Kinetic properties of Helicobacter pylori urease compared with jack bean urease

The urease proteins of the jack bean (Canavalia ensiformis) and Helicobacter pylori are similar in molecular mass when separated by non-denaturing gradient polyacrylamide gel electrophoresis, both having three main forms. The molecular mass of their major protein form is within the range 440-480 kDa with the other two lesser forms at 230-260 kDa and 660-740 kDa. These forms are all urease active; however, significant kinetic differences exist between the H. pylori and jack bean ureases. Jack bean urease has a single pH optimum at 7.4, whereas H. pylori urease has two pH optima of 4.6 and 8.2 in barbitone and phosphate buffers that were capable of spanning the pH range 3 to 10. The H. pylori Km was 0.6 mM at pH 4.6 and 1.0 mM at pH 8.2 in barbitone buffer, greater than 10.0 mM, and 1.1 mM respectively in phosphate buffer and also greater than 10.0 mM in Tris.HCl at pH 8.2. By comparison, the jack bean urease had a Km of 1.3 mM in Tris.HCl under our experimental conditions. The findings show that the urease activity of H. pylori was inhibited at the pH optimum of 4.6 in the phosphate buffer, but not in the barbitone buffer. This was shown to be due to competitive inhibition by the sodium and potassium ions in the phosphate buffer, not the phosphate ions as suggested earlier. Jack bean urease activity was similarly inhibited by phosphate buffer but again due to the effect of sodium and potassium ions.     

UreA2B2: a second urease system in the gastric pathogen Helicobacter felis

Urease activity is vital for gastric colonization by Helicobacter species, such as the animal pathogen Helicobacter felis. Here it is demonstrated that H. felis expresses two independent, and distinct urease systems. H. felis isolate CS1 expressed two proteins of 67 and 70 kDa reacting with antibodies to H. pylori urease. The 67-kDa protein was identified as the UreB urease subunit, whereas the N-terminal amino acid sequence of the 70-kDa protein displayed 58% identity with the UreB protein and was tentatively named UreB2. The gene encoding the UreB2 protein was identified and located in a gene cluster named ureA2B2. Inactivation of ureB led to complete absence of urease activity, whereas inactivation of ureB2 resulted in decreased urease activity. Although the exact function of the UreA2B2 system is still unknown, it is conceivable that UreA2B2 may contribute to pathogenesis of H. felis infection through a yet unknown mechanism.     

Translocation of the Helicobacter pylori CagA protein in gastric epithelial cells by a type IV secretion apparatus

Helicobacter pylori is one of the most common bacterial pathogens, infecting about 50% of the world population. The presence of a pathogenicity island (PAI) in H. pylori has been associated with gastric disease. We present evidence that the H. pylori protein encoded by the cytotoxin-associated gene A ( cagA ) is translocated and phosphorylated in infected epithelial cells. Two-dimensional gel electrophoresis (2-DE) of proteins isolated from infected AGS cells revealed H. pylori strain-specific and time-dependent tyrosine phosphorylation and dephosphorylation of several 125–135 kDa and 75–80 kDa proteins. Immunoblotting studies, matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS), cell fractionation and confocal microscopy demonstrated that one of the 125–135 kDa proteins represents the H. pylori CagA protein, which is translocated into the host cell membrane and the cytoplasm. Translocation of CagA was dependent on functional cagA gene and virulence ( vir ) genes of a type IV secretion apparatus composed of virB4 , virB7 , virB10 , virB11 and virD4 encoded in the cag PAI of H. pylori . Our findings support the view that H. pylori actively translocates virulence determinants, including CagA, which could be involved in the development of a variety of gastric disease.     

Helicobacter pylori ABC transporter: effect of allelic exchange mutagenesis on urease activity.

