Determination of subunit composition of Clostridium cellulovorans cellulosomes that degrade plant cell walls

Clostridium cellulovorans produces a cellulase enzyme complex (cellulosome). In this study, we isolated two plant cell wall-degrading cellulosomal fractions from culture supernatant of C. cellulovorans and determined their subunit compositions and enzymatic activities. One of the cellulosomal fractions showed fourfold-higher plant cell wall-degrading activity than the other. Both cellulosomal fractions contained the same nine subunits (the scaffolding protein CbpA, endoglucanases EngE and EngK, cellobiohydrolase ExgS, xylanase XynA, mannanase ManA, and three unknown proteins), although the relative amounts of the subunits differed. Since only cellobiose was released from plant cell walls by the cellulosomal fractions, cellobiohydrolases were considered to be key enzymes for plant cell wall degradation.     

Hydrophilic domains of scaffolding protein CbpA promote glycosyl hydrolase activity and localization of cellulosomes to the cell surface of Clostridium cellulovorans

CbpA, the scaffolding protein of Clostridium cellulovorans cellulosomes, possesses one family 3 cellulose binding domain, nine cohesin domains, and four hydrophilic domains (HLDs). Among the three types of domains, the function of the HLDs is still unknown. We proposed previously that the HLDs of CbpA play a role in attaching the cellulosome to the cell surface, since they showed some homology to the surface layer homology domains of EngE. Several recombinant proteins with HLDs (rHLDs) and recombinant EngE (rEngE) were examined to determine their binding to the C. cellulovorans cell wall fraction. Tandemly linked rHLDs showed higher affinity for the cell wall than individual rHLDs showed. EngE was shown to have a higher affinity for cell walls than rHLDs have. C. cellulovorans native cellulosomes were found to have higher affinity for cell walls than rHLDs have. When immunoblot analysis was carried out with the native cellulosome fraction bound to cell wall fragments, the presence of EngE was also confirmed, suggesting that the mechanism anchoring CbpA to the C. cellulovorans cell surface was mediated through EngE and that the HLDs play a secondary role in the attachment of the cellulosome to the cell surface. During a study of the role of HLDs on cellulose degradation, the mini-cellulosome complexes with HLDs degraded cellulose more efficiently than complexes without HLDs degraded cellulose. The rHLDs also showed binding affinity for crystalline cellulose and carboxymethyl cellulose. These results suggest that the CbpA HLDs play a major role and a minor role in C. cellulovorans cellulosomes. The primary role increases cellulose degradation activity by binding the cellulosome complex to the cellulose substrate; secondarily, HLDs aid the binding of the CbpA/cellulosome to the C. cellulovorans cell surface.     

Cohesin-dockerin interactions of cellulosomal subunits of Clostridium cellulovorans

The cellulosome of Clostridium cellulovorans consists of three major subunits: CbpA, EngE, and ExgS. The C. cellulovorans scaffolding protein (CbpA) contains nine hydrophobic repeated domains (cohesins) for the binding of enzymatic subunits. Cohesin domains are quite homologous, but there are some questions regarding their binding specificity because some of the domains have regions of low-level sequence similarity. Two cohesins which exhibit 60% sequence similarity were investigated for their ability to bind cellulosomal enzymes. Cohesin 1 (Coh1) was found to contain amino acid residues corresponding to amino acids 312 to 453 of CbpA, which contains a total of 1,848 amino acid residues. Coh6 was determined to contain amino acid residues corresponding to residues 1113 to 1254 of CbpA. By genetic construction, these two cohesins were each fused to MalE, producing MalE-Coh1 and MalE-Coh6. The abilities of two fusion proteins to bind to EngE, ExgS, and CbpA were compared. Although MalE-Coh6 could bind EngE and ExgS, little or no binding of the enzymatic subunits was observed with MalE-Coh1. Significantly, the abilities of the two fusion proteins to bind CbpA were similar. The binding of dockerin-containing enzymes to cohesin-containing proteins was suggested as a model for assembly of cellulosomes. In our examination of the role of dockerins, it was also shown that the binding of endoglucanase B (EngB) to CbpA was dependent on the presence of EngB's dockerin. These results suggest that different cohesins may function with differing efficiency and specificity, that cohesins may play some role in the formation of polycellulosomes through Coh-CbpA interactions, and that dockerins play an important role during the interaction of cellulosomal enzymes and cohesins present in CbpA.     

