AbrB modulates expression and catabolite repression of a Bacillus subtilis ribose transport operon.

A Bacillus subtilis ribose transport operon (rbs) was shown to be subject to AbrB-mediated control through direct AbrB-DNA binding interactions in the vicinity of the promoter. Overproduction of AbrB was shown to relieve catabolite repression of rbs during growth in the presence of poorer carbon sources such as arabinose but had much less effect when cells were grown in the presence of glucose, a rapidly metabolizable carbon source. A ccpA mutation relieved catabolite repression of rbs under all conditions tested. One of the AbrB-binding sites on the rbs promoter contains the putative site of action for the B. subtilis catabolite repressor protein CcpA, suggesting that competition for binding to this site could be at least partly responsible for modulating rbs expression during carbon-limited growth.     

A mutated PtsG, the glucose transporter, allows uptake of D-ribose.

Mutations arose from an Escherichia coli strain defective in the high (Rbs/ribose) and low (Als/allose and Xyl/xylose) affinity D-ribose transporters, which allow cells to grow on D-ribose. Genetic tagging and mapping of the mutations revealed that two loci in the E. coli linkage map are involved in creating a novel ribose transport mechanism. One mutation was found in ptsG, the glucose-specific transporter of phosphoenolpyruvate:carbohydrate phosphotransferase system and the other in mlc, recently reported to be involved in the regulation of ptsG. Five different mutations in ptsG were characterized, whose growth on D-ribose medium was about 80% that of the high affinity system (Rbs+). Two of them were found in the predicted periplasmic loops, whereas three others are in the transmembrane region. Ribose uptakes in the mutants, competitively inhibited by D-glucose, D-xylose, or D-allose, were much lower than that of the high affinity transporter but higher than those of the Als and Xyl systems. Further analyses of the mutants revealed that the rbsK (ribokinase) and rbsD (function unknown) genes are involved in the ribose transport through PtsG, indicating that the phosphorylation of ribose is not mediated by PtsG and that some unknown metabolic function mediated by RbsD is required. It was also found that D-xylose, another sugar not involved in phosphorylation, was efficiently transported through the wild-type or mutant PtsG in mlc-negative background. The efficiencies of xylose and glucose transports are variable in the PtsG mutants, depending on their locations, either in the periplasm or in the membrane. In an extreme case of the transmembrane change (I283T), xylose transport is virtually abolished, indicating that the residue is directly involved in determining sugar specificity. We propose that there are at least two domains for substrate specificity in PtsG with slightly altered recognition properties.     

The isolation of fumB mutants of Escherichia coli

Escherichia coli strains lacking the terminus region of the chromosome (min 29-36) due to an IS10-promoted deletion did not grow well in rich medium; they also did not grow on fumarate minimal medium because fumAC (min 35.7) is deleted. Strains with secondary mutations that partially suppress the deletion phenotype displayed healthier growth on rich medium and grew on minimal fumarate medium. These suppressor mutants had an IS10 insertion just upstream of the fumB structural gene (min 93.4). A strain with a Tn10 insertion at this location was constructed and used to delete nonessential fumB; fumB deletion mutants grew well on both rich and minimal fumarate media.     

Characterization of Bacillus subtilis mutants with carbon source-independent glutamate biosynthesis

Bacillus subtilis synthesizes glutamate from 2-oxoglutarate and glutamine using the glutamate synthase, encoded by the gltAB operon. Glutamate degradation involves the catabolic glutamate dehydrogenase (GDH) RocG. Expression of both gltAB and rocG is controlled by the carbon and nitrogen sources. In the absence of glucose or other well-metabolizable carbon sources, B. subtilis is unable to grow unless provided with external glutamate. In this work, we isolated mutations that suppressed this growth defect of B. subtilis on minimal media (sgd mutants). All mutations enabled the cells to express the gltAB operon even in the absence of glucose. The mutations were all identified in the rocG gene suggesting that the catabolic GDH is essential for controlling gltAB expression in response to the availability of sugars.     

