Isolation and analysis of the C-terminal signal directing export of Escherichia coli hemolysin protein across both bacterial membranes

Evidence that residues -15 to -46 of the haemolysin secretion signal are involved in early steps in secretion, leading to recognition of the translocator

We previously identified three well-dispersed mutations, E978-K, F989-L and D1009-R within the haemolysin A signal region, located at positions -46, -35 and -15, with respect to the C-terminus, respectively. Each mutation reduces the efficiency of secretion two- to threefold leaving 30-45% of the wild-type activity. We have constructed by in vitro manipulations double mutants of HlyA carrying all combinations of these mutations and a triple mutant carrying all three mutations. The effects on secretion were determined and the results, including residual levels of secretion with the triple mutant of only 0.6%, compared with the wild type, indicated that these residues may interact to form a single function in the wild-type signal. To test this further, we developed a secretion competition assay in order to classify signal mutations. We demonstrated that a CIZ-HlyA fusion protein, containing the C-terminal 81 kDa of HlyA fused to virtually the whole LacZ protein, strongly inhibits the secretion of the wild-type HlyA co-expressed in the same cell. The properties of the fusion indicate that it blocks the translocator. The three mutations singly and in combinations were recombined in vitro into the 3'-end of the hybrid gene. In every case, the presence of a mutation in the secretion signal of the hybrid protein alleviated the inhibition of secretion of the co-expressed HlyA. All the mutations are therefore essentially recessive and we propose that they all affect an early function, probably recognition of the translocator, rather than a subsequent step involved in translocation or final release of the toxin to the medium. This would indicate that residues involved in recognition (or steps leading to recognition) extend from at least -15 to -46 with respect to the HlyA C-terminus.

Loss of activity in the secreted form of Escherichia coli haemolysin caused by an rfaP lesion in core lipopolysaccharide assembly

A transposon mutant of Escherichia coli 5K was isolated which reduced 10- to 50-fold the secreted extracellular haemolytic activity of cells carrying the complete hlyCABD operon while leaving unaffected the intracellular haemolytic activity and the levels of intracellular and extracellular haemolysin protein, HlyA. The transposon insertion was identified within the rfaP gene (required for attachment of phosphate-containing substituents to the lipopolysaccharide inner core), and extracellular haemolytic activity was restored in trans by the intact rfaP gene. The loss in cytolytic activity of the secreted HlyA protein was not related to the HlyC-directed acylation of the protoxin. Activity of the secreted toxin was restored by chaotropic agents and during rate-zonal centrifugation the mutant-secreted HlyA migrated as a larger species than the wild type. The results indicate that the rfaP mutation affects the aggregation behaviour of the active toxin during or following the signal peptide-independent secretion process.

Enterobacterial hemolysins: activation, secretion and pore formation

Two types of enterobacterial hemolysins have been studied in detail: the Escherichia coli alpha-hemolysin and the Serratia marcescens hemolysin. Although they have similar properties, they differ entirely in the number and structure of the proteins that determine their hemolytic activities, in the mechanism and the subcellular location of activation and in their secretion mechanisms.

Repeat sequences in the Bordetella pertussis adenylate cyclase toxin can be recognized as alternative carboxy-proximal secretion signals by the Escherichia coli alpha-haemolysin translocator

The 1706-residue adenylate cyclase toxin (CyaA) of Bordetella pertussis is an RTX protein with extensive carboxy-proximal glycine and aspartate-rich repeats. CyaA does not have a cleavable amino-terminal signal peptide and can be secreted across both bacterial membranes of the Escherichia coli cell envelope by the alpha-haemolysin (HlyA) translocator (HlyBD/TolC). We performed deletion mapping of secretion signals recognized in CyaA by this heterologous translocator. Truncated proteins with N-terminal and internal deletions were secreted at levels up to 10 times higher than intact CyaA and similar to HlyA. A secretion signal recognized by HlyBD/TolC was found within the last 74 residues of CyaA. However, secretion of CyaA was reduced but not abolished upon deletion of the last 75 or 217 residues, indicating that at least two additional secretion signals recognized by HlyBD/TolC are within CyaA. One of them was localized to the repeat sequence between residues Asp-1587 to Ile-1631. Interestingly, a conserved 'acidic' motif (Glu/Asp)-(X)11-Asp-(X)3/5-(Glu/Asp)-(X)14-Asp was found in the C-terminal sequences of HlyA, CyaA and the two secreted CyaA derivatives. We speculate that the presence and spacing of acidic residues may be an important feature of secretion signals recognized by the haemolysin translocator.

The RTX cytotoxin-related FrpA protein of Neisseria meningitidis is secreted extracellularly by meningococci and by HlyBD+ Escherichia coli

Neisseria meningitidis produces proteins (FrpA and FrpC) related to the RTX cytotoxin family. In meningococcal strain FAM20 these proteins were both localized in the outer membrane and secreted into the extracellular medium. An Escherichia coli strain with wild-type hemolysin secretion genes hlyB and hlyD and containing a cloned frpA gene secreted FrpA, whereas an isogenic hlyBD mutant strain did not. Low-stringency DNA hybridization revealed hlyBD-like sequences in N. meningitidis FAM20, suggesting that a similar RTX secretion system exists in meningococci. Structural features found at the C termini of other RTX proteins and thought to be important for their secretion were also found at the C terminus of FrpA. The secretion of FrpA from E. coli by heterologous RTX transport proteins further demonstrates the relation of the FrpA protein to RTX toxins.

