Studies of the cellulolytic system of Trichoderma reesei QM 9414. Analysis of domain function in two cellobiohydrolases by limited proteolysis

The use of conserved cellulase family-specific sequences to clone cellulase homologue cDNAs from Fusarium oxysporum

Five cDNAs from the cellulolytic fungi Fusarium oxysporum that code for five distinct cellulase homologues have been cloned and sequenced. The cloning strategy exploited the hydrophobic cluster analysis-based cellulase family classification of Henrissat and Bairoch [Biochem. J. 293 (1993) 781-788] to design degenerate oligodeoxyribonucleotides (oligos) that encoded amino-acid sequences conserved in an intra-family, but not inter-family, manner among cellulases from different species. Polymerase chain reaction (PCR) experiments using F. oxysporum genomic DNA primed with these 'family-specific' oligos were used to rapidly generate PCR fragments which were in turn used to probe cDNA libraries. Two distinct cDNAs coding for cellulase C-family homologues and one cDNA each coding for homologues to the B, F and K families, were isolated in this manner. This approach is an example of the power of multiple sequence analysis to generate cross-species, homology-based probes to rapidly clone homologues in a species of interest.

Isolation, characterization, and analysis of the expression of the cbhII gene of Phanerochaete chrysosporium

Two cDNA sequences representing putative allelic variants of the Phanerochaete chrysosporium cbhII gene were isolated by hybridization to the Trichoderma reesei cbhII gene. Both of the equivalent genomic sequences were subsequently isolated by the inverse PCR technique. DNA sequencing showed that the cbhII open reading frame of 1,380 bp codes for a putative polypeptide of 460 amino acids which is interrupted by six introns. The domain structure found in T. reesei cbhII is conserved in the equivalent P. chrysosporium protein. The overall similarity between the two gene products is 54%, with the region of highest conservation being found in the cellulose-binding domain (65%). Unlike the cbhI gene of P. chrysosporium, cbhII does not appear to be a member of a class of closely related genes. CBHII is a new member of family B of the beta-1, 4-glucanases. Alignment of the P. chrysosporium and T. reesei CBHII protein sequences showed that all of the residues important for the formation of the extended loops of the catalytic domain and those residues that are involved in the catalytic action of the T. reesei enzyme are also present in the P. chrysosporium equivalent. The profiles of cbh gene expression in P. chrysosporium reveal that while cbhI.1 and cbhI.2 could be coregulated, cbhII can be independently controlled. The latter is so far the only cellulase gene found to be expressed when the fungus is grown on oat spelt arabinoxylan, suggesting that it may play an active role in the xylanolytic as well as the cellulolytic systems.

C1-Cx revisited: intramolecular synergism in a cellulase

Endoglucanase A (CenA) from the bacterium Cellulomonas fimi is composed of a catalytic domain and a nonhydrolytic cellulose-binding domain that can function independently. The individual domains interact synergistically in the disruption and hydrolysis of cellulose fibers. This intramolecular synergism is distinct from the well-known intermolecular synergism between individual cellulases. The catalytic domain corresponds to the hydrolytic Cx system and the cellulose-binding domain corresponds to the nonhydrolytic C1 system postulated by Reese et al. [Reese, E. T., Sui, R. G. H. & Levinson, H. S. (1950) J. Bacteriol. 59, 485-497] to be required for the hydrolysis of cellulose.

Cellulose hydrolysis by the cellulases from Trichoderma reesei: adsorptions of two cellobiohydrolases, two endocellulases and their core proteins on filter paper and their relation to hydrolysis

Separate binding of several purified cellulolytic components of Trichoderma reesei on to filter paper was studied and concomitant hydrolysis rates evaluated. Enhancement of mass transfer from the bulk liquid to the solid substrate by agitation has two different effects on adsorption depending on the type of enzyme: (i) the fraction of cellobiohydrolase II (CBH II) and endoglucanase III (EG III) bound at equilibrium is increased, whereas (ii) the rate but not the extent of cellobiohydrolase I (CBH I) and endoglucanase I (EG I) adsorption is affected. The adsorption of CBH I core, a component lacking the cellulose-binding domain (CBD), is, however, not significantly influenced by mass transfer. The CBH I interdomain peptide (present in CBH I core b) does not participate in adsorption but enhances stability. The adsorption of CBH I core proteins is a fully reversible process whereas that of the intact CBH I is not. Thus, the interaction of the CBD with filter paper apparently accounts for the mass-transfer-limited binding rate and also for the irreversible adsorption of intact CBH I. Adsorption isotherms at 50 degrees C indicate very similar relative association constants for the intact cellulases (0.24-0.30 l/g of cellulose), but drastically reduced values for CBH I core proteins (0.03 l/g of cellulose). The specific activities of adsorbed CBH I and of its core proteins are identical and a linear relationship between adsorption and rates of hydrolysis is found only for these enzymes. Thus, non-productive binding on to cellulose seems evident in the case of CBH II and EG III but not CBH I.

