Dual Regulation of Bacillus subtilis kinB Gene Encoding a Sporulation Trigger by SinR through Transcription Repression and Positive Stringent Transcription Control.

It is known that transcription of kinB encoding a trigger for Bacillus subtilis sporulation is under repression by SinR, a master repressor of biofilm formation, and under positive stringent transcription control depending on the adenine species at the transcription initiation nucleotide (nt). Deletion and base substitution analyses of the kinB promoter (P kinB ) region using lacZ fusions indicated that either a 5-nt deletion (Δ5, nt -61/-57, +1 is the transcription initiation nt) or the substitution of G at nt -45 with A (G-45A) relieved kinB repression. Thus, we found a pair of SinR-binding consensus sequences (GTTCTYT; Y is T or C) in an inverted orientation (SinR-1) between nt -57/-42, which is most likely a SinR-binding site for kinB repression. This relief from SinR repression likely requires SinI, an antagonist of SinR. Surprisingly, we found that SinR is essential for positive stringent transcription control of P kinB . Electrophoretic mobility shift assay (EMSA) analysis indicated that SinR bound not only to SinR-1 but also to SinR-2 (nt -29/-8) consisting of another pair of SinR consensus sequences in a tandem repeat arrangement; the two sequences partially overlap the '-35' and '-10' regions of P kinB . Introduction of base substitutions (T-27C C-26T) in the upstream consensus sequence of SinR-2 affected positive stringent transcription control of P kinB , suggesting that SinR binding to SinR-2 likely causes this positive control. EMSA also implied that RNA polymerase and SinR are possibly bound together to SinR-2 to form a transcription initiation complex for kinB transcription. Thus, it was suggested in this work that derepression of kinB from SinR repression by SinI induced by Spo0A∼P and occurrence of SinR-dependent positive stringent transcription control of kinB might induce effective sporulation cooperatively, implying an intimate interplay by stringent response, sporulation, and biofilm formation.

Regulation of the rhaEWRBMA Operon Involved in l-Rhamnose Catabolism through Two Transcriptional Factors, RhaR and CcpA, in Bacillus subtilis.

UNLABELLED: The Bacillus subtilis rhaEWRBMA (formerly yuxG-yulBCDE) operon consists of four genes encoding enzymes for l-rhamnose catabolism and the rhaR gene encoding a DeoR-type transcriptional regulator. DNase I footprinting analysis showed that the RhaR protein specifically binds to the regulatory region upstream of the rhaEW gene, in which two imperfect direct repeats are included. Gel retardation analysis revealed that the direct repeat farther upstream is essential for the high-affinity binding of RhaR and that the DNA binding of RhaR was effectively inhibited by L-rhamnulose-1-phosphate, an intermediate of L-rhamnose catabolism. Moreover, it was demonstrated that the CcpA/P-Ser-HPr complex, primarily governing the carbon catabolite control in B. subtilis, binds to the catabolite-responsive element, which overlaps the RhaR binding site. In vivo analysis of the rhaEW promoter-lacZ fusion in the background of ccpA deletion showed that the L-rhamnose-responsive induction of the rhaEW promoter was negated by the disruption of rhaA or rhaB but not rhaEW or rhaM, whereas rhaR disruption resulted in constitutive rhaEW promoter activity. These in vitro and in vivo results clearly indicate that RhaR represses the operon by binding to the operator site, which is detached by L-rhamnulose-1-phosphate formed from L-rhamnose through a sequence of isomerization by RhaA and phosphorylation by RhaB, leading to the derepression of the operon. In addition, the lacZ reporter analysis using the strains with or without the ccpA deletion under the background of rhaR disruption supported the involvement of CcpA in the carbon catabolite repression of the operon. IMPORTANCE: Since L-rhamnose is a component of various plant-derived compounds, it is a potential carbon source for plant-associating bacteria. Moreover, it is suggested that L-rhamnose catabolism plays a significant role in some bacteria-plant interactions, e.g., invasion of plant pathogens and nodulation of rhizobia. Despite the physiological importance of L-rhamnose catabolism for various bacterial species, the transcriptional regulation of the relevant genes has been poorly understood, except for the regulatory system of Escherichia coli. In this study, we show that, in Bacillus subtilis, one of the plant growth-promoting rhizobacteria, the rhaEWRBMA operon for L-rhamnose catabolism is controlled by RhaR and CcpA. This regulatory system can be another standard model for better understanding the regulatory mechanisms of L-rhamnose catabolism in other bacterial species.

