The secreted hemolysins of Proteus mirabilis, Proteus vulgaris, and Morganella morganii are genetically related to each other and to the alpha-hemolysin of Escherichia coli

Escherichia coli hemolysin is a potent inductor of phosphoinositide hydrolysis and related metabolic responses in human neutrophils

Escherichia coli hemolysin (Hly) is a proteinaceous pore-forming exotoxin that probably represents a significant virulence factor in E. coli infections. We investigated its influence on human polymorphonuclear neutrophils (PMN), previously identified as highly susceptible targets. Hly provoked rapid secretion of elastase and myeloperoxidase, generation of superoxide, and synthesis of platelet-activating factor (PAF) and lyso-PAF. Concomitantly, marked phosphatidylinositol (PtdIns) hydrolysis with sequential appearance of the inositol-phosphates, inositol-phosphates, inositol triphosphate, diphosphate, and monophosphate, respectively, and formation of diacylglycerol, occurred. The metabolic responses displayed distinct bell-shaped dose dependencies, with maximum events noted at low toxin concentrations of 0.1-0.5 hemolytic units per milliliter. PtdIns hydrolysis and metabolic responses elicited by Hly exceeded those evoked by optimal concentrations of formylmethionyl-leucyl phenylalanine, PAF, leukotriene B4, A23187, or staphylococcal alpha-toxin. The toxin-induced effects were sensitive toward modulators of PMN stimulus transmission pathways (pertussis toxin, the kinase C inhibitor H7, and phorbol myristate acetate "priming"). We conclude that the marked capacity of low doses of Hly to elicit degranulation, respiratory burst, and lipid mediator generation in human PMN probably envolves signal transduction via PtdIns hydrolysis.

Isolation and molecular characterization of spontaneously occurring cytolysin-negative mutants of Actinobacillus pleuropneumoniae serotype 7

Actinobacillus pleuropneumoniae serotype 7 strains are shown to spontaneously lose cytolytic activity with a frequency of approximately 10(-4). The phenotypic change is associated with the loss of approximately 8.5 kbp of chromosomal DNA. A genomic fragment encoding the cytolysin and its flanking sequences was cloned and characterized. Also, the corresponding truncated fragment was cloned from a spontaneous mutant. Comparison of the two clones allowed the definition of the excision site. The ends of the excised fragment are composed of 1,201 bp long direct identical repeats, possibly facilitating the genotypic change by homologous recombination. In accordance with this hypothesis, one repeat is conserved in the spontaneous mutant. Each repeat contains one open reading frame preceded by a Shine-Dalgarno consensus sequence, and the ends of each repeat contain 26-bp complementary sequences with four mismatches.

Mutational analysis supports a role for multiple structural features in the C-terminal secretion signal of Escherichia coli haemolysin

We have carried out an extensive mutational analysis of the C-terminal signal which targets the export of the 1024-residue haemolysin protein (HlyA) of Escherichia coli across both bacterial membranes into the surrounding medium. Over 60 variants of the HlyA C-terminal 53-amino-acid sequence were created by oligonucleotide-directed mutagenesis and fused to the HlyA N-terminal 830 residues. Transport of the HlyA derivatives by the HlyB/HlyD system was compared with the wild-type level and the data indicate that the HlyA C-terminal export signal lies within the last 48 amino acids and comprises three functional domains: an amphipathic, charged helix between residues 1,977 and R,996; a 13-amino-acid uncharged region from residue T,997 to S,1009; and an 8-amino-acid hydroxylated tail at the extreme C-terminus. Analogous features were found in the C-terminal sequences of an extended family of haemolysins, leukotoxins and proteases which are secreted by HlyB/HlyD-type translocators. In particular, all nine proteins which are secreted into the extracellular medium possess potential extended amphipathic helices. These results suggest a possible role for multiple regions of the HlyA C-terminal export signal in which the first two domains span the membranes and the third domain remains in the cytoplasm.

Superoxide generation by human neutrophils induced by low doses of Escherichia coli hemolysin

Escherichia coli hemolysin (Hly) was isolated from bacterial culture supernatants by polyethylene glycol precipitation and centrifugation in glycerol density gradients. The toxin preparations contained less than 1 mol of lipopolysaccharide per 10 mol of protein, and they had no fatty acids. The capacity of purified hemolysin to stimulate superoxide anion production in polymorphonuclear leukocytes was monitored kinetically in a lumimeter by using the lucigenin assay and was correlated with the kinetics of transmembrane pore formation. When applied to leukocytes suspended in protein-free buffer, very low concentrations (0.02 to 0.1 HU/ml) of the toxin strongly stimulated the production of superoxide anions; shortly thereafter, irreversible membrane permeabilization occurred. When the toxin was applied at concentrations exceeding 0.2 to 0.3 HU/ml, membrane permeabilization was so rapid that the cells were unable to mount a respiratory burst. When applied in the narrow range of 0.05 to 0.1 HU/ml, E. coli hemolysin rivaled phorbol myristate acetate in its capacity to stimulate production of superoxide anions. Additionally, hemolysin applied at doses that elicited no pore formation (0.01 to 0.02 HU/ml) primed leukocytes for an augmented response to subsequent challenge by the phorbol ester. These data demonstrate that very low doses of E. coli hemolysin can evoke cellular reactions that appear independent of and precede transmembrane pore formation and cell death.

Evidence for insertion sequence-mediated spread of the thermostable direct hemolysin gene among Vibrio species

The tdh gene of Vibrio parahaemolyticus which encodes the thermostable direct hemolysin has been found in some strains of other Vibrio species. Analysis of seven tdh genes cloned from V. parahaemolyticus, Vibrio mimicus, and non-O1 Vibrio cholerae revealed that all tdh genes were flanked by insertion sequence-like elements (collectively named ISVs) or related sequences derived from genetic rearrangement of ISVs. The ISVs possessed 18-bp terminal inverted repeats highly homologous to those of IS903 (2- to 4-bp mismatch) and were 881 to 1,058 bp long with less than 33.6% sequence divergence. These features and nucleotide sequence similarities among ISVs and IS903 (overall homologies between ISVs and IS903, ca. 50%) strongly suggest that they were derived from a common ancestral sequence. A family of ISVs were widely distributed in Vibrio species, often regardless of the possession of the tdh genes, and one to several copies of the ISVs per organism were detected. A strain of V. mimicus possessed two copies of the ISVs flanking the tdh gene and three copies unrelated to the tdh gene. However, the transposition activity of the ISVs could not be demonstrated, probably because they had suffered from base changes and insertions and deletions within the transposase gene. The possible mode of ISV-mediated spread of the tdh gene is discussed from an evolutionary standpoint.

