Molecular analysis of the two-component genes, ompR and envZ, in the symbiotic bacterium Xenorhabdus nematophilus

In Escherichia coli the histidine kinase sensor protein, EnvZ, undergoes autophosphorylation and subsequently phosphorylates the regulatory protein, OmpR. Modulation of the levels of OmpR-phosphate controls the differential expression of ompF and ompC . While the phosphotransfer reaction between EnvZ and OmpR has been extensively studied, the domains involved in the sensing function of EnvZ are not well understood. We have used a comparative approach to study the sensing function of EnvZ. During our search of numerous bacteria we found that the symbiotic/pathogenic bacterium Xenorhabdus nematophilus contained the operon encoding both ompR and envZ . Nucleotide sequence analysis revealed that EnvZ of X. nematophilus (EnvZ^X.n.) is composed of 342 amino acid residues, which is 108 residues shorter than EnvZ of E. coli (EnvZ^E.c.). Amino acid sequence comparison showed that the cytoplasmic domains of the EnvZ moleculsshared 57% sequence identity. In contrast, the large hydrophilic periplasmic domain of EnvZ^E.c. was absent in EnvZ^X.n., and was replaced by a shorter hydrophobic region. Although the periplasmic domains had diverged extensively, envZ^X.n. was able to complement a Δ envZ strain of E. coli . OmpF and OmpC were differentially produced in response to changes in medium osmolarity in this strain. Further genetic analysis established that heterologous phosphorylation between EnvZ^X.n. and OmpR of E. coli (OmpR^E.c.) accounted for the complementation of the Δ envZ strain. In addition we show that the OmpR molecules of X. nematophilus and E. coli share 78% amino acid sequence identity. These results indicate that the EnvZ protein of X. nematophilus was able to sense changes in the osmolarity of the growth environment and properly regulate the levels of OmpR-phosphate in E. coli .     

In vivo transfer of chromosomal mutations onto multicopy plasmids utilizing polA strains: Cloning of an ompR 2 mutation in Escherichia coli K-12

Abstract We have devised a simple in vivo scheme for moving chromosomal mutations onto multicopy plasmids in Escherichia coli K-12. A plasmid clone of the relevant wild-type gene is first integrated into the chromosome of a PolA⁻ strain carrying the desired mutation. The plasmid cointegrate formed is then resolved by P1 transduction to a PolA⁺ host. A certain fraction of these transductants will have the mutant allele on the plasmid. Employing this scheme we cloned an ompR 2 mutation onto a multicopy plasmid. To show that the plasmid actually contained the ompR 2 mutation, this allele was introduced back into the chromosome by the gene replacement technique of Gutterson and Koshland [1] and shown to be indistinguishable from the original ompR 2 by genetic mapping and phenotype.     

Interaction between two regulatory proteins in osmoregulatory expression of ompF and ompC genes in Escherichia coli: a novel ompR mutation suppresses pleiotropic defects caused by an envZ mutation.

The ompR and envZ genes, which together constitute the ompB operon, are involved in osmoregulatory expression of the OmpF and OmpC proteins, major outer membrane proteins of Escherichia coli. The envZ11 mutation results in the OmpF- OmpC-constitutive phenotype. A mutant which suppressed defects caused by the envZ11 mutation was isolated. The suppressor mutation also suppressed the LamB- PhoA- phenotype caused by the envZ11 mutation. The mutation occurred in the ompR gene and hence was termed ompR77. The ompR77 mutation alone produced no obvious phenotype. Functioning of the ompR77 allele remained envZ gene dependent. Although the ompR77 mutation suppressed the envZ11 mutation, it did not suppress a mutation that occurred in another position within the envZ gene (envZ160). These results indicate that OmpR and EnvZ, two regulatory proteins, functionally interact with each other.     

Mutation causing reverse osmoregulation of synthesis of OmpF, a major outer membrane protein of Escherichia coli.

Supplementation of growth media with high concentrations of substances like sucrose results in the induction of OmpC synthesis and the suppression of OmpF synthesis. We isolated a novel mutant in which OmpF synthesis is in the opposite direction from normal osmoregulation. By transductional mapping, the mutation was localized at 75 min between malA and aroB on the Escherichia coli chromosome map where the ompR-envZ region is. The mutation was suppressed by a plasmid carrying the ompR gene but not by a plasmid carrying the envZ gene alone. The mutation also resulted in the almost complete suppression of OmpC synthesis. However, the remaining OmpC synthesis was osmoregulated normally. Based on these observations, the mechanism of osmoregulation of OmpF-OmpC synthesis is discussed.     

