Penicillin-binding proteins of clostridia

The penicillin-binding protein (PBP) profiles of 33Clostridium perfringens and sixClostridium species isolated from clinically significant infections were analyzed. Three new PBPs—PBPs 2B, 4B, and 5B (84, 70, and 49 kDa respectively)—and a high-molecular-weight PBP 6 (45 kDa) were demonstrated in theC. perfringens isolates. In addition to PBPs 1 and 2, PBPs 2B and 4B were seen to show low binding affinities for penicillin, although further studies are required to determine their possible roles in the development of penicillin resistance. The PBP profiles of theC. perfringens isolates were complex. Variations in apparent molecular weights (M _r s) of all PBPs, with the exception of PBP 5 and the presence or absence of PBPs 2, 3, and 4B, gave rise to nine different PBP patterns. The high-M _rPBPs 5 and 6, which exhibited high-penicillin-binding affinities, were with only one exception consistent within theC. perfringens isolates. These PBPs 5 and 6 of theC. perfringens isolates and independent PBPs found in the otherClostridium species studied indicate that PBP analysis may assist in the differentiation ofClostridium spacies.     

Stress proteins of<Emphasis Type="Italic"> Clostridium perfringens</Emphasis> type A immunoreact with antiserum from rabbits infected with gas gangrene

Various stressors were used to induce stress proteins in Clostridium perfringens. Cultures of C. perfringens FD-1041 were subjected to cold shock (28°C for 1 h), acid shock (pH 4.5 for 30 min), or heat shock (50°C for 30 min). Cells were lysed and protein samples were analyzed by immunoblotting with antiserum derived from rabbits suffering from gas gangrene. Eight cold shock proteins (approximate M_r 101, 82, 70, 37, 22, 12, 10 and 6 kDa) and also eight heat shock proteins (approximate M_r 101, 82, 70, 27, 22, 16, 12 and 10 kDa) were immunoreactive with the serum. No immunoreactive proteins were detected in samples subjected to acid shock proteins and purified DnaK protein was also non-immunoreactive with the serum. These immunogenic stress proteins may be important in regulating diseases caused by C. perfringens. Such proteins could be involved in cell survival mechanisms, serve as targets during infection, or play a role in recognition of the bacteria by the host.     

Construction of a sequencedClostridium perfringens-Escherichia coli shuttle plasmid

A newClostridium perfringens-Escherichia coli shuttle plasmid has been constructed and its complete DNA sequence compiled. The vector, pJIR418, contains the replication regions from theC. perfringens replicon pIP404 and theE. coli vector pUC18. The multiple cloning site and lacZ gene from pUC18 are also present, which means that X-gal screening can be used to select recombinants inE. coli. Both chloramphenicol and erythromycin resistance can be selected inC. perfringens andE. coli since pJIR418 carries theC. perfringens catP and ermBP genes. Insertional inactivation of either the catP or ermBP genes can also be used to directly screen recombinants in both organisms. The versatility of pJIR418 and its applicability for the cloning of toxin genes fromC. perfringens have been demonstrated by the manipulation of a cloned gene encoding the production of phospholipase C.     

The Clostridium perfringens Tet P determinant comprises two overlapping genes: tetA(P), which mediates active tetracycline efflux, and tetB(P), which is related to the ribosomal protection family of tetracycline-resistance determinants

The complete nucleotide sequence and mechanism of action of the tetracycline-resistance determinant Tet P, from Clostridium perfringens has been determined. Analysis of the 4.4 kb of sequence data revealed the presence of two open reading frames, designated as tetA(P) and tetB(P), The tetA(P) gene appears to encode a 420 amino acid protein (molecular weight 46079) with twelve transmembrane domains. This gene was shown to be responsible for the active efflux of tetracycline from resistant ceils. Although there was some amino acid sequence similarity between the putative TetA(P) protein and other tetracycline efflux proteins, analysis suggested that TetA(P) represented a different type of efflux protein. The tetB(P) gene would encode a putative 652 amino acid protein (molecular weight 72639) with significant sequence similarity to Tet(M)-like cytoplasmic proteins that specify a ribosomal-protection tetracycline-resistance mechanism. In both C. perfringens and Escherichia coli. tetB(P) encoded low-level resistance to tetracycline and minocycline whereas tetA(P) only conferred tetracycline resistance. The tetA(P) and tetB(P) genes appeared to be linked in an operon, which represented a novel genetic arrangement for tetracycline-resistance determinants. It is proposed that tetB(P) evolved from the conjugative transfer into C. perfringens of a fer (M)-like gene from another bacterium.     