Closely linked genetic loci required for swarm cell differentiation and multicellular migration by Proteus mirabilis

The pathogenic bacterium Proteus mirabilis exhibits a form of multicellular behaviour called swarming migration. This involves the differentiation of vegetative cells at the colony margin into swarm cells which are long, aseptate, multinucleate, hyper-flagellated filaments able to undergo repeated cycles of co-ordinated population migration and consolidation (reversion to vegetative cells). Transposon mutagenesis of uropathogenic P. mirabilis strain U6450 with Tn5 generated 4860 chromosomal insertions and, of these, 75 (1.6%) caused visibly abnormal swarming behaviour, indicating that at least 45 genes are involved in directing motility, cell differentiation and multicellular behaviour. While about one fifth of the swarm-defective mutants lacked flagella and were non-motile non-swarming (NMNS) the majority were normally flagellated and motile but were unable to form swarm cells (motile non-swarming, MNS), or were motile and able to form swarm cells but displayed aberrant patterns of multicellular migration (dendritic swarming, DS) or consolidation (frequent and infrequent consolidation, FC and IC). Restriction enzyme mapping of representative mutant DNAs by Southern hybridization with transposon DNA probes identified eight different mutated genetic loci within the five phenotypic classes. Subsequent Southern analysis of large restriction fragments separated by pulsed-field electrophoresis showed that these eight mutated loci required for motility, cell differentiation and multicellular migration were clustered on a region of DNA spanning approximately 8% of the 4.2 mbp P. mirabilis chromosome. Further linkage analysis showed that the DS locus involved in the ordered migration of the swarm cell population mapped separately from two main clusters of swarm loci, one cluster containing, within 112 kbp, genetic determinants of motility (NMNS) and also differentiation into swarm cells (MNS1, MNS2), and a second within a neighbouring 95 kbp DNA sequence containing three loci involved in the control of consolidation (FC, IC1, IC2).

Structure and function of the B and D genes of the Actinobacillus actinomycetemcomitans leukotoxin complex

The Actinobacillus actinomycetemcomitans leukotoxin gene complex, consisting of four genes, has been cloned and the sequence of the AaLtC and AaLtA genes reported. The present paper details the sequences of the AaLtB and AaLtD genes which, like AaLtC and AaLTA, are also homologues of genes found in other cytolytic toxin complexes of several other Gram-negative bacterial pathogens. When tested in a recombinant expression system, the AaLtB and/or AaLtD genes are required for the translocation and insertion of the A. actinomycetemcomitans leukotoxin (AaLtA) into the cell membrane of Escherichia coli.

The Actinobacillus pleuropneumoniae hemolysin determinant: unlinked appCA and appBD loci flanked by pseudogenes

The appBD genes encoding the secretion functions for the 110-kDa RTX hemolysin of Actinobacillus pleuropneumoniae have been cloned and sequenced. Unlike analogous genes from other RTX determinants, the appBD genes do not lie immediately downstream from the hemolysin structural gene, appA. Although isolated from a diverse group of gram-negative organisms, the appBD genes and the characterized RTX BD genes from other organisms all exhibit a high degree of homology at both the DNA and predicted amino acid sequence levels. Analysis of the DNA sequences 3' to appA and 5' to appB suggests that these regions harbor remnant RTX B and A pseudogenes, respectively. Although the appA gene is most similar to the lktA gene from Pasteurella haemolytica (Y. F. Chang, R. Young, and D. K. Struck, DNA 8:635-647, 1989), the RTX A pseudogene upstream from appB most closely resembles the hlyB gene from Escherichia coli, suggesting that the appCA and appBD operons were derived from different ancestral RTX determinants.

In vitro activation of Escherichia coli prohaemolysin to the mature membrane-targeted toxin requires HlyC and a low molecular-weight cytosolic polypeptide

The c. 110 kDa haemolysin toxin secreted by Escherichia coli and other pathogenic Gram-negative bacteria is synthesized as the non-toxic precursor, prohaemolysin (proHlyA), which is unable to target mammalian cell membranes until activated intracellularly by an unknown mechanism dependent upon the coexpressed c. 20 kDa protein, HlyC. We have established in vitro post-translational activation of proHlyA in membrane-depleted cell extract fractions from E. coli recombinant strains containing (separately) the proHlyA and HlyC proteins. In vitro activation was calcium-independent and effective over a pH range of 6 to 9 and at temperatures from 42 degrees C to 4 degrees C. HlyC cell extract was also able to activate proHlyA which had been secreted out of cells containing the export proteins HlyB and HlyD. Fractionation of HlyC cell extracts by sucrose gradient centrifugation and molecular weight chromatography revealed activating fractions as having a molecular mass of 40 kDa, suggesting that the HlyC activator is present physiologically in a multimeric form. Cell extracts containing activation-competent HlyC and proHlyA were inactive following dialysis, but activity was restored by complementation with a cell extract lacking both proteins. HlyC and proHlyA proteins which were overproduced separately from recombinant expression plasmids were inactive following purification, but activity could again be restored with a Hly-negative cell extract. These experiments demonstrated that HlyC is not sufficient for activation; an additional cellular factor is required. The cellular factor was found in enterobacteria but not other bacteria or eukaryotic cells. It was cytosolic, protease-sensitive, and behaved as a c. 10 kDa polypeptide in a number of assays including dialysis, sucrose gradient centrifugation, and gel filtration chromatography. Thus activation was possible in a defined in vitro reaction containing only purified proHlyA, HlyC, and the cellular factor. Kinetic studies in which the relative concentrations of the three components of proHlyA activation were varied suggested that neither HlyC nor the cellular factor acts as a conventional enzyme, with each participating in a finite number of activation events.

Activation of Escherichia coli prohaemolysin to the mature toxin by acyl carrier protein-dependent fatty acylation

Haemolysin secreted by pathogenic Escherichia coli binds to mammalian cell membranes, disrupting cellular activities and lysing cells by pore-formation. It is synthesized as nontoxic prohaemolysin (proHlyA), which is activated intracellularly by a mechanism dependent on the cosynthesized HlyC. Haemolysin is one of a family of membrane-targeted toxins, including the leukotoxins of Pasteurella and Actinobacillus and the bifunctional adenylate cyclase haemolysin of Bordetella pertussis, which require this protoxin activation 1-5. HlyC alone cannot activate proHlyA, but requires a cytosolic activating factor6. Here we report the cytosolic activating factor is identical to the acyl carrier protein and that activation to mature toxin is achieved by the transfer of a fatty acyl group from acyl carrier protein to proHlyA. Only acyl carrier protein, not acyl-CoA, can promote HlyC-directed proHlyA acylation, but a range of acyl groups are effective.