Helicobacter pylori urease requires nickel ions in the enzyme active site for catalytic activity. Nickel ions must, therefore, be actively acquired by the bacterium. NixA (high-affinity nickel transport protein)-deficient mutants of H. pylori retain significant urease activity, suggesting the presence of alternate nickel transporters. Analysis of the nucleotide sequence of the H. pylori genome revealed a homolog of NikD, a component of an ATP-dependent nickel transport system in Escherichia coli. Based on this sequence, a 378-bp DNA fragment was PCR amplified from H. pylori genomic DNA and used as a probe to identify an H. pylori lambda ZAPII genomic library clone that carried these sequences. Four open reading frames of 621, 273, 984, and 642 bp (abcABCD) were revealed by sequencing and predicted polypeptides of 22.7, 9.9, 36.6, and 22.8 kDa, respectively. The 36.6-kDa polypeptide (AbcC) has significant homology (56% amino acid sequence identity) to an E. coli ATP-binding protein component of an ABC transport system, while none of the other putative proteins are significantly homologous to polypeptides in the available databases. To determine the possible contribution of these genes to urease activity, abcC and abcD were each insertionally inactivated with a kanamycin resistance (aphA) cassette and allelic exchange mutants of each gene were constructed in H. pylori UMAB41. Mutation of abcD resulted in an 88% decrease in urease activity to 27 +/- 31 mumol of NH3/min/mg of protein (P < 0.0001), and a double mutant of nixA and abcC resulted in the near abolishment of urease activity (1.1 +/- 1.4 mumol of NH3/min/mg of protein in the double mutant versus 228 +/- 92 mumol of NH3/min/mg of protein in the parent [P < 0.0001]). Synthesis of urease apoenzyme, however, was unaffected by mutations in any of the abc genes. We conclude that the abc gene cluster, in addition to nixA, is involved in production of a catalytically active urease.     

The cell cycle modulated glycoprotein GP115 is one of the major yeast proteins containing glycosylphosphatidylinositol

The cell cycle modulated protein gp115 (115 kDa, isoelectric point about 4.8-5) of Saccharomyces cerevisiae undergoes various post-translational modifications. It is N-glycosylated during its maturation along the secretory pathway where an intermediary precursor of 100 kDa (p100), dynamically related to the mature gp115 protein, is detected at the level of endoplasmic reticulum. Moreover, we have shown by the use of metabolic labeling with [35S]methionine, [3H]palmitic acid and myo-[3H]inositol combined with high resolution two-dimensional gel electrophoresis and immunoprecipitation with a specific antiserum, that gp115 is one of the major palmitate- and inositol-containing proteins in yeast. These results, and the susceptibility of gp115 to phosphatidylinositol-specific phospholipase C treatment strongly indicate that gp115 contains the glycosylphosphatidylinositol (GPI) structure as membrane anchor domain. The two-dimensional analysis of the palmitate- and inositol-labeled proteins has also allowed the characterization of other polypeptides which possibly contain a GPI structure.     

pH-dependent protein profiles of Helicobacter pylori analyzed by two-dimensional gels

Background. Helicobacter pylori survives transient exposure to extreme acid prior to adherence and growth on the gastric epithelium at neutral pH.
Materials and Methods. The effect of pH stress on protein profiles of H. pylori was observed using two-dimensional gel electrophoresis (2-D gels). H. pylori 26695 was grown microaerobically in tryptone-yeast extract broth, 3% fetal bovine serum. Growth in acid alkalinized the medium, whereas growth in base caused acidification. For 2-D gel analysis of protein profiles, cultures were grown in media buffered at pH 5.7 and at pH 7.5.
Results. Under all pH conditions, the most abundant proteins observed were the urease structural subunit UreB and the chaperonin GroEL. Growth in acid significantly increased the abundance of UreB. Thus, urease expression is not completely constitutive, as reported previously, but shows regulation by pH. Another protein observed only at low pH was identified as mammalian apolipoprotein A-I, possibly taken up by H. pylori from bovine serum in the growth medium. This finding, if confirmed, suggests that uptake of high-density lipoprotein from the human host may facilitate acquisition of cholesterol, required for formation of the unique cholesteryl glucosides in the membrane of H. pylori. In growth above pH 7, three stress proteins were induced: GroES (HspA), GroEL (HspB), and the antioxidant AhpC homolog TsaA. In addition, N-terminal sequence analysis identified five additional proteins that had not previously been reported on 2-D gels of H. pylori (FMN, SodB, TrxB, TsaA, and Tsr).
Conclusions. In summary, our 2-D gel study reveals expression of several proteins dependent on growth pH.     

Proteomic analysis of the sarcosine-insoluble outer membrane fraction of Helicobacter pylori strain 26695

Helicobacter pylori causes gastroduodenal disease, which is mediated in part by its outer membrane proteins (OMPs). To identify OMPs of H. pylori strain 26695, we performed a proteomic analysis. A sarcosine-insoluble outer membrane fraction was resolved by two-dimensional electrophoresis with immobilized pH gradient strips. Most of the protein spots, with molecular masses of 10 to 100 kDa, were visible on the gel in the alkaline pI regions (6.0 to 10.0). The proteome of the OMPs was analyzed by matrix-assisted laser desorption ionization-time-of-flight mass spectrometry. Of the 80 protein spots processed, 62 spots were identified; they represented 35 genes, including 16 kinds of OMP. Moreover, we identified 9 immunoreactive proteins by immunoblot analysis. This study contributes to the characterization of the H. pylori strain 26695 proteome and may help to further elucidate the biological function of H. pylori OMPs and the pathogenesis of H. pylori infection.     