Kinetics of spore coat protein synthesis byClostridium perfringens type A

Spore coat proteins of several strains ofClostridium perfringens were analyzed by immunoblotting with antisera against two major spore coat proteins, one [34-kilodalton (kDa)] from an enterotoxin-positive and one (19-kDa) from an enterotoxin-negative (ent^–) strain of this organism. The results indicated that spore coat proteins from many strains ofC. perfringens were immunologically related regardless of their ability to produce enterotoxin, but were not immunologically related to enterotoxin. The kinetics of synthesis and deposition of two major spore coat proteins differed depending upon the strain. Coat protein synthesis was sporulationspecific, since coat protein was not detected in vegetative cell extracts. There was no similarity between the amino acid composition of either coat protein and enterotoxin. These results suggest that, contrary to previous reports (W.R. Frieben and C.L. Duncan, Eur J Biochem 39:393–410, 1973), enterotoxin synthesis is not closely related to spore coat protein synthesis in this organism.     

Localization of the azoreductase ofClostridium perfringens by immuno-electron microscopy

An antibody againstClostridium perfringens azoreductase was used with protein A (gold-labeled) to locate the site of synthesis of extracellular azoreductase in this bacterium. Electron microscopy of immunogold-stained thin sections ofC. perfringens cells showed an average of 134 gold particles per cell, distributed throughout the cytoplasm and not associated with any organized structures.     

A Clostridium perfringens Vector for the Selection of Promoters

A promoter selection vector for Clostridium perfringens genes was constructed from a C. perfringens-Escherichia coli shuttle vector, pJIR418. The plasmid carries a promoterless chloramphenicol acetyltransferase gene (catP), derived from pIP401, downstream of the multiple cloning sites of pUC18. When a promoter region of the phospholipase C gene was inserted into one of the cloning sites, derivatives of C. perfringens strain 13 carrying the resultant plasmid acquired resistance to chloramphenicol. This plasmid should be a useful reporter system for C. perfringens genes.     

Identification and characterization of a putative endolysin encoded by episomal phage phiSM101 of <Emphasis Type="Italic">Clostridium perfringens</Emphasis>

Clostridium perfringens produces potent toxins and histolytic enzymes, causing various diseases including life-threatening fulminant diseases in humans and other animals. Aiming at utilizing a phage endolysin as a therapeutic alternative to antibiotics, we surveyed the genome and bacteriophage sequences of C. perfringens. A phiSM101 muramidase gene (psm) revealed by this study can be assumed to encode an N-acetylmuramidase, since the N-terminal catalytic domain deduced from the gene shows high homology of those of N-acetylmuramidases. The psm gene is characteristic in that it is present in phiSM101, an episomal phage of enterotoxigenic C. perfringens type A strain, SM101, and also in that homologous genes are present in the genomes of all five C. perfringens toxin types. The psm gene was cloned and expressed in Escherichia coli as a protein histidine-tagged at the N-terminus (Psm-his). Psm-his was purified to homogeneity by nickel-charged immobilized metal affinity chromatography and anion-exchange chromatography. The purified enzyme lysed cells of all C. perfringens toxin types but not other clostridial species tested, as was shown by a turbidity reduction assay. These results indicate the Psm-his is useful as a cell-wall lytic enzyme and also suggest that it is potentially useful for biocontrol of this organism.     

Conserved structure of genes encoding components of botulinum neurotoxin complex M and the sequence of the gene coding for the nontoxic component in nonproteolyticClostridium botulinum type F

For investigation of the genes of proteins associated in vivo with botulinum neurotoxin (BoNT), polymerase chain reaction (PCR) experiments were carried out with oligonucleotide primers designed to regions of the nontoxic-nonhemagglutinin (NTNH) gene ofClostridium botulinum type C. The primers were used to amplify a DNA fragment from genomic DNA ofC. botulinum types A, B, E, F, G and toxigenic strains ofClostridium barati andClostridium butyricum. The amplified product from all of these strains hybridized with an internal oligonucleotide probe, whereas all nontoxigenic clostridia tested gave no PCR product and showed no reaction with the probe. TheNTNH gene was shown to be located upstream of the gene encoding BoNT, thereby revealing a conserved structure for genes encoding the proteins of the M complex of the progenitor botulinum toxin in these organisms. The sequence of theNTNH gene of nonproteolyticC. botulinum type F was determined by PCR amplification and sequencing of overlapping cloned fragments. NTNH/F showed 71% and 61% identity with NTNH ofC. botulinum type E and type C respectively.     