The roles of the C-terminal domain and type III domains of chitinase A1 from Bacillus circulans WL-12 in chitin degradation

The mature form of chitinase A1 from Bacillus circulans WL-12 comprises a C-terminal domain, two type III modules (domains), and a large N-terminal domain which contains the catalytic site of the enzyme. In order to better define the roles of these chitinase domains in chitin degradation, modified chiA genes encoding various deletions of chitinase A1 were constructed. The modified chiA genes were expressed in Escherichia coli, and the gene products were analyzed after purification by high-performance liquid chromatography. Intact chitinase A1 specifically bound to chitin, while it did not show significant binding activity towards partially acetylated chitosan and other insoluble polysaccharides. Chitinases lacking the C-terminal domain lost much of this binding activity to chitin as well as colloidal chitin-hydrolyzing activity. Deletion of the type III domains, on the other hand, did not affect chitin-binding activity but did result in significantly decreased colloidal chitin-hydrolyzing activity. Hydrolysis of low-molecular-weight substrates, soluble high-molecular-weight substrates, and insoluble high-molecular-weight substrates to which chitinase A1 does not bind were not significantly affected by these deletions. Thus, it was concluded that the C-terminal domain is a chitin-binding domain required for the specific binding to chitin and that this chitin-binding activity is important for efficient hydrolysis of the sufficiently acetylated chitin. Type III modules are not directly involved in the chitin binding but play an important functional role in the hydrolysis of chitin by the enzyme bound to chitin.

The three-dimensional crystal structure of the catalytic core of cellobiohydrolase I from Trichoderma reesei

Cellulose is the major polysaccharide of plants where it plays a predominantly structural role. A variety of highly specialized microorganisms have evolved to produce enzymes that either synergistically or in complexes can carry out the complete hydrolysis of cellulose. The structure of the major cellobiohydrolase, CBHI, of the potent cellulolytic fungus Trichoderma reesei has been determined and refined to 1.8 angstrom resolution. The molecule contains a 40 angstrom long active site tunnel that may account for many of the previously poorly understood macroscopic properties of the enzyme and its interaction with solid cellulose. The active site residues were identified by solving the structure of the enzyme complexed with an oligosaccharide, o-iodobenzyl-1-thio-beta-cellobioside. The three-dimensional structure is very similar to a family of bacterial beta-glucanases with the main-chain topology of the plant legume lectins.

Cellulose hydrolysis by the cellulases from Trichoderma reesei: a new model for synergistic interaction

The hydrolysis of Whatman no. 1 filter paper by purified cellulolytic components from Trichoderma reesei and the synergistic action of binary combinations of these enzymes on the same substrate were investigated. At 20 milligrams filter paper, enzyme concentrations needed to obtain half-maximal hydrolysis rates (KE values) were in the 3-4 microM range for the cellobiohydrolases (CBHs) and 0.05-0.10 microM for the endoglucanases (EGs). Catalytic-core proteins of CBH I and EG III, lacking the cellulose-binding domain, exhibit KE values 2.3 and 5.1 times higher than those of the intact enzymes. In synergistic combinations of two cellulases, the KE value of at least one enzyme was 3-10-fold reduced. CBH I/CBH II and CBH I/EG III combinations showed the most powerful synergism, and optimal ratios were a function of the total protein concentration. Results obtained in activity and adsorption assays using filter paper pretreated with one component, followed by inactivation and subsequent hydrolysis with the same or another cellulase component, point to a sequential enzymic attack of the cellulose and seems consistent with the mathematical model presented.

The cellulose-binding domain of endoglucanase A (CenA) from Cellulomonas fimi: evidence for the involvement of tryptophan residues in binding

Cellulomonas fimi endo-beta-1,4-glucanase A (CenA) contains a discrete N-terminal cellulose-binding domain (CBDCenA). Related CBDs occur in at least 16 bacterial glycanases and are characterized by four highly conserved Trp residues, two of which correspond to W14 and W68 of CBDCenA. The adsorption of CBDCenA to crystalline cellulose was compared with that of two Trp mutants (W14A and W68A). The affinities of the mutant CBDs for cellulose were reduced by approximately 50- and 30-fold, respectively, relative to the wild type. Physical measurements indicated that the mutant CBDs fold normally. Fluorescence data indicated that W14 and W68 were exposed on the CBD, consistent with their participation in binding to cellobiosyl residues on the cellulose surface.

A bifunctional affinity linker to couple antibodies to cellulose

We have constructed a fusion protein between the staphylococcal A protein and the cellulose binding domain of an exoglucanase (Cex) from Cellulomonas fimi that can be directly immobilized on cellulose while retaining its capacity to bind immunoglobulin G molecules. The cellulose domain provides binding that does not interfere with the biological activity of the fusion partner, does not involve hazardous chemicals and the matrix does not need to be chemically activated which reduces its cost. We have tested some of the possible applications of the fusion protein and show that it can be used in immunoassays, affinity chromatography and immunoprecipitations.

Visualization of the adsorption of a bacterial endo-beta-1,4-glucanase and its isolated cellulose-binding domain to crystalline cellulose

Endo-beta-1,4-glucanase A (CenA), a cellulase from the bacterium Cellulomonas fimi, is composed of two domains: a catalytic domain and a cellulose-binding domain. Adsorption of CenA and its isolated cellulose-binding domain (CBD.PTCenA) to Valonia cellulose microcrystals was examined by transmission electron microscopy using an antibody sandwich technique (CenA/CBD.PTCenA-alpha CenA IgG-protein A-gold conjugate). Adsorption of both CenA and CBD.PTCenA occurred along the lengths of the microcrystals, with an apparent preference for certain crystal faces or edges. CenA or CBD.PTCenA, but not the isolated catalytic domain, were shown to prevent the flocculation of microcrystalline bacterial cellulose. The cellulose-binding domain may assist crystalline cellulose hydrolysis in vitro by promoting substrate dispersion.