ATPase activity and ATP/ADP-induced conformational change in the soluble domain of the bacterial protein translocator HlyB

The haemolysin exporter HlyB and its homologues are central to the unconventional signal-peptide-independent secretion of toxins, proteases and nodulation proteins by bacteria. HlyB is a member of the ATP-binding cassette (ABC) or traffic ATPase superfamily, and resembles closely in structure and function mammalian exporters such as the multidrug-resistance P-glycoprotein, combining both integral membrane and cytosolic domains. Overproduction of the HlyB cytoplasmic domain as a C-terminal peptide fused to glutathione S-transferase allowed the direct affinity purification and concentration of 30-50 mg ml-1 of soluble protein (GST-Bctp) in an apparently dimeric form possessing both transferase and ATPase activity. GST-Bctp bound to ADP-agarose and was eluted specifically by ATP and ADP, affinity behaviour which was confirmed in both the full-length HlyB and the unfused HlyB cytoplasmic domain synthesized in vitro. The stoichiometry of binding to MgATP and MgADP was close to equimolar and both ligands induced substantial conformational change in the protein. Mg(2+)-dependent ATPase activity of GST-Bctp (Vmax 1 mumol min-1 mg-1, Km 0.2 mM) was comparable with the activity of the bacterial importer MalK and human P-glycoprotein reconstituted into proteoliposomes, and over an order of magnitude higher than in vitro measurements of disaggregated MalK purified from inclusion bodies. Activity was unaffected by inhibitors of F- and V-type ATPases, non-hydrolysable ATP analogues, or translocation substrate, but was severely inhibited by inhibitors of E1E2 (P-type) ATPases, and the acidic phospholipid phosphatidyl glycerol.

Genetic conservation of hlyA determinants and serological conservation of HlyA: basis for developing a broadly cross-reactive subunit Escherichia coli alpha-hemolysin vaccine

The HlyA determinant among Escherichia coli isolates from patients with symptomatic urinary tract infection was compared in this report with a prototype HlyA encoded by pSF4000 by DNA-DNA hybridization tests with 20-base synthetic oligonucleotides and monoclonal antibody binding and neutralization assays. Hybridization results demonstrated that 349 (98%) of 357 definitive reactions among 54 hemolytic strains shared homology with seven DNA probes spanning many HlyA regions corresponding to residues (R) 41 to 47, 55 to 61, 248 to 254, 306 to 312, 336 to 343, 402 to 408, and 929 to 935. Genetic divergence was identified by lack of hybridization signals among 17 to 76% of the hemolytic strains within the distal portion of a predicted hydrophobic region corresponding to R491 to 319 and within a predicted hydrophilic region corresponding to R491 to 497 and R532 to 538. Serological studies demonstrated that 26 (81%) culture supernatants of 32 hemolytic strains were bound by all 12 monoclonal anti-HlyA antibodies. Among five of six remaining strains, the culture supernatants were bound by 3 to 11 monoclonal antibody preparations. There was only one hemolytic culture supernatant that failed to be bound by any monoclonal antibody, although the strain hybridized with nine hemolysin DNA probes. In addition, hemolytic activity of all 24 different culture supernatants tested was reduced by at least twofold by one monoclonal antibody specific for R2-161. These data extend and support previous views that the HlyA determinant is conserved among E. coli strains and suggest that a broadly cross-reactive HlyA subunit vaccine can be developed.

Cloning, nucleotide sequence and characterization of the gene encoding the Erwinia chrysanthemi B374 PrtA metalloprotease: a third metalloprotease secreted via a C-terminal secretion signal

Erwinia chrysanthemi, a phytopathogenic enterobacterium, secretes three proteases (PrtA, PrtB and PrtC) into the extracellular medium. The gene encoding the 50 kDa protease, prtA, was subcloned from a recombinant cosmid carrying a fragment of the E. chrysanthemi B374 chromosome. prtA was shown to be located immediately 3' to the structural genes for the other two extracellular proteases. The amino acid sequence of PrtA, as predicted from the prtA nucleotide sequence, showed a high level of homology with a family of metalloproteases that are all secreted via a signal peptide-independent pathway, including PrtB and PrtC of E. chrysanthemi B374, PrtC of E. chrysanthemi EC16, PrtSM of Serratia marcescens and AprA of Pseudomonas aeruginosa. PrtA secretion requires the E. chrysanthemi protease secretion factors PrtD, PrtE and PrtF. The secretion signal of PrtA is near to the carboxy-terminal end of the protein, as was previously shown to be the case for PrtB and PrtSM and for Escherichia coli alpha-hemolysin. The C-termini of these four proteins do not show extensive primary sequence homology, but PrtA, PrtB and PrtSM each have a potential amphipathic alpha-helix located close to the C-terminus.

Extracellular export of Shiga toxin B-subunit/haemolysin A (C-terminus) fusion protein expressed in Salmonella typhimurium aroA-mutant and stimulation of B-subunit specific antibody responses in mice

The Shiga toxin B-subunit has been fused to the 23-kD C-terminus of Escherichia coli haemolysin A (HlyA) and exported from attenuated antigen carrier strain of Salmonella typhimurium aroA (SL3261). The expression of the gene fusion under the control of a synthetic modified beta-lactamase promoter (constitutive expression) and under the iron-regulated aerobactin promoter showed that the fusion protein could be stably expressed and exported out of the bacterial cell in significant amounts so long as high copy number plasmids were not used. Oral and i.p. immunization of mice with the hybrid salmonellae resulted in significant B-subunit specific mucosal and serum antibody responses. A comparative analysis of the location of hybrid proteins in the antigen carrier bacterial cell (i.e. cytoplasmic expression and extracellular export) has shown that both modes of expression result in antigen-specific immune responses. This is the first report demonstrating that foreign polypeptides fused to the 23-kD C-terminus of E. coli haemolysin A can be exported from attenuated Salmonella vaccine strains and that such exported polypeptides can result in antigen-specific immune responses.