CcpA-mediated catabolite activation of the Bacillus subtilis ilv-leu operon and its negation by either CodY- or TnrA-mediated negative regulation.

The Bacillus subtilis ilv-leu operon functions in the biosynthesis of branched-chain amino acids. It undergoes catabolite activation involving a promoter-proximal cre which is mediated by the complex of CcpA and P-Ser-HPr. This activation of ilv-leu expression is negatively regulated through CodY binding to a high-affinity site in the promoter region under amino acid-rich growth conditions, and it is negatively regulated through TnrA binding to the TnrA box under nitrogen-limited growth conditions. The CcpA-mediated catabolite activation of ilv-leu required a helix face-dependent interaction of the complex of CcpA and P-Ser-HPr with RNA polymerase and needed a 19-nucleotide region upstream of cre for full activation. DNase I footprinting indicated that CodY binding to the high-affinity site competitively prevented the binding of the complex of CcpA and P-Ser-HPr to cre. This CodY binding not only negated catabolite activation but also likely inhibited transcription initiation from the ilv-leu promoter. The footprinting also indicated that TnrA and the complex of CcpA and P-Ser-HPr simultaneously bound to the TnrA box and the cre site, respectively, which are 112 nucleotides apart; TnrA binding to its box was likely to induce DNA bending. This implied that interaction of TnrA bound to its box with the complex of CcpA and P-Ser-HPr bound to cre might negate catabolite activation, but TnrA bound to its box did not inhibit transcription initiation from the ilv-leu promoter. Moreover, this negation of catabolite activation by TnrA required a 26-nucleotide region downstream of the TnrA box.

Structural characterization of a ligand-bound form of Bacillus subtilis FadR involved in the regulation of fatty acid degradation.

Bacillus subtilis FadR (FadR(Bs)), a member of the TetR family of bacterial transcriptional regulators, represses five fad operons including 15 genes, most of which are involved in ß-oxidation of fatty acids. FadR(Bs) binds to the five FadR(Bs) boxes in the promoter regions and the binding is specifically inhibited by long-chain (C14-C20 ) acyl-CoAs, causing derepression of the fad operons. To elucidate the structural mechanism of this regulator, we have determined the crystal structures of FadR(Bs) proteins prepared with and without stearoyl(C18)-CoA. The crystal structure without adding any ligand molecules unexpectedly includes one small molecule, probably dodecyl(C12)-CoA derived from the Escherichia coli host, in its homodimeric structure. Also, we successfully obtained the structure of the ligand-bound form of the FadR(Bs) dimer by co-crystallization, in which two stearoyl-CoA molecules are accommodated, with the binding mode being essentially equivalent to that of dodecyl-CoA. Although the acyl-chain-binding cavity of FadR(Bs) is mainly hydrophobic, a hydrophilic patch encompasses the C1-C10 carbons of the acyl chain. This accounts for the previous report that the DNA binding of FadR(Bs) is specifically inhibited by the long-chain acyl-CoAs but not by the shorter ones. Structural comparison of the ligand-bound and unliganded subunits of FadR(Bs) revealed three regions around residues 21-31, 61-76, and 106-119 that were substantially changed in response to the ligand binding, and particularly with respect to the movements of Leu108 and Arg109. Site-directed mutagenesis of these residues revealed that Arg109, but not Leu108, is a key residue for maintenance of the DNA-binding affinity of FadR(Bs).

Expression of kinA and kinB of Bacillus subtilis, necessary for sporulation initiation, is under positive stringent transcription control.

Bacillus subtilis cells were exposed to decoyinine to trigger stringent transcription control through inhibition of GMP synthase; amino acid starvation results in the same control through inhibition of GMP kinase by 5'-diphosphate 3'-diphosphate guanosine. The positive and negative transcription control of the stringent genes involves adenine and guanine at the transcription initiation sites, whereby they sense an increase and a decrease in the in vivo ATP and GTP pools, respectively. Decoyinine also induces sporulation in minimum medium. DNA microarray analysis revealed that decoyinine induced two major sensor kinase genes, kinA and kinB, involved in the phosphorelay leading to spore formation. lacZ fusion experiments involving the core promoter regions of kinA and kinB, whose transcription initiation bases are adenines, indicated that decoyinine induced their expression. This induction was independent of CodY and AbrB. When the adenines were replaced with guanines or cytosines, the induction by decoyinine decreased. The in situ replacement of the adenines with guanines actually affected this decoyinine-induced sporulation as well as massive sporulation in nutrient medium. These results imply that operation of the positive stringent transcription control of kinA and kinB, which is mediated by an increase in the ATP pool, is likely a prerequisite for the phosphorelay to transfer the phosphoryl group to Spo0A to initiate sporulation.

