Identification and preliminary characterization of temperature-sensitive mutations affecting HlyB, the translocator required for the secretion of haemolysin (HlyA) from Escherichia coli

We have carried out a genetic analysis of Escherichia coli HlyB using in vitro(hydroxylamine) mutagenesis and regionally directed mutagenesis. From random mutagenesis, three mutants, temperature sensitive (Ts) for secretion, were isolated and the DNA sequenced: Glyl0Arg close to the N-terminus, Gly408Asp in a highly conserved small periplasmic loop region PIV, and Pro624Leu in another highly conserved region, within the ATP-binding region. Despite the Ts character of the Gly10 substitution, a derivative of HlyB, in which the first 25 amino acids were replaced by 21 amino acids of the Cro protein, was still active in secretion of HlyA. This indicates that this region of HlyB is dispensable for function. Interestingly, the Gly408Asp substitution was toxic at high temperature and this is the first reported example of a conditional lethal mutation in HlyB. We have isolated 4 additional mutations in PIV by directed mutagenesis, giving a total of 5 out of 12 residues substituted in this region, with 4 mutations rendering HlyB defective in secretion. The Pro624 mutation, close to the Walker B-site for ATP binding in the cytoplasmic domain is identical to a mutation in HisP that leads to uncoupling of ATP hydrolysis from the transport of histidine. The expression of a fully functional haemolysin translocation system comprising HlyC,A,B and D increases the sensitivity of E. coli to vancomycin 2.5-fold, compared with cells expressing HlyB and HlyD alone. Thus, active translocation of HlyA renders the cells hyperpermeable to the drug. Mutations in hlyB affecting secretion could be assigned to two classes: those that restore the level of vancomycin resistance to that of E. coli not secreting HlyA and those that still confer hypersensitivity to the drug in the presence of HlyA. We propose that mutations that promote vancomycin resistance will include mutations affecting initial recognition of the secretion signal and therefore activation of a functional transport channel. Mutations that do not alter HlyA-dependent vancomycin sensitivity may, in contrast, affect later steps in the transport process.     

In vivo and in vitro studies on interactions between the components of the hemolysin (HlyA) secretion machinery of Escherichia coli

The glycopeptide antibiotic vancomycin blocks cell wall synthesis in Escherichia coli only when it can reach its target site in the periplasm. In vivo, sensitivity to vancomycin is enhanced in the presence of the hemolysin (hly) determinant of E. coli or its translocator portion hlyBD. Two different mutations in hlyD alter the cell's susceptibility to vancomycin: mutations in the tolC-homologous region of hlyD increase vancomycin resistance, whereas mutations at the 3′-terminus of hlyD lead to hypersensitivity to vancomycin and to the accumulation of large periplasmic and cytoplasmic pools of this antibiotic in E. coli. These effects are only observed in the presence of functional HlyB and TolC, the two other components of the hemolysin secretion machinery. A defect in TolC causes hyperresistance to vancomycin, even when present together with a mutant HlyD protein which in the presence of TolC renders E. coli hypersensitive to vancomycin. Lipid bilayer experiments in vitro revealed specific interactions between TolC and vancomycin or HlyD protein. Second-site suppressor mutations in hlyD and hlyB were obtained, which abolish the hypersensitive phenotype caused by the 3′-terminal mutations in hlyD. Our results are compatible with the idea that (a) TolC, together with the TolC-homologous part of HlyD, forms a pore in the outer membrane through which hemolysin is released and vancomycin taken up; and (b) the C-terminal sequence of HlyD interacts with periplasmic loop(s) of HlyB to form a closed channel spanning the periplasm. Received: 7 April 1997 / Accepted: 28 May 1997     

Protein exporter function and in vitro ATPase activity are correlated in ABC-domain mutants of HlyB

The Escherichia coli toxin exporter HlyB comprises an integral membrane domain fused to a cytoplasmic domain of the ATP-binding casette (ABC) super-family, and it directs translocation of the 110kDa haemolysin protein out of the bacterial cell without using an N-terminal secretion signal peptide. We have exploited the ability to purify the soluble HlyB ABC domain as a fusion with glutathione S-transferase to obtain a direct correlation of the in vivo export of protein by HlyB with the degree of ATP binding and hydrolysis measured in vitro. Mutations in residues that are invariant or highly conserved in the ATP-binding fold and glycine-rich linker peptide of prokaryotic and eukaryotic ABC transporters caused a complete less of both HlyB exporter function and ATPase activity in proteins still able to bind ATP effectively and undergo ATP-induced conformational change. Mutation of less-conserved residues caused reduced export and ATP hydrolysis, but not ATP binding, whereas substitutions of poorly conserved residues did not impair activity either in vivo or in vitro. The data show that protein export by HlyB has an absolute requirement for the hydrolysis of ATP bound by its cytoplasmic domain and indicate that comparable mutations that disable other prokaryotic and eukaryotic ABC transporters also cause a specific loss of enzymatic activity.     

