The ever-expanding tcp conjugation locus of pCW3 from Clostridium perfringens

The spore-forming, anaerobic Gram positive pathogen Clostridium perfringens encodes many of its disease-causing toxins on closely related conjugative plasmids. Studies of the tetracycline resistance plasmid pCW3 have identified many of the genes involved in conjugative transfer, which are located in the tcp conjugation locus. Upstream of this locus is an uncharacterised region (the cnaC region) that is highly conserved. This study examined the importance in pCW3 conjugation of several highly conserved proteins encoded in the cnaC region. Conjugative mating studies suggested that the SrtD, TcpN and Dam proteins were required for efficient pCW3 transfer between C. perfringens cells from the same strain background. The requirement of these proteins for conjugation was amplified in matings between C. perfringens cells of different strain backgrounds. Additionally, the putative collagen adhesin protein, CnaC, was only required for the optimal transfer of pCW3 between cells of different strain backgrounds. Based on these studies we postulate that CnaC, SrtD, TcpN and Dam are involved in enhancing the transfer frequency of pCW3. These studies have led to a significant expansion of the tcp conjugation locus, which now encompasses a 19 kb region.

Phosphorothioation of foreign DNA influences the transformation efficiency in Clostridium perfringens NCTC8239

Major advances in Clostridium perfringens genetics have been achieved through the development of electroporation-induced transformation; however, highly transformable strains are still limited. SM101 is the only useful strain for genetic manipulation via transformation in C. perfringens causing foodborne illness (FBI). We focused on the FBI strain NCTC8239, which is transformed at a low frequency, because it has a gene cassette that is predicted to encode enzymes involved in DNA phosphorothioation (PT). The oxidant-dependent degradation of NCTC8239 genomic DNA suggested that the genome is PT-modified. When foreign DNA was PT-modified using a plasmid expressing Salmonella enterica PT modification enzymes, the transformation efficiency of NCTC8239 was significantly higher than that using an unmodified plasmid. We then attempted to establish a highly transformable derivative of NCTC8239, and focused on DptFGH, which are predicted to be PT restriction enzymes. A dptG-null mutant exhibited significantly higher transformation efficiency with unmodified foreign DNA than did the wild-type strain. Furthermore, the mutant was transformed with the unmodified plasmid as efficiently as with a PT-modified plasmid, implying that DptG is involved in PT-dependent restriction. Thus, the present results revealed that PT modifications of foreign DNA influence the transformation frequency of NCTC8239 and suggest that PT is a factor contributing to transformation efficiency in NCTC8239.

Construction and characterization of pta gene-deleted mutant of Clostridium tyrobutyricum for enhanced butyric acid fermentation

Clostridium tyrobutyricum ATCC 25755 is an acidogenic bacterium, producing butyrate and acetate as its main fermentation products. In order to decrease acetate and increase butyrate production, integrational mutagenesis was used to disrupt the gene associated with the acetate formation pathway in C. tyrobutyricum. A nonreplicative integrational plasmid containing the phosphotransacetylase gene (pta) fragment cloned from C. tyrobutyricum by using degenerate primers and an erythromycin resistance cassette were constructed and introduced into C. tyrobutyricum by electroporation. Integration of the plasmid into the homologous region on the chromosome inactivated the target pta gene and produced the pta-deleted mutant (PTA-Em), which was confirmed by Southern hybridization. SDS-PAGE and two-dimensional protein electrophoresis results indicated that protein expression was changed in the mutant. Enzyme activity assays using the cell lysate showed that the activities of PTA and acetate kinase (AK) in the mutant were reduced by more than 60% for PTA and 80% for AK. The mutant grew more slowly in batch fermentation with glucose as the substrate but produced 15% more butyrate and 14% less acetate as compared to the wild-type strain. Its butyrate productivity was approximately 2-fold higher than the wild-type strain. Moreover, the mutant showed much higher tolerance to butyrate inhibition, and the final butyrate concentration was improved by 68%. However, inactivation of pta gene did not completely eliminate acetate production in the fermentation, suggesting the existence of other enzymes (or pathways) also leading to acetate formation. This is the first-reported genetic engineering study demonstrating the feasibility of using a gene-inactivation technique to manipulate the acetic acid formation pathway in C. tyrobutyricum in order to improve butyric acid production from glucose.

