C型产气荚膜梭菌β1毒素基因表达

利用PCR技术,从C型产气荚膜梭菌染色体DNA中扩增出β1毒素基因,然后用限制性核酸内切酶BamHI和EcoRI对其进行双酶切处理,回收0．95kb的β1毒素基因片段,最后将其定向克隆在事先经同样内切酶处理的载体pET-28c中相应位点上,转化至受体菌B121(DE3)qh。经BamHI和Eco RI双酶切鉴定和核苷酸序列测定证实,构建的重组质粒pETXBl含有B毒素基因,并且具有正确的基因序列和阅读框架。重组菌株BI21(DE3)(pETXB1)经IPIG诱导后,其表达产物经ELISA检测和SDS-PAGE分析,结果表明重组菌株可以高效表达β1毒素蛋白,该蛋白占菌体总蛋白相对含量的12．24％。     

Toxin Plasmids of Clostridium perfringens

SUMMARY

In both humans and animals, Clostridium perfringens is an important cause of histotoxic infections and diseases originating in the intestines, such as enteritis and enterotoxemia. The virulence of this Gram-positive, anaerobic bacterium is heavily dependent upon its prolific toxin-producing ability. Many of the ∼16 toxins produced by C. perfringens are encoded by large plasmids that range in size from ∼45 kb to ∼140 kb. These plasmid-encoded toxins are often closely associated with mobile elements. A C. perfringens strain can carry up to three different toxin plasmids, with a single plasmid carrying up to three distinct toxin genes. Molecular Koch''s postulate analyses have established the importance of several plasmid-encoded toxins when C. perfringens disease strains cause enteritis or enterotoxemias. Many toxin plasmids are closely related, suggesting a common evolutionary origin. In particular, most toxin plasmids and some antibiotic resistance plasmids of C. perfringens share an ∼35-kb region containing a Tn916-related conjugation locus named tcp (transfer of clostridial plasmids). This tcp locus can mediate highly efficient conjugative transfer of these toxin or resistance plasmids. For example, conjugative transfer of a toxin plasmid from an infecting strain to C. perfringens normal intestinal flora strains may help to amplify and prolong an infection. Therefore, the presence of toxin genes on conjugative plasmids, particularly in association with insertion sequences that may mobilize these toxin genes, likely provides C. perfringens with considerable virulence plasticity and adaptability when it causes diseases originating in the gastrointestinal tract.     

Effect of Clostridium perfringens Epsilon Toxin on Rat Isolated Aorta

The effect of Clostridium perfringens epsilon toxin on rat isolated aorta was investigated. The toxin caused contraction of the isolated aorta in a dose-dependent manner. The toxin induced no contraction of the isolated aorta in low-Na medium and of the tissue stored at 4 C for 7 days. However, tetrodotoxin (TTX) had no effect on the toxin-induced contraction. The toxin-induced contraction was significantly inhibited by phentolamine and prazosine, but did not by atropine, mecamylamine, chlorpheniramine and methysergide. These data suggest that the toxin-caused contraction is mediated through nervous system in rat isolated aorta.     

Effect of Clostridium perfringens Alpha Toxin on Contraction of Isolated Guinea-Pig Diaphragm

The effect of Clostridium perfringens alpha toxin on contraction induced by-electric stimulation of isolated guinea-pig diaphragm was investigated. The toxin inhibited electrically stimulated contraction of the tissue in a dose- and incubation time-dependent manner. Tetrodotoxin resulted in no effect of the action of the toxin. Nifedipine dose-dependently delayed the action of the toxin, but verapamil and diltiazem did not. On the other hand, treatment of the toxin with N-acetylimidazole caused significant reduction of the inhibitory activity of the toxin on contraction, but did not cause significant loss of phospholipase C activity (PN activity) as measured by hydrolysis of p-nitrophenylphosphorylcholine. The data showed that the toxin impairs contraction of isolated guinea-pig diaphragm.     

