Analysis of the Structural Gene Encoding a Hemolysin in Vibrio mimicus

An environmental isolate of V. mimicus, strain E-33, has been reported to produce and secrete a hemolysin of 63 kDa. The hemolysin is enterotoxic in test animals. The nucleotide sequence of the structural gene of the hemolysin was determined. We found a 2,232 bp open reading frame, which codes a peptide of 744 amino acids, with a calculated molecular weight of 83,903 Da. The sequence for the structural gene was closely related to the V. cholerae el tor hlyA gene, coding an exocellular hemolysin. The amino terminal amino-acid sequence of the 63 kDa hemolysin, purified from V. mimicus, was determined by the Edman degradation method and found to be NH₂-S-V-S-A-N-N-V-T-N-N-N-E-T. This sequence is identical from S-152 to T-164 predicted from the nucleotide sequence. So, it seems that the mature hemolysin in V. mimicus is processed upon deleting the first 151 amino acids, and the molecular mass is 65,972 Da. Analyzing the deduced amino-acid sequence, we also found a potential signal sequence of 24 amino acids at the amino terminal. Our results suggest that, like V. cholerae hemolysin, two-step processing also exists in V. mimicus hemolysin.     

Identification of hemolysin BL-producing Bacillus cereus isolates by a discontinuous hemolytic pattern in blood agar.

Bacillus cereus causes distinct exotoxin-mediated diarrheal and emetic food poisoning syndromes and a variety of nongastrointestinal infections. Evidence is accumulating that hemolysin BL is a major B. cereus virulence factor. We describe two methods for detection of hemolysin BL in crude samples and on primary culture media. In the first method, the highly unusual discontinuous hemolysis pattern that is characteristic of pure hemolysin BL was produced in sheep and calf blood agar around wells filled with crude culture supernatant from hemolysin BL-producing strains. In the second method, the pattern was formed surrounding colonies of hemolysin BL-producing strains grown on media consisting of nutrient agar, 0.15 M NaCl, 2% calf serum, and sheep or calf blood. Hemolysin BL production was detected with these methods in 41 of 62 (66%) previously identified B. cereus isolates and in 46 of 136 (34%) presumptive B. cereus isolates from soil. All nine isolates tested that were associated with diarrhea or nongastrointestinal illness were positive for hemolysin BL. The methods presented here are specific, simple, inexpensive, and applicable to the screening of large numbers of samples or isolates.     

Genetic and biochemical properties of a hemolysin (pyolysin) produced by a swine isolate of Arcanobacterium (Actinomyces) pyogenes

Arcanobacterium (Actinomyces) pyogenes, a causative agent of various pyogenic diseases in domestic animals, produces a hemolysin which is thought to be an important virulence factor. This hemolysin was purified from the culture supernatant of A. pyogenes swine isolate. The purified hemolysin showed a single band with a molecular mass of 56 kDa on SDS-polyacrylamide gel electrophoresis, and its isoelectric point was 9.2. The activity of this hemolysin was not enhanced by the addition of L-cysteine or sodium thioglycolate, but it was inhibited by cholesterol. The gene encoding the hemolysin was cloned, sequenced and expressed in Escherichia coli by means of ZAP Express vector. Analysis by SDS-polyacrylamide gel electrophoresis with immunoblotting showed that the molecular weight of the hemolysin expressed in E. coli is the same as that of the hemolysin purified from A. pyogenes. Nucleotide sequence analysis revealed an open reading frame of 1,605 bp encoding a 534 amino acid protein of 57,989 Da. The nucleotide sequence of the hemolysin gene from A. pyogenes swine isolate differed only slightly (97.6% identity) from the sequence of plo gene from A. pyogenes strain BBR1 reported by Billington et al (J. Bacteriol. 179: 6100-6106, 1997). The cysteine residue existed in the undecapeptide region of the hemolysin, which is highly conserved in thiol-activated cytolysins (cholesterol-binding cytolysins), and is replaced with alanine. Therefore, the hemolysin of A. pyogenes seems to be a novel member of the thiol-activated cytolysin family.     

