A new type of cohesin domain that specifically binds the dockerin domain of the Clostridium thermocellum cellulosome-integrating protein CipA.

The cellulosome-integrating protein CipA, which serves as a scaffolding protein for the cellulolytic complex produced by Clostridium thermocellum, comprises a COOH-terminal duplicated segment termed the dockerin domain. This paper reports the cloning and sequencing of a gene, termed sdbA (for scaffoldin dockerin binding), encoding a protein which specifically binds the dockerin domain of CipA. The sequenced fragment comprises an open reading frame of 1,893 nucleotides encoding a 631-amino-acid polypeptide, termed SdbA, with a calculated molecular mass of 68,577 kDa. SAA comprises an NH2-terminal leader peptide followed by three distinct regions. The NH2-terminal region is similar to the NH2-terminal repeats of C. thermocellum OlpB and ORF2p. The central region is rich in lysine and harbors a motif present in Streptococcus M proteins. The COOH-terminal region consists of a triplicated sequence present in several bacterial cell surface proteins. The NH2-terminal region of SdbA and a fusion protein carrying the first NH2-terminal repeat of OlpB were shown to bind the dockerin domain of CipA. Thus, a new type of cohesin domain, which is present in one, two, and four copies in SdbA, ORF2p, and OlpB, respectively, can be defined. Since OlpB and most likely SdbA and ORF2p are located in the cell envelope, the three proteins probably participate in anchoring CipA (and the cellulosome) to the cell surface.     

Recognition specificity of the duplicated segments present in Clostridium thermocellum endoglucanase CelD and in the cellulosome-integrating protein CipA.

The binding specificity of the duplicated segments borne by Clostridium thermocellum endoglucanase CelD and by the cellulosome-integrating protein CipA was investigated. The fusion protein CelC-DSCelD, in which the duplicated segment of CelD was fused to the COOH terminus of endoglucanase CelC, bound with an affinity of 4.7 x 10(7) M-1 to the fusion protein MalE-RDCipA, in which the seventh receptor domain of CipA was grafted onto the COOH terminus of the Escherichia coli maltose-binding protein MalE. The affinity of CelC-DSCelD for the homologous chimeric protein MalE-RDORF3p, carrying the receptor of the surface protein ORF3p, was 6.9 x 10(6) M-1. The fusion protein CelC-DSCipA, in which the duplicated segment of CipA was grafted onto the COOH terminus of CelC, did not bind detectably to MalE-RDCipA or MalE-RDORF3p. However, Western blotting (immunoblotting) experiments indicated that the duplicated segment of CipA was able to bind to a set of C. thermocellum proteins which are different from those recognized by the duplicated segment of CelD. These results argue against the hypothesis that ORF3p interacts with the duplicated segment of CipA. More probably, ORF3p binds to individual cellulases and hemicellulases harboring duplicated segments.     

Characterization and subcellular localization of the Clostridium thermocellum scaffoldin dockerin binding protein SdbA.

This article reports the characterization of the Clostridium thermocellum SdbA protein thought to anchor the cellulosome to the bacterial cell surface. The NH2-terminal region of SdbA consists of a cohesin domain which specifically binds the dockerin domain of the cellulosomal scaffolding protein CipA. The COOH-terminal region consists of a triplicated segment, termed SLH repeats, which is present in the sequence of many bacterial cell surface polypeptides. The binding parameters of the interaction between the dockerin domain of CipA and the cohesin domain of SdbA were studied by using, as a probe, the chimeric polypeptide CelC-DSCipA, which carries the dockerin domain of CipA fused to endoglucanase CelC. In the presence of Ca2+, CelC-DSCipA bound to SdbA with an affinity constant of 1.26 x 10(7) M(-1). Binding of CelC-DSCipA to SdbA as a function of Ca2+ concentration was sigmoidal, corresponding to a Hill coefficient of 2 and an affinity constant for Ca2+ of 4 x 10(6) M(-2). This suggested the presence of two cooperatively bound Ca2+ ions in the cohesin-dockerin complex. Immunoblotting of C. thermocellum subcellular fractions and electron microscopy of immunocytochemically labeled cells indicated that SdbA is located on the cell surface and is a component of the cellulosome. Together, the data confirm that SdbA could mediate anchoring of the cellulosome to the surface of C. thermocellum cells by interacting with the dockerin domain of CipA.     