Extracellular PagC-HlyAS fusion protein for the generation and identification of Salmonella-specific antibodies

The outer membrane protein, PagC, of Salmonella typhimurium was converted into a secreted protein by linking the 61-amino-acid long, C-terminal signal sequence of the E. coli hemolysin protein (HlyA_S) to the mature PagC peptide. This PagC-HlyA_S fusion protein was expressed and efficiently secreted into the culture supernatant by E. coli upon complementation with the hemolysin secretion proteins HlyB and HlyD. Polyclonal antibodies raised against this fusion protein not only recognized PagC in the membrane fraction of all salmonellae by Western blotting, but also reacted with proteins of smaller size in other gram-negative bacteria tested. A monoclonal antibody against the PagC-HlyA_S fusion protein recognized only PagC in membrane fractions. The antibody-binding domain was determined using synthetic peptides derived from specific PagC domains. Sera from Salmonella-infected human patients and from a rabbit infected with S. typhimurium did not react with PagC in immunoblots, suggesting that PagC may not be recognized as a major antigen by the humoral immune system. Received: 16 August 1995/Received revision: 6 November 1995/Accepted: 10 November 1995     

Type 1 protein secretion in bacteria,the ABC-transporter dependent pathway (Review)

The relatively simple type 1 secretion system in Gram-negative bacteria is nevertheless capable of transporting polypeptides of up to 800 kDa across the cell envelope in a few seconds. The translocator is composed of an ABC-transporter, providing energy through ATP hydrolysis (and perhaps the initial channel across the inner membrane), linked to a multimeric Membrane Fusion Protein (MFP) spanning the initial part of the periplasm and forming a continuous channel to the surface with an outer membrane trimeric protein. Proteins targeted to the translocator carry an (uncleaved), poorly conserved secretion signal of approximately 50 residues. In E. coli the HlyA toxin interacts with both the MFP (HlyD) and the ABC protein HlyB, (a half transporter) triggering, via a conformational change in HlyD, recruitment of the third component, TolC, into the transenvelope complex. In vitro, HlyA, through its secretion signal, binds to the nucleotide binding domain (NBD or ABC-ATPase) of HlyB in a reaction reversible by ATP that may mimic initial movement of HlyA into the translocation channel. HlyA is then transported rapidly, apparently in an unfolded form, to the cell surface, where folding and release takes place. Whilst recent structural studies of TolC and MFP-like proteins are providing atomic detail of much of the transport path, structural analysis of the HlyB NBD and other ABC ATPases, have revealed details of the catalytic cycle within an NBD dimer and a glimpse of how the action of HlyB is coupled to the translocation of HlyA.     

Identification and preliminary characterization of temperature-sensitive mutations affecting HlyB,the translocator required for the secretion of haemolysin (HlyA) from Escherichia coli

We have carried out a genetic analysis of Escherichia coli HlyB using in vitro(hydroxylamine) mutagenesis and regionally directed mutagenesis. From random mutagenesis, three mutants, temperature sensitive (Ts) for secretion, were isolated and the DNA sequenced: Glyl0Arg close to the N-terminus, Gly408Asp in a highly conserved small periplasmic loop region PIV, and Pro624Leu in another highly conserved region, within the ATP-binding region. Despite the Ts character of the Gly10 substitution, a derivative of HlyB, in which the first 25 amino acids were replaced by 21 amino acids of the λ Cro protein, was still active in secretion of HlyA. This indicates that this region of HlyB is dispensable for function. Interestingly, the Gly408Asp substitution was toxic at high temperature and this is the first reported example of a conditional lethal mutation in HlyB. We have isolated 4 additional mutations in PIV by directed mutagenesis, giving a total of 5 out of 12 residues substituted in this region, with 4 mutations rendering HlyB defective in secretion. The Pro624 mutation, close to the Walker B-site for ATP binding in the cytoplasmic domain is identical to a mutation in HisP that leads to uncoupling of ATP hydrolysis from the transport of histidine. The expression of a fully functional haemolysin translocation system comprising HlyC,A,B and D increases the sensitivity of E. coli to vancomycin 2.5-fold, compared with cells expressing HlyB and HlyD alone. Thus, active translocation of HlyA renders the cells hyperpermeable to the drug. Mutations in hlyB affecting secretion could be assigned to two classes: those that restore the level of vancomycin resistance to that of E. coli not secreting HlyA and those that still confer hypersensitivity to the drug in the presence of HlyA. We propose that mutations that promote vancomycin resistance will include mutations affecting initial recognition of the secretion signal and therefore activation of a functional transport channel. Mutations that do not alter HlyA-dependent vancomycin sensitivity may, in contrast, affect later steps in the transport process.     