Interactions among the seven Helicobacter pylori proteins encoded by the urease gene cluster

Survival of Helicobacter pylori in acid depends on intrabacterial urease. This urease is a Ni(2+)-containing oligomeric heterodimer. Regulation of its activity and assembly is important for gastric habitation by this neutralophile. The gene complex encodes catalytic subunits (ureA/B), an acid-gated urea channel (ureI), and accessory assembly proteins (ureE-H). With the use of yeast two-hybrid analysis for determining protein-protein interactions, UreF as bait identified four interacting sequences encoding UreH, whereas UreG as bait detected five UreE sequences. These results were confirmed by coimmunoprecipitation and beta-galactosidase assays. Native PAGE immunoblotting of H. pylori inner membranes showed interaction of UreA/B with UreI, whereas UreI deletion mutants lacked this protein interaction. Deletion of ureE-H did not affect this interaction with UreI. Hence, the accessory proteins UreE/G and UreF/H form dimeric complexes and UreA/B form a membrane complex with UreI, perhaps enabling assembly of the urease apoenzyme at the membrane surface and immediate urea access to intrabacterial urease to allow rapid periplasmic neutralization.     

Cutting edge: urease release by Helicobacter pylori stimulates macrophage inducible nitric oxide synthase

Inducible NO synthase (iNOS) expression and production of NO are both up-regulated with Helicobacter pylori infection in vivo and in vitro. We determined whether major pathogenicity proteins released by H. pylori activate iNOS by coculturing macrophages with wild-type or mutant strains deficient in VacA, CagA, picB product, or urease (ureA(-)). When filters were used to separate H. pylori from macrophages, there was a selective and significant decrease in stimulated iNOS mRNA, protein, and NO(2)(-) production with the ureA(-) strain compared with wild-type and other mutants. Similarly, macrophage NO(2)(-) generation was increased by H. pylori protein water extracts of all strains except ureA(-). Recombinant urease stimulated significant increases in macrophage iNOS expression and NO(2)(-) production. Taken together, these findings indicate a new role for the essential H. pylori survival factor, urease, implicating it in NO-dependent mucosal damage and carcinogenesis.     

In vivo interactome of Helicobacter pylori urease revealed by tandem affinity purification

In the human gastric bacterium Helicobacter pylori, two metalloenzymes, hydrogenase and urease, are essential for in vivo colonization, the latter being a major virulence factor. The UreA and UreB structural subunits of urease and UreG, one of the accessory proteins for Ni(2+) incorporation into apourease, were taken as baits for tandem affinity purification. The method allows the purification of protein complexes under native conditions and physiological expression levels of the bait protein. Furthermore the tandem affinity purification technology was combined with in vivo cross-link to capture transient interactions. The results revealed different populations of urease complexes: (i) urease captured during activation by Ni(2+) ions comprising all the accessory proteins and (ii) urease in association with metabolic proteins involved e.g. in ammonium incorporation and the cytoskeleton. Using UreG as a bait protein, we copurified HypB, the accessory protein for Ni(2+) incorporation into hydrogenase, that is reported to play a role in urease activation. The interactome of HypB partially overlapped with that of urease and revealed interactions with SlyD, which is known to be involved in hydrogenase maturation as well as with proteins implicated in the formation of [Fe-S] clusters present in the small subunit of hydrogenase. In conclusion, this study provides new insight into coupling of ammonium production and assimilation in the gastric pathogen and the intimate link between urease and hydrogenase maturation.     

Construction of isogenic urease-negative mutants of Helicobacter pylori by allelic exchange.

