated phyla and genera were different enough to be considered representatives of distinct populations. This can better inform future experiments and enzyme discovery efforts.     

Comparison of morphological and enzyme characteristics of anaerobic fungi isolated from Cervus dama

Seven anaerobic fungal isolates from Cervus dama (domesticated and free living) were grown on carboxymethyl cellulose (CMC) and avicel, and monitored over a five day period for substrate utilization and cellulase activities. All fungal isolates showed monocentric growth patterns; four of them had polyflagellated zoospores and morphologically resembled members of the genus Neocallimastix; the other three had monoflagellated zoospores and resembled members of the genus Piromyces. All of the isolates degraded CMC and avicel, and exhibited cellulolytic activities (carboxymethyl cellulase-(CMC-ase) and avicelase).     

Identification of Mycelium-Associated Cellulase from Streptomyces reticuli

Among 180 Streptomyces strains tested, 25 were capable of hydrolyzing microcrystalline cellulose (Avicel) at 30°C. Streptomyces reticuli was selected for further studies because of its ability to grow at between 30 and 50°C on Avicel. Enzymatic activities degrading Avicel, carboxymethyl cellulose, and cellobiose were found both in the culture supernatant and in association with the mycelium and crystalline substrate. The bound enzymes were efficiently solubilized by repeated washes with buffer of low ionic strength (50 mM Tris hydrochloride [pH 7.5]) and further purified by fast protein liquid chromatography. A high-molecular-weight Avicelase of >300 kilodaltons could be separated from carboxymethyl cellulase (CMCase) and β-glucosidase activities (molecular mass, 40 to 50 kilodaltons) by gel filtration on Superose 12. The CMCase fraction was resolved by Mono Q anion-exchange chromatography into two enzymes designated CMCase 1 and CMCase 2. The β-glucosidase activity was found to copurify with CMCase 2. The purified cellulase components showed optimal activity at around pH 7.0 and temperatures of between 45 and 50°C. Avicelase (but not CMCase) activity was stimulated significantly by the addition of CaCl₂.     

Determination of endoglucanase activity of paper decaying fungi from an old library at the ancient Medina of Fez

Paper from an ancient library of the cultural city of Fez (Morocco) is exposed to rapid deterioration by variety of microorganisms, especially cellulolytic fungi. For this, ten isolates fungi previously isolated from historical biodeteriorated paper were screened for their ability to produce endoglucanase (CMCase), amylase, polygalacturonase and ligninase enzymes. The CMCase activity of cellulolytic strains was essayed in liquid media at 25°C for 10 days. Influence of temperature and pH were assessed for the production of CMCase by all the fungus isolated from decaying paper. The research findings from the present study demonstrate that all the tested isolates had cellulase, amylase, pectinase and ligninase activities. It was found that Mucor racemosus PF15, Aspergillus niger, and Aspergillus oryzae exhibited the maximum endoglucanase activity in liquid medium (0.256, 0.236, and 0.216 UI/mL in descending order) for six days. Temperature profiling revealed optimum endoglucanase activity at 25 and 30°C. Maximum activity was observed at pH 5 and pH 6.     

Comparative genotyping of Clostridium thermocellum strains isolated from biogas plants: Genetic markers and characterization of cellulolytic potential

Clostridium thermocellum is among the most prevalent of known anaerobic cellulolytic bacteria. In this study, genetic and phenotypic variations among C. thermocellum strains isolated from different biogas plants were determined and different genotyping methods were evaluated on these isolates. At least two C. thermocellum strains were isolated independently from each of nine different biogas plants via enrichment on cellulose. Various DNA-based genotyping methods such as ribotyping, RAPD (Random Amplified Polymorphic DNA) and VNTR (Variable Number of Tandem Repeats) were applied to these isolates. One novel approach – the amplification of unknown target sequences between copies of a previously discovered Random Inserted Mobile Element (RIME) – was also tested. The genotyping method with the highest discriminatory power was found to be the amplification of the sequences between the insertion elements, where isolates from each biogas plant yielded a different band pattern. Cellulolytic potentials, optimal growth conditions and substrate spectra of all isolates were characterized to help identify phenotypic variations. Irrespective of the genotyping method used, the isolates from each individual biogas plant always exhibited identical patterns. This is suggestive of a single C. thermocellum strain exhibiting dominance in each biogas plant. The genotypic groups reflect the results of the physiological characterization of the isolates like substrate diversity and cellulase activity. Conversely, strains isolated across a range of biogas plants differed in their genotyping results and physiological properties. Both strains isolated from one biogas plant had the best specific cellulose-degrading properties and might therefore achieve superior substrate utilization yields in biogas fermenters.     