Characterization of a cellulose binding domain from Clostridium cellulovorans endoglucanase-xylanase D and its use as a fusion partner for soluble protein expression in Escherichia coli

Different chimeric proteins combining the non-catalytic C-terminal putative cellulose binding domain of Clostridium cellulovorans endoglucanase-xylanase D (EngD) with its proline-threonine rich region PT-linker, PTCBD(EngD), cellulose binding domain of C. cellulovorans cellulose binding protein A, CBD(CbpA), cohesin domains Cip7, Coh6 and CipC1 from different clostridial species and recombinant antibody binding protein LG were constructed, expressed, purified and analyzed. The solubilities of chimeric proteins containing highly soluble domains Cip7, CipC1 and LG were not affected by fusion with PTCBD(EngD). Insoluble domain Coh6 was solubilized when fused with PTCBD(EngD). In contrast, fusion with CBD(CbpA) resulted in only a slight increase in solubility of Coh6 and even decreased solubility of CipC1 greatly. PTCBD(EngD) and Cip7-PTCBD(EngD) were shown to bind regenerated commercial amorphous cellulose Cuprophan. The purity of Cip7-PTCBD(EngD) eluted from Cuprophan was comparable to that purified by conventional ion exchange chromatography. The results demonstrated that PTCBD(EngD) can serve as a bi-functional fusion tag for solubilization of fusion partners and as a domain for the immobilization, enrichment and purification of molecules or cells on regenerated amorphous cellulose.     

Synergistic interaction of Clostridium cellulovorans cellulosomal cellulases and HbpA

Clostridium cellulovorans, an anaerobic bacterium, produces a small nonenzymatic protein called HbpA, which has a surface layer homology domain and a type I cohesin domain similar to those found in the cellulosomal scaffolding protein CbpA. In this study, we demonstrated that HbpA could bind to cell wall fragments from C. cellulovorans and insoluble polysaccharides and form a complex with cellulosomal cellulases endoglucanase B (EngB) and endoglucanase L (EngL). Synergistic degradative action of the cellulosomal cellulase and HbpA complexes was demonstrated on acid-swollen cellulose, Avicel, and corn fiber. We propose that HbpA functions to bind dockerin-containing cellulosomal enzymes to the cell surface and complements the activity of cellulosomes.     

Cell-Surface-Anchoring Role of N-Terminal Surface Layer Homology Domains of Clostridium cellulovorans EngE

engE, coding for endoglucanase E, one of the three major subunits of the Clostridium cellulovorans cellulosome, has been cloned and sequenced (Y. Tamaru and R. H. Doi, J. Bacteriol. 181:3270-3276, 1999). The N-terminal-half region of EngE possesses three repeated surface layer homology (SLH) domains, which are homologous to those of some bacterial S-layer proteins. Also, the C-terminal-half region consists of a catalytic domain of glycosyl hydrolase family 5 and a duplicated sequence (dockerin) for binding EngE to scaffolding protein CbpA. Our hypothesis is that the SLH domains serve in the role of anchoring to the cell surface. This model was investigated by using recombinant EngEs (rEngE) with and without SLH domains that were synthesized in Escherichia coli and cell wall preparations from C. cellulovorans. When rEngE and SLH polypeptides of EngE were incubated with cell wall fragments prepared by sodium dodecyl sulfate treatment, these proteins bound strongly to the cell wall. However, rEngEs without SLH domains lost their ability to bind to cell walls. When rEngE was incubated with mini-CbpA, consisting of two cohesin domains, and cell wall fragments, the mini-CbpA was able to bind to the cell wall with rEngE. However, the binding of mini-CbpA was dramatically inhibited by addition of a chelating reagent, such as EDTA, which prevents cohesin-dockerin interactions. These results suggest not only that the SLH domains of EngE can bind to the cell surface but also that EngE plays an anchoring role for cellulosomes through the interaction of its dockerin domain with a CbpA cohesin.     