Rapid protocol for electroporation of Clostridium perfringens

A rapid and simple method has been developed for the electroporation of Clostridium perfringens with plasmid DNA. The new improvements, harvesting cells early in the logarithmic stage of growth, keeping the cells at room temperature and the absence of post-shock incubation on ice increased transformation efficiency by one order of magnitude.

Use of a lux reporter system for monitoring rapid changes in alpha-toxin gene expression in Clostridium perfringens during growth

To determine whether the luxA-luxB reporter system is suitable as a sensitive reporter for rapid real-time measurements of alpha-toxin gene (cpa) expression in Clostridium perfringens, and to widen the range of alpha-toxin-producing C. perfringens strains examined with respect to cpa expression during growth, the reporter plasmid pPS14 (possessing the alpha-toxin promoter region plus 0.7 kb of upstream region linked to the luxA-luxB genes), was used in batch growth experiments of C. perfringens P90.2.2, an alpha-toxin-producing strain with no known association with disease. Levels of in vivo bioluminescence obtained during growth were broadly in agreement with previous mRNA and reporter studies of cpa expression (Bullifent et al., FEMS Microbiol. Lett. 131 (1995) 99-105), confirming the suitability of lux as an accurate reporter system in this organism, but the sensitive nature of the lux reporter permitted the in vivo detection of a very rapid reduction in expression during late-exponential phase that was not attributable to loss in cell viability or limiting bioluminescence assay substrates. There was also a small peak in cpa expression in early- to mid-exponential phase cells, that was not detected in previous studies with other reporters. This may be indicative of the exquisite sensitivity of the lux reporter, or this may be a difference in cpa expression that occurs specifically in this C. perfringens strain. Whichever is the case, these results confirm the complexity of alpha-toxin gene expression in different strains of this pathogenic bacterium.

Electrotransformation of Clostridium thermosaccharolyticum

Transformation of the thermophile Clostridium thermosaccharolyticum ATCC 31960 was achieved using plasmid pCTC1 and electroporation. Evidence supporting transformation was provided by Southern blots, detection of the plasmid in 10 out of 10 erythromycin-resistant clones, retransformation of E. coli and C. thermosaccharolyticum with plasmid DNA isolated from C. thermosaccharolyticum, and a proportional relationship between the number of transformants and the amount of DNA added. Transformation efficiencies were very low for plasmid DNA prepared from E. coli (0.6 transformants mg-1 DNA), although somewhat higher for plasmid DNA prepared from C. thermosaccharolyticum (52 transformants mg-1 DNA). Transformation-dependent erythromycin resistance indicates that an adenosine methylase gene originating from Enterococcus faecalis, a mesophile, is expressed in C. thermosaccharolyticum. The plasmid pCTC1 appears to be replicated independently of the chromosome, as indicated by visualization of recovered plasmid on gels, and retransformation using recovered plasmid. pCTC1 is maintained in C. thermosaccharolyticum at both 45 and 60 degrees C. Restriction analysis showed little or no rearrangement occurred upon passage through the thermophile.

Bioluminescence (lux) expression in the anaerobe Clostridium perfringens

To determine whether bacterial luciferase is expressed in the anaerobe Clostridium perfringens to produce an oxygen-requiring bioluminescence reaction, a suitable plasmid vector possessing the luxA and luxB genes of Vibrio fischeri was constructed and introduced into C. perfringens cells. luxAB were placed under the transcriptional control of the C. perfringens alpha-toxin gene promoter region. Suitable ribosome binding sites were introduced upstream of both genes. Bioluminescence was strongly expressed in C. perfringens transformants. Comparisons of in vivo and in vitro bioluminescence measurements demonstrated that in vivo data constituted a quantitative measure of gene expression. This is the first study to show that luxA and luxB genes can be expressed in an anaerobic bacterium and that bioluminescence can be used as a quantitative reporter system in future in vivo studies of gene expression in C. perfringens.

Construction of a sequenced Clostridium perfringens-Escherichia coli shuttle plasmid

A new Clostridium perfringens-Escherichia coli shuttle plasmid has been constructed and its complete DNA sequence compiled. The vector, pJIR418, contains the replication regions from the C. perfringens replicon pIP404 and the E. 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 in E. coli. Both chloramphenicol and erythromycin resistance can be selected in C. perfringens and E. coli since pJIR418 carries the C. 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 from C. perfringens have been demonstrated by the manipulation of a cloned gene encoding the production of phospholipase C.