Analysis of Molecular Size Distributions of Cellulose Molecules during Hydrolysis of Cellulose by Recombinant Cellulomonas fimi β-1,4-Glucanases

Four β-1,4-glucanases (cellulases) of the cellulolytic bacterium Cellulomonas fimi were purified from Escherichia coli cells transformed with recombinant plasmids. Previous analyses using soluble substrates had suggested that CenA and CenC were endoglucanases while CbhA and CbhB resembled the exo-acting cellobiohydrolases produced by cellulolytic fungi. Analysis of molecular size distributions during cellulose hydrolysis by the individual enzymes confirmed these preliminary findings and provided further evidence that endoglucanase CenC has a more processive hydrolytic activity than CenA. The significant differences between the size distributions obtained during hydrolysis of bacterial microcrystalline cellulose and acid-swollen cellulose can be explained in terms of the accessibility of β-1,4-glucan chains to enzyme attack. Endoglucanases and cellobiohydrolases were much more easily distinguished when the acid-swollen substrate was used.     

Cellulase screening by iodine staining: An artefact

Hydrolysis zones visualized by iodine (KI/I₂) staining of cellulose-agar media after growth of Trichoderma reesei QM6a, RUT C30, QM9136 (cellulase negative) or Thielavia terrestris cultures, or incubation of crude endoglucanases and amylases, were due primarily to degradation of a small amount of starch contaminant in commercial agar and not to cellulolysis as recently suggested. No zones were evident when amylase-digested agar or Gelrite was used as the gelling agent or when purified cellobiohydrolase and endoglucanase were used. Cellulase screening free from artefacts is best obtained by growing cultures on acid-swollen or crystalline cellulose with Gelrite as optimal gelling agent, followed by incubation at elevated temperature to enhance visualization of hydrolysis zones while restricting fungal growth, but without additional staining.     

Synergistic Saccharification, and Direct Fermentation to Ethanol, of Amorphous Cellulose by Use of an Engineered Yeast Strain Codisplaying Three Types of Cellulolytic Enzyme

A whole-cell biocatalyst with the ability to induce synergistic and sequential cellulose-degradation reaction was constructed through codisplay of three types of cellulolytic enzyme on the cell surface of the yeast Saccharomyces cerevisiae. When a cell surface display system based on α-agglutinin was used, Trichoderma reesei endoglucanase II and cellobiohydrolase II and Aspergillus aculeatus β-glucosidase 1 were simultaneously codisplayed as individual fusion proteins with the C-terminal-half region of α-agglutinin. Codisplay of the three enzymes on the cell surface was confirmed by observation of immunofluorescence-labeled cells with a fluorescence microscope. A yeast strain codisplaying endoglucanase II and cellobiohydrolase II showed significantly higher hydrolytic activity with amorphous cellulose (phosphoric acid-swollen cellulose) than one displaying only endoglucanase II, and its main product was cellobiose; codisplay of β-glucosidase 1, endoglucanase II, and cellobiohydrolase II enabled the yeast strain to directly produce ethanol from the amorphous cellulose (which a yeast strain codisplaying β-glucosidase 1 and endoglucanase II could not), with a yield of approximately 3 g per liter from 10 g per liter within 40 h. The yield (in grams of ethanol produced per gram of carbohydrate consumed) was 0.45 g/g, which corresponds to 88.5% of the theoretical yield. This indicates that simultaneous and synergistic saccharification and fermentation of amorphous cellulose to ethanol can be efficiently accomplished using a yeast strain codisplaying the three cellulolytic enzymes.     

