Bacillus subtilis is the best-characterized member of the Gram-positive bacteria. Its genome of 4,214,810 base pairs comprises 4,100 protein-coding genes. Of these protein-coding genes, 53% are represented once, while a quarter of the genome corresponds to several gene families that have been greatly expanded by gene duplication, the largest family containing 77 putative ATP-binding transport proteins. In addition, a large proportion of the genetic capacity is devoted to the utilization of a variety of carbon sources, including many plant-derived molecules. The identification of five signal peptidase genes, as well as several genes for components of the secretion apparatus, is important given the capacity of Bacillus strains to secrete large amounts of industrially important enzymes. Many of the genes are involved in the synthesis of secondary metabolites, including antibiotics, that are more typically associated with Streptomyces species. The genome contains at least ten prophages or remnants of prophages, indicating that bacteriophage infection has played an important evolutionary role in horizontal gene transfer, in particular in the propagation of bacterial pathogenesis.
CodY, a highly conserved protein in the low G + C, gram-positive bacteria, regulates the expression of many Bacillus subtilis genes that are induced as cells make the transition from rapid exponential growth to stationary phase and sporulation. This transition has been associated with a transient drop in the intracellular pool of GTP. Many stationary-phase genes are also induced during exponential-growth phase by treatment of cells with decoyinine, a GMP synthetase inhibitor. The effect of decoyinine on an early-stationary-phase gene is shown here to be mediated through CodY and to reflect a reduction in guanine nucleotide accumulation. CodY proved to bind GTP in vitro. Moreover, CodY-mediated repression of target promoters was dependent on a high concentration of GTP, comparable to that found in rapidly growing exponential-phase cells. Because a codY-null mutant was able to sporulate under conditions of nutrient excess, CodY also appears to be a critical factor that normally prevents sporulation under such conditions. Thus, B. subtilis CodY is a novel GTP-binding protein that senses the intracellular GTP concentration as an indicator of nutritional conditions and regulates the transcription of early-stationary-phase and sporulation genes, allowing the cell to adapt to nutrient limitation. Our understanding of the relationship between environmental signals and global changes in gene expression is limited by the difficulty in identifying intracellular signaling molecules that interact with key regulatory proteins. This gap is particularly apparent for cases of general nutrient limitation. When Bacillus subtilis cells encounter nutrient limitation and enter stationary phase, a variety of adaptive processes-such as genetic competence, secretion of macromolecule-degrading enzymes, import of secondary nutrients, activation of metabolic pathways, chemotaxis and motility, production of antibiotics, and sporulation-are initiated (Sonenshein 1989). A network of global regulatory proteins modulates the cell's response and regulates the choice between adaptation to poor growth conditions and sporulation (Sonenshein 1989(Sonenshein , 2000Burkholder and Grossman 2000), but the specific signals to which these regulators respond have remained a mystery.Many B. subtilis genes that are expressed early in stationary phase are repressed by CodY (Table 1). Preliminary results indicate that CodY also contributes to regulation of at least two genes (citB, spo0A) whose products are necessary for sporulation (M. Ratnayake- Lecamwasam and A.L. Sonenshein, unpubl. Bolotin et al. 1999).CodY was first identified as a repressor of the B. subtilis dipeptide transport (dpp) operon and was found to be active when cells are grown with an excess of glucose or Casamino acids (CAA) as reported by Slack et al. (1995). During vegetative growth, the dpp operon is also directly repressed by AbrB, a second global regulator of earlystationary-phase genes Strauch 1993;Serror and Sonenshein 1996b), but the repressive effects of nutrient excess are mediat...
