Environmental regulation of Bacillus subtilis sigma(D)-dependent gene expression

The sigma(D) regulon of Bacillus subtilis is composed of genes encoding proteins for flagellar synthesis, motility, and chemotaxis. Concurrent analyses of sigma(D) protein levels and flagellin mRNA demonstrate that sigD expression and sigma(D) activity are tightly coupled during growth in both complex and minimal media, although they exhibit different patterns of expression. We therefore used the sigma(D)-dependent flagellin gene (hag) as a model gene to study the effects of different nutritional environments on sigma(D)-dependent gene expression. In complex medium, the level of expression of a hag-lacZ fusion increased exponentially during the exponential growth phase and peaked early in the transition state. In contrast, the level of expression of this reporter remained constant and high throughout growth in minimal medium. These results suggest the existence of a nutritional signal(s) that affects sigD expression and/or sigma(D) activity. This signal(s) allows for nutritional repression early in growth and, based on reconstitution studies, resides in the complex components of sporulation medium, as well as in a mixture of mono-amino acids. However, the addition of Casamino Acids to minimal medium results in a dose-dependent decrease in hag-lacZ expression throughout growth and the postexponential growth phase. In work by others, CodY has been implicated in the nutritional repression of several genes. Analysis of a codY mutant bearing a hag-lacZ reporter revealed that flagellin expression is released from nutritional repression in this strain, whereas mutations in the transition state preventor genes abrB, hpr, and sinR failed to elicit a similar effect during growth in complex medium. Therefore, the CodY protein appears to be the physiologically relevant regulator of hag nutritional repression in B. subtilis.     

Chromosomal tetA(L) gene of Bacillus subtilis: regulation of expression and physiology of a tetA(L) deletion strain.

Deletion of the tetA(L) chromosomal region of Bacillus subtilis in a strain designated JC112 increased the strain's sensitivity to low tetracycline concentrations. It also resulted in phenotypic changes that correlate with the previously found role of TetA(L) in mediating electrogenic NA+/H+ antiport. Growth of JC112 was impaired relative to that of the wild type at both pH 7.0 and 8.3; Na(+)- and K(+)-dependent pH homeostases were impaired at alkaline pH. The phenotype of JC112 was complemented by plasmid-borne tetA(L) and related tet(K) genes; the antiport activity conferred by the tet(K) gene had an apparently higher preference for K+ over Na+ than that conferred by tetA(L). The data were consistent with TetA(L) being the major Na+(K+)/H+ antiporter involved in pH homeostasis in B. subtilis as well as a significant Na+ extrusion system. The phenotype of JC112 was much more pronounced than that of an earlier transposition mutant, JC111, with a disruption in the putative tetA(L) promoter region. Northern (RNA) blot analysis of tetA(L) RNA from wild-type and JC111 strains revealed the same patterns. That JC111 nevertheless exhibited some Na+ and alkali sensitivity may be accounted for by disruption of regulatory features that, in the wild type, allow increased tetA(L) expression under specific conditions of pH and monovalent cation concentration. Evidence for several different regulatory effects emerged from studies of lacZ expression from the transposon of JC111 and from a tetA(L)-lacZ translational fusion introduced into the amyE locus of wild-type and JC112 strains.     

Cloning and regulation of the expression of the lysA gene from Bacillus subtilis]

Cloning of Bacillus subtilis DNA fragment with the lysA gene encoding diaminopimelatecarboxylase (EC 4.1.1.20) was done. The cloned gene in poorly expressed both in Escherichia coli and in Bacillus subtilis. Some DNA sequence distant from the lysA gene seems to be necessary for full gene expression, this sequence having been not cloned together with the lysA. The sequence in needed for regulation of the expression as well.     

Role of the Bacillus subtilis gsiA gene in regulation of early sporulation gene expression.

The Bacillus subtilis gsiA operon was induced rapidly, but transiently, as cells entered the stationary phase in nutrient broth medium. A mutation at the gsiC locus caused sporulation to be defective and expression of gsiA to be elevated and prolonged. The sporulation defect in this strain was apparently due to persistent expression of gsiA, since a gsiA null mutation restored sporulation to wild-type levels. Detailed mapping experiments revealed that the gsiC82 mutation lies within the kinA gene, which encodes the histidine protein kinase member of a two-component regulatory system. Since mutations in this gene caused a substantial blockage in expression of spoIIA, spoIIG, and spoIID genes, it seems that accumulation of a product of the gsiA operon interferes with sporulation by blocking the completion of stage II. It apparently does so by inhibiting or counteracting the activity of KinA.     

Complex regulation of the Bacillus subtilis aconitase gene

The roles of the CcpC, CodY, and AbrB proteins in regulation of the Bacillus subtilis aconitase (citB) gene were found to be distinct and to vary with the conditions and phase of growth. CcpC, a citrate-inhibited repressor that is the primary factor regulating citB expression in minimal-glucose-glutamine medium, also contributed to repression of citB during exponential-phase growth in broth medium. A null mutation in codY had no effect on citB expression during growth in minimal medium even when combined with ccpC and abrB mutations. However, a codY mutation slightly relieved repression during exponential growth in broth medium and completely derepressed citB expression when combined with a ccpC mutation. An abrB mutation led to decreased expression of citB during stationary phase in both broth and minimal medium. All three proteins bound in vitro to specific and partially overlapping sites within the citB regulatory region. Interaction of CcpC and CodY with the citB promoter region was partially competitive.     

Transition-state regulators: sentinels of Bacillus subtilis post-exponential gene expression

When Bacillus subtilis encounters a nutrient-depleted environment, it expresses a wide variety of genes that encode functions in alternative pathways of metabolism and energy production. Expression of these genes first occurs during the transition from active growth into stationary phase and is controlled by a class of proteins termed transition-state regulators. In several instances, a given gene is redundantly controlled by two or more of these regulators and many of these regulators control genes in numerous different pathways. The AbrB, Hpr and Sin proteins are the best-studied examples of these regulatory molecules. Their role is to prevent inappropriate and possibly detrimental functions from being expressed during exponential growth when they are not needed. They serve as elements integrating sporulation with ancillary stationary-phase phenomena and appear to participate in the timing of early sporulation events and in fine-tuning the magnitude of gene expression in response to specific environmental conditions.     

Bacillus subtilis ypaA gene regulation mechanism by FMN riboswitch

We studied the regulation of the Bacillus subtilis ypaA gene-encoding riboflavin-transporter by FMN riboswitch. Using translational fusions of the leader region of wild-type ypaA gene with the lacZ-reporter gene in the leader region we showed that in vivo ypaA gene expression decreased more than 10-fold in the presence of endogenous FMN. Introduction of two nucleotide substitutions providing stabilization of the sequester hairpins results in almost complete repression of reporter gene expression. Using toeprint assay in vitro it has been shown that FMN presence inhibits the formation of the 30S initiation complexint the ypaA gene leader mRNA. Our results support the model of ypaA gene regulation whereby FMN binding with the ypaA gene leader sequence results in translation suppression through the sequestering of the SD-sequence.