Duplicated dockerin subdomains of Clostridium thermocellum endoglucanase CelD bind to a cohesin domain of the scaffolding protein CipA with distinct thermodynamic parameters and a negative cooperativity

Mutagenized dockerin domains of endoglucanase CelD (type I) and of the cellulosome-integrating protein CipA (type II) were constructed by swapping residues 10 and 11 of the first or the second duplicated segment between the two polypeptides. These residues have been proposed to determine the specificity of cohesin-dockerin interactions. The dockerin domain of CelD still bound to the seventh cohesin domain of CipA (CohCip7), provided that mutagenesis occurred in one segment only. Binding was no longer detected by nondenaturing gel electrophoresis when both segments were mutagenized. The dockerin domain of CipA bound to the cohesin domain of SdbA as long as the second segment was intact. None of the mutated dockerins displayed detectable binding to the noncognate cohesin domain. Isothermal titration calorimetry showed that binding of the CelD dockerin to CohCip7 occurred with a high affinity [K(a) = (2.6 +/- 0.5) x 10(9) M(-1)] and a 1:1 stoichiometry. The reaction was weakly exothermic (DeltaHdegrees = -2.22 +/- 0.2 kcal x mol(-1)) and largely entropy driven (TDeltaSdegrees = 10.70 +/- 0.5 kcal x mol(-1)). The heat capacity change on complexation was negative (DeltaC(p) = -305 +/- 15 cal x mol(-1) x K(-1)). These values show that cohesin-dockerin binding is mainly hydrophobic. Mutations in the first or the second dockerin segment reduced or enhanced, respectively, the hydrophobic character of the interaction. Due to partial enthalpy-entropy compensation, these mutations induced only small changes in binding affinity. However, the binding affinity was strongly decreased when both segments were mutated, indicating strong negative cooperativity between the two mutated sites.     

Involvement of Both Dockerin Subdomains in Assembly of the Clostridium thermocellum Cellulosome

Clostridium thermocellum produces an extracellular cellulase complex termed the cellulosome. It consists of a scaffolding protein, CipA, containing nine cohesin domains and a cellulose-binding domain, and at least 14 different enzymatic subunits, each containing a conserved duplicated sequence, or dockerin domain. The cohesin-dockerin interaction is responsible for the assembly of the catalytic subunits into the cellulosome structure. Each duplicated sequence of the dockerin domain contains a region bearing homology to the EF-hand calcium-binding motif. Two subdomains, each containing a putative calcium-binding motif, were constructed from the dockerin domain of CelS, a major cellulosomal catalytic subunit. These subdomains, called DS1 and DS2, were cloned by PCR and expressed in Escherichia coli. The binding of DS1 and DS2 to R3, the third cohesin domain of CipA, was analyzed by nondenaturing gel electrophoresis. A stable complex was formed only when R3 was combined with both DS1 and DS2, indicating that the two halves of the dockerin domain interact with each other and such interaction is required for effective binding of the dockerin domain to the cohesin domain.     

Subcellular localization of Clostridium thermocellum ORF3p, a protein carrying a receptor for the docking sequence borne by the catalytic components of the cellulosome.