Carboxymethylcellulase and avicelase activities from a cellulolytic Clostridium strain A11

The extracellular cellulase enzyme system of Clostridium A11 was fractionated by affinity chromatography on Avicel: 80% of the initial carboxymethylcellulase (CMCase) activity was adhered. This cellulase system was a multicomponent aggregate. Several CMCase activities were detected, but the major protein P1 had no detectable activity. Adhered and unadhered cellulases showed CMCase activity with the highest specific activity in Avicel-adhered fraction. However, only afhered fractions could degrade Avicel. Thus, efficiency of the enzymatic hydrolysis of Avicel was related to the cellulase-adhesion capacity. Carboxymethylcellulase and Avicelase activities were studied with the extracellular enzyme system and cloned cellulases. Genomic libraries from Clostridium A11 were constructed with DNA from this Clostridium, and a new gene cel1 was isolated. The gene(s) product(s) from cel1 exhibited CMCase and p-nitrophenylcellobiosidase (pNPCbase) activities. This cloned cellulase adhered to cellulose. Synergism between adhered enzyme system and cloned endoglucanases was observed on Avicel degradation. Conversely, no synergism was observed on CMC hydrolysis. Addition of cloned endoglucanase to cellulase complex led to increase of the V_max without significant K _m variation. Cloned endoglucanases can be added to cellulase complexes to efficiently hydrolyze cellulose.     

Cellulosic ethanol production by combination of cellulase-displaying yeast cells

As an effort to find suitable endoglucanases to generate cellulolytic yeast strains, two fungal endoglucanases, Thermoascus aurantiacus EGI and Trichoderma reesei EGII, and two bacterial endoglucanases, Clostridium thermocellum CelA and CelD, were expressed on the yeast surface, and their surface expression levels, pH- and temperature-dependent enzyme activities, and substrate specificities were analyzed. T. aurantiacus EGI showed similar patterns of pH- and temperature-dependent activities to those of T. reesei EGII which has been widely used due to its high enzyme activity. Although EGII showed higher carboxymethyl cellulose (CMC) degradation activity than EGI, EGI showed better activity toward phosphoric acid swollen cellulose (PASC). For ethanol production from PASC, we combined three types of yeast cells, each displaying T. aurantiacus EGI, T. reesei CBHII (exoglucanase) and Aspergillus aculeatus BGLI (β-glucosidase), instead of co-expressing these enzymes in a single cell. In this system, ethanol production can be easily optimized by adjusting the combination ratio of each cell type. A mixture of cells with the optimized EGI:CBHII:BGLI ratio of 6:2:1 produced 1.3 fold more ethanol (2.1 g/l) than cells composed of an equal amount of each cell type, suggesting the usefulness of this system for cellulosic ethanol production.     

Cloning, sequencing, and expression of the cellulase genes of Humicola grisea var. thermoidea

We have cloned an endoglucanase (EGI) gene and a cellobiohydrolase (CBHI) gene of Humicola grisea var. thermoidea using a portion of the Trichoderma reesei endoglucanase I gene as a probe, and determined their nucleotide sequences. The deduced amino acid sequence of EGI was 435 amino acids in length and the coding region was interrupted by an intron. The EGI lacks a hinge region and a cellulose-binding domain. The deduced amino acid sequence of CBHI was identical to the H. grisea CBHI previously reported, with the exception of three amino acids. The H. grisea EGI and CBHI show 39.8% and 37.7% identity with the T. Reesei EGI, respectively. In addition to TATA box and CAAT motifs, putative CREA binding sites were observed in the 5′ upstream regions of both genes. The cloned cellulase genes were expressed in Aspergillus oryzae and the gene products were purified. The optimal temperatures of CBHI and EGI were 60 °C and 55–60 °C, respectively. The optimal pHs of these enzymes were 5.0. CBHI and EGI had distinct substrate specificities: CBHI showed high activity toward Avicel, whereas EGI showed high activity toward carboxymethyl cellulose (CMC).     

