Omptin proteins: an expanding family of outer membrane proteases in Gram-negative Enterobacteriaceae (Review)

The Escherichia coli K-12 outer membrane protein OmpT is a prototype of a unique family of bacterial endopeptidases known as the omptins. This family includes OmpT and OmpP of E. coli, SopA of Shigella flexneri, PgtE of Salmonella enterica, and Pla of Yersinia pestis. Despite their sequence similarities, the omptins vary in their reported functions. The OmpT protease is characterized by narrow cleavage specificity defined by the extracellular loops of the β-barrel protruding above the lipid bilayer. It employs a distinct proteolytic mechanism that involves a histidine and an aspartate residue. Most of the omptin proteins have been implicated in bacterial pathogenesis. As a result, the omptins are potential targets for antimicrobial drug and vaccine development. This review summarizes recent developments in omptins structure and function, emphasizes their role in pathogenesis, proposes evolutionary relation among the existing omptins, and offers possible directions for future research.     

Crystal structure of the outer membrane protease OmpT from Escherichia coli suggests a novel catalytic site

OmpT from Escherichia coli belongs to a family of highly homologous outer membrane proteases, known as omptins, which are implicated in the virulence of several pathogenic Gram-negative bacteria. Here we present the crystal structure of OmpT, which shows a 10-stranded antiparallel beta-barrel that protrudes far from the lipid bilayer into the extracellular space. We identified a putative binding site for lipopolysaccharide, a molecule that is essential for OmpT activity. The proteolytic site is located in a groove at the extracellular top of the vase-shaped beta-barrel. Based on the constellation of active site residues, we propose a novel proteolytic mechanism, involving a His-Asp dyad and an Asp-Asp couple that activate a putative nucleophilic water molecule. The active site is fully conserved within the omptin family. Therefore, the structure described here provides a sound basis for the design of drugs against omptin-mediated bacterial pathogenesis. Coordinates are in the Protein Data Bank (accession No. 1I78)     

Display and release of the Plasmodium falciparum circumsporozoite protein using the autotransporter MisL of Salmonella enterica

The Salmonella enterica MisL (protein of membrane insertion and secretion) is an autotransporter with high homology to AIDA-I (adhesin involved in diffuse adherence) of enteropathogenic Escherichia coli. Considering that it has been reported that the MisL beta translocator domain is able to display heterologous passenger peptides to the bacterial surface, we developed a system to display proteins and release them to the external environment by means of proteolytic cleavage. Plasmids were constructed encoding 8 or 53 repeats of the NANP (Asp-Ala-Asp-Pro) tetrapeptide, which is the main B cell epitope of the Plasmodium falciparum circumsporozoitic protein (CSP), fused to the the MisL beta-domain and including the recognition cleavage sequence from the E. coli OmpT surface protease. E. coli XL-10Gold and BL21(DE3) (OmpT positive and negative, respectively) and Salmonella enterica serovar Typhimurium SL3261 (Aro A(-)) were transformed with the plasmids and, both expression and localization of the fusion proteins were assessed by Western blot, indirect immunofluorescence, and flow cytometry, using a monoclonal antibody against (NANP)(3). Higher expression of the (NANP)(8) and (NANP)(53) fusion proteins was demonstrated on the bacterial surface of the OmpT negative E. coli strains and the (NANP)(53) in the culture supernatant of E. coli XL-10Gold indicating a protease mediated cleavage. The flow cytometry analysis suggested 71 and 98% cleavage efficiency for the (NANP)(8) and (NANP)(53), respectively, in E. coli XL-10Gold. Similar results were obtained in S. enterica serovar Typhimurium SL3261, suggesting the involvement of other proteases related to OmpT. These results demonstrate that MisL may be used for the autodisplay and release of passenger proteins in attenuated Salmonella or E. coli strains, which may have several applications in vaccine design.     

