Influence of deletions within domain II of exotoxin A on its extracellular secretion from Pseudomonas aeruginosa

Pseudomonas aeruginosa is a gram-negative bacterium that secretes many proteins into the extracellular medium via the Xcp machinery. This pathway, conserved in gram-negative bacteria, is called the type II pathway. The exoproteins contain information in their amino acid sequence to allow targeting to their secretion machinery. This information may be present within a conformational motif. The nature of this signal has been examined for P. aeruginosa exotoxin A (PE). Previous studies failed to identify a common minimal motif required for Xcp-dependent recognition and secretion of PE. One study identified a motif at the N terminus of the protein, whereas another one found additional information at the C terminus. In this study, we assess the role of the central PE domain II composed of six alpha-helices (A to F). The secretion behavior of PE derivatives, individually deleted for each helix, was analyzed. Helix E deletion has a drastic effect on secretion of PE, which accumulates within the periplasm. The conformational rearrangement induced in this variant is predicted from the three-dimensional PE structure, and the molecular modification is confirmed by gel filtration experiments. Helix E is in the core of the molecule and creates close contact with other domains (I and III). Deletion of the surface-exposed helix F has no effect on secretion, indicating that no secretion information is contained in this helix. Finally, we concluded that disruption of a structured domain II yields an extended form of the molecule and prevents formation of the conformational secretion motif.     

A periplasmic intermediate in the extracellular secretion pathway of Pseudomonas aeruginosa exotoxin A.

Pseudomonas aeruginosa exotoxin A is synthesized with a secretion signal peptide typical of proteins whose final destination is the periplasm. However, exotoxin A is released from the cell without a detectable periplasmic pool, suggesting that additional determinants in this protein are important for recognition by a specialized machinery of extracellular secretion. The role of the N terminus of the mature exotoxin A in this recognition was investigated. A series of exotoxin A proteins with amino acid substitutions for the glutamic acid pair at the +2 and +3 positions were constructed by mutagenesis of the exotoxin A gene. These N-terminal acidic residues of the mature exotoxin A protein were found to be important not only for efficient processing of the precursor protein but also for extracellular localization of the toxin. The mutated exotoxin A proteins, in which a glutamic acid at the +2 position was replaced by a lysine or a double substitution of lysine and glutamine for the pair of adjacent glutamic acids, accumulated in precursor forms in the mixed cytoplasmic and membrane fractions, which was not seen with the wild-type exotoxin A. The processing of the precursor form of one exotoxin A mutant, in which the glutamic acid at the +2 position was replaced with a glutamine, was not affected. Moreover, a substantial fraction of the mature forms of all three mutants of exotoxin A accumulated in the periplasm, while wild-type exotoxin A could be detected only extracellularly. The periplasmic pools of these variants of exotoxin A could therefore represent the intermediate state during extracellular secretion. The signal for extracellular localization may be located in a small region near the amino terminus of the mature protein or could consist of several regions that are brought together after the polypeptide has folded. Alternatively, the acidic residues may be important for ensuring a conformation essential for exotoxin A to traverse the outer membrane.     

Crystallization of exotoxin A from Pseudomonas aeruginosa

Exotoxin A from Pseudomonas aeruginosa has been crystallized in a form suitable for high resolution diffraction analysis. The crystals, grown in the presence of high concentrations of polyethylene glycol (20%, w/v) and of NaCl (1.5 m), are monoclinic and contain one monomeric toxin molecule per asymmetric unit. The space group is P2₁, with $\text{a = 60.6}\text{A}\text{?}\text{, b = 100.2}\text{A}\text{?}\text{, c = 59.8}\text{A}\text{?}\text{, β = 98.6 °}$.     