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SummaryProteolysis is essential for supplying Lactococcus lactis with amino acids during growth in milk. Expression of the major components of the L. lactis proteolytic system, including the cell wall proteinase (PrtP), the oligopeptide transport system (Opp) and at least four intracellular peptidases (PepO1, PepN, PepC, PepDA2), was shown previously to be controlled negatively by a rich nitrogen source. The transcription of prtP, opp±pepO1, pepN and pepC genes is regulated by dipeptides in the medium. Random insertion mutants derepressed for nitrogen control in the expression of the oligopeptide transport system were isolated using an opp±lacZ fusion. A third of the mutants were targeted in the same locus. The product of the inactivated gene shared 48% identity with CodY from Bacillus subtilis, a pleiotropic repressor of the dipeptide permease operon (dpp) and several genes including genes involved in amino acid degradation and competence induction. The signal controlling CodY-dependent repression was searched for by analysing the response of the opp±lux fusion to the addition of 67 dipeptides with different amino acid compositions. Full correlation was found between the dipeptide content in branched-chain amino acids (BCAA; isoleucine, leucine or valine) and their ability to mediate the repression of opp±pepO1 expression. The repressive effect resulting from specific regulatory dipeptides was abolished in L. lactis mutants affected in terms of their transport or degradation into amino acids, showing that the signal was dependent on the BCAA pool in the cell. Lastly, the repression of opp±pepO1 expression was stronger in a mutant unable to degrade BCAAs, underlining the central role of BCAAs as a signal for CodY activity. This pattern of regulation suggests that, in L. lactis and possibly other Gram-positive bacteria, CodY is a pleiotropic repressor sensing nutritional supply as a function of the BCAA pool in the cell.
Lactic acid bacteria (LAB) constitute a heterogeneous group of bacteria that are traditionally used to produce fermented foods. The industrialization of food bio-transformations increased the economical importance of LAB, as they play a crucial role in the development of the organoleptique and hygienic quality of fermented products. Therefore, the reliability of starter strains in terms of quality and functional properties (important for the development of aroma and texture), but also in terms of growth performance and robustness has become essential. These strains should resist to adverse conditions encountered in industrial processes, for example during starter handling and storage (freeze-drying, freezing or spray-drying). The development of new applications such as life vaccines and probiotic foods reinforces the need for robust LAB since they may have to survive in the digestive tract, resist the intestinal flora, maybe colonize the digestive or uro-genital mucosa and express specific functions under conditions that are unfavorable to growth (for example, during stationary phase or storage). Also in nature, the ability to quickly respond to stress is essential for survival and it is now well established that LAB, like other bacteria, evolved defense mechanisms against stress that allow them to withstand harsh conditions and sudden environmental changes. While genes implicated in stress responses are numerous, in LAB the levels of characterization of their actual role and regulation differ widely between species. The functional conservation of several stress proteins (for example, HS proteins, Csp, etc) and of some of their regulators (for example, HrcA, CtsR) renders even more striking the differences that exist between LAB and the classical model micro-organisms. Among the differences observed between LAB species and B. subtilis, one of the most striking is the absence of a sigma B orthologue in L. lactis ssp. lactis as well as in at least two streptococci and probably E. faecalis. The overview of LAB stress responses also reveals common aspects of stress responses. As in other bacteria, adaptive responses appear to be a usual mode of stress protection in LAB. However, the cross-protection to other stress often induced by the expression of a given adaptive response, appears to vary between species. This observation suggests that the molecular bases of adaptive responses are, at least in part, species (or even subspecies) specific. A better understanding of the mechanisms of stress resistance should allow to understand the bases of the adaptive responses and cross protection, and to rationalize their exploitation to prepare LAB to industrial processes. Moreover, the identification of crucial stress related genes will reveal targets i) for specific manipulation (to promote or limit growth), ii) to develop tools to screen for tolerant or sensitive strains and iii) to evaluate the fitness and level of adaptation of a culture. In this context, future genome and transcriptome analyses will undoubtedly complement ...