Structural Insights into Clostridium perfringens Delta Toxin Pore Formation

Clostridium perfringens Delta toxin is one of the three hemolysin-like proteins produced by C. perfringens type C and possibly type B strains. One of the others, NetB, has been shown to be the major cause of Avian Nectrotic Enteritis, which following the reduction in use of antibiotics as growth promoters, has become an emerging disease of industrial poultry. Delta toxin itself is cytotoxic to the wide range of human and animal macrophages and platelets that present G_M2 ganglioside on their membranes. It has sequence similarity with Staphylococcus aureus β-pore forming toxins and is expected to heptamerize and form pores in the lipid bilayer of host cell membranes. Nevertheless, its exact mode of action remains undetermined. Here we report the 2.4 Å crystal structure of monomeric Delta toxin. The superposition of this structure with the structure of the phospholipid-bound F component of S. aureus leucocidin (LukF) revealed that the glycerol molecules bound to Delta toxin and the phospholipids in LukF are accommodated in the same hydrophobic clefts, corresponding to where the toxin is expected to latch onto the membrane, though the binding sites show significant differences. From structure-based sequence alignment with the known structure of staphylococcal α-hemolysin, a model of the Delta toxin pore form has been built. Using electron microscopy, we have validated our model and characterized the Delta toxin pore on liposomes. These results highlight both similarities and differences in the mechanism of Delta toxin (and by extension NetB) cytotoxicity from that of the staphylococcal pore-forming toxins.     

Clostridium perfringens Epsilon Toxin Increases the Small Intestinal Permeability in Mice and Rats

Epsilon toxin is a potent neurotoxin produced by Clostridium perfringens types B and D, an anaerobic bacterium that causes enterotoxaemia in ruminants. In the affected animal, it causes oedema of the lungs and brain by damaging the endothelial cells, inducing physiological and morphological changes. Although it is believed to compromise the intestinal barrier, thus entering the gut vasculature, little is known about the mechanism underlying this process. This study characterizes the effects of epsilon toxin on fluid transport and bioelectrical parameters in the small intestine of mice and rats. The enteropooling and the intestinal loop tests, together with the single-pass perfusion assay and in vitro and ex vivo analysis in Ussing''s chamber, were all used in combination with histological and ultrastructural analysis of mice and rat small intestine, challenged with or without C. perfringens epsilon toxin. Luminal epsilon toxin induced a time and concentration dependent intestinal fluid accumulation and fall of the transepithelial resistance. Although no evident histological changes were observed, opening of the mucosa tight junction in combination with apoptotic changes in the lamina propria were seen with transmission electron microscopy. These results indicate that C. perfringens epsilon toxin alters the intestinal permeability, predominantly by opening the mucosa tight junction, increasing its permeability to macromolecules, and inducing further degenerative changes in the lamina propria of the bowel.     

Medium for Toxin Production by Clostridium perfringens in Continuous Culture

A tryptone-salts medium for continuous growth and alpha toxin production of Clostridium perfringens type A in an adapted chemostat is described. In such steady-state cultures, fermentative and biochemical activity of C. perfringens remained unchanged. Toxigenic ability to produce alpha, theta, and nu toxins was preserved.     

Clostridium perfringens Delta Toxin Is Sequence Related to Beta Toxin,NetB, and Staphylococcus Pore-Forming Toxins,but Shows Functional Differences

Clostridium perfringens produces numerous toxins, which are responsible for severe diseases in man and animals. Delta toxin is one of the three hemolysins released by a number of C. perfringens type C and possibly type B strains. Delta toxin was characterized to be cytotoxic for cells expressing the ganglioside G_M2 in their membrane. Here we report the genetic characterization of Delta toxin and its pore forming activity in lipid bilayers. Delta toxin consists of 318 amino acids, its 28 N-terminal amino acids corresponding to a signal peptide. The secreted Delta toxin (290 amino acids; 32619 Da) is a basic protein (pI 9.1) which shows a significant homology with C. perfringens Beta toxin (43% identity), with C. perfringens NetB (40% identity) and, to a lesser extent, with Staphylococcus aureus alpha toxin and leukotoxins. Recombinant Delta toxin showed a preference for binding to G_M2, in contrast to Beta toxin, which did not bind to gangliosides. It is hemolytic for sheep red blood cells and cytotoxic for HeLa cells. In artificial diphytanoyl phosphatidylcholine membranes, Delta and Beta toxin formed channels. Conductance of the channels formed by Delta toxin, with a value of about 100 pS to more than 1 nS in 1 M KCl and a membrane potential of 20 mV, was higher than those formed by Beta toxin and their distribution was broader. The results of zero-current membrane potential measurements and single channel experiments suggest that Delta toxin forms slightly anion-selective channels, whereas the Beta toxin channels showed a preference for cations under the same conditions. C. perfringens Delta toxin shows a significant sequence homolgy with C. perfringens Beta and NetB toxins, as well as with S. aureus alpha hemolysin and leukotoxins, but exhibits different channel properties in lipid bilayers. In contrast to Beta toxin, Delta toxin recognizes G_M2 as receptor and forms anion-selective channels.     