Direct and indirect regulation of the ycnKJI operon involved in copper uptake through two transcriptional repressors, YcnK and CsoR, in Bacillus subtilis.

Northern blot and primer extension analyses revealed that the ycnKJI operon and the ycnL gene of Bacillus subtilis are transcribed from adjacent promoters that are divergently oriented. The ycnK and ycnJ genes encode a DeoR-type transcriptional regulator and a membrane protein involved in copper uptake, respectively. DNA binding experiments showed that the YcnK protein specifically binds to the ycnK-ycnL intergenic region, including a 16-bp direct repeat that is essential for the high binding affinity of YcnK, and that a copper-specific chelator significantly inhibits YcnK's DNA binding. lacZ reporter analysis showed that the ycnK promoter is induced by copper limitation or ycnK disruption. These results are consistent with YcnK functioning as a copper-responsive repressor that derepresses ycnKJI expression under copper limitation. On the other hand, the ycnL promoter was hardly induced by copper limitation, but ycnK disruption resulted in a slight induction of the ycnL promoter, suggesting that YcnK also represses ycnL weakly. Moreover, while the CsoR protein did not bind to the ycnK-ycnL intergenic region, lacZ reporter analysis demonstrated that csoR disruption induces the ycnK promoter only in the presence of intact ycnK and copZA genes. Since the copZA operon is involved in copper export and repressed by CsoR, it appears that the constitutive copZA expression brought by csoR disruption causes intracellular copper depletion, which releases the repression of the ycnKJI operon by YcnK.

Identification of aromatic residues critical to the DNA binding and ligand response of the Bacillus subtilis QdoR (YxaF) repressor antagonized by flavonoids.

Bacillus subtilis LmrA and QdoR (formerly YxaF) are paralogous transcriptional regulators that repress their regulon comprising the lmrAB operon, the qdoR gene, and the qdoI-yxaH operon, by binding to the LmrA/QdoR boxes located in the promoter regions. Detachment of them followed by derepression of the target genes is induced by certain flavonoids. To identify the residues critical to the ligand response in QdoR, we selected eight residues based on structural information, produced eight single-mutated QdoRs in which each residue was replaced with alanine, and evaluated their capacities for DNA binding and the flavonoid response by gel retardation analysis. The three mutants, carrying the alanine substitution at Phe87, Trp131, or Phe135, showed features distinctly different from those of the wild type and from each other. We further examined the in vivo function of the mutant with alanine substitution at Trp131 by reporter assay. This largely supported the corresponding in vitro results. The in vitro and in vivo data suggest that Phe87, Trp131, and Phe135, forming a hydrophobic cluster in QdoR, play crucial roles in the DNA binding, flavonoid accommodation, and/or conformational change triggered by ligand binding.

Catabolite repression of the Bacillus subtilis FadR regulon, which is involved in fatty acid catabolism.

The Bacillus subtilis fadR regulon involved in fatty acid degradation comprises five operons, lcfA-fadR-fadB-etfB-etfA, lcfB, fadN-fadA-fadE, fadH-fadG, and fadF-acdA-rpoE. Since the lcfA-fadRB-etfBA, lcfB, and fadNAE operons, whose gene products directly participate in the ß-oxidation cycle, had been found to be probably catabolite repressed upon genome-wide transcript analysis, we performed Northern blotting, which indicated that they are clearly under CcpA-dependent catabolite repression. So, we searched for catabolite-responsive elements (cre's) to which the complex of CcpA and P-Ser-HPr binds to exert catabolite repression by means of a web-based cis-element search in the B. subtilis genome using known cre sequences, which revealed the respective candidate cre sequences in the lcfA, lcfB, and fadN genes. DNA footprinting indicated that the complex actually interacted with these cre's in vitro. Deletion analysis of each cre using the lacZ fusions with the respective promoter regions of the three operons with and without it, indicated that these cre's are involved in the CcpA-dependent catabolite repression of the operons in vivo.

Excess production of Bacillus subtilis quercetin 2,3-dioxygenase affects cell viability in the presence of quercetin.