Effect of water-borne zinc on osmoregulation in the freshwater amphipod Gammarus pulex (L.) from populations that differ in their sensitivity to metal stress

1. Although there is some evidence that exposure to heavy metals can disrupt osmoregulation in crustaceans, most studies have been carried out on relatively pollution-tolerant, marine or estuarine species. Consequently the effects of water-borne zinc (Zn) on osmoregulation by the freshwater amphipod, Gammarus pulex (L.), from two populations that differ in their heavy metal sensitivity, have been compared.
2. 'Clean' site animals (Clowne, Derbyshire) exhibited a marked haemoconcentration (after 4 days at 37·0 μmol Zn l^–1, 5 days at 18·2 μmol Zn l^–1) shown by an increase in haemolymph osmotic pressure (OP_h) and [Na⁺] and [K⁺]. However, after 5 days at 37·0 μmol Zn l^–1, haemolymph of survivors exhibited an OP_h significantly less than controls. 'Contaminated' site animals showed a reduction in OP_h (but not ions) only after 5 days at 76·2 μmol Zn l^–1.
3. There were differences in the threshold and nature of osmoregulatory response to Zn between animals from 'clean' and 'contaminated' sites, but only at concentrations in excess of those (a) known to affect growth and reproduction in 'clean' site animals and (b) occurring at the 'contaminated' site. Clearly population differences in physiological capacity and tolerance do exist but their ecological significance is unclear.     

Promoter exchange between ompF and ompC, genes for osmoregulated major outer membrane proteins of Escherichia coli K-12.

Expression of the ompF and ompC genes coding for major outer membrane proteins OmpF and OmpC is regulated in opposite directions by medium osmolarity. Chimera genes were constructed by a reciprocal exchange of the promoter-signal sequence region between the two genes. The chimera gene construction was designed so that the proteins synthesized by these genes were essentially the same as the OmpC and OmpF proteins. Studies with the chimera genes demonstrated that the osmoregulation of the OmpF-OmpC synthesis was promoter dependent. They also showed that cells grew normally even when the osmoregulation took place in opposite directions. The effects of the ompR2 and envZ mutations, which suppress ompC and ompF expression, respectively, also became reversed. The reduced expression was still subject to the promoter-controlled osmoregulation. Based on these observations, the mechanism of regulation of the ompF-ompC gene expression and its physiological importance are discussed.     

cis-acting sites required for osmoregulation of ompF expression in Escherichia coli K-12.

OmpF and OmpC are major outer membrane proteins which form passive diffusion pores in Escherichia coli K-12. The expression of the structural genes for these proteins, ompF and ompC, is influenced by medium osmotic strength and requires the products of two regulatory genes, ompR and envZ. We have constructed a series of ompF-lacZ fusions containing different regions of ompF to determine sites involved with osmoregulation. These fusions were crossed onto a specialized transducing phage and integrated into the bacterial chromosome in unit copy. By measuring the fluctuations of beta-galactosidase activity in lysogens grown in high versus low osmolarity, we have identified three regions which are necessary. Furthermore, we have determined that, although the OmpR activation site is not sufficient, OmpR is probably essential for ompF osmoregulation.     

Cloning of the regulatory genes (ompR and envZ) for the matrix proteins of the Escherichia coli outer membrane.

We have cloned the regulatory gene cluster of Escherichia coli which is composed of at least two distinct genes, ompR and envZ. These genes are known to regulate the production of the outer membrane matrix proteins. The newly formed plasmids were found to complement not only ompR mutations but also envZ mutations. The ompR gene product was identified as a protein of an apparent molecular weight of 28,500.     

Characterization by deletion mutagenesis in vitro of the promoter region of ompF, a positively regulated gene of Escherichia coli

The ompF gene codes for a major outer membrane protein whose expression is positively regulated by the ompR and envZ genes. Two sets of promoter deletions, upstream deletions and downstream deletions, were generated in vitro, and the promoter function was studied by connecting them with the tet genes. One of the hybrid genes thus constructed had a functioning ompF-tet hybrid promoter. The 107 base-pair fragment was found to be functioning as the ompF promoter, 90 nucleotides upstream and 17 nucleotides downstream of the mRNA start site that was also determined in this study. The start site was preceded by a convenient Pribnow box. Although the sequence at the -35 region had a low degree of homology to the consensus sequence, analyses of the hybrid promoter suggested that this region is involved in the promoter function in relation to the Pribnow box. They also indicated that the domain responsible for regulation by the ompR gene is located within the -35 region and its upstream region.     

Phenotypic revertant mutations of a new OmpR2 mutant (V203Q) of Escherichia coli lie in the envZ gene, which encodes the OmpR kinase.

The Escherichia coli ompR2 allele ompR472 contains a valine-to-methionine point mutation at position 203, resulting in an OmpF-constitutive OmpC- outer membrane phenotype. In the present study, OmpR residue V-203 was replaced with glutamine (V203Q mutation), resulting in the same outer membrane phenotype. However, unlike the OmpFc OmpC- phenotype conferred by the OmpR(V203M) mutant protein, the OmpFc OmpC- phenotype produced by the OmpR(V203Q) mutation was suppressed by the envZ11(T247R) allele. Additional suppressors of OmpR(V203Q) were isolated by random mutagenesis. All suppressor mutations were found in the envZ gene and conferred an OmpC+ OmpF- phenotype in the presence of the wild-type ompR. These envZ11-like mutations mapped to a region different from those previously reported and were incapable of suppressing the ompR(V203M) allele. Our results indicate that while methionine or glutamine replacements could cause similar effects on OmpF and OmpC expression, they conferred different abilities on the mutant proteins to be suppressed by envZ.     