Sequence of a cluster of genes controlling synthesis and secretion of alkaline protease in Pseudomonas aeruginosa: relationships to other secretory pathways

A genetic locus implicated in the synthesis and secretion of alkaline protease (APR) in Pseudomonas aeruginosa has been previously described [Guzzo et al., J. Bacteriol. 172 (1990) 942-948]. The nucleotide sequence of the DNA fragment encoding these functions was determined and revealed the existence of five open reading frames: aprA, the structural gene encoding APR; aprI, which encodes a protease inhibitor; and aprD, aprE, aprF whose products are involved in protease secretion. The AprD, AprE and AprF proteins share significant homology with proteins implicated in secretion of Erwinia chrysanthemi proteases and Escherichia coli alpha-haemolysin. These results provide further evidence for the existence of a specialized secretory system widespread among Gram- bacteria.

Activation of Escherichia coli prohemolysin to the membrane-targetted toxin by HlyC-directed ACP-dependent fatty acylation

Hemolysin (HlyA) and related toxins of Escherichia coli and other Gram-negative pathogenic bacteria form membrane pores in cells of the host immune system, causing cell dysfunction and death. An insight into the mechanism by which HlyA is targetted to mammalian cell membranes was achieved by establishing in vitro activation of the non-toxic precursor proHlyA. By this approach we have discovered that conversion of proHlyA to the post-translational active HlyA toxin is determined by fatty acylation of proHlyA in an apparently novel process directed by the HlyC homodimer activator protein, and dependent upon the cellular acyl carrier protein (ACP). By further exploiting the in vitro activation system it is now possible to obtain direct evidence that HlyC binds to an internal recognition sequence in the proHlyA precursor, in this way providing specificity for the transfer to proHlyA of a fatty acid moiety carried by the ACP. It is possible that the fatty acid modification determines directly the binding of HlyA to mammalian membrane lipids, thus initiating the toxin interaction with the target cells.

Functional analysis of the Ca(2+)-regulated hemolysin I operon of Actinobacillus pleuropneumoniae serotype 1

The genetic determinant encoding the synthesis and secretion of hemolysin I (HlyI; gene designation, hlyI) by Actinobacillus pleuropneumoniae serotype 1 4074T was cloned in the lambda vector EMBL4. A 10.2-kb fragment that encoded hemolytic activity in the phage lysate was aligned by Southern blot hybridization to genes hlyC, hlyA, hlyB, and hlyD of the Escherichia coli hemolysin operon, and expression of the A. pleuropneumoniae genes in E. coli revealed that they have the same functions as their E. coli analogs: hlyIC encodes a protein that activates inactive 105-kDa prohemolysin I (encoded by hlyIA) to active hemolysin I, while hlyIB and hlyID are necessary for HlyIA secretion. Northern (RNA) hybridization of A. pleuropneumoniae RNA revealed that the gene cluster is transcribed as two RNA species, a major one of 3.5 kb, corresponding to hlyICA, and a second, minor one of 7.5 kb, corresponding to the whole operon, hlyICABD. The level of hlyI mRNA was substantially higher in A. pleuropneumoniae 4074T cells grown in the presence of Ca2+, supporting the view that the expression of the hlyI determinant is Ca2+ regulated. Parallel RNA hybridization with random gene probes suggested that this Ca2+ regulation is specific for the hlyI determinant.

E.coli hemolysin interactions with prokaryotic and eukaryotic cell membranes

The hemolysin toxin (HlyA) is secreted across both the cytoplasmic and outer membranes of pathogenic Escherichia coli and forms membrane pores in cells of the host immune system, causing cell dysfunction and death. The processes underlying the interaction of HlyA with the bacterial and mammalian cell membranes are remarkable. Secretion of HlyA occurs without a periplasmic intermediate and is directed by an uncleaved C-terminal targetting signal and the HlyB and HlyD translocator proteins, the former being a member of a transporter superfamily central to import and export of a wide range of substrates by prokaryotic and eukaryotic cells. The separate process by which HlyA is targetted to mammalian cell membranes is dependent upon fatty acylation of a non-toxic precursor, proHlyA. This is achieved by a novel mechanism directed by the activator protein HlyC, which binds to an internal proHlyA recognition sequence and provides specificity for the transfer of fatty acid from cellular acyl carrier protein.

Sorting of protein A to the staphylococcal cell wall

The cell wall of gram-positive bacteria can be thought of as representing a unique cell compartment, which contains anchored surface proteins that require specific sorting signals. Some biologically important products are anchored in this way, including protein A and fibronectin binding protein of Staphylococcus aureus and streptococcal M protein. Studies of staphylococcal protein A and Escherichia coli alkaline phosphatase show that the signal both necessary and sufficient for cell wall anchoring consists of an LPXTGX motif, a C-terminal hydrophobic domain, and a charged tail. These sequence elements are conserved in many surface proteins from different gram-positive bacteria. We propose the existence of a hitherto undescribed sorting mechanism that positions proteins on the surface of gram-positive bacteria.

