Role of sodium bioenergetics in Vibrio cholerae

The ability of the bacterium to use sodium in bioenergetic processes appears to play a key role in both the environmental and pathogenic phases of Vibrio cholerae. Aquatic environments, including fresh, brackish, and coastal waters, are an important factor in the transmission of cholera and an autochthonous source. The organism is considered to be halophilic and has a strict requirement for Na(+) for growth. Furthermore, expression of motility and virulence factors of V. cholerae is intimately linked to sodium bioenergetics and to each other. Several lines of evidence indicated that the activity of the flagellum of V. cholerae might have an impact on virulence gene regulation. As the V. cholerae flagellum is sodium-driven and the Na(+)-NQR enzyme is known to create a sodium motive force across the bacterial membrane, it was recently suggested that the increased toxT expression observed in a nqr-negative strain is mediated by affecting flagella activity. It was suggested that the V. cholerae flagellum might respond to changes in membrane potential and the resulting changes in flagellar rotation might serve as a signal for virulence gene expression. However, we recently demonstrated that although the flagellum of V. cholerae is not required for the effects of ionophores on virulence gene expression, changes in the sodium chemical potential are sensed and thus alternative mechanisms, perhaps involving the TcpP/H proteins, for the detection of these conditions must exist. Analyzing the underlying mechanisms by which bacteria respond to changes in the environment, such as their ability to monitor the level of membrane potential, will probably reveal complex interplays between basic physiological processes and virulence factor expression in a variety of pathogenic species.     

Characterization of a Vibrio cholerae virulence factor homologous to the family of TonB-dependent proteins

IrgA is an iron-regulated virulence factor for infection in an animal model with classical Vibrio cholerae strain 0395. We detected gene sequences hybridizing to irgA at high stringency in clinical isolates in addition to 0395, including another classical strain of V. cholerae, three V. cholerae strains of the El Tor biotype, three non-O1 isolates of V. cholerae, and individual isolates of Vibrio parahaemolyticus, Vibrio fluvialis, and Vibrio alginolyticus. No hybridization to irgA was seen with chromosomal DNA from Vibrio vulnificus or Aeromonas hydrophila. To verify that irgA is the structural gene for the major iron-regulated outer membrane protein of V. cholerae, we determined the amino-terminal sequence of this protein recovered after gel electrophoresis and demonstrated that it corresponds to the amino acid sequence of IrgA deduced from the nucleotide sequence. Gel electrophoresis showed that two El Tor strains of V. cholerae had a major iron-regulated outer membrane protein identical in size and appearance to IrgA in strain 0395, consistent with the findings of DNA hybridization. We have previously suggested that IrgA might be the outer membrane receptor for the V. cholerae siderophore, vibriobactin. Biological data presented here, however, show that a mutation in irgA had no effect on the transport of vibriobactin and produced no defect in the utilization of iron from ferrichrome, ferric citrate, haemin or haemoglobin. The complete deduced amino acid sequence of IrgA demonstrated homology to the entire class of Escherichia coli TonB-dependent proteins, particularly Cir. Unlike the situation with Cir, however, we were unable to demonstrate a role for IrgA as a receptor for catechol-substituted cephalosporins. The role of IrgA in the pathogenesis of V. cholerae infection, its function as an outer membrane receptor, and its potential interaction with a TonB-like protein in V. cholerae remain to be determined.     

Direct immunofluorescence assay for rapid environmental detection ofVibrio cholerae O1

An immunofluorescence assay for direct detection of V. cholerae O1 was developed using polyclonal antibodies raised against outer membrane proteins (OMPs) of V. cholerae O1. Production of OMPs varied with growth media used; maximum production was found in tryptic soy broth. The detection system was specific because no cross-reactivity was observed with other bacteria including V. cholerae O139, E. coli, S. dysenteriae and Salmonella enterica subsp. enterica serovar Typhi. The technique was able to detect 240 CFU/mL of V. cholerae O1 suspended in phosphate-buffered saline. The assay coupled with bacterial enrichment in APW for 6 h detected as few as 5 CFU of V. cholerae in spiked samples. Moreover, a 2-h incubation of enriched bacterial cells in 0.1% yeast extract with 10 ppm nalidixic acid enhanced the bacterial size and helped in morphological identification of V. cholerae. Among 32 potable water samples from afflicted hand pumps and wells collected from a cholera-plagued area 12 were found to be contaminated with V. cholerae by immunofluorescence assay as well as by conventional culture methods. The proposed method could thus be employed in environmental surveillance of V. cholerae O1.     

