Protein secretion in gram-negative bacteria. The extracellular metalloprotease B from Erwinia chrysanthemi contains a C-terminal secretion signal analogous to that of Escherichia coli alpha-hemolysin

The secretion signal of extracellular metalloprotease B that is secreted without a signal peptide by the Gram-negative phytopathogenic bacterium Erwinia chrysanthemi is shown by deletion and gene fusion analyses to be located within the last 40 C-terminal amino acids. Secretion of a peptide containing only this region of the protease requires the same three secretion factors (PrtD, PrtE, and PrtF) that were previously shown to be required for the secretion of the full-length protease. This secretion signal can also be recognized, albeit inefficiently, by the analogous secretion machinery of alpha-hemolysin, another protein with a C-terminal secretion signal that is secreted by some strains of the Gram-negative bacterium Escherichia coli. The secretion signal was fused to an internal 200-amino acid fragment from the sequence of the cytoplasmic protein amylomaltase to promote its specific secretion by the protease secretion pathway. Almost exactly the same sequence as that identified as the protease B secretion signal was also found at the C terminus of metalloprotease C that is also secreted by E. chrysanthemi.     

Cloning and expression in Escherichia coli of the Serratia marcescens metalloprotease gene: secretion of the protease from E. coli in the presence of the Erwinia chrysanthemi protease secretion functions.

The Serratia marcescens extracellular protease SM is secreted by a signal peptide-independent pathway. When the prtSM gene was cloned and expressed in Escherichia coli, the cells did not secrete protease SM. The lack of secretion could be very efficiently complemented by the Erwinia chrysanthemi protease B secretion apparatus constituted by the PrtD, PrtE, and PrtF proteins. As with protease B and alpha-hemolysin, the secretion signal was located within the last 80 amino acids of the protease. These results indicate that the mechanism of S. marcescens protease SM secretion is analogous to the mechanisms of protease B and hemolysin secretion.     

Secretion processing and activation of Erwinia chrysanthemi proteases

E chrysanthemi, a phytopathogenic enterobacterium, secretes several enzymes into the medium such as pectinases cellulases and proteases. It also produces 3 distinct and antigenically related extracellular proteases. The proteases secretion pathway seems to be distinct from that of the other extracellular enzymes since pleiotropic mutants impaired in cellulase and pectinase secretion are unimpaired in protease secretion. E chrysanthemi proteases B and C secretion occurs without an N-terminal signal peptide and is dependent upon specific secretion functions which are encoded by genes adjacent to the protease structural genes. This secretion pathway might be analogous to the alpha-hemolysin secretion pathway in E coli. Protection against intracellular proteolytic activity is achieved by 2 distinct mechanisms: the proteases are synthesized as inactive precursors with an N-terminal extension of 15 aminoacids (protease B) and 17 aminoacids (protease C) absent in the mature active extracellular enzymes; an intracellular specific protease inhibitor is produced by some E chrysanthemi strains.     

Cloning of genes encoding extracellular metalloproteases from Erwinia chrysanthemi EC16.

A 14-kilobase BamHI-EcoRI DNA fragment cloned from Erwinia chrysanthemi EC16 contained a gene encoding a metalloprotease inhibitor as well as three tandem prt genes encoding metalloproteases. The prt genes were separated from the inhibitor gene by a ca. 4-kilobase region that was necessary for extracellular secretion of the proteases. When individually subcloned downstream from vector promoters, the three prt genes each led to substantial extracellular secretion of the proteases by Escherichia coli cells, provided that the 4-kilobase required region was supplied in cis or trans. One of the protease structural genes, prtC, was sequenced and had high homology to a metalloprotease gene previously described from Serratia species as well as to the prtB gene of E. chrysanthemi B374. Marker exchange mutants of E. chrysanthemi EC16 defective in production of one or all of the extracellular proteases were not impaired in virulence on plant tissue.     

The three genes lipB, lipC, and lipD involved in the extracellular secretion of the Serratia marcescens lipase which lacks an N-terminal signal peptide.