The expression of murine protein disulfide isomerase in Escherichia coli

Protein disulfide isomerase (PDI), a luminal enzyme of the endoplasmic reticulum (ER), is thought to be involved in the process that assures that the correct disulfide bonds form as a newly synthesized protein folds into its appropriate three-dimensional structure (Freeman, 1984). In recent years, the ER has been shown to have at least two additional, distinct PDI-related luminal proteins (Bennett et al., 1988; Mazzarella et al., 1990). As a potential first step toward an investigation of the structure and function of PDI and of the PDI-related proteins as well, we have developed a bacterial expression system in Escherichia coli capable of synthesizing significant levels of enzymatically active PDI under the control of the inducible tac promoter. We have observed that the use of this bacterial expression system is complicated by the fact that there is a significant amount of internal initiation of protein synthesis within the PDI coding sequence and the fact that all of the PDI-related expression products are found equally distributed between the cytoplasmic and periplasmic fractions due to a single peptide-independent mechanism. Our studies with this system have demonstrated that at least some truncated PDI molecules containing the carboxy-terminal most active site have significant PDI activity.

Identification of individual amino acids required for secretion within the haemolysin (HlyA) C-terminal targeting region

The release of haemolysin from Escherichia coli involves direct secretion across both the inner and outer membranes. Secretion of HlyA is dependent upon a specific membrane export complex composed of HlyB, -D and possibly TolC. HlyA is targeted to the medium via the membrane translocation complex, by a novel C-terminal secretion signal. Previous studies involving deletion and fusion analyses have given contradictory results for the minimal length (20-60 residues) of this HlyA signal region and little is known of the nature of the specific residues and structural features required for function. In this study we have analysed, quantitatively, the effect upon secretion of many point mutations introduced into the HlyA C-terminus. The results indicate the presence of a minimal secretion signal domain whose proximal boundary extends to at least residue -46 and which contains at least four individual residues essential for maximal secretion levels. We propose that such residues act co-operatively, forming multiple contact points with the translocator proteins, with the 'best fit' promoting maximal levels of secretion.

icsB: a Shigella flexneri virulence gene necessary for the lysis of protrusions during intercellular spread

Shigella flexneri causes bacillary dysentery by invading epithelial cells of the colonic mucosa. We have characterized the icsB gene which is located on the virulence plasmid pWR100. After inactivation of icsB, the mutant strain remained invasive, but formed abnormally small plaques on HeLa cell monolayers, colonized only the peripheral cells of Caco-2 islets, and was unable to provoke a keratoconjunctivitis in guinea-pigs. Examination of infected HeLa cells showed that the icsB mutant was able to lyse the phagocytic vacuole and to form protrusions at the surface of infected cells, but, unlike the wild type, remained trapped in protrusions surrounded by two membranes. These results indicate that IcsB is involved in the lysis of the protrusions, a step necessary for intercellular spread.

Signal peptides open protein-conducting channels in E. coli

Plasma membrane vesicles and protoplasts of Escherichia coli were fused to planar lipid bilayers and studied with electrophysiological techniques. Large transmembrane aqueous channels were opened when 0.2 nM LamB signal peptide was added to the cytoplasmic side of the membrane. These aqueous pores are similar in conductance to those previously observed in mammalian endoplasmic reticulum when puromycin is used to release and thus unplug nascent translocating chains. Signal sequences have been previously shown to be necessary and sufficient for targeting proteins to cellular membranes. These results demonstrate that signal peptides are sufficient for opening the protein-conducting channels. We suggest that they are the physiological ligands that open protein-conducting channels at the initiation of protein translocation across prokaryotic plasma membrane and mammalian endoplasmic reticulum.

Processing by OmpT of fusion proteins carrying the HlyA transport signal during secretion by the Escherichia coli hemolysin transport system

A fusion gene (ces-hlyAs) was constructed by ligating the genetic information for the C-terminal 60 amino acids (hlyAs) of Escherichia coli hemolysin (HlyA) to the ces gene for a cholesterol esterase/lipase (CE) from a Pseudomonas species. Part (about 30%) of the expressed fusion protein CE-HlyAs was secreted in E. coli carrying hlyB and hlyD genes. Following the insertion between the reporter gene and hlyAs of a linker sequence that contains the information for potential cleavage sites for the outer membrane protease OmpT, two different fusion proteins (PhoA-HlyAs and CE-HlyAs) were shown to be cleaved by OmpT between the two parts during HlyB/HlyD-mediated secretion. Processed PhoA and CE accumulated in the supernatant. The efficiency of cleavage by OmpT was considerably improved by increased ompT gene dose. It was further shown that OmpT preferentially recognizes potential cleavage sites within the linker sequence.

Polar localization of a bacterial chemoreceptor

The bacterial chemotaxis signal transducer MCP is an integral membrane receptor protein. The chemoreceptor is localized at the flagellum-bearing pole of Caulobacter crescentus swarmer cells. Amino-terminal sequences of the MCP target the protein to the membrane while the carboxy-terminal portion of the protein is responsible for polar localization. The C. crescentus and Escherichia coli MCPs have highly conserved carboxy-terminal domains, and when an E. coli MCP is expressed in C. crescentus, it is targeted to the swarmer cell progeny. These results suggest that subcellular localization of a prokaryotic protein involves interaction of specific regions of the protein with unique cell sites that contain either localized binding proteins or a specific secretory apparatus.

