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.     

Proteomic screening and identification of differentially distributed membrane proteins in Escherichia coli

Bacteria show asymmetric subcellular distribution of many proteins involved in diverse cellular processes such as chemotaxis, motility, actin polymerization, chromosome partitioning and cell division. In many cases, the specific subcellular localization of these proteins is critical for proper regulation and function. Although cellular organization of the bacterial cell clearly plays an important role in cell physiology, systematic studies to uncover asymmetrically distributed proteins have not been reported previously. In this study, we undertook a proteomics approach to uncover polar membrane proteins in Escherichia coli. We identified membrane proteins enriched in E. coli minicells using a combination of two-dimensional electrophoresis and mass spectrometry. Among a total of 173 membrane protein spots that were consistently detected, 36 spots were enriched in minicell membranes, whereas 15 spots were more abundant in rod cell membranes. The minicell-enriched proteins included the inner membrane proteins MCPs, AtpA, AtpB, YiaF and AcrA, the membrane-associated FtsZ protein and the outer membrane proteins YbhC, OmpW, Tsx, Pal, FadL, OmpT and BtuB. We immunolocalized two of the minicell-enriched proteins, OmpW and YiaF, and showed that OmpW is a bona fide polar protein whereas YiaF displays a patchy membrane distribution with a polar and septal bias.     

OmpW and OmpV are required for NaCl regulation in Photobacterium damsela

Photobacterium damsela is a marine pathogen to both fish and human beings. The bacterium can shift between the ambient seawater and hosts, suggesting the existence of proteins rapidly responding to salt concentration. In the current study, proteomic methodologies were applied to screen the outer membrane proteins (OMPs) related to salt stress. OmpW and OmpV were determined in the response in this bacterium as OmpC and OmpF did in E. coli. Furthermore, the two genes were overexpressed in E. coli Top10F and complemented in V. paraheamolyticus mutants. The ability in salt-tolerance was elevated in the E. coli overexpressed OmpW and reduced in the cells overexpressed OmpV. These V. paraheamolyticus mutants could recover their response to environmental salt concentration when they were complemented by P. damsela OmpW and OmpV. These findings indicate that OmpW and OmpV are required for environmental salt regulation in P. damsela, in which OmpW and OmpV, respectively, elevate and reduce the ability in salinity-tolerance.     

Identification and network of outer membrane proteins regulating streptomysin resistance in Escherichia coli

Bacterial Outer membrane (OM) proteins involved in antibiotic resistance have been reported. However, little is known about the OM proteins and their interaction network regulating streptomycin (SM) resistance. In the present study, a subproteomic approach was utilized to characterize OM proteins of Escherichia coli with SM resistance. TolC, OmpT and LamB were found to be up-regulated, and FadL, OmpW and a location-unknown protein Dps were down-regulated in the SM-resistant E. coli strain. These changes at the level of protein expression were validated using Western blotting. The possible roles of the altered proteins involved in the SM resistance were investigated using genetic modified strains with the deletion of these altered genes. It is found that decreased and elevated minimum inhibitory concentrations and survival capabilities of the gene deleted strains and their resistant strains, Delta tolC, Delta ompT, Delta dps, Delta tolC-R, Delta ompT-R, Delta dps-R and Delta fadL-R, were correlated with the changes of TolC, OmpT, Dps and FadL at the protein expression levels detected by 2-DE gels, respectively. The results may suggest that these proteins are the key OM proteins and play important roles in the regulation of SM resistance in E. coli. Furthermore, an interaction network of altered OM proteins involved in the SM resistance was proposed in this report. Of the six altered proteins, TolC may play a central role in the network. These findings may provide novel insights into mechanisms of SM resistance in E. coli.     