Assessment of the endo-1,4-beta-glucanase components of Ruminococcus flavefaciens FD-1

The extracellular endo-1,4-beta-glucanase components of Ruminococcus flavefaciens FD-1 were analyzed by high-performance liquid chromatography (HPLC) by using DEAE ion-exchange, hydroxylapatite, and gel filtration chromatography and polyacrylamide gel electrophoresis (PAGE). Two endo-1,4-beta-glucanase peaks were resolved by DEAE-HPLC and termed endoglucanases A and B. Carboxymethyl cellulose (CMC) zymograms were achieved by enzyme separation using nondenaturing PAGE followed by incubation of the gel on top of a CMC-agarose gel. This revealed no less than 13 and 5 endo-1,4-beta-glucanase components present in endoglucanases A and B, respectively. Hydroxylapatite chromatography of endoglucanases A and B revealed one activity peak for each preparation, which contained 4 and 5 endo-1,4-beta-glucanase components, respectively. Gel filtration chromatography of endoglucanase A following hydroxylapatite chromatography resolved the most active carboxymethylcellulase (CMCase) component from other endo-1,4-beta-glucanase activities. Gel filtration of endoglucanase B following hydroxylapatite chromatography showed one CMCase activity peak. Protein stains of sodium dodecyl sulfate-PAGE and nondenaturing PAGE gels of endoglucanases A and B from hydroxylapatite and gel filtration chromatography revealed multiple protein components. When xylan was substituted for CMC in zymograms, identical separation patterns for CMCase and xylanase activities were observed for both endoglucanases A and B. These data suggest that both 1,4-beta linkage-hydrolyzing activities reside on the same polypeptide or protein complex. The highest endo-1,4-beta-glucanase-specific activities were observed following DEAE-HPLC chromatography, with 16.2 and 7.5 mumol of glucose equivalents per min per mg of protein for endoglucanases A and B, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Assessment of the endo-1,4-beta-glucanase components of Ruminococcus flavefaciens FD-1.

The extracellular endo-1,4-beta-glucanase components of Ruminococcus flavefaciens FD-1 were analyzed by high-performance liquid chromatography (HPLC) by using DEAE ion-exchange, hydroxylapatite, and gel filtration chromatography and polyacrylamide gel electrophoresis (PAGE). Two endo-1,4-beta-glucanase peaks were resolved by DEAE-HPLC and termed endoglucanases A and B. Carboxymethyl cellulose (CMC) zymograms were achieved by enzyme separation using nondenaturing PAGE followed by incubation of the gel on top of a CMC-agarose gel. This revealed no less than 13 and 5 endo-1,4-beta-glucanase components present in endoglucanases A and B, respectively. Hydroxylapatite chromatography of endoglucanases A and B revealed one activity peak for each preparation, which contained 4 and 5 endo-1,4-beta-glucanase components, respectively. Gel filtration chromatography of endoglucanase A following hydroxylapatite chromatography resolved the most active carboxymethylcellulase (CMCase) component from other endo-1,4-beta-glucanase activities. Gel filtration of endoglucanase B following hydroxylapatite chromatography showed one CMCase activity peak. Protein stains of sodium dodecyl sulfate-PAGE and nondenaturing PAGE gels of endoglucanases A and B from hydroxylapatite and gel filtration chromatography revealed multiple protein components. When xylan was substituted for CMC in zymograms, identical separation patterns for CMCase and xylanase activities were observed for both endoglucanases A and B. These data suggest that both 1,4-beta linkage-hydrolyzing activities reside on the same polypeptide or protein complex. The highest endo-1,4-beta-glucanase-specific activities were observed following DEAE-HPLC chromatography, with 16.2 and 7.5 mumol of glucose equivalents per min per mg of protein for endoglucanases A and B, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification and characterization of endoglucanase and exoglucanase components from Trichoderma viride