Methyl directed DNA mismatch repair inVibrio cholerae

Mismatches in DNA occur either due to replication error or during recombination between homologous but non-identical DNA sequences or due to chemical modification of bases. The mismatch in DNA, if not repaired, result in high spontaneous mutation frequency. The repair has to be in the newly synthesized strand of the DNA molecule, otherwise the error will be fixed permanently. Three distinct mechanisms have been proposed for the repair of mismatches in DNA in prokaryotic cells and gene functions involved in these repair processes have been identified. The methyl-directed DNA mismatch repair has been examined inVibrio cholerae, a highly pathogenic gram negative bacterium and the causative agent of the diarrhoeal disease cholera. The DNA adenine methyltransferase encoding gene (dam) of this organism which is involved in strand discrimination during the repair process has been cloned and the complete nucleotide sequence has been determined.Vibrio cholerae dam gene codes for a 21.5 kDa protein and can substitute for theEscherichia coli enzyme. Overproduction ofVibrio cholerae Dam protein is neither hypermutable nor lethal both in Escherichia coli andVibrio cholerae. WhileEscherichia coli dam mutants are sensitive to 2-aminopurine,Vibrio cholerae 2-aminopurine sensitive mutants have been isolated with intact GATC methylation activity. The mutator genesmutS andmutL involved in the recognition of mismatch have been cloned, nucleotide sequence determined and their products characterized. Mutants ofmutS andmutL ofVibrio cholerae have been isolated and show high rate of spontaneous mutation frequency. ThemutU gene ofVibrio cholerae, the product of which is a DNA helicase II, codes for a 70 kDa protein. The deduced amino acid sequence of themutU gene hs all the consensus helicase motifs. The DNA cytosine methyltransferase encoding gene (dam) ofVibrio cholerae has also been cloned. Thedcm gene codes for a 53 kDa protein. This gene product might be involved in very short patch (VSP) repair of DNA mismatches. The vsr gene which is directly involved in VSP repair process codes for a 23 kDa protein. Using these information, the status of DNA mismatch repair inVibrio cholerae will be discussed.     

Utility of the Clostridial Site-Specific Recombinase TnpX To Clone Toxic-Product-Encoding Genes and Selectively Remove Genomic DNA Fragments

TnpX is a site-specific recombinase responsible for the excision and insertion of the transposons Tn4451 and Tn4453 in Clostridium perfringens and Clostridium difficile, respectively. Here, we exploit phenotypic features of TnpX to facilitate genetic mutagenesis and complementation studies. Genetic manipulation of bacteria often relies on the use of antibiotic resistance genes; however, a limited number are available for use in the clostridia. The ability of TnpX to recognize and excise specific DNA fragments was exploited here as the basis of an antibiotic resistance marker recycling system, specifically to remove antibiotic resistance genes from plasmids in Escherichia coli and from marked chromosomal C. perfringens mutants. This methodology enabled the construction of a C. perfringens plc virR double mutant by allowing the removal and subsequent reuse of the same resistance gene to construct a second mutation. Genetic complementation can be challenging when the gene of interest encodes a product toxic to E. coli. We show that TnpX represses expression from its own promoter, P_attCI, which can be exploited to facilitate the cloning of recalcitrant genes in E. coli for subsequent expression in the heterologous host C. perfringens. Importantly, this technology expands the repertoire of tools available for the genetic manipulation of the clostridia.     

Characterization of enolase fromClostridium difficile

We have isolated and purified enolase fromClostridium difficile. This is the first report of an enolase of theClostridium genus, and in general its characteristics resemble those described previously for other species, except that it is extremely thermostable. Interestingly,C. difficile enolase has an octameric structure (approximately 300 kDa on native PAGE, 50 kDa on SDS PAGE, and 338 kDa by gel filtration). Enolases fromC. sordellii andC. bifermentans have been partially purified and have a molecular weight similar to that ofC. difficile. It may be that this large size is common for enolases isolated from bacteria of theClostridium genus.     