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 cytopiasmic 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. Mg²⁺ -dependent ATPase activity of GST-Bctp V_max 17mu;mol min^?1 mg^?1, K_m 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.     

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

Summary 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 (HlyA_s) ofEscherichia coli haemolysin (HlyA). Secretion of the AP-HlyA_s 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.     

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 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 theE. 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.     

Production of glucoamylase in pyruvate decarboxylase deletion mutants of the yeast Kluyveromyces lactis

We have developed a novel Escherichia coli cell surface display system by employing PgsA as an anchoring motif. In our display system, C-terminal fusion to PgsA anchor protein from Bacillus subtilis was used. The enzymes selected for display were α-amylase (AmyA) from Streptococcus bovis 148 and lipase B (CALB) from Candida antarctica. The molecular mass values of AmyA and CALB are approximately 77 and 34 kDa, respectively. The enzymes were displayed on the surface as a fusion protein with a FLAG peptide tag at the C terminus. Both the PgsA-AmyA-FLAG and PgsA-CALB-FLAG fusion proteins were shown to be displayed by immunofluorescence labeling using anti-FLAG antibody. The displayed enzymes were active forms, and AmyA and CALB activities reached 990 U/g (dry cell weight) and 4.6 U/g (dry cell weight), respectively. AmyA-displaying E. coli cells grew utilizing cornstarch as the sole carbon source, while CALB-displaying E. coli cells catalyzed enantioselective transesterification, indicating that they are effective whole-cell biocatalysts. Since a target enzyme with a size of 77 kDa and an industrially useful lipase have been successfully displayed on the cell surface of E. coli for the first time, PgsA protein is probably a useful anchoring motif to display various enzymes.     

In vivo and in vitro studies on interactions between the components of the hemolysin (HlyA) secretion machinery of Escherichia coli

The glycopeptide antibiotic vancomycin blocks cell wall synthesis in Escherichia coli only when it can reach its target site in the periplasm. In vivo, sensitivity to vancomycin is enhanced in the presence of the hemolysin (hly) determinant of E. coli or its translocator portion hlyBD. Two different mutations in hlyD alter the cell's susceptibility to vancomycin: mutations in the tolC-homologous region of hlyD increase vancomycin resistance, whereas mutations at the 3′-terminus of hlyD lead to hypersensitivity to vancomycin and to the accumulation of large periplasmic and cytoplasmic pools of this antibiotic in E. coli. These effects are only observed in the presence of functional HlyB and TolC, the two other components of the hemolysin secretion machinery. A defect in TolC causes hyperresistance to vancomycin, even when present together with a mutant HlyD protein which in the presence of TolC renders E. coli hypersensitive to vancomycin. Lipid bilayer experiments in vitro revealed specific interactions between TolC and vancomycin or HlyD protein. Second-site suppressor mutations in hlyD and hlyB were obtained, which abolish the hypersensitive phenotype caused by the 3′-terminal mutations in hlyD. Our results are compatible with the idea that (a) TolC, together with the TolC-homologous part of HlyD, forms a pore in the outer membrane through which hemolysin is released and vancomycin taken up; and (b) the C-terminal sequence of HlyD interacts with periplasmic loop(s) of HlyB to form a closed channel spanning the periplasm.     

Topological and functional studies on HlyB of Escherichia coli

Summary The topology of HlyB, a protein located in the inner membrane of Escherichia coli and involved in the secretion of -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, -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-HlyA_s 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.     

Improved Secretory Production of Recombinant Proteins by Random Mutagenesis of hlyB, an Alpha-Hemolysin Transporter from Escherichia coli