The ORF3 gene of Clostridium thermocellum encodes a polypeptide (ORF3p) which contains a receptor domain for the docking sequence borne by the catalytic subunits of the cellulosome and a triplicated domain related to some bacterial cell surface proteins. It was thus surmised that ORF3p is a surface protein. In this study, this hypothesis was confirmed. Subcellular fractionation, Western blotting (immunoblotting), and electron microscopy of immunocytochemically labeled cells indicated that ORF3p produced by C. thermocellum was located in the outer surface layer of the bacterium. This layer appeared to consist of a soft matrix shedding off particulate fragments. Nonsedimenting ORF3p derived from sonicated cells was associated with high-molecular-mass fractions (> 20 MDa), probably corresponding to fragments of the outer cell layer. The same high-molecular-mass fractions also contained the cellulosomal marker CipA. Contrary to CipA, however, ORF3p was not associated with 2- to 4-MDa fractions corresponding to individual cellulosomes, and a significant fraction of ORF3p failed to bind to cellulose. It is proposed that ORF3 and ORF3p be renamed olpA and OlpA, respectively (for outer layer protein).     

Interactions of the CelS binding ligand with various receptor domains of the Clostridium thermocellum cellulosomal scaffolding protein, CipA.

The Clostridium thermocellum cellulosomal scaffolding protein, CipA, acts as an anchor on the cellulose surface for the various catalytic subunits of the cellulosome, a large extracellular cellulase complex. CipA contains nine repeated domains that serve as receptors for the cellulosomal catalytic subunits, each of which carries a conserved, duplicated ligand sequence (DS). Four representative CipA receptor domains with sequence dissimilarity were cloned and expressed in Escherichia coli. The interaction of these cloned receptor domains with the duplicated ligand sequence of CelS (expressed as a thioredoxin fusion protein, TRX-DSCelS), was studied by nondenaturing polyacrylamide gel electrophoresis. TRX-DSCelS formed a stable complex with each of the four receptor domains, indicating that CelS, the most abundant cellulosomal catalytic subunit, binds nonselectively to all of the CipA receptors. Conversely, the duplicated sequence of CipA (in the form of TRX-DSCipA), which is homologous to that of CelS, did not bind to any of the receptors under the experimental conditions.     

Cloning of a Clostridium thermocellum DNA fragment encoding polypeptides that bind the catalytic components of the cellulosome

A test based on the binding of 125I-labelled endoglucanase CelD was used to clone a DNA region encoding at least two different polypeptides that interact with the conserved reiterated segment present in many catalytic components of the Clostridium thermocellum cellulosome. One of the polypeptides corresponds to the COOH-terminal region of the SL (or S1) component of the cellulosome (U.T. Gerngross and A.L. Demain, personal communication). It comprises repeated domains that are responsible for binding 125I-labelled CelD, and presumably represent anchoring sites for the various catalytic components of the cellulosome. The other polypeptide is encoded by a gene that has not yet been described.     

Cloning and sequence analysis of a new cellulase gene encoding CelK, a major cellulosome component of Clostridium thermocellum: evidence for gene duplication and recombination.

The cellulolytic and hemicellulolytic complex of Clostridium thermocellum, termed cellulosome, consists of up to 26 polypeptides, of which at least 17 have been sequenced. They include 12 cellulases, 3 xylanases, 1 lichenase, and CipA, a scaffolding polypeptide. We report here a new cellulase gene, celK, coding for CelK, a 98-kDa major component of the cellulosome. The gene has an open reading frame (ORF) of 2,685 nucleotides coding for a polypeptide of 895 amino acid residues with a calculated mass of 100,552 Da. A signal peptide of 27 amino acid residues is cut off during secretion, resulting in a mature enzyme of 97,572 Da. The nucleotide sequence is highly similar to that of cbhA (V. V. Zverlov et al., J. Bacteriol. 180:3091-3099, 1998), having an ORF of 3,690 bp coding for the 1,230-amino-acid-residue CbhA of the same bacterium. Homologous regions of the two genes are 86.5 and 84.3% identical without deletion or insertion on the nucleotide and amino acid levels, respectively. Both have domain structures consisting of a signal peptide, a family IV cellulose binding domain (CBD), a family 9 glycosyl hydrolase domain, and a dockerin domain. A striking distinction between the two polypeptides is that there is a 330-amino-acid insertion in CbhA between the catalytic domain and the dockerin domain containing a fibronectin type 3-like domain and family III CBD. This insertion, missing in CelK, is responsible for the size difference between CelK and CbhA. Upstream and downstream flanking sequences of the two genes show no homology. The data indicate that celK and cbhA in the genome of C. thermocellum have evolved through gene duplication and recombination of domain coding sequences. celK without a dockerin domain was expressed in Escherichia coli and purified. The enzyme had pH and temperature optima at 6.0 and 65 degrees C, respectively. It hydrolyzed p-nitrophenyl-beta-D-cellobioside with a Km and a Vmax of 1.67 microM and 15.1 U/mg, respectively. Cellobiose was a strong inhibitor of CelK activity, with a Ki of 0.29 mM. The enzyme was thermostable, after 200 h of incubation at 60 degrees C, 97% of the original activity remained. Properties of the enzyme indicated that it is a cellobiohydrolase.     

