Transformation of 2,4,6-trinitrotoluene by purified xenobiotic reductase B from Pseudomonas fluorescens I-C.

The enzymatic transformation of 2,4,6-trinitrotoluene (TNT) by purified XenB, an NADPH-dependent flavoprotein oxidoreductase from Pseudomonas fluorescens I-C, was evaluated by using natural abundance and [U-(14)C]TNT preparations. XenB catalyzed the reduction of TNT either by hydride addition to the aromatic ring or by nitro group reduction, with the accumulation of various tautomers of the protonated dihydride-Meisenheimer complex of TNT, 2-hydroxylamino-4,6-dinitrotoluene, and 4-hydroxylamino-2, 6-dinitrotoluene. Subsequent reactions of these metabolites were nonenzymatic and resulted in predominant formation of at least three dimers with an anionic m/z of 376 as determined by negative-mode electrospray ionization mass spectrometry and the release of approximately 0.5 mol of nitrite per mol of TNT consumed. The extents of the initial enzymatic reactions were similar in the presence and in the absence of O(2), but the dimerization reaction and the release of nitrite were favored under aerobic conditions or under anaerobic conditions in the presence of NADP(+). Reactions of chemically and enzymatically synthesized and high-pressure liquid chromatography-purified TNT metabolites showed that both a hydroxylamino-dinitrotoluene isomer and a tautomer of the protonated dihydride-Meisenheimer complex of TNT were required precursors for the dimerization and nitrite release reactions. The m/z 376 dimers also reacted with either dansyl chloride or N-1-naphthylethylenediamine HCl, providing evidence for an aryl amine functional group. In combination, the experimental results are consistent with assigning the chemical structures of the m/z 376 species to various isomers of amino-dimethyl-tetranitrobiphenyl. A mechanism for the formation of these proposed TNT metabolites is presented, and the potential enzymatic and environmental significance of their formation is discussed.

Cloning and sequence analysis of two Pseudomonas flavoprotein xenobiotic reductases.

The genes encoding flavin mononucleotide-containing oxidoreductases, designated xenobiotic reductases, from Pseudomonas putida II-B and P. fluorescens I-C that removed nitrite from nitroglycerin (NG) by cleavage of the nitroester bond were cloned, sequenced, and characterized. The P. putida gene, xenA, encodes a 39,702-Da monomeric, NAD(P)H-dependent flavoprotein that removes either the terminal or central nitro groups from NG and that reduces 2-cyclohexen-1-one but did not readily reduce 2,4,6-trinitrotoluene (TNT). The P. fluorescens gene, xenB, encodes a 37,441-Da monomeric, NAD(P)H-dependent flavoprotein that exhibits fivefold regioselectivity for removal of the central nitro group from NG and that transforms TNT but did not readily react with 2-cyclohexen-1-one. Heterologous expression of xenA and xenB was demonstrated in Escherichia coli DH5alpha. The transcription initiation sites of both xenA and xenB were identified by primer extension analysis. BLAST analyses conducted with the P. putida xenA and the P. fluorescens xenB sequences demonstrated that these genes are similar to several other bacterial genes that encode broad-specificity flavoprotein reductases. The prokaryotic flavoprotein reductases described herein likely shared a common ancestor with old yellow enzyme of yeast, a broad-specificity enzyme which may serve a detoxification role in antioxidant defense systems.

Transcriptional activation of the Bacillus subtilis ackA gene requires sequences upstream of the promoter.

Transcriptional activation of the Bacillus subtilis ackA gene, encoding acetate kinase, was previously shown to require catabolite control protein A (CcpA) and sequences upstream of the ackA promoter. CcpA, which is responsible for catabolite repression of a number of secondary carbon source utilization genes in B. subtilis and other gram-positive bacteria, recognizes a cis-acting consensus sequence, designated cre (catabolite response element), generally located within or downstream of the promoter of the repressed gene. Two sites resembling this sequence are centered at positions -116.5 and -56.5 of the ackA promoter and have been termed cre1 and cre2, respectively. Synthesis of acetate kinase, which is involved in the conversion of acetyl coenzyme A to acetate, is induced when cells are grown in the presence of an easily metabolized carbon source such as glucose. In this study, cre2, the site closer to the promoter, and the region upstream of cre2 were shown to be indispensable for CcpA-dependent transcriptional activation of ackA, whereas cre1 was not required. In addition, insertion of 5 bp between cre2 and the promoter disrupted activation, while 10 bp was tolerated, suggesting face-of-the-helix dependence of the position of cre2 and/or upstream sequences. DNase footprinting experiments demonstrated binding of CcpA in vitro to cre2 but not cre1, consistent with the genetic data. Activation of ackA transcription was blocked in a ptsH1/crh double mutant, suggesting involvement of this pathway in CcpA-mediated transcriptional activation.