The extracellular lipase of Serratia marcescens Sr41, lacking a typical N-terminal signal sequence, is secreted via a signal peptide-independent pathway. The 20-kb SacI DNA fragment which allowed the extracellular lipase secretion was cloned from S. marcescens by selection of a phenotype conferring the extracellular lipase activity on the Escherichia coli cells. The subcloned 6.5-kb EcoRV fragment was revealed to contain three open reading frames which are composed of 588, 443, and 437 amino acid residues constituting an operon (lipBCD). Comparisons of the deduced amino acid sequences of the lipB, lipC, and lipD genes with those of the Erwinia chrysanthemi prtDEC, prtEEC, and prtFEC genes encoding the secretion apparatus of the E. chrysanthemi protease showed 55, 46, and 42% identity, respectively. The products of the lipB and lipC genes were 54 and 45% identical to the S. marcescens hasD and hasE gene products, respectively, which were secretory components for the S. marcescens heme-binding protein and metalloprotease. In the E. coli DH5 cells, all three lipBCD genes were essential for the extracellular secretion of both S. marcescens lipase and metalloprotease proteins, both of which lack an N-terminal signal sequence and are secreted via a signal-independent pathway. Although the function of the lipD gene seemed to be analogous to those of the prtFEC and tolC genes encoding third secretory components of ABC transporters, the E. coli TolC protein, which was functional for the S. marcescens Has system, could not replace LipD in the LipB-LipC-LipD transporter reconstituted in E. coli. These results indicated that these three proteins are components of the device which allows extracellular secretion of the extracellular proteins of S. marcescens and that their style is similar to that of the PrtDEF(EC) system.     

Serratia marcescens S-layer protein is secreted extracellularly via an ATP-binding cassette exporter, the Lip system

The Serratia marcescens Lip exporter belonging to the ATP-binding cassette (ABC) exporter is known to be involved in signal peptide-independent extracellular secretion of a lipase and a metalloprotease. Although the genes of secretory proteins and their ABC exporters are usually all reported to be linked in several Gram-negative bacteria, neither the lipase nor the protease gene is located close to the Lip exporter genes, lipBCD . A gene ( slaA ) located upstream of the lipBCD genes was cloned, revealing that it encodes a polypeptide of 100 kDa and is partially similar to the Caulobacter crescentus paracrystalline cell surface layer (S-layer) protein. The Lip exporter-deficient mutants of S . marcescens failed to secrete the SlaA protein. Electron micrography demonstrated the cell surface layer of S . marcescens . The S-layer protein was secreted to the cultured media in Escherichia coli cells carrying the Lip exporter. Three ABC exporters, Prt, Has and Hly systems, could not allow the S-layer secretion, indicating that the S . marcescens S-layer protein is strictly recognized by the Lip system. This is the first report concerning secretion of an S-layer protein via its own secretion system.     

The Caulobacter crescentus Paracrystalline S-Layer Protein Is Secreted by an ABC Transporter (Type I) Secretion Apparatus

Caulobacter crescentus is a gram-negative bacterium that produces a two-dimensional crystalline array on its surface composed of a single 98-kDa protein, RsaA. Secretion of RsaA to the cell surface relies on an uncleaved C-terminal secretion signal. In this report, we identify two genes encoding components of the RsaA secretion apparatus. These components are part of a type I secretion system involving an ABC transporter protein. These genes, lying immediately 3′ of rsaA, were found by screening a Tn5 transposon library for the loss of RsaA transport and characterizing the transposon-interrupted genes. The two proteins presumably encoded by these genes were found to have significant sequence similarity to ABC transporter and membrane fusion proteins of other type I secretion systems. The greatest sequence similarity was found to the alkaline protease (AprA) transport system of Pseudomonas aeruginosa and the metalloprotease (PrtB) transport system of Erwinia chrysanthemi. The prtB and aprA genes were introduced into C. crescentus, and their products were secreted by the RsaA transport system. Further, defects in the S-layer protein transport system led to the loss of this heterologous secretion. This is the first report of an S-layer protein secreted by a type I secretion apparatus. Unlike other type I secretion systems, the RsaA transport system secretes large amounts of its substrate protein (it is estimated that RsaA accounts for 10 to 12% of the total cell protein). Such levels are expected for bacterial S-layer proteins but are higher than for any other known type I secretion system.     

Identification of two components of the Serratia marcescens metalloprotease transporter: protease SM secretion in Escherichia coli is TolC dependent.