Cohesin-dockerin interactions within and between Clostridium josui and Clostridium thermocellum: binding selectivity between cognate dockerin and cohesin domains and species specificity

The cellulosome components are assembled into the cellulosome complex by the interaction between one of the repeated cohesin domains of a scaffolding protein and the dockerin domain of an enzyme component. We prepared five recombinant cohesin polypeptides of the Clostridium thermocellum scaffolding protein CipA, two dockerin polypeptides of C. thermocellum Xyn11A and Xyn10C, four cohesin polypeptides of Clostridium josui CipA, and two dockerin polypeptides of C. josui Aga27A and Cel8A, and qualitatively and quantitatively examined the cohesin-dockerin interactions within C. thermocellum and C. josui, respectively, and the species specificity of the cohesin-dockerin interactions between these two bacteria. Surface plasmon resonance (SPR) analysis indicated that there was a certain selectivity, with a maximal 34-fold difference in the K(D) values, in the cohesin-dockerin interactions within a combination of C. josui, although this was not detected by qualitative analysis. Affinity blotting analysis suggested that there was at least one exception to the species specificity in the cohesin-dockerin interactions, although species specificity was generally conserved among the cohesin and dockerin polypeptides from C. thermocellum and C. josui, i.e. the dockerin polypeptides of C. thermocellum Xyn11A exceptionally bound to the cohesin polypeptides from C. josui CipA. SPR analysis confirmed this exceptional binding. We discuss the relationship between the species specificity of the cohesin-dockerin binding and the conserved amino acid residues in the dockerin domains.     

The Synthesis and Biology of Fluorinated Prostacyclins

Abstract

Clostridium thermocellum produces a highly active cellulase system that consists of a high-M_r multienzyme complex termed cellulosome. Hydrolytic components of the cellulosome are organized around a large, noncatalytic glycoprotein termed CipA that acts both as a scaffolding component and a cellulose-binding factor. Catalytic subunits of the cellulosome bear conserved, noncatalytic subdomains, termed dockerin domains, which bind to receptor domains of CipA, termed cohesin domains. CipA includes nine cohesin domains, a cellulose-binding domain, and a specialized dockerin domain. Proteins of the cell envelope carrying cohesin domains that specifically bind the dockerin domain of CipA have been identified. These proteins may mediate anchoring of the cellulosomes to the cell surface. Cellulase complexes similar to the cellulosome of C. thermocellum are produced by several cellulolytic clostridia. High-Mr multienzyme complexes have also been identified in anaerobic rumen fungi. The architecture of the fungal complexes also seems to rely on the interaction of conserved, noncatalytic docking domains with a scaffolding component. However, the sequence of the fungal docking domains bears no resemblance to the clostridial dockerin domains, suggesting that the fungal and clostridial complexes arose independently.     