NADP, corepressor for the Bacillus catabolite control protein CcpA.

Expression of the alpha-amylase gene (amyE) of Bacillus subtilis is subject to CcpA (catabolite control protein A)-mediated catabolite repression, a global regulatory mechanism in Bacillus and other Gram-positive bacteria. To determine effectors of CcpA, we tested the ability of glycolytic metabolites, nucleotides, and cofactors to affect CcpA binding to the amyE operator, amyO. Those that stimulated the DNA-binding affinity of CcpA were tested for their effect on transcription. HPr-P (Ser-46), proposed as an effector of CcpA, also was tested. In DNase I footprint assays, the affinity of CcpA for amyO was stimulated 2-fold by fructose-1,6-diphosphate (FDP), 1.5-fold by oxidized or reduced forms of NADP, and 10-fold by HPr-P (Ser-46). However, the triple combinations, CcpA/NADP/HPr-P (Ser-46) and CcpA/FDP/HPr-P (Ser-46) synergistically stimulated DNA-binding affinity by 120- and 300-fold, respectively. NADP added to CcpA specifically stimulated transcription inhibition of the amyE promoter by 120-fold. CcpA combined with HPr (Ser-46) inhibited transcription from the amyE promoter, but it also inhibited several control promoters. FDP did not stimulate transcription inhibition by CcpA nor did the triple combinations. The finding that NADP had little effect on CcpA DNA binding but increased the ability of CcpA to inhibit transcription suggests that catabolite repression is not simply caused by CcpA binding amyO but rather a result of interactions with the transcription machinery enhanced by NADP.

The -16 region of Bacillus subtilis and other gram-positive bacterial promoters.

The Bacillus subtilis alpha-amylase promoter amy P contains an essential TGTG motif (-16 region) upstream of the -10 region. Mutations of this region significantly reduced in vitro promoter strength. A -15 G-->C transversion eliminated transcription from amy P by both B.subtilis and Escherichia coli RNA polymerase (RNAP). A second alpha-amylase promoter ( amy P2) also required the -16 region for function. To determine conserved sequences in promoters containing -16 region elements, sequences of 64 B.subtilis promoters with the second TG motif of the -16 region were aligned and analyzed. Unlike the E.coli class of 'extended -10 promoters', with a similar TG motif but lacking a -35 region, the -16 region promoters contain highly conserved -35 regions. They also contain conserved A n and T n tracts upstream of the -35 region. In addition, we analyzed all available gram-positive bacterial promoter compilations to determine the generality of the -16 region. From this analysis, the -16 region TRTG motif (R = purine) appears to be a basic element found in a large portion of gram-positive bacterial promoters and is, in the case of at least the alpha-amylase promoters, necessary for transcription by the major form of B.subtilis and E.coli RNAP.

Regioselectivity of nitroglycerin denitration by flavoprotein nitroester reductases purified from two Pseudomonas species.