Sandwich ELISA formats designed to detect 17 kDa IL-1 beta significantly underestimate 35 kDa IL-1 beta

The IL-1 beta precursor (proIL-1 beta) represents a significant component of total IL-1 beta production in certain cell types such as keratinocytes, fibroblasts and alveolar macrophages. It has been presumed that immunodetection systems for the mature 17 kDa IL-1 beta can be used interchangeably for the 35 kDa intracellular proIL-1 beta. However, during attempts to purify alveolar macrophage proIL-1 beta, we found that conventional enzyme-linked immunoassays (ELISAs) (using antibodies directed against the 17 kDa mature IL-1 beta) underestimated the amounts of 35 kDa proIL-1 beta by at least ten-fold compared to detection by Western blot techniques. This difference was due to the fact that ELISAs, with an antigen capture format (i.e., that use more than one epitope), can more readily see these distinct epitopes on mature or partially processed IL-1 beta than on the proIL-1 beta molecule. This problem does not occur with the Western blot technique, either because only one antibody is needed and hence there is no stearic blockade of a second epitope or because it denatures 35 kDa proIL-1 beta during the immobilization step, presumably better exposing epitopes as expressed on mature 17 kDa IL-1 beta. The problem with the ELISA can be partially corrected by proteolytic removal of the aminoterminus of 35 kDa proIL-1 beta with neutrophil elastase. More accurate determinations of proIL-1 beta by ELISA can be made by using 35 kDa proIL-1 beta as the reference standard (when the 35 kDa proIL-1 beta is free of molecular weight IL-1 beta). These data suggest that there are conformational differences between the carboxyterminus of 35 kDa proIL-1 beta and mature 17 kDa IL-1 beta which may affect immunodetection when using antibodies directed against mature 17 kDa IL-1 beta.

Escherichia coli HlyT protein, a transcriptional activator of haemolysin synthesis and secretion, is encoded by the rfaH (sfrB) locus required for expression of sex factor and lipopolysaccharide genes

Synthesis and secretion of the 110kDa haemolysin toxin of Escherichia coli and other pathogenic Gram-negative bacteria are governed by the four genes of the hly operon. We have identified, by transposon mutagenesis, an E. coli cellular locus, hlyT, required for the synthesis and secretion of haemolysin encoded in trans by intact hly operons carrying the hly upstream regulatory region. Mutation of the hlyT locus specifically reduced the level of hlyA structural gene transcript 20-100-fold and thus markedly lowered both intracellular and extracellular levels of the HlyA protein. Genetic and structural analysis of the hlyT locus mapped it at co-ordinate 3680 kbp (minute 87) on the chromosome adjacent to the fadBA operon, and identified it specifically as the rfaH (sfrB) locus which is required for transcription of the genes encoding synthesis of the sex pilus and also the lipopolysaccharide core for attachment of the O-antigen of E. coli and Salmonella. Expression of the hly operon in the E. coli hlyT mutant was restored in trans by both the hlyT and rfaH genes, suggesting that the rfaH gene is an important activator of regulon structures that are central to the fertility and virulence of these pathogenic bacteria. DNA sequencing of the hlyT locus identifies the HlyT/RfaH transcriptional activator as a protein of 162 amino acids (Mr 18325) which shows no identity to characterized transcription factors.

Topological and functional studies on HlyB of Escherichia coli

The topology of HlyB, a protein located in the inner membrane of Escherichia coli and involved in the secretion of alpha-haemolysin (HlyA), was determined by the generation of HlyB-PhoA and HlyB-LacZ fusion proteins. The data obtained by this biochemical method together with computer predictions suggest that HlyB is inserted in the cytoplasmic membrane by six stable hydrophobic, alpha-helical transmembrane segments. These segments extend from amino acid positions 158 to 432 of HlyB. The cytoplasmic loops between these transmembrane segments are relatively large and carry an excess of positively charged amino acids, while the periplasmic loops are rather small. In addition to these six transmembrane segments, two additional regions in the 78 N-terminal amino acids of HlyB appear to be also inserted in the cytoplasmic membrane. However, the association of these two segments with the cytoplasmic membrane seems to be less tight, since active PhoA and LacZ fusions were obtained by insertion into the same positions of these segments. A LacZ-HlyAs, fusion protein carrying, at the C-terminus of LacZ, the 60-amino acid signal sequence of HlyA was not secreted in the presence of HlyB/HlyD. However, transport of this fusion protein into the cytoplasmic membrane appeared to be initiated, as suggested by the tight association of this protein with the inner membrane. A similar close association of LacZ-HlyAs with the inner membrane was also observed in the presence of HlyB alone but not in its absence. These data suggest that HlyB recognizes the HlyA signal sequence and initiates the transport of HlyA into the membrane.