Bacillus subtilis quercetin 2,3-dioxygenase (QdoI) catalyzes the C-ring cleavage of quercetin to yield 2-protocatechuoyl-phloroglucinol carboxylic acid and carbon monoxide. The recombinant QdoI effectively decomposed several flavonols, including quercetin, whereas its activity toward fisetin was low, suggesting that the 5-hydroxyl group at the A-ring is critical for substrate recognition. A B. subtilis mutant with derepressed QdoI activity was much more sensitive to quercetin than the wild type, but did not exhibit similar sensitivity toward the other flavonoids tested. Further analysis, including co-cultivation with the wild type and the mutant, led to the assumption that intracellular accumulation of protocatechuic acid derived from the rapid decomposition of quercetin severely affects cell viability. Although protocatechuic acid is also produced by fisetin degradation, cell death was avoided, probably due to the lower activity of QdoI toward fisetin. The sensitivity of the B. subtilis mutant toward quercetin was quenched by repression of QdoI by the use of its authentic repressors. Moreover, this adverse effect of excess QdoI with quercetin was also exerted on Escherichia coli cells. This implies the availability of the QdoI regulatory system as a novel selection marker for genetic transformation without using antibiotic-resistant ones.

Transcriptional regulation of the Bacillus subtilis asnH operon and role of the 5'-proximal long sequence triplication in RNA stabilization.

The Bacillus subtilis asnH operon, comprising yxbB, yxbA, yxnB, asnH and yxaM, is induced dramatically in the transition between exponential growth and stationary phase in rich sporulation medium. The asnH operon is transcribed to produce an unstable long transcript covering the entire operon as well as a short one corresponding to the first three genes. Northern blot analysis revealed that the discrete band corresponding to the short transcript was detectable even 1 h after the addition of excess rifampicin, suggesting its unusual stability. The transcription start site of the operon was determined; its corresponding promoter was most likely sigma-A dependent and under tight control of AbrB and CodY. Within the 5'-proximal region of the transcript preceding yxbB, there is a mysterious long sequence triplication (LST) segment, consisting of a tandem repeat of two highly conserved 118 bp units and a less conserved 129 bp unit. This LST segment was not involved in regulation by AbrB and CodY. Transcriptional fusion of the 5'-region containing the LST segment to lacZ resulted in a significant increase in beta-galactosidase synthesis in cells; the LST segment was thought to prevent degradation of the 5'-region-lacZ fusion transcript. These results suggest that the 5'-region containing the LST segment could function as an mRNA stabilizer that prolongs the lifetime of the transcript to which it is fused.

Heavy involvement of stringent transcription control depending on the adenine or guanine species of the transcription initiation site in glucose and pyruvate metabolism in Bacillus subtilis.

In Bacillus subtilis cells, the GTP level decreases and the ATP level increases upon a stringent response. This reciprocal change in the concentrations of the substrates of RNA polymerase affects the rate of transcription initiation of certain stringent genes depending on the purine species at their transcription initiation sites. DNA microarray analysis suggested that not only the rrn and ilv-leu genes encoding rRNAs and the enzymes for synthesis of branched-chain amino acids, respectively, but also many genes, including genes involved in glucose and pyruvate metabolism, might be subject to this kind of stringent transcription control. Actually, the ptsGHI and pdhABCD operons encoding the glucose-specific phosphoenolpyruvate:sugar phosphotransferase system and the pyruvate dehydrogenase complex were found to be negatively regulated, like rrn, whereas the pycA gene encoding pyruvate carboxylase and the alsSD operon for synthesis of acetoin from pyruvate were positively regulated, like ilv-leu. Replacement of the guanine at position 1 and/or position 2 of ptsGHI and at position 1 of pdhABCD (transcription initiation base at position 1) by adenine changed the negative stringent control of these operons in the positive direction. The initiation bases for transcription of pdhABCD and pycA were newly determined. Then the promoter sequences of these stringent operons were aligned, and the results suggested that the presence of a guanine(s) and the presence of an adenine(s) at position 1 and/or position 2 might be indispensable for negative and positive stringent control, respectively. Such stringent transcription control that affects the transcription initiation rate through reciprocal changes in the GTP and ATP levels likely occurs for numerous genes of B. subtilis.

Identification and characterization of a novel multidrug resistance operon, mdtRP (yusOP), of Bacillus subtilis.