Mode of action, kinetic properties and physicochemical characterization of two different domains of a bifunctional (1-->4)-beta-D-xylanase from Ruminococcus flavefaciens expressed separately in Escherichia coli

Two catalytic domains, A and C, of xylanase A (XYLA) from Ruminococcus flavefaciens were expressed separately as truncated gene products from lacZ fusions in Escherichia coli. The fusion products, referred to respectively as XYLA-A1 and XYLA-C2, were purified to homogeneity by anion-exchange chromatography and chromatofocusing. XYLA-A1 was isoelectric at pH 5.0 and had a molecular mass of 30 kDa, whereas XYLA-C2 had a pI of 5.4 and a molecular mass of 44 kDa. The catalytic activity shown by both domains was optimal at 50 degrees C, but XYLA-A1 was more sensitive than XYLA-C2 to temperatures higher than the optimum. XYLA-A1 showed a higher sensitivity to pH than XYLA-C2. The enzyme activity of both domains was completely inactivated in the presence of copper or silver ions and partially inactivated by iron or zinc ions. Neither domain was active on xylo-oligosaccharides shorter than xylopentaose: the rate of degradation of longer xylo-oligosaccharides (degree of polymerization 5-10) increased as the chain length increased. Analysis of the products of hydrolysis of xylo-oligosaccharides and xylan (arabinoxylan) polysaccharide showed that the two domains differed in their modes of action: xylobiose was the shortest product of the hydrolysis. With oat spelt xylan as substrate, XYLA-A1 activity was apparently restricted to regions where xylopyranosyl residues did not carry arabinofuranosyl substituents, whereas XYLA-C2 was able to release hetero-oligosaccharides carrying arabinofuranosyl residues. Neither domain was able to release arabinose from oat spelt xylan.

Molecular analysis of the major cellulase (CelV) of Erwinia carotovora: evidence for an evolutionary "mix-and-match" of enzyme domains

The structural gene for the major cellulase of Erwinia carotovora subspecies carotovora (Ecc) was isolated and expressed in Escherichia coli. Sequencing of the gene (celV) revealed a typical signal sequence and two functional domains in the enzyme; a catalytic domain linked by a short proline/threonine-rich linker to a cellulose-binding domain (CBD). The deduced amino acid sequence of the catalytic domain showed homology with cellulases of Family A, including enzymes from Bacillus spp. and Erwinia chrysanthemi CelZ, whereas the CBD showed homology with cellulases from several diverse families, supporting a "mix-and-match" hypothesis for evolution of this domain. Analysis of the substrate specificity of CelV showed it to be an endoglucanase with some exoglucanase activity. The pH optimum is about 7.0 and the temperature optimum about 42 degrees C. CelV is secreted by Ecc and by the taxonomically related Erwinia carotovora subspecies atroseptica (Eca) but not by E. coli. Overproduction of the enzyme from multicopy plasmids in Ecc appears to overload the secretory mechanism.

A modular esterase from Pseudomonas fluorescens subsp. cellulosa contains a non-catalytic cellulose-binding domain

The 5' regions of genes xynB and xynC, coding for a xylanase and arabinofuranosidase respectively, are identical and are reiterated four times within the Pseudomonas fluorescens subsp. cellulosa genome. To isolate further copies of the reiterated xynB/C 5' region, a genomic library of Ps. fluorescens subsp. cellulosa DNA was screened with a probe constructed from the conserved region of xynB. DNA from one phage which hybridized to the probe, but not to sequences upstream or downstream of the reiterated xynB/C locus, was subcloned into pMTL22p to construct pFG1. The recombinant plasmid expressed a protein in Escherichia coli, designated esterase XYLD, of M(r) 58,500 which bound to cellulose but not to xylan. XYLD hydrolysed aryl esters, released acetate groups from acetylxylan and liberated 4-hydroxy-3-methoxycinnamic acid from destarched wheat bran. The nucleotide sequence of the XYLD-encoding gene, xynD, revealed an open reading frame of 1752 bp which directed the synthesis of a protein of M(r) 60,589. The 5' 817 bp of xynD and the amino acid sequence between residues 37 and 311 of XYLD were almost identical with the corresponding regions of xynB and xynC and their encoded proteins XYLB and XYLC. Truncated derivatives of XYLD lacking the N-terminal conserved sequence retained the capacity to hydrolyse ester linkages, but did not bind cellulose. Expression of truncated derivatives of xynD, comprising the 5' 817 bp sequence, encoded a non-catalytic polypeptide that bound cellulose. These data indicate that XYLD has a modular structure comprising of a N-terminal cellulose-binding domain and a C-terminal catalytic domain.