Hemolytic activity in the periodontopathogen Porphyromonas gingivalis: kinetics of enzyme release and localization

Porphyromonas gingivalis W50, W83, A7A1-28, and ATCC 33277 were investigated for their abilities to lyse sheep, human, and rabbit erythrocytes. All of the P. gingivalis strains studied produced an active hemolytic activity during growth, with maximum activity occurring in late-exponential-early-stationary growth phase. The enzyme was cell bound and associated with the outer membrane. Fractionation of P. gingivalis W50 localized the putative hemolysin almost exclusively in the outer membrane fraction, with significant hemolytic activity concentrated in the outer membrane vesicles. Ca2+ and Mg2+ ions significantly increased the expression of hemolytic activity. Hemolytic activity was inhibited by proteinase K, trypsin, the proteinase inhibitors Na-P-tosyl-L-lysine chloromethyl ketone and benzamidine, the metabolic inhibitor M-chlorophenyl-hydrazone, and iodoacetate. KCN and sodium azide (NaN3) only partially inhibited P. gingivalis hemolytic activity, while antiserum to whole cells of each of the P. gingivalis strains had a significant inhibitory effect on hemolytic activity. The P. gingivalis W50 hemolysin was inhibited by cysteine, dithiothreitol, and glutathione at concentrations of at least 10 mM; at low concentrations (i.e., 2 mM), dithiothreitol did not completely inhibit hemolytic activity. Heating to temperatures above 55 degrees C resulted in an almost complete inhibition of hemolytic activity. The effect of heme limitation (i.e., iron) on hemolysin production indicated that either limitation or starvation for heme resulted in significantly increased hemolysin production compared with that of P. gingivalis grown in the presence of excess heme.

Cloning and expression in Escherichia coli of the Serratia marcescens metalloprotease gene: secretion of the protease from E. coli in the presence of the Erwinia chrysanthemi protease secretion functions

The Serratia marcescens extracellular protease SM is secreted by a signal peptide-independent pathway. When the prtSM gene was cloned and expressed in Escherichia coli, the cells did not secrete protease SM. The lack of secretion could be very efficiently complemented by the Erwinia chrysanthemi protease B secretion apparatus constituted by the PrtD, PrtE, and PrtF proteins. As with protease B and alpha-hemolysin, the secretion signal was located within the last 80 amino acids of the protease. These results indicate that the mechanism of S. marcescens protease SM secretion is analogous to the mechanisms of protease B and hemolysin secretion.

Mutations affecting pore formation by haemolysin from Escherichia coli

By introduction of site-specific deletions, three regions in HlyA were identified, which appear to be involved in pore formation by Escherichia coli haemolysin. Deletion of amino acids 9-37 at the N-terminus led to a haemolysin which had an almost threefold higher specific activity than wild-type and formed pores in an artificial asolectin lipid bilayer with a much longer lifetime than those produced by wild-type haemolysin. The three hydrophobic regions (DI-DIII) located between amino acids 238-410 contributed to pore formation to different extents. Deletion of DI led to a mutant haemolysin which was only slightly active on erythrocyte membranes and increased conductivity of asolectin bilayers without forming defined pores. Deletions in the two other hydrophobic regions (DII and DIII) completely abolished the pore-forming activity of the mutant haemolysin. The only polar amino acid in DI, Asp, was shown to be essential for pore formation. Removal of this residue led to a haemolysin with a considerably reduced capacity to form pores, while replacement of Asp by Glu or Asn had little effect on pore formation. A deletion mutant which retained all three hydrophobic domains but had lost amino acids 498-830 was entirely inactive in pore formation, whereas a shorter deletion from amino acids 670-830 led to a mutant haemolysin which formed abnormal minipores. The conductivity of these pores was drastically reduced compared to pores introduced into an asolectin bilayer by wild-type haemolysin. Based on these data and structural predictions, a model for the pore-forming structure of E. coli haemolysin is proposed.

Characterization of cell-bound and cell-free hemolytic activity of Proteus strains

The relationship between growth condition and production of cell-bound hemolysin by Proteus mirabilis S1959 strain was investigated. Hemolytic activity was not dependent on type of medium, oxygen accessibility and was inhibited in presence of N-ethylmaleimide, different sera or trypsine. Cell-free hemolysin was released to the medium during stationary-death phases of growth of fluid Proteus mirabilis and vulgaris cultures.

Secretion of hybrid proteins by the Yersinia Yop export system

After incubation at 37 degrees C in the absence of Ca2+ ions, pathogenic strains of Yersinia spp. release large amounts of a set of plasmid-encoded proteins called Yops. The secretion of these proteins, involved in pathogenicity, occurs via a mechanism that involves neither the removal of a signal sequence nor the recognition of a C-terminal domain. Analysis of deletion mutants allowed the secretion recognition domain to be localized within the 48 N-terminal amino acids of protein YopH, within the 98 N-terminal residues of protein YopE, and within the 76 N-terminal residues of YopQ. Comparison of these regions failed to reveal any sequence similarity, suggesting that the secretion signal of Yop proteins is conformational rather than sequential. Hybrid proteins containing the amino-terminal part of YopH fused to either the alpha-peptide of beta-galactosidase or to alkaline phosphatase deprived of its signal sequence were efficiently secreted to the Yersinia culture medium. This observation opens new prospects in using Yersinia spp. as chimeric-protein producers and as potential live carriers for foreign antigens.

Pore-forming cytolysins of gram-negative bacteria

A great deal is known about the structure, function and metabolic effects of enzymatic bacterial toxins such as the diphtheria, pertussis and cholera toxins. By comparison, our understanding of the pore-forming, cytolytic toxins, particularly those produced by Gram-negative bacterial pathogens, is far less complete. The genetics and biochemistry of a large, newly discovered family of calcium-dependent, pore-forming cytotoxins (RTX toxins) produced by different genera of the Enterobacteriaceae and Pasteurellaceae are discussed in this review. This toxin family is especially noteworthy because the individual toxins often exhibit different cell- and host-specificity. A brief review is also included of two ancestrally unrelated groups of calcium-independent, pore-forming toxins, the haemolysins produced by Proteus mirabilis and Serratia marcescens and the aerolysins secreted by species of Aeromonas. Their structure and function are contrasted with those of the RTX family members. Emerging questions about the role of cytolysins in pathogenesis are presented. Perhaps the most important issue raised is whether or not less attention should be paid to the lytic capacity of these cytotoxins, with more energy being devoted to the understanding of their non-lytic inhibitory activities against host cells.

The secretion genes of Pseudomonas aeruginosa alkaline protease are functionally related to those of Erwinia chrysanthemi proteases and Escherichia coli alpha-haemolysin

The extracellular alkaline protease produced by Pseudomonas aeruginosa is secreted by a specific pathway, independent of the pathway used by most of the other extracellular proteins of this organism. Secretion of this protease is dependent on the presence of several genes located adjacent to the apr gene. Complementation studies have shown that PrtD, E, and F, the three secretion functions for Erwinia chrysanthemi proteases B and C (Létoffé et al., 1990), can mediate the secretion of the alkaline protease by Escherichia coli. The secretion functions involved in alpha-haemolysin secretion in E. coli (hlyB, hlyD, tolC) can also be used to complement alkaline protease secretion by E. coli, although less efficiently. These data indicate that protease secretion mechanisms in Pseudomonas and Erwinia are very similar and are homologous to that of E. coli alpha-haemolysin.