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.     

Three Surface Layer Homology Domains at the N Terminus of the Clostridium cellulovorans Major Cellulosomal Subunit EngE

The gene engE, coding for endoglucanase E, one of the three major subunits of the Clostridium cellulovorans cellulosome, has been isolated and sequenced. engE is comprised of an open reading frame (ORF) of 3,090 bp and encodes a protein of 1,030 amino acids with a molecular weight of 111,796. The amino acid sequence derived from engE revealed a structure consisting of catalytic and noncatalytic domains. The N-terminal-half region of EngE consisted of a signal peptide of 31 amino acid residues and three repeated surface layer homology (SLH) domains, which were highly conserved and homologous to an S-layer protein from the gram-negative bacterium Caulobacter crescentus. The C-terminal-half region, which is necessary for the enzymatic function of EngE and for binding of EngE to the scaffolding protein CbpA, consisted of a catalytic domain homologous to that of family 5 of the glycosyl hydrolases, a domain of unknown function, and a duplicated sequence (DS or dockerin) at its C terminus. engE is located downstream of an ORF, ORF1, that is homologous to the Bacillus subtilis phosphomethylpyrimidine kinase (pmk) gene. The unique presence of three SLH domains and a DS suggests that EngE is capable of binding both to CbpA to form a CbpA-EngE cellulosome complex and to the surface layer of C. cellulovorans.     

A large gene cluster for the Clostridium cellulovorans cellulosome

A large gene cluster for the Clostridium cellulovorans cellulosome has been cloned and sequenced upstream and downstream of the cbpA and exgS genes (C.-C. Liu and R. H. Doi, Gene 211:39-47, 1998). Gene walking revealed that the engL gene cluster (Y. Tamaru and R. H. Doi, J. Bacteriol. 182:244-247, 2000) was located downstream of the cbpA-exgS genes. Further DNA sequencing revealed that this cluster contains the genes for the scaffolding protein CbpA, the exoglucanase ExgS, several endoglucanases of family 9, the mannanase ManA, and the hydrophobic protein HbpA containing a surface layer homology domain and a hydrophobic (or cohesin) domain. The sequence of the clustered genes is cbpA-exgS-engH-engK-hbpA-engL-man A-engM-engN and is about 22 kb in length. The engN gene did not have a complete catalytic domain, indicating that engN is a truncated gene. This large gene cluster is flanked at the 5' end by a putative noncellulosomal operon consisting of nifV-orf1-sigX-regA and at the 3' end by noncellulosomal genes with homology to transposase (trp) and malate permease (mle). Since gene clusters for the cellulosome are also found in C. cellulolyticum and C. josui, they seem to be typical of mesophilic clostridia, indicating that the large gene clusters may arise from a common ancestor with some evolutionary modifications.     

Degradation of corn fiber by Clostridium cellulovorans cellulases and hemicellulases and contribution of scaffolding protein CbpA

