Metal-ion-induced expression of gene fragments from subseafloor micro-organisms in the Kumano forearc basin, Nankai Trough.

AIMS: Using substrate-induced gene-expression (SIGEX) screening on subseafloor sediment samples from the Nankai Trough, Japan, we identified gene fragments showing an induction response to metal ions. METHODS AND RESULTS: Environmental DNA libraries in Escherichia coli host cells were tested by the addition of metal ions (Ni2+ , Co2+ , Ga3+ or Mo6+ ), followed by cell sorting of clones exhibiting green fluorescence upon co-expression of green fluorescence protein downstream of the inserted gene fragments. One clone displayed Ni2+ -specific induction, three clones displayed Ga3+ -specific induction and three clones displayed an induction response to multiple metal ions. DNA sequence analysis showed that a variety of genes showed induction responses in the screened clones. CONCLUSIONS: Using the SIGEX approach, we retrieved gene fragments with no previously identified response to metal ions that exhibited metal-ion-induced expression. This method has the potential to promote exploration of gene function through gene-induction response. SIGNIFICANCE AND IMPACT OF THE STUDY: We successfully linked gene-induction response with sequence information for gene fragments of previously unknown function. The SIGEX-based approach exhibited the potential to identify genetic function in unknown gene pools from the deep subseafloor biosphere, as well as novel genetic components for future biotechnological applications.

Biochemistry and molecular genetics of poly-gamma-glutamate synthesis.

Current research into poly-gamma-glutamate (PGA) and its biosynthesis is reviewed. In PGA-producing Bacillus subtilis, glutamate racemase supplies abundant DL-glutamate, the substrate for PGA synthesis. The pgsBCA genes of PGA-producing B. subtilis, which encode the membrane-associated PGA synthetase complex PgsBCA, were characterized and the enzyme complex was suggested to be an atypical amide ligase based on its structure and function. A novel reaction mechanism of PGA synthesis is proposed.

Physiological and biochemical characteristics of poly gamma-glutamate synthetase complex of Bacillus subtilis.

An enzymatic system for poly gamma-glutamate (PGA) synthesis in Bacillus subtilis, the PgsBCA system, was investigated. The gene-disruption experiment showed that the enzymatic system was the sole machinery of PGA synthesis in B. subtilis. We succeeded in achieving the enzymatic synthesis of elongated PGAs with the cell membrane of the Escherichia coli clone producing PgsBCA in the presence of ATP and D-glutamate. The enzyme preparation solubilized from the membrane with 8 mM Chaps catalyzed ADP-forming ATP hydrolysis only in the presence of glutamate; the D-enantiomer was the best cosubstrate, followed by the L-enantiomer. Each component of the system, PgsB, PgsC, and PgsA, was translated in vitro and the glutamate-dependent ATPase reaction was kinetically analyzed. The PGA synthetase complex, PgsBCA, was suggested to be an atypical amide ligase.

Isolation of Bacillus subtilis (chungkookjang), a poly-gamma-glutamate producer with high genetic competence.

A bacterium with high poly-gamma-glutamate (PGA) productivity was isolated from the traditional Korean seasoning, Chung-Kook-Jang. This bacterium could be classified as a Bacillus subtilis, but sporulation in culture was infrequent in the absence of Mn2+. It was judged to be a variety of B. subtilis and designated B. subtilis (chungkookjang). L-Glutamate significantly induced PGA production, and highly elongated PGAs were synthesized. The volumetric yield reached 13.5 mg ml(-1) in the presence of 2% L-glutamate. The D-glutamate content was over 50% in every PGA produced under the conditions used. During PGA production, glutamate racemase activity was found in the cells, suggesting that the enzyme is involved in the D-glutamate supply. Molecular sizes of PGAs were changed by the salt concentration in the medium; PGAs with comparatively low molecular masses were produced in culture media containing high concentrations of NaCl. B. subtilis (chungkookjang) harbors no plasmid and is the first B. subtilis strain reported with both naturally high PGA productivity and high genetic competence.

Efflux system for pyridoxine in Schizosaccharomyces pombe.

Pyridoxine-charged Schizosaccharomyces pombe released pyridoxine rapidly at 30 degrees C: very low amounts of three other B6 vitamers were also released. The rate of efflux was temperature-dependent. The initial rate of efflux was dependent on the concentration of pyridoxine in the cells: the rate was almost zero at lower than 0.02 mM and became saturated at higher than 0.2 mM. Na+, sodium azide, and dinitrophenol increased the rate in both the presence and absence of D-glucose. Mg++, thiamine, and menadione inhibited the efflux. The intracellular concentration of ATP did not significantly affect the efflux rate. The system may be dependent on a membrane potential of the yeast cells. It was found that the fission yeast cells have a gate or carrier system for efflux of pyridoxine, which was distinct from that in Saccharomyces cerevisiae.