Structural and functional relationships among the RTX toxin determinants of gram-negative bacteria

The RTX (repeats in toxin) cytolytic toxins represent a family of important virulence factors that have disseminated widely among Gram-negative bacteria. They are characterised by a series of glycine-rich repeat units at the C-terminal end of each protein. They also have other features in common. Secretion from the cell occurs without a periplasmic intermediate by a novel mechanism which involves recognition of a signal sequence at the C-terminus of the toxin by membrane-associated proteins that export the toxin directly to the outside of the cell. The structural gene for each protein encodes an inactive toxin which is modified post-translationally to an active cytotoxic form by another gene product before secretion. The genes for toxin synthesis, activation and secretion are for the most part grouped together on the chromosome and form an operon. The toxins all create pores in the cell membrane of target cells leading to eventual cell lysis and they appear to require Ca2+ for cytotoxic activity. Although the toxins have a similar mode of action, they vary in target cell specificity. Some are cytotoxic for a wide variety of eukaryotic cell types while others exhibit precise target cell specificity and are only active against leukocytes from certain host species. The characteristic glycine-rich repeat units have been identified in other exoproteins besides those with cytotoxic activity and it is likely that the novel secretory mechanism has been harnessed by a variety of pathogens to release important virulence-associated factors from the cell or to locate them on the cell surface.

Haemolysin-derived synthetic peptides with pore-forming and haemolytic activity

Escherichia coli haemolysin (Hlya) is a pore-forming protein which belongs to the family of 'Repeat-toxins' (RTX) (Lo et al., 1987; Lally et al., 1989; Kraig et al., 1990). A model for the pore-forming structure of HlyA has been proposed (Ludwig et al., 1991) which consists of eight transmembrane segments all present in this hydrophobic region of HlyA. We report here that two synthetic peptides of 10 and 8 amino acids in length (Pep1 and Pep2, respectively), which are derived from transmembrane segment V, are able to form pores in an artificial lipid bilayer. In addition, Pep1 exhibits strong haemolytic activity when tested on human red blood cells (HRBCs). The haemolytic activity of Pep1 and of E. coli haemolysin is completely inhibited by antibodies raised against Pep1.

Secretion of the Rhizobium leguminosarum nodulation protein NodO by haemolysin-type systems

The Rhizobium leguminosarum biovar viciae nodulation protein NodO is partially homologous to haemolysin of Escherichia coli and, like haemolysin, is secreted into the growth medium. The NodO protein can be secreted by a strain of E. coli carrying the cloned nodO gene plus the haemolysin secretion genes hlyBD, in a process that also requires the outer membrane protein encoded by tolC. The related protease secretion genes, prtDEF, from Erwinia chrysanthemi also enable E. coli to secrete NodO. The Rhizobium genes encoding the proteins required for NodO secretion are unlinked to nodO and are unlike other nod genes, since they do not require flavonoids or NodO for their expression. Although proteins similar to NodO were not found in rhizobia other than R. leguminosarum bv. viciae, several rhizobia and an Agrobacterium strain containing the cloned nodO gene were found to have the ability to secrete NodO. These observations indicate that a wide range of the Rhizobiaceae have a protein secretion mechanism analogous to that which secretes haemolysin and related toxins and proteases in the ENterobacteriaceae.

Separable domains define target cell specificities of an RTX hemolysin from Actinobacillus pleuropneumoniae

The leukotoxin (LktA) from Pasteurella haemolytica and the hemolysin (AppA) from Actinobacillus pleuropneumoniae are members of a highly conserved family of cytolytic proteins produced by gram-negative bacteria. Despite the extensive homology between these gene products, LktA is specific for ruminant leukocytes while AppA, like other hemolysins, lyses erythrocytes and a variety of nucleated cells, including ruminant leukocytes. Both proteins require activation facilitated by the product of an accessory repeat toxin (RTX) C gene for optimal biological activity. We have constructed six genes encoding hybrid toxins by recombining domains of ltkA and appA and have examined the target cell specificities of the resulting hybrid proteins. Our results indicate that the leukocytic potential of AppA, like that of LktA, maps to the C-terminal half of the protein and is physically separable from the region specifying erythrocyte lysis. As a consequence, we were able to construct an RTX toxin capable of lysing erythrocytes but not leukocytes. The specificity of one hybrid was found to be dependent upon the RTX C gene used for activation. With appC activation, this hybrid toxin lysed both erythrocytes and leukocytes, while lktC activation produced a toxin which could attack only leukocytes. This is the first demonstration that the specificity of an RTX toxin can be determined by the process of C-mediated activation.

Characterization of three proteins expressed from the virulence region of plasmid pSDL2 in Salmonella dublin

Infection of both cattle and humans with Salmonella dublin can result in septicemia and death. Like many nontyphoid Salmonella species that cause disease, S. dublin contains a cryptic plasmid (pSDL2) that is required for the full expression of virulence. Transposon mutagenesis of pSDL2 defined a 4.1-kb EcoRI region that is necessary for the development of a systemic infection in BALB/c mice. This EcoRI fragment was cloned into an expression vector (pEL11), and three proteins produced from this region with apparent molecular weights of 30,500, 76,000, and 27,000 were identified. Because bacterial proteins that play a role in virulence are often associated with the outer membrane, we were interested in establishing whether the proteins expressed from the EcoRI fragment are located in the membrane. Transposon mutagenesis of pEL11 with TnphoA defined the order of the genes along the fragment and suggested that the proteins may be exported out of the cytoplasm. Sucrose gradient cell fractionation was done to identify the cellular location of each of the three proteins. The 30-kDa protein was identified in the outer membrane fraction, and the 76-kDa protein was located in the cytosolic fraction. The 27-kDa protein was identified in both the cytosolic and the outer membrane fractions. The outer membrane contained less than 10% of the activity of enzymes known to be located in the cytoplasm, periplasm, and inner membrane. Sequence data of the 4.1-kb EcoRI region revealed that both the 30- and the 27-kDa proteins lack a typical signal sequence for export out of the cytoplasm (M. Krause, C. Roudier, J. Fierer, J. Harwood, and D. G. Guiney, Mol. Microbiol. 5:307, 1991). The outer membrane location of these proteins suggests that they may be exported out of the cytoplasm by an unusual mechanism.