Two species of Pseudomonas capable of utilizing nitroglycerin (NG) as a sole nitrogen source were isolated from NG-contaminated soil and identified as Pseudomonas putida II-B and P. fluorescens I-C. While 9 of 13 laboratory bacterial strains that presumably had no previous exposure to NG could degrade low concentrations of NG (0.44 mM), the natural isolates tolerated concentrations of NG that were toxic to the lab strains (1.76 mM and higher). Whole-cell studies revealed that the two natural isolates produced different mixtures of the isomers of dinitroglycerol (DNG) and mononitroglycerol (MNG). A monomeric, flavin mononucleotide-containing NG reductase was purified from each natural isolate. These enzymes catalyzed the NADPH-dependent denitration of NG, yielding nitrite. Apparent kinetic constants were determined for both reductases. The P. putida enzyme had a Km for NG of 52 +/- 4 microM, a Km for NADPH of 28 +/- 2 microM, and a Vmax of 124 +/- 6 microM x min(-1), while the P. fluorescens enzyme had a Km for NG of 110 +/- 10 microM, a Km for NADPH of 5 +/- 1 microM, and a Vmax of 110 +/- 11 microM x min(-1). Anaerobic titration experiments confirmed the stoichiometry of NADPH consumption, changes in flavin oxidation state, and multiple steps of nitrite removal from NG. The products formed during time-dependent denitration reactions were consistent with a single enzyme being responsible for the in vivo product distributions. Simulation of the product formation kinetics by numerical integration showed that the P. putida enzyme produced an approximately 2-fold molar excess of 1,2-DNG relative to 1,3-DNG. This result could be fortuitous or could possibly be consistent with a random removal of the first nitro group from either the terminal (C-1 and C-3) positions or middle (C-2) position. However, during the denitration of 1,2-DNG, a 1.3-fold selectivity for the C-1 nitro group was determined. Comparable simulations of the product distributions from the P. fluorescens enzyme showed that NG was denitrated with a 4.6-fold selectivity for the C-2 position. Furthermore, a 2.4-fold selectivity for removal of the nitro group from the C-2 position of 1,2-DNG was also determined. The MNG isomers were not effectively denitrated by either purified enzyme, which suggests a reason why NG could not be used as a sole carbon source by the isolated organisms.

Contacts between Bacillus subtilis catabolite regulatory protein CcpA and amyO target site.

Catabolite control protein A (CcpA) is a global regulatory protein involved in catabolite repression and glucose activation in Gram-positive bacteria. cis -Acting DNA sequences, catabolite response elements ( cre s), involved in this regulatory system contain a 14 base pair (bp) region of dyad symmetry. CcpA, a repressor of the Lac I family, has been shown to bind specifically to cre s. To better understand cre recognition by CcpA, we have focused on the interaction between CcpA and the amyE cre , called amyO, which is located at the transcription start site of the alpha-amylase gene. DNA-protein complexes were probed with dimethylsulfate (DMS) and N -ethylnitrosourea (EtNU) to identify guanines and phosphates that participate in complex formation. Interaction between amyO and CcpA visualized through methylation protection and interference showed that CcpA contacts guanine residues at the outer bounds of amyO with higher affinity than near the dyad axis. From ethylation interference studies, it was found that CcpA contacts three phosphate groups at each end of amyO, and one or two phosphate groups near the dyad axis. Exonuclease III protection revealed that CcpA protects a 26 bp region centered around the dyad axis of amyO. The isolated N-terminal fragment still specifically bound to the sequence resembling the half sites of the amyO sequence. Considering these findings and the helical structure of B-DNA, our results suggest that each of the two monomers of the CcpA molecule contact the major groove in each half of the region of dyad symmetry and that the contacts are on the same face of the DNA helix, which is typical of bacterial repressor-operator interactions. However, the absence of strong contacts near the dyad axis by CcpA is in contrast to the situation with the gal repressor, another member of the Lac I family of repressors.

Significance of HPr in catabolite repression of alpha-amylase.

CcpA and HPr are presently the only two proteins implicated in Bacillus subtilis global carbon source catabolite repression, and the ptsH1 mutation in the gene for the HPr protein was reported to relieve catabolite repression of several genes. However, alpha-amylase synthesis by B. subtilis SA003 containing the ptsH1 mutation was repressed by glucose. Our results suggest HPr(Ser-P) may be involved in but is not required for catabolite repression of alpha-amylase, indicating that HPr(Ser-P) is not the sole signaling molecule for CcpA-mediated catabolite repression in B. subtilis.

Specificity of DNA binding activity of the Bacillus subtilis catabolite control protein CcpA.