Mutagenesis and isolation of Aeromonas hydrophila genes which are required for extracellular secretion

Transposon mutagenesis was used to isolate mutants of Aeromonas hydrophila which were deficient in the production of extracellular proteins. The culture supernatants of two of the mutants were essentially devoid of the proteins normally secreted by the parent strain, despite their continued synthesis. Western immunoblot analysis of one of these proteins indicated that normal signal sequence processing occurred but that normal zymogen activation did not, and cell fractionation experiments indicated that both mutants accumulated the three different extracellular proteins assayed in a position external to the cytoplasmic membrane, presumably in the periplasm. The two mutants differed, however, in that one was lysed during the osmotic shock procedures and also contained severely reduced amounts of two of the major protein components of the outer membrane. The wild-type chromosomal regions into which the transposon had been inserted in the two mutants were cloned. In each case, transconjugants of the mutants containing the corresponding cloned fragment were complemented for the defects in secretion, and one of the mutants was complemented by the heterologous clone as well, suggesting the possibility of an interaction between these two genes or gene products. These results indicate that two separate functions which are required for extracellular secretion were interrupted in the insertion mutants and that one of these is also critically important in the biogenesis of the outer membrane.

Pore-forming bacterial protein hemolysins (cytolysins)

Protein toxins forming pores in biological membranes occur frequently in Gram-positive and Gram-negative bacteria. They kill either bacteria or eukaryotic cells (at most, a few seem to act on both groups of organisms). Most of the toxins affecting eukaryotes have clearly been shown to be related to the pathogenicity of the producing organisms. Toxin formation frequently involves a number of genes which encode the toxin polypeptide as well as proteins for toxin activation and secretion. Regulation of toxin production is usually coupled with that of the synthesis of a number of other virulence factors. Iron is the only known environmental factor that regulates transcription of a number of toxin genes by a Fur repressor-type mechanism, as has been originally described in Escherichia coli. Interestingly, the thiol-activated hemolysins (cytolysins) of Gram-positive bacteria contain a single cysteine which can be replaced by alanine without affecting the cytolytic activity. The Gram-negative hemolysins (cytolysins) are usually synthesized as precursor proteins, then covalently modified to yield an active hemolysin and secreted via specific export systems, which differ for various types of hemolysins.

Virulence factors in Escherichia coli urinary tract infection

Uropathogenic strains of Escherichia coli are characterized by the expression of distinctive bacterial properties, products, or structures referred to as virulence factors because they help the organism overcome host defenses and colonize or invade the urinary tract. Virulence factors of recognized importance in the pathogenesis of urinary tract infection (UTI) include adhesins (P fimbriae, certain other mannose-resistant adhesins, and type 1 fimbriae), the aerobactin system, hemolysin, K capsule, and resistance to serum killing. This review summarizes the virtual explosion of information regarding the epidemiology, biochemistry, mechanisms of action, and genetic basis of these urovirulence factors that has occurred in the past decade and identifies areas in need of further study. Virulence factor expression is more common among certain genetically related groups of E. coli which constitute virulent clones within the larger E. coli population. In general, the more virulence factors a strain expresses, the more severe an infection it is able to cause. Certain virulence factors specifically favor the development of pyelonephritis, others favor cystitis, and others favor asymptomatic bacteriuria. The currently defined virulence factors clearly contribute to the virulence of wild-type strains but are usually insufficient in themselves to transform an avirulent organism into a pathogen, demonstrating that other as-yet-undefined virulence properties await discovery. Virulence factor testing is a useful epidemiological and research tool but as yet has no defined clinical role. Immunological and biochemical anti-virulence factor interventions are effective in animal models of UTI and hold promise for the prevention of UTI in humans.

Protein secretion in Pseudomonas aeruginosa: the xcpA gene encodes an integral inner membrane protein homologous to Klebsiella pneumoniae secretion function protein PulO

xcp mutations have pleiotropic effects on the secretion of proteins in Pseudomonas aeruginosa PAO. The nucleotide sequence of a 1.2-kb DNA fragment that complements the xcp-1 mutation has been determined. Sequence analysis shows the xcpA gene product to be a 31.8-kDa polypeptide, with a highly hydrophobic character. This is consistent with a localization in the cytoplasmic membrane in P. aeruginosa, determined after specific expression of the xcpA gene under control of the T7 phi 10 promoter. A very strong homology was found between XcpA and PulO, a membrane protein required for pullulanase secretion in Klebsiella pneumoniae. This suggests the existence of a signal sequence-dependent secretion process common to these two unrelated gram-negative bacteria.

Genetic transformation in Streptococcus pneumoniae: nucleotide sequence analysis shows comA, a gene required for competence induction, to be a member of the bacterial ATP-dependent transport protein family

The complete nucleotide sequence of comA, a gene required for induction of competence for genetic transformation in Streptococcus pneumoniae, was determined by using plasmid DNA templates and synthetic oligonucleotide primers. The sequence contained a single large open reading frame, ORF1, of 2,151 bp. ORF1 was included within the comAB locus previously mapped genetically and accounted for 50% of its extent. The predicted molecular weight of the largest polypeptide encoded within ORF1, 80,290, coincided with that measured previously (77,000) for the product of in vitro transcription-translation of the cloned comA locus. A Shine-Dalgarno sequence (AAAGGAG, delta G = -14 kcal) lay immediately upstream of ORF1. A sequence (TTtAat-17 bp-TAaAAT) similar to the Escherichia coli sigma 70 promoter consensus was located 410 bp upstream of ORF1. The deduced protein sequence of ComA showed a very strong similarity to the E. coli hemolysin secretion protein, HlyB, and strong similarities to other members of the family of ATP-dependent transport proteins, including the mammalian multidrug resistance P-glycoprotein. These similarities suggest that ComA functions in the transport of some molecule, possibly pneumococcal competence factor itself.

An HlyB-type function is required for expression of the Enterococcus faecalis hemolysin/bacteriocin

The nucleotide sequence of a 3,422-bp internal restriction fragment from the Enterococcus faecalis pAD1 hemolysin/bacteriocin-encoding region was determined. This fragment was associated with expression of hemolysin/bacteriocin component L and contained a 2,142-bp open reading frame. The inferred amino acid sequence revealed a protein which shared extensive similarity with HlyB of the Escherichia coli alpha-hemolysin operon. The inferred protein, CylB, was observed to be independently expressed in E. coli and capable of complementing an insertion mutation in the cloned hemolysin/bacteriocin operon in trans. Despite the extensive similarity to HlyB, CylB was incapable of complementing an insertion mutation in hlyB. Cytolysin determinants possessing an HlyB-type transport function are widely dispersed throughout gram-negative genera. We believe this to be the first example of an HlyB-type protein encoded within a cytolysin determinant from a gram-positive bacterium.

