Genomic-sequence comparison of two unrelated isolates of the human gastric pathogen Helicobacter pylori.

Helicobacter pylori, one of the most common bacterial pathogens of humans, colonizes the gastric mucosa, where it appears to persist throughout the host's life unless the patient is treated. Colonization induces chronic gastric inflammation which can progress to a variety of diseases, ranging in severity from superficial gastritis and peptic ulcer to gastric cancer and mucosal-associated lymphoma. Strain-specific genetic diversity has been proposed to be involved in the organism's ability to cause different diseases or even be beneficial to the infected host and to participate in the lifelong chronicity of infection. Here we compare the complete genomic sequences of two unrelated H. pylori isolates. This is, to our knowledge, the first such genomic comparison. H. pylori was believed to exhibit a large degree of genomic and allelic diversity, but we find that the overall genomic organization, gene order and predicted proteomes (sets of proteins encoded by the genomes) of the two strains are quite similar. Between 6 to 7% of the genes are specific to each strain, with almost half of these genes being clustered in a single hypervariable region.

A genetic selection for isolating cDNAs encoding secreted proteins.

We describe a simple, rapid technique for simultaneously isolating large numbers of cDNAs encoding secreted proteins. The technique makes use of a facile genetic selection performed in a strain of Saccharomyces cerevisiae deleted for its endogenous invertase gene. A cDNA cloning vector which carries a modified invertase gene lacking its leader sequence is used in conjunction with this strain. Heterologous secreted genes fused appropriately upstream of this defective invertase provide the necessary signals to restore secretion, allowing the yeast to grow on sugars such as sucrose or raffinose. This microbial growth selection facilitates scanning cDNA libraries containing millions of clones, enabling the wholesale identification of novel secreted proteins without the need for specific bioassays. The technique is similar to one previously described (Klein et al. (1996) Proc. Natl. Acad. Sci. USA 93, 7108-7113). We describe results using a cDNA library derived from activated human peripheral blood mononuclear cells (PBMC). Genes identified from this library encoded signal sequences of proteins of diverse structure, function, and cellular location such as cytokines, type 1 and type 2 transmembrane proteins, and proteins found in intracellular organelles. In addition, a number of novel secreted proteins were identified, including a chemokine and a novel G-protein-coupled receptor. Since signal sequences possess features conserved throughout evolution, the procedure can be used to isolate genes encoding secreted proteins from both eukaryotes and prokaryotes.

Molecular cloning of murine FLT and FLT4.

A wide range of growth and differentiation processes are regulated by the signalling of receptor tyrosine kinases (RTKs). We have developed a nested polymerase chain reaction (PCR) procedure with degenerate primers, and used it to identify RTKs expressed in murine fetal thymus. A novel RTK, called FLT4, and the murine homologue of FLT were found, and their PCR fragment sequences were used to isolate larger cDNA clones spanning the complete coding regions of these receptors. FLT4 was found to contain an extracellular region similar to the corresponding sequences of FLT and Flk-1, containing seven immunoglobulin domains.

Molecular cloning of the cDNA encoding a receptor tyrosine kinase-related molecule with a catalytic region homologous to c-met.

Receptor tyrosine kinases mediate a range of growth and differentiation processes in multiple biological systems. In this work, we report the identification of a novel tyrosine kinase-related molecule, nyk-r, and the molecular cloning of its complete cDNA. Its extra-cellular domain bears no apparent homology with other receptor families, but its intracellular kinase-related region has considerable similarity with members of the insulin-receptor family such as c-met and trk B. Also, the nyk-r gene is expressed in a wide range of tissues and cell lines.

Coordinate expression of hydrogenase and ribulose bisphosphate carboxylase in Rhizobium japonicum Hupc mutants.

In contrast to the wild type, H2 uptake-constitutive mutants of Rhizobium japonicum expressed both hydrogenase and ribulose bisphosphate carboxylase activities when grown heterotrophically. However, as bacteroids from soybean root nodules, the H2 uptake-constitutive mutants, like the wild type, did not express ribulose bisphosphate carboxylase activity.

Regulation of hydrogenase in Rhizobium japonicum: analysis of mutants altered in regulation by carbon substrates and oxygen.