Generation and characterization of an inter-generic bivalent alpha domain fusion protein αCS from Clostridium perfringens and Staphylococcus aureus for concurrent diagnosis and therapeutic applications

Aim: To evaluate an inter‐generic recombinant alpha domain fusion protein for simultaneous detection and neutralization of Clostridium perfringens and Staphylococcus aureus alpha toxins. Methods and Results: Truncated portions of clostridial and staphylococcal alpha haemolysin genes were PCR amplified and linked to each other through a hydrophilic flexible Glycine linker sequence using overlap‐extension PCR to form a chimeric gene αCS. The recombinant αCS fusion protein was expressed and characterized for its toxicity, cell binding capacity and haemolysis inhibition properties. The fusion protein was nontoxic and effectively retarded staphylococcal alpha haemolysis, probably by competitively interacting with putative staphylococcal alpha haemolysin receptors on erythrocytes. Murine hyperimmune polysera raised against r‐αCS specifically detected 42‐kDa and 33‐kDa proteins when culture supernatants of Cl. perfringens (clostridial alpha toxin) and Staph. aureus (staphylococcal alpha toxin), respectively, were analysed in Western blot. The polyclonal antisera effectively diminished the haemolytic action of both the wild‐type toxins in vitro. Conclusions: The r‐αCS fusion protein was nontoxic competitive inhibitor of staphylococcal alpha haemolysin. The protein elicited specific immune response against Cl. perfringens and Staph. aureus alpha toxins. The antisera also neutralized the toxicities of both the native wild‐type toxins in vitro. Significance of the Study: The bivalent recombinant αCS protein could be a novel intervention in the field of diagnostics and therapeutics against Cl. perfringens and Staph. aureus infections, particularly, in case of co‐infections like gangrenous ischaemia, gangrenous mastitis, etc.     

Expression ofMbR4, a TIR-NBS type of appleR Gene, confers resistance to bacterial spot disease inArabidopsis

A single disease resistance gene candidate,MbR4, was isolated from the wild-type apple speciesMalus baccta. This gene was predicted to encode motifs characteristic of the Toll Interleukin 1 Receptor (TIR) — Nucleotide Binding Site (NBS) of theR gene. Starting with an isolated cDNA clone, genomic clones were obtained via inverse polymerase chain reaction (IPCR). TheMbR4 gene has a single open reading frame (ORF) of 2178 nucleotides, a 41-b untranslated 5’ region, a 21-b untranslated 3’ region, and a predicted protein of 726 amino acids (82 kDa). Its deduced amino acid sequence resembles the N protein of tobacco and the NL25 protein of potato. Ectopic expression ofMbR4 induced enhanced resistance in transgenicArabidopsis plants against the virulent pathogen,Pseudomonas syringae pv.tomato DC3000. Microarray analysis confirmed the induction of defense-related gene expression in pathogen-free 35S::MbR4 heterologousArabidopsis plants, thereby indicating that theMbR4 gene likely activates a pathogen-independent resistance pathway, rather than a gene-for-gene pathway. Our results suggest thatMbR4 plays a role in theR gene, and may be a source of resistance for cultivated apple species.     

Conjugative Transfer of theEscherichia coli–Clostridium perfringensShuttle Vector pJIR1457 toClostridium botulinumType A Strains

An RP4-oriT shuttle vector pJIR1457 originally developed forClostridium perfringenswas successfully transferred by conjugation fromEscherichia colitoClostridium botulinumtype A strains and to a nontoxigenicC. botulinumtype A–transposon Tn916mutant strain lacking the entire toxin gene cluster. The light chain (LC) of botulinum toxin was highly expressed in the toxin deletion mutant strain from a pJIR1457 construct containing the recombinant botulinal gene for LC. This shuttle vector system will be valuable for genetic analysis ofC. botulinumand will enable genetic manipulation and recombinant expression studies of botulinum neurotoxins as pharmaceutical agents.     