Isogenic urease-negative mutants of Helicobacter pylori were constructed by allelic replacement. A region of cloned H. pylori DNA containing the structural urease genes (ureA and ureB) was disrupted by insertion of a mini-Tn3-Km transposon. Electrotransformation of H. pylori cells with kanamycin-ureB-disrupted derivative plasmids resulted in isolation of kanamycin-resistant H. pylori transformants. Competence for electrotransformation appeared to be restricted to certain wild-type H. pylori isolates; only 1 isolate (of 10 tested) was consistently transformed. Two of the kanamycin-resistant H. pylori transformants were further studied and shown to be urease negative. Southern hybridization analyses demonstrated that the urease-negative mutants had been constructed by allelic exchange involving simultaneous replacement of the ureB gene with the kanamycin-ureB-disrupted copy and loss of the vector. Immunoblot studies of whole-cell extracts of the isogenic ureB mutants with anti-H. pylori sera indicated the absence of a polypeptide with an apparent molecular mass of 61 kDa; thus, the mutants no longer synthesized the UreB product. Generation of stable, genetically engineered urease mutants of H. pylori will be useful for addressing the role of urease in the pathogenesis of H. pylori infection.     

幽门螺杆菌表面抗原免疫保护作用的体外与活体研究

目的：调查幽门螺杆菌（Hp)几种表面蛋白体外对T细胞增殖的影响和在小鼠体内的免疫保护作用。方法：评价Hp全菌抗原、尿原酶（Urease)、黏附素（hpaA)、外膜蛋白25（Hop25)和38（Hop38)对人外周血T细胞及小鼠CD4^ T细胞增殖的影响;与佐剂合用,评价上述重组蛋白对小鼠Hp感染的免疫预防作用。结果：Urease和Hop25可刺激人及鼠T细胞增殖,hapA只能刺激Hp^ PBL增殖,而Hop38则有毒性作用;Hop25和Hop38均可产生60％的完全保护,hpaA可产生100％的部分保护即降低细菌定植密度,而Urease只能产生40％的部分保护。结论：外膜蛋白可能是一组高效的Hp疫苗免疫原;其长期免疫效果及对T细胞功能的活体调节作用尚需进一步评价。国际上尚未见相关报道。     

Dependence of Helicobacter pylori urease activity on the nickel-sequestering ability of the UreE accessory protein

The Helicobacter pylori ureE gene product was previously shown to be required for urease expression, but its characteristics and role have not been determined. The UreE protein has now been overexpressed in Escherichia coli, purified, and characterized, and three altered versions were expressed to address a nickel-sequestering role of UreE. Purified UreE formed a dimer in solution and was capable of binding one nickel ion per dimer. Introduction of an extra copy of ureE into the chromosome of mutants carrying mutations in the Ni maturation proteins HypA and HypB resulted in partial restoration of urease activity (up to 24% of the wild-type levels). Fusion proteins of UreE with increased ability to bind nickel were constructed by adding histidine-rich sequences (His-6 or His-10 to the C terminus and His-10 as a sandwich fusion) to the UreE protein. Each fusion protein was overexpressed in E. coli and purified, and its nickel-binding capacity and affinity were determined. Each construct was also expressed in wild-type H. pylori and in hypA and hypB mutant strains for determining in vivo urease activities. The urease activity was increased by introduction of all the engineered versions, with the greatest Ni-sequestering version (the His-6 version) also conferring the greatest urease activity on both the hypA and hypB mutants. The differences in urease activities were not due to differences in the amounts of urease peptides. Addition of His-6 to another expressed protein (triose phosphate isomerase) did not result in stimulation of urease, so urease activation is not related to the level of nonspecific protein-bound nickel. The results indicate a correlation between H. pylori urease activity and the nickel-sequestering ability of the UreE accessory protein.     

New inhibitors of Helicobacter pylori urease holoenzyme selected from phage-displayed peptide libraries.

Urease is an important virulence factor for Helicobacter pylori and is critical for bacterial colonization of the human gastric mucosa. Specific inhibition of urease activity has been proposed as a possible strategy to fight this bacteria which infects billions of individual throughout the world and can lead to severe pathological conditions in a limited number of cases. We have selected peptides which specifically bind and inhibit H. pylori urease from libraries of random peptides displayed on filamentous phage in the context of pIII coat protein. Screening of a highly diverse 25-mer combinatorial library and two newly constructed random 6-mer peptide libraries on solid phase H. pylori urease holoenzyme allowed the identification of two peptides, 24-mer TFLPQPRCSALLRYLSEDGVIVPS and 6-mer YDFYWW that can bind and inhibit the activity of urease purified from H. pylori. These two peptides were chemically synthesized and their inhibition constants (Ki) were found to be 47 microM for the 24-mer and 30 microM for the 6-mer peptide. Both peptides specifically inhibited the activity of H. pylori urease but not that of Bacillus pasteurii.     