Effects of Escherichia coli hemolysin on endothelial cell function

Escherichia coli hemolysin is considered an important virulence factor in extraintestinal E. coli infections. The present study demonstrates that cultured pulmonary artery endothelial cells are susceptible to attack by low concentrations of E. coli hemolysin (greater than or equal to 0.05 hemolytic units/ml; greater than or equal to 5 ng/ml). Sublytic amounts of hemolysin increased the permeability of endothelial cell monolayers in a time- and dose-dependent manner. The hydraulic conductivity increased approximately 30-fold and the reflection coefficient for large molecules dropped from 0.71 to less than 0.05, indicating a toxin-induced loss of endothelial barrier function. The alterations of endothelial monolayer permeability were accompanied by cell retraction and interendothelial gap formation. In addition, E. coli hemolysin stimulated prostacyclin synthesis in endothelial cells. This effect was strictly dependent on the presence of extracellular Ca2+ but not of Mg2+. An enhanced passive influx of 45Ca2+ and 3H-sucrose but not of tritiated inulin and dextran was noted in toxin-treated cells, indicating that small transmembrane pores comparable to those detected in rabbit erythrocytes had been generated in endothelial cell membranes. These pores may act as nonphysiologic Ca2+ gates, thereby initiating different Ca2+-dependent cellular processes. We conclude that endothelial cells are highly susceptible to E. coli hemolysin and that two major endothelial cell functions are altered by very low concentrations of hemolysin.

Deletions affecting hemolytic and toxin activities of Bordetella pertussis adenylate cyclase

The Bordetella pertussis cyaA gene encodes a virulence factor which is a bifunctional protein exhibiting calmodulin-sensitive adenylate cyclase and hemolytic activities (P. Glaser, H. Sakamoto, J. Bellahov, A. Ullmann, and A. Danchin, EMBO J. 7:3997-4004, 1988). We characterized the hemolytic and toxin activities of the 200-kilodalton (kDa) bifunctional (CyaA) protein and showed that, whether cell associated or secreted, the 200-kDa CyaA protein carries hemolytic and toxin functions. The catalytically active 45-kDa form of adenylate cyclase released by proteolytic digestion of the 200-kDa CyaA protein displayed neither hemolytic nor toxin activities. We constructed in-phase deletions in the 3' region of the cyaA gene, which presumably carries the hemolytic determinant, and showed that the resulting proteins exhibited wild-type adenylate cyclase activity and were secreted without processing into culture supernatants. The hemolytic activities of these mutant CyaA proteins were severely reduced, and their toxin activities were abolished. These results suggest that the structural integrity of the 200-kDa CyaA protein is necessary for toxin activity and that distinct structural determinants within the CyaA protein are involved in secretion, pore formation, and entry into target cells.

Inflammatory lipid mediator generation elicited by viable hemolysin-forming Escherichia coli in lung vasculature

Escherichia coli hemolysin, a transmembrane pore-forming exotoxin, is considered an important virulence factor for E. coli-related extraintestinal infections and sepsis. The possible significance of hemolysin liberation for induction of inflammatory lipid mediators was investigated in isolated rabbit lungs infused with viable bacteria (concentration range, 10(4)-10(7)/ml). Hemolysin-secreting E. coli (E. coli-Hly+), but not an E. coli strain that releases an inactive form of the exotoxin, induced marked lung leukotriene (LT) generation with predominance of cysteinyl LTs. Eicosanoid synthesis was not inhibited in the presence of plasma with toxin-neutralizing capacity. Pre-application of 2 x 10(8) human granulocytes, which sequestered in the lung microvasculature, caused a severalfold increase in leukotriene generation in response to E. coli-Hly+ challenge both in the absence and presence of plasma. Data are presented indicating neutrophil-endothelial cell cooperation in arachidonic acid lipoxygenase metabolism as an underlying mechanism. We conclude that liberation of hemolysin from viable E. coli induces marked lipid mediator generation in lung vasculature, which is potentiated in the presence of neutrophil sequestration and may contribute to microcirculatory disturbances during the course of severe infections.

In vitro cytotoxic effect of alpha-hemolytic Escherichia coli on human blood granulocytes. Inhibition by alpha-hemolysin antibody

The influence of alpha-hemolysin antibody on the in vitro cytotoxic effect of alpha-hemolytic Escherichia coli bacteria and culture filtrates was investigated. Damage to human blood granulocytes was quantified by measuring the release of chromium 51 from labelled cells in the presence of whole or fractionated plasma containing alpha-hemolysin antibody. Anti-alpha-hemolysin activity was found exclusively in the IgG fraction of plasma. Human plasma contained "natural" alpha-hemolysin antibody to various titers. Vaccination of rabbits resulted in only modest rises in alpha-hemolysin antibody titers. The cytotoxic effect of alpha-hemolytic E. coli bacteria as well as that of bacterial culture filtrates was reduced in a titer-dependent way in the presence of plasma containing alpha-hemolysin antibody. These results indicate that the cytotoxic effect of alpha-hemolytic E. coli is inhibited by alpha-hemolysin antibody.

Hemolysin as a marker for Serratia

All Serratia marcescens strains (total of 33) of different sources were hemolytic including clinical strains previously classified as being nonhemolytic. DNA fragments of the two hemolysin genes hybridized with the chromosomal DNA of S. marcescens, S. liquefaciens, S. kiliensis, S. grimesii, S. proteamaculans, S. plymutica, S. rubridaea which were also hemolytic. The restriction pattern of the hemolysin locus differed in each strain. S. ficaria and S. marinorubra expressed a different hemolysin which was much smaller than the S. marcescens hemolysin since it diffused through dialysis membranes. The DNA of the latter strains did not hybridize with the S. marcescens hemolysin DNA probes. Some S. marcescens strains, S. kiliensis and S. liquefaciens also expressed in addition the small hemolysin. No hybridization was found with DNA of Escherichia coli, Salmonella typhimurium, Proteus mirabilis, Proteus vulgaris, Citrobacter freundii, Enterobacter cloacae, Klebsiella arerogenes, Klebsiella pneumoniae, Shigella dysenteriae, Yersinia enterocolitica, Yersinia pseudotuberculosus, Listeria sp., Aeromonas sp., Legionella sp. and a Meninococcus sp., indicating that the hemolysin DNA probes are specific for Serratia, or that the hemolysin genes occur rarely in genera other than Serratia.

The HpmA hemolysin is more common than HlyA among Proteus isolates

Two different hemolysins, HpmA and HlyA, have been reported in Proteus spp. To study the distribution of these hemolysins among Proteus strains, isolates from various infections and normal feces were screened for hemolysin production. All 63 Proteus mirabilis strains and 23 of the 24 Proteus vulgaris strains produced a calcium-independent hemolytic activity detectable in cell-free supernatants. The calcium-independent activity was due to HpmA; this activity correlated with the presence of hpmA sequences and the production of an extracellular 166-kilodalton (kDa) protein that reacted with anti-HpmA antiserum. HpmA- mutants, constructed by deletion of the central portion of the hpmA gene, did not produce the 166-kDa protein and were no longer hemolytic when compared with their respective parent strains. Among the 87 P. mirabilis and P. vulgaris isolates examined, calcium-dependent hemolytic activity was produced by only two P. vulgaris strains. These strains produced a 110-kDa protein which comigrated with the Escherichia coli hemolysin (HlyA) antibodies in immunoblots. These studies show that Proteus spp. produce two distinct extracellular hemolysins, with nearly all strains producing the calcium-independent hemolysin, HpmA, but only an occasional P. vulgaris isolate producing HlyA.