Disulfide arrangement and functional domains of beta-1,4-endoglucanse E5 from Thermomonospora fusca

Thermomonospora fusca cellulase E5 contains six cysteine residues. The number and location of the disulfide bonds and the effect of reduction of the disulfides and modification of the resulting half-cystine residues on enzymatic activity were determined. No free sulfhydryl groups were found in E5. Reduction and subsequent labeling with iodoacetamide of E5 and of an enzymatically active 32-kDa proteolytic derivative of E5 (E5cd) showed that one of the three disulfides is accessible to reduction under nondenatured conditions while the other two are not accessible. Full reduction of the disulfides and complete carboxymethylation of the six cysteines decrease the specific activity of E5 on CMC by more than half, but reduction of only the exposed disulfide bond does not affect enzymatic activity or binding of E5 to cellulose. A 14-kDa proteolytic fragment of E5 containing 120 amino acids from the N-terminus of the protein was shown to bind to crystalline cellulose. This confirms earlier evidence that the cellulose binding domain of E5 is located at the N-terminus of the protein. This 14-kDa fragment contains the accessible disulfide bond involving Cys93 and Cys100. The location of the two disulfide bonds in the other fragment (E5cd) was determined by cleaving it with cyanogen bromide under conditions that left the disulfide bonds intact. The resulting peptides were separated under both nonreducing and reducing conditions using RP-HPLC. Amino acid analysis of peptide peaks indicated that one disulfide linkage in E5cd joins Cys138 to Cys143 while the other joins Cys166 to Cys406.

Trichoderma reesei has no true exo-cellulase: all intact and truncated cellulases produce new reducing end groups on cellulose

Adsorption to and formation of insoluble reducing end groups on cellulose was studied for intact enzymes and catalytic domains, 'cores', of the four major cellulases from Trichoderma reesei, CBH I, CBH II, EG I and EG III. Individual enzymes were incubated with NaBH4-reduced, phosphoric acid swollen Avicel (regenerated cellulose) or with filter paper. Adsorption onto regenerated cellulose was rapid (equilibration reached within 2 min), but was slow onto filter paper (not completed after 24 h). On both substrates, less was bound of the core domains than of the intact enzymes. After reaching a maximum in adsorption, all the core domains except CBH I core were released again. In general, the desorption of the core enzymes was much faster than the rate of substrate conversion. All enzymes produced new reducing end groups on both substrates, and thus none of them is a true exo-cellulase. However, both the rate of formation and the amount was considerably higher for the EG enzymes than for the CBH's, which may justify the classification of cellulases into two groups, although the difference is quantitative rather than qualitative. EG III was the most endo-active of the enzymes, and CBH I the least.

Hydrolyses of alpha- and beta-cellobiosyl fluorides by cellobiohydrolases of Trichoderma reesei

Cellobiohydrolase II hydrolyses alpha- and beta-D-cellobiosyl fluorides to alpha-cellobiose at comparable rates, according to Michaelis-Menten kinetics. The stereochemistry, absence of transfer products and strict hyperbolic kinetics of the hydrolysis of alpha-cellobiosyl fluoride suggest that the mechanism for the alpha-fluoride may be the enzymic counterpart of the SNi reaction observed in the trifluoroethanolysis of alpha-glucopyranosyl fluoride [Sinnott and Jencks (1980) J. Am. Chem. Soc. 102, 2026-2032]. The absolute factors by which this enzyme accelerates fluoride ion release are small and greater for the alpha-fluoride than for the beta, suggesting that its biological function may not be just glycoside hydrolysis. Cellobiohydrolase I hydrolyses only beta-cellobiosyl fluoride, which is, however, an approx. 1-3% contaminant in alpha-cellobiosyl fluoride as prepared and purified by conventional methods. Instrumental assays for the various components of the cellulase complex are discussed.

Biochemical Characterization of a Protease Involved in the Processing of a Streptomyces reticuli Cellulase (Avicelase)

A 36-kDa protease from Streptomyces reticuli had recently been shown to be responsible for the in vivo and in vitro processing of the 82-kDa cellulase (Avicelase) Cel-1 from S. reticuli to a 42-kDa truncated enzyme. It was induced only in the presence of Avicel, hydroxyethylcellulose, and xylan. The addition of the nonionic detergent Tween 80 to the culture medium containing Avicel as the carbon source led to a 10-fold increase in extracellular proteolytic activity. The protease, which has an isoelectric point of 3.9, was purified to homogeneity from the culture filtrate by a combination of anion-exchange and hydrophobic-interaction chromatographies and was characterized biochemically. The enzyme hydrolyzed gelatin and the chromogenic substrates Azocoll, Azocasein, and Azoalbumin. Its highest activity was determined between pH 7.0 and 7.7 and at 55°C. The proteolytic activity was inhibited by 1,10-phenanthroline and EDTA; however, no metal ions were detected to be associated with the protein. The protease was stable in the presence of 1 M urea and 0.01 M sodium dodecyl sulfate. The inhibitory effect of alpha-2-macroglobulin indicated an endo-mode of proteolytic cleavage. Studies with lectins and sugar analysis by mass spectroscopy indicated that the cellulase (Avicelase) Cel-1 was neither N nor O glycosylated. Its processing by the protease occurred at temperatures ranging from 30 to 55°C, pH 7.5, in the presence of 2 mM dithiothreitol.