Evolutionary similarity among peptide segments is a basis for prediction of protein folding

Short segments of polypeptide, from a protein for which the primary sequence but not the three-dimensional structure is known, are compared to a library of known structures. The basis of comparison is the probability with which residues in the unknown segment might substitute through evolution for residues in segments of known structure. In test cases, segments from known structures that are similar in sequence to those from a protein treated as unknown are often found to be similar in three-dimensional structure to one another and to the true structure of the “unknown” segment. This provides a basis for prediction of the local configuration (secondary structure) of polypeptides.     

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.     

Definition of a Sequence Unique in βII Spectrin Required for Its Axon-Specific Interaction with Fodaxin (A60)

Abstract: Spectrin isotypes segregate in neurons and are differentially distributed between axons and somatodendritic compartments. Their functions in those compartments are likely to be mediated by proteins that interact selectively with one or other isotype. Fodaxin (an axon-specific protein previously termed A60) colocalizes in CNS neurons with axonal spectrin and in vitro binds brain spectrin (a mixture of αI, βI, αII, and βII polypeptides) but not erythrocyte spectrin (αI and βI). Because αII and βII spectrin polypeptides are enriched in axons, we investigated a possible binding of fodaxin to the types of spectrin found in axons. Fodaxin did not bind to isolated brain α chains. Bacterially expressed C-terminal segments 18–19 of βII spectrin bound to fodaxin and inhibited the binding of fodaxin to whole brain spectrin. By contrast, recombinant segments 18–19 of the somatodendritic βIΣ2 spectrin showed no interaction with fodaxin. Within βII, fodaxin binding activity was localized to residues 2,087–2,198, which are unique to βII and link between the end of segment 18 and the pleckstrin homology domain in segment 19. The divergent regions of sequence in segments 19 of βII and βIΣ2 are candidates to mediate the isotype-specific functions of spectrin. Fodaxin is the first protein to be described that discriminates between the unique regions of β spectrin isoforms.     

Escherichia coli expression and purification of four antimicrobial peptides fused to a family 3 carbohydrate-binding module (CBM) from Clostridium thermocellum

Antimicrobial peptides (AMPs) are molecules that act in a wide range of physiological defensive mechanisms developed to counteract bacteria, fungi, parasites and viruses. Several hundreds of AMPs have been identified and characterized. These molecules are presently gaining increasing importance, as a consequence of their remarkable resistance to microorganism adaptation. Carbohydrate-binding modules (CBMs) are non-catalytic domains that anchor glycoside hydrolases into complex carbohydrates. Clostridium thermocellum produces a multi-enzyme complex of cellulases and hemicellulases, termed the cellulosome, which is organized by the scaffoldin protein CipA. Binding of the cellulosome to the plant cell wall results from the action of CipA family 3 CBM (CBM3), which presents a high affinity for crystalline cellulose. Here CipA family 3 CBM was fused to four different AMPs using recombinant DNA technology and the fusion recombinant proteins were expressed at high levels in Escherichia coli cells. CBM3 does not present antibacterial activity and does not bind to the bacterial surface. However, the four recombinant proteins retained the ability to bind cellulose, suggesting that CBM3 is a good candidate polypeptide to direct the binding of AMPs into cellulosic supports. A comprehensive characterization of the antimicrobial activity of the recombinant fusion proteins is currently under evaluation.     

Identification of polypeptides encoded in open reading frame 1b of the putative polymerase gene of the murine coronavirus mouse hepatitis virus A59.

The polypeptides encoded in open reading frame (ORF) 1b of the mouse hepatitis virus A59 putative polymerase gene of RNA 1 were identified in the products of in vitro translation of genome RNA. Two antisera directed against fusion proteins containing sequences encoded in portions of the 3'-terminal 2.0 kb of ORF 1b were used to immunoprecipitate p90, p74, p53, p44, and p32 polypeptides. These polypeptides were clearly different in electrophoretic mobility, antiserum reactivity, and partial protease digestion pattern from viral structural proteins and from polypeptides encoded in the 5' end of ORF 1a, previously identified by in vitro translation. The largest of these polypeptides had partial protease digestion patterns similar to those of polypeptides generated by in vitro translation of a synthetic mRNA derived from the 3' end of ORF 1b. The polypeptides encoded in ORF 1b accumulated more slowly during in vitro translation than polypeptides encoded in ORF 1a. This is consistent with the hypothesis that translation of gene A initiates at the 5' end of ORF 1a and that translation of ORF 1b occurs following a frameshift at the ORF 1a-ORF 1b junction. The use of in vitro translation of genome RNA and immunoprecipitation with antisera directed against various regions of the polypeptides encoded in gene A should make it possible to study synthesis and processing of the putative coronavirus polymerase.     