Domains of Escherichia coli hemolysin (HlyA) involved in binding of calcium and erythrocyte membranes

The primary structure of Escherichia coli hemolysin (HlyA) contains a 9-amino-acid sequence which is tandemly repeated 13 times near the C terminus and which is essential for hemolytic activity. Hemolysin also requires an unknown modification by an accessory protein, HlyC, for hemolytic activity. The role of calcium in the interaction of HlyA with erythrocytes was investigated by using recombinant strains which produced inactive hemolysins unmodified by HlyC or deleted of the repeat sequences. 45Ca2+ autoradiography of the recombinant hemolysins separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transferred to nitrocellulose showed that full-length, active hemolysin bound calcium. The domain involved in binding calcium was identified as the tandemly repeated sequences, since the deletion derivative missing 11 of the 13 repeats did not bind calcium. Inactive hemolysin, unmodified by HlyC, contained the repeated sequences and bound calcium as efficiently as the active, full-length toxin. The binding of the inactive toxins to erythrocytes was investigated by immunoblotting saline-washed, toxin-treated cells with monoclonal antibodies after sodium dodecyl sulfate-polyacrylamide gel electrophoresis separation of membrane proteins. The binding of full-length, active hemolysin to erythrocytes was calcium dependent. Inactive hemolysin deleted of the repeat units did not bind to cells. The inactive hemolysin, unmodified by HlyC, bound calcium but did not bind to erythrocytes. These results highlight the importance of calcium in the binding of hemolysin to erythrocytes and suggest that the binding of hemolysin to cells requires an interaction between the calcium-binding repeat domain and the modification produced by the HlyC protein.

Effects of Escherichia coli hemolysin on human monocytes. Cytocidal action and stimulation of interleukin 1 release

This study reports on the potent cytocidal and interleukin-1 releasing properties of Escherichia coli hemolysin (ECH) on human monocytes. Nanomolar concentrations of purified ECH (250-2,000 ng/ml) caused rapid and irreversible depletion of cellular ATP to levels below 20% of controls within 60 min. Subcytocidal doses (10-200 ng/ml) of ECH induced rapid release within 60-120 min of large amounts of interleukin 1 beta (IL-1 beta) from cultured monocytes. IL-1 beta release occurred in the presence of actinomycin D and cycloheximide, and was thus probably due to processing and export of intracellular IL-1 beta precursor. Incubation of toxin-producing E. coli at ratios of only 0.3-3 colony-forming units per monocyte evoked approximately 50% depletion of total cellular ATP within 90 min. Toxin producers also stimulated synthesis and release of large amounts of interleukin 1, but not of tumor necrosis factor within the same time span. In contrast, non-toxin producers caused neither cell death nor rapid interleukin 1 release. Stimulation of rapid interleukin 1 release coupled with potent cytocidal effects on cells of monocytic origin may represent pathogenetically significant events incurred by bacterial strains that produce ECH and related cytolysins.

Cytotoxic activity of the Proteus hemolysin HpmA

We previously showed that hpmA is the hemolysin determinant most commonly found among Proteus isolates. To assess the potential contribution of HpmA to virulence, we first characterized the toxic activities of this hemolysin. Hemolytic activity was present in total cell cultures and cell-free supernatants of Proteus clinical isolates as well as Escherichia coli containing cloned hpm genes. HpmA also possesses cytotoxic activity which was detected by a chromium release assay against a variety of target cell lines (Daudi, Raji, T24, U937, and Vero). Analysis of the dose response of bacterial cells against both T24 cells and erythrocytes showed that E. coli containing cloned hpm genes was 30-fold more cytotoxic than Proteus mirabilis BA6163. Also, 10(5)-fold more bacterial cells were needed to lyse T24 cells than to lyse erythrocytes. HpmA- mutants of two Proteus strains in which the central portion of hpmA was deleted were constructed. These HpmA- mutants, which have lost the hemolytic and cytotoxic activities exhibited by their respective parent strains, demonstrate that HpmA is needed for both of these activities. In an ascending model of murine urinary tract infection, the hpmA mutant strain WPM111 behaved no differently from its parent strain, BA6163, with respect to either the level of kidney colonization or histopathological changes in the kidney. However, WPM111 had a sixfold higher 50% lethal dose than BA6163 when injected intravenously into C3H mice.

Secretion and expression of the Pasteurella haemolytica Leukotoxin

The Pasteurella haemolytica leukotoxin gene cluster (lktCABD) is homologous to the Escherichia coli hemolysin locus (hlyCABD). Since the cloned leukotoxin (LktA) is not secreted from E. coli cells, a heteroplasmid complementation system was developed that permits secretion of the leukotoxin from cells expressing the hemolysin transport proteins HlyB and HlyD. We observed that the secreted leukotoxin protein had weak hemolytic activity when activated by either the HlyC or LktC proteins and that LktC expressed in E. coli could confer weak hemolytic activity upon hemolysin. Thus, it appears that the accessory proteins of the leukotoxin and hemolysin gene clusters are functionally similar, although their expression in E. coli is not equivalent. Northern (RNA) blot analysis of the P. haemolytica leukotoxin gene cluster revealed a major 3.5-kilobase transcript that includes the lktC and lktA genes. The start site for this transcript mapped to a cytosine residue 30 nucleotides upstream from the putative start of lktC; a similar initiation site was observed in E. coli, although adjacent cytosine and adenine residues were also utilized. The 3.5-kilobase transcript terminated near the rho-independent terminator structure between lktA and lktB, but transcription may continue, via antitermination or de novo transcription initiation, into the downstream lktB and lktD genes. We propose that the lack of LktB and LktD function in E. coli is a result, at least in part, of poor lktBD transcription and suggest that a P. haemolytica-specific regulator is required for optimal expression of the leukotoxin genes.

A role for pore-forming proteins in the pathogenesis by parasites?

Over the past decade or so, pore-forming proteins (PFPs) have been isolated from various immune cells and nonpathogenic bacteria. It is now becoming apparent that PFPs may also be produced by a number of parasites. Although far from definitive, the evidence currently available for the role of PFPs in the survival and pathogenesis by parasites in briefly presented by David Ojcius and John Ding-E Young.

Nucleotide sequencing of the Proteus mirabilis calcium-independent hemolysin genes (hpmA and hpmB) reveals sequence similarity with the Serratia marcescens hemolysin genes (shlA and shlB)

We cloned a 13.5-kilobase EcoRI fragment containing the calcium-independent hemolysin determinant (pWPM110) from a clinical isolate of Proteus mirabilis (477-12). The DNA sequence of a 7,191-base-pair region of pWPM110 was determined. Two polypeptides are encoded in this region, HpmB and HpmA (in that transcriptional order), with predicted molecular masses of 63,204 and 165,868 daltons, respectively. A putative Fur-binding site was identified upstream of hpmB overlapping the -35 region of the proposed hpm promoter. In vitro transcription-translation of pWPM110 DNA and other subclones confirmed the assignment of molecular masses for the predicted polypeptides. These polypeptides are predicted to have NH2-terminal leader peptides of 17 and 29 amino acids, respectively. NH2-terminal amino acid sequence analysis of purified extracellular hemolysin (HpmA) confirmed the cleavage of the 29-amino-acid leader peptide in the secreted form of HpmA. Hemolysis assays and immunoblot analysis of Escherichia coli containing subclones expressing hpmA, hpmB, or both indicated that HpmB is necessary for the extracellular secretion and activation of HpmA. Significant nucleotide identity (52.1%) was seen between hpm and the shl hemolysin gene sequences of Serratia marcescens despite differences in the G+C contents of these genes (hpm, 38%; shl, 65%). The predicted amino acid sequences of HpmB and HpmA are also similar to those of ShlB and ShlA, the respective sequence identities being 55.4 and 46.7%. Predicted cysteine residues and major hydrophobic and amphipathic domains have been strongly conserved in both proteins. Thus, we have identified a new hemolysin gene family among gram-negative opportunistic pathogens.