The acquisition of genetic competence by Bacillus subtilis is repressed when the growth medium contains Casamino Acids. This repression was shown to be exerted at the level of expression from the promoters of the competence-regulatory genes srfA and comK and was relieved in strains carrying a null mutation in the codY gene. DNase I footprinting experiments showed that purified CodY binds directly to the srfA and comK promoter regions.When Bacillus subtilis cells reach stationary phase, they induce several adaptive responses. Among these is the acquisition of genetic competence, a physiological state that enables cells to take up exogenous DNA. The acquisition of competence requires the expression of at least 20 "late" com genes (7), whose transcription is regulated by a variety of nutritional, growth stage-, and cell type-specific mechanisms. These regulatory mechanisms involve the products of at least 15 additional genes (13). In the primary regulatory cascade, two extracellular signal peptides, competence-stimulating factor (39) and ComX (21), are detected by the products of the oligopeptide permease (opp) operon (29, 32) and comP, respectively, and as a result, the transcription factor ComA becomes phosphorylated. Phosphorylated ComA acts as a positive regulator for the srfA operon (14,26,27,45), one of whose products, ComS, is needed for expression of comK (5,6,18). ComK, in turn, activates transcription of the late com genes (e.g., comG [1,16,42,44]). The ComK activation pathway is counterbalanced by the MecA/MecB system, which inhibits ComK activity and can prevent the acquisition of competence under inappropriate environmental conditions (10,19,20,24).During exponential growth in minimal medium, competence is repressed by the addition of Casamino acids (9), an effect that appears to be exerted before srfA expression in the regulatory cascade (15). Such a repressive effect of amino acid mixtures has been described for other operons (2), including hut, the histidine utilization operon (3), dpp (37), which encodes a dipeptide transport system (23), and gsiA (25), which codes for a regulatory protein phosphatase (28). The product of the codY gene has been shown to be required for amino acid repression of the dpp operon (36, 38), and a codY mutation partially relieves amino acid control of hut (11, 38) and gsiA (35). Moreover, purified CodY binds to a part of the dpp promoter region within which mutations relieve amino acid repression (34). Since competence is also repressed by mixtures of amino acids, we tested whether the codY gene has any role in this repression. We show that CodY is required for the effect of Casamino Acids on competence and that CodY interacts with the srfA and comK promoter regions. MATERIALS AND METHODSBacterial strains. All B. subtilis strains used in this study (Table 1) were derived from FJS107 (36), a derivative of JH642 (30).Media. S7 minimal medium for competence assays and -galactosidase assays contained S7 minimal salts (46) supplemented with 1% glucose, 0.1% glutamate, and ami...
Polylysogeny is frequently considered to be the result of an adaptive evolutionary process in which prophages confer fitness and/or virulence factors, thus making them important for evolution of both bacterial populations and infectious diseases. The Enterococcus faecalis V583 isolate belongs to the high-risk clonal complex 2 that is particularly well adapted to the hospital environment. Its genome carries 7 prophage-like elements (V583-pp1 to -pp7), one of which is ubiquitous in the species. In this study, we investigated the activity of the V583 prophages and their contribution to E. faecalis biological traits. We systematically analyzed the ability of each prophage to excise from the bacterial chromosome, to replicate and to package its DNA. We also created a set of E. faecalis isogenic strains that lack from one to all six non-ubiquitous prophages by mimicking natural excision. Our work reveals that prophages of E. faecalis V583 excise from the bacterial chromosome in the presence of a fluoroquinolone, and are able to produce active phage progeny. Intricate interactions between V583 prophages were also unveiled: i) pp7, coined EfCIV583 for E. faecalis chromosomal island of V583, hijacks capsids from helper phage 1, leading to the formation of distinct virions, and ii) pp1, pp3 and pp5 inhibit excision of pp4 and pp6. The hijacking exerted by EfCIV583 on helper phage 1 capsids is the first example of molecular piracy in Gram positive bacteria other than staphylococci. Furthermore, prophages encoding platelet-binding-like proteins were found to be involved in adhesion to human platelets, considered as a first step towards the development of infective endocarditis. Our findings reveal not only a role of E. faecalis V583 prophages in pathogenicity, but also provide an explanation for the correlation between antibiotic usage and E. faecalis success as a nosocomial pathogen, as fluoriquinolone may provoke release of prophages and promote gene dissemination among isolates.
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