Pierre Béguin

Detection of cellulase activity in polyacrylamide gels using Congo red-stained agar replicas

Bands that have cellulolytic activity are visualized after polyacrylamide gel electrophoresis by laying the slab gel on top of a thin sheet of 2% agar containing 0.1% carboxymethylcellulose. After a suitable incubation time, zones of carboxymethylcellulose hydrolysis are revealed by staining the agar replica with Congo red.

Interaction of the duplicated segment carried by Clostridium thermocellum cellulases with cellulosome components

The function of the non‐catalytic, duplicated segment found in C. thermocellum cellulases was investigated. Rabbit antibodies reacting with the duplicated segment of endoglucanase CelD cross‐reacted with a variety of cellulosome components ranging between 50 and 100 kDa. 125I‐labeled forms of CelD and of xylanase XynZ carrying the duplicated segment bound to a set of cellulosome proteins ranging between 66 and 250 kDa, particularly to the 250 kDa SL (or S1) subunit. 125I‐labeled forms of CelD and XynZ devoid of the duplicated segment failed to bind to any cellulosome protein. The duplicated segment appears thus to serve to anchor the various cellulosome subunits to the complex by binding to SL, which may be a scaffolding element of the cellulosome.

V. Functions of S‐layers

Although S-layers are being increasingly identified on Bacteria and Archaea, it is enigmatic that in most cases S-layer function continues to elude us. In a few instances, S-layers have been shown to be virulence factors on pathogens (e.g. Campylobacter fetus ssp. fetus and Aeromonas salmonicida), protective against Bdellovibrio, a depository for surface-exposed enzymes (e.g. Bacillus stearothermophilus), shape-determining agents (e.g. Thermoproteus tenax) and nucleation factors for fine-grain mineral development (e.g. Synechococcus GL 24). Yet, for the vast majority of S-layered bacteria, the natural function of these crystalline arrays continues to be evasive. The following review up-dates the functional basis of S-layers and describes such diverse topics as the effect of S-layers on the Gram stain, bacteriophage adsorption in lactobacilli, phagocytosis by human polymorphonuclear leukocytes, the adhesion of a high-molecular-mass amylase, outer membrane porosity, and the secretion of extracellular enzymes of Thermoanaerobacterium. In addition, the functional aspect of calcium on the Caulobacter S-layer is explained.

High activity of inclusion bodies formed in Escherichia coli overproducing Clostridium thermocellum endoglucanase D

The formation of cytoplasmic inclusion bodies by Escherichia coli overproducing Clostridium thermocellum endoglucanase D (EGD) was investigated. EGD was found in inclusion bodies as a 68 kDa form, whereas the size of the cytoplasmic form was 65 kDa. Upon solubilization with urea followed by dialysis, the 68 kDa form was converted to the 65 kDa species. Proteolysis occurred within the COOH‐terminal, reiterated region of the 68 kDa form, which is conserved among most C. thermocellum endoglucanase, but is not required for catalytic activity. The specific activity of the enzyme embedded in inclusion bodies was close to that of the purified protein. Thus, inclusion body formation does not involve denaturation of the catalytic domain of EGD, but more likely, the participation of the reiterated, conserved region in intermolecular interactions.

Identification of a region responsible for binding to the cell wall within the S-layer protein of Clostridium thermocellum.

The protomer forming the S-layer of Clostridium thermocellum was identified as a 140 kDa protein which was non-covalently bound to the cell wall. Cloning and sequencing of the corresponding gene revealed an open reading frame of 3108 nucleotides encoding a polypeptide of 1036 amino acids, termed SlpA. The amino acid composition of SlpA matches the composition of a previously described exocellular glycoprotein. SlpA shared extensive similarity with the S-layer protein of Bacillus sphaericus and with the outer wall protein of Bacillus brevis. In addition, the amino-terminal region of SlpA contained a segment presenting similarities with segments termed SLH (S-layer homologous), which are found in several bacterial exoproteins. A polypeptide of 209 residues comprising this segment was shown to bind to cell walls extracted from C. thermocellum cells.

Cloning of a genetically unstable cytochrome P-450 gene cluster involved in degradation of the pollutant ethyl tert-butyl ether by Rhodococcus ruber.

