Insoluble Cellulosic Substrates Research Articles

Addition of a carbohydrate-binding module enhances cellulase penetration into cellulose substrates

IntroductionCellulases are of great interest for application in biomass degradation, yet the molecular details of the mode of action of glycoside hydrolases during degradation of insoluble cellulose remain elusive. To further improve these enzymes for application at industrial conditions, it is critical to gain a better understanding of not only the details of the degradation process, but also the function of accessory modules.MethodWe fused a carbohydrate-binding module (CBM) from family 2a to two thermophilic endoglucanases. We then applied neutron reflectometry to determine the mechanism of the resulting enhancements.ResultsCatalytic activity of the chimeric enzymes was enhanced up to three fold on insoluble cellulose substrates as compared to wild type. Importantly, we demonstrate that the wild type enzymes affect primarily the surface properties of an amorphous cellulose film, while the chimeras containing a CBM alter the bulk properties of the amorphous film.ConclusionOur findings suggest that the CBM improves the efficiency of these cellulases by enabling digestion within the bulk of the film.

Fusion of cellulose binding domain from Trichoderma reesei CBHI to Cryptococcus sp. S-2 cellulase enhances its binding affinity and its cellulolytic activity to insoluble cellulosic substrates

Cryptococcus sp. S-2 carboxymethyl cellulase (CSCMCase) is active in the acidic pH and lacks a binding domain. The absence of the binding domain makes the enzyme inefficient against insoluble cellulosic substrates. To enhance its binding affinity and its cellulolytic activity to insoluble cellulosic substrates, cellulose binding domain (CBD) of cellobiohydrolase I (CBHI) from Trichoderma reesei belonging to carbohydrate binding module (CBM) family 1 was fused at the C-terminus of CSCMCase. The constructed fusion enzymes (CSCMCase-CBD and CSCMCase-2CBD) were expressed in a newly recombinant expression system of Cryptococcus sp. S-2, purified to homogeneity, and then subject to detailed characterization. The recombinant fusion enzymes displayed optimal pH similar to those of the native enzyme. Compared with rCSCMCase, the recombinant fusion enzymes had acquired an increased binding affinity to insoluble cellulose and the cellulolytic activity toward insoluble cellulosic substrates (SIGMACELL® and Avicel) was higher than that of native enzyme, confirming the presence of CBDs improve the binding and the cellulolytic activity of CSCMCase on insoluble substrates. This attribute should make CSCMCase an attractive applicant for various application.

Recyclable Thermoresponsive Polymer–Cellulase Bioconjugates for Biomass Depolymerization

Here we report the construction and characterization of a recoverable, thermoresponsive polymer-endoglucanase bioconjugate that matches the activity of unmodified enzymes on insoluble cellulose substrates. Two copolymers exhibiting a thermoresponsive lower critical solution temperature (LCST) were created through the copolymerization of an aminooxy-bearing methacrylamide with N-isopropylacrylamide (NIPAm) or N-isopropylmethacrylamide (NIPMa). The aminooxy group provided a handle through which the LCST was adjusted through small-molecule quenching. This allowed materials with LCSTs ranging from 20.9 to 60.5 °C to be readily obtained after polymerization. The thermostable endoglucanase EGPh from the hypothermophilic Pyrococcus horikoshii was transaminated with pyridoxal-5'-phosphate to produce a ketone-bearing protein, which was then site-selectively modified through oxime linkage with benzylalkoxyamine or 5 kDa-poly(ethylene glycol)-alkoxyamine. These modified proteins showed activity comparable to the controls when assayed on an insoluble cellulosic substrate. Two polymer bioconjugates were then constructed using transaminated EGPh and the aminooxy-bearing copolymers. After 12 h, both bioconjugates produced an equivalent amount of free reducing sugars as the unmodified control using insoluble cellulose as a substrate. The recycling ability of the NIPAm copolymer-EGPh conjugate was determined through three rounds of activity, maintaining over 60% activity after two cycles of reuse and affording significantly more soluble carbohydrates than unmodified enzyme alone. When assayed on acid-pretreated Miscanthus, this bioconjugate increased the amount of reducing sugars by 2.8-fold over three rounds of activity. The synthetic strategy of this bioconjugate allows the LCST of the material to be changed readily from a common stock of copolymer and the method of attachment is applicable to a variety of proteins, enabling the same approach to be amenable to thermophile-derived cellulases or to the separation of multiple species using polymers with different recovery temperatures.

