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

Change in the cellular localization of alkaline phosphatase by alteration of its carboxy-terminal sequence

Alkaline phosphatase (AP) is secreted into the medium when the carboxy-terminal 25 amino acids are replaced by the 60 amino acid carboxy-terminal signal peptide (HlyAs) of Escherichia coli haemolysin (HlyA). Secretion of the AP-HlyAs fusion protein is dependent on HlyB and HlyD but independent of SecA and SecY. The efficiency of secretion by HlyB/HlyD is decreased when AP carries its own N-terminal signal peptide. Translocation of this fusion protein into the periplasm is not observed even in the absence of HlyB/HlyD. The failure of the Sec export machinery to transport the latter protein into the periplasm seems to be due in part to the loss of the carboxy-terminal sequence of AP since even AP derivatives which do not carry the HlyA signal peptide but lack the 25 C-terminal amino acids of AP are localized in the membrane but not translocated into the periplasm.

DNA sequence analysis of pglA and mechanism of export of its polygalacturonase product from Pseudomonas solanacearum

The pglA gene encodes a 52-kilodalton extracellular polygalacturonase (PGA) which is associated with the phytopathogenic virulence of Pseudomonas solanacearum. The nucleotide sequence of pglA and the putative amino acid sequence of the PGA protein were determined. A computer search identified a 150-residue region of PGA which was similar (41%) to the amino acid sequence of a region of the PG-2A polygalacturonase from tomato. Comparison of the amino terminus of the pglA open reading frame with the actual amino-terminal sequence of purified extracellular PGA suggested that pglA is initially translated as a higher-molecular-mass precursor with a 21-residue amino-terminal signal sequence. Localization of various pglA-phoA fusion proteins in Escherichia coli and P. solanacearum indicated that the 21-residue leader sequence directs the export of PhoA only as far as the periplasm of both bacteria. Deletion of the last 13 residues of PGA eliminated its catalytic activity, as well as its ability to be exported outside of the P. solanacearum cell. Our results suggest that PGA excretion occurs in two steps. The first step involves a signal sequence cleavage mechanism similar to that used for periplasmic proteins and results in export of PGA across the inner membrane; the second step (transit of the outer membrane) occurs by an unknown mechanism requiring sequences from the mature PGA protein and biochemical factors absent from E. coli.

Translocation and compartmentalization of Escherichia coli hemolysin (HlyA)

Hemolysin plasmids were constructed with mutations in hlyB, hlyD, or both transport genes. The localization of hemolysin activity and HlyA protein in these mutants was analyzed by biochemical and immunological methods. It was found that mutants defective in hlyB accumulated internal hemolysin, part of which was associated with the inner membrane and was degraded in the late logarithmic growth phase. In an HlyB+ HlyD- mutant, hemolysin was predominantly localized in the membrane compartment. Labeling of these Escherichia coli cells with anti-HlyA antibody indicated that part of HlyA, presumably the C-terminal end but not the pore-forming domains, was already transported to the cellular surface. This finding suggests that HlyB is able to recognize the C-terminal signal of the HlyA protein and to initiate its translocation across the membranes.

The mechanism of secretion of hemolysin and other polypeptides from gram-negative bacteria

In the secretion of polypeptides from Gram-negative bacteria, the outer membrane constitutes a specific barrier which has to be circumvented. In the majority of systems, secretion is a two-step process, with initial export to the periplasm involving an N-terminal signal sequence. Transport across the outer membrane then involves a variable number of ancillary polypeptides including both periplasmic and outer membrane. While such ancillary proteins are probably specific for each secreted protein, the mechanism of movement across the outer membrane is unknown. In contrast to these systems, secretion of the E. coli hemolysin (HlyA) has several distinctive features. These include a novel targeting signal located within the last 50 or so C-terminal amino acids, the absence of any periplasmic intermediates in transfer, and a specific membrane-bound translocator, HlyB, with important mammalian homologues such as P-glycoprotein (Mdr) and the cystic fibrosis protein. In this review we discuss the nature of the HlyA targeting signal, the structure and function of HlyB, and the probability that HlyA is secreted directly to the medium through a trans-envelope complex composed of HlyB and HlyD.

Characterisation and sequence of a protective rhoptry antigen from Plasmodium falciparum

We have recently demonstrated that a non-polymorphic rhoptry antigen, RAP-1 (rhoptry associated protein-1), which is recognised by human immune serum, can successfully protect Saimiri monkeys from a lethal infection of Plasmodium falciparum malaria. In this report we further characterise the antigen, which consists of four major proteins of 80, 65, 42 and 40 kDa and two minor proteins of 77 and 70 kDa, and present the antigen's gene sequence. Monoclonal antibody evidence, autocatalytic processing and immunological cross-reactivity suggest that all components of this antigen are derived from the same precursor protein. The antigen is lipophilic, and disulphide bonding plays an important role in its structure. We discuss the structure and function of RAP-1 in the light of its deduced amino acid sequence and consider the relationship of this antigen to other rhoptry antigens of similar subunit size and composition.