Lack of O-antigen is essential for plasminogen activation by Yersinia pestis and Salmonella enterica

The O-antigen of lipopolysaccharide (LPS) is a virulence factor in enterobacterial infections, and the advantage of its genetic loss in the lethal pathogen Yersinia pestis has remained unresolved. Y. pestis and Salmonella enterica express beta-barrel surface proteases of the omptin family that activate human plasminogen. Plasminogen activation is central in pathogenesis of plague but has not, however, been found to be important in diarrhoeal disease. We observed that the presence of O-antigen repeats on wild-type or recombinant S. enterica, Yersinia pseudotuberculosis or Escherichia coli prevents plasminogen activation by PgtE of S. enterica and Pla of Y. pestis; the O-antigen did not affect incorporation of the omptins into the bacterial outer membrane. Purified His6-Pla was successfully reconstituted with rough LPS but remained inactive after reconstitution with smooth LPS. Expression of smooth LPS prevented Pla-mediated adhesion of recombinant E. coli to basement membrane as well as invasion into human endothelial cells. Similarly, the presence of an O-antigen prevented PgtE-mediated bacterial adhesion to basement membrane. Substitution of Arg-138 and Arg-171 of the motif for protein binding to lipid A 4'-phosphate abolished proteolytic activity but not membrane translocation of PgtE, indicating dependence of omptin activity on a specific interaction with lipid A. The results suggest that Pla and PgtE require LPS for activity and that the O-antigen sterically prevents recognition of large-molecular-weight substrates. Loss of O-antigen facilitates Pla functions and invasiveness of Y. pestis; on the other hand, smooth LPS renders plasminogen activator cryptic in S. enterica.     

Lipopolysaccharide regions involved in the activation of Escherichia coli outer membrane protease OmpT.

OmpT is an integral outer membrane protease of Escherichia coli. Overexpression of OmpT in E. coli and subsequent in vitro folding of the produced inclusion bodies yielded protein with a native-like structure. However, enzymatically active protease was only obtained after addition of the outer membrane lipid lipopolysaccharide (LPS). OmpT is the first example of an enzyme that requires LPS for activity. In this study, we investigated the nature of this activation. Circular dichroism analysis showed that binding of LPS did not lead to large structural changes. Titration of OmpT with LPS and determining the resulting OmpT activity with a fluorimetric assay yielded a dissociation constant of 10-4 m for E. coli K-12 LPS. Determining the dissociation constants for different LPS chemotypes revealed that a fully acylated lipid A part is minimally required for activation of OmpT. The heptose-bound phosphates in the inner core region were also important for activation. The affinity for LPS was not dependent on the concentration of substrate, neither was affinity for the substrate influenced by the concentration of LPS. This indicated that LPS most likely does not act at the level of substrate binding. We hypothesize that LPS induces a subtle conformational change in the protein that is required for obtaining a native active site geometry.     

Protein regions important for plasminogen activation and inactivation of alpha2-antiplasmin in the surface protease Pla of Yersinia pestis

