Moderate Halophile Vibrio Costicola Research Articles

Analysis of the Genome of Vibrio costicola: Pulsed-Field Gel Electrophoretic Analysis of Genome Size and Plasmid Content

Summary The genome organization of the moderate halophile Vibrio costicola has been investigated. To estimate its genome size, large restriction fragments of genomic DNA were separated by pulsed-field gel electrophoresis (PFGE) after digestion with restriction endonucleases. Enzymes SfiI and MboI generated 25 and 6 restriction fragments, respectively. The genome size of V. costicola E-367 was estimated to be 2,505 kb (SfiI) or 2,259 kb (MboI). Genomic DNA digested with SfiI also permitted the calculation of the genome sizes of five additional V. costicola strains, which ranged from 2,100 to 2,600 kb. Besides, three plasmids, designated pVC1, pVC2 and pVC3 (of 2.95 kb, 19 kb and 21 kb, respectively), as well as a megaplasmid, were detected in V. costicola E-367. The restriction map of pVC1 was determined following the use of 14 restriction enzymes, showing cleavage sites for BamHI, BglII, HindII and SalI. Plasmid pVC1 is a candidate for use in the development of cloning vectors suitable for genetic manipulation of V. costicola. An interesting finding is that the DNA of V. costicola is likely to be highly methylated because digestion with MboI yields few cleavage sites. Additionally, different MboI restriction patterns were observed when this moderate halophile was grown at different salinities. This suggests that the methylation system of this halophile may be affected by the salinity of the growth medium.

Effects of penicillin on a moderately halophilic bacterium,Vibrio costicola

Penicillin inhibited growth and killed growing cells of the moderate halophileVibrio costicola. Cells were more susceptible to penicillin at lower than at higher NaCl concentrations. Inhibition of growth by KCN prevented the lethal action of penicillin. Envelopes of treated cells showed structural damage. Chains of cells separated under the action of the drug. Treated cells swelled rapidly, an unexpected reaction in a bacterium whose internal and external osmolarities are thought to be the same.

Formation and role of glycine betaine in the moderate halophile Vibrio costicola

The moderate halophile Vibrio costicola, growing on a chemically-defined medium, transformed choline into glycine betaine (betaine) by the membrane-bound enzyme choline dehydrogenase and the cytoplasmic enzyme betainal (betaine aldehyde) dehydrogenase. Choline dehydrogenase was strongly induced and betainal dehydrogenase less strongly induced by choline. The formation of these enzymes was also regulated by the NaCl concentration of the growth medium, increasing with increasing NaCl concentrations. Intracellular betaine concentrations also increased with increasing choline and NaCl concentrations in the medium. This increase was almost completely blocked by chloramphenicol, which does not block the increase in salt-tolerant active transport on transfer from a low to a high salt concentration.

Use of natural mRNAs in the cell-free protein-synthesizing systems of the moderate halophile Vibrio costicola

In vitro protein synthesis was studied in extracts of the moderate halophile Vibrio costicola by using as mRNAs the endogenous mRNA of V. costicola and the RNA of the R17 bacteriophage of Escherichia coli. Protein synthesis (amino acid incorporation) was dependent on the messenger, ribosomes, soluble cytoplasmic factors, energy source, and tRNA(FMet) (in the R17 RNA system) and was inhibited by certain antibiotics. These properties indicated de novo protein synthesis. In the V. costicola system directed by R17 RNA, a protein of the same electrophoretic mobility as the major coat protein of the R17 phage was synthesized. Antibiotic action and the response to added tRNA(FMet) showed that protein synthesis in the R17 RNA system, but not in the endogenous messenger system, absolutely depended on initiation. Optimal activity of both systems was observed in 250 to 300 mM NH4+ (as glutamate). Higher salt concentrations, especially those with Cl- as anion, were generally inhibitory. The R17 RNA-directed system was more sensitive to Cl- ions than the endogenous system was. Glycine betaine stimulated both systems and partly overcame the toxic effects of Cl- ions. Both systems required Mg2+, but in lower concentrations than the polyuridylic acid-directed system previously studied. Initiation factors were removed from ribosomes by washing with 3.0 to 3.5 M NH4Cl, concentrations about three times as high as that needed to remove initiation factors from E. coli ribosomes. Washing with 4.0 M NH4Cl damaged V. costicola ribosomes, although the initiation factors still functioned. Cl- ions inhibited the attachment of initiation factors to tRNA(FMet) but had little effect on binding of initiation factors to R17 RNA.