Biochemical evidence that Escherichia coli hyi (orf b0508, gip) gene encodes hydroxypyruvate isomerase.

We found a significant activity of hydroxypyruvate isomerase in Escherichia coli clone cells harboring an E. coli gene (called orf b0508 or gip), which is located downstream of the glyoxylate carboligase gene. We newly designated the gene hyi. The enzyme was purified from cell extracts of the E. coli clone. The enzyme had a molecular mass of 58 kDa and was composed of two identical subunits. The optimum pH for the isomerization of hydroxypyruvate was 6.8-7.2. The enzyme required no cofactor. It exclusively catalyzed the isomerization between hydroxypyruvate and tartronate semialdehyde. The apparent K(m) value for hydroxypyruvate was 12.5 mM. The amino acid sequence of E. coli hydroxypyruvate isomerase is highly similar to those of glyoxylate-induced proteins, Gip, found widely from prokaryotes to eukaryotes.

A poly-gamma-glutamate synthetic system of Bacillus subtilis IFO 3336: gene cloning and biochemical analysis of poly-gamma-glutamate produced by Escherichia coli clone cells.

Three genes encoding a poly-gamma-glutamate synthetic system of Bacillus subtilis IFO 3336 (Bacillus natto) were cloned and expressed in Escherichia coli. The E. coli clone produced poly-gamma-glutamate extracellularly. The genes, newly designated as pgsBCA, were homologous with capBCA genes of Bacillus anthracis. All of pgsB, pgsC, and pgsA genes were essential for the polymer production. Addition of Mn(2+), instead of Mg(2+), to the polymer-synthesis medium resulted in an increase in the polymer yield. Co-expression of glutamate racemase gene in E. coli cells harboring pgsBCA genes increased both the polymer production and D-glutamate content in the polymer. The polymer produced by the E. coli clone was higher in average molecular size than that produced by B. subtilis IFO 3336.

Purification, molecular cloning, and catalytic activity of Schizosaccharomyces pombe pyridoxal reductase. A possible additional family in the aldo-keto reductase superfamily.

Pyridoxal reductase (PL reductase), which catalyzes reduction of PL by NADPH to form pyridoxine and NADP(+), was purified from Schizosaccharomyces pombe. The purified enzyme was very unstable but was stabilized by low concentrations of various detergents such as Tween 40. The enzyme was a monomeric protein with the native molecular weight of 41,000 +/- 1,600. The enzyme showed a single absorption peak at 280 nm (E(1%) = 10.0). PL and 2-nitrobenzaldehyde were excellent substrates, and no measurable activity was observed with short chain aliphatic aldehydes; substrate specificity of PL reductase was obviously different from those of yeast aldo-keto reductases (AKRs) so far purified. The peptide sequences of PL reductase were identical with those in a hypothetical 333-amino acid protein from S. pombe (the DDBJ/EMBL/GenBank(TM) accession number D89205). The gene corresponding to this protein was expressed in Escherichia coli, and the purified protein was found to have PL reductase activity. The recombinant PL reductase showed the same properties as those of native PL reductase. PL reductase showed only low sequence identities with members of AKR superfamily established to date; it shows the highest identity (18.5%) with human Shaker-related voltage-gated K(+) channel beta2 subunit. The elements of secondary structure of PL reductase, however, distributed similarly to those demonstrated in the three-dimensional structure of human aldose reductase except that loop A region is lost, and loop B region is extended. Amino acid residues involved in substrate binding or catalysis are also conserved. Conservation of these features, together with the major modifications, establish PL reductase as the first member of a new AKR family, AKR8.

Characterization of yrpC gene product of Bacillus subtilis IFO 3336 as glutamate racemase isozyme.