Characteristics of the interaction of a treponemal hemolysin with rabbit erythrocytes

The mechanism of action on rabbit red cells of Treponema hyodysenteriae hemolysin was studied using volume analysis and release of hemoglobin. While fixation of the hemolysin on the erythrocytes is temperature independent, it appears that hemolysis is temperature dependent. The kinetics of hemolysis proceed according to a sigmoid curve characterized by a prelytic lag. The duration of the prelytic lag varies inversely with the quantity of hemolysin but the rate and the maximum value of hemolysis are directly proportional to the quantity of hemolysin. The effect of sucrose and trypan blue on the hemolysin and the red cells suggest that erythrocyte lysis is likely to be induced by the hemolysin in a way different from that known for other hemolytic agents.     

Cloning and functional characterization of the plasmid-encoded hemolysin determinant of Escherichia coli.

We cloned the DNA containing the Escherichia coli hemolysin determinant on a small, high-copy plasmid. We generated plasmids containing fragments of this DNA and used them either alone or in two-plasmid complementation systems to define the limits of the structural genes. This system also allowed us to partially characterize the function of each of the gene products in the production and transport of hemolysin. Taken with previously published data, the present experiments indicate the following. (i) At least three cistrons, hlyC, hlyA, and hlyB (these were previously designated cisC, etc. [Noegel et al., Mol. Gen. Genet. 175:343-350, 1979]), contain the specific genetic information for the hemolytic phenotype, (ii) hlyA encodes a 107,000-kilodalton protein, which seems to be an inactive precursor of hemolysin. (iii) Normal amounts of hemolysin activity inactive precursor of hemolysin. (iii) Normal amounts of hemolysin activity require only the products of hlyA and hlyC. This activity was found in the periplasm; very little hemolysin activity was found in the cytoplasm, suggesting that the hlyC product is required for transport or activation of the hlyA product or both. (iv) Active hemolysin remains in the periplasm in the absence of hlyB function, hence the hlyB product seems to be necessary for the transport of hemolysin to the exterior of the cell. We further show that overproduction of the hlyA product is lethal, probably causing lysis of the cell.     

Simple Purification Method for a Vibrio vulnificus Hemolysin by a Hydrophobic Column Chromatography in the Presence of a Detergent

A Vibrio vulnificus hemolysin (VVH) was purified by two steps of hydrophobic column chromatography on Phenyl-Sepharose HP. The first chromatography was carried out at pH 6.0. In this pH condition, VVH efficiently bound to the column, but the hemolysin fraction eluted was accompanied with colored substance(s). To eliminate this colored substance, the second chromatography was carried out at pH 9.8 in the presence of 1% 3-[(3-cholamidopropyl) dimethylammonio]-1-propanesulfonate (CHAPS), a zwitterionic detergent. Homogeneity of the hemolysin thus obtained was shown by polyacrylamide gel electrophoresis. The specific activity increased 33, 600 times and the yield was 35%. The method is simple and useful to supply enough VVH for study of the role of the hemolysin in the infection by V. vulnificus or on the mechanism of action of the hemolysin.     

Demonstration of a plasmid-borne gene encoding a thermostable direct hemolysin in Vibrio cholerae non-O1 strains

Of 15 Vibrio cholerae non-O1 strains, 2 produced a hemolysin termed NAG-rTDH, which is very similar to the thermostable direct hemolysin of V. parahaemolyticus. These two strains contained DNA sequences which are homologous to a DNA probe for the V. parahaemolyticus thermostable direct hemolysin gene. A probe-positive 9-kilobase HindIII fragment was cloned from a plasmid of a V. cholerae non-O1 strain into plasmid pBR322, and the resulting Escherichia coli clones produced intracellular NAG-rTDH.     