A mechanism of transposon-mediated directed mutation

Directed mutation is a proposed process that allows mutations to occur at higher frequencies when they are beneficial. Until now, the existence of such a process has been controversial. Here we describe a novel mechanism of directed mutation mediated by the transposon, IS 5 in Escherichia coli . crp deletion mutants mutate specifically to glycerol utilization (Glp⁺) at rates that are enhanced by glycerol or the loss of the glycerol repressor (GlpR), depressed by glucose or glpR overexpression, and RecA-independent. Of the four tandem GlpR binding sites ( O1–O4 ) upstream of the glpFK operon, O4 specifically controls glpFK expression while O1 primarily controls mutation rate in a process mediated by IS 5 hopping to a specific site on the E. coli chromosome upstream of the glpFK promoter. IS 5 insertion into other gene activation sites is unaffected by the presence of glycerol or the loss of GlpR. The results establish an example of transposon-mediated directed mutation, identify the protein responsible and define the mechanism involved.     

Mutations in pts cause catabolite-resistant sporulation and altered regulation of spo0H in Bacillus subtilis.

A mutation in Bacillus subtilis, ggr-31, that relieves glucose-glutamine-dependent control of a spoVG-lacZ translational fusion was isolated and was subsequently found to confer a pleiotropic phenotype. Mutants cultured in glucose- and glutamine-rich media exhibited a Crs- (catabolite-resistant sporulation) phenotype; enhanced expression of the spo0H gene, encoding sigma H, as evidenced by immunoblot analysis with anti-sigma H antiserum; and derepression of srfA, an operon involved in surfactin biosynthesis and competence development. In addition, ggr-31 mutants exhibited a significant increase in generation time when they were cultured in minimal glucose medium. The mutant phenotype was restored to the wild type by Campbell integration of a plasmid containing part of the ptsG (encoding the enzyme II/III glucose permease) gene, indicating that the mutation probably resides within ptsG and adversely affects glucose uptake. A deletion mutation within ptsI exhibited a phenotype similar to that of ggr-31.     

Evolution of the D-ribose operon on Escherichia coli B/r.

The D-ribose operon (rbs) of Escherichia coli K-12 maps at 83 min and is inducible. The rbs operon of E. coli B/r maps at 2 min and is constitutive. Evidence is presented showing that a second inducible copy of the rbs operons is present in E. coli B/r mapping at 83 min. The data indicated that the duplication of the rbs operon represented a transposition of the 83-min region to 2 min. The identification of a second copy of the rbs operon in B/r and the determination of its inducibility were based on the reactivation, through mutagenesis, of inducible rbs expression, mapping by P1 transduction of the mutation site to 83 min, and merodiploid complementation analysis of the D-ribokinase expression in E. coli B/r. We also show that the rbs transposition to 2-min continued to generate transposable elements coding for the 1- to 2-min region of the chromosome and transposing onto extrachromosomal DNA target molecules such as pBR322.     

Evidence that Na+-pumping occurs through the D-channel in Vitreoscilla cytochrome bo

The operon (cyo) encoding the Na(+)-pumping respiratory terminal oxidase (cytochrome bo) of the bacterium Vitreoscilla was transformed into Escherichia coli GV100, a deletion mutant of cytochrome bo. This was done for the wild type operon and five mutants in three conserved Cyo subunit I amino acids known to be crucial for H(+) transport in the E. coli enzyme, one near the nuclear center, one in the K-channel, and one in the D-channel. CO-binding, NADH and ubiquinol oxidase, and Na(+)-pumping activities were all substantially inhibited by each mutation. The wild type Vitreoscilla cytochrome bo can pump Na(+) against a concentration gradient, resulting in a transmembrane concentration differential of 2-3 orders of magnitude. It is proposed that Vitreoscilla cytochrome bo pumps four Na(+) through the D-channel to the exterior and transports four H(+) through the K-channel for the reduction of each O(2).     

Isopropylbenzene catabolic pathway in Pseudomonas putida RE204: nucleotide sequence analysis of the ipb operon and neighboring DNA from pRE4

