Detection and subcellular localization of three Ptl proteins involved in the secretion of pertussis toxin from Bordetella pertussis.

The ptl locus of Bordetella pertussis contains eight open reading frames which are predicted to encode proteins (PtlA to PtlH) that are essential for secretion of pertussis toxin from the bacterium and which are members of a family of transport proteins found in other types of bacteria. We have detected PtlE, PtlF, and PtlG in immunoblots of extracts of B. pertussis by using antibodies raised to fusion proteins consisting of maltose-binding protein and the individual Ptl proteins. These proteins have apparent molecular weights similar to those predicted by DNA sequence analysis. Cell fractionation studies indicated that all three Ptl proteins are associated with the membranes of B. pertussis, suggesting that the Ptl proteins form a gate or channel which facilitates transport of pertussis toxin. Cell extracts of other Bordetella spp. were probed with antibodies to Ptl proteins for the presence of these transport proteins. Neither Bordetella parapertussis nor Bordetella bronchiseptica contained detectable levels of PtlE or PtlF. This lack of detectable Ptl protein may provide an explanation for previous observations which indicated that introduction of the genes encoding pertussis toxin subunits from B. pertussis into other Bordetella spp. results in production of the toxin but not secretion of the toxin.     

Stabilization of the pertussis toxin secretion apparatus by the C terminus of PtlD

Pertussis toxin (PT) is secreted from Bordetella pertussis by a type IV secretion system, known as the Ptl transporter, that comprises nine different proteins, PtlA to PtlI. In this study, we found that PtlD is required for the stability of three Ptl proteins, PtlE, PtlF, and PtlH. A region limited to the C-terminal 72 amino acids of PtlD (amino acids 392 to 463) was sufficient for maintaining the stability of PtlE, PtlF, and PtlH, although this region was not sufficient to support secretion of the toxin. Further analysis demonstrated that a stretch of 10 amino acids at the C-terminal end of PtlD (amino acids 425 to 434) contributes to transporter stability.     

The subunit S1 is important for pertussis toxin secretion

Pertussis toxin is a protein containing five noncovalently linked subunits which are assembled into the monomer A (containing the subunit S1) and the oligomer B (containing subunits S2, S3, S4, and S5 in a 1:1:2:1 ratio). Each of the five subunits is synthesized as a precursor containing a secretory leader peptide and is secreted into the periplasm of Bordetella pertussis where the five subunits are assembled into the oligomeric structure and then released into the culture medium. In the absence of subunit S3 the remaining subunits are not secreted into the medium, thus suggesting that the assembled structure is necessary for the release of the toxin into the supernatant. In this study we describe four B. pertussis mutants which secrete into the medium low amounts of the B oligomer of pertussis toxin. These mutants have single or multiple changes in the gene encoding the S1 subunit and synthesize S1 proteins with altered conformation which are not assembled into the holotoxin and are apparently degraded in the periplasm. These data indicate that while the B oligomer alone has the structural information necessary for the extracellular export of pertussis toxin, the S1 subunit is required for its efficient release into the medium.     

The ins and outs of pertussis toxin

Pertussis toxin, produced and secreted by the whooping cough agent Bordetella pertussis, is one of the most complex soluble bacterial proteins. It is actively secreted through the B. pertussis cell envelope by the Ptl secretion system, a member of the widespread type IV secretion systems. The toxin is composed of five subunits (named S1 to S5 according to their decreasing molecular weights) arranged in an A-B structure. The A protomer is composed of the enzymatically active S1 subunit, which catalyzes ADP-ribosylation of the α subunit of trimeric G proteins, thereby disturbing the metabolic functions of the target cells, leading to a variety of biological activities. The B oligomer is composed of 1S2:1S3:2S4:1S5 and is responsible for binding of the toxin to the target cell receptors and for intracellular trafficking via receptor-mediated endocytosis and retrograde transport. The toxin is one of the most important virulence factors of B. pertussis and is a component of all current vaccines against whooping cough.     

Transient entry of enterotoxin subunits into the periplasm occurs during their secretion from Vibrio cholerae.

