The nucleotide sequence for a proline-activating domain of gramicidin S synthetase 2 gene from Bacillus brevis

A fragment encoding proline-activating domain (grs 2-pro) of gramicidin S synthetase 2 (GS 2) was found in an 8.1-kilobase pairs (kb) DNA fragment of Bacillus brevis Nagano, which contained the full length of GS 1 gene (grs 1). The clones designated GS719 and GS708, which expressed gramicidin S synthetase 1, were elucidated to express immunoreactive proteins to GS 2 antibodies with approximate molecular weights of 115,000, 105,000 (GS719), and 110,000 (GS708). The partial purification of the gene products of these clones was carried out using DEAE-Sepharose CL-6B column chromatography. The immunoreactive proteins to GS 2 antibodies were separated from gramicidin S synthetase 1 protein and had specific proline-dependent ATP-32PPi exchange activity. The nucleotide sequence for the proline-activating domain in the 8.1-kb insert was determined. This fragment was 2,879 base pairs long, and encoded 959 amino acids. The calculated molecular weight of 111,671 was consistent with the apparent molecular weight of 115,000 found in SDS-PAGE of the immunoreactive products to GS 2 antibodies. The open reading frame for this protein followed grs 1 gene, though two were separated by a 73-base pair noncoding sequence, and remained open to the end.(ABSTRACT TRUNCATED AT 250 WORDS)     

A comparative study of sulfhydryl groups required for the catalytic activity of gramicidin S synthetase and isoleucyl tRNA synthetase

The sulfhydryl groups required for the catalytic activity of gramicidin S synthetase of Bacillus brevis and Escherichia coli isoleucyl tRNA synthetase were compared. In gramicidin S synthetase 2(GS 2), about four sulfhydryl groups react rapidly with 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) or N-ethylmaleimide (NEM), and are essential for gramicidin S formation in the presence of gramicidin S synthetase 1 (GS 1). These sulfhydryl groups are protected against DTNB and NEM reactions by the preincubation of GS 2 with amino acid substrates in the presence of ATP and MgCl2, like the sulfhydryl groups that react rapidly with DTNB or NEM and are required for the catalytic activity of GS 1 and isoleucyl tRNA synthetase. In GS 2, GS 1, and isoleucyl tRNA synthetase, the sulfhydryl group that reacts rapidly with NEM and is required for the catalytic activity is involved in the amino acid binding as a thioester. In isoleucyl tRNA synthetase, it is suggested that isoleucine may be transferred from the isoleucine thioester enzyme complex to tRNA by a mechanism similar to that proposed for gramicidin S synthetase.     

Biosynthesis of the Escherichia coli siderophore enterobactin: sequence of the entF gene, expression and purification of EntF, and analysis of covalent phosphopantetheine.

The sequence of the entF gene which codes for the serine activating enzyme in enterobactin biosynthesis is reported. The gene encodes a protein with a calculated molecular weight of 142,006 and shares homologies with the small subunits of gramicidin S synthetase and tyrocidine synthetase. We have subcloned and overexpressed entF in a multicopy plasmid and attempted to demonstrate L-serine-dependent ATP-[32P]PPi exchange activity and its participation in enterobactin biosynthesis, but the overexpressed enzyme appears to be essentially inactive in crude extract. A partial purification of active EntF from wild-type Escherichia coli, however, has confirmed the expected activities of EntF. In a search for possible causes for the low level of activity of the overexpressed enzyme, we have discovered that EntF contains a covalently bound phosphopantetheine cofactor.     

Organization of the biosynthesis genes for the peptide antibiotic gramicidin S.

A recombinant bacteriophage containing the intact Bacillus brevis gene for gramicidin S synthetase 1, grsA, and the 5' end of the gramicidin S synthetase 2 gene, grsB, was identified by screening an EMBL3 library with anti-GrsA antibodies. This clone, EMBL315, has a 14-kilobase (kb) insert that hybridizes to the previously isolated 3.9-kb fragment of the grsB gene, which encodes the 155-kilodalton ornithine-activating domain of gramicidin S synthetase 2. Deletion and subcloning experiments with the 14-kb insert located the grsA structural gene and its putative promoter on a 4.5-kb PvuII fragment which encoded the full-length 120-kilodalton protein in Escherichia coli. In addition, hybridization analysis revealed that the 5' end of the grsB gene is located approximately 3 kb from the grsA structural gene. Furthermore, these studies indicated that grsA and grsB are transcribed in opposite orientations.     