Proteomic analysis of nalidixic acid resistance in Escherichia coli: identification and functional characterization of OM proteins

The worldwide emergence of antibiotic-resistant bacteria poses a serious threat to human health. To understand the mechanisms of the resistance is extremely important to the control of these bacteria. In the current study, proteomic methodologies were utilized to characterize OM proteome of Escherichia coli with nalidixic acid (NA) resistance. The OM proteins TolC, OmpT, OmpC and OmpW were found to be up-regulated, and FadL was down-regulated in the NA-resistant E. coli strains. The changes at the level of protein expression were validated using Western blotting. Furthermore, the possible roles these altered proteins played in regulation of NA resistance were investigated using genetically modified strains with the deletion of these genes. The results obtained from functional characterization of these genetically modified strains suggest that TolC and OmpC may play more important roles in the control of NA resistance than other OM proteins identified. To gain better understanding of the mechanisms of NA resistance, we also characterized the role of the two-component system EnvZ/OmpR which is responsible for the regulation of OmpC and OmpF expression in response to NA resistance using their genetically modified strains. Our results suggest that OmpF and the EnvZ/OmpR are also important participants of the pathways regulating the NA resistance of E. coli.     

Crystal structure of the bacterial nucleoside transporter Tsx

Tsx is a nucleoside-specific outer membrane (OM) transporter of Gram-negative bacteria. We present crystal structures of Escherichia coli Tsx in the absence and presence of nucleosides. These structures provide a mechanism for nucleoside transport across the bacterial OM. Tsx forms a monomeric, 12-stranded beta-barrel with a long and narrow channel spanning the outer membrane. The channel, which is shaped like a keyhole, contains several distinct nucleoside-binding sites, two of which are well defined. The base moiety of the nucleoside is located in the narrow part of the keyhole, while the sugar occupies the wider opening. Pairs of aromatic residues and flanking ionizable residues are involved in nucleoside binding. Nucleoside transport presumably occurs by diffusion from one binding site to the next.     

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.     

Analysis of outer membrane proteome of Escherichia coli related to resistance to ampicillin and tetracycline

The elucidation of the molecular details of antibiotic resistance will lead to improvements in extending the efficacy of current antimicrobials. In the current study, proteomic methodologies were applied to characterize functional outer membrane proteins (Omps) of E. coli K-12 responded to tetracycline and ampicillin resistance for understanding of universal pathways that form barriers for antimicrobial agents. For this purpose, E. coli K-12 expressional outer membrane proteome was characterized and identified with the use of 2-DE and MALDI-TOF/MS methods. Then, differential Omps due to tetracycline or ampcilin resistance were determined by comparison between tetracycline minimum inhibitory concentration (MIC)10, ampicillin MIC10, control0 and control10, showing 9 proteins with 11 spots for tetracycline and 8 protein with 9 spots for ampicillin, showing a difference in only 1 protein (decreased LamB in tetracyclin) between the two antibiotics. Among the proteins, 3 were known as antibiotic-resistant proteins, including TolC, OmpC and YhiU, while FimD precursor, LamB, Tsx, YfiO, OmpW, NlpB were first reported here to be antibiotic-resistance-related proteins. Our findings will be helpful for further understanding of antibiotic-resistant mechanism(s). This study also shows that the combination of Omp purification methods certainly contributes the sensitivity of Omp detection.     

Substantial changes of cellular iron homeostasis during megakaryocytic differentiation of K562 cells

We investigated the remodeling of iron metabolism during megakaryocytic development of K562 cells. Differentiation was successfully verified by increase of the megakaryocytic marker CD61 and concomitant decrease of the erythroid marker γ-globin. The reduction of erythroid properties was accompanied by changes in the cellular iron content and in the expression of proteins regulating cellular iron homeostasis. Independent of available inorganic or transferrin-bound extracellular iron, total intracellular iron increases while the iron-to-protein ratio decreases. The iron exporter ferroportin is downregulated within 1-6 h, followed by downregulation of transferrin receptor-1 (TfR1) and ferritin heavy chain (H-ferritin) mainly after 24-48 h. The hemochromatosis protein-1, a ligand of TfR1, peaked after 24 h. All effects were independent of iron supply with the exception of H-ferritin, which was restored by excess iron. While alterations of CD61, TfR1 and ferritin expression were revoked by a protein kinase C inhibitor, downregulation of ferroportin remained unaffected.     