Cholera toxin and heat-labile enterotoxin (LT) are structurally similar oligomeric proteins which are capable of being efficiently secreted from Vibrio cholerae. Here we report that these proteins transiently enter the periplasm of V. cholerae as they traverse the cell envelope to reach the extracellular milieu. Pulse-chase experiments on V. cholerae TRH7000 harboring an LT-encoding plasmid revealed that radiolabeled LT A and B subunits entered the periplasm rapidly, followed by their slow efflux (half-time, 13 min) into the medium. LT B-subunit efflux from the periplasm was calculated to be at a rate of ca. 170 monomers per min per cell (which is equivalent to 34 assembled LT holotoxin molecules per min per cell). These values were estimated to be sufficient to account for the increase in extracellular enterotoxin concentration during exponential cell growth. Thus, all enterotoxin subunits which are secreted into the medium can be assumed to be channelled via the periplasm. These findings led to an improved model of the pathway of toxin secretion by V. cholerae.     

The PtlE protein of Bordetella pertussis has peptidoglycanase activity required for Ptl-mediated pertussis toxin secretion

Pertussis toxin of Bordetella pertussis is secreted by a type IV secretion system comprised of the products of the nine ptl (pertussis toxin liberation) genes. These proteins are believed to form a complex spanning both the inner and outer membranes and passing through the peptidoglycan layer. Peptidoglycan acts as a barrier for transport through the periplasm of large folded molecules. Assembled pertussis toxin and the secretion component proteins PtlC through PtlH are too large to diffuse through intact peptidoglycan. Therefore, we hypothesized that the Ptl system contains a peptidoglycanase activity. The PtlE protein was found to exhibit a sequence match to the active site of glycohydrolase enzymes. An N-terminally polyhistidine-tagged PtlE fusion protein, constructed and expressed in Escherichia coli and in B. pertussis, exhibited peptidoglycanase activity on activity gels. A fusion protein with alanine substitutions at the putative active site residues (aspartic acid at position 53 and glutamic acid at position 62) lacked peptidoglycanase activity. B. pertussis strains with the amino acid substitutions were deficient for pertussis toxin secretion. Based on these results, we concluded that PtlE is a peptidoglycanase responsible for the local removal or rearrangement of the peptidoglycan layer during Ptl secretion complex assembly.     

Genetic exchange of the S2 and S3 subunits in pertussis toxin

Bordetella pertussis, the causative agent of whooping cough, produces a complex hetero-oligomeric exotoxin, named pertussis toxin (PTX), which is responsible for several of the clinical manifestations associated with whooping cough. The toxin is composed of five dissimilar subunits, named S1 through S5 and arranged in a hexameric structure with a 1S1:1S2:1S3:2S4:1S5 stoichiometry. Although S2 and S3 share 70% amino acid identity, these two subunits were previously thought not to be able to substitute for each other in toxin assembly/secretion and the biological activities of PTX. Here, we show that toxin analogues containing two S3 subunits and lacking S2 (PTXdeltaS2), or containing two S2 subunits and lacking S3 (PTXdeltaS3), can be produced, assembled and secreted by B. pertussis strains, in which the S2-encoding cistron or the S3-coding cistrons have been inactivated by internal in-frame deletions that avoid downstream effects. In fact, PTXdeltaS3 was produced in higher amounts in the bacterial culture supernatants than natural PTX, whereas PTXdeltaS2 was produced in lower amounts than PTX. The action of the toxin analogues on the clustering of Chinese Hamster Ovary cells was also affected differentially by the S2-S3 substitution. These toxin analogues constitute thus interesting probes for the study of cellular functions, in particular immune cell functions, for which natural PTX has already shown its usefulness.     

Mutants in the ptlA-H genes of Bordetella pertussis are deficient for pertussis toxin secretion

The nine ptl genes (A-I) are required for efficient secretion of pertussis toxin past the outer membrane. Mutations were made in ptlA-H by filling in unique restriction sites, generating in-frame deletions, or inserting a FLAG epitope tag. The mutations were cloned into a suicide shuttle plasmid containing the ptxptl operon and introduced into the adenylate cyclase locus of the chromosome of a Bordetella pertussis strain deleted for ptx. The wild-type ptxptl operon restored pertussis toxin expression and secretion. The ptl mutant constructs also restored expression of periplasmic pertussis toxin to the ptx deletion strain but the mutants had a statistically significant decrease in secretion of pertussis toxin of between 5- to 35-fold, suggesting all of the ptl genes must be intact for efficient pertussis toxin secretion. The mutations were also introduced into the adenylate cyclase locus of a wild-type ptxptl strain, resulting in a ptl diploid strain. The PtlC, PtlD, PtlE, PtlF, PtlG and PtlH mutants exerted dominance over the wild-type allele.     