Major cellulase components—four endoglucanases (Endo I, II, III and IV) and one exoglucanase (Exo II)—were isolated from a commercial cellulase preparation derived from Trichoderma viride by a series of chromatographic procedures. The average molecular weights were determined by SDS-polyacrylamide gel electrophoresis. Endos I, III and IV, with M_rs of 52,000, 42,000 and 38,000, respectively, exhibited a more random hydrolytic mode on carboxymethylcellulose (CMC) than Endo II, which has an M_r of 60,000. Endo II showed low activity towards CMC, but out of the four purified endoglucanases this enzyme had the highest specific activity against Avicel. In the hydrolysis of H₃PO₄-swollen cellulose by Endos I, III and IV, cellobiose was the major product, but equimolar amounts of glucose and cellobiose were formed by Endo II. Exo II, with an M_r of 62,000, released cellobiose as the main product in the hydrolysis of H₃PO₄-swollen cellulose, but glucose was negligible. The combination of Endo I, II, III or IV with Exo II resulted in a synergistic effect in the degradation of Avicel at various combination ratios of these enzymes; the specific optimum ratio of endoglucanase to exoglucanase was largely dependent upon the random hydrolytic mode of the endoglucanase. On the other hand, adsorption of cellulase components was found apparently to obey the Langmuir isotherm, and the thermodynamic parameter (ΔH) was calculated from the adsorption equilibrium constant (K). The enthalpies of adsorption of the endoglucanases were in the range of −2.6–−7.2 KJmol⁻¹, much smaller than that of Exo II (−19.4 KJmol⁻¹). This suggest that Exo II shows stronger preferential adsorption than endoglucanases, and that the enthalpy of adsorption will be effective in distinguishing endoglucanase from exoglucanase.     

The Cellulases Endoglucanase I and Cellobiohydrolase II of Trichoderma reesei Act Synergistically To Solubilize Native Cotton Cellulose but Not To Decrease Its Molecular Size

Degradation of cotton cellulose by Trichoderma reesei endoglucanase I (EGI) and cellobiohydrolase II (CBHII) was investigated by analyzing the insoluble cellulose fragments remaining after enzymatic hydrolysis. Changes in the molecular-size distribution of cellulose after attack by EGI, alone and in combination with CBHII, were determined by size exclusion chromatography of the tricarbanilate derivatives. Cotton cellulose incubated with EGI exhibited a single major peak, which with time shifted to progressively lower degrees of polymerization (DP; number of glucosyl residues per cellulose chain). In the later stages of degradation (8 days), this peak was eventually centered over a DP of 200 to 300 and was accompanied by a second peak (DP, (apprx=)15); a final weight loss of 34% was observed. Although CBHII solubilized approximately 40% of bacterial microcrystalline cellulose, the cellobiohydrolase did not depolymerize or significantly hydrolyze native cotton cellulose. Furthermore, molecular-size distributions of cellulose incubated with EGI together with CBHII did not differ from those attacked solely by EGI. However, a synergistic effect was observed in the reducing-sugar production by the cellulase mixture. From these results we conclude that EGI of T. reesei degrades cotton cellulose by selectively cleaving through the microfibrils at the amorphous sites, whereas CBHII releases soluble sugars from the EGI-degraded cotton cellulose and from the more crystalline bacterial microcrystalline cellulose.     

Purification of two immunologically distinct endoglucanases without affinity for microcrystalline cellulose from Cellulomonas sp. ATCC 21399

Two endoglucanases (endoglucanase B and endoglucanase C) without affinity for cellulose were purified from the culture broth of Cellulomonas sp. ATCC 21399 using gelfiltration and ion exchange chromatography. Fused rocket immunoelectrophoresis was used to select the fractions with the highest content of endoglucanase and lowest content of contaminating proteins. The endoglucanases were purified to immunological homogeneity. In addition both endoglucanases were homogeneous when analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (molecular weights of endoglucanase B and endoglucanase C were 67000 and 25000, respectively). Endoglucanase B was homogeneous when studied by isoelectric focusing showing one protein band at pl 4.3. Both endoglucanases lacked activity against microcrystalline cellulose (Avicel) and showed similar endo action on carboxymethylcellulose (CMC). Endoglucanase B had a high specific activity against CMC, H(3)PO(4)-swollen Avicel and xylan, but showed no activity against galactomannan. In contrast, endoglucanase C showed activity against both CMC, xylan, and galactomannan all being polysaccharide substrates linked with beta-1-4-D-glucoside bonds. The specific activity of endoglucanase C against H(3)PO(4)-swollen Avicel was low.     