The Serratia marcescens metalloprotease (protease SM) belongs to a family of proteins secreted from gram-negative bacteria by a signal peptide-independent pathway which requires a specific transporter consisting of three proteins: two in the inner membrane and one in the outer membrane. The prtDSM and prtESM genes encoding the two S. marcescens inner membrane components were cloned and expressed in Escherichia coli. Their nucleotide sequence revealed high overall homology with the two analogous inner membrane components of the Erwinia chrysanthemi protease secretion apparatus and lower, but still significant, homology with the two analogous inner membrane components of the E. coli hemolysin transporter. When expressed in E. coli, these two proteins, PrtDSM and PrtESM, allowed the secretion of protease SM only in the presence of TolC protein, the outer membrane component of the hemolysin transporter.     

Escherichia coli requires the protease activity of FtsH for growth

FtsH protease, the product of the essential ftsH gene, is a membrane-bound ATP-dependent metalloprotease of Escherichia coli that has been shown to be involved in the rapid turnover of key proteins, secretion of proteins into and through the membrane, and mRNA decay. The pleiotropic effects of ftsH mutants have led to the suggestion that FtsH possesses an ATP-dependent chaperone function that is independent of its protease function. When considering FtsH as a target for novel antibacterials, it is necessary to determine which of these functions is critical for the growth and survival of bacteria. To address this, we constructed the FtsH mutants E418Q, which retains significant ATPaseactivity but lacks protease activity, and K201N, which lacks both protease and ATPase activities. These mutants were introduced into an E. coli ftsH knockout strain which has wild-type FtsH supplied from a plasmid under control of the inducible araBAD promoter. Since neither mutant would complement the ftsH defect produced in the absence of arabinose, we conclude that the protease function of FtsH is required for bacterial growth.     

The E. coli alpha-hemolysin secretion system and its use in vaccine development.

Many Gram-negative bacteria use a type I secretion system to translocate proteins, including pore-forming toxins, proteases, lipases and S-layer proteins, across both the inner and outer membranes into the extracellular surroundings. The Escherichia coli alpha-hemolysin (HlyA) secretion system is the prototypical and best characterized type I secretion system. The structure and function of the components of the HlyA secretion apparatus, HlyB, HlyD and TolC, have been studied in great detail. The functional characteristics of this secretion system enable it to be used in a variety of different applications, including the presentation of heterologous antigens in live-attenuated bacterial vaccines. Such vaccines can be an effective delivery system for heterologous antigens, and the use of a type I secretion system allows the antigens to be actively exported from the cytoplasm of the bacterial carrier rather than only becoming accessible to the host immune system after bacterial disintegration.     

Optimization of an extracellular zinc-metalloprotease (SVP2) expression in Escherichia coli BL21 (DE3) using response surface methodology

In this work, SVP2 from Salinivibrio proteolyticus strain AF-2004, a zinc metalloprotease with suitable biotechnological applications, was cloned for expression at high levels in Escherichia coli with the intention of changing culture conditions to generate a stable extracellular enzyme extract. The complete ORF of SVP2 gene was heterologously expressed in E. coli BL21 (DE3) by using pQE-80L expression vector system. In initial step, the effect of seven factors include: incubation temperature, peptone and yeast extract concentration, cell density (OD600) before induction, inducer (IPTG) concentration, induction time, and Ca(2+) ion concentrations on extracellular recombinant SVP2 expression and stability were investigated. The primary results revealed that the IPTG concentration, Ca(2+) ion concentration and induction time are the most important effectors on protease secretion by recombinant E. coli BL21. Central composite design experiment in the following showed that the maximum protease activity (522 U/ml) was achieved in 0.0089 mM IPTG for 24h at 30 °C, an OD600 of 2, 0.5% of peptone and yeast extract, and a Ca(2+) ion concentration of 1.3 mM. The results exhibited that the minimum level of IPTG concentration along with high cell density and medium level of Ca(2+) with prolonged induction time provided the best culture condition for maximum extracellular production of heterologous protease SVP2 in E. coli expression system.     