Purification and characterization of urease from Helicobacter pylori

Urease was purified 112-fold to homogeneity from the microaerophilic human gastric bacterium, Helicobacter pylori. The urease isolation procedure included a water extraction step, size exclusion chromatography, and anion exchange chromatography. The purified enzyme exhibited a Km of 0.3 +/- 0.1 mM and a Vmax of 1,100 +/- 200 mumols of urea hydrolyzed/min/mg of protein at 22 degrees C in 31 mM Tris-HCl, pH 8.0. The isoelectric point was 5.99 +/- 0.03. Molecular mass estimated for the native enzyme was 380,000 +/- 30,000 daltons, whereas subunit values of 62,000 +/- 2,000 and 30,000 +/- 1,000 were determined. The partial amino-terminal sequence (17 residues) of the large subunit of H. pylori urease (Mr = 62,000) was 76% homologous with an internal sequence of the homohexameric jack bean urease subunit (Mr = 90,770; Takashima, K., Suga, T., and Mamiya, G. (1988) Eur. J. Biochem. 175, 151-165) and was 65% homologous with amino-terminal sequences of the large subunits of heteropolymeric ureases from Proteus mirabilis (Mr = 73,000) and from Klebsiella aerogenes (Mr = 72,000; Mobley, H. L. T., and Hausinger, R. P. (1989) Microbiol. Rev. 53, 85-108). The amino-terminal sequence (20 residues) of the small subunit of H. pylori urease (Mr = 30,000) was 65 and 60% homologous with the amino-terminal sequences of the subunit of jack bean urease and with the Mr = 11,000 subunit of P. mirabilis urease (Jones, B. D., and Mobley, H. L. T. (1989) J. Bacteriol. 171, 6414-6422), respectively. Thus, the urease of H. pylori shows similarities to ureases found in plants and other bacteria. When used as antigens in an enzyme-linked immunosorbent assay, neither purified urease nor an Mr = 54,000 protein that co-purified with urease by size exclusion chromatography was as effective as crude preparations of H. pylori proteins at distinguishing sera from persons known either to be infected with H. pylori or not.     

Influence of sample preparation technique on two-dimensional gel electrophoresis of proteins from Porphyromonas gingivalis

Sample preparation methods were compared for two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) of cellular proteins from the proteolytic bacterium Porphyromonas gingivalis. Standard solubilization buffer yielded poorly resolved protein spots, but pre-treatment of cells with trichloroacetic acid or inclusion of the protease inhibitor TLCK during solubilization improved definition and separation. The latter approach allowed reliable detection of a 55 kDa immunodominant surface antigen by Western immunoblotting. Further improvements in resolution occurred when SDS was included in the sample preparation. Thus, controlling proteolysis and optimizing protein solubilization were essential for reproducible separations and maximal protein recovery during 2D-PAGE of P. gingivalis.     

Characterisation of chloroplast heat shock proteins in young leaves of C4 monocotyledons

In vivo radiolabeling of chloroplast proteins in grain sorghum (Sorghum bicolor L. cv. Texas 610) leaves and their separation by one-dimensional electrophoresis revealed at least 6 heat shock proteins (HSPs) between 24 and 94 kDa. of which the 24 kDa protein was the most prominent. All of these chloroplast heat shock proteins were found exclusively in the stroma. The 24 kDa heat shock protein, upon closer examination using two-dimensional electrophoresis proved to be two similarly-sized heat shock polypeptides with identical molecular masses and level of radiolahel incorporation, hut slightly different in isoeiectric points, suggesting isomers. Separation of stromal heat shock proteins synthesised in two other C₄ monocotyledons ( Punicum miliaceum L. and Umchloa panictrides L.) revealed similar putative isomers. each of 24 kDa. Several other, previously unidentified, heat shock proteins between 22 and 38 kDa were also observed in all three species. In P. miliaceum. the most prominent HSP was the pair of 24 kDa proteins, whereas in U. panicoides. it was a group of 35 to 38 kDa HSPs that was most abundant. In vivo chlorophyll fluorescence measurements showed that no sustained impairment to photosynthetic efficiency had occurred for each species after the heat stress regime. However, when cytoplasmic protein synthesis was inhibited during the high temperature treatment, a dramatic decrease was observed in photosynthetic efficiency, suggesting a possible protective role for chloroplast heat shock proteins. It was also shown that a single chloroplast HSP complex of around 380 kDa was observed in the stroma of both 5. bicolor and P. miliaceum leaves in vivo. This was in contrast to the smaller HSP complex (200–265 kDa) observed in previous studies on chloroplast heat shock proteins in C_j species.