Rolle der einzelnen Komponenten des Cellulasekomplexes bei der Hydrolyse unlöslicher Cellulose

The kinetics of the hydrolysis of microcrystalline cellulose (MC) by a Trichoderma reesei cellulase complex and by the individual endoglucanase (pI 4.4–5.2) and cellobiohydrolase (pI 4.0–4.2) has been studied. A flow chart for the enzymatic hydrolysis of the cellulose has been revealed, which formed a basis for a computer simulation of the kinetic regularities observed. As a result of it, the values of the catalytic rate constants for the individual stages of the enzymatic degradation of MC have been calculated. Then, the synergistic behaviour of endoglucanase and cellobiohydrolase in the hydrolysis of MC has been described both quantitatively and graphically. The relative efficiency of the individual stages for the MC hydrolysis in terms of glucose and cellobiose formation for cellulase complexes of various composition has been calculated. It was quantitatively shown that cellobiohydrolase plays the key role in the MC hydrolysis by T. reesei cellulase preparations, because it gives up to 80% glucose and up to 80–90% cellobiose in the presnce of endoglucanase which in turn plays a relatively minor role in a direct formation of both soluble products of the hydrolysis.     

Hydrolysis of amorphous and crystalline cellulose by heterologously produced cellulases of Melanocarpus albomyces

Three thermostable neutral cellulases from Melanocarpus albomyces, a 20-kDa endoglucanase (Cel45A), a 50-kDa endoglucanase (Cel7A), and a 50-kDa cellobiohydrolase (Cel7B) heterologously produced in a recombinant Trichoderma reesei were purified and studied in hydrolysis (50 degrees C, pH 6.0) of crystalline and amorphous cellulose. To improve their efficiency, M. albomyces cellulases naturally harboring no cellulose-binding module (CBM) were genetically modified to carry the CBM of T. reesei CBHI/Cel7A, and were studied under similar experimental conditions. Hydrolysis performance and product profiles were used to evaluate hydrolytic features of the investigated enzymes. Each cellulase proved to be active against the tested substrates; the cellobiohydrolase Cel7B had greater activity than the endoglucanases Cel45A and Cel7A against crystalline cellulose, whereas in the case of amorphous substrate the order was reversed. Evidence of synergism was observed when mixtures of the novel enzymes were applied in a constant total protein dosage. Presence of the CBM improved the hydrolytic potential of each enzyme in all experimental configurations; it had a greater effect on the endoglucanases Cel45A and Cel7A than the cellobiohydrolase Cel7B, especially against crystalline substrate. The novel cellobiohydrolase performed comparably to the major cellobiohydrolase of T. reesei (CBHI/Cel7A) under the applied experimental conditions.     

Cellulase Complex of the Fungus Chrysosporium lucknowense: Isolation and Characterization of Endoglucanases and Cellobiohydrolases

Using different chromatographic techniques, eight cellulolytic enzymes were isolated from the culture broth of a mutant strain of Chrysosporium lucknowense: six endoglucanases (EG: 25 kD, pI 4.0; 28 kD, pI 5.7; 44 kD, pI 6.0; 47 kD, pI 5.7; 51 kD, pI 4.8; 60 kD, pI 3.7) and two cellobiohydrolases (CBH I, 65 kD, pI 4.5; CBH II, 42 kD, pI 4.2). Some of the isolated cellulases were classified into known families of glycoside hydrolases: Cel6A (CBH II), Cel7A (CBH I), Cel12A (EG28), Cel45A (EG25). It was shown that EG44 and EG51 are two different forms of one enzyme. EG44 seems to be a catalytic module of an intact EG51 without a cellulose-binding module. All the enzymes had pH optimum of activity in the acidic range (at pH 4.5-6.0), whereas EG25 and EG47 retained 55-60% of the maximum activity at pH 8.5. Substrate specificity of the purified cellulases against carboxymethylcellulose (CMC), beta-glucan, Avicel, xylan, xyloglucan, laminarin, and p-nitrophenyl-beta-D-cellobioside was studied. EG44 and EG51 were characterized by the highest CMCase activity (59 and 52 U/mg protein). EG28 had the lowest CMCase activity (11 U/mg) amongst the endoglucanases; however, this enzyme displayed the highest activity against beta-glucan (125 U/mg). Only EG51 and CBH I were characterized by high adsorption ability on Avicel cellulose (98-99%). Kinetics of Avicel hydrolysis by the isolated cellulases in the presence of purified beta-glucosidase from Aspergillus japonicus was studied. The hydrolytic efficiency of cellulases (estimated as glucose yield after a 7-day reaction) decreased in the following order: CBH I, EG60, CBH II, EG51, EG47, EG25, EG28, EG44.     