Investigation of the function of mutated cellulose-binding domains of Trichoderma reesei cellobiohydrolase I

The function of the cellulose-binding domain (CBD) of the cellobiohydrolase I of Trichoderma reesei was studied by site-directed mutagenesis of two amino acid residues identified by analyzing the 3D structure of this domain. The mutant enzymes were produced in yeast and tested for binding and activity on crystalline cellulose. Mutagenesis of the tyrosine residue (Y492) located at the tip of the wedge-shaped domain to alanine or aspartate reduced the binding and activity on crystalline cellulose to the level of the core protein lacking the CBD. However, there was no effect on the activity toward small oligosaccharide (4-methylumbelliferyl beta-D-lactoside). The mutation tyrosine to histidine (Y492H) lowered but did not destroy the cellulose binding, suggesting that the interaction of the pyranose ring of the substrate with an aromatic side chain is important. However, the catalytic activity of this mutant on crystalline cellulose was identical to the other two mutants. The mutation P477R on the edge of the other face of the domain reduces both binding and activity of CBHI. These results support the hypothesis that both surfaces of the CBD are involved in the interaction of the binding domain with crystalline cellulose.

The gene encoding the cellulase (Avicelase) Cel1 from Streptomyces reticuli and analysis of protein domains

Streptomyces reticuli produces an unusual cellulase (Avicelase), with an apparent molecular weight of 82 kDa, which is solely sufficient to degrade crystalline cellulose. During cultivation the processing of the Avicelase to a truncated enzyme (42 kDa) and an inactive protein (40 kDa) correlated with the occurrence of an extracellular protease. After its purification this 36 kDa protease cleaved the S. reticuli Avicelase in vitro in the same manner. Using antibodies raised against the Avicelase and its truncated form (42 kDa) and gene libraries of S. reticuli DNA in the Escherichia coli phage vectors lambda gt11 and Charon 35, the Avicelase gene (cel1) was identified. Further subcloning and DNA-sequencing revealed a G+C rich (72%) reading frame of 2238 bp encoding a protein of 746 amino acids. The transcriptional start site was mapped about 180 bp upstream from the GTG start codon. A signal sequence of 29 amino acids was identified by aligning the deduced amino acids with the characterized N-terminus of the 82 kDa Avicelase. Comparison of the N-terminal amino acids from the purified proteins with the amino acid sequence derived from the Avicelase gene revealed that the truncated enzyme (42 kDa) corresponds to the C-terminal region whereas the inactive proteolytically derived protein (40 kDa) represents the N-terminal part of the 82 kDa Avicelase. Comparisons with amino acid sequences deduced from known cellulase genes indicated the presence of three putative protein domains: (i) an N-terminal part showing significant similarity with a repeat region of endoglucanase C from Cellulomonas fimi, recently shown to be a cellulose-binding domain; (ii) an adjoining region sharing homology with the N-terminal domains with unknown function of endoglucanase A from Pseudomonas fluorescens, endoglucanase D from Clostridium thermocellum and a cellodextrinase from Butyrivibrio fibrisolvens, and (iii) a C-terminal catalytic domain belonging to cellulase family E.

Genomic organization of a cellulase gene family in Phanerochaete chrysosporium

Southern blot and nucleotide sequence analysis of Phanerochaete chrysosporium BKM-F-1767 genomic clones indicate that this wood-degrading fungus contains at least six genes with significant homology to the Trichoderma reesei cellobiohydrolase I gene (cbh1). Using pulsed-field gel electrophoresis to separate P. chrysosporium chromosomes, the six cellulase genes were found to hybridize to at least three different chromosomes, one of which is dimorphic. The organization of these genes was similar in another P. chrysosporium strain, ME 446. It is clear that, unlike T. reesei, the most well-studied cellulolytic fungus, P. chrysosporium contains a complex, cbh1-like gene family.

Biochemical and Electron Microscopic Studies of the Streptomyces reticuli Cellulase (Avicelase) in Its Mycelium-Associated and Extracellular Forms

Streptomyces reticuli is able to grow efficiently with crystalline cellulose (Avicel) as the sole carbon source. Cultivation in the presence of the nonionic detergent Tween 80 at a concentration of 0.1% led to a 10-fold increase in extracellular cellulolytic activity. Under these conditions, one single 82-kDa cellulase (Avicelase) capable of degrading crystalline and soluble cellulose as well as cellodextrins and p -nitrophenylcellobioside was purified to apparent homogeneity by a procedure which consisted of two consecutive anion-exchange chromatographies followed by chromatofocusing. Aggregation, which was a major problem during protein purification, could be avoided by including Triton X-100 at a concentration of 0.1% in every chromatographic step. The Avicelase was identified in extracellular and mycelium-associated forms, the latter of which could be released efficiently by nonionic detergents. In addition, a 42-kDa truncated form retaining cellulolytic activity was identified which had been generated from the 82-kDa enzyme by a protease. Antibodies raised against the mycelium-associated Avicelase reacted with the 42-kDa derivative and the extracellular form. The mycelial association of the enzyme was confirmed by immunofluorescence and immunoelectron microscopies.