A novel extracellular phospholipase C of Pseudomonas aeruginosa is required for phospholipid chemotaxis

Pseudomonas aeruginosa and other bacterial pathogens express one or more homologous extracellular phospholipases C (PLC) that are secreted through the inner membrane via the twin arginine translocase (TAT) pathway. Analysis of TAT mutants of P. aeruginosa uncovered a previously unidentified extracellular PLC that is secreted via the Sec pathway (PlcB). Whereas all presently known PLCs of P. aeruginosa (PlcH, PlcN and PlcB) hydrolyse phosphatidylcholine (PC), only PlcB is active on phosphatidylethanolamine (PE). plcB candidates were identified based on deductions made from bioinformatics data and extant DNA microarray data. Among these candidates, a gene (PA0026) required for the expression of an extracellular PE-PLC was identified. The protein encoded by PA0026 has limited, but significant similarity, over a short region (approximately 60aa of 328), to a class of zinc-dependent prokaryotic PLCs. A conserved His residue of PlcB (His216) that is required for coordinate binding of zinc in this class of PLCs was mutated. Analysis of this mutant established that the protein encoded by PA0026 is PlcB. Three in-dependent recently published reports indicate that homoserine lactone-mediated quorum sensing regulates the expression of PA0026 (i.e. plcB). PlcB, but not PlcH or PlcN, is required for directed twitching motility up a gradient of certain kinds of phospholipids. This response shows specificity for the fatty acid moiety of the phospholipid.     

假单孢菌外毒素A的介绍

介绍了假单孢菌外毒素Ａ的理化性质,分子结构与功能的关系以及假单孢菌外毒素Ａ的应用前景。     

Identification of regB, a gene required for optimal exotoxin A yields in Pseudomonas aeruginosa

The yield of exotoxin A from Pseudomonas aeruginosa has been shown to be strain-dependent. Exotoxin A production requires the presence of the positive regulatory gene, regA. We cloned the regA genetic locus from the prototypical P. aeruginosa strain PAO1 and examined its ability to influence exotoxin A yields compared to the same region cloned from the hypertoxin-producing strain, PA103. The P. aeruginosa regA mutant strain, PA103-29, containing the PAO1 regA locus in trans produced approximately five to seven times less extracellular exotoxin A than PA103-29 containing the regA locus cloned from the hypertoxigenic strain, PA103. Nucleotide sequence analysis of the PAO1 regA locus revealed several differences, the most striking of which was the absence of a second open reading frame that was present in the analogous PA103 DNA. In addition, an amino acid substitution was found at position 144 of RegA (Thr in PAO1 and Ala in PA103). Recombinant molecules were constructed to test the contribution of each of these changes in nucleotide sequence on extracellular exotoxin A yields. The amino acid substitution in the PAO1 RegA protein was found not to affect overall exotoxin A yields. In contrast, the presence of the second open reading frame immediately downstream of the PA103 regA gene was found to influence extracellular exotoxin A yields. This open reading frame encodes a gene which we call regB. Nucleotide sequence analysis indicates that regB is 228 nucleotides in length and encodes a protein of 7527 Daltons. Our data suggest that regB is required for optimal exotoxin A production and its absence in strain PAO1 partially accounts for the difference in yield of extracellular exotoxin A between P. aeruginosa strains PAO1 and PA103.     

A catalytic loop within Pseudomonas aeruginosa exotoxin A modulates its transferase activity.

Mutagenesis techniques were used to replace two loop regions within the catalytic domain of Pseudomonas aeruginosa exotoxin A (ETA) with functionally silent polyglycine loops. The loop mutant proteins, designated polyglycine Loops N and C, were both less active than the wild-type enzyme. However, the polyglycine Loop C mutant protein, replaced with the Gly(483)-Gly(490) loop, showed a much greater loss of enzymatic activity than the polyglycine Loop N protein. The former mutant enzyme exhibited an 18,000-fold decrease in catalytic turnover number (k(cat)), with only a marginal effect on the K(m) value for NAD(+) and the eukaryotic elongation factor-2 binding constant. Furthermore, alanine-scanning mutagenesis of this active-site loop region revealed the specific pattern of a critical region for enzymatic activity. Binding and kinetic data suggest that this loop modulates the transferase activity between ETA and eukaryotic elongation factor-2 and may be responsible for stabilization of the transition state for the reaction. Sequence alignment and molecular modeling also identified a similar loop within diphtheria toxin, a functionally and structurally related class A-B toxin. Based on these results and the similarities between ETA and diphtheria toxin, we propose that this catalytic subregion represents the first report of a diphthamide-specific ribosyltransferase structural motif. We expect these findings to further the development of pharmaceuticals designed to prevent ETA toxicity by disrupting the stabilization of the transition state during the ADP-ribose transfer event.     