Characterization of monoclonal antibodies against the Escherichia coli hemolysin

Twelve monoclonal antibodies (MAbs) produced against the Escherichia coli hemolysin (HlyA) encoded by the hemolysin recombinant plasmid pWAM04 were studied. HlyA derivatives from recombinant strains with different plasmids encoding HlyA amino-terminal and carboxy-terminal truncates, HlyA in-frame deletions, and HlyA frameshift mutations were used in immunoblots to localize the antigenic determinants for the anti-HlyA MAbs. The mapping of the MAb epitopes was also facilitated by immunoblotting analysis of HlyA polypeptide fragments derived by cyanogen bromide cleavage. The HlyA epitopes for 11 of the MAbs were mapped to relatively small linear regions of the cytolysin ranging from 28 to 160 amino acids. Five of the MAbs (C10, G8, E2, B7, and D12) neutralized HlyA hemolytic activity to varying degrees. The epitopes for these neutralizing MAbs were found to reside within the following HlyA regions: C10 and G8, amino acids 2 to 160; E2, amino acids 161 to 194; B7, amino acids 518 to 598; and D12, amino acids 626 to 726. Hemolytically active HlyA was dependent on the action of the hlyC gene product. The D12 MAb recognized only HlyA produced by strains with an intact hlyC function. MAb A10 recognized an epitope within the HlyA region from amino acids 728 to 829 where a glycine-rich repeat domain exists; however, this MAb did not neutralize HlyA hemolytic activity. A HlyA domain map showing the anti-HlyA epitope location was constructed.

Nonreciprocal complementation of the hlyC and lktC genes of the Escherichia coli hemolysin and Pasteurella haemolytica leukotoxin determinants

The genetic organization of the Pasteurella haemolytica leukotoxin operon (lktCABD) is similar to that of the Escherichia coli hemolysin (hlyCABD). Their gene products share a sequence similarity of 66, 62, 90.5, and 75.6%, respectively. We investigated the role of the C proteins (LktC and HlyC) by performing reciprocal transcomplementation analyses in an E. coli recombinant background. In the absence of the C genes, neither LktA nor HlyA had their respective cytotoxic activities. When hlyC was provided in trans to lktA, the toxin that was produced had the same activity and target cell specificity as the wild-type leukotoxin; it was leukotoxic for bovine lymphoid cells but not human lymphoblast cells when it was evaluated by a 51Cr-release assay. We also detected a weak hemolytic activity for the active form of LktA against sheep erythrocytes. In contrast, an E. coli strain containing lktC with hlyA produced a form of HlyA which was neither hemolytic nor cytotoxic. A monoclonal antibody (D12) against HlyA which recognized an epitope specific to the active form of HlyA did not cross-react in immunoblots with LktA that was activated by either LktC or HlyC. We conclude that the mechanism for activation of leukotoxin and hemolysin by their respective C proteins (LktC and HlyC) is mechanistically similar but that the exact structural requirements involved in the process are different.

HlyB-dependent secretion of hemolysin by uropathogenic Escherichia coli requires conserved sequences flanking the chromosomal hly determinant

The synthesis and secretion of hemolysin (HlyA) by Escherichia coli are governed by four contiguous genes (hlyCABD) that are closely conserved on plasmids and, among human pathogenic strains, on the chromosome. We have previously shown that in plasmid pHly152 the coexpressed synthesis and export functions are uncoupled by intraoperon transcription termination, which is in turn alleviated by antitermination dictated in cis by a region upstream of the hly operon. In this study we describe an analogous region of ca. 1,100 base pairs flanking the chromosomal hly determinant of the uropathogenic strain E. coli 2001. This region had no significant effect on intracellular levels of hemolysin but activated strongly, both in cis and in trans, the specific hlyB-hlyD-dependent hemolysin secretion function. The secretion-activating region increased the transcription of the secretion gene hlyB, but the transcription effect was not as pronounced as that seen in the pHly152 determinant and was not evident when the region was present in trans to the hemolysin genes, suggesting that, in addition to transcriptional activation, the region may possibly exert a secondary posttranscriptional influence. Southern hybridizations with the 1,100-base pairs secretion-activating sequence showed low identity to plasmid pHly152 and no identity with total DNA from nonhemolytic uropathogenic E. coli or hemolytic isolates of Proteus vulgaris, Proteus mirabilis, and Morganella morganii. In contrast, hybridization to total DNA from hemolytic E. coli isolates belonging to different serotypes showed strong conservation of the activating sequence, indicating that it is an integral component of the chromosomal hly determinant that is widespread among uropathogenic E. coli.

Secretion of the Bordetella pertussis adenylate cyclase from Escherichia coli containing the hemolysin operon

The extracellular calmodulin-sensitive adenylate cyclase produced by Bordetella pertussis is synthesized as a 215-kDa precursor. This polypeptide is transported to the outer membrane of the bacteria where it is proteolytically processed to a 45-kDa catalytic subunit which is released into the culture supernatant [Masure, H.R., & Storm, D.R. (1989) biochemistry 28, 438-442]. The gene encoding this enzyme, cyaA, is part of the cya operon that also includes the genes cyaB, cyaD, and cyaE. A comparison of the predicted amino acid sequences encoded by cyaA, cyaB, and cyaD with the amino acid sequences encoded by hlyA, hlyB, and hlyD genes from the hemolysin (hly) operon from Escherichia coli shows a large degree of sequence similarity [Glaser, P., Sakamoto, H., Bellalou, J., Ullmann, A., & Danchin, A. (1988) EMBO J. 7, 3997-4004]. Complementation studies have shown that HlyB and HlyD are responsible for the secretion of HlyA (hemolysin) from E. coli. The signal sequence responsible for secretion of hemolysin has been shown to reside in its C-terminal 27 amino acids. Similarly, CyaB, CyaD, and CyaE are required for the secretion of CyaA from Bordetella pertussis. We placed the cyaA gene and a truncated cyaA gene that lacks the nucleotides that code for a putative C-terminal secretory signal sequence under the control of the lac promoter in the plasmid pUC-19. These plasmids were transformed into strains of E. coli which contained the hly operon. The truncated cyaA gene product, lacking the putative signal sequence, was not secreted but accumulated inside the cell.(ABSTRACT TRUNCATED AT 250 WORDS)