Processivity and Enzymatic Mode of a Glycoside Hydrolase Family 5 Endoglucanase from Volvariella volvacea

EG1 is a modular glycoside hydrolase family 5 endoglucanase from Volvariella volvacea consisting of an N-terminal carbohydrate-binding module (CBM1) and a catalytic domain (CD). The ratios of soluble to insoluble reducing sugar produced from filter paper after 8 and 24 h of exposure to EG1 were 6.66 and 8.56, respectively, suggesting that it is a processive endoglucanase. Three derivatives of EG1 containing a core domain only or additional CBMs were constructed in order to evaluate the contribution of the CBM to the processivity and enzymatic mode of EG1 under stationary and agitated conditions. All four enzymatic forms exhibited the same mode of action on both soluble and insoluble cellulosic substrates with cellobiose as a main end product. An additional CBM fused at either the N or C terminus reduced specific activity toward soluble and insoluble celluloses under stationary reaction conditions. Deletion of the CBM significantly decreased enzyme processivity. Insertion of an additional CBM also resulted in a dramatic decrease in processivity in enzyme-substrate reaction mixtures incubated for 0.5 h, but this effect was reversed when reactions were allowed to proceed for longer periods (24 h). Further significant differences were observed in the substrate adsorption/desorption patterns of EG1 and enzyme derivatives equipped with an additional CBM under agitated reaction conditions. An additional family 1 CBM improved EG1 processivity on insoluble cellulose under highly agitated conditions. Our data indicate a strong link between high adsorption levels and low desorption levels in the processivity of EG1 and possibly other processive endoglucanses.

An amperometric enzyme biosensor for real‐time measurements of cellobiohydrolase activity on insoluble cellulose

An amperometric enzyme biosensor for continuous detection of cellobiose has been implemented as an enzyme assay for cellulases. We show that the initial kinetics for cellobiohydrolase I, Cel7A from Trichoderma reesei, acting on different types of cellulose substrates, semi-crystalline and amorphous, can be monitored directly and in real-time by an enzyme-modified electrode based on cellobiose dehydrogenase (CDH) from Phanerochaete chrysosporium (Pc). PcCDH was cross-linked and immobilized on the surface of a carbon paste electrode which contained a mediator, benzoquinone. An oxidation current of the reduced mediator, hydroquinone, produced by the CDH-catalyzed reaction with cellobiose, was recorded under constant-potential amperometry at +0.5 V (vs. Ag/AgCl). The CDH-biosensors showed high sensitivity (87.7 µA mM(-1) cm(-2)), low detection limit (25 nM), and fast response time (t(95%) ≈ 3 s) and this provided experimental access to the transient kinetics of cellobiohydrolases acting on insoluble cellulose. The response from the CDH-biosensor during enzymatic hydrolysis was corrected for the specificity of PcCDH for the β-anomer of cello-oligosaccharides and the approach were validated against HPLC. It is suggested that quantitative, real-time data on pure insoluble cellulose substrates will be useful in attempts to probe the molecular mechanism underlying enzymatic hydrolysis of cellulose.

