Polysaccharide that may serve as a carbon and energy storage compound for sporulation in Bacillus cereus.

An intracellular, glucose-containing polysaccharide accumulates in Bacillus cereus early in sporulation and is degraded at the time of spore maturation. This pattern of accumulation and degradation occurred when growth was limited by glucose or a component of yeast extract. These data suggest that the polysaccharide may be serving as a carbon and energy storage compound for sporulation. A somewhat similar pattern of accumulation and degradation of poly-beta-hydroxybutyric acid (PHB) was shown earlier by Kominek and Halvorson (1965) to occur in Bacillus cereus. When cells were grown in a medium buffered strongly at pH 7.4, however, very little accumulation of PHB occurred. We have found that polysaccharide accumulates in cells grown in both the strong and weakly buffered media. Perhaps polysaccharide is the major carbon and energy storage compound when cells are grown under conditions preventing significant accumulation of PHB. The lack of polysaccharide accumulation during the exponential phase of growth may be an indication that the needed biosynthetic enzymes are controlled by catabolite repression during growth. The polysaccharide was purified and found to consist of glucose. The iodine absorption spectrum suggests a degree of branching between that of glycogen and amylopectin.

Critical regions of the Vibrio fischeri luxR protein defined by mutational analysis.

Expression of Vibrio fischeri luminescence genes requires an inducer, termed autoinducer, and a positive regulatory element, the luxR gene product. A plasmid containing a tac promoter-controlled luxR was mutagenized in vitro with hydroxylamine, and luxR mutant plasmids were identified by their inability to complement a luxR deletion mutation in trans. Sixteen luxR mutant plasmids were obtained, ten of which encoded full-length but inactive luxR gene products as demonstrated by a Western immunoblot analysis. The effects of 1 of the 10 mutations could be overcome by the addition of autoinducer at a high concentration. The mutations in each of the 10 mutant plasmids that directed the synthesis of an inactive LuxR protein were identified by DNA sequencing. Of the 10 proteins encoded by the mutant luxR plasmids, 9 differed from the normally active LuxR in only a single amino acid residue. The amino acid residue substitutions in the proteins encoded by the nine mutant luxR genes clustered in two regions. One region around the middle of the polypeptide encoded by luxR was hypothesized to represent an autoinducer-binding domain, and the other region towards the carboxy terminus of the gene product was hypothesized to constitute a lux operator DNA-binding domain or a lux operator DNA recognition domain.

An apparent Bacillus subtilis folic acid biosynthetic operon containing pab, an amphibolic trpG gene, a third gene required for synthesis of para-aminobenzoic acid, and the dihydropteroate synthase gene.

McDonald and Burke (J. Bacteriol. 149:391-394, 1982) previously cloned a sulfanilamide-resistance gene, sul, residing on a 4.9-kb segment of Bacillus subtilis chromosomal DNA, into plasmid pUB110. In this study we determined the nucleotide sequence of the entire 4.9-kb fragment. Genes identified on the fragment include pab, trpG, pabC, sul, one complete unidentified open reading frame, and one incomplete unidentified open reading frame. The first three of these genes, pab, trpG, and pabC, are required for synthesis of p-aminobenzoic acid. The trpG gene encodes an amphibolic glutamine amidotransferase required for synthesis of both p-aminobenzoate and anthranilate, the latter an intermediate in the tryptophan biosynthetic pathway. The pabC gene may encode a B. subtilis analog of enzyme X, an enzyme needed for p-aminobenzoate synthesis in Escherichia coli. The sul gene probably encodes dihydropteroate synthase, the enzyme responsible for formation of 7,8-dihydropteroate, the immediate precursor of folic acid. All six of the cloned genes are arranged in a single operon. Since all four of the identified genes are needed for folate biosynthesis, we refer to this operon as a folic acid operon. Expression of the trpG gene is known to be negatively controlled by tryptophan. We propose that this regulation is at the level of translation. This hypothesis is supported by the finding of an apparent Mtr-binding site which overlaps with the trpG ribosome-binding site.