Project description:A polymerase chain reaction (PCR) assay was developed for discrimination of Bacillus subtilis from other members of B. subtilis group as well as rapid identification from environmental samples. Primers ENIF and EN1R from endoglucanase gene were used to amplify a1311 bp DNA fragment. The specificity of the primers was tested with seven reference strains and 28 locally isolated strains of endoglucanase positive Bacillus species. The PCR product was only produced from B. subtilis. The results demonstrated high specificity of two oligonucleotides for B. subtilis. This species-specific PCR method provides a quick, simple, powerful and reliable alternative to conventional methods in the detection and identification of B. subtilis. To our knowledge this is the first report of a B. subtilis specific primer set.

Project description:Kin discrimination, broadly defined as differential treatment of conspecifics according to their relatedness, could help biological systems direct cooperative behavior toward their relatives. Here we investigated the ability of the soil bacterium Bacillus subtilis to discriminate kin from nonkin in the context of swarming, a cooperative multicellular behavior. We tested a collection of sympatric conspecifics from soil in pairwise combinations and found that despite their history of coexistence, the vast majority formed distinct boundaries when the swarms met. Some swarms did merge, and most interestingly, this behavior was only seen in the most highly related strain pairs. Overall the swarm interaction phenotype strongly correlated with phylogenetic relatedness, indicative of kin discrimination. Using a subset of strains, we examined cocolonization patterns on plant roots. Pairs of kin strains were able to cocolonize roots and formed a mixed-strain biofilm. In contrast, inoculating roots with pairs of nonkin strains resulted in biofilms consisting primarily of one strain, suggestive of an antagonistic interaction among nonkin strains. This study firmly establishes kin discrimination in a bacterial multicellular setting and suggests its potential effect on ecological interactions.

Project description:Succinic acid is an important acid which is used in medicine and pharmaceutical companies. Metabolically engineered Escherichia coli strain was used for the effective production of succinic acid using Cocos nucifera water, which contained 5.00 ± 0.02 g/L glucose, 6.10 ± 0.01 g /L fructose and 6.70 ± 0.02 g /L sucrose. Fermentation of C. nucifera water with E. coli M6PM produced a final concentration of 11.78 ± 0.02 g/L succinic acid and yield of 1.23 ± 0.01 mol/mol, 0.66 ± 0.01 g/g total sugars after 72 h dual-phase fermentation in M9 medium while modeled sugar was 0.38 ± 0.02 mol/mol total sugars. It resulted in 72% of the maximum theoretical yield of succinic acid. Here we show that novel substrate of C. nucifera water resulted in effective production of succinic acid. These investigations unveil the importance of C. nucifera water as a substrate for the production of biochemicals.

Project description:Multicellularity inherently involves a number of cooperative behaviors that are potentially susceptible to exploitation but can be protected by mechanisms such as kin discrimination. Discrimination of kin from non-kin has been observed in swarms of the bacterium Bacillus subtilis, but the underlying molecular mechanism has been unknown. We used genetic, transcriptomic, and bioinformatic analyses to uncover kin recognition factors in this organism. Our results identified many molecules involved in cell-surface modification and antimicrobial production and response. These genes varied significantly in expression level and mutation phenotype among B. subtilis strains, suggesting interstrain variation in the exact kin discrimination mechanism used. Genome analyses revealed a substantial diversity of antimicrobial genes present in unique combinations in different strains, with many likely acquired by horizontal gene transfer. The dynamic combinatorial effect derived from this plethora of kin discrimination genes creates a tight relatedness cutoff for cooperation that has likely led to rapid diversification within the species. Our data suggest that genes likely originally selected for competitive purposes also generate preferential interactions among kin, thus stabilizing multicellular lifestyles.