The plasminogen activator, surface protease Pla, of the plague bacterium Yersinia pestis is an important virulence factor that enables the spread of Y. pestis from subcutaneous sites into circulation. Pla-expressing Y. pestis and recombinant Escherichia coli formed active plasmin in the presence of the major human plasmin inhibitor, alpha2-antiplasmin, and the bacteria were found to inactivate alpha2-antiplasmin. In contrast, only poor plasminogen activation and no cleavage of alpha2-antiplasmin was observed with recombinant bacteria expressing the homologous gene ompT from E. coli. A beta-barrel topology model for Pla and OmpT predicted 10 transmembrane beta-strands and five surface-exposed loops L1-L5. Hybrid Pla-OmpT proteins were created by substituting each of the loops between Pla and OmpT. Analysis of the hybrid molecules suggested a critical role of L3 and L4 in the substrate specificity of Pla towards plasminogen and alpha2-antiplasmin. Substitution analysis at 25 surface-located residues showed the importance of the conserved residues H101, H208, D84, D86, D206 and S99 for the proteolytic activity of Pla-expressing recombinant E. coli. The mature alpha-Pla of 292 amino acids was processed into beta-Pla by an autoprocessing cleavage at residue K262, and residues important for the self-recognition of Pla were identified. Prevention of autoprocessing of Pla, however, had no detectable effect on plasminogen activation or cleavage of alpha2-antiplasmin. Cleavage of alpha2-antiplasmin and plasminogen activation were influenced by residue R211 in L4 as well as by unidentified residues in L3. OmpT, which is not associated with invasive bacterial disease, was converted into a Pla-like protease by deleting residues D214 and P215, by substituting residue K217 for R217 in L4 of OmpT and also by substituting the entire L3 with that from Pla. This simple modification of the surface loops and the substrate specificity of OmpT exemplifies the evolution of a housekeeping protein into a virulence factor by subtle mutations at critical protein regions. We propose that inactivation of alpha2-antiplasmin by Pla of Y. pestis promotes uncontrolled proteolysis and contributes to the invasive character of plague.     

Substrate specificity of the integral membrane protease OmpT determined by spatially addressed peptide libraries

Escherichia coli outer membrane protease T (OmpT) is an endopeptidase that specifically cleaves between two consecutive basic residues. In this study we have investigated the substrate specificity of OmpT using spatially addressed SPOT peptide libraries. The peptide acetyl-Dap(dnp)-Ala-Arg/Arg-Ala-Lys(Abz)-Gly was synthesized directly onto cellulose membrane. The peptide contained the aminobenzoyl (Abz) fluorophore, which was internally quenched by the dinitrophenyl (dnp) moiety. Treatment of the SPOT membrane with the small, water-soluble protease trypsin resulted in highly fluorescent peptide SPOTs. However, no peptide cleavage was observed after incubation with detergent-solubilized OmpT, a macromolecular complex with an estimated molecular mass of 180 kDa. This problem could be solved by the introduction of a long, polar polyoxyethylene glycol linker between the membrane support and the peptide. Peptide libraries for the P(2), P(1), P(1)', and P(2)' positions in the substrate were screened with OmpT, and peptides of positive SPOTs were resynthesized and subjected to kinetic measurements in solution. The best substrate Abz-Ala-Lys-Lys-Ala-Dap(dnp)-Gly had a turnover number k(cat) of 40 s(-)(1), which is 12-fold higher than the starting substrate. Peptides containing an acidic residue at P(2) or P(2)' were not substrates for OmpT, suggesting that long-range electrostatic interactions are important for the formation of the enzyme-substrate complex. OmpT was highly selective toward L-amino acids at P(1) but was less so at P(1)' where a peptide with D-Arg at P(1)' was a competitive inhibitor (K(i) of 19 microM). An affinity chromatography resin based on these findings was developed, which allowed for the one-step purification of OmpT from a bacterial lysate. The implications of the determined consensus substrate sequence (Arg/Lys)/(Arg/Lys)-Ala for the proposed biological function of OmpT in defense against antimicrobial peptides are discussed.     

Prevalence of ompT among Escherichia coli isolates of human origin

OmpT is a protease associated with the outer membrane of Escherichia coli and possesses a high degree of homology to the plasminogen activator, Pla, of Yersinia pestis. We show here that OmpT from intact cells can indeed activate plasminogen. Clinical specimens of E. coli were examined for protease activity and for the ompT gene. Few isolates (12%) were found to be positive for OmpT activity, whereas most (77%) carried the ompT gene and expressed the cloned protease gene. In this report we present evidence suggesting that the surface architecture of E. coli influences the activity of OmpT and that OmpT may be indicative of the pathogenic potential of the organism.     

ompT encodes the Escherichia coli outer membrane protease that cleaves T7 RNA polymerase during purification.