The synthesis of the H2 uptake system in free-living Rhizobium japonicum SR is repressed both by oxygen and by carbon substrates. Mutants selected for the ability to express hydrogenase in 10.0% partial pressure O2 were also less sensitive than the wild type to repression by carbon substrates such as arabinose, glycerol, gluconate, and succinate. The H2 uptake system in another class of mutants, previously shown to be hypersensitive to repression by O2, is also more sensitive to repression by carbon substrates. The oxygen- and carbon-insensitive mutants express the hydrogen uptake system during heterotrophic growth in the absence of hydrogen and thus can be considered constitutive (Hupc). The amount of cytochromes in the Hupc mutants is similar to that in the wild-type strain; however, the Hupc mutants contain greater methylene blue-dependent and O2-dependent hydrogenase activity, both as free-living cells and as bacteroids. Two-dimensional polyacrylamide gel electrophoresis revealed that during heterotrophic growth the Hupc mutant strain SR470 synthesized at least six peptides not found in the wild-type strain. The concentrations of cyclic AMP and guanosine tetraphosphate were similar in strain SR and the Hupc mutants during heterotrophic growth.

Mutants of Rhizobium japonicum with Increased Hydrogenase Activity.

Some strains of Rhizobium japonicum can use hydrogen as an energy source for growth under microaerophilic conditions. Mutant strains have been selected that use hydrogen in the presence of high partial pressures of oxygen. The mutants contain more hydrogenase than the parent strain, both as free-living cells and as bacteroids in nitrogen-fixing soybean root nodules.

Altered expression of biodegradative threonine dehydratase in Escherichia coli mutants.

A number of strains of Escherichia coli K-12 failed to synthesize significant amounts of biodegradative threonine dehydratase (EC 4.2.1.16) when grown anaerobically in tryptone-yeast extract medium, a condition which is optimal for the induction of this enzyme. However, the addition of 10 mM potassium nitrate to the culture medium enabled a few of these strains, notably MB201, to induce the enzyme. An examination of the kinetic parameters, modifier sensitivity, and immunological cross-reactivity revealed that the enzyme produced by MB201 in nitrate-supplemented medium appeared indistinguishable from the dehydratase of a wild-type strain. The reduced expression of threonine dehydratase in MB201 appeared highly specific; the synthesis of two other inducible enzymes, D-serine deaminase and tryptophanase, and two "anaerobic" proteins, namely, fumarate reductase and cytochrome c551, remained unaffected. The mutation (tdcI) responsible for the altered expression of the dehydratase in MB201 was located at min 91 on the E. coli chromosome and appeared to tightly linked to if not identical with pgi, the gene encoding phosphoglucose isomerase, as judged by growth experiments on glucose and fructose, direct assay of phosphoglucose isomerase activity, spontaneous and simultaneous reversion of MB201 (tdcI) to TdcI+ and Pgi+ phenotype, and cosegregation of the two loci during transduction with P1 phage. Because not all strains lacking the dehydratase showed nitrate-dependent enzyme synthesis or had lesions at the pgi locus, it appears that mutations at multiple loci on the E. coli chromosome may influence the expression of the enzyme in vivo.

Rhizobium japonicum mutants that are hypersensitive to repression of H2 uptake by oxygen.

The synthesis of an H2 oxidation system in free-living Rhizobium japonicum wild-type strain SR is repressed by oxygen. Maximal H2 uptake rates were obtained in strain SR after derepression in 11 microM or less dissolved oxygen. Oxygen levels above 45 microM completely repressed H2 uptake in strain SR. Five R. japonicum mutant strains that are hypersensitive to repression or H2 oxidation by oxygen were derived from strain SR. The mutants were obtained by screening H2 uptake-negative mutants that retained the ability to oxidize H2 as bacteroids from soybean nodules. As bacteroids, the five mutant strains were capable of H2 oxidation rates comparable to that of the wild type. The mutants did not take up H2 when derepressed in 22 microM dissolved oxygen, whereas strain SR had substantial activity at this oxygen concentration. The O2 repression of H2 uptake in both the wild-type and two mutant strains, SR174 and SR200, was rapid and was similar to the effect of inhibiting synthesis of H2 uptake system components with rifampin. None of the mutant strains was able to oxidize H2 when the artificial electron acceptors methylene blue or phenazine methosulfate were provided. The mutant strains were not sensitive to killing by oxygen, they took up O2 at rates similar to strain SR, and they did not produce an H2 uptake system that was oxygen labile. Cyclic AMP levels were comparable in strain SR and the five mutant strains after subjection of the cultures to the derepression conditions.