Expression, characterization and immunogenicity of a major outer membrane protein from Vibrio alginolyticus

Vibrio alginolyticus is one of the Vibrio pathogens common to humans and marine animals.During infection and induction of the host immune response,outer membrane proteins of bacteria play animportant role.In this study,an outer membrane protein gene(ompW)was cloned from V.alginolyticus andexpressed in Escherichia coli.The 645 bp open reading frame(ORF)encodes a protein of 214 amino acidresidues with a predicted molecular weight of 23.3 kDa.The amino acid sequence showed a high identitywith that of Photobacterium damselae(96.2%)and Vibrio parahaemolyticus(94.4%).The alignment analy-sis indicated that OmpW was highly conserved.Sodium dodecyl sulfate-polyacrylamide gel electrophoresisshowed that the gene was over-expressed in E.coli BL21(DE3).Western blot analysis revealed that theexpressed protein had immunoreactivity.The recombinant protein was purified by affinity chromatographyon Ni-NTA Superflow resin.Large yellow croaker vaccinated with the purified OmpW showed significantlyincreased antibody to OmpW,which could resist the infection by V.alginolyticus.A specific antibody wasdetected by enzyme-linked immunosorbent assay.This study suggested that the conserved OmpW could bean effective vaccine candidate against infection by V.alginolyticus.     

Identification of a segment of the Escherichia coli Tsx protein that functions as a bacteriophage receptor area.

The Escherichia coli outer membrane protein Tsx functions as a nucleoside-specific channel and serves as the receptor for colicin K and a number of T-even-type bacteriophages, including phage T6. To identify those segments of the Tsx protein that are important for its phage receptor function, we devised a selection and screening procedure which allowed us to isolate phage-resistant strains synthesizing normal amounts of Tsx. Three different Tsx-specific phages (T6, Ox1, and H3) were employed for the selection of phage-resistant derivatives of a strain expressing a tsx(+)-lacZ+ operon fusion, and 28 tsx mutants with impaired phage receptor function were characterized. Regardless of the Tsx-specific phage used for the initial mutant selection, cross-resistance against a set of six different Tsx phages invariably occurred. With one exception, these mutant Tsx proteins could still serve as a colicin K receptor. DNA sequence analysis of 10 mutant tsx genes revealed the presence of four distinct tsx alleles: two point mutations, an 18-bp deletion, and a 27-bp tandem duplication. In three isolates, Asn-249 was replaced by a Lys residue (tsx-504), and in four others, residue Asn-254 was replaced by Lys (tsx-505). The deletion (tsx-506; one isolate) removed six amino acids (residue 239 to residue 244) from the 272-residue Tsx polypeptide chain, and the DNA duplication (tsx-507; two isolates) resulted in the addition of nine extra amino acids (residue 229 to residue 237) to the Tsx protein. In contrast to the wild-type Tsx protein and the other mutant Tsx proteins the Tsx-507 protein was cleaved by trypsin when intact cells were treated with this protease. The Tsx proteins encoded by the four tsx alleles still functioned in deoxyadenosine uptake in vivo, demonstrating that their nucleoside-specific channel activity was not affected by the alterations that caused the loss of their phage receptor function. HTe changes in the Tsx polypeptide that confer resistance against the Tsx-specific phages are clustered in a small region near the carboxy terminus of Tsx. Our results are discussed in terms of a model for the topological organization of the carboxy-terminal end of the Tsx protein within the outer membrane.     

The outer membrane protein OmpW forms an eight-stranded beta-barrel with a hydrophobic channel

Escherichia coli OmpW belongs to a family of small outer membrane proteins that are widespread in Gram-negative bacteria. Their functions are unknown, but recent data suggest that they may be involved in the protection of bacteria against various forms of environmental stress. To gain insight into the function of these proteins A we have determined the crystal structure of E. coli OmpW to 2.7-A resolution. The structure shows that OmpW forms an 8-stranded beta-barrel with a long and narrow hydrophobic channel that contains a bound n-dodecyl-N,N-dimethylamine-N-oxide detergent molecule. Single channel conductance experiments show that OmpW functions as an ion channel in planar lipid bilayers. The channel activity can be blocked by the addition of n-dodecyl-N,N-dimethylamine-N-oxide. Taken together, the data suggest that members of the OmpW family could be involved in the transport of small hydrophobic molecules across the bacterial outer membrane.     