Correct folding of alpha-lytic protease is required for its extracellular secretion from Escherichia coli

alpha-Lytic protease is a bacterial serine protease of the trypsin family that is synthesized as a 39-kD preproenzyme (Silen, J. L., C. N. McGrath, K. R. Smith, and D. A. Agard. 1988. Gene (Amst.). 69: 237-244). The 198-amino acid mature protease is secreted into the culture medium by the native host, Lysobacter enzymogenes (Whitaker, D. R. 1970. Methods Enzymol. 19:599-613). Expression experiments in Escherichia coli revealed that the 166-amino acid pro region is transiently required either in cis (Silen, J. L., D. Frank, A. Fujishige, R. Bone, and D. A. Agard. 1989. J. Bacteriol. 171:1320-1325) or in trans (Silen, J. L., and D. A. Agard. 1989. Nature (Lond.). 341:462-464) for the proper folding and extracellular accumulation of the enzyme. The maturation process is temperature sensitive in E. coli; unprocessed precursor accumulates in the cells at temperatures above 30 degrees C (Silen, J. L., D. Frank, A. Fujishige, R. Bone, and D. A. Agard. 1989. J. Bacteriol. 171:1320-1325). Here we show that full-length precursor produced at nonpermissive temperatures is tightly associated with the E. coli outer membrane. The active site mutant Ser 195----Ala (SA195), which is incapable of self-processing, also accumulates as a precursor in the outer membrane, even when expressed at permissive temperatures. When the protease domain is expressed in the absence of the pro region, the misfolded, inactive protease also cofractionates with the outer membrane. However, when the folding requirement for either wild-type or mutant protease domains is provided by expressing the pro region in trans, both are efficiently secreted into the extracellular medium. Attempts to separate folding and secretion functions by extensive deletion mutagenesis within the pro region were unsuccessful. Taken together, these results suggest that only properly folded and processed forms of alpha-lytic protease are efficiently transported to the medium.     

Erythrocyte diagnostic kits for detection of Pseudomonas aeruginosa exotoxin A

The use of formulated chick red blood cells loaded with IgG preparations and affinity-purified antibodies, in comparison with initial immune serum to P. aeruginosa exotoxin A (ETA), has been shown to increase the sensitivity of antibody erythrocyte diagnosticum (AbED) 17-fold and to ensure the detection of ETA at a concentration of 1.2 mg of protein per ml. The passive hemagglutination (PHA) test with AbED has proved to be a more sensitive method for the detection of ETA than the antibody neutralization test with the use of antigenic erythrocyte diagnosticum, the latex agglutination test, the coagglutination test and the enzyme immunoassay. The PHA test has permitted the detection of ETA in the culture fluid of 80% of P. aeruginosa cultures under study.     

Purification of extracellular lipase from Pseudomonas aeruginosa.

Lipase (triacylglycerol acylhydrolase, EC 3.1.1.3) was excreted by Pseudomonas aeruginosa PAC1R during the late logarithmic growth phase. Characterization of cell-free culture supernatants by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed the presence of significant amounts of lipopolysaccharide, part of which seemed to be tightly bound to lipase. After concentration of culture supernatants by ultrafiltration, lipase-lipopolysaccharide complexes were dissociated by treatment with EDTA-Tris buffer and subsequent sonication in the presence of the zwitterionic detergent 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate. The solubilized lipase was purified by isoelectric focusing in an agarose gel containing the same detergent; the lipase activity appeared in a single peak corresponding to a distinct band in the silver-stained gel. The isoelectric point was 5.8. Analysis of purified lipase by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and scanning revealed an apparent molecular weight of 29,000 and a specific activity of 760 mu kat/mg of protein. Estimations based on these data showed that a single P. aeruginosa cell excreted about 200 molecules of lipase, each having a molecular activity of 2.2 X 10(4) per s.     