Sequence analysis of the Clostridium cellulolyticum endoglucanase-A-encoding gene, celCCA

The nucleotide sequence of a Clostridium cellulolyticum endo-beta-1,4- glucanase (EGCCA)-encoding gene (celCCA) and its flanking regions, was determined. An open reading frame (ORF) of 1425 bp was found, encoding a protein of 475 amino acids (aa). This ORF began with an ATG start codon and ended with a TAA ochre stop codon. The N-terminal region of the EGCCA protein resembled a typical signal sequence of a Gram-positive bacterial extracellular protein. A putative signal peptidase cleavage site was determined. EGCCA, without a signal peptide, was found to be composed of more than 35% hydrophobic aa and to have an Mr of 50715. Comparison of the encoded sequence with other known cellulase sequences showed the existence of various kinds of aa sequence homologies. First, a strong homology was found between the C-terminal region of EGCCA, containing a reiterated stretch of 24 aa, and the conserved reiterated region previously found to exist in four Clostridium thermocellum endoglucanases and one xylanase from the same organism. This region was suspected of playing a role in organizing the cellulosome complex. Second, an extensive homology was found between EGCCA and the N-terminal region of the large endoglucanase, EGE, from C. thermocellum, which suggests that they may have a common ancestral gene. Third, a region, which extended for 21 aa residues beginning at aa + 127, was found to be homologous with regions of cellulases belonging to Bacilli, Clostridia and Erwinia chrysanthemi.     

Stoichiometric Assembly of the Cellulosome Generates Maximum Synergy for the Degradation of Crystalline Cellulose,as Revealed by In Vitro Reconstitution of the Clostridium thermocellum Cellulosome

The cellulosome is a supramolecular multienzyme complex formed by species-specific interactions between the cohesin modules of scaffoldin proteins and the dockerin modules of a wide variety of polysaccharide-degrading enzymes. Cellulosomal enzymes bound to the scaffoldin protein act synergistically to degrade crystalline cellulose. However, there have been few attempts to reconstitute intact cellulosomes due to the difficulty of heterologously expressing full-length scaffoldin proteins. We describe the synthesis of a full-length scaffoldin protein containing nine cohesin modules, CipA; its deletion derivative containing two cohesin modules, ΔCipA; and three major cellulosomal cellulases, Cel48S, Cel8A, and Cel9K, of the Clostridium thermocellum cellulosome. The proteins were synthesized using a wheat germ cell-free protein synthesis system, and the purified proteins were used to reconstitute cellulosomes. Analysis of the cellulosome assembly using size exclusion chromatography suggested that the dockerin module of the enzymes stoichiometrically bound to the cohesin modules of the scaffoldin protein. The activity profile of the reconstituted cellulosomes indicated that cellulosomes assembled at a CipA/enzyme molar ratio of 1/9 (cohesin/dockerin = 1/1) and showed maximum synergy (4-fold synergy) for the degradation of crystalline substrate and ∼2.4-fold-higher synergy for its degradation than minicellulosomes assembled at a ΔCipA/enzyme molar ratio of 1/2 (cohesin/dockerin = 1/1). These results suggest that the binding of more enzyme molecules on a single scaffoldin protein results in higher synergy for the degradation of crystalline cellulose and that the stoichiometric assembly of the cellulosome, without excess or insufficient enzyme, is crucial for generating maximum synergy for the degradation of crystalline cellulose.