Project description:Methanolic fractions of supernatants of cultures of B. subtilis wild strains. Raw dataset and feature finding project for IIN protocol, July 2019.

Project description:In this work we conducted Term-seq on Wild Type B. subtilis, and strains compromosing all logical mutations in all combinations of the genes that encode for NusA, NusG, and Rho, where we developed the first transcription termination atlas. We used this atlas to find that Rho can stimulate intrinsic termination in B. subtilis and we recapitulated this finding in vitro to dissect the mechanism.

Project description:We determined whether we could identify clusters of children with critical asthma by functional immunophenotyping using an intracellular viral analog stimulus. We performed a single-center, prospective, observational cohort study of 43 children ages 6 – 17 years admitted to a pediatric intensive care unit for an asthma attack between July 2019 to February 2021.

Project description:planktonic and sediment bacteria in July 2019

Project description:cytoplasmic extract of Bacillus subtilis wild type control (untreated) separated by non-reducing SDS-PAGE, lane cut into 10 fractions, fraction 1 in-gel-digested

Project description:We determined whether we could identify clusters of children with critical asthma by plasma cytokine concentration. Differences in gene expression between the two clusters were analyzed using a targeted Nanostring immunology array. We performed a single-center, prospective, observational cohort study of 64 children ages 6 – 17 years admitted to a pediatric intensive care unit for an asthma attack between July 2019 to February 2021.

Project description:Apis mellifera workers in temperate climates display two castes; short lived summer bees that engage in nursing, hive maintenance and foraging, and long lived winter bees (diutinus bees) which remain within the hive and are essential for thermoregulation. Label free quantitative proteomic analysis was conducted on A. mellifera workers sampled from July to October 2019 to compare the proteomes of workers as the colony progresses through the year. Proteomic analysis revealed a shift in protein expression in workers in September and October in comparison to July and August samples. Workers samples in September and October had a higher abundance of proteins associated with oxidative phosphorylation and storage proteins such as hexamerin. Interestingly, a shift in protein expression was detected in newly emerged bees between July to October, providing evidence that workers have adapted to emerge with a different protein profile in preparation for the winter months.

Project description:Background: Microbial gene expression is to a large extend determined by environmental growth conditions. Differential gene expression analysis between two conditions has been frequently used to reveal regulatory networks and to assign physiological function to unknown genes. In nature, microorganisms cohabit however these interactions have been rarely studied and reproduced in laboratory set-up. Thus to quantitatively explore the genome-wide responses of microbial interaction, we co-cultivated Penicillium chrysogenum and Bacillus subtilis in chemostat culture. Results: Time course expression analysis of P. chrysogenum to co-cultivation with B. subtilis was carried out to understand the natural responses of P. chrysogenum to prokaryotes. Steady state chemostats of P. chrysogenum in non-B-lactam producing conditions was pulsed with B. subtilis and co-cultivation was followed for 72 hours. The dynamic physiological and transcriptional responses of P. chrysogenum in mixed culture were monitored. B. subtilis outcompeted growth of P. chrysogenum resulting in an increased B. subtilis biomass by more than three fold of its original size and a reduction in P. chrysogenum biomass to half of its original size after 72 h of mixed culture. Genes of the penicillin pathway, synthesis of the side-chain and precursors were overall unresponsive to the presence of B. subtilis. Moreover Penicillium polyketide synthase and nonribosomal peptide synthetase genes either remained silent or down-regulated, whereas genes responsible for protein synthesis, metabolism, energy conservation, respiration and transport were upregulated in the presence of B. subtilis. Among highly responsive genes, two putative B-1,3 endoglucanase (mutanase) genes viz Pc12g07500 and Pc12g13330 were upregulated by more than 15-fold and 8-fold respectively. Measurement of enzyme activity in the supernatant of mixed culture confirmed that the co-cultivation with B. subtilis induced mutanase production in P. chrysogenum. Mutanase activity was not observed in pure cultures of P. chrysogenum and B. subtilis or when P. chrysogenum was co-cultured with B. subtilis supernatant or heat inactivated B. subtilis cells. However, mutanase production was observed in cultures of P. chrysogenum pulsed with filter sterilized supernatants from mixed cultures P. chrysogenum and B. subtilis. Heterologous expression of Pc12g07500 and Pc12g13330 genes in Saccharomyces cerevisiae confirmed that at least Pc12g07500 encoded an B-1,3 endoglucanase. Conclusion: Time course transcriptional profiling of P. chrysogenum revealed several differentially expressed genes during mixed culture, potentially reflecting interactions between the eukaryotic and the prokaryotic systems. M-oM-^AM-!-1,3 endoglucanase produced by P. chrysogenum against B. subtilis signals may have application in improving the efficacy of antibiotics by degrading exopolysacchride biofilms of pathogenic bacteria. The objective of the present study is to investigate the response of P. chrysogenum to co-cultivation with B. subtilis. To trigger an interaction specific behaviour, steady state chemostat of P. chrysogenum Wisconsin 54-1255 was pulsed with B. subtilis. The dynamic, transcriptional and physiological responses of P. chrysogenum in mixed culture were monitored and analyzed. Several differentially expressed genes potentially reflected interactions between the eukaryotic and the prokaryotic systems. To test whether any bacterial signaling molecules are responsible for differential expression of selected fungal genes, P. chrysogenum cultures were inoculated with supernatant of B. subtilis culture, supernatants from mixed culture and with heat-inactivated B. subtilis. The specific transcriptional responses identified using microarray was verified by analysis of fermentation broth and functional characterization by expression of selected genes in S. cerevisiae.

Project description:To obtain an insight into the in vivo dynamics of RNA polymerase (RNAP) on the B. subtilis genome, we analyzed the distribution of ?A and ? subunits of RNAP and the NusA elongation factor on the genome in exponentially growing cells, using the ChAP (Chromatin Affinity Precipitation)-chip method. In contrast to E. coli RNAP, which often accumulates at the promoter-proximal region, B. subtilis RNAP is evenly distributed from the promoter to the coding sequences in the majority of genes. This finding suggests that B. subtilis RNAP recruited to the promoter promptly translocates away from the promoter to form the elongation complex. We detected RNAP accumulation in the promoter-proximal regions of some genes, most of which are attributed to transcription attenuation systems in the leader region. Our findings suggest that the differences in RNAP behavior during initiation and early elongation steps between E. coli and B. subtilis result in distinct strategies for post-initiation control of transcription. The E. coli mechanism involves trapping at the promoter and promoter-proximal pausing of RNAP in addition to transcription attenuation, whereas transcription attenuation in leader sequences is mainly employed in B. subtilis. Wild-type strain, Bacillus subtilis 168, was also used for RNA and genomic DNA extraction and analysis - RNA data was divided by genome DNA data to normalize (1) PCR bias and (2) copy number of RNA molecule per genome for multi-copy genome of exponentially growing bacteria.

Project description:We report the transcriptional changes associated with toxic effects of methanolic coal dust extract on normal zebrafish development. Early exposure of wild type embryos at 4 hpf to coal dust extract led to 3 groups of malformed phenotypes - tail deformity (P1), deformed yolk (P2) and smaller embryos with extruded yolks (P3). RNAseq of each phenotypic group revealed changes in genes involved in xenobiotic metabolism, intermediate filament composition, oxidation-reduction processes, calcium ion binding, focal adhesion and the ECM-receptor interaction pathway.