Periplasmic disulphide bond formation is essential for cellulase secretion by the plant pathogen Erwinia chrysanthemi

Secretion to the cell exterior of cellulase EGZ and of at least six pectinases enables the Gram-negative Erwinia chrysanthemi to cause severe plant disease. The C-terminal cellulose-binding domain (CBD) of EGZ was found to contain a disulphide bond which forms, in the periplasm, between residues Cys-325 and Cys-382. Dithiothreitol (DTT)-treatment of native EGZ showed that the disulphide bond was dispensable, both for catalysis and cellulose binding. Adding DTT to E. chrysanthemi cultures led to immediate arrest of secretion of EGZ which accumulated in the periplasm where the CBD was eventually proteolysed. Site-directed mutagenesis that affected Cys residues involved in disulphide bond formation resulted in molecules that were catalytically active and able to bind to cellulose but were no longer secreted, Instead they accumulated in the periplasm. Interestingly, the region around EGZ Cys-325 is conserved in two pectinases secreted by the same pathway as EGZ. We conclude that the conserved Cys, and possibly adjacent residues, bear essential information for EGZ to be secreted and that periplasmic disulphide bond formation is an obligatory step which provides a pre-folded functional form of EGZ with secretion competence.     

MacAB is involved in the secretion of Escherichia coli heat-stable enterotoxin II

The heat-stable enterotoxin (ST) produced by enterotoxigenic Escherichia coli is an extracellular peptide toxin that evokes watery diarrhea in the host. Two types of STs, STI and STII, have been found. Both STs are synthesized as precursor proteins and are then converted to the active forms with intramolecular disulfide bonds after being released into the periplasm. The active STs are finally translocated across the outer membrane through a tunnel made by TolC. However, it is unclear how the active STs formed in the periplasm are led to the TolC channel. Several transporters in the inner membrane and their periplasmic accessory proteins are known to combine with TolC and form a tripartite transport system. We therefore expect such transporters to also act as a partner with TolC to export STs from the periplasm to the exterior. In this study, we carried out pulse-chase experiments using E. coli BL21(DE3) mutants in which various transporter genes (acrAB, acrEF, emrAB, emrKY, mdtEF, macAB, and yojHI) had been knocked out and analyzed the secretion of STs in those strains. The results revealed that the extracellular secretion of STII was largely decreased in the macAB mutant and the toxin molecules were accumulated in the periplasm, although the secretion of STI was not affected in any mutant used in this study. The periplasmic stagnation of STII in the macAB mutant was restored by the introduction of pACYC184, containing the macAB gene, into the cell. These results indicate that MacAB, an ATP-binding cassette transporter of MacB and its accessory protein, MacA, participates in the translocation of STII from the periplasm to the exterior. Since it has been reported that MacAB cooperates with TolC, we propose that the MacAB-TolC system captures the periplasmic STII molecules and exports the toxin molecules to the exterior.     

Pertussis toxin export requires accessory genes located downstream from the pertussis toxin operon

Pertussis toxin, a major virulence factor of Bordetella pertussis, is an oligomeric protein composed of five different subunits that are exported individually to the periplasmic space by the signal peptide–dependent pathway. After assembly, the protein is exported from the periplasm to the extracellular compartment. We show that pertussis toxin secretion across the outer membrane requires the gene product of at least one gene (ptlC) that is located downstream from the pertussis toxin operon. The amino acid sequence of PtlC shows a high degree of homology to VirB4, a protein encoded by the virB operon, which contains 11 open reading frames that are involved in the transfer of T-DNA from Agrobaderium tumefaciens to the plant cells. This is a novel mechanism of protein export in Gram-negative bacteria.     

Secretion of nuclease across the outer membrane of Serratia marcescens and its energy requirements.

Extracellular secretion of Serratia marcescens nuclease occurs as a two-step process via a periplasmic intermediate. Unlike other extracellular proteins secreted by gram-negative bacteria by the general secretory pathway, nuclease accumulates in the periplasm in its active form for an unusually long time before its export into the growth medium. The energy requirements for extracellular secretion of nuclease from the periplasm were investigated. Our results suggest that the second step of secretion across the outer membrane is dependent upon the external pH; acidic pH effectively but reversibly blocks extracellular secretion. However, electrochemical proton gradient, and possibly ATP hydrolysis, are not required for this step. We suggest that nuclease uses a novel mechanism for the second step of secretion in S. marcescens.     