Gene duplication of the eight-stranded beta-barrel OmpX produces a functional pore: a scenario for the evolution of transmembrane beta-barrels

The repeating unit of outer membrane beta-barrels from Gram-negative bacteria is the beta-hairpin, and representatives of this protein family always have an even strand number between eight and 22. Two dominant structural forms have eight and 16 strands, respectively, suggesting gene duplication as a possible mechanism for their evolution. We duplicated the sequence of OmpX, an eight-stranded beta-barrel protein of known structure, and obtained a beta-barrel, designated Omp2X, which can fold in vitro and in vivo. Using single-channel conductance measurements and PEG exclusion assays, we found that Omp2X has a pore size similar to that of OmpC, a natural 16-stranded barrel. Fusions of the homologous proteins OmpX, OmpA and OmpW were able to fold in vitro in all combinations tested, revealing that the general propensity to form a beta-barrel is sufficient to evolve larger barrels by simple genetic events.     

The structure of the outer membrane protein OmpX from Escherichia coli reveals possible mechanisms of virulence.

BACKGROUND: The integral outer membrane protein X (OmpX) from Escherichia coli belongs to a family of highly conserved bacterial proteins that promote bacterial adhesion to and entry into mammalian cells. Moreover, these proteins have a role in the resistance against attack by the human complement system. Here we present the first crystal structure of a member of this family. RESULTS: The crystal structure of OmpX from E. coli was determined at 1.9 A resolution using multiple isomorphous replacement. OmpX consists of an eight-stranded antiparallel all-next-neighbor beta barrel. The structure shows two girdles of aromatic amino acid residues and a ribbon of nonpolar residues that attach to the membrane interior. The core of the barrel consists of an extended hydrogen-bonding network of highly conserved residues. OmpX thus resembles an inverse micelle. The structure explains the dramatically improved crystal quality of OmpX containing the mutation His100-->Asn, which made the X-ray analysis possible. The coordination spheres of two bound platinum ions are described. CONCLUSIONS: The OmpX structure shows that within a family of virulence-related membrane proteins, the membrane-spanning part of the protein is much better conserved than the extracellular loops. Moreover, these loops form a protruding beta sheet, the edge of which presumably binds to external proteins. It is suggested that this type of binding promotes cell adhesion and invasion and helps defend against the complement system. Although OmpX has the same beta-sheet topology as the structurally related outer membrane protein A (OmpA), their barrels differ with respect to the shear numbers and internal hydrogen-bonding networks.     

Dynamic proteome changes of Shigella flexneri 2a during transition from exponential growth to stationary phase

Shigella flexneri is an infectious pathogen that causes dysentery to human, which remains a serious threat to public health, particularly in developing countries. In this study, the global protein expression patterns of S. flexneri during transition from exponential growth to stationary phase in vitro were analyzed by using 2-D PAGE combined with MALDI-TOF MS. In a time-course experiment with five time points, the relative abundance of 49 protein spots varied significantly. Interestingly, a putative outer membrane protein YciD （OmpW） was almost not detected in the exponential growth phase but became one of the most abundant proteins in the whole stationary-phase proteome. Some proteins regulated by the global regulator FNR were also significantly induced （such as AnsB, AspA, FrdAB, and KatG） or repressed （such as AceEF, OmpX, SodA, and SucAB） during the growth phase transition. These proteins may be the key effectors of the bacterial cell cycle or play important roles in the cellular maintenance and stress responses. Our expression profile data provide valuable information for the study of bacterial physiology and form the basis for future proteomic analyses of this pathogen.     