Rhodococcus ruber (formerly Gordonia terrae) IFP 2001 is one of a few bacterial strains able to degrade ethyl tert-butyl ether (ETBE), which is a major pollutant from gasoline. This strain was found to undergo a spontaneous 14.3-kbp chromosomal deletion, which results in the loss of the ability to degrade ETBE. Sequence analysis of the region corresponding to the deletion revealed the presence of a gene cluster, ethABCD, encoding a ferredoxin reductase, a cytochrome P-450, a ferredoxin, and a 10-kDa protein of unknown function, respectively. The EthB and EthD proteins could be easily detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and were induced by ETBE in the wild-type strain. Upstream of ethABCD lies ethR, which codes for a putative positive transcriptional regulator of the AraC/XylS family. Transformation of the ETBE-negative mutant by a plasmid carrying the ethRABCD genes restored the ability to degrade ETBE. Complementation was abolished if the plasmid carried ethRABC only. The eth genes are located in a DNA fragment flanked by two identical direct repeats of 5.6 kbp. The ETBE-negative mutants carry a single copy of this 5.6-kbp repeat, suggesting that the 14.3-kbp chromosomal deletion resulted from a recombination between the two identical sequences. The 5.6-kbp repeat is a class II transposon carrying a TnpA transposase, a truncated form of the recombinase TnpR, and a terminal inverted repeat of 38 bp. The truncated TnpR is encoded by an IS3-interrupted tnpR gene.

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 25OkDa SI 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.

Purification and properties of the endoglucanase C of Clostridium thermocellum produced in Escherichia coli

The celC gene, which codes for a new endoglucanase of Clostridium thermocellum, termed endoglucanase C, was found to be expressed when cloned in Escherichia coli. The enzyme was purified to electrophoretic homogeneneity from E. coli and its biochemical properties were studied. It differs from the previously studied endoglucanases A and B. In particular, endoglucanase C displays features common to endo- and exoglucanases, since it had a high activity on carboxymethylcellulose and on p-nitrophenyl-beta-D-cellobioside where only the agluconic bond was split. In addition, the enzyme was able to release cellobiose units from G3, G4 and G5 cellodextrins. Endoglucanase C was characterized by Western blot in a culture supernatant from C. thermocellum grown on cellulose, using an antiserum raised against the enzyme produced by E. coli.

Identification of the endoglucanase encoded by the celB gene of Clostridium thermocellum

The endoglucanase encoded by the celB gene of Clostridium thermocellum was purified from an E. coli strain carrying and expressing the C. thermocellum gene cloned in the plasmid pBR322. The preparation showed two active bands, with Mr 55,000 and 53,000, presumably derived from the primary translation product by proteolysis. Specific antiserum raised against these bands was used to identify the corresponding antigen in the culture supernatant of C. thermocellum: in a double immunodiffusion test (Ouchterlony), a precipitin line was observed which fused completely with that formed by an E. coli extract containing endoglucanase B expressed from the cloned gene. Proteins from C. thermocellum supernatant were further analyzed by SDS-polyacrylamide gel electrophoresis and transferred to a nitrocellulose sheet. After incubating the nitrocellulose blot with antiserum and subsequently with 125I-labeled protein A, a band with Mr 66,000, corresponding to the celB gene product expressed by C. thermocellum, was detected by autoradiography.

Nucleotide sequence of the cellulase gene celF of Clostridium thermocellum

The nucleotide sequence of the celF gene of Clostridium thermocellum was determined. The open reading frame extended over 2217 bp. The encoded 739-aa polypeptide, CelF, with a Mw = 82,015, was an endoglucanase with activity against carboxymethylcellulose. The N terminus showed a typical signal peptide, and a cleavage site after Ala-27 was predicted. From residues 28 to 470, the sequence of CelF was related to the catalytic domains of type E2 endoglucanases, with a strong homology to the endoglucanases CelZ of Clostridium stercorarium and CenB of Cellulomonas fimi. The catalytic region was followed by a 134-aa segment also present in C. stercorarium CelZ and in C. fimi CenB, and belonging to the family of non-catalytic, presumably cellulose-binding domains first identified in Bacillus subtilis endoglucanase. A 21-aa segment rich in Pro/Thr/Ser residues separated the putative cellulose-binding region from the COOH-terminal region, which contained two conserved stretches of 24 amino acids closely similar to those previously described in endoglucanases CelA, CelB, CelD, CelE, CelH and CelX, and xylanase XynZ of C. thermocellum.