Bacteriophage T7 RNA polymerase is stable in Escherichia coli but very susceptible to cleavage by at least one endoprotease after cell lysis. The major source of this endoprotease activity was found to be localized to the outer membrane of the cell. A rapid whole-cell assay was developed to screen different strains for the presence of this proteolytic activity. Using this assay, we identified some common laboratory strains that totally lack the protease. Genetic and Southern analyses of these null strains allowed us to conclude that the protease that cleaves T7 RNA polymerase is OmpT (formerly termed protein a), a known outer membrane endoprotease, and that the null phenotype results from deletion of the OmpT structural gene. A recombinant plasmid carrying the ompT gene enables these deletion strains to synthesize OmpT and converts them to a protease-positive phenotype. The plasmid led to overproduction of OmpT protein and protease activity in the E. coli K-12 and B strains we used, but only weak expression in the E. coli C strain, C1757. This strain-dependent difference in ompT expression was investigated with respect to the known influence of envZ on OmpT synthesis. A small deletion in the ompT region of the plasmid greatly diminishes the amount of OmpT protein and plasmid-encoded protease present in outer membranes. Use of ompT deletion strains for production of T7 RNA polymerase from the cloned gene has made purification of intact T7 RNA polymerase routine. Such strains may be useful for purification of other proteins expressed in E. coli.     

Outer membrane proteome and its regulation networks in response to glucose concentration changes in Escherichia coli

Escherichia coli growth is a complicated process involved in many factors including the utilization of glucose. It has been reported that E. coli cell growth rate is closely related with glucose concentrations in the cell culture medium. However, the protein regulation networks in response to glucose concentration changes are largely unknown. In the present study, a sub-proteomic methodology has been utilized to characterize alterations of E. coli OM proteins in response to 0.02, 0.2 and 2% concentrations of glucose. In comparison with E. coli cells treated with 0.2% glucose concentration, downregulation of FhuE, FepA, CirA, TolC and OmpX and upregulation of LamB, FadL, OmpF, OmpT and Dps were detected in the E. coli cells treated with 0.02% glucose, and a decrease of TolC, LamB, OmpF, OmpT, OmpX, Dps and elevation of FhuE, FepA, CirA, YncD, FadL and MipA were found in 2% glucose. TolC, LamB and OmpT showed more important roles than other altered OM proteins. Furthermore, the interaction among these altered OM proteins was investigated, and protein interaction networks were characterized. In the networks, all proteins were interacted and regulated by others. TolC, LamB and Dps were the top three proteins that regulated more proteins than others, whereas CirA and OmpT were the top two proteins that were regulated by others. The protein networks could be modified correspondingly with the changes of glucose concentrations. The modifications included the addition of new OM proteins or the change of regulation direction. These findings suggest the important roles of the bacterial OM protein network in E. coli's responses to glucose concentration changes and other environment stresses.     

Proteolysis of bacteriophage phi X174 prohead accessory protein gpB by Escherichia coli OmpT protease is not essential for phage maturation in vivo.

To examine whether cleavage of the phi X174 prohead accessory protein, gpB, by the OmpT protease is required for phage development in vivo, a phage mutant lacking the OmpT cleavage site and an Escherichia coli C delta ompT strain were constructed. The results of burst size experiments suggest that neither the cleavage site nor the OmpT protein is required for phi X174 development.     

Structural basis for activation of an integral membrane protease by lipopolysaccharide

Omptins constitute a unique family of outer membrane proteases that are widespread in Enterobacteriaceae. The plasminogen activator (Pla) of Yersinia pestis is an omptin family member that is very important for development of both bubonic and pneumonic plague. The physiological function of Pla is to cleave (activate) human plasminogen to form the plasma protease plasmin. Uniquely, lipopolysaccharide (LPS) is essential for the catalytic activity of all omptins, including Pla. Why omptins require LPS for enzymatic activity is unknown. Here, we report the co-crystal structure of LPS-free Pla in complex with the activation loop peptide of human plasminogen, its natural substrate. The structure shows that in the absence of LPS, the peptide substrate binds deep within the active site groove and displaces the nucleophilic water molecule, providing an explanation for the dependence of omptins on LPS for enzymatic activity.     