Molecular cloning and nucleotide sequence of the gramicidin S synthetase 1 gene

The entire gene for gramicidin S synthetase 1 (GS 1) was cloned into the plasmid vector pUC18, and the nucleotide sequences of the GS 1 gene and its flanking region were determined. The full-length clone was 4,539 base pairs long and had an open reading frame of 3,294 nucleotides coding for 1,098 amino acids. The calculated molecular weight of 123,474 agreed with the apparent molecular weight of 120,000 found in SDS-PAGE of GS 1 from B. brevis. The nucleotide sequence of GS 1 gene was highly homologous to that of tyrocidine synthetase 1. The overall similarity between the deduced amino acid sequences of the two genes was 57.5%. The gene product of clone GS309 was easily purified to an essentially homogeneous state by ammonium sulfate fractionation followed by DEAE-Sepharose CL-6B, Ultrogel AcA-34, and second DEAE-Sepharose CL-6B column chromatography. The purified protein catalyzed the D-phenylalanine-dependent ATP-32PPi exchange reaction which is specific for GS 1 activity, and the specific activity of the purified product was nearly the same as the purified GS 1 from B. brevis. The product also showed a weak phenylalanine racemase activity.     

Dependence of in vivo inactivation kinetics of gramicidin S synthetase on cell physiology

Gramicidin S synthetase, the enzyme complex catalyzing the biosynthesis of the antibiotic gramicidin S in Bacillus brevis, is subject to O(2)-dependent in vivo inactivation during exponential aerobic growth after reaching a peak in specific activity. The five amino acid substrates of the synthetase are capable of stabilizing its activity to varying degrees in whole cells shaken aerobically. Depending on the time of cell harvesting before, during, or after the peak in intracellular gramicidin S synthetase specific activity, the enzyme has a long, medium, or short half-life, respectively. The kinetic profiles of gramicidin S synthetase in B. brevis cells indicate that both the kinetics of synthetase loss and the degree of its amino-acid-mediated stabilization are a strong function of the cells' physiological development.     

Oxygen-dependent inactivation of gramicidin S synthetase in Bacillus brevis.

Incorporation of L-[14C]ornithine into gramicidin S by crude, unfractionated lysozyme extracts of Bacillus brevis ATCC 9999 was shown to represent the activity of the gramicidin synthetase complex. Frozen-thawed cells were the source of active extracts, but when cells were shaken in air at 37 degrees C, they rapidly lost activity in a first-order reaction with a half-life of 13 min. Protease inhibitors and inhibitors of energy metabolism had no effect on the inactivation process in frozen-thawed cells. Stabilization was achieved when the cells were shaken in nitrogen or helium instead of air. The addition of dithiothreitol produced a moderate degree of stabilization. The L-ornithine- and D-phenylalanine-activating activities of the gramicidin S synthetase complex were also lost during aeration of the cells. Crude cell-free extracts also lost activity when they were shaken in oxygen, but, in this case, inactivation was slower (half-life of 80 min). Nitrogen also stabilized these cell-free extracts.     

Cloning of the tyrocidine synthetase 1 gene from Bacillus brevis and its expression in Escherichia coli

Summary The entire structural gene for tyrocidine synthetase 1 from Bacillus brevis ATCC 8185 has been cloned and expressed in Escherichia coli. Transformed E. coli cells were screened for their ability to produce tyrocidine synthetase 1 by in situ immunoassay using antibodies against gramicidin S synthetase 2 which cross-react with tyrocidine synthetase 1. The cloned gene is within a 5.2 kb fragment of B. brevis genomic DNA and requires no external promoter for its expression in E. coli. It was also observed that cloning of the 5.2 kb insert in the opposite orientation still resulted in a high level of tyrocidine synthetase 1 expression in transformed E. coli cells. In addition, protein blotting and partial purification of the gene product by gel filtration revealed a major protein of molecular weight about 100,000 with specific d-phenylalanine dependent ATP-³²PP_i and 2deoxy ATP-³²PP_i exchange activities. These unique activities of tyrocidine synthetase 1 were not detected in protein extracts of E. coli strains carrying the vector.     