Project description:Limited digestion of the pyruvate dehydrogenase complex of Bacillus subtilis with either trypsin or chymotrypsin at 0 degrees C inhibited its ability to decarboxylate pyruvate and 2-oxoisovalerate oxidatively, without causing disassembly of the complex. The proteinases selectively cleaved the E1 alpha subunits to form two fragments of Mr 31500 and approx. 9500, as judged by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, both fragments remaining bound to the complex. Trypsin also caused a much slower cleavage of the E2 subunits, to form a fragment of apparent Mr 34000. The inhibition of overall dehydrogenase-complex activity was accompanied by the apparent loss of the pyruvate-driven and 2-oxoisovalerate-driven E1 activities, which was found to be due to a large increase in the Km for the 2-oxo acids: this change was correlated with the cleavage of the E1 alpha subunit.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description: Not available

Project description:Glucose is the most favorable carbon source for many bacteria, which have several glucose-responsive gene networks. Recently, we found that in Bacillus subtilis glucose induces the expression of the extracellular sigma factor genes sigX and sigM through the acetylation of CshA (RNA helicase), which associates with RNA polymerase (RNAP). We performed a transposon mutagenesis screen for mutants with no glucose induction (GI) of sigX-lacZ. While screening for such mutants, we recently found that the GI of sigX/M involves YlxR, a nucleoid-associated protein (NAP) that regulates nearly 400 genes, including metabolic genes. It has been shown that acetylated CshA positively regulates expression of ylxR-containing operon. Here, we report additional mutations in yqfO or tsaD required for the GI of sigX. YqfO contains a universally conserved domain with unknown function. YqfO and YlxR were found to regulate expression of the tsaEBD-containing operon. Mutational analysis using lacZ fusions revealed the adenine-rich cis-element for YlxR. TsaD is a component of the TsaEBD enzyme required for the synthesis of threonylcarbamoyl adenosine (t6A). The t6A modification of tRNA is universal across the three domains of life. Western blot analysis showed that the tsaD mutation in the presence of glucose reduced levels of soluble PdhA, PdhB, and PdhD, which are subunits of the pyruvate dehydrogenase complex (PDHc). This resulted in severely defective PDHc function and thus reduced concentrations of cellular acetyl-CoA, a reaction product of PDHc and plausible source for CshA acetylation. Thus, we discuss a suggested glucose-responsive system (GRS) involving self-reinforcing CshA acetylation. This self-reinforcing pathway may contribute to the maintenance of the acetyl-CoA pool for protein acetylation.

Project description:An assay based on the PCR has been developed to facilitate detection and identification of Bacillus cereus in foods. Three primers for the PCR have been designed within the sequence for cereolysin AB, a cytolytic determinant that encodes lecithin-hydrolyzing and hemolytic activities of B. cereus. With the PCR and hybridization, the specificity of the primers was tested with 39 isolates of the B. cereus group, with 17 other Bacillus spp., and with 21 non-Bacillus strains. Results demonstrate a high specificity of the three oligonucleotides for isolates of the B. cereus group. With a combined PCR-hybridization assay, the detection limit for B. cereus in artificially contaminated milk was 1 CFU/ml of milk.

Project description:We have cloned the operon coding for the Bacillus subtilis S complex, which has been proposed to be a component in protein secretion machinery. A lambda gt10 library of B. subtilis was screened with antiserum directed against the Staphylococcus aureus membrane-bound ribosome protein complex, which is homologous to the B. subtilis S complex. Two positive overlapping lambda clones were sequenced. The S-complex operon, 5 kilobases in size, was shown to contain four open reading frames and three putative promoters, which are located upstream of the first, the third, and the last gene. The four proteins encoded by the operon are 42, 36, 48, and 50 kilodaltons in size. All of these proteins were recognized by antisera separately raised against each protein of the S. aureus membrane-bound ribosome protein and B. subtilis S complexes, thus verifying the S-complex identity of the lambda clones. Sequence analysis revealed that all four proteins of the B. subtilis S complex are homologous to the four subunits of the human pyruvate dehydrogenase (PDH). Also, the N terminus of the 48-kilodalton protein was found to have 70% amino acid identity with the N-terminal 211 amino acids, determined so far, from the E2 subunit of B. stearothermophilus PDH. Furthermore, chromosomal mapping of the S-complex operon gave a linkage to a marker gene located close to the previously mapped B. subtilis PDH genes. Thus, the S complex is evidently identical to the B. subtilis PDH, which has been shown to contain four subunits with molecular weights very similar to those of the S complex. Therefore, we propose that the S complex is not a primary component of protein secretion.