Beta2 toxin,a novel toxin produced by Clostridium perfringens

A novel toxin (Beta2) and its gene were characterized from a Clostridium perfringens strain isolated from a piglet with necrotic enteritis. At the amino-acid level, Beta2 toxin (27 670 Da) has no significant homology with the previously identified Beta toxin (called Beta1) (34 861 kDa) from C. perfringens type B NCTC8533 ( Hunter, S.E.C., Brown, J.E., Oyston, P.C.F., Sakurai, J., Titball, R.W., 1993. Molecular genetic analysis of beta-toxin of Clostridium perfringens reveals sequence homology with alpha-toxin, gamma-toxin, and leukocidin of Staphylococcus aureus. Infect. Immun. 61, 3958–3965). Both Beta1 and Beta2 toxins were lethal for mice and cytotoxic for the cell line I407, inducing cell rounding and lysis without affecting the actin cytoskeleton. The genes encoding Beta1 and Beta2 toxins have been localized in unlinked loci in large plasmids of C. perfringens. In addition, Beta2 toxin-producing C. perfringens strains were found to be associated with animal diseases such as necrotic enteritis in piglets and enterocolitis in horses.     

A型产气荚膜梭菌α毒素基因的高效表达

用NooI/EcoRI酶切含α毒素基因质粒pXCPA02,回收1.2kb的α毒素基因片段,通过T4 DNA连接酶,将回收的α毒素基因片段与经NcoI/Eco RI酶切的表达载体pET-28c连接,转化至受体菌BI21(DE3)中,经NcoI/EcoRI,BamHI/Eco RI和NcoI/BamHI/Eco RI酶切反应鉴定和核苷酸序列分析证实,获得的表达质粒aXETA02含有α毒素基因,而且阅读框架是正确的.重组菌株BL21(DE3),(pXETA02)经IPTG诱导后,其表达产物经ELISA检测和SDS-PAGE分析,结果表明重组菌株可以高效表达α毒素蛋白,该蛋白占菌体总蛋白相对含量的36.83%.     

Polymerase Chain Reaction Test for Differentiation of Five Toxin Types of Clostridium perfringens

In order to avoid the use of experimental animals, the polymerase chain reaction (PCR) method was applied to differentiate Clostridium perfringens into five toxin types. Twenty-two out of 23 strains tested produced the toxin(s) corresponding to the toxin gene(s) identified by PCR, and vice versa. Consequently, the gene typing was consistent with conventional typing by animal tests. Twenty-five strains were identified as types different from original ones by the PCR method as well as a toxin neutralization test. These findings suggest that the PCR method, which is easy and timesaving, is applicable to identify the toxin types of C. perfringens as an alternative to animal tests, and that beta-, epsilon- and iota-toxin genes might be lost by long-term preservation. The reasons why the strains lost the genes are discussed.     

Oligomerization of Clostridium perfringens Epsilon Toxin Is Dependent upon Caveolins 1 and 2