鸭疫里默氏杆菌外膜蛋白生物学特性研究

血清2型鸭疫里默氏杆菌强毒菌株体外传200代获得了无毒力无免疫原性菌株,采用超声波裂解和超速离心法提取二株菌的外膜蛋白, 以比较分析鸭疫里默氏杆菌外膜蛋白的生物学特性。电镜观察细菌超微结构显示传代菌株外膜膜密度降低, 外膜泡的数量明显减少, 细胞质不均匀、内有空泡产生;免疫印迹结果表明二株菌的外膜蛋白免疫原性多肽存在明显区别;原代菌株的外膜蛋白仅与2型RA抗体出现特异性凝集, 而传代菌株的外膜蛋白与 1、2、10与11型RA抗体均出现凝集;二株菌的外膜蛋白均可诱导雏鸭产生抗体, 但原代菌株外膜蛋白诱导雏鸭产生抗体滴度显著高于200代次菌株;原代菌株外膜蛋白免疫鸭对同源RA菌株的攻击可产生100%的免疫保护, 而传代菌株外膜蛋白免疫鸭对同源RA菌株的攻击不产生免疫保护。序列分析显示两者的外膜蛋白A同源性达到99.9%。结果表明强毒菌株的外膜蛋白为良好的亚单位疫苗候选, 体外连续传代对RA外膜蛋白生物学特性影响显著。     

鸭疫里默氏杆菌外膜蛋白生物学特性研究

血清2型鸭疫里默氏杆菌强毒菌株体外传200代获得了无毒力无免疫原性菌株,采用超声波裂解和超速离心法提取二株菌的外膜蛋白, 以比较分析鸭疫里默氏杆菌外膜蛋白的生物学特性。电镜观察细菌超微结构显示传代菌株外膜膜密度降低, 外膜泡的数量明显减少, 细胞质不均匀、内有空泡产生;免疫印迹结果表明二株菌的外膜蛋白免疫原性多肽存在明显区别;原代菌株的外膜蛋白仅与2型RA抗体出现特异性凝集, 而传代菌株的外膜蛋白与 1、2、10与11型RA抗体均出现凝集;二株菌的外膜蛋白均可诱导雏鸭产生抗体, 但原代菌株外膜蛋白诱导雏鸭产生抗体滴度显著高于200代次菌株;原代菌株外膜蛋白免疫鸭对同源RA菌株的攻击可产生100%的免疫保护, 而传代菌株外膜蛋白免疫鸭对同源RA菌株的攻击不产生免疫保护。序列分析显示两者的外膜蛋白A同源性达到99.9%。结果表明强毒菌株的外膜蛋白为良好的亚单位疫苗候选, 体外连续传代对RA外膜蛋白生物学特性影响显著。     

El Tor型霍乱弧菌分泌性蛋白初步分析

摘要：【目的】利用高通量蛋白质组分析技术,初步探讨El Tor型霍乱弧菌的分泌性蛋白组成,为进一步的功能研究打下基础。【方法】选取El Tor型霍乱弧菌流行株N16961和非流行株92-3,用双相电泳和激光辅助解析-飞行时间串联质谱（Matrix Assisted Laser Desorption Ionization-Time of Flight,MALDI-TOF）技术对培养上清的全部蛋白质组份进行鉴定和分析。【结果】从N16961株培养上清中可检测到206个蛋白点,并鉴定出49种蛋白;从92-3株培养上清中可检测到236个蛋白点,并鉴定出42种蛋白,两株菌共鉴定蛋白68种,其中经预测含有信号肽的蛋白占总数的55.88%（38/68）。按功能不同将所鉴定出的蛋白分为10类,其中代谢酶、蛋白折叠/伴侣蛋白、蛋白合成以及信号传导相关蛋白占全部培养上清蛋白数的36.76%,转运蛋白占14.71%,鞭毛蛋白占11.76%,降解酶占10.29%,外膜蛋白占5.88%,毒素占1.47%,在所鉴定出的蛋白中有11种具有信号肽的假想蛋白和2种功能未知的蛋白为首次被实验证实可出现在霍乱弧菌培养上清中,占19.12%。【结论】初步获得了El Tor型霍乱弧菌流行株和非流行株的分泌性蛋白谱及其组成特征,并提示与霍乱弧菌致病关系密切的鞭毛蛋白在胞外释放机制、红血球凝集素/蛋白酶在非流行株中的高表达特征等值得高度关注。     