Isolation and purification of isoenzymes of cellobiohydrolase I and II of trichoderma reesei using LPLC methods

Five cellulases were fractionated from a commercial cellulase preparation (Celluclast^TM) Two isoenzymes of cellobiohydrolase I (CBHI)(pI = 4.1) could be proved to be real exo-glucanases due to their activity towards MU (=methylumbelliferyl)-lactoside being inhibited by cellobiose (5 mM) and due to production of cellobiose from carboxymethylcellulose (CMC) as the sole final product.Two isoenzymes of CBHII (pI=6.15, 6.0) were shown to act as endo-glucanases because they produced glucose, cellobiose and cellotetraose from CMC and because they were not inhibited by cellobiose when decomposing MU-lactoside. Results confirm recent reports in the literature classifying CBHI and CBHII as exo-type and endo-type cellulases, respectively. Both the CBHI and the CBHII isoenzymes were shown to be active towards CMC and amorphous cellulose.CBHI and CBHII reactions could be differentiated from one another by the velocities of decomposition of CMC: CBHI acts slowly and linearly whereas CBHII acts strongly and exponentially.The fifth of the purified enzymes must be classed as a conventional endoglucanase which exhibits activity towards CMC but fails to be active towards MU-lactoside and amorphous cellulose.     

Synergistic saccharification, and direct fermentation to ethanol, of amorphous cellulose by use of an engineered yeast strain codisplaying three types of cellulolytic enzyme

A whole-cell biocatalyst with the ability to induce synergistic and sequential cellulose-degradation reaction was constructed through codisplay of three types of cellulolytic enzyme on the cell surface of the yeast Saccharomyces cerevisiae. When a cell surface display system based on alpha-agglutinin was used, Trichoderma reesei endoglucanase II and cellobiohydrolase II and Aspergillus aculeatus beta-glucosidase 1 were simultaneously codisplayed as individual fusion proteins with the C-terminal-half region of alpha-agglutinin. Codisplay of the three enzymes on the cell surface was confirmed by observation of immunofluorescence-labeled cells with a fluorescence microscope. A yeast strain codisplaying endoglucanase II and cellobiohydrolase II showed significantly higher hydrolytic activity with amorphous cellulose (phosphoric acid-swollen cellulose) than one displaying only endoglucanase II, and its main product was cellobiose; codisplay of beta-glucosidase 1, endoglucanase II, and cellobiohydrolase II enabled the yeast strain to directly produce ethanol from the amorphous cellulose (which a yeast strain codisplaying beta-glucosidase 1 and endoglucanase II could not), with a yield of approximately 3 g per liter from 10 g per liter within 40 h. The yield (in grams of ethanol produced per gram of carbohydrate consumed) was 0.45 g/g, which corresponds to 88.5% of the theoretical yield. This indicates that simultaneous and synergistic saccharification and fermentation of amorphous cellulose to ethanol can be efficiently accomplished using a yeast strain codisplaying the three cellulolytic enzymes.     