Hybridization analysis of the gene encoding a hemolysin (suilysin) of Streptococcus suis type 2: evidence for the absence of the gene in some isolates

A hemolysin gene was cloned from a virulent strain of Streptococcus suis type 2 strain 1933. Analysis of the gene and its product revealed that it is identical to a previously reported hemolysin (suilysin) of S. suis type 2. Southern hybridization analysis of the digested total genomic DNA from S. suis with the cloned hemolysin DNA sequences as probe indicated that the hemolysin gene is present as a single copy on the genome. Genomic DNA of 63 isolates of S. suis encompassing all known serotypes were examined by DNA hybridization and polymerase chain reaction (PCR) studies for the presence of the hemolysin gene homolog. The results of both techniques were identical and demonstrated the absence of the hemolysin gene in some isolates. In DNA hybridization studies, three DNA probes derived from the hemolysin encoding gene were used. Results showed that sequences encoding the C-terminal 257 amino acid residues (Probe 1) were the most conserved and hybridized to a 1.2 kb fragment in 32 (51%) strains and a 4.0 kb fragment in 23 (36%) strains respectively. Thus, Probe 2 hybridized to the DNA of 55 (87%) of the isolates tested. The first probe (Probe 1) comprising almost the entire hemolysin gene and the third probe (Probe 3) which consisted of the N-terminal sequences hybridized only to a 4.0 kb fragment in 23 (36%) of the strains tested. Eight (13%) of the strains tested were hybridization and PCR negative. The hybridization of the C-terminal end sequences (Probe 2) to the 1.2 kb fragment in 32 (51%) of the strains and the lack of hybridization of the probes to eight (13%) strains may suggest the presence of different types of hemolysin molecule in S. suis strains.     

Effects of penicillin on the synthesis of membrane proteins of Chlamydia trachomatis LGV2 serotype

Abstract Actinobacillus (Hemophilus) pleuropneumoniae type strain 4074, serotype 1, secretes a potent hemolysin. This hemolysin is thermolabile and inactivated by proteinase K. We have purified the hemolysin to homogeneity and characterized it as a protein of 105 kDa by SDS-Polyacrylamide gel electrophoresis. Using a calibrated gel filtration column, the active hemolysin was identified as a monomer of the 105 kDa polypeptide. This hemolysin is an acid protein with an isoelectric point at p I 4.3.     

Demonstration of a plasmid-borne gene encoding a thermostable direct hemolysin in Vibrio cholerae non-O1 strains.

Of 15 Vibrio cholerae non-O1 strains, 2 produced a hemolysin termed NAG-rTDH, which is very similar to the thermostable direct hemolysin of V. parahaemolyticus. These two strains contained DNA sequences which are homologous to a DNA probe for the V. parahaemolyticus thermostable direct hemolysin gene. A probe-positive 9-kilobase HindIII fragment was cloned from a plasmid of a V. cholerae non-O1 strain into plasmid pBR322, and the resulting Escherichia coli clones produced intracellular NAG-rTDH.     

Synthesis and secretion of hemolysin by Escherichia coli.

Hemolytic Escherichia coli cells were found to synthesize and secrete significant amounts of hemolysin into a mineral salt-glucose medium containing hemoglobin. The release of de novo-synthesized hemolysin was stopped in the presence of energy metabolism inhibitors such as 2,4-dinitrophenol, sodium azide, or potassium cyanide, resulting in an accumulation of intracellular hemolysin. A similar effect was observed in the presence of procaine, a neuroactive drug which inhibits the processing of exoproteins. Small amounts of hemolysin were secreted into the medium within approximately 10 min of inhibition of protein synthesis by chloramphenicol. This represented the final release of preformed periplasmic hemolysin en route to secretion through the outer membrane and was not caused by adsorption of external hemolysin to the cell surface. This secretion was not energy dependent but was inhibited above pH 8 and at low temperatures (10 to 20 degrees C). We concluded that two transport processes are involved in hemolysin secretion. De novo-synthesized hemolysin is extruded by an energy-dependent process through the cytoplasmic membrane and probably requires processing. In the periplasmic space a small internal pool of preformed hemolysin is accumulated temporarily before being transported through the outer membrane. Release of hemolysin through the outer membrane does not require energy or de novo protein synthesis.     