Evidence from multiple studies suggests that Clostridium perfringens ε-toxin is a pore-forming toxin, assembling into oligomeric complexes in the plasma membrane of sensitive cells. In a previous study, we used gene-trap mutagenesis to identify mammalian factors contributing to toxin activity, including caveolin-2 (CAV2). In this study, we demonstrate the importance of caveolin-2 and its interaction partner, caveolin-1 (CAV1), in ε-toxin-induced cytotoxicity. Using CAV2-specific shRNA in a toxin-sensitive human kidney cell line, ACHN, we confirmed that cells deficient in CAV2 exhibit increased resistance to ε-toxin. Similarly, using CAV1-specific shRNA, we demonstrate that cells deficient in CAV1 also exhibit increased resistance to the toxin. Immunoprecipitation of CAV1 and CAV2 from ε-toxin-treated ACHN cells demonstrated interaction of both CAV1 and -2 with the toxin. Furthermore, blue-native PAGE indicated that the toxin and caveolins were components of a 670 kDa protein complex. Although ε-toxin binding was only slightly perturbed in caveolin-deficient cells, oligomerization of the toxin was dramatically reduced in both CAV1- and CAV2-deficient cells. These results indicate that CAV1 and -2 potentiate ε-toxin induced cytotoxicity by promoting toxin oligomerization – an event which is requisite for pore formation and, by extension, cell death.     

Effect of Clostridium perfringens epsilon toxin on MDCK cells

Epsilon toxin is one of the major lethal toxins produced by Clostridium perfringens type D and B. It is responsible for a rapidly fatal disease in sheep and other farm animals. Many facts have been published about the physical properties and the biological activities of the toxin, but the molecular mechanism of the action inside the cells remains unclear. We have found that the C. perfringens epsilon toxin caused a significant decrease of the cell numbers and a significant enlargement of the mean cell volume of MDCK cells. The flow cytometric analysis of DNA content revealed the elongation of the S phase and to a smaller extent of the G2+M phase of toxin-treated MDCK cells in comparison to untreated MDCK cells. The results of ultrastructural studies showed that the mitosis is disturbed and blocked at a very early stage, and confirmed the toxin influence on the cell cycle of MDCK cells.     

Effect of Soy Proteins on the Growth of Clostridium perfringens

Proteins that are used to fabricate imitation foods such as synthetic meats were evaluated for stimulative or inhibitory effects on the growth of Clostridium perfringens. Growth rate and extent were measured in thioglycolate medium without dextrose. This liquid medium contains Trypticase (BBL) which served as the protein control. For comparison, various soy proteins, synthetic meats, beef, turkey, sodium caseinate, and combinations of each were substituted for Trypticase. Meat loaf systems were also employed to determine the effects of protein additives to meat under actual meat loaf conditions. Growth of C. perfringens type A, strain S40, was measured in the respective media at 45 C at a pH of 7.0 and an E(h) of below -300 mv. Viable populations were enumerated by agar plate techniques on Trypticase-sulfite-yeast-citrate-agar incubated anaerobically (90% N(2)-10% CO(2)) for 18 hr at 35 C. When compared to Trypticase, some soy proteins had stimulative effects on the growth of C. perfringens, whereas sodium caseinate and some soy proteins were inhibitory. In liquid medium in which meat or soy meat was the source of protein, there was a marked stimulation by beef, chicken, and soy beef. Soy chicken supported growth at a rate less than observed with Trypticase. Under actual meat loaf conditions, the addition of soy meat or protein additives to beef did not affect the growth of C. perfringens. The addition of protein additives to turkey meat loaves significantly enhanced the rate of growth of C. perfringens. The stimulative effects of some soy proteins are significant in relation to control of foodborne disease.     

Roles of Asp179 and Glu270 in ADP-Ribosylation of Actin by Clostridium perfringens Iota Toxin

Clostridium perfringens iota toxin is a binary toxin composed of the enzymatically active component Ia and receptor binding component Ib. Ia is an ADP-ribosyltransferase, which modifies Arg177 of actin. The previously determined crystal structure of the actin-Ia complex suggested involvement of Asp179 of actin in the ADP-ribosylation reaction. To gain more insights into the structural requirements of actin to serve as a substrate for toxin-catalyzed ADP-ribosylation, we engineered Saccharomyces cerevisiae strains, in which wild type actin was replaced by actin variants with substitutions in residues located on the Ia-actin interface. Expression of the actin mutant Arg177Lys resulted in complete resistance towards Ia. Actin mutation of Asp179 did not change Ia-induced ADP-ribosylation and growth inhibition of S. cerevisiae. By contrast, substitution of Glu270 of actin inhibited the toxic action of Ia and the ADP-ribosylation of actin. In vitro transcribed/translated human β-actin confirmed the crucial role of Glu270 in ADP-ribosylation of actin by Ia.