Homologous catalytic domains in a rumen fungal xylanase: evidence for gene duplication and prokaryotic origin

A cDNA (xynA), encoding xylanase A (XYLA), was isolated from a cDNA library, derived from mRNA extracted from the rumen anaerobic fungus, Neocallimastix patriciarum. Recombinant XYLA, purified from Escherichia coli harbouring xynA, had a M(r) of 53,000 and hydrolysed oat-spelt xylan to xylobiose and xylose. The enzyme did not hydrolyse any cellulosic substrates. The nucleotide sequence of xynA revealed a single open reading frame of 1821 bp coding for a protein of M(r) 66,192. The predicted primary structure of XYLA comprised an N-terminal signal peptide followed by a 225-amino-acid repeated sequence, which was separated from a tandem 40-residue C-terminal repeat by a threonine/proline linker sequence. The large N-terminal reiterated regions consisted of distinct catalytic domains which displayed similar substrate specificities to the full-length enzyme. The reiterated structure of XYLA suggests that the enzyme was derived from an ancestral gene which underwent two discrete duplications. Sequence comparison analysis revealed significant homology between XYLA and bacterial xylanases belonging to cellulase/xylanase family G. One of these homologous enzymes is derived from the rumen bacterium Ruminococcus flavefaciens. The homology observed between XYLA and a rumen prokaryote xylanase could be a consequence of the horizontal transfer of genes between rumen prokaryotes and lower eukaryotes, either when the organisms were resident in the rumen, or prior to their colonization of the ruminant. It should also be noted that Neocallimastix XYLA is the first example of a xylanase which consists of reiterated sequences. It remains to be established whether this is a common phenomenon in other rumen fungal plant cell wall hydrolases.

Structure, organization, and transcription of a cellobiohydrolase gene cluster from Phanerochaete chrysosporium

Restriction mapping and sequence analysis of cosmid clones revealed a cluster of three cellobiohydrolase genes in Phanerochaete chrysosporium. P. chrysosporium cbh1-1 and cbh1-2 are separated by only 750 bp and are located approximately 14 kb upstream from a cellulase gene previously cloned from P. chrysosporium (P. Sims, C. James, and P. Broda, Gene 74:411-422, 1988). Within a well-conserved region, the deduced amino acid sequences of P. chrysosporium cbh1-1 and cbh1-2 are, respectively, 80 and 69% homologous to that of the Trichoderma reesei cellobiohydrolase I gene. The conserved cellulose-binding domain typical of microbial cellulases is absent from cbh1-1. Transcript levels of the three P. chrysosporium genes varied substantially, depending on culture conditions. cbh1-1 and cbh1-2 were not induced in the presence of cellulose, nor did they appear to be subject to glucose repression. Therefore, aspects of the chromosomal organization, structure, and transcription of these genes are unlike those of any previously described cellulase genes.

Involvement of separate domains of the cellulosomal protein S1 of Clostridium thermocellum in binding to cellulose and in anchoring of catalytic subunits to the cellulosome

Fragments of the 250 kDa S1 subunit of the Clostridium thermocellum cellulosome were obtained by protease-induced or spontaneous degradation. All detectable fragments, down to a mass of about 30 kDa, retained the ability to bind to 125I-labelled endoglucanase CelD, one of the catalytic subunits of the cellulosome. Several fragments were able to bind both to cellulose and to CelD. However, some fragments that could still bind to CelD did not have the ability to bind to cellulose. Therefore, S1, a putative scaffolding protein of the cellulosome, is likely to carry two separate types of domains, one of which binds to cellulose, while the other type binds to the various catalytic subunits of the complex.

Cellobiose oxidase of Phanerochaete chrysosporium enhances crystalline cellulose degradation by cellulases

The effect of Phanerochaete chrysosporium cellobiose oxidase (CBO) on microcrystalline cellulose hydrolysis by Trichoderma cellulases was determined. Addition of 10 micrograms.ml-1 CBO to a reaction mixture containing T. viride cellulase increased glucose and cellobiose production by 10% and 48%, respectively. Cellulose weight loss was also enhanced by 19%. At higher concentrations (20-80 micrograms.ml-1), CBO decreased glucose and cellobiose production. Cellulose weight loss at 60 micrograms.ml-1 CBO was 76% compared to control cellulase reactions. This decrease appears to be due to inactivation of cellulase by H2O2 produced via CBO reaction, because addition of catalase enhances sugar production and cellulose weight loss. These findings suggest that at low, perhaps physiologically relevant concentrations, CBO enhances crystalline cellulose degradation by cellulases.

The binding of Cellulomonas fimi endoglucanase C (CenC) to cellulose and Sephadex is mediated by the N-terminal repeats

Endoglucanase C (CenC) from Cellulomonas fimi binds to cellulose and to Sephadex. The enzyme has two contiguous 150-amino-acid repeats (N1 and N2) at its N-terminus and two unrelated contiguous 100-amino-acid repeats (C1 and C2) at its C-terminus. Polypeptides corresponding to N1, N1N2, C1, and C1C2 were produced by expression of appropriate cenC gene fragments in Escherichia coli. N1N2, but not N1 alone, binds to Sephadex; both polypeptides bind to Avicel, (a heterogeneous cellulose preparation containing both crystalline and non-crystalline components). Neither C1 nor C1C2 binds to Avicel or Sephadex. N1N2 and N1 bind to regenerated ('amorphous') cellulose but not to bacterial crystalline cellulose; the cellulose-binding domain of C. fimi exoglucanase Cex binds to both of these forms of cellulose. Amino acid sequence comparison reveals that N1 and N2 are distantly related to the cellulose-binding domains of Cex and C. fimi endoglucanases A and B.