大肠杆菌外膜蛋白酶T及其突变体的表达、复性及生物活性分析

外膜蛋白酶T(Outer-membrane protease T,OmpT)是定位于大肠杆菌外膜,具有高度底物特异性的蛋白水解酶。本文旨在建立克隆表达膜蛋白OmpT和体外复性的方法,考察其蛋白酶活性。首先以大肠杆菌基因组DNA为模板,PCR扩增ompT基因,连接至pET28a(pET-ompT),引入点突变Asp85Ala,构建表达质粒pET-ompT85。然后将两种重组质粒转化入BL21(DE3),均以包涵体形式大量表达。纯化后的蛋白经稀释法复性,并加入粗制脂多糖(Lipopolysaccharide,LPS)恢复蛋白酶活性。通过SDS-PAGE、鱼精蛋白水解试验及生长曲线观察表明,重组蛋白OmpT在体外能水解抗菌肽鱼精蛋白和兔肌肉肌酸激酶,而OmpT突变体则无上述功能。上述结果表明本文获得了具有蛋白水解酶功能的重组蛋白OmpT,该蛋白在体外可保护大肠杆菌抵抗鱼精蛋白的杀菌作用。     

Comparison of Escherichia coli K-12 outer membrane protease OmpT and Salmonella typhimurium E protein.

The predicted amino acid sequence of OmpT, an Escherichia coli outer membrane protease, was found to be highly homologous to that predicted for the pgtE gene product of Salmonella typhimurium. In this paper, it is shown that pgtE codes for a protein functionally homologous to OmpT as judged by its ability to proteolyze T7 RNA polymerase and to localize in the outer membrane of E. coli.     

Immunity protein protects colicin E2 from OmpT protease

The endonuclease colicin E2 (ColE2), a bacteriocidal protein, and the associated cognate immunity protein (Im2) are released from producing Escherichia coli cells. ColE2 interaction with the target cell outer membrane BtuB protein and Tol import machinery allows the dissociation of Im2 from its colicin at the outer membrane surface. Here, we use in vivo approaches to show that a small amount of ColE2-Im2 protein complex bound to sensitive cells is susceptible to proteolytic cleavage by the outer membrane protease, OmpT. The presence of BtuB is required for ColE-Im2 cleavage by OmpT. The amount of colicin cleaved by OmpT is greatly enhanced when ColE2 is dissociated from Im2. We further demonstrate that OmpT cleaves the C-terminal DNase domain of the toxin. As expected, strains that over-produce OmpT are less susceptible to infection by ColE2 than by ColE2-Im2. Our findings reveal an additional function for the immunity protein beside protection of producing cells against their own colicin in the cytoplasm. Im2 protects ColE2 against OmpT-mediated proteolytic attack.     

Identification and cloning of the gene encoding penicillin-binding protein 7 of Escherichia coli.

Penicillin-binding protein (PBP) 7 of Escherichia coli is a poorly characterized member of the family of enzymes that synthesize and modify the bacterial cell wall. The approximate chromosomal position of the gene encoding this protein was determined by measuring the expression of PBPs during lytic infection of E. coli by each of the 476 miniset members of the Kohara lambda phage genomic library. Phages lambda 363 and lambda 364, encompassing the region from 47.7 to 48 min of the chromosome, overproduced PBP 7. One open reading frame, yohB, was present on both these phages and directed the expression of PBPs 7 and 8. The predicted amino acid sequence of PBP 7 contains the consensus motifs associated with other PBPs and has a potential site near the carboxyl terminus where proteolysis by the OmpT protein could occur, creating an appropriately sized PBP 8. The PBP 7 gene (renamed pbpG) was interrupted by insertion of a kanamycin resistance gene cassette and was moved to the chromosome of E. coli. No obvious growth defects were observed, suggesting that PBP 7 is not essential for growth under normal laboratory conditions.     