Absence of pantothenic acid in gramicidin S synthetase 2 obtained from some mutants of Bacillus brevis

The pantothenic acid content of gramicidin S synthetase 2(GS 2) was estimated microbiologically with enzymes obtained from the wild strain and gramicidin S-lacking mutant strains of Bacillus brevis. Four mutant enzymes from BI-4, C-3, E-1, and E-2 lacked pantothenic acid. Other mutant enzymes from BII-3, BI-3, BI-9, and BI-2 contained the same amount of pantothenic acid as the wild-type enzyme. Pantothenic acid-lacking GS 2 belonged to group V of mutant enzymes, which could activate all amino acids related to gramicidin S; their complementary enzyme, gramicidin S synthetase 1(GS 1), lacked racemizing activity. To ascertain whether 4'-phosphopantetheine is involved in the formation of D-phenylalanyl-L-prolyl diketopiperazine (DKP) and gramicidin S, combinations were tested of intact GS 1 from the wild strain with various mutant GS 2 either containing or lacking pantothenic acid. Only the combinations of wild-type GS 1 with mutant GS 2 containing pantothenic acid could synthesize DKP. Combinations with pantothenic acid-lacking GS 2 also failed to elongate peptide chains. Pantothenic acid-lacking GS 2 could bind the four amino acids which constitute gramicidin S as acyladenylates and thioesters, but the binding abilities were lower than those of the wild-type enzyme and other mutant enzymes containing the pantothenic group.     

Biological properties of a Bacillus brevis 101 mutant

Some features of the Bacillus brevis 101 mutant producing the antibiotic gramicidin S are described. The mutant is very close to the initial P+-variant of Bacillus brevis var. G-B by cultural, physiological and biochemical characteristics. The most typical features of Bacillus brevis 101 are high antibiotic activity (up to 2 g/l) and the specific phenotype of the colonies. The phenotypical features of Bacillus brevis 101 are dependent on the conditions of its cultivation. On minimal media rich in organics a change of the culture correlated with a lower antibiotic activity.     

The proline-activating activity of the multienzyme gramicidin S synthetase 2 can be recovered on a 115-kDa tryptic fragment

The multienzyme gramicidin S synthetase 2 was treated with trypsin to obtain fragments capable of activating proline. Three different active fragments were detected. The course of proteolysis was simulated by using a concentration range of trypsin; the cleavage pattern indicated that one of the fragments was particularly stable. This fragment was purified and shown to have a molecular mass of 115 kDa. It was compared chromatographically, by SDS/PAGE, and enzymatically to a Pro-activating fragment produced by a gramicidin-S-negative mutant. It can be concluded that the proteolytic fragment represents a structure which is contained on a continuous part of the polypeptide chain of gramicidin S synthetase 2 and has a relatively compact structure. This provides evidence that the multienzyme gramicidin S synthetase 2 is, at least in part, constructed from functional domains. An approach towards extending these studies to other parts of the gramicidin S synthetase 2 molecule has also been devised. This work complements recombinant DNA studies in the area, providing stable functional fragments.     

Cloning of a gene responsible for the biosynthesis of glutathione in Escherichia coli B

A gene (gshI) responsible for gamma-glutamylcysteine synthetase (GSH-I) activity was cloned to construct an Escherichia coli B strain having high glutathione synthesizing activity. For this purpose, two E. coli B mutants (strains C912 and RC912) were used. C912 was deficient in GSH-I activity. RC912, a revertant of C912, had a GSH-I activity that was desensitized to feedback inhibition of reduced glutathione. To clone gshI, chromosomal DNAs of RC912 and plasmid vector pBR322 were digested with various restriction endonucleases and then ligated with T4 DNA ligase. The whole ligation mixture was used to transform C912, and the transformants were selected as tetramethylthiuramdisulfide-resistant colonies. Of about 20 resistant colonies, 2 or 3 became red when treated with nitroprusside and showed appreciably high GSH-I activities. The chimeric plasmid DNA, designated pBR322-gshI, was isolated from the strain having the highest GSH-I activity and transformed into RC912. The structure and molecular size of pBR322-gshI in RC912 were determined. The molecular size of this plasmid was 6.2 megadaltons, and the plasmid contained a 3.4-megadalton segment derived from RC912 chromosomal DNA, which included gshI gene. The GSH-I activity of RC912 cells containing pBR322-gshI was fourfold higher than that of RC912 cells without pBR322-gshI.     