大肠杆菌外膜蛋白OmpW的克隆及在外膜上高表达

目的: 利用表达载体pLLP-OmpA实现大肠杆菌K12外膜蛋白OmpW在外膜上高表达。方法: PCR扩增ompW基因,构建重组表达载体pLLP-OmpA-ompW,然后转化大肠杆菌K12,得到在外膜上高表达的菌株。提取该菌外膜蛋白,利用免疫小鼠制备得到的抗血清进行Western blot分析验证高表达的OmpW是否定位于外膜。结果: 成功构建了重组表达载体,经转化后成功筛选到高表达菌株,并经Western blot证实高表达的OmpW定位在外膜上。结论: 首次成功获得OmpW在外膜上的高表达,该高表达菌株可为深入研究OmpW在细菌致病机制中的作用及其它功能提供研究基础。     

凡纳滨对虾血蓝蛋白与病原菌凝集作用靶标的鉴定

血蓝蛋白是一种具有多种非特异性免疫学活性的多功能蛋白,以前的研究发现,血蓝蛋白具有凝集活性.本研究采用凝集抑制实验和亲和蛋白质组学等方法探索凡纳滨对虾血蓝蛋白与病原菌的凝集作用靶标.结果显示,大肠杆菌K12和副溶血弧菌外膜蛋白可以抑制血蓝蛋白对7种细菌的凝集活性,其中大肠杆菌K12中2种分子质量分别为16 kD、18 kD （命名为 p16、p18）的外膜蛋白可以与血蓝蛋白发生特异性的结合,经MALDI-TOF/MS鉴定,p16、p18 分别与大肠杆菌外膜蛋白OmpC、OmpX具有高度同源性.尤其是与大肠杆菌K12野生菌株相比,血蓝蛋白对 ΔOmpX 的凝集特异性明显降低,后者仅为前者的25％.由此推测,OmpX 应为血蓝蛋白与病原菌的凝集作用靶标.     

Cloning, expression and immunogenicty analysis of five outer membrane proteins of Vibrio parahaemolyticus zj2003

Genes of five outer membrane proteins of Vibrio parahaemolyticus zj2003, including OmpW, OmpV, OmpK, OmpU and TolC, were cloned and expressed as N-terminal His(6)-tagged proteins in Escherichia coli. The recombinant fusion proteins were purified with nickel chelate affinity chromatography. To analyze the immunogenicity of these proteins, large yellow croaker (Pseudosciaena crocea) were immunized by intraperitoneal injection. Antibody response was assessed by method of enzyme-linked immunosorbent assay. Titres to all five recombinant proteins increased during 4 to 8 weeks post immunization, within the range of log 2 values of 5.75 to 10.8. Recorded relative survival percent (RPS) of the vaccinated groups varied from 80% to 90%, while 10 fish in control group all died. Western blot tests were undertaken with the serum of survival fish after experimental infection. Except for recombinant TolC, the other four recombinant proteins were recognized by the serum. It is indicated that four outer membrane proteins of V. parahaemolyticus zj2003, including OmpW, OmpV, OmpU and OmpK, are immunogenic during in vivo infection, which would be of some significance in developing efficient vaccine in aquaculture. This is the first report of successful vaccination against V. parahaemolyticus with purified recombinant outer membrane proteins.     

NMR structure of the integral membrane protein OmpX

The structure of the integral membrane protein OmpX from Escherichia coli reconstituted in 60 kDa DHPC micelles (OmpX/DHPC) was calculated from 526 NOE upper limit distance constraints. The structure determination was based on complete sequence-specific assignments for the amide protons and the Val, Leu, and Ile(delta1) methyl groups in OmpX, which were selectively protonated on a perdeuterated background. The solution structure of OmpX in the DHPC micelles consists of a well-defined, eight-stranded antiparallel beta-barrel, with successive pairs of beta-strands connected by mobile loops. Several long-range NOEs observed outside of the transmembrane barrel characterize an extension of a four-stranded beta-sheet beyond the height of the barrel. This protruding beta-sheet is believed to be involved in intermolecular interactions responsible for the biological functions of OmpX. The present approach for de novo structure determination should be quite widely applicable to membrane proteins reconstituted in mixed micelles with overall molecular masses up to about 100 kDa, and may also provide a platform for additional functional studies.