Using comparative genome sequencing analysis, we identified a novel mutation in Bacillus subtilis that confers a low level of resistance to fusidic acid. This mutation was located in the mdtR (formerly yusO) gene, which encodes a MarR-type transcriptional regulator, and conferred a low level of resistance to several antibiotics, including novobiocin, streptomycin, and actinomycin D. Transformation experiments showed that this mdtR mutation was responsible for multidrug resistance. Northern blot analysis revealed that the downstream gene mdtP (formerly yusP), which encodes a multidrug efflux transporter, is cotranscribed with mdtR as an operon. Disruption of the mdtP gene completely abolished the multidrug resistance phenotype observed in the mdtR mutant. DNase I footprinting and primer extension analyses demonstrated that the MdtR protein binds directly to the mdtRP promoter, thus leading to repression of its transcription. Moreover, gel mobility shift analysis indicated that an Arg83 --> Lys or Ala67 --> Thr substitution in MdtR significantly reduces binding affinity to DNA, resulting in derepression of mdtRP transcription. Low concentrations of fusidic acid induced the expression of mdtP, although the level of mdtP expression was much lower than that in the mdtR disruptant. These findings indicate that the MdtR protein is a repressor of the mdtRP operon and that the MdtP protein functions as a multidrug efflux transporter in B. subtilis.

Regulation of the Bacillus subtilis divergent yetL and yetM genes by a transcriptional repressor, YetL, in response to flavonoids.

DNA microarray analysis revealed that transcription of the Bacillus subtilis yetM gene encoding a putative flavin adenine dinucleotide-dependent monooxygenase was triggered by certain flavonoids during culture and was derepressed by disruption of the yetL gene in the opposite orientation situated immediately upstream of yetM, which encodes a putative MarR family transcriptional regulator. In vitro analyses, including DNase I footprinting and gel retardation analysis, indicated that YetL binds specifically to corresponding single sites in the divergent yetL and yetM promoter regions, with higher affinity to the yetM region; the former region overlaps the Shine-Dalgarno sequence of yetL, and the latter region contains a perfect 18-bp palindromic sequence (TAGTTAGGCGCCTAACTA). In vitro gel retardation and in vivo lacZ fusion analyses indicated that some flavonoids (kaempferol, apigenin, and luteolin) effectively inhibit YetL binding to the yetM cis sequence, but quercetin, galangin, and chrysin do not inhibit this binding, implying that the 4-hydroxyl group on the B-ring of the flavone structure is indispensable for this inhibition and that the coexistence of the 3-hydroxyl groups on the B- and C-rings does not allow antagonism of YetL.

Carbon catabolite control of the metabolic network in Bacillus subtilis.

The histidine-containing protein (HPr) is the energy coupling protein of the phosphoenolpyruvate-dependent carbohydrate:phosphotransferase system (PTS), which catalyzes the transport of carbohydrates in bacteria. In Bacillus subtilis and close relatives, global regulation of carbon catabolite control occurs on the binding of the complex of CcpA (catabolite control protein A) and P-Ser-HPr (seryl-phosphorylated form of HPr) to the catabolite responsive elements (cre) of the target operons, the constituent genes of which are roughly estimated to number 300. The complex of CcpA and P-Ser-HPr triggers the expression of several genes involved in the formation of acetate and acetoin, major extracellular products of B. subtilis grown on glucose. It also triggers the expression of an anabolic operon (ilv-leu) involved in the biosynthesis of branched-chain amino acids, which subsequently leads to cell propagation. On the other hand, this complex represses many genes and operons, which include an entrance gene for the TCA cycle (citZ), several transporter genes for TCA cycle-intermediates, some respiration genes, and many catabolic and anabolic genes involved in carbon, nitrogen, and phosphate metabolism, as well as for certain extracellular enzymes and secondary metabolites. Furthermore, these bacteria have CcpA-independent catabolite regulation systems, each of which involves a transcriptional repressor of CggR or CcpN. CggR and CcpN are derepressed under glycolytic and gluconeogenic growth conditions, and enhance glycolysis and gluconeogenesis respectively. Another CcpA-independent catabolite repression system involves P-His-HPr (histidyl-phosphorylated form of HPr). P-His-HPr phosphorylates and activates glycerol kinase, whose product is necessary for antitermination of the glycerol utilization operon through GlpP, the antiterminators (LicT and SacT, Y) of several operons for the utilization of less-preferred PTS-sugars, and some transcriptional activators such as LevR for the levan utilization operon. This phosphorylation is reduced due to the decreased level of P-His-HPr during active transport of a preferred PTS-carbohydrate such as glucose, resulting in catabolite repression of the target operons.Thus CcpA-dependent and independent networks for carbon metabolism play a major role in the coordinate regulation of catabolism and anabolism to ensure optimum cell propagation in the presence and the absence of a preferred PTS-carbohydrate.