CcpA was purified from Escherichia coli BL21 (lambda DE3)/pLysS carrying plasmid pTSC5, which was constructed by inserting the ccpA gene into the polycloning site of pGEM4. The purified protein migrated in sodium dodecyl sulfate-polyacrylamide gel electrophoresis with an apparent mass of 38 kDa but was eluted from a calibrated Bio-Gel P-100 column with an apparent mass of 75 kDa. Western blot (immunoblot) analysis revealed the presence of CcpA in E. coli BL21 (lambda DE3)/pLysS/pTSC5, which carries ccpA, and in wild-type Bacillus subtilis 168 but not in E. coli BL21 (lambda DE3)/pLysS/pGEM4 or in B. subtilis WLN-29, in which ccpA is inactivated by transposon Tn917 insertion. Purified CcpA bound to DNA containing amyO and retarded its mobility in electrophoretic mobility shift analysis. Complete retardation of the DNA required 75 ng of CcpA per assay. In DNase protection analysis, CcpA bound to DNA containing amyO and protected a region spanning amyO when either DNA strand was labeled. Mutant forms of amyO not effective in catabolite repression were not retarded by CcpA.

The -16 region, a vital sequence for the utilization of a promoter in Bacillus subtilis and Escherichia coli.

The promoter (amyP) of the Bacillus subtilis alpha-amylase gene, which is recognized by E sigma A, has a three out of six match to the consensus promoter in both the -35 and -10 hexamers. Oligonucleotide-directed mutagenesis was used to identify important bases for promoter utilization in the spacer sequence between the hexamers. Mutations in the sequence TGTG extending from positions -18 to -15 (the -16 region) caused a 5-94-fold decrease in alpha-amylase production. A G-C transversion at position -15 was the most detrimental mutation: it essentially eliminated amyP utilization in B. subtilis and in Escherichia coli. Mutating the -35 and -10 hexamers to the E sigma A consensus promoter increased alpha-amylase production 56-fold in B. subtilis and fivefold in E. coli. Introducing the -15 G to C transversion into the consensus promoter reduced alpha-amylase production threefold, in contrast to the 94-fold reduction for the wild-type promoter in B. subtilis. The -15 G to C transversion did not reduce alpha-amylase synthesis directed by the consensus promoter in E. coli. The alpha-amylase gene is subject to two forms of transcriptional regulation: catabolite repression and temporal regulation. None of the mutants constructed in this study had any effect on either type of regulation. The -16 region, especially the G at position -15, appears to be moderately conserved in B. subtilis and in other Gram-positive organisms and weakly conserved in E. coli. The evidence suggests that the -16 region is an additional region of E sigma A promoters in B. subtilis and E sigma 70 promoters in E. coli, essential in some weak promoters such as the alpha-amylase promoter but, of little benefit to very strong promoters.

Characterization of a new sporulation factor in Bacillus subtilis.

We report the existence and partial purification of sporulation factor, which stimulates sporulation of Bacillus subtilis at low cell density. Proline or arginine is required for stimulation under the conditions of our assay. Sporulation factor is a small heat-stable substance produced by the cells during exponential growth phase. It is required in small amounts and is resistant to various proteolytic agents. Several spo mutants were tested for the ability to produce functional sporulation factor. All of these mutants produce factor and do not sporulate in the presence of factor from wild-type cells. Sporulation factor is not involved in the induction of alpha-amylase synthesis at the initiation of sporulation.

Rapid isolation and sequencing of purified plasmid DNA from Bacillus subtilis.

We report two methods for isolation of plasmid DNA from the gram-positive bacterium Bacillus subtilis. The protoplast alkaline lysis procedure was developed for general use, and the protoplast alkaline lysis magic procedure was developed for isolation of DNA for sequencing. Both procedures yielded large amounts of high-quality DNA in less than 1 h, while current protocols require 4 to 7 h to perform and give lower yields and quality. Plasmid DNA was obtained from strains containing either high- or low-copy-number plasmids. In addition, the procedures were easily adapted to yield large amounts of plasmid DNA suitable for sequencing from another gram-positive organism, Staphylococcus aureus. Further, we demonstrated that neither chloramphenicol, used for plasmid selection, nor the mutation recE4 reduced plasmid DNA yield from the strains we examined.

Catabolite repression of alpha-amylase gene expression in Bacillus subtilis involves a trans-acting gene product homologous to the Escherichia coli lacl and galR repressors.