Glr, the glutamate racemase of Bacillus subtilis (formerly Bacillus natto) IFO 3336 encoded by the glr gene, and YrpC, a protein encoded by the yrpC gene, which is located at a different locus from that of the glr gene in the B. subtilis genome, share a high sequence similarity. The yrpC gene complemented the D-glutamate auxotrophy of Escherichia coli WM335 cells defective in the glutamate racemase gene. Glutamate racemase activity was found in the extracts of E. coli WM335 clone cells harboring a plasmid, pYRPC1, carrying its gene. Thus, the yrpC gene encodes an isozyme of glutamate racemase of B. subtilis IFO 3336. YrpC is mostly found in an inactive inclusion body in E. coli JM109/pYRPC1 cells. YrpC was solubilized readily, but glutamate racemase activity was only slightly restored. We purified YrpC from the extracts of E. coli JM109/pYRPC2 cells using a Glutathione S-transferase Gene Fusion System to characterize it. YrpC is a monomeric protein and contains no cofactors, like Glr. Enzymological properties of YrpC, such as the substrate specificity and optimum pH, are also similar to those of Glr. The thermostability of YrpC, however, is considerably lower than that of Glr. In addition, YrpC showed higher affinity and lower catalytic efficiency for L-glutamate than Glr. This is the first example showing the occurrence and properties of a glutamate racemase isozyme.

Sequence analysis of a cryptic plasmid from Flavobacterium sp. KP1, a psychrophilic bacterium.

A cryptic plasmid found at high copy number was isolated from Flavobacterium sp. KP1, a psychrophilic Gram-negative bacterium, cloned, and sequenced. The sequence will appear in the DDBJ/EMBL/GenBank databases under the accession number AB007196. The pFL1 plasmid is 2311 nucleotides in length with 32.7% GC content, and shows a distinctive nucleotide sequence without homology to other plasmids of similar length. The plasmid contains two open reading frames of significant length, ORFI and ORFII. ORFI encodes a protein similar to the replication proteins found in Gram-negative bacterial plasmids, Bacteroides fragilis plasmid pBI143 and Zymomonas mobilis plasmid pZM2. The putative translation product of ORFII shows homologies with plasmid recombination proteins found mainly in Gram-positive bacterial plasmids such as Staphylococcus aureus plasmid pT181.

Nucleotide sequence, cloning, and overexpression of the D-threonine dehydrogenase gene from Pseudomonas cruciviae.

D-Threonine dehydrogenase (EC 1.1.1) catalyses the oxidation of the 3-hydroxyl group of D-threonine. The nucleotide sequence of the structural gene, dtdS, for this enzyme from Pseudomonas cruciviae IFO 12047 was determined. The dtdS gene encodes a 292 amino acid polypeptide. The enzyme was overproduced in Escherichia coli cells; the activity was found in cell extracts of the clone. The enzyme showed high sequence similarity to 3-hydroxyisobutyrate dehydrogenases. This is the first example showing the primary structure of an enzyme catalysing the NADP(+)-dependent dehydrogenation of D-threo-3-hydroxyamino acids.

Optimization for beta-mannanase production of a psychrophilic bacterium, Flavobacterium sp.

We found that a psychrophilic bacterium, Flavobacterium sp., characterized in this study, has a beta-mannanase (EC 3.2.1.78) activity in the culture medium. The mannanase activity was the highest in the culture medium, containing 1.0% (w/v) guar gum (as a carbon source), 0.3% (NH4)2SO4 (as a nitrogen source), and 0.06% (w/v) yeast extract, of five-days cultivation at 4 degrees C. No mannanase activity was found in the medium containing a monosaccharide or a disaccharide as a carbon source, although the psychrophile could use them. The enzyme activity was found only when the bacterium was cultured in the medium containing a polysaccharide. The enzyme preparation showed a single activity band on a washed gel of SDS-PAGE. The optimal temperature for the enzyme activity was 35 degrees C. When the reaction was done at 10 degrees C, the enzyme showed 25% of the optimal activity. The beta-mannanase preparation efficiently hydrolyzed guar gum, locust bean gum, and glucomannan as well as beta-mannan.

Properties of glutamate racemase from Bacillus subtilis IFO 3336 producing poly-gamma-glutamate.

We found glutamate racemase activity in cell extracts of Bacillus subtilis IFO 3336, which abundantly produces poly-gamma-glutamate. The highest activity was obtained in the early stationary phase of growth. The racemase was purified to homogeneity. The enzyme was a monomer with a molecular mass of about 30 kDa and required no cofactor. It almost exclusively catalyzed the racemization of glutamate; other amino acids, including alanine and aspartate but not homocysteinesulfinate, were inactive as either substrates or inhibitors. Although the Vmax value of the enzyme for L-glutamate is 21-fold higher than that for D-glutamate, the Vmax/Km value for L-glutamate is almost equal to that for the D-enantiomer. The racemase gene, glr, was cloned into Escherichia coli cells and sequenced. The racemase was overproduced in the soluble fraction of the E. coli clone cells with the substitution of ATG for TTG, the initial codon of the glr gene. D-Amino acid aminotransferase activity was not detected in Bacillus subtilis IFO 3336 cells. B. subtilis CU741, a leuC7 derivative of B. subtilis 168, showed lower glutamate racemase activity and lower productivity of poly-gamma-glutamate than B. subtilis IFO 3336. These results suggest that the glutamate racemase is mainly concerned in D-glutamate synthesis for poly-gamma-glutamate production in B. subtilis IFO 3336.