Fusion proteins with an alpha-hemolysin (HlyA) C-terminal signal sequence are known to be secreted by the HlyB-HlyD-TolC translocator in Escherichia coli. We aimed to establish an efficient Hly secretory expression system by random mutagenesis of hlyB and hlyD. The fusion protein of subtilisin E and the HlyA signal sequence (HlyA₂₁₈) was used as a marker protein for evaluating secretion efficiency. Through screening of more than 1.5 × 10⁴ E. coli JM109 transformants, whose hlyB and hlyD genes had been mutagenized by error-prone PCR, we succeeded in isolating two mutants that had 27- and 15-fold-higher levels of subtilisin E secretion activity than the wild type did at 23°C. These mutants also exhibited increased activity levels for secretion of a single-chain antibody-HlyA₂₁₈ fusion protein at 23 and 30°C but unexpectedly not at 37°C, suggesting that this improvement seems to be dependent on low temperature. One mutant (AE104) was found to have seven point mutations in both HlyB and HlyD, and an L448F substitution in HlyB was responsible for the improved secretion activity. Another mutant (AE129) underwent a single amino acid substitution (G654S) in HlyB. Secretion of c-Myc-HlyA₂₁₈ was detected only in the L448F mutant (AE104F) at 23°C, whereas no secretion was observed in the wild type at any temperature. Furthermore, for the PTEN-HlyA₂₁₈ fusion protein, AE104F showed a 10-fold-higher level of secretion activity than the wild type did at 37°C. This result indicates that the improved secretion activity of AE104F is not always dependent on low temperature.     

Properties of the Escherichia coli rhodanese-like protein SseA: contribution of the active-site residue Ser240 to sulfur donor recognition

The product of Escherichia coli sseA gene (SseA) was the subject of the present investigation aimed to provide a tool for functional classification of the bacterial proteins of the rhodanese family. E. coli SseA contains the motif CGSGVTA around the catalytic cysteine (Cys238). In eukaryotic sulfurtransferases this motif discriminates for 3-mercaptopyruvate:cyanide sulfurtransferase over thiosulfate:cyanide sulfurtransferases (rhodanese). The biochemical characterization of E. coli SseA allowed the identification of the first prokaryotic protein with a preference for 3-mercaptopyruvate as donor substrate. Replacement of Ser240 with Ala showed that the presence of a hydrophobic residue did not affect the binding of 3-mercaptopyruvate, but strongly prevented thiosulfate binding. On the contrary, substitution of Ser240 with an ionizable residue (Lys) increased the affinity for thiosulfate.     

Antibody analysis of the localisation, expression and stability of HlyD, the MFP component of the E. coli haemolysin translocator

HlyD has a single transmembrane domain (residues 59-80) and a large periplasmic domain, and is essential for the secretion of haemolysin from Escherichia coli. Using an antibody raised against HlyD, the protein was localised to the cell envelope by immunofluorescence and to the cytoplasmic membrane by sucrose gradient analysis. We have examined the stability of this protein in the presence and absence of other putative components of the translocator, HlyB and TolC. HlyD is normally highly stable but in the absence of TolC, the steady-state level of HlyD is greatly reduced and the protein has a half-life at 37° C of 36 min. In the absence of HlyB, HlyD is also unstable and specific degradation products are detected, which co-fractionate with the inner membrane, indicating in this case limited cleavage at specific sites. However, the effect of removing both HlyB and TolC is not additive. On the contrary, in the absence of both HlyB and TolC the half-life of HlyD is approximately 110 min. This result shows that in the presence of HlyB removal of TolC renders HlyD more unstable than it is in the absence of both HlyB and TolC. This suggests that the presence of HlyB induces a structural change in HlyD. In addition, HlyB itself appears to be less stable in the absence of HlyD. These results are consistent with an interaction between HlyD/TolC and HlyB/HlyD. A derivative of HlyD, HlyD22, lacking the 40 N-terminal residues of HlyD assembles into the inner membrane displaying the same stability with and without HlyB as wild type HlyD does. This N-terminal region therefore appears to play no role in stable localisation but is involved in secretion, since HlyD22 is completely secretion defective. Modification of the C-terminus on the other hand completely destabilised the molecule and HlyD was not detectable in the envelope. Secretion of active haemolysin is limited to a brief period during mid to late exponential phase. In contrast, HlyD is apparently synthesised constitutively throughout the growth phase, demonstrating that the production of this component of the translocator is not the limiting factor for growth phase-dependent secretion. Received: 10 July 1998 / Accepted: 19 October 1998     

Physiological characteristics of recombinant Escherichia coli cells displaying poly-His peptides

Using the Escherichia coli OmpC protein as an anchoring motif, four different poly-His units (1, 2, 3 and 6 copies of 6-His) were displayed on the seventh loop of the OmpC. Recombinant E. coli strains displaying 1, 3 or 6 copies of poly-His became much more sensitive to SDS (0.1%, w/v) and EDTA (2 mM) compared with control strains. However, recombinant E. coli cells displaying 2 copies of poly-His were resistant to SDS and EDTA; greater than 70% and 90% of cells maintained cell integrity after 60 min treatment with SDS and EDTA, respectively, suggesting its usefulness as a whole cell biosorbent.