In vitro protein synthesis by the moderate halophile Vibrio costicola: site of action of Cl- ions

In vitro protein synthesis in Vibrio costicola [poly(U)-directed incorporation of phenylalanine] was studied. The extent of protein synthesis was limited by the number of ribosomes present. Density gradient centrifugation experiments suggested that, after runoff of ribosomes from the artificial messenger, the 50S subunit was unable to attach to the 30S-messenger complex. As shown previously (M. Kamekura and D. J. Kushner, J. Bacteriol. 160:385-390, 1984), Cl- ions inhibited protein synthesis; indeed, the highest rate of synthesis took place in the lowest attainable Cl- concentration (37 mM). The inhibitory effects were partly reversed by glutamate and betaine, both of which are concentrated within cells of V. costicola. The strongest reversal was seen when both glutamate and betaine were present. Cl- ions can prevent binding of ribosomes to poly(U) and displace ribosomes already bound to this artificial messenger. The effects of Cl- ions on binding were also reversed by glutamate and betaine. Cl- ions did not affect accuracy of translation; they were shown previously (Kamekura and Kushner, J. Bacteriol. 160:385-390, 1984) not to affect phenylalanyl-tRNA synthetase. It was also found that washing ribosomes with inhibitory NaCl concentrations did not interfere with their ability to carry out protein synthesis later in optimal (low) salt concentrations. On the contrary, these ribosomes were more active than before they were washed. We conclude that the main site of action of Cl- in the system studied is on the binding of ribosomes to the mRNA.

Solute tolerance and membrane lipid composition in some halotolerant food-spoilage bacteria

The solute tolerances of some species of halotolerant Vibrio, Pseudomonas, Staphylococcus, Streptococcus, Bacillus and Lactobacillus have been determined. The upper growth limit for most strains is 1·0–1·8 m NaCl, the same or slightly higher osmolality in glycerol, but considerably less in sucrose. The response of lipid composition to increased solute concentration was tested in 8 representative strains. All showed an increase in anionic lipids (e.g. phosphatidyl-glycerol or glycolipid) relative to zwitterionic lipids (e.g. phosphatidylethanolamine) after growth in NaCl at concentrations close to the maximum tolerated. In two Vibrio spp., a Pseudomonas sp. and a Bacillus sp. the main change was an increase in phosphatidylglycerol relative to phosphatidylethanolamine. Representative Vibrio and Bacillus spp., but not the Pseudomonas spp. showed the same changes in sucrose media; the Vibrio sp. also increased phosphatidylglycerol content in glycerol media. Most of the Gram-positive species tested contained (phospho)glycolipids as major lipid components, which increased, sometimes with phosphatidylglycerol, relative to the zwitterionic lipids in response to raised solute concentration. We conclude that the changes in anionic lipids in response to raised solute concentrations are common amongst a wide variety of Gram-negative and Gram-positive food-spoilage bacteria and, as observed previously in the moderate halophile Vibrio costicola, the response is not specific to NaCl; it is more likely to be part of an osmoregulatory response.

The primary structure of rat ribosomal protein L7. The presence near the amino terminus of L7 of five tandem repeats of a sequence of 12 amino acids.

The covalent structure of rat ribosomal protein L7 was determined in part from the sequence of nucleotides in a recombinant cDNA and in part from the sequence of amino acids in portions of the protein. The complementary analyses supplemented and confirmed each other. Ribosomal protein L7 contains 258 amino acids and has a molecular weight of 30,040. The protein has an unusual and striking structural feature near the NH2 terminus: five tandem repeats of a sequence of 12 residues. Rat L7 appears to be related to ribosomal protein L7 from the moderate halophile Vibrio costicola and perhaps to L30 from Bacillus stearothermophilus, to L7 from the moderate halophile NRCC 41227, and to L22 from Nicotinia tobaccum chloroplast. In addition, there is a sequence of 24 amino acids in rat protein L7 that may be related to segments of the same number of residues in Escherichia coli ribosomal proteins S10, S15, L9, and L22.

The susceptibility of the moderate halophile Vibrio costicola to heavy metals

Fifty‐eight strains of the moderate halophile Vibrio costicola, including both culture collection strains and freshly isolated strains from solar salterns, were examined for their susceptibility to 10 heavy metal ions by using an agar dilution technique. All strains were sensitive to cadmium, copper, silver, zinc and mercury. This latter ion showed the highest activity even at 0·05 mmol/1 metal concentration. On the other hand, all strains were similarly tolerant to lead, and a great proportion of them were also tolerant to nickel (91%) and chromium (88%). Only 44% and 14% of them showed tolerance to arsenate and cobalt, respectively. The majority of strains (96·4%) were multiply metal‐tolerant, with three different metal ion tolerances as the major pattern.