集胞藻PCC6803中S2P同源蛋白Slr0643及Sll0862 金属蛋白酶活性的体外鉴定

【目的】金属蛋白酶S2P在细菌中通过在膜切割转录调控因子、释放δ因子参与胁迫响应是跨膜信号转导的保守机制,但蓝细菌中S2P的功能还未被鉴定,故我们考察集胞藻PCC6803中的S2P同源蛋白Slr0643及Sll0862的金属蛋白酶活性。【方法】以pET-30b(+)为载体,分别构建重组质粒pF0643和pF0862,在大肠杆菌BL21(CE3)中诱导表达并纯化Slr0643及Sll0862蛋白,以β-酪蛋白为底物检测重组蛋白的酶活性。【结果】体外酶活实验显示重组表达的Slr0643及Sll0862蛋白有内切蛋白酶活性,且其活性受金属螯合剂o-phenanthroline的抑制。体外酶活的鉴定结果为进一步研究Slr0643和Sll0862的体内酶活和生物学功能奠定了基础。【结论】集胞藻PCC6803中的S2P同源蛋白Slr0643及Sll0862具有金属蛋白酶活性。     

Haemophilus influenzae immunoglobulin A1 protease genes: cloning by plasmid integration-excision, comparative analyses, and localization of secretion determinants.

Many bacteria which establish infections after invasion at human mucosal surfaces produce enzymes which cleave immunoglobulin A (IgA), the primary immunoglobulin involved with protection at these sites. Bacterial species such as Haemophilus influenzae which produce IgA1 proteases secrete this enzyme into their environment. However, when the gene encoding this protein was isolated from H. influenzae serotype d and introduced into Escherichia coli, the activity was not secreted into the medium but was localized in the periplasmic space. In this study, the IgA1 protease gene (iga) from an H. influenzae serotype c strain was isolated and the gene from the serotype d strain was reisolated. The IgA1 proteases produced in E. coli from these genes were secreted into the growth medium. A sequence linked to the carboxyl terminus of the iga gene but not present in the original clone was shown to be necessary to achieve normal secretion. Tn5 mutagenesis of the additional carboxyl-terminal region was used to define a 75- to 100-kilodalton coding region required for complete secretion of IgA1 protease but nonessential for protease activity. The iga genes were isolated by a plasmid integration-excision procedure. In this method a derivative of plasmid pBR322 containing a portion of the protease gene and the kanamycin resistance determinant of Tn5 was introduced into H. influenzae by transformation. The kanamycin resistance gene was expressed in H. influenzae, but since pBR322 derivatives are unable to replicate in this organism, kanamycin-resistant transformants arose by integration of the plasmid into the Haemophilus chromosome by homologous recombination. The plasmid, together with the adjoining DNA encoding IgA1 protease, was then excised from the chromosome with DNA restriction enzymes, religated, and reintroduced into E. coli. Comparisons between the H. influenzae protease genes were initiated which are useful in locating functional domains of these enzymes.     

The secretion genes of Pseudomonas aeruginosa alkaline protease are functionally related to those of Erwinia chrysanthemi proteases and Escherichia coliα-haemolysin

The extracellular alkaline protease produced by Pseudomonas aeruginosa is secreted by a specific pathway, independent of the pathway used by most of the other extracellular proteins of this organism. Secretion of this protease is dependent on the presence of several genes located adjacent to the apr gene. Complementation studies have shown that PrtD, E, and F, the three secretion functions for Erwinia chrysanthemi proteases B and C (Létoffé et al., 1990), can mediate the secretion of the alkaline protease by Escherichia coli. The secretion functions involved in alpha-haemolysin secretion in E. coli (hlyB, hlyD, tolC) can also be used to complement alkaline protease secretion by E. coli, although less efficiently. These data indicate that protease secretion mechanisms in Pseudomonas and Erwinia are very similar and are homologous to that of E. coli alpha-haemolysin.     

The secreted hemolysins of Proteus mirabilis, Proteus vulgaris, and Morganella morganii are genetically related to each other and to the alpha-hemolysin of Escherichia coli.

Secreted hemolysins were extremely common among clinical isolates of Proteus mirabilis, Proteus vulgaris, and Morganella morganii, and hemolytic activity was either cell associated or cell free. Southern hybridization of total DNA from hemolytic isolates to cloned regions of the Escherichia coli alpha-hemolysin (hly) determinant showed clear but incomplete homology between genes encoding production of hemolysins in the four species. One of the two E. coli secretion genes, hlyD, hybridized only with DNA from P. vulgaris and M. morganii, which produced cell-free hemolysis, but not with that from P. mirabilis, which showed only cell-associated activity. Molecular cloning of the genetic determinants of cell-free hemolytic activity from P. vulgaris and M. morganii chromosomal DNA allowed their functional analysis via inactivation with the transposons Tn1000 and Tn5. Both hemolysin determinants were about 7.5 kilobase pairs and comprised contiguous regions directing regulation, synthesis, and specific secretion out of the cell. Transposon mutations which eliminated secretion of the Proteus and Morganella hemolysins could be complemented specifically by the E. coli hemolysin secretion genes hlyB or hlyD. Alignment of the physically and functionally defined hly determinants from P. vulgaris and M. morganii with that of the E. coli alpha-hemolysin confirmed a close genetic relationship but also indicated extensive evolutionary divergence.     