Construction and characterization of chimeric cellulases with enhanced catalytic activity towards insoluble cellulosic substrates

The chimeric proteins viz. CBM3–Cel9A, CBM4–Cel9A and CBM30–Cel9A, are constructed by fusion of family 3, 4, and 30 cellulose binding modules (CBMs) to N-terminus of family 9 endoglucanase (Cel9A) from Alicyclobacillus acidocaldrious. The chimeric enzymes were successfully expressed in Escherichia coli and purified to homogeneity. The chimeric enzymes showed significant increase in Avicel (8–12 folds) and filter paper (7–10 folds) degradation activities compared to Cel9A endoglucanase. Computational protein modeling and simulation on the chimeric enzymes were applied to analyze the fused CBMs effect on the increased insoluble cellulosic substrates degradation activity. Thin layer chromatography analysis of the enzymatic hydrolysis products and distribution of reducing sugars between soluble and insoluble fractions indicated processive cleavage of insoluble cellulosic substrates by the chimeras. The fused CBMs played a critical accessory role for the Cel9A catalytic domain and changed its character to facilitate the processive cleavage of insoluble cellulosic substrates.

A Molecular View of Cellulase-Catalyzed Hydrolysis of Cellulose: A Single Molecule Approach

The efficient conversion of biomass to biofuels such as ethanol would meet a large portion of energy requirements in the near future. A crucial step in this process is the enzyme-catalyzed hydrolysis of cellulose to glucose that is then converted into fuel by fermentation. The hydrolysis is complex - it entails the cooperative (synergistic) action of multiple enzymes known collectively as cellulases: endoglucanase, exoglucanase and beta-glucosidase on both insoluble and soluble substrates. In contrast to homogeneous solution-phase catalysis, the overall efficiency of this heterogeneous catalysis process depends on factors in addition to the catalytic rates of the cellulases, including: cellulase absorption, desorption and diffusion rates on the insoluble cellulose substrate, endoglucanase-catalyzed conversion of cellulose from its crystalline to amorphous forms, and the processivity of exoglucanase-catalyzed hydrolysis of individual cellulose strands. To date, due in large part to limitations of the analysis methods used for its study, this heterogeneous reaction is poorly understood. Here we use single-molecule imaging to directly elucidate molecular-level details of cellulase activity that cannot be readily inferred from ensemble averages reported by conventional, bulk analyses.In our research, the activities of exo- and endoglucanases on cellulose microfibrils are investigated at the single-molecule level. Total internal reflection fluorescence microscopy (TIRFM) is used to monitor the activity of individual fluorescently-labeled cellulases interacting with insoluble cellulose substrates. Using wide field imaging, we are able to simultaneously record the motion of multiple, individual cellulases with nanometer spatial resolution. Time-resolved localization microscopy provides insights on: (i) binding and diffusion of enzyme to ‘active’ sites on cellulose; (ii) lifetime of enzyme activity for hydrolysis; (iii) enzyme processivity; and (iv) the nature of synergy between cellulase enzymes.

How recombinant swollenin from Kluyveromyces lactisaffects cellulosicsubstrates and accelerates their hydrolysis

BackgroundIn order to generate biofuels, insoluble cellulosic substrates are pretreated and subsequently hydrolyzed with cellulases. One way to pretreat cellulose in a safe and environmentally friendly manner is to apply, under mild conditions, non-hydrolyzing proteins such as swollenin - naturally produced in low yields by the fungus Trichoderma reesei. To yield sufficient swollenin for industrial applications, the first aim of this study is to present a new way of producing recombinant swollenin. The main objective is to show how swollenin quantitatively affects relevant physical properties of cellulosic substrates and how it affects subsequent hydrolysis.ResultsAfter expression in the yeast Kluyveromyces lactis, the resulting swollenin was purified. The adsorption parameters of the recombinant swollenin onto cellulose were quantified for the first time and were comparable to those of individual cellulases from T. reesei. Four different insoluble cellulosic substrates were then pretreated with swollenin. At first, it could be qualitatively shown by macroscopic evaluation and microscopy that swollenin caused deagglomeration of bigger cellulose agglomerates as well as dispersion of cellulose microfibrils (amorphogenesis). Afterwards, the effects of swollenin on cellulose particle size, maximum cellulase adsorption and cellulose crystallinity were quantified. The pretreatment with swollenin resulted in a significant decrease in particle size of the cellulosic substrates as well as in their crystallinity, thereby substantially increasing maximum cellulase adsorption onto these substrates. Subsequently, the pretreated cellulosic substrates were hydrolyzed with cellulases. Here, pretreatment of cellulosic substrates with swollenin, even in non-saturating concentrations, significantly accelerated the hydrolysis. By correlating particle size and crystallinity of the cellulosic substrates with initial hydrolysis rates, it could be shown that the swollenin-induced reduction in particle size and crystallinity resulted in high cellulose hydrolysis rates.ConclusionsRecombinant swollenin can be easily produced with the robust yeast K. lactis. Moreover, swollenin induces deagglomeration of cellulose agglomerates as well as amorphogenesis (decrystallization). For the first time, this study quantifies and elucidates in detail how swollenin affects different cellulosic substrates and their hydrolysis.