Production of an diagnostic erythrocyte agent from Pseudomonas aeruginosa exotoxin A

The sensitization of formolized sheep red blood cells with exotoxin A by means of chromium chloride or glutaraldehyde is more effective with respect to their sensitivity in the passive hemagglutination test than loading by means of amidol, tannin and rivanol. The use of chromium chloride decreases the consumption of exotoxin A 2, 8, 16 and 16 times in comparison with the use of amidol, tannin, rivanol or glutaraldehyde respectively. The high specificity of erythrocyte diagnosticum obtained from exotoxin A by means of chromium chloride is indicated in the study of hyperimmune sera to 22 different antigens of enteric bacteria and staphylococci in the passive hemagglutination test and to 10 different enterobacterial and staphylococcal antigens in the antibody neutralization test.     

Biochemical analysis of CRM 66. A nonfunctional Pseudomonas aeruginosa exotoxin A

Pseudomonas aeruginosa exotoxin A (ETA) is an ADP-ribosyltransferase which inactivates protein synthesis by covalently attaching the ADP-ribose portion of NAD+ onto eucaryotic elongation factor 2 (EF-2). A direct biochemical comparison has been made between ETA and a nonenzymatically active mutant toxin (CRM 66) using highly purified preparations of each protein. The loss of ADP-ribosyltransferase activity and subsequent cytotoxicity have been correlated with the presence of a tyrosine residue in place of a histidine at position 426 in CRM 66. In the native conformation, CRM 66 demonstrated a limited ability (by a factor or at least 100,000) to modify EF-2 covalently and lacked in vitro and in vivo cytotoxicity, yet CRM 66 appeared to be normal with respect to NAD+ binding. Upon activation with urea and dithiothreitol, CRM 66 lost ADP-ribosyltransferase activity entirely yet CRM 66 retained the ability to bind NAD+. Replacement of Tyr-426 with histidine in CRM 66 completely restored cytotoxicity and ADP-ribosyltransferase activity. These results support previous findings from this laboratory (Wozniak, D. J., Hsu, L.-Y., and Galloway, D. R. (1988) Proc. Natl. Acad. Sci. U. S. A. 85, 8880-8884) which suggest that the His-426 residue of ETA is not involved in NAD+ binding but appears to be associated with the interaction between ETA and EF-2.     

Protein secretion in Pseudomonas aeruginosa.

The Gram-negative bacterium Pseudomonas aeruginosa secretes many proteins into the extracellular medium. At least two distinct secretion pathways can be discerned. The majority of the exoproteins are secreted via a two-step mechanism. These proteins are first translocated across the inner membrane in a signal sequence-dependent fashion. The subsequent translocation across the outer membrane requires the products of at least 12 distinct xcp genes. The exact role of one of these proteins, the XcpA protein, has been resolved. It is a peptidase that is required for the processing of the precursors of four other Xcp proteins, thus allowing their assembly into the secretion apparatus. This peptidase is also required for the processing of the precursors of type IV pili subunits. Two other Xcp proteins, XcpR and XcpS, display extensive homology to proteins involved in pili biogenesis, which suggests that the assembly of the secretion apparatus and the biogenesis of type IV pili are related processes. The secretion of alkaline protease does not require the xcp gene products. This enzyme, which is encoded by the aprA gene, is not synthesized in a precursor form with an N-terminal signal sequence. Secretion across the two membranes probably takes place in one step at adhesion zones that may be constituted by three accessory proteins, designated AprD, AprE and AprF. The two secretion pathways found in P. aeruginosa appear to have disseminated widely among Gram-negative bacteria.