Trans-translation is involved in the CcpA-dependent tagging and degradation of TreP in Bacillus subtilis.

TreP [trehalose-permease (phosphotransferase system (PTS) trehalose-specific enzyme IIBC component)] is one of the target proteins of tmRNA-mediated trans-translation in Bacillus subtilis [Fujihara et al. (2002) Detection of tmRNA-mediated trans-translation products in Bacillus subtilis. Genes Cells, 7, 343-350]. The TreP synthesis is subject to CcpA-dependent carbon catabolite repression (CCR), and the treP gene contains catabolite-responsive element (cre) sequence, a binding site of repressor protein CcpA, in the coding region. Here, we demonstrated that the tmRNA-tagging of TreP occurs depending on the gene for CcpA. In the presence of CcpA, the transcription of treP mRNA terminates at 8-9 nucleotides upstream of the 5'-edge of the internal cre sequence, and translational switch to the tag-sequence occurs at the 101st amino-acid (asparagine) position from N-terminus of TreP. The results show that trans-translation reaction is involved in the tagging and degradation of the N-terminal TreP fragment produced by truncated mRNA, which is a product of transcriptional roadblock by CcpA binding to the cre sequence in the internal coding region.

Novel gene regulation mediated by overproduction of secondary metabolite neotrehalosadiamine in Bacillus subtilis.

Bacillus subtilis GlcP regulates a secondary metabolism, the neotrehalosadiamine synthesis pathway, by repressing a neotrehalosadiamine biosynthesis operon in response to glucose present in the medium. Here, we investigated, by use of transcriptome, additional effects of glcP disruption on other gene expression. In the GlcP-null mutant, the expression of alsSD and maeN was decreased, while the expression of licBCAH, ntdABC, yyaH-maa, and yyaJ was increased. The effect caused by loss of GlcP function was, however, completely negated in a mutant lacking the ability to synthesize neotrehalosadiamine. Moreover, addition of neotrehalosadiamine into the growth medium had no effect on the expression of these genes, indicating that GlcP-promoted regulation was exerted depending on de novo neotrehalosadiamine synthesis rather than neotrehalosadiamine per se. These findings suggest that GlcP participates in regulation of certain genes by repressing the neotrehalosadiamine biosynthesis operon. This novel regulation system may provide new insights into study of B. subtilis gene expression.

Molecular mechanisms underlying the positive stringent response of the Bacillus subtilis ilv-leu operon, involved in the biosynthesis of branched-chain amino acids.

Branched-chain amino acids are the most abundant amino acids in proteins. The Bacillus subtilis ilv-leu operon is involved in the biosynthesis of branched-chain amino acids. This operon exhibits a RelA-dependent positive stringent response to amino acid starvation. We investigated this positive stringent response upon lysine starvation as well as decoyinine treatment. Deletion analysis involving various lacZ fusions revealed two molecular mechanisms underlying the positive stringent response of ilv-leu, i.e., CodY-dependent and -independent mechanisms. The former is most likely triggered by the decrease in the in vivo concentration of GTP upon lysine starvation, GTP being a corepressor of the CodY protein. So, the GTP decrease derepressed ilv-leu expression through detachment of the CodY protein from its cis elements upstream of the ilv-leu promoter. By means of base substitution and in vitro transcription analyses, the latter (CodY-independent) mechanism was found to comprise the modulation of the transcription initiation frequency, which likely depends on fluctuation of the in vivo RNA polymerase substrate concentrations after stringent treatment, and to involve at least the base species of adenine at the 5' end of the ilv-leu transcript. As discussed, this mechanism is presumably distinct from that for B. subtilis rrn operons, which involves changes in the in vivo concentration of the initiating GTP.

myo-Inositol catabolism in Bacillus subtilis.