Cloning, sequencing and expression of the acylneuraminate lyase gene from Clostridium perfringens A99

The acylneuraminate lyase gene from Clostridium perfringens A99 was cloned on a 3.3 kb HindIII DNA fragment identified by screening the chromosomal DNA of this species by hybridization with an oligonucleotide probe that had been deduced from the N-terminal amino acid sequence of the purified protein, and another probe directed against a region that is conserved in the acylneuraminate lyase gene of Escherichia coli and in the putative gene of Clostridium tertium. After cloning, three of the recombinant clones expressed lyase activity above the background of the endogenous enzyme of the E. coli host. The sequenced part of the cloned fragment contains the complete acylneuraminate lyase gene (ORF2) of 864 bp that encodes 288 amino acids with a calculated molecular weight of 32.3 kDa. The lyase structural gene follows a non-coding region with an inverted repeat and a ribosome binding site. Upstream from this regulatory region another open reading frame (ORF1) was detected. The 3′-terminus of the lyase structural gene is followed by a further ORF (ORF3). A high homology was found between the amino acid sequences of the sialate lyases from Clostridium perfringens and Haemophilus influenzae (75% identical amino acids) or Trichomonas vaginalis (69% identical amino acids), respectively, whereas the similarity to the gene from E. coli is low (38% identical amino acids). Based on our new sequence data, the ‘large’ sialidase gene and the lyase gene of C. perfringens are not arranged next to each other on the chromosome of this species. This revised version was published online in November 2006 with corrections to the Cover Date.     

Expression of the mosquitocidal-protein genes ofBacillus thuringiensis subsp.israelensis and the herbicide-resistance genebar inSynechocystis PCC6803

CyanobacteriumSynechocystis PCC6803 was used as a model system for a prolonged delivery of insecticidal crystal proteins ofBacillus thuringiensis subsp.israelensis in the water surface. Thebt8 gene, encoding a 128 kDa (Bt8) mosquitocidal protein, and the28kd gene, encoding a 28 kDa cytotoxic protein, were integrated into the cyanobacterial chromosome. The genes were expressed under the control of thepsbA promoter, derived from the tobacco chloroplast genome. The Bt8 protein produced by the cyanobacterium was toxic to mosquito larvae. The28kd gene expression in the cyanobacterium was very low, partly owing to the low level of steady state mRNA. With the same system, it was demonstrated that the herbicide-resistance genebar could be used as a new selectable marker in cyanobacterial transformation experiments.     

Construction of an Alpha Toxin Gene Knockout Mutant of Clostridium perfringens Type A by Use of a Mobile Group II Intron

In developing Clostridium perfringens as a safe vaccine vector, the alpha toxin gene (plc) in the bacterial chromosome must be permanently inactivated. Disrupting genes in C. perfringens by traditional mutagenesis methods is very difficult. Therefore, we developed a new strategy using group II intron-based Target-Tron technology to inactivate the plc gene in C. perfringens ATCC 3624. Western blot analysis showed no production of alpha toxin protein in the culture supernatant of the plc mutant. Advantages of this technology, such as site specificity, relatively high frequency of insertion, and introduction of no antibiotic resistance genes into the chromosome, could facilitate construction of other C. perfringens mutants.     

Genetics of colicin E susceptibility inCitrobacter freundii

The insensitivity ofCitrobacter freundii to the E colicins is based on tolerance to colicin E1 and resistance to colicins E2 and E3. Spontaneous colicin A resistant mutants ofC. freundii also lost their colicin E1 receptor function. Sensitivity to colicin E1 can be induced by F′gal ⁺ tol ⁺ plasmids, thetol A⁺ gene product of which is responsible for this effect. Receptor function for colicins E2 and E3 is induced by theE. coli F′14bfe ⁺ plasmid, which is also able to enhance notably the receptor capacity for colicin E1. Thebfe ⁺ gene product ofE. coli, which is responsible for these phenomena, also restores the receptor function for colicin A and E1 in colicin A resistant mutants ofC. freundii. All results show that there is a remarkable difference between theE. coli bfe ⁺ gene product and thebfe ⁺ gene product ofC. freundii and also between thetol A⁺ gene products of these strains. The sensitivity to phage BF23 parallels the sensitivity to colicins E2 and E3 and is also induced by the F′14bfe ⁺ plasmid.