The primary structure of the ribosomal A-protein (L12) from the moderate halophile NRCC 41227.

The complete amino acid sequence of the ribosomal A-protein (equivalent to L7/L12 in Escherichia coli) from a moderate halophile, NRCC 41227, has been determined using an automatic Beckman sequencer and by the manual Edman cleavage of peptides obtained from selective proteolytic cleavage of the ribosomal A-protein. The protein contains 122 amino acids and has a composition of Asp5, Asn2, Thr6, Ser6, Glu21, Gln2, Pro2, Gly12, Ala21, Val14, Met4, Ile4, Leu9, Phe2, Lys11, and Arg1, and a molecular weight of 12 537. It has a net negative charge of -14 and is, therefore, slightly more acidic than other eubacterial ribosomal A-proteins. The phylogenetic tree, obtained by computer analysis of the amino acid sequence of this and other eubacterial A-proteins, indicate these proteins form five subgroups within the eubacterial kingdom. The moderate halophile NRCC 41227 is part of a group of Gram-negative bacteria that include E. coli and another moderate halophile Vibrio costicola. The sequence data provides further evidence that the moderate and extreme halophiles have evolved by separate pathways.

Proton circulation in Vibrio costicola.

The importance of proton movements was assessed in the moderate halophile Vibrio costicola. When anaerobic cells in acidic buffer (pH 6.5) were given an O2 pulse, protons were extruded regardless of the presence of Na+. At pH 8.5, however, V. costicola produced an acidic response to an O2 pulse in the absence of Na+ and an alkaline response when Na+ was present. An Na+/H+ antiport activity was confirmed at pH 8.5. All of these effects were prevented by protonophores or butanol treatment. Growth in complex medium at pH 8.5 was prevented by a high concentration (50 microM) of carbonyl cyanide m-chlorophenyl-hydrazone (CCCP) or a low concentration (5 microM) of another protonophore, 3,3',4',5-tetrachlorosalicylanilide (TCS). The relative ineffectiveness of the former protonophore was caused by the proteose peptone and tryptone ingredients of the complex medium, since 5 microM completely prevented growth in their absence. The results are explained by a primary respiratory-linked proton efflux coupled to a secondary Na+/H+ antiport operating at alkaline pH. Evidence was seen for a role of Na+ in stimulating proton influx at alkaline pH, presumably via the pH homeostasis mechanism.

Effect of chloride and glutamate ions on in vitro protein synthesis by the moderate halophile Vibrio costicola.

Vibrio costicola grown in the presence of different NaCl concentrations contains cell-associated Na+ and K+ ions whose sum is equal to or greater than the external Na+ concentration. In the presence of 0.5 M NaCl, virtually no in vitro protein is synthesized in extracts of cells grown in 1.0 M NaCl. However, we report here that active in vitro protein synthesis occurred in 0.6 M or higher concentrations of Na2SO4, sodium formate, sodium acetate, sodium aspartate, or sodium glutamate, whereas 0.6 M NaF, NaCl, or NaBr completely inhibited protein synthesis as measured by polyuridylic acid-directed incorporation of [14C]phenylalanine. Sodium glutamate, sodium aspartate, and betaine (0.3 M) counteracted the inhibitory action of 0.6 M NaCl. The cell-associated Cl- concentration was 0.22 mol/kg in cells grown in 1.0 M NaCl. Of this, the free intracellular Cl- concentration was only 0.02 mol/kg. Cells contained 0.11 mol of glutamate per kg and small concentrations of other amino acids. All of the negative counterions for cell-associated Na+ and K+ have not yet been determined. In vitro protein synthesis by Escherichia coli was inhibited by sodium glutamate. Hybridization experiments with ribosomes and the soluble (S-100) fractions from extracts of E. coli and V. costicola showed that the glutamate-sensitive fraction was found in the soluble, not the ribosomal, part of the system. The phenylalanyl-tRNA synthetase of V. costicola was not inhibited by 0.5 M or higher concentrations of NaCl; it was slightly more sensitive to high concentrations of sodium glutamate. Therefore, this enzyme was not responsible for the salt response of the V. costicola in vitro protein-synthesizing system.