Analysis of the haemolysin transport process through the secretion from Escherichia coli of PCM, CAT or beta-galactosidase fused to the Hly C-terminal signal domain

Secretion of haemolysin (HlyA) is secA independent, but depends upon two accessory membrane proteins, HlyB and HlyD, encoded by the hly determinant. A fourth (cytoplasmic) protein, HlyC, is required to activate HlyA post-translationally, but has no role in export. Deletion studies have previously shown that the HlyA molecule contains a targeting signal close to the C-terminus which specifically directs its secretion to the medium. This targeting signal has been variously located within the terminal 27, 53, 60 or 113 amino acids. In this paper, we have sought to confirm the presence of a C-terminal targeting signal and to analyse the specificity of the Hly transport system through fusion of C-terminal fragments of HlyA to heterologous polypeptides. A C-terminal fragment (23 kDa) of HlyA, when fused at the C-terminus, efficiently promoted the secretion of the eukaryotic protein prochymosin (PCM) to the medium via HlyB and HlyD. This result is in contrast to previous findings that prochymosin, preceded by the alkaline phosphatase signal sequence, cannot be translocated across the Escherichia coli inner membrane. The HlyA targeting domain was also used to secrete to the medium varying portions of chloramphenicol acetyltransferase (CAT) and 98 per cent of the beta-galactosidase (LacZ) molecule (both E. coli cytoplasmic proteins). In the case of the PCM and CAT fusions the efficiency of secretion was reduced as the proportion of the PCM and CAT molecule increased. This result is consistent with inhibition of secretion through the irreversible folding of the larger passenger protein fragments, or the occlusion of the HlyA targeting signal by upstream sequences. Analysis of the nature of the C-terminal domain promoting secretion of prochymosin, demonstrated that shortening the signal domain from 218 to 113 amino acids significantly reduced the efficiency of secretion. This result may also reflect the importance of maintaining an independently folded signal motif well separated from a passenger domain.

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.

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.

The hha gene modulates haemolysin expression in Escherichia coli

A mutation in the hha allele results in a large increase in the production of intracellular as well as extracellular haemolysin in Escherichia coli cells harbouring the haemolytic recombinant plasmid pANN202-312. This single gene mutation was located between 490 and 491.6 kb on the physical map of the E. coli chromosome. From the DNA sequence of hha a small polypeptide of 8629 Da was predicted and was expressed in minicells. The deduced polypeptide sequence did not show significant similarities to other characterized proteins related to the regulation of gene expression in E. coli, although it was shown that the hha mutation increases cytoplasmic synthesis of haemolysin.

Localization of IpaB protein in Escherichia coli K-12 MC1061 strain carrying Shigella sonnei form I plasmid pSS120

We partially purified antigens which reacted with shigellosis convalescent-monkey antisera. Hybridomas, which were constructed from mice immunized by the antigens, produced monoclonal antibodies recognizing IpaB protein. Using the monoclonal antibody against IpaB, evidence indicating that IpaB proteins were localized on the cell surface of invasive bacteria (Escherichia coli K-12 MC1061 harboring pSS120 plasmid) was obtained by immunoelectron microscopy.

Characterization of a non-hemolytic mutant of Actinobacillus pleuropneumoniae serotype 5: role of the 110 kilodalton hemolysin in virulence and immunoprotection

To determine the role of hemolysin(s) in virulence and immunoprotection, non-hemolytic mutants of Actinobacillus pleuropneumoniae serotype 5, strain J45, were isolated following chemical mutagenesis. One mutant was selected for extensive characterization. Differences in capsule content, or in lipopolysaccharide or membrane protein electrophoretic profiles of the parent and mutant were not detected. A predominant, calcium-inducible protein of 110 kDa was present in culture supernatant of the parent, but absent from the mutant. Two-dimensional (2-D) gel electrophoresis confirmed that the 110 kDa protein was absent in culture supernatant of the mutant, but few, if any, minor differences could be detected in whole-cell proteins between the parent and mutant. The mutant totally lacked extracellular hemolytic and cytotoxic activity. Lysates of whole cells of the mutant contained weak hemolytic activity, and the 110 kDa protein could be detected by immunoblotting. Neutralization titers were negative in pigs immunized with the mutant or purified, denatured hemolysin, although enzyme-immunoassay titers were detected. Four additional independently isolated non-hemolytic mutants were avirulent in pigs and mice at doses greater than 10 times the lethal dose of the parent. Neither pigs nor mice were protected against lethal infection following immunization with the non-hemolytic mutant. We conclude that the 110 kDa hemolysin plays an important role in bacterial virulence and the pathogenesis of pleuropneumonia, and that sufficiently high levels of neutralizing antibodies to the 110 kDa hemolysin may be required for protection of pigs against disease.

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.

Analysis of the membrane organization of an Escherichia coli protein translocator, HlyB, a member of a large family of prokaryote and eukaryote surface transport proteins

Haemolysin B (HlyB) is essential for secretion of the 107 x 10(3) Mr haemolysin A protein from Escherichia coli and is a member of a family of highly conserved, apparently ATP-dependent surface proteins in many organisms. We have shown in this study that both HlyB and HlyD fractionate primarily with the cytoplasmic membrane of E. coli and are accessible to proteases after removal of the outer membrane. We have measured experimentally the topological organization of HlyB within the membrane by construction of fusions to beta-lactamase as a reporter. The predicted folding of HlyB, with a minimum of six transmembrane segments, does not always coincide with regions of highest average hydrophobicity. This suggests that HlyB may have a novel organization within the bilayer. From our data and comparative sequence analysis, we have been able to predict very similar topological models for the other members of the HlyB family.