In this issue: Biotechnolgy Journal 1/2011

AbstractPulling proteins from tissuesFalk, et al., Biotechnol. J. 2011, 6, 28–37The group of Sophia Hober from Stockholm, Sweden presents a competitive elution approach to selectively pullout proteins from tissue samples. One commonly used strategy to identify proteins in tissues or cells is the isolation by specific binders, often antibodies. To avoid false‐positive identifications, not only is the antibody specificity crucial, but also the washing and elution conditions. Monospecific antibodies were used to selectively pullout target proteins from liver extracts. The target proteins were competitively eluted from the antibody affinity media with the recombinant antigen. To deplete the antigen from the eluted sample, IMAC spin columns were utilized to bind the N‐terminal His‐tag of the antigens. SDS‐PAGE analysis and mass spectrometry confirmed affinity isolation of expected target proteins. The new technique offers an effective approach for wide‐scale pullout experiments where proteins and their interaction partners are studied.High‐troughput cellulase screeningJäger, et al., Biotechnol. J. 2011, 6, 74–85Lignocellulose is a renewable resource for production of biofuels and chemicals. However, efficient hydrolysis of its main component cellulose to glucose is currently the rate‐limiting and most expensive processing step. The group of Jochen Büchs from Aachen, Germany, presents a new cellulase assay platform that utilizes highthroughput and online analysis while using insoluble cellulosic substrates. Three different substrates were tested using a commercial cellulase preparation. The activity was quantified using the BioLector technique, which measures scattered light intensities in a continuously shaken microtiter plate. The authors determined cellulase/cellulose ratios for optimal processing and the ideal pH for maximum cellulase activity. They show for the first time that high‐throughput scattered light measurements can be used for monitoring the non‐hydrolytic effect of cellulases on insoluble cellulose. This new platform will accelerate fundamental research on cellulase screening.Flow cytometry pollen screeningMoon, et al., Biotechnol. J. 2011, 6, 118–123Finding a few transgenic pollen grains in a large pool is much like searching for the needle in a haystack. To study gene flow and assessing the effectiveness of transgene containment, mostly microscopic screening methods or progeny analyses are used, which are time‐consuming and laborious. Researchers from the University of Tennessee now describe a fast, simple and high‐throughput method in which flow cytometry is employed. A suspension of non‐transgenic tobacco pollen was spiked with a known amount of verified transgenic tobacco pollen synthesizing low or high amounts of GFP. The method is rapid, as it is able to count 5000 pollen grains per minute‐long run. Although this method is not less laborious than other methods, it is very accurate for high GFP‐expressing pollen grains.