Protein secretion by hybrid bacterial ABC-transporters: specific functions of the membrane ATPase and the membrane fusion protein.

The Erwinia chrysanthemi metalloprotease C and the Serratia marcescens haem acquisition protein HasA are both secreted from Gram-negative bacteria by a signal peptide-independent pathway which requires a C-terminal secretion signal and a specific ABC-transporter made up of three proteins: a membrane ATPase (the ABC-protein), a second inner membrane component belonging to the membrane fusion protein family and an outer membrane polypeptide. HasA and protease C transporters are homologous although the secreted polypeptides share no sequence homology. Whereas protease C can use both translocators, HasA is secreted only by its specific transporter. Functional analysis of protease C and HasA secretion through hybrid transporters obtained by combining components from each system demonstrates that the ABC-protein is responsible for the substrate specificity and that inhibition of protease C secretion in the presence of HasA results from a defective interaction between HasA and the ABC-protein. We also show that the outer membrane protein, TolC, can combine with the membrane fusion protein HasE in the presence of either ABC-protein to form a functional transporter but not with the membrane fusion protein, PrtE. This indicates a specific interaction between the outer membrane component and the membrane fusion protein.     

Genetics of hemolysin of Escherichia coli.

The expression of alpha-hemolysin is a property frequently associated with Escherichia coli extraintestinal infections. We have examined the genetic basis for hemolysin expression by an E. coli strain isolated from a human urinary tract infection. The genes necessary for hemolysin synthesis were found to be chromosomal and to map near the ilv gene cluster. Isogenic hly+ and hly derivatives were also prepared and tested for virulence in the chicken embryo model system. Hemolysin was found to be necessary but not in itself sufficient for E. coli virulence in this in vitro model.     

Expression and characterization of a metalloprotease from a Vibrio parahaemolyticus isolate

The extracellular zinc metalloprotease from Vibrio parahaemolyticus (VPM) is a putative virulence factor for host infection. It is synthesized from the vpm gene of V. parahaemolyticus as a polypeptide of 814 amino acids with an estimated molecular mass of 89,833 Da, containing a zinc metalloprotease HEXXH consensus motif. To investigate the enzymatic properties of V. parahaemolyticus metalloprotease, the mature vpm gene was overexpressed in Escherichia coli, and the recombinant protein (rVPM) was purified by a His-binding metal affinity column (>95% purity). The activity of the recombinant protease produced in E. coli was examined by gelatin activity staining and proteolytic activity assays using gelatin and azocasein as substrates. rVPM showed maximum activity at about 37 degrees C and pH 8. The cytotoxicity against flounder gill cells and fish pathogenicity indicated a potential role in pathogenesis.     

Functional complementation between bacterial MDR-like export systems: colicin V, alpha-hemolysin, and Erwinia protease.

The antibacterial protein Colicin V (ColV) is secreted from gram-negative bacteria by a signal sequence-independent pathway. The proteins that mediate the export of ColV share sequence similarities with components from other signal sequence-independent export systems such as those for alpha-hemolysin (Hly) and Erwinia protease (Prt). We report here that the intact HlyBD export system can export active ColV from Escherichia coli strains lacking the ColV export proteins CvaA and CvaB. The individual Hly export genes complement mutations in their respective ColV homologs, but do so at a lower efficiency. When CvaA or CvaB is expressed along with the intact HlyBD exporter, the Cva export protein interferes with export of ColV through the HlyBD system. Gene fusions and point mutations in the ColV structural gene were used to define signals in ColV recognized by the Hly exporter. An export signal in ColV recognized by HlyBD is localized to the amino-terminal 57 amino acids of the protein. In addition, mutations in the ColV export signal differentially affect export through CvaAB and HlyBD, suggesting differences in signal specificity between the Cva and Hly systems. The three Erwinia protease export proteins can also export active ColV, and interference is seen when CvaA or CvaB is expressed along with the intact Prt exporter. Functional complementation is not reciprocal; alpha-hemolysin is not exported through either the ColV system or the Prt system.