Cloning of a gene responsible for the biosynthesis of glutathione in Escherichia coli B.

A gene (gshI) responsible for gamma-glutamylcysteine synthetase (GSH-I) activity was cloned to construct an Escherichia coli B strain having high glutathione synthesizing activity. For this purpose, two E. coli B mutants (strains C912 and RC912) were used. C912 was deficient in GSH-I activity. RC912, a revertant of C912, had a GSH-I activity that was desensitized to feedback inhibition of reduced glutathione. To clone gshI, chromosomal DNAs of RC912 and plasmid vector pBR322 were digested with various restriction endonucleases and then ligated with T4 DNA ligase. The whole ligation mixture was used to transform C912, and the transformants were selected as tetramethylthiuramdisulfide-resistant colonies. Of about 20 resistant colonies, 2 or 3 became red when treated with nitroprusside and showed appreciably high GSH-I activities. The chimeric plasmid DNA, designated pBR322-gshI, was isolated from the strain having the highest GSH-I activity and transformed into RC912. The structure and molecular size of pBR322-gshI in RC912 were determined. The molecular size of this plasmid was 6.2 megadaltons, and the plasmid contained a 3.4-megadalton segment derived from RC912 chromosomal DNA, which included gshI gene. The GSH-I activity of RC912 cells containing pBR322-gshI was fourfold higher than that of RC912 cells without pBR322-gshI.     

Heavy metal cation-induced increase in the antimicrobial activity of gramicidin S. Increased sensitivity of metal-resistant mutants of Escherichia coli B to the antibiotic]

Gramicidin S response of metal resistant mutants of E. coli B and the effect of concentrations of Cu2+, Ag+, Co2+ and Cd2+ on the growth and sensitivity of E. coli B to cationic antibiotics, i.e. gramicidin S2+ and streptomycin2+, were studied. It was shown that the metal-cumulating mutants of E. coli B with two different mechanisms of cross resistance to Cu2+, Cd2+ and Ag+ had higher sensitivity to gramicidin S than the initial wild type strain of E. coli B. It was found that in the threshold or higher doses the salts of Cu, Ag, Co and Cd increased the gramicidin S antimicrobial action on actively metabolizing cells of E. coli B. Analysis of the experimental data as well as the literature ones suggested that the synergic action of gramicidin S and the heavy metals stemmed from an increase in the cationic conductivity of the cytoplasma membrane modified by the metals in the threshold doses which induced an increase in the transport and accumulation of the cations in the bacterial cells by the electric field gradient (with the negative sign inside). Withdrawal of Ca2+ and Mg2+ from the E. coli outer structures into the cytoplasm impaired the barrier properties of the outer membrane and promoted binding of the gramicidin S cations to the liberated anionic groups of the E. coli outer structures and potentiation of the gramicidin S antimicrobial activity as was shown in our experiments.     

Reaction mechanism of gramicidin S synthetase 1, phenylalanine racemase, of Bacillus brevis

We have demonstrated that gramicidin S synthetase 1 (GS 1), phenylalanine racemase [EC 5.1.1.11], of Bacillus brevis catalyzes the exchange between a proton in the medium and alpha-hydrogen of phenylalanine in the course of the racemase reaction by using tritiated water or L-phenyl[2,3-3H]alanine. GS 1 from some gramicidin S non-producing mutants of B. brevis lacking phenylalanine racemase activity did not catalyze the tritium exchange reaction. The proton exchange between phenylalanine bound as thioester on the GS 1-phenylalanine complex and water in the medium was detected, but 5,5'-dithiobis(2-nitrobenzoic acid)-modified complex lacked both the proton exchange and phenylalanine racemase activity. It is suggested that a base group, probably a sulfhydryl group, on the enzyme functions as proton donor and acceptor during the phenylalanine racemase reaction.     