Screening and identification of newly isolated cellulose-degrading bacteria from the gut of xylophagous termite Microcerotermes diversus (Silvestri)

The aim of the present study was to isolate and characterize the cellulose-degrading bacteria from the gut of the local termite, Microcerotermes diversus (Silvestri), inhabiting the Khuzestan province of Iran. The microorganisms capable of growing in the liquid medium containing cellulose as the only source of carbon were isolated and their cellulolytic activity on CMC-containing media was confirmed by the congo red clearing zone assay. The isolates were identified based on biochemical characteristics and the phylogenetic analysis of 16S rRNA gene fragments. The results of the present study show that three cellulose-degrading bacteria isolated from local termite guts belonged to the genera Acinetobacter, Pseudomonas and Staphylococcus and four cellulose-degrading bacteria belonged to Enterobacteriaceae and Bacillaceae families. Several isolates recovered from separate termite Microcerotermes diversus samples closely clustered in phylogenetic trees indicating high similarity and the abundance of particular cellulolytic strains. Bacillus B5B and Acinetobacter L9B hydrolyzed cellulose faster than the other isolates (with CMCase activity of 1.47 and 1.22 U/mL, respectively). The stability of CMCase produced by Bacillus B5B over a broad range of pH and high temperature indicated that the enzyme may be of great commercial value.     

Cellulolytic bacteria from soils in harsh environments

It is believed that the exposure of organisms to harsh climate conditions may select for differential enzymatic activities, making the surviving organisms a very promising source for bioprospecting. Soil bacteria play an important role in degradation of organic matter, which is mostly due to their ability to decompose cellulose-based materials. This work focuses on the isolation and identification of cellulolytic bacteria from soil found in two environments with stressful climate conditions (Antarctica and the Brazilian semi-arid caatinga). Cellulolytic bacteria were selected using enrichments at high and low temperatures (4 or 60°C) in liquid media (trypic soy broth—TSB and minimum salt medium—MM) supplemented with cellulose (1%). Many of the isolates (119 out of 254—46.9%) displayed the ability to degrade carboxymethyl-cellulose, indicating the presence of endoglucolytic activity, while only a minority of these isolates (23 out of 254—9.1%) showed exoglucolytic activity (degradation of avicel). The obtained isolates revealed a preferential endoglucolytic activity according to the temperature of enrichments. Also, the identification of some isolates by partial sequencing of the 16S rRNA gene indicated that the Bacteroidetes (e.g., Pedobacter, Chryseobacterium and Flavobacterium) were the main phylum of cellulolytic bacteria isolated from soil in Antarctica; the Firmicutes (e.g., Bacillus) were more commonly isolated from samples from the caatinga; and Actinobacteria were found in both types of soil (e.g., Microbacterium and Arthrobacter). In conclusion, this work reports the isolation of bacteria able to degrade cellulose-based material from soil at very low or very high temperatures, a finding that should be further explored in the search for cellulolytic enzymes to be used in the bioenergy industry.     

Production of extracellular enzymes by two Pleurotus species using banana pseudostem biomass

The degradation of lignocellulosic biomass of banana pseudoste was investigated during solid state fermentation (SSF) by P. ostreatus and P. sajor-caju. Both organisms proved to be efficient degraders of banana pseudostem biomass. P.ostreatus degraded hemicellulose (40% of dry weight, d.w.) better than cellulose (17.5% of d.w.) and lignin (10% of d.w.). P. sajor-caju also degraded hemicellulose (31% of d.w.) better than cellulose (12.4% of d.w.) and lignin (6% of d.w.). In both cases, a preferential removal of hemicellulose during the initial growth period and a delayed degradation of lignin were observed. The kinetics of cellulolytic, hemicellulolytic and lignolytic enzyme production in liquid culture were also examined. The activities of CMCase and β-glucosidase were highest at 16 days of growth and avicelase activity was at its maximum after 24 days (CMCase - 1.1 IU/ml, β-glucosidase - 0.09 IU/ml in the case of P. ostreatus; CMCase - 1.0 IU/ml, β-glucosidase - 0.087 - IU/ml in the case of P. sajor-caju.). Xylanase and laccase activity reached their maximum after day 16 and day 24 of incubation, respectively. (Xylanase - 1.1 IU/ml and laccase 3.0 IU/ml in the case of P. ostreatus; xylanase - 1.0 IU/ml and laccase - 3.6 IU/ml in the case of P. sajor-caju.). The efficient degrading capacity of test fungi demonstrated their potential use in the conversion of banana pseudostem biomass into mycelial protein-rich fermented animal feed.     

Characterization of Cellulolytic Activities of Environmental Bacterial Consortia from an Argentinian Native Forest

Cellulolytic activities of three bacterial consortia derived from a forest soil sample from Chaco region, Argentina, were characterized. The phylogenetic analysis of consortia revealed two main highly supported groups including Achromobacter and Pseudomonas genera. All three consortia presented cellulolytic activity. The carboxymethylcellulase (CMCase) and total cellulase activities were studied both quantitatively and qualitatively and optimal enzymatic conditions were characterized and compared among the three consortia. Thermal and pH stability were analyzed. Based on its cellulolytic activity, one consortium was selected for further characterization by zymography. We detected a specific protein of 55 kDa with CMCase activity. In this study, we have shown that these consortia encode for cellulolytic enzymes. These enzymes could be useful for lignocellulosic biomass degradation into simple components and for different industrial applications.