Catabolite repression of the operon for xylose utilization from Bacillus subtilis W23 is mediated at the level of transcription and depends on a cis site in the xylA reading frame

Catabolite repression of the Bacillus subtilis gnt operon mediated by the CcpA protein

Inducer exclusion was not important in catabolite repression of the Bacillus subtilis gnt operon. The CcpA protein (also known as AlsA) was found to be necessary for catabolite repression of the gnt operon, and a mutation (crsA47, which is an allele of the sigA gene) partially affected this catabolite repression.

Catabolite repression in the gram-positive bacteria: generation of negative regulators of transcription

Operons subject to catabolite repression (CR) in the gram-positive bacteria appear to be transcriptionally regulated by negative acting catabolite repressors. Cis elements within the promoter regions of a few CR operons have been identified as the target sequences for these repressors. It has also been proposed that sequences internal to the transcriptional unit may represent targets for recognition of the operons as catabolite repressible. The precise mechanism(s) of regulation have yet to be worked out.

Catabolite repression of the xyl operon in Bacillus megaterium

We characterized catabolite repression of the genes encoding xylose utilization in Bacillus megaterium. A transcriptional fusion of xylA encoding xylose isomerase to the spoVG-lacZ indicator gene on a plasmid with a temperature-sensitive origin of replication was constructed and efficiently used for single-copy replacement cloning in the B. megaterium chromosome starting from a single transformant. In the resulting strain, beta-galactosidase expression is 150-fold inducible by xylose and 14-fold repressed by glucose, showing that both regulatory effects occur at the level of transcription. Insertion of a kanamycin resistance gene into xylR encoding the xylose-dependent repressor leads to the loss of xylose-dependent regulation and to a small drop in the efficiency of glucose repression to eightfold. Deletion of 184 bp from the 5' part of the xylA reading frame reduces glucose repression to only twofold. A potential glucose-responsive element in this region is discussed on the basis of sequence similarities to other glucose-repressed genes in Bacillus subtilis. The sequence including the glucose-responsive element is also necessary for repression exerted by the carbon sources fructose and mannitol. Their efficiencies of repression correlate to the growth rate of B. megaterium, as is typical for catabolite repression. Glycerol, ribose, and arabinose exert only a basal twofold repression of the xyl operon, which is independent of the presence of the cis-active glucose-responsive element within the xylA reading frame.

Regulation of Staphylococcus xylosus xylose utilization genes at the molecular level

We have investigated the regulation of the operon encoding xylose utilization in Staphylococcus xylosus C2a and Staphylococcus carnosus TM300. For in vivo studies, transcriptional fusions of the xylAB regulatory region to the lipase gene from Staphylococcus hyicus were constructed. Repression of lipase activity depended on a functional xylR gene and an xyl operator palindrome downstream of the promoter, while induction was obtained in the presence of xylose. Inactivation of either xylR or the xyl operator led to constitutive expression in the absence of xylose. Crude protein extracts from xylR+ staphylococci led to gel mobility shifts of the xyl regulatory DNA in the absence but not in the presence of xylose. A copper-phenanthroline footprint of the shifted band revealed protection of 28 phosphodiesters from cleavage in each strand of the xyl operator. Thus, the Xyl repressor covers the DNA over more than 2.5 helical turns. Glucose repression of the xyl operon occurs at the level of transcription and is independent of a functional xylR gene. A potential cis-active sequence element for glucose repression is discussed on the basis of sequence similarities to respective elements from bacilli.

Developmental regulation of transcription of the Bacillus subtilis ftsAZ operon

The products of the ftsA and ftsZ genes play a major role in septum formation in Escherichia coli. Their homologues have been found in various bacterial species, such as Bacillus subtilis where they are involved in septation during vegetative growth as well as during sporulation, a developmental process that is initiated by the formation of an asymmetrically positioned septum. Transcription of the B. subtilis ftsAZ operon was studied during exponential growth and sporulation by monitoring beta-galactosidase synthesis in strains harboring fusions of the E. coli lacZ gene with various fragments of the ftsAZ regulatory region. Transcription of the ftsAZ operon was found to be controlled by three promoters which were mapped by primer extension and characterized by their temporal pattern of expression. Two of these promoters, P1 and P3, are dependent on sigma A, the major vegetative sigma factor, and are expressed mainly during growth. The third one, P2, is recognized by sigma H associated RNA polymerase and its activity increases three- to four-fold around the onset of sporulation. The post-exponential enhancement of P2-driven transcription is abolished in a spo0A mutant but partially restored in an abrB spo0A double mutant. After inactivation by oligonucleotide-directed mutagenesis mutated copies of P1 and P2 were introduced into the chromosome upstream from the ftsAZ operon. Transformants could be obtained only when ftsAZ transcription was controlled by a combination of two intact promoters, neither P1, P2 nor P3 being essential for viability. The sporulation efficiency was found to be dependent on the level of transcription of ftsAZ, the absence of P2 still allowing 30% of the normal sporulation rate. Therefore the post-exponential burst of synthesis of the FtsA and FtsZ proteins is not an absolute requirement for the successful completion of the asymmetric septum.

Regulation of the Bacillus subtilis W23 xylose utilization operon: interaction of the Xyl repressor with the xyl operator and the inducer xylose

A crude protein extract of Bacillus subtilis W23 contains a sequence-specific DNA binding activity for the xyl operator as detected by the gel mobility shift assay. A xylR determinant encoded on a multicopy plasmid leads to increased expression of this binding activity. In situ footprinting analysis of the protein-DNA complex in a polyacrylamide gel shows that the xyl operator is sequence-specifically bound and protected from cleavage by copper-phenanthroline at 26 phosphodiester bonds on each strand. Quantitative competition assays for repressor binding reveal that a 25 bp synthetic xyl operator cloned into a polylinker is bound with the same affinity as the operator in the wild-type xyl regulatory region. This confirms that no additional sites in the wild-type sequence contribute to repressor binding. The xyl operator consists of ten palindromic base pairs flanking five central non-palindromic base pairs. A mutational analysis shows that the sequence of the central base pairs contributes to recognition by the repressor protein and that the spacing of the palindromic elements is crucial for repressor binding. An operator half site is not bound by the repressor. In vivo and in vitro induction studies suggest that, of several structurally similar sugars, xylose is the only molecular inducer of the Xyl repressor.