The iolABCDEFGHIJ operon of Bacillus subtilis is responsible for myo-inositol catabolism involving multiple and stepwise reactions. Previous studies demonstrated that IolG and IolE are the enzymes for the first and second reactions, namely dehydrogenation of myo-inositol to give 2-keto-myo-inositol and the subsequent dehydration to 3D-(3,5/4)-trihydroxycyclohexane-1,2-dione. In the present studies the third reaction was shown to be the hydrolysis of 3D-(3,5/4)-trihydroxycyclohexane-1,2-dione catalyzed by IolD to yield 5-deoxy-d-glucuronic acid. The fourth reaction was the isomerization of 5-deoxy-D-glucuronic acid by IolB to produce 2-deoxy-5-keto-D-gluconic acid. Next, in the fifth reaction 2-deoxy-5-keto-D-gluconic acid was phosphorylated by IolC kinase to yield 2-deoxy-5-keto-D-gluconic acid 6-phosphate. IolR is known as the repressor controlling transcription of the iol operon. In this reaction 2-deoxy-5-keto-D-gluconic acid 6-phosphate appeared to be the intermediate acting as inducer by antagonizing DNA binding of IolR. Finally, IolJ turned out to be the specific aldolase for the sixth reaction, the cleavage of 2-deoxy-5-keto-D-gluconic acid 6-phosphate into dihydroxyacetone phosphate and malonic semialdehyde. The former is a known glycolytic intermediate, and the latter was previously shown to be converted to acetyl-CoA and CO(2) by a reaction catalyzed by IolA. The net result of the inositol catabolic pathway in B. subtilis is, thus, the conversion of myo-inositol to an equimolar mixture of dihydroxyacetone phosphate, acetyl-CoA, and CO(2).

Regulation of fatty acid metabolism in bacteria.

In Escherichia coli, the main player in transcription regulation of fatty acid metabolism is the FadR protein, which is involved in negative regulation of fatty acid degradation and in positive and negative regulation of the cellular processes related to it, as well as in positive regulation of the biosynthesis of unsaturated fatty acids in a concerted manner with negative regulation of FabR. On the other hand, Bacillus subtilis possesses two global transcriptional regulators, FadR (YsiA) and FapR. B. subtilis FadR represses fatty acid degradation, whereas FapR represses almost all the processes in the biosynthesis of saturated fatty acids and phospholipids. Furthermore, Streptococcus pneumoniae FabT represses the genes of fatty acid biosynthesis that are clustered in its genome. Long-chain acyl-CoAs appear to be metabolic signals for fatty acid degradation by bacteria in general, and antagonize the FadR protein from either E. coli or B. subtilis. However, malonyl-CoA is a metabolic signal for fatty acid and phospholipid biosynthesis by Gram-positive low-GC bacteria, and it antagonizes FapR. These would be the primary aspects for understanding the elaborate and complex regulation of fatty acid metabolism in bacteria to maintain membrane lipid homeostasis.

Dual regulation of the Bacillus subtilis regulon comprising the lmrAB and yxaGH operons and yxaF gene by two transcriptional repressors, LmrA and YxaF, in response to flavonoids.

Bacillus subtilis LmrA is known to be a repressor that regulates the lmrAB and yxaGH operons; lmrB and yxaG encode a multidrug resistance pump and quercetin 2,3-dioxygenase, respectively. DNase I footprinting analysis revealed that LmrA and YxaF, which are paralogous to each other, bind specifically to almost the same cis sequences, LmrA/YxaF boxes, located in the promoter regions of the lmrAB operon, the yxaF gene, and the yxaGH operon for their repression and containing a consensus sequence of AWTATAtagaNYGgTCTA, where W, Y, and N stand for A or T, C or T, and any base, respectively (three-out-of-four match [in lowercase type]). Gel retardation analysis indicated that out of the eight flavonoids tested, quercetin, fisetin, and catechin are most inhibitory for LmrA to DNA binding, whereas quercetin, fisetin, tamarixetin, and galangin are most inhibitory for YxaF. Also, YxaF bound most tightly to the tandem LmrA/YxaF boxes in the yxaGH promoter region. The lacZ fusion experiments essentially supported the above-mentioned in vitro results, except that galangin did not activate the lmrAB and yxaGH promoters, probably due to its poor incorporation into cells. Thus, the LmrA/YxaF regulon presumably comprising the lmrAB operon, the yxaF gene, and the yxaGH operon is induced in response to certain flavonoids. The in vivo experiments to examine the regulation of the synthesis of the reporter beta-galactosidase and quercetin 2,3-dioxgenase as well as that of multidrug resistance suggested that LmrA represses the lmrAB and yxaGH operons but that YxaF represses yxaGH more preferentially.