Pseudomonas putida RE204 employs a set of plasmid-specified enzymes in the catabolism of isopropylbenzene (cumene) and related alkylbenzenes. A 21,768 bp segment of the plasmid pRE4, whose sequence is discussed here, includes the ipb (isopropylbenzene catabolic) operon as well as associated genetic elements. The ipb operon, ipbAaAbAcAdBCEGFHD, encodes enzymes catalyzing the conversion of isopropylbenzene to isobutyrate, pyruvate, and acetyl-coenzyme A as well as an outer membrane protein (IpbH) of uncertain function. These gene products are 75 to 91% identical to those encoded by other isopropylbenzene catabolic operons and are somewhat less similar to analogous proteins of related pathways for the catabolism of mono-substituted benzenes. Upstream of ipbAa, ipbR encodes a positive regulatory protein which has about 56% identity to XylS regulatory proteins of TOL (xylene/toluate) catabolic plasmids. This similarity and that of the DNA sequence in the proposed ipb operator-promoter region (ipbOP) to the same region of the xyl meta operon (xylOmPm) suggest that, although the IpbR and XylS regulatory proteins recognize very different inducers, their interactions with DNA to activate gene expression are similar. Upstream of ipbR is an 1196 bp insertion sequence, IS1543, related to IS52 and IS1406. Separating ipbR from ipbAa are 3 additional tightly clustered IS elements. These are IS1544, related to IS1543, IS52, and other members of the IS5 family; IS1545, related to IS1240; and IS1546, related to IS1491. Encompassing the ipb catabolic genes and the other genetic elements and separated from each other by 18,492 bp, are two identical, directly repeated 1007 bp DNA segments. Homologous recombination between these segments appears to be responsible for the occasional deletion of the intervening DNA from pRE4.     

The catabolite control protein CcpA controls ammonium assimilation in Bacillus subtilis

Carbon catabolite repression of several catabolic operons in Bacillus subtilis is mediated by the repressor CcpA. An inactivation of the ccpA gene has two distinct phenotypes: (i) catabolite repression of catabolic operons is lost and (ii) the growth of bacteria on minimal medium is severely impaired. We have analyzed the physiological properties of a ccpA mutant strain and show that the ccpA mutation does not affect sugar transport. We have isolated extragenic suppressors of ccpA that suppress the growth defect (sgd mutants). Catabolite repression of beta-xylosidase synthesis was, however, not restored suggesting that the suppressor mutations allow differentiation between the phenotypes of the ccpA mutant. A close inspection of the growth requirements of the ccpA mutant revealed the inability of the mutant to utilize inorganic ammonium as a single source of nitrogen. An intact ccpA gene was found to be required for expression of the gltAB operon encoding glutamate synthase. This enzyme is necessary for the assimilation of ammonium. In a sgd mutant, gltAB operon expression was no longer dependent on ccpA, suggesting that the poor expression of the gltAB operon is involved in the growth defect of the ccpA mutant.     

Adaptive Evolution That Requires Multiple Spontaneous Mutations. I. Mutations Involving an Insertion Sequence

Escherichia coli K12 strain chi 342LD requires two mutations in the bgl (beta-glucosidase) operon, bglR0----bglR+ and excision of IS103 from within bglF, in order to utilize salicin. In growing cells the two mutations occur at rates of 4 x 10(-8) per cell division and less than 2 x 10(-12) per cell division, respectively. In 2-3-week-old colonies on MacConkey salicin plates the double mutants occur at frequencies of 10(-8) per cell, yet the rate of an unselected mutation, resistance to valine, is unaffected. The two mutations occur sequentially. Colonies that are 8-12 days old contain from 1% to about 10% IS103 excision mutants, from which the Sal+ secondary bglR0----bglR+ mutants arise. It is shown that the excision mutants are not advantageous within colonies; thus, they must result from a burst of independent excisions late in the life of the colony. Excision of IS103 occurs only on medium containing salicin, despite the fact that the excision itself confers no detectable selective advantage and serves only to create the potential for a secondary selectively advantageous mutation.     

Ribokinase from Escherichia coli K12. Nucleotide sequence and overexpression of the rbsK gene and purification of ribokinase

The nucleotide sequence of a 1455-base pair TaqI-HinfI fragment of the rbs operon of Escherichia coli K12 has been determined. It includes the 3' terminus of rbsB (the gene for ribose-binding protein) and the entire rbsK gene, encoding ribokinase. Potential consensus promoter sequences and a stable stem-loop structure are present in the rbsB-rbsK intercistronic region. The regulatory significance of these sequence features is discussed with respect to the rbs operon. rbsK has been cloned downstream from the Serratia marcescens trp promoter on a multicopy plasmid. Cells harboring this plasmid, when grown on minimal ribose plus ampicillin, express ribokinase at the level of 2% of the soluble protein, and induction with indoleacrylic acid raises ribokinase levels another 8-fold. Ribokinase has been purified to homogeneity (216 mumol/min/mg) from a strain harboring this plasmid. Protein sequence analyses of peptides generated by cyanogen bromide cleavage and o-iodosobenzoic acid cleavage confirmed the translation initiation site and the reading frame of the DNA sequence. Amino acid compositions of native ribokinase and the C-terminal dodecapeptide agree with the predicted amino acid compositions, confirming the accuracy of the DNA sequence and the translation termination site.     