Expression of the alpha-amylase gene of Bacillus subtilis is controlled at the transcriptional level, and responds to the growth state of the cell as well as the availability of rapidly metabolizable carbon sources. Glucose-mediated repression has previously been shown to involve a site near the transcriptional start-point of the amyE gene. In this study, a transposon insertion mutation was characterized which resulted in loss of glucose repression of amyE gene expression. The gene affected by this mutation, which was localized near 263 degrees on the B. subtilis chromosomal map, was isolated and its DNA sequence was determined. This gene, designated ccpA, exhibited striking homology to repressor genes of the lac and gal repressor family. The ccpA gene was found to be allelic to alsA, previously identified as a regulator of acetoin biosynthesis, and may be involved in catabolite regulation of other systems as well.

Bacillus subtilis mutants with alterations in ribosomal protein S4.

Two mutants with different alterations in the electrophoretic mobility of ribosomal protein S4 were isolated as spore-plus revertants of a streptomycin-resistant, spore-minus strain of Bacillus subtilis. The mutations causing the S4 alterations, designated rpsD1 and rpsD2, were located between the argGH and aroG genes, at 263 degrees on the B. subtilis chromosome, distant from the major ribosomal protein gene cluster at 12 degrees. The mutant rpsD alleles were isolated by hybridization using a wild-type rpsD probe, and their DNA sequences were determined. The two mutants contained alterations at the same position within the S4-coding sequence, in a region containing a 12-bp tandem duplication; the rpsD1 allele corresponded to an additional copy of this repeated segment, resulting in the insertion of four amino acids, whereas the rpsD2 allele corresponded to deletion of one copy of this segment, resulting in the loss of four amino acids. The effects of these mutations, alone and in combination with streptomycin resistance mutations, on growth, sporulation, and streptomycin resistance were analyzed.

Site-directed mutagenesis of a catabolite repression operator sequence in Bacillus subtilis.

Catabolite repression of the Bacillus subtilis alpha-amylase gene (amyE) involves an operator sequence located just downstream of the promoter (amyR), overlapping the transcription start site. Oligonucleotide site-directed mutagenesis of this sequence identified bases required for catabolite repression. Two mutations increased both the 2-fold symmetry of the operator and the repression ratio. Although many mutations reduced the repression ratio 3- to 11-fold, some also caused a 2-fold or greater increase in amylase production. Others caused hyperproduction without affecting catabolite repression. Homologous sequences in other catabolite-repressed B. subtilis promoters suggest a common regulatory site may be involved in catabolite repression.

Genetic analysis of the promoter region of the Bacillus subtilis alpha-amylase gene.

The amyR2 allele of the Bacillus subtilis alpha-amylase cis-regulatory region enhances production of amylase and transcription of amyE, the structural gene, by two- to threefold over amyR1. The amylase gene bearing each of these alleles was cloned on plasmids of about 10 to 15 copies per chromosome. Transcription of the cloned amylase gene by each amyR allele was activated at the end of exponential growth and was subject to catabolite repression by glucose. The amount of amylase produced was roughly proportional to the copy number of the plasmid, and cells containing the amyR2-bearing plasmid, pAR2, produced two- to threefold more amylase than cells with the amyR1 plasmid, pAMY10. Deletion of DNA 5' to the alpha-amylase promoter, including deletion of the A + T-rich inverted repeat found in amyR1 and amyR2, had no effect on expression or transcription of alpha-amylase. Deletion of DNA 3' to the amyR1 promoter did not impair temporal activation of chloramphenicol acetyltransferase in amyR1-cat-86 transcriptional fusions, but catabolite repression was abolished. When an 8-base-pair linker was inserted in pAMY10 at the same site from which the 3' deletion was made, amylase expression doubled and was repressed less by glucose. Both the deletion and the insertion disrupted four bases at the 3' end of the putative amylase operator region. Site-directed mutagenesis was used to change bases in the promoter-operator region of amyR1 to their amyR2 counterparts. Either change alone increased amylase production twofold, but only the change at +7, next to the linker insertion of 3' deletion site, yielded the increased amylase activity in the presence of glucose that is characteristic of the amyR2 strain. The double mutant behaved most like strains carrying the amyR2 allele.

Bacillus licheniformis alpha-amylase gene, amyL, is subject to promoter-independent catabolite repression in Bacillus subtilis.