Alanine dehydrogenase from Enterobacter aerogenes: purification, characterization, and primary structure.

Alanine dehydrogenase [EC 1. 4. 1. 1] was purified to homogeneity from a crude extract of Enterobacter aerogenes ICR 0220. The enzyme had a molecular mass of about 245 kDa and consisted of six identical subunits. The enzyme showed maximal activity at about pH 10.9 for the deamination of L-alanine and at about pH 8.7 for the amination of pyruvate. The enzyme required NAD+ as a coenzyme. Analogs of NAD+, deamino-NAD+ and nicotinamide guanine dinucleotide served as coenzymes. Initial-velocity and product inhibition studies suggested that the deamination of L-alanine proceeded through a sequential ordered binary-ternary mechanism. NAD+ bound first to the enzyme, followed by L-alanine, and the products were released in the order of ammonia, pyruvate, and NADH. The Km were 0.47 mM for L-alanine, 0.16 mM for NAD+, 0.22 mM for pyruvate, 0.067 mM for NADH, and 66.7 mM for ammonia. The Km for L-alanine was the smallest in the alanine dehydrogenases studied so far. The enzyme gene was cloned into Escherichia coli JM109 cells and the nucleotides were sequenced. The deduced amino acid sequence was very similar to that of the alanine dehydrogenase from Bacillus subtilis. However, the Enterobacter enzyme has no cysteine residue. In this respect, the Enterobacter enzyme is different from other alanine dehydrogenases.

In vivo effect of GroESL on the folding of glutamate racemase of Escherichia coli.

The overexpression of the murI (glr) gene, which encodes the glutamate racemase of Escherichia coli, resulted in the formation of inclusion bodies of the enzyme, and little activity was found in the soluble fraction of the transformant cells. The coexpression of the groESL gene with murI caused an in vivo solubilization of glutamate racemase in an active form. We isolated the active enzyme and purified it effectively.

Bacterial glutamate racemase has high sequence similarity with myoglobins and forms an equimolar inactive complex with hemin.

Glutamate racemase (EC 5.1.1.3), an enzyme of microbial origin, shows significant sequence homology with mammalian myoglobins, in particular in the regions corresponding to the E and F helices, which constitute the heme binding pocket of myoglobins. Glutamate racemase binds tightly an equimolar amount of hemin, leading to loss of racemase activity. Although this enzyme shows homology with aspartate racemase, the latter does not bind hemin. The glutamate racemase gene of Pediococcus pentosaceus has a 795-nt open reading frame and encodes 265-amino acid residues, which form a monomeric protein (M(r) 29,000). Neither racemase has cofactors, but they contain essential cysteine residues [Yohda, M., Okada, H. & Kumagai, H. (1991) Biochim. Biophys. Acta 1089, 234-240].

Expression of glr (murI, dga) gene encoding glutamate racemase in Escherichia coli.

The murI (dga) gene of Escherichia coli is required for the biosynthesis of D-glutamate, an essential component of bacterial peptidoglycan (Doublet, P., van Heijetnoort, J., and Mengin-Lecreulx, D. (1992) J. Bacteriol. 174, 5772-5779; Dougherty, T. J., Thanassi, J. A., and Pucci, M. J. (1993) J. Bacteriol. 175, 111-116), but its gene product has not been identified. We found that the amino acid sequence of protein deduced from the nucleotide sequence of the open reading frame of murI gene (ORF1) shows a significant homology with that of glutamate racemase of Pediococcus pentosaceus. The amino acid sequence of glutamate racemase of Lactobacillus fermenti recently reported also shows a homology with the deduced amino acid sequence of ORFI (Gallo, K. A., and Knowles, J. R. (1993) Biochemistry 32, 3981-3990). The murI (dga) gene was ligated into a plasmid, pKK223-3, with a designed ribosome binding site and expressed in E. coli JM109 cells. Glutamate racemase was produced by the transformant cells, whereas the enzyme was not found in the host cells. Accordingly, we newly termed the gene glr, which is more relevant than murI and dga. We partially purified the enzyme to characterize it. The enzyme consists of two identical subunits with a molecular weight of about 31,000 in contrast to the P. pentosaceus enzyme, a monomer protein.