Molecular analysis of mutant ompR genes exhibiting different phenotypes as to osmoregulation of the ompF and ompC genes of Escherichia coli

Summary Expression of the ompF and ompC genes coding for major outer membrane proteins is osmoregulated by solutes, such as sucrose and NaCl, in the growth medium. The OmpR protein, a positive regulator of these genes, is involved in the osmoregulation (Dairi et al. 1985; Nara et al. 1984). In the present work, five mutant ompR genes exhibiting different phenotypes of osmoregulation were cloned and sequenced. Three of them, ompR1, ompR2 and ompR20, were previously isolated mutants. The others, ompR3 and ompR4, were isolated in the present work. The ompR1 mutation resulted in the deletion of 19 amino acids near the C-terminus of the OmpR protein. The ompR3 and ompR4 mutations resulted in Arg¹⁵ to Cys and Arg⁷¹ to Thr conversions, respectively, at the N-terminal portion, whereas the ompR20 and ompR2 mutations resulted in Arg¹⁵⁰ to Cys and Val²⁰⁷ to Met conversions, respectively, at the C-terminal portion. Based on these results, the structure and function of the OmpR protein are discussed in relation to the mechanism of osmoregulation.Abbreviations Tc^r tetracycline resistance - Sm^r streptomycin resistance - Cm^r chloramphenicol resistance - Km^r kanamycin resistance - SDS sodium dodecyl sulphate     

Regulation of haemolymph sodium and potassium during dehydration in the cricket Teleogryllus oceanicus

ABSTRACT. Male crickets ( Teleogryllus oceanicus ) when dehydrated for 3 days lost 51% of their body water, and 65% of their haemolymph volume. Haemolymph osmolality rose from 391 to 572mOs/kg; [Na⁺] from 149 to 289 HIM; and [K⁺] from 13.0 to 26.3 mM. During dehydration 385 μig Na (expressed as NaCl) and 41 μug K (expressed as KCI) were removed from the haemolymph. Rehydration of the dehydrated insects failed to restore the Na⁺ and K⁺ concentrations to near their original levels. Approximately 62% of the missing Na⁺ was excreted, whilst five times the amount of K⁺ removed from the haemolymph was excreted. It is presumed that the excess represents K⁺ removed from intracellular fluid.     

Segregational and structural instability of recombinant plasmid carrying genes for naphthalene degrading pathway

The stability of recombinant plasmid carrying genes for naphthalene mineralization was determined. A strain of Pseudomonas putida capable of mineralizing naphthalene (Nap⁺) via salicylate (Sal⁺) was isolated, and all regulatory and structural genes for the whole pathway were found to be encoded on a 25 kb Eco RI fragment of an approximately 83 kb plasmid present in this strain. The 25 kb Eco RI fragment was cloned into a tetracycline-resistant (Tc^R) cloning vector pLAFR3 and the recombinant plasmid, pRKJ3 (Nap⁺, Sal⁺, Tc^R), thus obtained was transferred into the plasmid-free strain Pseudomonas putida KT2442 in order to test the stability of the plasmid. Plasmid pRKJ3 was found to be segregationally and/or structurally unstable, depending on the growth conditions. Two types of novel derivative strains having the phenotypes Nap⁻, Sal⁺, Tc^R and Nap⁻, Sal⁻, Tc^R with specific deletions of approximately 2 kb and 18 kb, respectively, were obtained.     

CsiA is a bacterial cell wall synthesis inhibitor contributing to DNA translocation through the cell envelope

Agrobacterium tumefaciens VirB10 couples inner membrane (IM) ATP energy consumption to substrate transfer through the VirB/D4 type IV secretion (T4S) channel and also mediates biogenesis of the virB -encoded T pilus. Here, we determined the functional importance of VirB10 domains denoted as the: (i) N-terminal cytoplasmic region, (ii) transmembrane (TM) α-helix, (iii) proline-rich region (PRR) and (iv) C-terminal β-barrel domain. Mutations conferring a transfer- and pilus-minus (Tra^-, Pil^-) phenotype included PRR deletion and β-barrel substitution mutations that prevented VirB10 interaction with the outer membrane (OM) VirB7–VirB9 channel complex. Mutations permissive for substrate transfer but blocking pilus production (Tra⁺, Pil^-) included a cytoplasmic domain deletion and TM domain insertion mutations. Another class of Tra⁺ mutations also selectively disrupted pilus biogenesis but caused release of pilin monomers to the milieu; these mutations included deletions of α-helical projections extending from the β-barrel domain. Our findings, together with results of Cys accessibility studies, indicate that VirB10 stably integrates into the IM, extends via its PRR across the periplasm, and interacts via its β-barrel domain with the VirB7–VirB9 channel complex. The data further support a model that distinct domains of VirB10 regulate formation of the secretion channel or the T pilus.