Structure and function of haemolysin B,P-glycoprotein and other members of a novel family of membrane translocators

Recent studies have identified two sub-families of highly conserved polypeptides in a wide variety of organisms concerned with the transport of many different compounds, specific for each transport protein. Both families, represented by HisP and HlyB, respectively, have in common a highly conserved, approximately 25 kD domain, containing an ATP-binding site. The HisP sub-family essentially consists of cytoplasmic proteins which couple energy to the import of small substrates through cytoplasmic membrane permeases in Gram-negative bacteria. The HlyB (P-glycoprotein) sub-family, on the other hand, contains a second large domain which apparently acts as the transmembrane translocator itself, which in most cases drives the secretion of a variety of compounds. These membrane domains share a number of structural features which also serve to distinguish these proteins as a closely related group. Nevertheless, the compounds secreted by the HlyB sub-family include large polypeptides, polysaccharides and a variety of anti-tumour drugs. We describe here the properties of each of these remarkable proteins and we speculate on their possible mechanism of action.

The cytotoxic protein YopE of Yersinia obstructs the primary host defence

It has previously been shown that the plasmid-encoded YopE protein of Yersinia pseudotuberculosis is a virulence determinant. In this study, HeLa cells, macrophages and mice were used as different model systems to determine the actual role of YopE in the virulence process. The YopE protein mediates a cytotoxic response on a confluent layer of HeLa cells. A prerequisite of this activity is that the pathogen binds to the cell surface. YopE also induces a cytotoxic response on mouse macrophages where it influences the ability of the pathogen to resist phagocytosis. Bacterial mutants defective in their ability to express YopE are avirulent after oral or intraperitoneal infection but virulent following intravenous injection. On the basis of these results, we propose a role for YopE in the virulence process of Yersinia.

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.

Haemolysin secretion from E coli

Haemolysin (HlyA) secretion from E coli is directed by a specific C-terminal targeting signal, located within the last 27-50 amino acids, with quite novel characteristics. The HlyA molecule is secreted directly to the medium without a periplasmic intermediate or detectable proteolytic processing. The C-terminal domain of HlyA can also be used to promote the secretion of several other E coli and mammalian proteins. HlyD and HlyB are essential for translocation of HlyA to the medium and we propose that these proteins form a transenvelope complex which initially binds the HlyA signal followed by transport of HlyA to the medium. HlyB is a member of a family of membrane proteins engaged in ATP dependent secretion mechanisms conserved in many organisms including man (P-glycoprotein and the CF protein). In this review we discuss the structure, function and regulation of the secretion mechanism.

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.

Secretion, processing and activation of bacterial extracellular proteases

Many different bacteria secrete proteases into the culture medium. Extracellular proteases produced by Gram-positive bacteria are secreted by a signal-peptide-dependent pathway and have a propeptide located between the signal peptide and the mature protein. Many extracellular proteases synthesized by Gram-negative bacteria are also produced as precursors with a signal peptide. However, at least two species of Gram-negative bacteria secrete one or more proteases via a novel signal-peptide-independent route. Most proteases secreted by Gram-negative bacteria also have a propeptide whose length and location vary according to the protease. Specific features of protease secretion pathways and the mechanisms of protease activation are discussed with particular reference to some of the best-characterized extracellular proteases produced by Gram-positive and Gram-negative bacteria.

PapD, a periplasmic transport protein in P-pilus biogenesis

The product of the papD gene of uropathogenic Escherichia coli is required for the biogenesis of digalactoside-binding P pili. Mutations within papD result in complete degradation of the major pilus subunit, PapA, and of the pilinlike proteins PapE and PapF and also cause partial breakdown of the PapG adhesin. The papD gene was sequenced, and the gene product was purified from the periplasm. The deduced amino acid sequence and the N-terminal sequence obtained from the purified protein revealed that PapD is a basic and hydrophilic peripheral protein. A periplasmic complex between PapD and PapE was purified from cells that overproduced and accumulated these proteins in the periplasm. Antibodies raised against this complex reacted with purified wild-type P pili but not with pili purified from a papE mutant. In contrast, anti-PapD serum did not react with purified pili or with the culture fluid of piliated cells. However, this serum was able to specifically precipitate the PapE protein from periplasmic extracts, confirming that PapD and PapE were associated as a complex. It is suggested that PapD functions in P-pilus biogenesis as a periplasmic transport protein. Probably PapD forms complexes with pilus subunits at the outer surface of the inner membrane and transports them in a stable configuration across the periplasmic space before delivering them to the site(s) of pilus polymerization.

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.