N-terminus leader sequence of Shiga toxin (Stx) 1 is essential for production of active recombinant protein in E. coli

Escherichia coli clones expressing recombinant shiga toxin (Stx1) and its derivatives Stx1-A and Stx1-B subunits were established to release the proteins into periplasmic space. The expression was examined by SDS-PAGE to visualize the subunits. The secreted assembled subunits were extracted with polymyxin B and assessed for biological activity. The results showed that the presence of N-terminus leader sequence of the gene is essential for assembly of the subunits to yield biologically active holotoxin (AB5). The absence of the leader sequence did not affect the expression of the subunits but did disrupt the holotoxin assembly.     

Extracellular production of recombinant human epidermal growth factor (hEGF) in Escherichia coli cells

An expression plasmid pPTK-hEGF2 was constructed to provide for the extracellular production of recombinant human epidermal growth factor by the Escherichia coli cells. The plasmid contained two expression cassettes, one of which carried a tandem of the fused genes ompF-hegf under the control of the tac promoter, ensuring regulated secretion of hEGF into the E. coli periplasm, and another one contained the kil gene from the ColE1 plasmid under the control of lac promoter. The regulated low-level biosynthesis of Kil protein increased the permeability of E. coli outer membrane for periplasmic proteins. This enabled the recombinant proteins secreted into the cell periplasm to outflow into the cultural medium. As a result, the E. coli strains that harboured this plasmid construct produced effectively the recombinant hEGF into the cultural medium. The yields of hEGF produced by the nTG1(pPTK-hEGF2) and HB101(pPTK-hEGF2) strains reached 25 and 30 mg/l of cell culture after 14 and 18 h of cultivation, respectively. The hEGF preparation isolated possessed biological activity both in vivo and in vitro.     

Pyoverdine biosynthesis and secretion in Pseudomonas aeruginosa: implications for metal homeostasis

Pyoverdines are siderophores produced by fluorescent Pseudomonads to acquire iron. At least 60 different pyoverdines produced by diverse strains have been chemically characterized. They all consist of a dihydroquinoline‐type chromophore linked to a peptide. These peptides are of various lengths and the sequences are strain specific. Pyoverdine biosynthesis in Pseudomonas aeruginosa and fluorescent Pseudomonads is a complex process involving at least 12 different proteins, starting in the cytoplasm and ending in the periplasm. The cellular localization of pyoverdine precursors was recently shown to be consistent with their biosynthetic enzymes. In the cytoplasm, pyoverdine appears to be assembled at the inner membrane and particularly at the old cell pole of the bacterium. Mature pyoverdine is uniformly distributed throughout the periplasm, like the periplasmic enzyme PvdQ. Secretion of pyoverdine involves a recently identified ATP‐dependent efflux pump, PvdRT‐OpmQ. This efflux system does not only secrete newly synthesized pyoverdine but also pyoverdine that already transported iron into the bacterial periplasm and any pyoverdine–metal complex other than ferri‐pyoverdine present in the periplasm. This review considers how these new insights into pyoverdine biosynthesis and secretion contribute to our understanding of the role of pyoverdine in iron and metal homeostasis in fluorescent Pseudomonads.     

One-dimensional peptide mapping of the subunits of pertussis toxin

Pertussis toxin (pertussigen) purified from the cytoplasmic fraction of Bordetella pertussis strain 18334, phase 1, consisted of five subunits which included an additional subunit (S1a) not previously reported. Subunits S1, S1a and S2 showed extensive structural homology when analysed by one-dimensional peptide mapping, indicating that the latter two were probably derived from proteolytic cleavage of the largest subunit, S1. Subunits S3 and S4,5 generated only a limited number of peptides following chemical and enzymic degradation, but these subunits differed structurally from each other and from those showing structural homology.     

Secretion of active recombinant human tissue plasminogen activator derivatives in Escherichia coli