Screening of cellulases for biofuel production: Online monitoring of the enzymatic hydrolysis of insoluble cellulose using high‐throughput scattered light detection

A new prospective cellulase assay simultaneously combining high-throughput, online analysis and insoluble cellulosic substrates is described. The hydrolysis of three different insoluble cellulosic substrates, catalysed by a commercial cellulase preparation from Trichoderma reesei (Celluclast), was monitored using the BioLector - allowing online monitoring of scattered light intensities in a continuously shaken microtiter plate. Cellulase activities could be quantitatively assayed using the BioLector. At low cellulase/cellulose ratios, the Michaelis-Menten parameters of the cellulase mixture were mainly affected by the crystallinity index of the cellulose. Here, the apparent maximum cellulase activities inversely correlated with the crystallinity index of the cellulose. At high cellulase/cellulose ratios the particle size of the cellulose, defining the external surface area accessible to the cellulases, was the key determining factor for cellulase activity. The developed technique was also successfully applied to evaluate the pH optimum of cellulases. Moreover, the non-hydrolytic deagglomeration of cellulose particles was investigated, for the first time, using high-throughput scattered light detection. In conclusion, this cellulase assay ideally links high-throughput, online analysis and realistic insoluble cellulosic substrates in one simple system. It will considerably simplify and accelerate fundamental research on cellulase screening.

Heterologous co-production of Thermobifida fusca Cel9A with other cellulases in Saccharomyces cerevisiae

The processive endoglucanase Cel9A of the moderately thermophilic actinomycete Thermobifida fusca was functionally produced in Saccharomyces cerevisiae. Recombinant Cel9A displayed activity on both soluble (carboxymethylcellulose) and insoluble (Avicel) cellulose substrates confirming its processive endoglucanase activity. High-performance anionic exchange chromatography analyses of soluble sugars released from Avicel revealed a cellobiose/glucose ratio of 2.5 +/- 0.1. Growth by the recombinant strain on amorphous cellulose was possible due to the sufficient amount of glucose cleaved from the cellulose chain. This is the first confirmed report of S. cerevisiae growing on a cellulosic substrate as sole carbohydrate source while only expressing one recombinant gene. To improve the cellulolytic capability of S. cerevisiae and to investigate the level of synergy among cellulases produced by a recombinant host, the cel9A gene was co-expressed with four cellulase-coding genes of Trichoderma reesei: two endoglucanases cel5A (egII) and cel7B (egI), and two cellobiohydrolases cel6A (cbhII) and cel7A (cbhI). Synergy, especially between the Cel9A and the two cellobiohydrolases, resulted in a higher cellulolytic capability of the recombinant host.

Production and purification of the isolated family 2a carbohydrate-binding module from Cellulomonas fimi

Cellulose is the most abundant polymer on Earth and in recent years, renewed interest has developed in its use for the production of biofuels and other value added products. Cellulose is degraded to glucose by the concerted action of cellulolytic enzymes that include cellulases, cellobiohydrolases, and β-glucosidases. In many cases, these enzymes are multi-modular, being comprised of distinct catalytic and carbohydrate-binding modules. The latter appear to aid in both the adsorption of the enzymes to the insoluble cellulose substrate and the destabilization of the hydrogen-bonding network within the crystalline substrate. To better understand these dynamic processes, we have engineered a carbohydrate-binding module that can be attached to the probe of an atomic force microscope. Thus, the coding sequence for the leader peptide and carbohydrate-binding module from the Cellulomonas fimi cellulase A (cenA) was cloned and over-expressed in Escherichia coli. Site-directed mutagenesis was used to replace Thr87 of this module with Cys to facilitate covalent binding of the module to gold-plated AFM probes. The recombinant proteins with cleavable N-terminal His-tags were purified to apparent homogeneity by a combination of affinity and anion-exchange chromatographies using Ni 2+–NTA-agarose and Source Q, respectively. Their ability to bind insoluble cellulose was demonstrated using a cellulose-binding assay involving the micro-crystalline cellulose, Avicel.