Mode of antagonism of Brevibacillus brevis against Botrytis cinerea in vitro

AIMS: To assess the activity of Brevibacillus brevis (formerly Bacillus brevis) Nagano and the antibiotic it produces, gramicidin S, against the plant pathogen Botrytis cinerea. METHODS AND RESULTS: Germination and growth of Bot. cinerea were assessed in the presence of B. brevis or gramicidin S in liquid media, on solid media and on leaf sections of Chinese cabbage. Germination was 10-fold more sensitive to gramicidin S than growth. Inhibition of Bot. cinerea was greater in liquid media compared with on solid media. Activity of gramicidin S against Bot. cinerea on leaf sections was much lower than in vitro. In vitro inhibition of Bot. cinerea by B. brevis Nagano was similar to equivalent levels of gramicidin. CONCLUSIONS: Antibiosis, via gramicidin S, is the mode of antagonism exhibited by B. brevis Nagano against Bot. cinerea in vitro. SIGNIFICANCE AND IMPACT OF THE STUDY: The mode of antagonism of B. brevis against Bot. cinerea was elucidated. The differing activity of gramicidin S against Bot. Cinerea in vitro and on leaf sections indicates one mechanism by which biocontrol activity may differ between laboratory and field conditions.     

Cloning of the phospho-β-galactosidase gene in Escherichia coli from lactose-negative mutants of Streptococcus mutans isolated following random mutagenesis with plasmid pVA891 clone banks

Abstract In order to mutagenize Streptococcus mutans a marker rescue plasmid, pVA891, was employed. The plasmid was ligated with Sau 3AI digested chromosomal DNA fragments from S. mutans GS-5IS3 and the resultant plasmids were amplified in Escherichia coli . These plasmids were then randomly integrated into the chromosome of strain GS-5IS3 following transformation. Lactose-negative transformants were isolated as white colonies on lactose-BTR-Xgal agar plates containing erythromycin. Six lactose-negative mutants representing three different chromosomal sites of integration were isolated from about eight thousand transformants. Mutant chromosomal DNA fragments flanking the plasmids were recovered by a marker-rescue method in E. coli and exhibited phospho-β-galactosidase activity.     

A comparative study of essential arginine residues in Gramicidin S synthetase 2 and isoleucyl tRNA synthetase

In gramicidin S synthetase 2 (GS 2) from Bacillus brevis, L-proline, L-valine, L-ornithine, and L-leucine activations to aminoacyl adenylates are progressively inhibited by phenylglyoxal. The inactivation of GS 2 obeys pseudo-first-order kinetics. ATP completely prevents inactivation of GS 2 by phenylglyoxal, whereas amino acids only partially prevent it. In the presence of ATP, four arginine residues per mol of GS 2 are protected from modification by phenylglyoxal as determined by amino acid analysis and the incorporation of [7-14C]phenylgloxal into the enzyme protein, indicating that a single arginine residue is necessary for each amino acid activation. In isoleucyl tRNA synthetase from Escherichia coli, phenylglyoxal inhibits activation of L-isoleucine to isoleucyl adenylate. ATP completely prevents inactivation, although isoleucine only partially prevents it. One arginine residue of isoleucyl tRNA synthetase is protected by ATP from modification by phenylglyoxal, suggesting that a single arginine residue is essential for isoleucine activation. These results support the involvement of arginine residues in ATP binding with GS 2 or isoleucyl tRNA synthetase, and thus indicate that arginine residues of amino acid activating enzymes are essential for the formation of aminoacyl adenylates in both nonribosomal and ribosomal peptide biosynthesis.     

Studies on gramicidin S synthetase. Purification and properties of the light enzyme obtained from some mutants of Bacillus brevis.

The phenylalanine-activating and/or-racemizing enzyme, i.e., the light enzyme, of gramicidin S synthetase was purified to a homogenous state by D-phenylalanine-Sepharose 4B chromatography from a wild and some gramicidin S-lacking mutant strains of Bacillus brevis. The light enzyme obtained from a mutant strain E-1 could activate phenylalanine but not racemize it, and had no phenylalanine-dependent ATP-[14C]AMP exchange activity, whereas the same enzyme obtained from other mutants and the wild strain had all three activities. Furthermore, the light enzyme of the mutant E-1 could form only acid-labile enzyme-bound phenylalanine, while the same fraction of the wild strain carried half of the enzyme-bound phenylalanine as acid-labile adenylate and half as a acid-stable thioester. These results suggest that the thiol site of the light enzyme of mutant E-1 might be damaged.