The DNA fragment coding for kringle 2 plus serine protease domains (K2S) of tissue plasminogen activator (tPA) was inserted into a phagemid vector, pComb3HSS. In the recombinant vector, pComb3H-K2S, the K2S gene was fused to gpIII of PhiM13 and linked to the OmpA signal sequence. The resulting gene, rK2S-gpIII, was inducibly expressed in Escherichia coli XL-1 Blue. The protein was presented on the phage particle. To stop the expression of gpIII, a stop codon between K2S and the gpIII gene was inserted by site-directed mutagenesis. This mutated vector, MpComb3H-K2S, was transformed in XL-1 Blue. After induction with IPTG (isopropyl-beta-D-thiogalactopyranoside), rK2S was found both in the periplasm as an inactive form of approximately 32% and in the culture supernatant as an active form of approximately 68%. The secreted form of rK2S was partially purified by ammonium sulfate (55%) precipitation. The periplasmic form was isolated from whole cells by chloroform extraction. The fibrin binding site of kringle 2 was demonstrated in all expressed versions (phage-bound, periplasmic, and secreted forms) using the monoclonal anti-kringle 2 antibody (16/B). Only the secreted form of rK2S revealed a fibrinogen-dependent amidolytic activity with the specific activity of 236 IU/microg. No amidolytic activity of rK2S was observed in either the periplasmic or the phage-bound form. The secretion of rK2S as an active enzyme offers a novel approach for the production of the active-domain deletion mutant tPA, rK2S, without any requirements for bacterial compartment preparation and in vitro refolding processes. This finding is an important technological advance in the development of large-scale, bacterium-based tPA production systems.     

Analysis of factors affecting the periplasmic production of recombinant proteins in Escherichia coli

Five fusion proteins between Z domains derived from Staphylococcal Protein A and Green Fluorescent Protein or Human Proinsulin were produced on the periplasm of Escherichia coli. The effects of the molecular weight and amino acid composition of the translocated peptide, culture medium composition, and growth phase of the bacterial culture were analyzed regarding the expression and periplasmic secretion of the recombinant proteins. It was found that secretion was not affected by the size of the translocated peptide (17-42 kDa) and that the highest periplasmic production values were obtained on the exponential phase of growth. Moreover, the highest periplasmic values were obtained in minimal medium, showing the relevance of the culture medium composition on secretion. In silico prediction analysis suggested that with respect to the five proteins used in this study, those that are prone to form alpha-helix structures are more translocated to the periplasm.     

Mechanisms and kinetics of monoclonal antibody synthesis and secretion in synchronous and asynchronous hybridoma cell cultures.

The kinetics of monoclonal antibody synthesis and secretion have been studied in synchronous and asynchronous mouse hybridoma cell cultures. Pulse-labelling of IgG followed by immunoprecipitation and quantitation of synthesized and secreted IgG in synchronous cultures show maximum production during G1/S phases. Secretion takes place through exocytotic release of vesicle contents. Pulse-chase experiments show that 71% of the synthesized IgG is secreted within 8 h of the pulsing period and only a further 4% is secreted by 22 h. Higher specific antibody production (QA) is obtained if (a) cells are arrested and then maintained in G1/S phases, (b) viability is decreased during the death phase of batch culture, (c) the dilution rate is decreased in continuous culture or (d) cells are subjected to hydrodynamically induced stress. The increase in QA in all these cases is mainly due to the passive release of the accumulated intracellular antibody. DNA and protein synthetic activity peak during the early exponential phase and decline rapidly during mid and late exponential and death phases. Metabolic activity however peaks up to 20 h after the peak in DNA synthesis, and declines similarly during the death phase. The data are consistent with the idea that slow growth and higher death rates increase QA and that Ig secretion is probably subject to complex intracellular control.     

Donor strand complementation mechanism in the biogenesis of non-pilus systems

The F1 antigen of Yersinia pestis belongs to a class of non-pilus adhesins assembled via a classical chaperone-usher pathway. Such pathways consist of PapD-like chaperones that bind subunits and pilot them to the outer membrane usher, where they are assembled into surface structures. In a recombinant Escherichia coli model system, chaperone-subunit (Caf1M:Caf1n) complexes accumulate in the periplasm. Three independent methods showed that these complexes are rod- or coil-shaped linear arrays of Caf1 subunits capped at one end by a single copy of Caf1M chaperone. Deletion and point mutagenesis identified an N-terminal donor strand region of Caf1 that was essential for polymerization in vitro, in the periplasm and at the cell surface, but not for chaperone-subunit interaction. Partial protease digestion of periplasmic complexes revealed that this region becomes buried upon formation of Caf1:Caf1 contacts. These results show that, despite the capsule-like appearance of F1 antigen, the basic structure is assembled as a linear array of subunits held together by intersubunit donor strand complementation. This example shows that strikingly different architectures can be achieved by the same general principle of donor strand complementation and suggests that a similar basic polymer organization will be shared by all surface structures assembled by classical chaperone-usher pathways.