Bacterial hemolysins and leukotoxins affect target cells by forming large exogenous pores into their plasma membrane.Escherichia coli hemolysin a as a case example

Many bacteria include among their virulence factors exoproteins which exert leukocidal and cytolytic functions and have the ability to form pores in model membranes. We show that, at least in the case of the RTX hemolysin produced byEscherichia coli (HlyA), formation of pores in planar lipid membranes is parallelled by opening of strikingly similar channels in the plasma membrane of exposed macrophages. Formation of such lesions in leukocytes can give rise to a variety of effects leading altogether to a diminished immune response towards the invasive bacteria.Abbreviations HlyA Escherichia coli hemolysin A - RTX Repeat ToXins - HMDM human monocyte-derived macrophages - PLM planar lipid membranes     

Nebrodeolysin,a novel hemolytic protein from mushroom Pleurotus nebrodensis with apoptosis-inducing and anti-HIV-1 effects

A novel hemolysin was isolated from the edible mushroom Pleurotus nebrodensis by ion exchange and gel filtration chromatography on DEAE-Sepharose and Sephacryl S-100. The hemolysin from Pleurotus nebrodensis hemolysin (nebrodeolysin) is a monomeric protein with a molecular weight of approximately 27 kDa as determined by gel filtration and SDS-PAGE. Nebrodeolysin exhibited remarkable hemolytic activity towards rabbit erythrocytes and caused efflux of potassium ions from erythrocytes. Subsequently, this hemolysin showed strong cytotoxicity against Lu-04, Bre-04, HepG2, L929, and HeLa cells. It was also found that this hemolysin induced apoptosis in L929 and HeLa cells as evidenced by microscopic observations and DNA ladder, respectively. Moreover, this hemolysin was shown to possess anti-HIV-1 activity in CEM cell culture.     

Analysis of a gene (vch) encoding hemolysin isolated and sequenced from Vibrio campbellii

This study describes the amplification, localization, and sequence analysis of a hemolysin gene from type strain V. campbellii NBRC 15631--the first report of a full-length hemolysin gene for the species. An amplicon ( approximately 600 bp) of polymerase chain reaction performed using V. campbellii DNA template and primers previously designed to target a fragment of V. harveyi hemolysin gene (vhh) was shotgun-cloned and sequenced, generating 576 bp nucleotide sequences of the V. campbellii hemolysin gene. PCR primers designed based on these initial sequences were used to amplify a 551-bp V. campbellii hemolysin gene fragment that was used as probe in Southern hybridization, which localized the complete hemolysin gene within a 3.5-kb HindIII restriction fragment of the V. campbellii genomic DNA. To obtain the remaining DNA sequences upstream and downstream of the 576-bp hemolysin gene sequences, inverse PCR was performed using a self-ligated (circularized) V. campbellii HindIII restriction fragment as the template and PCR primers designed to amplify flanking regions of the 576-bp gene fragment. Nucleotide sequences from the terminal regions of the 3.1-kb product of inverse PCR provided the flanking sequences, resulting in the complete sequence for the V. campbellii hemolysin gene. A VCH PCR primer set was designed to amplify a 1.3-kb region containing the entire hemolysin gene even from other V. campbellii strains, which was sequenced to confirm the V. campbellii hemolysin gene sequence. An open reading frame (ORF) of 1,254 bp (designated as vch) was identified, sharing 79% sequence identity with V. harveyi hemolysin gene vhh, representing 262 base substitutions between V. campbellii and V. harveyi. The deduced amino acid sequence of V. campbellii hemolysin (VCH) shows homologies to the V. harveyi hemolysin (VHH), thermolabile hemolysin of V. parahaemolyticus, proteins such as phospholipase of V. vulnificus and lecithinases of V. mimicus and V. cholerae. The VCH primer set did not produce any amplicon in PCR using V. harveyi DNA, and may therefore be used to distinguish environmental strains of V. campbellii from V. harveyi.     

Subcellular location and unique secretion of the hemolysin of Serratia marcescens

It is shown that Serratia marcescens exports a hemolysin to the cell surface and secretes it to the extracellular space. Escherichia coli containing the cloned hemolysin genes shlA and shlB exported and secreted the S. marcescens hemolysin. A nonhemolytic secretion-incompetent precursor of the hemolysin, designated ShlA*, was synthesized in a shlB deletion mutant and accumulated in the periplasmic space of E. coli. Immunogold-labeled ultrathin sections revealed ShlA* bound to the outer face of the cytoplasmic membrane and to the inner face of the outer membrane. A number of mutants carrying 3' deletions in the shlA gene secreted truncated polypeptides, the smallest of which contained only 261 of the 1578 amino acids of the mature ShlA hemolysin, showing that the information for export to the cell surface of E. coli and secretion into the culture medium is located in the NH2-terminal segment of the hemolysin. We propose a secretion pathway in which ShlA and ShlB are exported across the cytoplasmic membrane via a signal sequence-dependent mechanism. ShlB is integrated into the outer membrane. ShlA is translocated across the outer membrane with the help of ShlB. During the latter export process or at the cell surface, ShlA acquires the hemolytically active conformation and is released to the extracellular space. The hemolysin secretion pathway appears to be different from any other secretion system hitherto reported and involves only a single specific export protein.     