Electrophoretic mobility and immune response of outer membrane proteins of Vibrio cholerae O139

Abstract The outer membrane (OM) protein components of a Vibrio cholerae O1 and four V. cholerae O139 strains, collected from cholera patients, were analysed by SDS-PAGE. A protein of 69 kDa molecular mass was observed only when the OMPs were prepared from strains grown in synthetic broth. As a result of passage in the rabbit ileal loop (RIL), virulence was enhanced, and a protein component around 18 kDa of the V. cholerae O139 OM became the major protein component. On immunoblot analysis with rabbit antiserum against V. cholerae O139 OM, it was shown that, apart from the major protein component of V. cholerae O1 OM of around 45 kDa and that of V. cholerae O139 OM of around 38 kDa, all other minor protein components were cross-reactive between the two serogroups. In immunoblot assays with convalescent sera obtained from V. cholerae O139-infected patients, it was observed that in addition to the lipopolysaccharide (LPS)-induced antibody, only the 38 kDa major protein component elicited considerable levels of antibody in the pateint. Minor OM components of 18 kDa were detected in the immunoblot analysis by LPS-directed antibody, however, as the OM proteins are known to be associated with LPS.     

Transposon-induced non-motile mutants of Vibrio cholerae

Non-motile mutants of Vibrio cholerae were isolated after transposon insertion mutagenesis with either Tn5 on a plasmid or Tn10ptac mini-kan in bacteriophage lambda. The physical location and number of transposon insertions was determined. Eighteen Tn5 insertion mutants and 11 Tn10ptac mini-kan insertion mutants had single unique insertion sites. The 18 Tn5 insertions were contained within six different EcoRI fragments and the 11 Tn10ptac mini-kan insertions were contained within eight different fragments of V. cholerae chromosomal DNA. These data suggest that multiple genes are involved in motility. Immunoblot analysis of non-motile mutants with antibody to wild-type flagellar core protein indicated that two of the non-motile mutants made flagellar core protein. Three additional mutants reacted weakly with the antibodies. However, these mutants with immunopositive reactions did not produce any structures which resembled flagella by transmission electron microscopy. In addition, none of the other non-motile mutants produced wild-type flagella. However, five mutants which did not react in the immunoblot produced a structure which resembled a flagellar sheath without the internal flagellar core. In addition to having no filamentous core, the sheaths often extended from the sides of the bacteria, rather than from the poles where the flagellum is normally located. The data suggest that sheath formation is independent of flagellar filament formation, but that proper positioning of the sheath may require the flagellar filament.     

Identification of the vibriobactin receptor of Vibrio cholerae.

Vibrio cholerae produces the novel phenolate siderophore vibriobactin and several outer membrane proteins in response to iron starvation. To determine whether any of these iron-regulated outer membrane proteins serves as the receptor for vibriobactin, the classical V. cholerae strain 0395 was mutagenized by using TnphoA, and iron-regulated fusions were analyzed for vibriobactin transport. One mutant, MBG14, was unable to bind or utilize exogenous vibriobactin and did not grow in low-iron medium. However, synthesis of the siderophore and transport of other iron complexes, including ferrichrome, hemin, and ferric citrate, were unaffected in MBG14. Analysis of membrane proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis demonstrated the loss from the mutant of a 74-kDa iron-regulated outer membrane protein present in the parental strain when grown in iron-limiting conditions. This protein partitioned into the detergent phase during Triton X-114 extraction, suggesting that it is a hydrophobic membrane protein. DNA sequences encoding the gene into which TnphoA had inserted, designated viuA (vibriobactin uptake), restored the wild-type phenotype to the mutant; the complemented mutant expressed the 74-kDa outer membrane protein under iron-limiting conditions and possessed normal vibriobactin binding and uptake. These data indicate that the 74-kDa outer membrane protein of V. cholerae serves as the vibriobactin receptor.     