Clostridium cellulovorans, an anaerobic bacterium, degrades native substrates efficiently by producing an extracellular enzyme complex called the cellulosome. All cellulosomal enzyme subunits contain dockerin domains that can bind to hydrophobic domains termed cohesins which are repeated nine times in CbpA, the nonenzymatic scaffolding protein of C. cellulovorans cellulosomes. In this study, the synergistic interactions of cellulases (endoglucanase E, EngE; endoglucanase L, EngL) and hemicellulases (arabinofuranosidase A, ArfA; xylanase A, XynA) were determined on the degradation of corn fiber, a natural substrate containing mainly xylan, arabinan, and cellulose. The degradation by XynA and ArfA of cellulose/arabinoxylan was greater than that of corn fiber and resulted in 2.6-fold and 1.4-fold increases in synergy, respectively. Synergistic effects were observed in increments in both simultaneous and sequential reactions with ArfA and XynA. These synergistic enzymes appear to represent potential rate-limiting enzymes for efficient hemicellulose degradation. When mini-cellulosomes were constructed from the cellulosomal enzymes (XynA and EngL) and mini-CbpA with cohesins 1 and 2 (mini-CbpA1&2) and mini-CbpA with cohesins 5 and 6 (mini-CbpA5&6), higher activity was observed than that for the corresponding enzymes alone. Based on the degradation of different types of celluloses and hemicelluloses, the interaction between cellulosomal enzymes (XynA and EngL) and mini-CbpA displayed a diversity that suggests that dockerin-cohesin interaction from C. cellulovorans may be more selective than random.     

Effects of the PT region of EngD and HLD of CbpA on solubility, catalytic activity and purification characteristics of EngD-CBD(CbpA) fusions from Clostridium cellulovorans

Chimeric proteins combining the catalytic N-terminal region of native EngD with its proline-threonine-threonine (PT) linker region, hydrophilic domain (HLD) and cellulose binding domain (CBD) of cellulose binding protein A (CbpA) from Clostridium cellulovorans were constructed, expressed, and analyzed. The chimeric proteins with CBD(CbpA) all demonstrated strong affinity to Avicel. The chimeric protein with the PT region of EngD and the HLD had the best catalytic activity and the highest estimated percentage of soluble protein amongst the chimeric proteins. Native EngD and two of the chimeric proteins (EngD-PT-HLD-CBD and EngD-CBD) were purified and their characteristics analyzed. Their binding affinities to Avicel as well as their enzymatic activities against various substrates were found to be consistent with the results we saw from protein lysate samples, which was good binding to Avicel but a decrease in solubility and catalytic activities in chimeric proteins without PT and/or HLD. The reasons for these are discussed. These fusion proteins may be important in applications, such as immobilization to solid cellulose substrate for purification of proteins and enrichment/aggregation of protein complexes.     

Mutation analysis of the cellulose-binding domain of the Clostridium cellulovorans cellulose-binding protein A.

Cellulose-binding protein A (CbpA) has been previously shown to mediate the interaction between crystalline cellulose substrates and the cellulase enzyme complex of Clostridium cellulovorans. CbpA contains a family III cellulose-binding domain (CBD) which, when expressed independently, binds specifically to crystalline cellulose. A series of N- and C-terminal deletions and a series of small internal deletions of the CBD were created to determine whether the entire region previously described as a CBD is required for the cellulose-binding function. The N- and C-terminal deletions reduced binding affinity by 10- to 100-fold. Small internal deletions of the CBD resulted in substantial reduction of CBD function. Some, but not all, point mutations throughout the sequence had significant disruptive effects on the binding ability of the CBD. Thus, mutations in any region of the CBD had effects on the binding of the fragment to cellulose. The results indicate that the entire 163-amino-acid region of the CBD is required for maximal binding to crystalline cellulose.     

Cellulosome and noncellulosomal cellulases of Clostridium cellulovorans

This paper reviews the properties of the cellulosome and noncellulosome cellulases produced by Clostridium cellulovorans, an anaerobic, mesophilic, spore-forming microorganism that produces copious amounts of cellulase. The three major subunits of the cellulosome, CbpA, exoglucanase S (ExgS), and P100, are described, as well as the properties of the functional domains of CbpA. The properties of two noncellulosomal endoglucanases, EngD and EngF, are compared. The functions of the cellulose-binding domain (CBD) of CbpA indicate its potential uses in biotechnology. Received: November 18, 1997 / Accepted: November 26, 1997     

Nucleotide sequence and characteristics of endoglucanase gene engB from Clostridium cellulovorans