Energetics of sodium-dependent α-aminoisobutyric acid transport in the moderate halophile Vibrio costicola

The energetics of α-aminoisobutyric acid transport were examined in Vibrio costicola grown in a medium containing the NaCl content (1 M) optimal for growth. Respiration rate, the membrane potential (Δψ) and α-aminoisobutyric acid transport had similar pH profiles, with optima at 8.5–9.0. Cells specifically required Na + ions to transport α-aminoisobutyric acid and to maintain the highest Δψ (150–160 mV). Sodium was not required to sustain high rates of O 2-uptake. Δψ (and α-aminoisobutyric acid transport) recovered fully upon addition of Na + to Na +-deficient cells, showing that Na + is required in formation or maintenance of the transmembrane gradients of ions. Inhibitions by protonophores, monensin, nigericin and respiratory inhibitors revealed a close correlation between the magnitudes of Δψ and α-aminoisobutyric acid transport. Also, dissipation of Δψ with triphenylmethylphosphonium cation abolished α-aminoisobutyric acid transport without affecting respiration greatly. On the other hand, alcohols which stimulated respiration showed corresponding increases in α-aminoisobutyric acid transport, without affecting Δψ. Similarly, N, N′-dicyclohexylcarbodiimide (10 μM) stimulated respiration and α-aminoisobutyric acid transport and did not affect Δψ, but caused a dramatic decline in intracellular ATP content. From these, and results obtained with artificially established energy sources (Δψ and Na + chemical potential), we conclude that Δψ is obligatory for α-aminoisobutyric acid transport, and that for maximum rates of transport an Na + gradient is also required.

Role of membrane-bound 5'-nucleotidase in nucleotide uptake by the moderate halophile Vibrio costicola.

Intact cells of Vibrio costicola hydrolyzed ATP, ADP, and AMP. The membrane-bound 5'-nucleotidase (C. Bengis-Garber and D. J. Kushner, J. Bacteriol. 146:24-32, 1981) was solely responsible for these activities, as shown by experiments with anti-5'-nucleotidase serum and with the ATP analog, adenosine 5'-(beta gamma-imido)-diphosphate. Fresh cell suspensions rapidly accumulated 8-14C-labeled adenine 5'-nucleotides and adenosine. The uptake of ATP, ADP, and AMP (but not the adenosine uptake) was inhibited by adenosine 5'-(beta gamma-imido)-diphosphate similarly to the inhibition of the 5'-nucleotidase. Furthermore, the uptake of nucleotides had Mg2+ requirements similar to those of the 5'-nucleotidase. The uptake of ATP was competitively inhibited by unlabeled adenosine and vice versa; inhibition of the adenosine uptake by ATP occurred only in the presence of Mg2+. These experiments indicated that nucleotides were dephosphorylated to adenosine before uptake. The hydrolysis of [alpha-32P]ATP as well as the uptake of free adenosine followed Michaelis-Menten kinetics. The kinetics of uptake of ATP, ADP, and AMP also each appeared to be a saturable carrier-mediated transport. The kinetic properties of the uptake of ATP were compared with those of the ATP hydrolysis and the uptake of adenosine. It was concluded that the adenosine moiety of ATP was taken up via a specific adenosine transport system after dephosphorylation by the 5'-nucleotidase.

Some properties of the NADP-specific malic enzyme from the moderate halophile Vibrio costicola.

NADP-specific malic enzyme (EC 1.1.1.40) has been purified about 160-fold from the moderate halophile Vibrio costicola. The enzyme has a molecular weight of about 120,000. The purified enzyme was unstable in dilute solutions but could be stabilised by NaCl or glycerol. NH4Cl or KCI caused maximal activation at 0.1M, but higher concentrations were inhibitory. NaCl did not activate and was instead a mixed-type inhibitor towards NH4Cl or KCI. The salt concentration affected the kinetic parameters of the reaction. The apparent Km for L-malate reached a minimal value at about 0.1 M salt; the value for NADP, on the other hand, increased continuosly with the Co2+ or Mg2+. NADH was a mixed-type inhibitor towards both substrates, whereas oxaloacetate was strictly competitive towards L-malate and non-competitive towards NADP. The inhibition kinetics were sigmoidal for NADH and hyperbolic for oxaloacetate. The malic enzyme form V. costicola was similar to those of a marine Pseudomonas and Halobacterium cutirubrum in kinetic and regulatory properties but showed a response to salts intermediate between those of the latter enzymes.