Comparison of the cell envelope structure of a lipopolysaccharide-defective (heptose-deficient) strain and a smooth strain of Salmonella typhimurium.

The cell envelope structure of Salmonella typhimurium LT2, which has a heptose-deficient lipopolysaccharide (LPS), is significantly different from that of an isogenic strain with a normal LPS. The rough strain, when examined by freeze-etching, lacks most surface structures that are routinely present in the smooth strain (surface particles and flagella) and has few transmemberane studs in the cytoplasmic membrane (those present are generally found in aggregates), and the outer membrane cleavage is substantially stronger than that of the smooth strain. These envelope differences were independent of both growth temperature and culture age. Examination of ultrathin sections indicated that the rough strain has an outer membrane which forms a much more defined double-track artifact than the smooth strain. The addition of MgCl2 to the growth medium of the rough strain decreased the extent of outer membrane cleavage, and flagella became evident in freeze-etched preparations. The presence of supplemental MgCl2 in the growth medium, which resulted in these morphological changes in the rough strain, also produced growth at a previously restrictive temperature and a decrease in the leakage of periplasmic enzymes. The smooth strain was unaltered morphologically or physiologically by MgCl2 under identical conditions. It is suggested that the outer membrane of the rough strain is more planar.     

FLAGELLAR DEVELOPMENT AND REGENERATION IN VOLVOX CARTERI (CHLOROPHYTA)1

The biflagellate somatic cells of Volvox carteri f. nagariensis lyengar exhibit an asymmetric pattern of flagellar development. Initiallt each somatic cell has two short (4 μm) flagella but after several hours one flagellum on each cell elongates unitl it reaches a length of 12 μm. Due to the regular arrangement of somatic cells in the Volvox spheroid it is apparent that the same flagellum on each somatic is the first to elongale. The asymmetric flagellar length is maintained for about 8 h after which the second flagellum on each somatic cell elongates. When the second flagellum attains the same length (12 μm) as the first flagellum, both flagella elongale at the same rate until reaching a final length of 22 μm. Experimental removal of somatic cell flagella results in their regeneration. Somatis cells regenerate both flagella simultaneously and full length flagella are produced in about 2 h. The intial rate of flagellar regeneration is about ten times faster than the intial rate of flagllar growth in development. Cycloheximide, an inhibitor of protein synthesis, has no effect on the initial rate of flagellar regeneration but the flagella produced in the presence of the drug are half the length of flagella produced in its absence. Somatic cells are able to regenerate flagella up to the time of α and β tubulin, the major structural proteins of the flagellar axoneme, and other cellular proteins.     

Effect of changes in the osmolarity of the growth medium on Vibrio cholerae cells.

The rate and extent of lysis of Vibrio cholerae cells under nongrowing conditions were dependent on the osmolarity of the growth medium. Gross alterations in cellular morphology were observed when V. cholerae cells were grown in media of high and low osmolarity. The rate of lysis of V. cholerae cells under nongrowing conditions increased after treatment with chloramphenicol. Chloramphenicol-treated V. cholerae 569B cells showed formation of sphaeroplast-like bodies in medium of high osmolarity, but not in low osmolarity. Changes in the osmolarity of the growth medium also regulated the expression of the outer membrane proteins. This regulation was abolished if V. cholerae cells were grown in Pi-depleted medium. Analysis of the lytic behavior and composition of outer membrane proteins of an osmotically fragile mutant strain revealed a similar dependence on the osmolarity of the growth medium.     