OmpT expression and activity increase in response to recombinant chloramphenicol acetyltransferase overexpression and heat shock in E. coli

The activity of a 35 kDa protease increased in response to induced expression of chloramphenicol acetyltransferase (CAT) in E. coli. This protease was partially purified, extensively characterized, and identified via the use of zymogram gels as the outer membrane protease, OmpT. In experiments targeting the overlap of well-characterized stress responses, OmpT activity was found to increase in response to heat shock but was only minimally affected by amino acid limitation. The largest increase in activity was found after induction of CAT. OmpT expression levels also increased in response to induction of recombinant CAT overexpression and heat shock. This is the first report of increased activity and expression of an outer membrane protease during cytoplasmic overexpression of a recombinant protein.     

Disruption of IcsP, the major Shigella protease that cleaves IcsA, accelerates actin-based motility

Shigella pathogenesis involves bacterial invasion of colonic epithelial cells and movement of bacteria through the cytoplasm and into adjacent cells by means of actin-based motility. The Shigella protein IcsA (VirG) is unipolar on the bacterial surface and is both necessary and sufficient for actin-based motility. IcsA is inserted into the outer membrane as a 120-kDa polypeptide that is subsequently slowly cleaved, thereby releasing the 95-kDa amino-terminal portion into the culture supernatant. IcsP, the major Shigella protease that cleaves IcsA, was identified and cloned. It has significant sequence similarity to the E. coli serine proteases, OmpP and OmpT. Disruption of icsP in serotype 2a S. flexneri leads to a marked reduction in IcsA cleavage, increased amounts of IcsA associated with the bacterium and altered distribution of IcsA on the bacterial surface. The icsP mutant displays significantly increased rates of actin-based motility, with a mean speed 27% faster than the wild-type strain; moreover, a significantly greater percentage of the icsP mutant moves in the cytoplasm. Yet, plaque formation on epithelial monolayers by the mutant was not altered detectably. These data suggest that IcsA, and not a host protein, is limiting in the rate of actin-based motility of wild-type serotype 2a S. flexneri .     

Identification and antibody-therapeutic targeting of chloramphenicol-resistant outer membrane proteins in Escherichia coli

Bacterial resistance to an antibiotic may result from survival in a suddenly strong antibiotic or in sub-minimum inhibitory concentration of the drug. Their shared proteins responsible for the resistance should be potential targets for designing new drugs to inhibit the growth of the antibiotic-resistant bacteria. In the current study, comparative proteomic methodologies were used for identification of sharedly altered outer membrane proteins (OM proteins) that are responsible for chloramphenical (CAP)-resistant Escherichia coli and for survival in medium with suddenly strong CAP treatment. Six differential OM proteins and another protein with unknown location were determined to be sharedly CAP-resistant-related proteins with the use of 2-DE/MS, Western blotting and gene mutant methods, in which TolC, OmpT, OmpC, and OmpW were critically altered proteins and potential targets for designing of the new drugs. Furthermore, a novel method of specific antibody combating bacterial growth was developed on these OM proteins. Only anti-TolC showed a very significant inhibition on bacterial growth in medium with CAP when antisera to TolC, OmpC, OmpT, and OmpW were separately utilized. The growth of CAP-resistant E. coli and its original strain was completely inhibited when they bound with anti-TolC and survived in 1/8 MIC of CAP. This observed result is basically the same to the finding that DeltatolC was survived in the same concentration of the antibiotic. Our study demonstrates that the enhancement of expression of antibody target with antibiotic could be very effective approach compared to using a drug alone, which highlights a potential way for treatment of infection by antibiotic-resistant bacteria.