Suppression of hypersensitivity of Escherichia coli acrB mutant to organic solvents by integrational activation of the acrEF operon with the IS1 or IS2 element

The AcrAB-TolC efflux pump plays an intrinsic role in resistance to hydrophobic solvents in Escherichia coli. E. coli OST5500 is hypersensitive to solvents due to inactivation of the acrB gene by insertion of IS30. Suppressor mutants showing high solvent resistance were isolated from OST5500. These mutants produced high levels of AcrE and AcrF proteins, which were not produced in OST5500, and in each mutant an insertion sequence (IS1 or IS2) was found integrated upstream of the acrEF operon, coding for the two proteins. The suppressor mutants lost solvent resistance on inactivation of the acrEF operon. The solvent hypersensitivity of OST5500 was suppressed by introduction of the acrEF operon with IS1 or IS2 integrated upstream but not by introduction of the operon lacking the integrated IS. It was concluded that IS integration activated acrEF, resulting in functional complementation of the acrB mutation. The acrB mutation was also complemented by a plasmid containing acrF or acrEF under the control of Plac. The wild-type tolC gene was found to be essential for complementation of the acrB mutation by acrEF. Thus, it is concluded that in these cells a combination of the proteins AcrA, AcrF, and TolC or the proteins AcrE, AcrF, and TolC is functional in solvent efflux instead of the AcrAB-TolC efflux pump.     

The end of the cob operon: evidence that the last gene (cobT) catalyzes synthesis of the lower ligand of vitamin B12, dimethylbenzimidazole.

The cob operon of Salmonella typhimurium includes 20 genes devoted to the synthesis of adenosyl-cobalamin (coenzyme B12). Mutants with lesions in the promoter-distal end of the operon synthesize vitamin B12 only if provided with 5,6-dimethylbenzimidazole (DMB), the lower ligand of vitamin B12. In the hope of identifying a gene(s) involved in synthesis of DMB, the DNA base sequence of the end of the operon has been determined; this completes the sequence of the cob operon. The cobT gene is the last gene in the operon. Four CobII (DMB-) mutations mapping to different deletion intervals of the CobII region were sequenced; all affect the cobT open reading frame. Both the CobT protein of S. typhimurium and its Pseudomonas homolog have been shown in vitro to catalyze the transfer of ribose phosphate from nicotinate mononucleotide to DMB. This reaction does not contribute to DMB synthesis but rather is the first step in joining DMB to the corrin ring compound cobinamide. Thus, the phenotype of Salmonella cobT mutants conflicts with the reported activity of the affected enzyme, while Pseudomonas mutants have the expected phenotype. J. R. Trzebiatowski, G. A. O'Toole, and J. C. Escalante Semerena have suggested (J. Bacteriol. 176:3568-3575, 1994) that S. typhimurium possesses a second phosphoribosyltransferase activity (CobB) that requires a high concentration of DMB for its activity. We support that suggestion and, in addition, provide evidence that the CobT protein catalyzes both the synthesis of DMB and transfer of ribose phosphate. Some cobT mutants appear defective only in DMB synthesis, since they grow on low levels of DMB and retain their CobII phenotype in the presence of a cobB mutation. Other mutants including those with deletions, appear defective in transferase, since they require a high level of DMB (to activate CobB) and, in combination with a cobB mutation, they eliminate the ability to join DMB and cobinamide. Immediately downstream of the cob operon is a gene (called ORF in this study) of unknown function whose mutants have no detected phenotype. Just counterclockwise of ORF is an asparagine tRNA gene (probably asnU). Farther counterclockwise, a serine tRNA gene (serU or supD) is weakly cotransducible with the cobT gene.