Characterization and comparison of Clostridium cellulovorans endoglucanases-xylanases EngB and EngD hyperexpressed in Escherichia coli

By the use of a T7 expression system, endoglucanases-xylanases EngB and EngD from Clostridium cellulovorans were hyperexpressed and purified from Escherichia coli. The two enzymes demonstrated both endoglucanase and xylanase activities. The substrate specificities of both endoglucanases were similar except that EngD had four-times-greater p-nitrophenyl beta-1,4-cellobiosidase activity. The two proteins were very homologous (80%) up to the Pro-Thr-Thr region which divided the protein into -NH2- and -COOH-terminals. The -COOH- region of EngB has high homology to the endoglucanases and a xylanase from Clostridium thermocellum and to an endoglucanase from Clostridium cellulolyticum and did not show strong binding to cellulose (Avicel). However, the -COOH- region of EngD, which had homology to the cellulose-binding domains of Cellulomonas fimi exo- and endoglucanases and to Pseudomonas fluorescens endoglucanase, demonstrated binding ability to cellulose even when the domain was fused to the N-terminal domain of EngB. By probing the Avicel-purified cellulase complex (F8) with anti-EngB and anti-EngD antibodies, both EngB and EngD were shown to be present on the cellulase complex of C. cellulovorans. Many proteins homologous to EngB and EngD were also present on the complex.

The 1,4-beta-D-glucan glucanohydrolases from Phanerochaete chrysosporium. Re-assessment of their significance in cellulose degradation mechanisms

A physico-chemical, functional and structural characterization, including partial sequence data, of three major 1,4-beta-D-glucan glucanohydrolases (EC. 3.2.1.4) isolated from the culture filtrate of the white-rot fungus Phanerochaete chrysosporium, shows that all three enzymes belong to a single family of cellulases. EG44, pI 4.3, (named after its apparent molecular mass in kDa), shows a clear homology with Schizopyllum commune Endoglucanase I (EGI); whereas EG38, pI 4.9, (named in the same manner) is related more closely to Trichoderma reesei (Trichoderma longibrachiatum) Endoglucanase III (EGIII). EG36, pI 5.6-5.7, is probably an EG38 protein lacking its cellulose binding domain. Strong synergistic action is induced by the enzymes acting in concert with cellobiohydrolases (CBHI and CBHII) from the same organism, indicating a highly effective enzymatic system for cellulose degradation. Controlled proteolysis with papain has allowed a so far unique cleavage of endoglucanases EG44 and EG38 into two domains: a core protein, which virtually lacks the capacity to absorb onto microcrystal-line cellulose but retains full catalytic activity against carboxymethyl cellulose and low molecular weight soluble substrates; and a peptide fragment corresponding to the cellulose binding domain. The latter appears to be of paramount significance in the mechanisms involved in the hydrolysis of microcrystalline cellulose.

Three N-terminal domains of beta-1,3-glucanase A1 are involved in binding to insoluble beta-1,3-glucan

Limited proteolysis of beta-1,3-glucanase A1 by three different proteases, trypsin, chymotrypsin, and papain, gave three major active fragments. The sizes of the three major fragments generated by each protease treatment were identical to those of beta-1,3-glucanase A2, A3, and A4 detected in both the culture supernatant of Bacillus circulans WL-12 and the periplasmic space of Escherichia coli carrying a cloned glcA gene. These results indicate a four-domain structure for the enzyme. At the N terminus of the glucanase, duplicated segments of approximately 100 amino acids were observed. N-terminal amino acid sequence analysis revealed that the active fragments with sizes corresponding to those of A2 and A3 lack the first segment (domain) and both duplicated segments (domains), respectively. The fragment corresponding to A4 lacks both duplicated segments and the following ca. 120-amino-acid region. By losing the first, second, and third (corresponding to the segment of 120 amino acids) domains, beta-1,3-glucanase progressively lost the ability to bind to pachyman, beta-1,3-glucan. An active fragment which did not have the three N-terminal domains did not show significant binding to pachyman. Thus, all three N-terminal domains contribute to binding to beta-1,3-glucan, and the presence of three domains confers the highest binding activity on the glucanase. The loss of these binding domains remarkably decreased pachyman-hydrolyzing activity, indicating that the binding activity is essential for the efficient hydrolysis of insoluble beta-1,3-glucan.

Structural and functional relationships in two families of beta-1,4-glycanases

CenA and Cex are beta-1,4-glycanases produced by the cellulolytic bacterium Cellulomonas fimi. Both enzymes are composed of two domains and contain six Cys residues. Two disulfide bonds were assigned in both enzymes by peptide analysis of the isolated catalytic domains. A further disulfide bond was deduced in both cellulose-binding domains from the absence of free thiols under denaturing conditions. Corresponding Cys residues are conserved in eight of nine other known C. fimi-type cellulose-binding domains. CenA and Cex belong to families B and F, respectively, in the classification of beta-1,4-glucanases and beta-1,4-xylanases based on similarities in catalytic domain primary structure. Disulfide bonds in the CenA catalytic domain correspond to the two disulfide bonds in the catalytic domain of Trichoderma reesei cellobiohydrolase II (family B) which stabilize loops forming the active-site tunnel. Sequence alignment indicates the probable occurrence of disulfides at equivalent positions in the two other family B enzymes. Partial resequencing of the gene encoding Streptomyces KSM-9 beta-1,4-glucanase CasA (family B) revealed five errors in the original nucleotide sequence analysis. The corrected amino acid sequence contains an Asp residue corresponding to the proposed proton donor in hydrolysis catalysed by cellobiohydrolase II. Cys residues which form disulfide bonds in the Cex catalytic domain are conserved in XynZ of Clostridium thermocellum and Xyn of Cryptococcus albidus but not in the other eight known family F enzymes. Like other members of its family, Cex catalyses xylan hydrolysis. The catalytic efficiency (kcat/Km) for hydrolysis of the heterosidic bond of p-nitrophenyl-beta-D-xylobioside is 14,385 min-1.mM-1 at 25 degrees C; the corresponding kcat/Km for p-nitrophenyl-beta-D-cellobioside hydrolysis is 296 min-1.mM-1.