An endoglucanase gene, engB, from Clostridium cellulovorans, previously cloned into pUC19, has been further characterized and its product investigated. The enzyme, EngB, encoded by the gene was secreted into the periplasmic space of Escherichia coli. The enzyme was active against carboxymethylcellulose, xylan and lichenan but not Avicel (crystalline cellulose). The sequenced gene showed an open reading frame of 1323 base pairs and coded for a protein with a molecular mass of 48.6 kDa. The mRNA contained a typical Gram-positive ribosome-binding site sequence GGAGG and a sequence coding for a putative signal peptide. There is high amino acid and base sequence homology between the N-terminal regions of EngB and another C. cellulovorans endoglucanase, EngD, but they differ significantly in their C-termini. Deletion analyses revealed that up to 32 amino acids of the N-terminus and 52 amino acids of the C-terminus were not required for catalytic activity. The conserved reiterated domains at the C-terminus of EngB were similar to those from endoglucanases from other cellulytic bacteria. According to our deletion analyses, this region is not needed for catalytic activity.     

Cellulose promotes extracellular assembly of Clostridium cellulovorans cellulosomes.

Cellulosome synthesis by Clostridium cellulovorans was investigated by growing the cells in media containing different carbon sources. Supernatant from cells grown with cellobiose contained no cellulosomes and only the free forms of cellulosomal major subunits CbpA, P100, and P70 and the minor subunits with enzymatic activity. Supernatant from cells grown on pebble-milled cellulose and Avicel contained cellulosomes capable of degrading crystalline cellulose. Supernatants from cells grown with cellobiose, pebble-milled cellulose, and Avicel contained about the same amount of carboxymethyl cellulase activity. Although the supernatant from the medium containing cellobiose did not initially contain active cellulosomes, the addition of crystalline cellulose to the cell-free supernatant fraction converted the free major forms to cellulosomes with the ability to degrade crystalline cellulose. The binding of P100 and P70 to crystalline cellulose was dependent on their attachment to the endoglucanase-binding domains of CbpA. These data strongly indicate that crystalline cellulose promotes cellulosome assembly.     

Determination of Subunit Composition of Clostridium cellulovorans Cellulosomes That Degrade Plant Cell Walls

Clostridium cellulovorans produces a cellulase enzyme complex (cellulosome). In this study, we isolated two plant cell wall-degrading cellulosomal fractions from culture supernatant of C. cellulovorans and determined their subunit compositions and enzymatic activities. One of the cellulosomal fractions showed fourfold-higher plant cell wall-degrading activity than the other. Both cellulosomal fractions contained the same nine subunits (the scaffolding protein CbpA, endoglucanases EngE and EngK, cellobiohydrolase ExgS, xylanase XynA, mannanase ManA, and three unknown proteins), although the relative amounts of the subunits differed. Since only cellobiose was released from plant cell walls by the cellulosomal fractions, cellobiohydrolases were considered to be key enzymes for plant cell wall degradation.     

Interaction between the endoglucanase CelA and the scaffolding protein CipC of the Clostridium cellulolyticum cellulosome.

The 5' end of the cipC gene, coding for the N-terminal part of CipC, the scaffolding protein of Clostridium cellulolyticum ATCC 35319, was cloned and sequenced. It encodes a 586-amino-acid peptide, including several domains: a cellulose-binding domain, a hydrophilic domain, and two hydrophobic domains (cohesin domains). Sequence alignments showed that the N terminus of CipC and CbpA of C. cellulovorans ATCC 35296 have the same organization. The mini-CipC polypeptide, containing a cellulose-binding domain, hydrophilic domain 1, and cohesin domain 1, was overexpressed in Escherichia coli and purified. The interaction between endoglucanase CelA, with (CelA2) and without (CelA3) the characteristic clostridial C-terminal domain called the duplicated-segment or dockerin domain, and the mini-CipC polypeptide was monitored by two different methods: the interaction Western blotting (immunoblotting) method and binding assays with biotin-labeled protein. Among the various forms of CelA (CelA2, CelA3, and an intermediary form containing only part of the duplicated segment), only CelA2 was found to interact with cohesin domain 1 of CipC. The apparent equilibrium dissociation constant of the CelA2-mini-CipC complex was 7 x 10(-9)M, which indicates that there exists a high affinity between these two proteins.     