Isolation of the Actinobacillus pleuropneumoniae haemolysin gene and the activation and secretion of the prohaemolysin by the HlyC, HlyB and HlyD proteins of Escherichia coli

The gene encoding the c. 105 kD secreted haemolysin protein of the porcine pathogen Actinobacillus pleuropneumoniae serotype 1 has been isolated by screening a lambda gt11 expression library in Escherichia coli with antiserum raised against the wild-type protein. A derivative recombinant DNA pJFF702 expressed the hlylA haemolysin gene from the pUC19 lac promoter but the resulting haemolysin I protein remained within the E. coli cell and was haemolytically inactive. Export of the intracellular A. pleuropneumoniae prohaemolysin out into the medium was achieved by the presence in trans of the E. coli haemolysin secretion genes hlyB and hlyD, and high levels of intracellular haemolytic activity were attained similarly by the E. coli post-translational haemolysin activator gene, hlyC. Southern hybridization of A. pleuropneumoniae parental DNA nevertheless indicated only a low degree of nucleotide sequence identity to the haemolysin structural and secretion genes hlyA and hlyB of E. coli. The data show that despite substantial nucleotide sequence divergence the A. pleuropneumoniae serotype 1 haemolysin determinant is closely related to that which is dispersed throughout other Gram-negative human and animal pathogens.

Cloning and characterization of a hemolysin gene from Actinobacillus (Haemophilus) pleuropneumoniae

Neutralizing antisera to the leukotoxin secreted by Pasteurella haemolytica neutralized the hemolysin of Actinobacillus pleuropneumoniae and recognized a 110-kD antigen in cell-free culture supernatants from this organism. A series of nine overlapping recombinant phage clones carrying the gene for this 110-kD antigen were identified using affinity-purified anti-hemolysin antibody and a DNA probe containing sequences from the P. haemolytica lktCA genes. Eight of the nine clones expressed a 110-kD protein recognized by both anti-leukotoxin and anti-hemolysin antisera. The remaining clone expressed a truncated 80-kD antigen which was also recognized by both antisera. Sequence analysis of a region of the cloned DNA revealed two open reading frames encoding proteins with predicted masses of 18.5 and 102.5 kD. These genes, which we designate appC and appA, respectively, are similar in sequence to the hlyCA genes of Escherichia coli and the lktCA genes of P. haemolytica. Hemolytic activity could be detected in lysates of E. coli harboring plasmids containing the appCa genes.

The role of Proteae in diarrhea

A survey was undertaken on the occurrence of Protease in the human fecal flora and its coincidence with other well-documented enteropathogens such as Campylobacter, Salmonella, Shigella, Staphylococcus aureus, Yersinia, protozoa and rotavirus. A total of 2000 fecal specimens was investigated, 1000 from patients suffering from diarrhea and 1000 from healthy persons which served as controls. Proteus mirabilis was isolated more frequently from diarrhea cases than from healthy people. The difference was statistically significant (P less than 0.001). There was no correlation between its occurrence and isolation of Campylobacter, Salmonella, Shigella, Staphylococcus aureus, and protozoa. However, a questionable coincidence was found with rotavirus (P less than 0.2) and a more certain correlation with Yersinia enterocolitica (P less than 0.025). Proteus mirabilis in patients suffering from infection by other known enteropathogens was largely absent, suggesting that the organisms were independent causative agents of intestinal disorders. Notwithstanding this, they may additionally play a role as opportunists in enteric diseases due to some other pathogens.

Regulation of expression of the Pasteurella haemolytica leukotoxin determinant

The Pasteurella haemolytica leukotoxin determinant is composed of four contiguous genes encoded on the same DNA strand and denoted lktCABD, in the order of their genetic organization. To gain a better understanding of the expression and regulation of the leukotoxin, the transcripts and promoters of the lkt determinant were mapped. Northern (RNA) blot analysis revealed two sets of transcripts. One set was 3.7 and 3.4 kilobases long, encoded lktCA, and comprised approximately 90% of the transcripts, whereas the other set was 7.4 and 7.1 kilobases long and encoded lktCABD. Two promoters were present, and each had features similar to the Escherichia coli consensus promoter sequences. Both promoters were located upstream from lktC; they were separated by 258 base pairs, as mapped by primer extension analysis. These results suggest a mechanism of expression similar to that of the related E. coli hemolysin. Transcription initiated upstream from lktC at either promoter and continued through lktC and lktA to a rho-independent transcriptional termination signal in the lktA-lktB intercistronic region. This signal attenuated expression by terminating 90% of transcription to generate the 3.7- and 3.4-kilobase lktCA transcripts. The remaining readthrough transcription generated full-length 7.4- and 7.1-kilobase lktCABD transcripts. Expression of the leukotoxin was greatly reduced by growth at 30 degrees C, pH 6.5, and Fe2+ limitation. These conditions also modulated the expression of a number of other secreted proteins, which suggests that all of these secreted proteins are controlled by the same regulatory mechanism.

Electrical properties and molecular architecture of the channel formed by Escherichia coli hemolysin in planar lipid membranes

A 107 kDa hemolysin from Escherichia coli is able to open pores in lipid membranes. By studying its interaction with planar phospholipid bilayers we have derived some structural information on the organization of the pore. We measured the current-voltage characteristic and the ion selectivity of the channel both in neutral membranes, made of egg phosphatidylcholine (PC) and in negatively charged membranes, made of a 1:1 mixture of PC with phosphatidylserine (PS). Experiments were performed varying both the pH and the salt concentration of the bathing KCl solution. In neutral membranes the pore is ohmic and its conductance increases almost linearly with the salt concentration. The channel is cation-selective at high pH but nearly unselective at low pH. We interpret these results in terms of a minimal model based on classical electro-diffusional theories assuming that the pore is wide and bears a negative charge at its entrances. In membranes containing the acidic lipid the current-voltage curve is non-linear in such a way to suggest that the trans (but not the cis) entrance of the pore is affected by the surface potential of the membrane. Applying our model we find that the trans and cis entrances are located, respectively, about 0.5 nm and more than 5 nm apart from the plane of the membrane. We confirmed the asymmetric disposition of the channel by enzymatic digestion of preformed pores. This was effective only when the enzyme was applied on the cis side.

Transcription antitermination in an Escherichia coli haemolysin operon is directed progressively by cis-acting DNA sequences upstream of the promoter region

Export of haemolysin protein (HlyA) directed by the Escherichia coli pHly152 hly determinant is dependent upon transcriptional activation, primarily strong intraoperon transcript antitermination imposed between the haemolysin structural genes hlyC and hlyA and the contiguous downstream export genes hlyB and hlyD. Transcript elongation was dictated by a DNA sequence several kb upstream of the rho-independent terminator but could not be assigned to a discrete locus; on the contrary, it was progressive, increasing with the addition of up to 3.5 kbp of operon-proximal sequence containing the insertion elements IS2 and IS91. Antitermination was prominent throughout logarithmic growth but absent in stationary phase, and was effective only in cis but not in trans. Primer extension indicated that transcription activation utilized the native transcriptional start sites of the unactivated hly operon.