Characterization of endoglucanase A from Clostridium cellulolyticum

A construction was carried out to obtain a high level of expression in Escherichia coli of the gene celCCA, coding for the endoglucanase A from Clostridium cellulolyticum (EGCCA). The enzyme was purified in two forms with different molecular weights, 51,000 and 44,000. The smaller protein was probably the result of proteolysis, although great care was taken to prevent this process from occurring. Evidence was found for the loss of the conserved reiterated domains which are characteristic of C. thermocellum and C. cellulolyticum cellulases. The two forms were extensively studied, and it was demonstrated that although they had the same pH and temperature optima, they differed in their catalytic properties. The truncated protein gave the more efficient catalytic parameters on carboxymethyl cellulose and showed improved endoglucanase characteristics, whereas the intact enzyme showed truer cellulase characteristics. The possible role of clostridial reiterated domains in the hydrolytic activity toward crystalline cellulose is discussed.

Characterization of hybrid proteins consisting of the catalytic domains of Clostridium and Ruminococcus endoglucanases, fused to Pseudomonas non-catalytic cellulose-binding domains

The N-terminal 160 or 267 residues of xylanase A from Pseudomonas fluorescens subsp. cellulosa, containing a non-catalytic cellulose-binding domain (CBD), were fused to the N-terminus of the catalytic domain of endoglucanase E (EGE') from Clostridium thermocellum. A further hybrid enzyme was constructed consisting of the 347 N-terminal residues of xylanase C (XYLC) from P. fluorescens subsp. cellulosa, which also constitutes a CBD, fused to the N-terminus of endoglucanase A (EGA) from Ruminococcus albus. The three hybrid enzymes bound to insoluble cellulose, and could be eluted such that cellulose-binding capacity and catalytic activity were retained. The catalytic properties of the fusion enzymes were similar to EGE' and EGA respectively. Residues 37-347 and 34-347 of XYLC were fused to the C-terminus of EGE' and the 10 amino acids encoded by the multiple cloning sequence of pMTL22p respectively. The two hybrid proteins did not bind cellulose, although residues 39-139 of XYLC were shown previously to constitute a functional CBD. The putative role of the P. fluorescens subsp. cellulosa CBD in cellulase action is discussed.

The cellodextrinase from Pseudomonas fluorescens subsp. cellulosa consists of multiple functional domains

A genomic library of Pseudomonas fluorescens subsp. cellulosa DNA was constructed in pUC18 and Escherichia coli recombinants expressing 4-methylumbelliferyl beta-D-cellobioside-hydrolysing activity (MUCase) were isolated. Enzyme produced by MUCase-positive clones did not hydrolyse either cellobiose or cellotriose but converted cellotetraose into cellobiose and cleaved cellopentaose and cellohexaose, producing a mixture of cellobiose and cellotriose. There was no activity against CM-cellulose, insoluble cellulose or xylan. On this basis, the enzyme is identified as an endo-acting cellodextrinase and is designated cellodextrinase C (CELC). Nucleotide sequencing of the gene (celC) which directs the synthesis of CELC revealed an open reading frame of 2153 bp, encoding a protein of Mr 80,189. The deduced primary sequence of CELC was confirmed by the Mr of purified CELC (77,000) and by the experimentally determined N-terminus of the enzyme which was identical with residues 38-47 of the translated sequence. The N-terminal region of CELC showed strong homology with endoglucanase, xylanases and an arabinofuranosidase of Ps. fluorescens subsp. cellulosa; homologous sequences included highly conserved serine-rich regions. Full-length CELC bound tightly to crystalline cellulose. Truncated forms of celC from which the DNA sequence encoding the conserved domain had been deleted, directed the synthesis of a functional cellodextrinase that did not bind to crystalline cellulose. This is consistent with the N-terminal region of CELC comprising a non-catalytic cellulose-binding domain which is distinct from the catalytic domain. The role of the cellulose-binding region is discussed.

Structural and functional analysis of Trichoderma reesei endoglucanase I expressed in yeast Saccharomyces cerevisiae

The function of the domains of Trichoderma reesei endoglucanase I (EGI) has been studied. Truncated EGI proteins were expressed from the 3'-end deleted cDNAs in the yeast Saccharomyces cerevisiae under the control of the ADC1 expression cassette. EGI protein was detected by monoclonal antibody EI-2 and EGI activity as cleared zones around growing colonies on agar plates containing hydroxyethylcellulose (HEC) covalently stained with Ostazin brilliant red (OBR). The results showed that the The-Ser-rich hinge region and the conserved 'tail' are not necessary for the efficient synthesis and secretion of EGI in yeast, but the intact core region is necessary for the enzymatic activity.