Dimerization and DNA‐dependent aggregation of the Escherichia coli nucleoid protein and chaperone CbpA

The Escherichia coli curved DNA‐binding protein A (CbpA) is a nucleoid‐associated DNA‐binding factor and chaperone that is expressed at high levels as cells enter stationary phase. Using a combination of genetics, biochemistry, structural modelling and single‐molecule atomic force microscopy we have examined dimerization of, and DNA binding by, CbpA. Our data show that CbpA dimerization is driven by a hydrophobic surface comprising amino acid side chains W287 and L290 located on the same side of an α helix close to the C‐terminus of CbpA. Derivatives of CbpA that are unable to dimerize are also unable to bind DNA. Free in solution, CbpA can exist as either a monomer or dimer. However, when bound to DNA, CbpA forms large aggregates that can protect DNA from degradation by nucleases. These CbpA–DNA aggregates are similar in morphology to protein–DNA complexes formed by the DNA‐binding protein from starved cells (Dps), the only other stationary phase‐specific nucleoid protein. Conversely, protein–DNA complexes formed by Fis, the major growth phase nucleoid protein, have a markedly different appearance.     

Characterization of the cellulose-binding domain of the Clostridium cellulovorans cellulose-binding protein A.

Cellulose-binding protein A (CbpA), a component of the cellulase complex of Clostridium cellulovorans, contains a unique sequence which has been demonstrated to be a cellulose-binding domain (CBD). The DNA coding for this putative CBD was subcloned into pET-8c, an Escherichia coli expression vector. The protein produced under the direction of the recombinant plasmid, pET-CBD, had a high affinity for crystalline cellulose. Affinity-purified CBD protein was used in equilibrium binding experiments to characterize the interaction of the protein with various polysaccharides. It was found that the binding capacity of highly crystalline cellulose samples (e.g., cotton) was greater than that of samples of low crystallinity (e.g., fibrous cellulose). At saturating CBD concentration, about 6.4 mumol of protein was bound by 1 g of cotton. Under the same conditions, fibrous cellulose bound only 0.2 mumol of CBD per g. The measured dissociation constant was in the 1 microM range for all cellulose samples. The results suggest that the CBD binds specifically to crystalline cellulose. Chitin, which has a crystal structure similar to that of cellulose, also was bound by the CBD. The presence of high levels of cellobiose or carboxymethyl cellulose in the assay mixture had no effect on the binding of CBD protein to crystalline cellulose. This result suggests that the CBD recognition site is larger than a simple cellobiose unit or more complex than a repeating cellobiose moiety. This CBD is of particular interest because it is the first CBD from a completely sequenced nonenzymatic protein shown to be an independently functional domain.     

DNA recognition by Escherichia coli CbpA protein requires a conserved arginine–minor-groove interaction

Curved DNA binding protein A (CbpA) is a co-chaperone and nucleoid associated DNA binding protein conserved in most γ-proteobacteria. Best studied in Escherichia coli, CbpA accumulates to >2500 copies per cell during periods of starvation and forms aggregates with DNA. However, the molecular basis for DNA binding is unknown; CbpA lacks motifs found in other bacterial DNA binding proteins. Here, we have used a combination of genetics and biochemistry to elucidate the mechanism of DNA recognition by CbpA. We show that CbpA interacts with the DNA minor groove. This interaction requires a highly conserved arginine side chain. Substitution of this residue, R116, with alanine, specifically disrupts DNA binding by CbpA, and its homologues from other bacteria, whilst not affecting other CbpA activities. The intracellular distribution of CbpA alters dramatically when DNA binding is negated. Hence, we provide a direct link between DNA binding and the behaviour of CbpA in cells.