Continuous hydrogen production during fermentation of α‐cellulose by the thermophillic bacterium Clostridium thermocellum

Continuous hydrogen (H2) production during fermentation of alpha-cellulose was established using the thermophillic, anaerobic bacterium Clostridium thermocellum ATCC 27405. The objectives of this work were to characterize growth of C. thermocellum, quantify H2 production and determine soluble end-product synthesis patterns during fermentation of a cellulosic substrate under continuous culture conditions. A 5 L working volume fermentor was established and growth experiments were maintained for over 3,000 h. Substrate concentrations were varied from 1 to 4 g/L and the feed was introduced with continuous nitrogen gas sparging to prevent clogging of the feed-line. The pH and temperature of the reactor were maintained at 7.0 and 600 degrees C, respectively, throughout the study. At concentrations above 4 g/L, the delivery of alpha-cellulose was impaired due to feed-line clogging and it became difficult to maintain a homogenous suspension. The highest total gas (H2 plus CO2) production rate, 56.6 mL L(-1) h(-1), was observed at a dilution rate of 0.042 h(-1) and substrate concentration of 4 g/L. Under these conditions, the H2 production rate was 5.06 mmol h(-1). Acetate and ethanol were the major soluble end-products, while lactate and formate were greatly reduced compared to production in batch cultures. Concentrations of all metabolites increased with increasing substrate concentration, with the exception of lactate. Despite a number of short-term electrical and mechanical failures during the testing period, the system recovered quickly, exhibiting substantial robustness. A carbon balance was completed to ensure that all end-products were accounted for, with final results indicating near 100% carbon recovery. This study shows that long-term, stable H2 production can be achieved during direct fermentation of an insoluble cellulosic substrate under continuous culture conditions.

An acidic and thermostable carboxymethyl cellulase from the yeast Cryptococcus sp. S-2: Purification, characterization and improvement of its recombinant enzyme production by high cell-density fermentation of Pichia pastoris

The extracellular carboxymethyl cellulase (CSCMCase) from the yeast, Cryptococcus sp. S-2, was produced when grown on cellobiose. It was purified to homogeneity from the supernatant by ultrafiltration, DEAE-5PW anion exchange column and TSK-Gel G3000SW gel filtration. The purified enzyme was monomeric protein with molecular mass of approximately 34 kDa. The optimum temperature and pH for the action of the enzyme were at 40–50 °C and 3.5, respectively. It was stable at pH range of 5.5–7.5 and retained approximately 50% of its maximum activity after incubating at 90 °C for 1 h. Moreover, it could able to hydrolyze carboxymethyl cellulose sodium salt higher than insoluble cellulose substrate such as Avicel, SIGMACELL ® and CM cellulose. Due to its action at acidic pH and moderately stable at high temperature, the gene encoding carboxymethyl cellulase (CSCMCase) was isolated and improved the enzyme yield by high cell-density fermentation of Pichia pastoris. The CSCMCase cDNA contains 1023 nucleotides and encodes a 341-amino acid. It was successfully expressed under the control of alcohol oxidase I promoter using methanol induction of P. pastoris fermentation in a 2L ABLE bioreactor. The production of the recombinant carboxymethyl cellulases was higher than that from Cryptococcus sp. S-2 of 657-fold (2.75 and 4.2 × 10 −3 mg protein L −1, respectively) indicating that the leader sequence of CSCMCase has been recognized and processed as efficiently by P. pastoris. Furthermore, the recombinant enzyme was purified in two-step of ultrafiltration and hydrophobic interaction chromatography which would be much more convenient for large-scale purification for successful industrial application.

Functional display of fungal cellulases from Trichoderma reesei on phage M13

To test whether the phage display technology could be applied in cellulase engineering, phagemids harboring the genes encoding the mature forms of cellobiohydrolase I (CBH I) and endoglucanase I (EG I) from filamentous fungus Trichoderma reesei were constructed, respectively. CBH I and EG I fused to the phage coat protein encoded by the g3 gene were expressed and displayed on phage M13. The phage-bound cellulases retained their activities as determined by hydrolysis of the corresponding substrates, Also, their binding abilities to insoluble cellulose substrate were confirmed by an ELISA method. Overall, these results demonstrate that cellulases can be displayed on phage surface while maintaining their biological function, thus providing an alternative for directed evolution and high-throughput screening for improved cellulases.