Visualization of enzymatic hydrolysis of cellulose using AFM phase imaging

Complete cellulase, an endoglucanase (EGV) with cellulose-binding domain (CBD) and a mutant endoglucanase without CBD (EGI) were utilized for the hydrolysis of a fully bleached reed Kraft pulp sample. The changes of microfibrils on the fiber surface were examined with tapping mode atomic force microscopy (TM–AFM) phase imaging. The results indicated that complete cellulase could either peel the fibrillar bundles along the microfibrils (peeling) or cut microfibrils into short length across the length direction (cutting) during the process. After 24 h treatment, most orientated microfibrils on the cellulose fiber surface were degraded into fragments by the complete cellulase. Incubation with endoglucanase (EGV or EGI) also caused peeling action. But no significant size reduction of microfibrils length was observed, which was probably due to the absence of cellobiohydrolase. The AFM phase imaging clearly revealed that individual EGV particles were adsorbed onto the surface of a cellulose fiber and may be bound to several microfibrils.     

Analysis of Molecular Size Distributions of Cellulose Molecules during Hydrolysis of Cellulose by Recombinant Cellulomonas fimi β-1,4-Glucanases

Four β-1,4-glucanases (cellulases) of the cellulolytic bacterium Cellulomonas fimi were purified from Escherichia coli cells transformed with recombinant plasmids. Previous analyses using soluble substrates had suggested that CenA and CenC were endoglucanases while CbhA and CbhB resembled the exo-acting cellobiohydrolases produced by cellulolytic fungi. Analysis of molecular size distributions during cellulose hydrolysis by the individual enzymes confirmed these preliminary findings and provided further evidence that endoglucanase CenC has a more processive hydrolytic activity than CenA. The significant differences between the size distributions obtained during hydrolysis of bacterial microcrystalline cellulose and acid-swollen cellulose can be explained in terms of the accessibility of β-1,4-glucan chains to enzyme attack. Endoglucanases and cellobiohydrolases were much more easily distinguished when the acid-swollen substrate was used.Cellulose hydrolysis by aerobic fungi, such as Trichoderma reesei, is usually explained in terms of the synergistic activities of endo-β-1,4-glucanases and exocellobiohydrolases. Models that describe the attack of cellulose at susceptible regions by endoglucanases, followed by cellobiohydrolase attack at the newly formed chain ends, continue to form the basis of most discussions of enzymatic cellulose hydrolysis (2, 24).Although the occurrence of endoglucanases and cellobiohydrolases in fungi is firmly established, the extent to which the cellulase systems of aerobic bacteria resemble those from fungi was unclear until recently, because there was little evidence for the presence of cellobiohydrolases in bacteria. However, it now appears that at least some cellulolytic bacteria produce enzymes similar to the fungal cellobiohydrolases. For example, Cellulomonas fimi produces at least six β-1,4-glucanases, of which four (CenA, CenB, CenC, and CenD) are endoglucanases and two (CbhA and CbhB) appear to be cellobiohydrolases that are the functional equivalents of T. reesei CBHI and CBHII (6, 15, 21, 22). Similar cellobiohydrolases have been described for the actinomycete Thermomonospora fusca (9).

C. fimi cellobiohydrolases.

The preferential attack of cellulose at the ends of glucan chains by C. fimi cellobiohydrolases CbhA and CbhB is strongly suggested by hydrolysis experiments using cellooligosaccharides or carboxymethylcellulose (CMC) (14, 15, 21, 22). However, we lack direct evidence for exohydrolytic activity on cellulose itself. Accordingly, we have examined the activities of CbhA and CbhB on cellulose by measurement of molecular size distributions during hydrolysis. Analysis of CenA was also included to allow comparison of cellobiohydrolase and endoglucanase activities.

C. fimi CenC.

Previous studies have indicated that CenA attacks susceptible linkages in soluble CMC in a relatively nonprocessive manner (7, 14); i.e., the enzyme dissociates from the substrate after each hydrolytic event. While CenB and CenD attack CMC in a similar way (14, 23), C. fimi CenC seems to act in a more processive fashion (16, 23). Therefore, CenC activity was analyzed in order to determine if the enzyme behaves in a similarly processive manner on cellulose.

Cellulose substrates.