The extracellular metalloprotease of Vibrio tubiashii is a major virulence factor for pacific oyster (Crassostrea gigas) larvae

Vibrio tubiashii is a recently reemerging pathogen of larval bivalve mollusks, causing both toxigenic and invasive disease. Marine Vibrio spp. produce an array of extracellular products as potential pathogenicity factors. Culture supernatants of V. tubiashii have been shown to be toxic to oyster larvae and were reported to contain a metalloprotease and a cytolysin/hemolysin. However, the structural genes responsible for these proteins have yet to be identified, and it is uncertain which extracellular products play a role in pathogenicity. We investigated the effects of the metalloprotease and hemolysin secreted by V. tubiashii on its ability to kill Pacific oyster (Crassostrea gigas) larvae. While V. tubiashii supernatants treated with metalloprotease inhibitors severely reduced the toxicity to oyster larvae, inhibition of the hemolytic activity did not affect larval toxicity. We identified structural genes of V. tubiashii encoding a metalloprotease (vtpA) and a hemolysin (vthA). Sequence analyses revealed that VtpA shared high homology with metalloproteases from a variety of Vibrio species, while VthA showed high homology only to the cytolysin/hemolysin of Vibrio vulnificus. Compared to the wild-type strain, a VtpA mutant of V. tubiashii not only produced reduced amounts of protease but also showed decreased toxicity to C. gigas larvae. Vibrio cholerae strains carrying the vtpA or vthA gene successfully secreted the heterologous protein. Culture supernatants of V. cholerae carrying vtpA but not vthA were highly toxic to Pacific oyster larvae. Together, these results suggest that the V. tubiashii extracellular metalloprotease is important in its pathogenicity to C. gigas larvae.     

Pathogenicity ofAeromonas hydrophila in red leg disease in frogs

Endotoxin and hemolysin fromAeromonas hydrophila A₃ were studied to understand the pathogenicity of the organism. Neither the endotoxin nor the hemolysin alone produced typical red leg disease symptoms or death in frogs, even at a very high dosage of 8,000 μg; however, endotoxin and hemolysin together did. Further, histamine-stressed frogs died from hemolysin but not endotoxin. Hemolytic activity of hemolysin increased in cells that were preincubated with endotoxin. Results point to the conclusion that red leg disease in frogs represents a complex interaction between endotoxin and hemolysin and that stress-producing factors other than the endotoxin might trigger disease production.     

Expression of the hemolysin operon in Escherichia coli is modulated by a nucleoid-protein complex that includes the proteins Hha and H-NS

The Escherichia coli protein Hha is a temperature- and osmolarity-dependent modulator of the expression of the hemolysin operon. The Hha protein was purified and its DNA-binding properties analyzed. Hha binds in a non-specific manner throughout the upstream regulatory region of the hemolysin operon in the recombinant hemolytic plasmid pANN202-312. A search for interacting proteins revealed that Hha interacts with H-NS. DNA-binding studies showed that, in vitro, Hha and H-NS together form a complex with DNA that differs from those formed with either protein alone. These data, together with the effects of hha and hns mutations on the expression of the hemolysin genes, suggest that in vivo H-NS and Hha form a nucleoid-protein complex that accounts for the thermo-osmotic regulation of the hemolysin operon in E. coli. Received. 18 October 1999 / Accepted: 21 December 1999     

Mapping of a gene that regulates hemolysin production in Vibrio cholerae.

A gene that regulates the hemolysin structural gene (hly) was found to be tightly linked to the tox-1000 locus of Vibrio cholerae RJ1 and separated from hly by a large section of the V. cholerae genetic map. This hemolysin regulatory gene was designated hlyR.