Comparative characterization of a recombinant Volvariella volvacea endoglucanase I (EG1) with its truncated catalytic core (EG1-CM), and their impact on the bio-treatment of cellulose-based fabrics

Recombinant Volvariella volvacea endoglucanase 1 (EG1) and its catalytic module (EG1-CM) were obtained by expression in Pichia pastoris, purified by two-step chromatography, and the catalytic activities and binding capacities were compared. EG1 and EG1-CM exhibited very similar specific activities towards the soluble substrates carboxymethyl cellulose, lichenan and mannan, and insoluble H(3)PO(4) acid-swollen cellulose, whereas the specific activities of EG1-CM towards the insoluble substrates alpha-cellulose, Avicel and filter paper were approximately 58, 43 and 38%, respectively compared to EG1. No increase in reducing sugar release was detected in the reaction mixture supernatants after 50h exposure of filter paper, Avicel or alpha-cellulose to EG1-CM, whereas increases in the total reducing sugar equivalents (i.e. reducing sugar released into solution together with new reducing ends generated in the cellulosic substrates) in reaction mixtures were observed after 1h. In reaction mixtures containing EG1, soluble reducing sugar equivalents were detected in supernatants after 3h incubation with the insoluble cellulosic substrates. EG1-CM did not adsorb to Avicel, and the binding capacities of EG1-CM towards filter paper and H(3)PO(4) acid-swollen cellulose were 27.9-33.3% and 29.6-60.6%, respectively of values obtained with EG1 within the range of total added protein. In enzymatic deinking experiments, the ink removal rate in EG1-CM-treated samples was only slightly higher (approximately 8%), than that of untreated controls, whereas that of the EG1-treated samples was 100% higher. Bio-stoning of denim with EG1-CM resulted in increases of 48% and 40% in weight loss and indigo dye removal, respectively compared with untreated controls. These increases were considerably lower than the corresponding values of 219% and 133% obtained when samples were treated with EG1.

Endoglucanases from Paenibacillus spp. form a new clan in glycoside hydrolase family 5

Endoglucanase (Egl)-producing bacteria from soil samples were screened using insoluble cellulosic substrates as sole carbon sources at alkaline pH (pH 9-10). Four Egls with Avicelase activity at alkaline pH were found in the culture broth of each isolate. The Egl genes of the isolates (all Paenibacillus spp.) were shotgun cloned and sequenced-all had a 1752bp open reading frame (584 amino acids) with a putative signal sequence (33 amino acids), and encoded mature enzymes of 551 amino acids (58,360-58,672Da). The mature enzymes showed a high degree of similarity to each other (>93% identity), with the next closest similarity to Egl3a of a patented strain of Paenibacillus lautus NCIMB 40250 (81.5-87.3% identity). These enzymes showed low similarity to other known Egls with less than 50% identity. A representative recombinant enzyme degraded lichenan, carboxymethylcellulose (CMC), glucomannan, acid or alkaline swollen celluloses, and microcrystalline cellulose (Avicel). The optimal pH and temperature of the recombinant enzyme for degrading CMC and Avicel were pH 6.0-8.5 and 45-55 degrees C, respectively. Egls belong to glycoside hydrolase family 5 and form a distinct clan based on the phylogenetic analysis of their amino acid sequences.

Production, purification and properties of endoglucanase from a newly isolated strain of Mucor circinelloides

A newly isolated strain of the fungus, Mucor circinelloides (NRRL 26519), when grown on lactose, cellobiose, or Sigmacell 50 produces complete cellulase (endoglucanase, cellobiohydrolase, and β-glucosidase) system. The extracellular endoglucanase (EG) was purified to homogeneity from the culture supernatant by ethanol precipitation (75%, v/v), CM Bio-Gel A column chromatography, and Bio-Gel A-0.5 m gel filtration. The purified EG (specific activity 43.33 U/mg protein) was a monomeric protein with a molecular weight of 27 000. The optimum temperature and pH for the action of the enzyme were at 55 °C and 4.0–6.0, respectively. The purified enzyme was fully stable at pH 4.0–7.0 and temperature up to 60 °C. It hydrolysed carboxymethyl cellulose and insoluble cellulose substrates (Avicel, Solka-floc, and Sigmacell 50) to soluble cellodextrins. No glucose, cellobiose, and short chain cellooligosaccarides were formed from these substrates. The purified EG could not degrade oat spelt xylan and larch wood xylan. It bound to Avicell, Solka-floc, and Sigmacell 50 at pH 5.0 and the bound enzyme was released by changing the pH to 8.0. The enzyme activity was enhanced by 27±5 and 44±14% by the addition of 5 mM MgCl 2 and 0.5 mM CoCl 2, respectively, to the reaction mixture. Comparative properties of this enzyme with other fungal EGs are presented.