Previous determinations of molecular size distribution during hydrolysis have shown that the choice of substrate is an important consideration (10). In this study we used two forms of cellulose: bacterial microcrystalline cellulose (BMCC) and phosphoric acid-swollen cellulose (PASC). These celluloses were chosen in order to simplify the interpretation of data by avoiding complications due to low surface/volume ratios and substrate heterogeneity, which are associated with the use of substrates like cotton or pulp fibers (24). Both BMCC and PASC have a high surface/volume ratio (17). BMCC is a highly crystalline form of cellulose I prepared from cellulose produced by Acetobacter xylinum. PASC is produced by swelling microcrystalline cellulose in concentrated phosphoric acid; although often described as amorphous, it is probably a low-crystallinity form of cellulose II (1). Recent data suggest that cellulose I and cellulose II contain glucan chains arranged in parallel orientation (12).     

Exo-mode of action of cellobiohydrolase Cel48C from Paenibacillus sp. BP-23. A unique type of cellulase among Bacillales.

Sequence analysis of a Paenibacillus sp. BP-23 recombinant clone coding for a previously described endoglucanase revealed the presence of an additional truncated ORF with homology to family 48 glycosyl hydrolases. The corresponding 3509-bp DNA fragment was isolated after gene walking and cloned in Escherichia coli Xl1-Blue for expression and purification. The encoded enzyme, a cellulase of 1091 amino acids with a deduced molecular mass of 118 kDa and a pI of 4.85, displayed a multidomain organization bearing a canonical family 48 catalytic domain, a bacterial type 3a cellulose-binding module, and a putative fibronectin-III domain. The cloned cellulase, unique among Bacillales and designated Cel48C, was purified through affinity chromatography using its ability to bind Avicel. Maximum activity was achieved at 45 degrees C and pH 6.0 on acid-swollen cellulose, bacterial microcrystalline cellulose, Avicel and cellodextrins, whereas no activity was found on carboxy methyl cellulose, cellobiose, cellotriose, pNP-glycosides or 4-methylumbeliferyl alpha-d-glucoside. Cellobiose was the major product of cellulose hydrolysis, identifying Cel48C as a processive cellobiohydrolase. Although no chromogenic activity was detected from pNP-glycosides, TLC analysis revealed the release of p-nitrophenyl-glycosides and cellodextrins from these substrates, suggesting that Cel48C acts from the reducing ends of the sugar chain. Presence of such a cellobiohydrolase in Paenibacillus sp. BP-23 would contribute to widen up its range of action on natural cellulosic substrates.     

Isolation and characterization of endoglucanases 1 and 2 from Bacteroides succinogenes S85.

Two endoglucanases designated EG1 and EG2 were purified by column chromatography from the nonsedimentable extracellular culture fluid of Bacteroides succinogenes S85. They accounted for approximately 32 and 11%, respectively, of the total endoglucanase present in the nonsedimentable fraction. The most active enzyme (EG1) had a molecular weight of 65,000, pI of 4.8, and temperature and pH optima of 39 degrees C and 6.4, respectively. The Km for carboxymethyl cellulose was 3.6 mg/ml, and the Vmax was 84 U/mg. The major products of cellulose hydrolysis catalyzed by EG1 were cellotriose and cellobiose. EG2 was present as two components with molecular weights of 118,000 and 94,000. The two components had nearly identical cyanogen bromide peptide maps, thereby indicating that the 94,000-dalton component was a proteolytic degradation product of the 118,000-dalton enzyme. The larger component, which was more abundant in the culture fluid than the smaller form was, had a Km of 12.2 mg/ml and a Vmax of 10.4 U/mg. It was a basic protein with a pI of 9.4, a temperature optimum of 39 degrees C, and a pH optimum of 5.8. The major product of cellulose hydrolysis was cellotetraose. EG2 exhibited specific binding to acid-swollen cellulose, whereas EG1 did not, and neither of them had affinity for crystalline cellulose. Based on the substrate specificities and the affinities of the two enzymes for cellulose, we postulated that EG2 is involved in the early stages of cellulose hydrolysis and that EG1 is active primarily on the products arising from EG2.