Expression of the Bacillus licheniformis alpha-amylase gene, amyL, was temporally activated and subject to catabolite repression both in its natural host and when cloned on a 3.55-kilobase fragment in Bacillus subtilis. A subclone from which the promoter region of amyL and sequences upstream from the promoter were deleted had a low level of amylase activity. Expression of the promoterless gene was still subject to repression by glucose when the gene was present either on a multicopy plasmid or integrated into the B. subtilis chromosome. Catabolite repression occurred independently of the amylase promoter and irrespective of the distance of the promoterless amyL gene from the promoter which transcribed it. The transcriptional start sites of amyL activated by its own promoter and by a vector sequence promoter were determined by S1 mapping. alpha-Amylase-specific mRNA levels were measured in repressing and nonrepressing media, and catabolite repression was found to act at the level of transcription.

Catabolite repression-resistant mutations of the Bacillus subtilis alpha-amylase promoter affect transcription levels and are in an operator-like sequence.

The amyR1 locus controls the regulated transcription of amyE, the structural gene encoding alpha-amylase in Bacillus subtilis. Transcription of amyE is activated in early stationary phase cells, and can be repressed by rapidly metabolized carbon sources such as glucose. Transcription of amyE initiates in vitro from a promoter recognized by the major vegetative form of RNA polymerase, E sigma 43. S1 nuclease mapping of in-vivo amylase transcripts suggests that this promoter is also used in vivo. Two independently isolated cis-acting mutations, gra-5 and gra-10, which abolish glucose-mediated repression of amylase synthesis without altering temporal activation, were determined by DNA sequencing to result from a G.C to A.T transition at a position located five base-pairs downstream from the start site of transcription. While this is the first example of a site involved in catabolite repression of gene expression in a Gram-positive micro-organism, the region surrounding the gra mutations shows considerable homology to certain cis-acting regulatory loci in Escherichia coli, suggesting that such sequences have been evolutionarily conserved.

Effect of decoyinine on the regulation of alpha-amylase synthesis in Bacillus subtilis.

Decoyinine, an inhibitor of GMP synthetase, allows sporulation in Bacillus subtilis to initiate and proceed under otherwise catabolite-repressing conditions. The effect of decoyinine on alpha-amylase synthesis in B. subtilis, an event which exhibits regulatory features resembling sporulation initiation, was examined. Decoyinine did not overcome catabolite repression of alpha-amylase synthesis in a wild-type strain of B. subtilis but did cause premature and enhanced synthesis in a mutant strain specifically blocked in catabolite repression of alpha-amylase synthesis. Decoyinine had no effect on alpha-amylase enzymatic activity. Thus, it appears that the catabolite control mechanisms governing alpha-amylase synthesis and sporulation in B. subtilis differ in their responses to decoyinine and hence must consist at least partially of separate components.

Endo-beta-1,4-glucanase gene of Bacillus subtilis DLG.

The DNA sequence of the Bacillus subtilis DLG endo-beta-1,4-glucanase gene was determined, and the in vivo site of transcription initiation was located. Immediately upstream from the transcription start site were sequences closely resembling those recognized by B. subtilis sigma 43-RNA polymerase. Two possible ribosome-binding sites were observed downstream from the transcription start site. These were followed by a long open reading frame capable of encoding a protein of ca. 55,000 daltons. A signal sequence, typical of those present in gram-positive organisms, was observed at the amino terminus of the open reading frame. Purification of the mature exocellular beta-1,4-glucanase and subsequent amino-terminal protein sequencing defined the site of signal sequence processing to be between two alanine residues following the hydrophobic portion of the signal sequence. The probability of additional carboxy-terminal processing of the beta-1,4-glucanase precursor is discussed. S1 nuclease protection studies showed that the amount of beta-1,4-glucanase mRNA in cells increased significantly as the culture entered the stationary phase. In addition, glucose was found to dramatically stimulate the amount of beta-1,4-glucanase mRNA in vivo. Finally, the specific activities of purified B. subtilis DLG endo-beta-1,4-glucanase and Trichoderma reesei QM9414 endo-beta-1,4-glucanase (EC 3.2.1.4) were compared by using the noncrystalline cellulosic substrate trinitrophenyl-carboxymethyl cellulose.