Probing pH-dependent functional elements in proteins: modification of carboxylic acid pairs in Trichoderma reesei cellobiohydrolase Cel6A.

Two carboxylic acid side chains can, depending on their geometry and environment, share a proton in a hydrogen bond and form a carboxyl-carboxylate pair. In the Trichoderma reesei cellobiohydrolase Cel6A structure, five carboxyl-carboxylate pairs are observed. One of these pairs (D175-D221) is involved in catalysis, and three other pairs are found in, or close to the two surface loops covering the active site tunnel of the catalytic domain. To stabilize Cel6A at alkaline pH values, where deprotonation of the carboxylic acids leads to repulsion of their side chains, we designed two mutant enzymes. In the first mutant, one carboxyl-carboxylate pair (E107-E399) was replaced by a corresponding amide-carboxylate pair (Q107-E399), and in the second mutant, all three carboxyl-carboxylate pairs (E107-E399, D170-E184, and D366-D419) were mutated in a similar manner. The unfolding studies using both intrinsic tryptophan fluorescence and far-ultraviolet circular dichroism spectroscopy at different pH values demonstrate that the unfolding temperature (T(m)) of both mutants has changed, resulting in destabilization of the mutant enzymes at acidic pH and stabilization at alkaline pH. The effect of stabilization seems additive, as a Cel6A triple mutant is the most stable enzyme variant. This increased stability is also reflected in the 2- or 4-fold increased half-life of the two mutants at alkaline pH, while the catalytic rate on cellotetraose (at t = 0) has not changed. Increased operational stability at alkaline pH was also observed on insoluble cellulosic substrates. Local conformational changes are suggested to take place in the active site loops of Cel6A wild-type enzyme at elevated pHs (pH 7), affecting to the end-product spectrum on insoluble cellulose. The triple mutant does not show such pH-dependent behavior. Overall, our results demonstrate that carboxyl-carboxylate pair engineering is a useful tool to alter pH-dependent protein behavior.

Carbon mass balance evaluation of cellulase production on soluble and insoluble substrates.

A methodology is described and applied for performing carbon mass balances across cellulase enzyme production processes using both soluble sugar and insoluble cellulose substrates. The fungus Trichoderma reesei was grown on either glucose, lactose, or cellulose in aerobic batch mode, and the evolution of the main carbonaceous components (cell mass, cellulose, soluble protein, adsorbed protein, sugars, and carbon dioxide) was followed. A variety of analytical techniques were utilized to measure these components, including (i) gravimetric analysis, (ii) near-infrared spectroscopy, (iii) bicinchoninic acid based soluble protein measurement, (iv) gas mass spectrometry and flow rate, (v) CHNS/O elemental analyses, and (vi) high-performance liquid chromatography. The combined set of measurements allowed carbon mass balances across the cellulase production process to be assessed to determine the consistency of the underlying kinetic data. Results demonstrate the capability to determine the levels and distribution of all major carbonaceous components during the cellulase production process on both soluble and insoluble substrates. Average carbon mass balance closures were near 100% during early stages (<72 h) of the cultivations using glucose, lactose, or cellulose as the substrates, but carbon mass closures trended high later in the cultivation. Analysis of carbon allocation results suggests that an error in the gas mass flow rate measurement was the primary cause for carbon mass balance closures to exceed 110% late in the process.