Sequence variability of the 40-kDa outer membrane proteins of Fusobacterium nucleatum strains and a model for the topology of the proteins

The complete nucleotide sequences of the fomA genes encoding the 40-kDa outer membrane proteins (OMPs) of strains ATCC 10953 and ATCC 25586 of Fusobacterium nucleatum were determined using the genomic DNA, or DNA fragments ligated into a vector plasmid, as template in a polymerase chain reaction. The deduced amino acid sequences of these two proteins were aligned with the amino acid sequence of the corresponding protein of F. nucleatum strain Fev1 and examined for conserved/variable polypeptide segments. A model for the topology of the 40-kDa OMPs is proposed on the basis of this alignment and application of the structural principles derived for OMPs of Escherichia coli. According to this model, sixteen polypeptide segments, which are highly conserved, traverse the outer membrane, thereby creating eight external loops, most of which are highly variable.     

Requirements for conversion of the Na(+)-driven flagellar motor of Vibrio cholerae to the H(+)-driven motor of Escherichia coli

Bacterial flagella are powered by a motor that converts a transmembrane electrochemical potential of either H(+) or Na(+) into mechanical work. In Escherichia coli, the MotA and MotB proteins form the stator and function in proton translocation, whereas the FliG protein is located on the rotor and is involved in flagellar assembly and torque generation. The sodium-driven polar flagella of Vibrio species contain homologs of MotA and MotB, called PomA and PomB, and also contain two other membrane proteins called MotX and MotY, which are essential for motor rotation and that might also function in ion conduction. Deletions in pomA, pomB, motX, or motY in Vibrio cholerae resulted in a nonmotile phenotype, whereas deletion of fliG gave a nonflagellate phenotype. fliG genes on plasmids complemented fliG-null strains of the parent species but not fliG-null strains of the other species. FliG-null strains were complemented by chimeric FliG proteins in which the C-terminal domain came from the other species, however, implying that the C-terminal part of FliG can function in conjunction with the ion-translocating components of either species. A V. cholerae strain deleted of pomA, pomB, motX, and motY became weakly motile when the E. coli motA and motB genes were introduced on a plasmid. Like E. coli, but unlike wild-type V. cholerae, motility of some V. cholerae strains containing the hybrid motor was inhibited by the protonophore carbonyl cyanide m-chlorophenylhydrazone under neutral as well as alkaline conditions but not by the sodium motor-specific inhibitor phenamil. We conclude that the E. coli proton motor components MotA and MotB can function in place of the motor proteins of V. cholerae and that the hybrid motors are driven by the proton motive force.     

Sequence variability of the 40-kDa outer membrane proteins of Fusobacterium nucleatum strains and a model for the topology of the proteins

The complete nucleotide sequences of the fomA genes encoding the 40-kDa outer membrane proteins (OMPs) of strains ATCC 10953 and ATCC 25586 of Fusobacterium nucleatum were determined using the genomic DNA, or DNA fragments ligated into a vector plasmid, as template in a polymerase chain reaction. The deduced amino acid sequences of these two proteins were aligned with the amino acid sequence of the corresponding protein of F. nucleatum strain Fev1 and examined for conserved/variable polypeptide segments. A model for the topology of the 40-kDa OMPs is proposed on the basis of this alignment and application of the structural principles derived for OMPs of Escherichia coli. According to this model, sixteen polypeptide segments, which are highly conserved, traverse the outer membrane, thereby creating eight external loops, most of which are highly variable.     

Motifs in outer membrane protein sequences: applications for discrimination

Discriminating outer membrane proteins (OMPs) from other folding types of globular and membrane proteins is an important problem for predicting their secondary and tertiary structures and detecting outer membrane proteins from genomic sequences as well. In this work, we have systematically analyzed the distribution of amino acid residues in the sequences of globular and outer membrane proteins with several motifs, such as A*B, A**B, etc. We observed that the motifs E*L, A*K and L*E occur frequently in globular proteins while S*S, N*S and R*D predominantly occur in OMPs. We have devised a statistical method based on frequently occurring motifs in globular and OMPs and obtained an accuracy of 96% and 82% for correctly identifying OMPs and excluding globular proteins, respectively. Further, we noticed that the motifs of transmembrane helical (TMH) proteins are different from that of OMPs. While I*A, I*L and L*I prefer in TMH proteins S*S, N*S and N*N predominantly occur in OMPs. The information about the occurrence of A*B motifs in TMH and OMPs could discriminate them with an accuracy of 80% for excluding OMPs and 100% for identifying OMPs. The influence of protein size and structural class for discrimination is discussed.