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.

Genetic analysis of an MDR-like export system: the secretion of colicin V

The extracellular secretion of the antibacterial toxin colicin V is mediated via a signal sequence independent process which requires the products of two linked genes: cvaA and cvaB. The nucleotide sequence of cvaB reveals that its product is a member of a subfamily of proteins, involved in the export of diverse molecules, found in both eukaryotes and prokaryotes. This group of proteins, here referred to as the 'MDR-like' subfamily, is characterized by the presence of a hydrophobic region followed by a highly conserved ATP binding fold. By constructing fusions between the structural gene for colicin V, cvaC, and a gene for alkaline phosphatase, phoA, lacking its signal sequence, it was determined that 39 codons in the N-terminus of cvaC contained the structural information to allow CvaC-PhoA fusion proteins to be efficiently translocated across the plasma membrane of Escherichia coli in a CvaA/CvaB dependent fashion. This result is consistent with the location of point mutations in the cvaC gene which yielded export deficient colicin V. The presence of the export signal at the N-terminus of CvaC contrasts with the observed C-terminal location of the export signal for hemolysin, which also utilizes an MDR-like protein for its secretion. It was also found that the CvaA component of the colicin V export system shows amino acid sequence similarities with another component involved in hemolysin export, HlyD. The role of the second component in these systems and the possibility that other members of the MDR-like subfamily will also have corresponding second components are discussed. A third component used in both colicin V and hemolysin extracellular secretion is the E. coli host outer membrane protein, TolC.

Clostridium difficile toxin A carries a C-terminal repetitive structure homologous to the carbohydrate binding region of streptococcal glycosyltransferases

A detailed analysis of the 8130-bp open reading frame (ORF) of gene toxA and of an upstream ORF designated utxA, indicates the presence of a transcription terminator stem-loop for toxA, promoter sequences, and Shine-Dalgarno boxes for toxA and utxA. No transcription terminator between toxA and utxA is suggested by the sequence. ToxA contains two domains, one-third (C-terminal) with a repetitive structure and the residual two-thirds with no repetitions. The 2499-bp sequence encoding the repetitive structure is composed of nine groups of different short repetitive oligodeoxyribonucleotides (SRONs). A combination of these SRONs codes for five groups of combined repetitive oligopeptides (CROPs). Seven 50-amino acid (aa) CROPs and 23 CROPs of 21 aa in length are noticed. The CROPs are generally highly conserved, but four exhibit variability and possibly represent 'hot spots' of the repetitive structure. The reactivity of the C-terminal repeat with monoclonal antibody 1337C8 indicates that this part contains the carbohydrate-binding domain of ToxA. In this region homology exists between the ToxA repeats and the glucosyltransferases of Streptococci. We propose that binding of ToxA to cells occurs via the C-terminal repeat domain, with the N-terminal domain being responsible for toxic function.

Deletion analysis resolves cell-binding and lytic domains of the Pasteurella leukotoxin

A series of internal deletions in the lktA gene of Pasteurella haemolytica has been constructed. All of the deletions eliminated the lytic activity of the leukotoxin towards the bovine lymphoma cell line, BL-3. Deletions removing segments of the amino-proximal hydrophobic region, which is thought to constitute an essential membrane-spanning domain, were found to agglutinate BL-3 cells. Agglutination was similar to lysis by the wild-type toxin in that it was dependent upon the presence of calcium and required expression of the lktC gene. The agglutinating deletion proteins protected BL-3 cells from lysis by the wild-type toxin in a competitive fashion. This suggests that these mutants bind to a surface feature of the leukocyte which interacts with the native leukotoxin. These findings demonstrate that the cell-binding and lytic domains of the leukotoxin are separable.

Analysis of the haemolysin secretion system by PhoA-HlyA fusion proteins

We studied the efficiency of the pHly152-derived haemolysin transport system using PhoA-HlyA fusion proteins and different constructs which provide HlyB/HlyD in trans. The optimal C-terminal HlyA signal consists of the last 60 amino acids. Longer stretches of HlyA do not improve the transport efficiency of PhoA-HlyA fusion proteins. The introduction of deletions and/or replacements in the 60 amino acid HlyA signal domain revealed at least three functional regions with different degrees of specificity. Amino acids 1-21 (numbered from the N-terminal part of the 60 amino acid HlyA signal), termed region I, could be replaced by a Pro-containing peptide. The other two regions II and III (amino acids 22-40 and 41-60, respectively) seem to interact directly with the HlyB/HlyD translocator since a PhoA fusion protein which contains either of the two regions was still secreted in a HlyB/HlyD-dependent mode, albeit at low efficiency. An efficient trans-complementing HlyB/HlyD system was only obtained from the pHLy152-encoded hly determinant when the regulatory hlyR element was provided in cis. Secretion of the PhoA-HlyA fusion protein did not interfere with the secretion of HlyA even when the fusion protein was induced to a high level. This suggests that the capacity of the HlyB/HlyD translocation system is high and not normally saturated by its natural HlyA substrate.