Ften using B. subtilis as a model organism [7,8]. In this report

Ften using B. CAL120 chemical information subtilis as a model organism [7,8]. In this report, we combined transcriptomic analyses with studies of the genetic and physiological responses of B. subtilis to fusaricidins. The profiling revealed that fusaricidins strongly activated SigA, a protein that regulates RNA polymerase to control cell growth. Kinetic analyses of transcriptional responses showed that differentially regulated genes represent several metabolic pathways, including those regulating proline levels, ion transport, amino acid transport, and nucleotide metabolism.Materials and Methods Bacterial Strain and MediaB. subtilis 168 was stored in our laboratory. LB (Luria-Bertani) medium (10-g tryptone, 5-g yeast extract, and 10-g NaCl per liter of distilled H2O) was used to grow B. subtilis cultures.Mechanisms of Fusaricidins to Bacillus subtilisFigure 1. Time points of the transcriptome experiments. A and B are duplicate control samples; D and E are duplicate INCB039110 site samples treated with fusaricidin after the 7-h culture of B. subtilis 168. doi:10.1371/journal.pone.0050003.gFigure 2. Protein-protein interaction networks at 5 min using the string analysis. doi:10.1371/journal.pone.0050003.gMechanisms of Fusaricidins to Bacillus subtilisFigure 3. The rapid-response pathways of B. subtilis to the fusaricidin treatment. Fus, fusaricidin. The red columns indicate the hypothetical proteins translated from the genes in the corresponding blue ellipses. doi:10.1371/journal.pone.0050003.gGrowth ConditionsIn our experiments, B. subtilis 168 was used, stored at 220uC in 25 1313429 glycerol. It was inoculated in LB medium and grown overnight at 37uC and 200 rpm. Then, the seed culture was used to inoculate 10 mL of fresh LB medium. To study the effect of fusaricidin on B. subtilis 168 cells and the corresponding transcriptomic profiles, fusaricidin (1.713 mg/mL) was added at an OD600 of approximately 1.30 at the exponential growth phase (7-h culture period). Two independently cultured replicates were performed, respectively. Samples were taken to measure the OD600 at designated time points (5, 20, and 170 min) and to extract RNA for the following experiments.MISP AnalysisThe differentially expressed genes chosen with a coefficient of variation .0.1 were distributed over the MIPS functional categories for their classification (http://mips.gsf.de/projects/).Results and Discussion B. subtilis 168 Cell Growth was Inhibited by FusaricidinChanges in cell growth (measured as change in cell concentration) were studied for 3.5 h after the addition of fusaricidin (,1 minimal inhibitory concentration [MIC], 1.713 1407003 mg/mL). As shown in Figure 1, the replicates of the cells treated with fusaricidin grew more slowly; by contrast, the replication of the control was continuous. This indicates that fusaricidin is toxic to B. subtilis 168. The influence of fusaricidin on the transcriptome of logarithmically growing B. subtilis cells was quantified using fluorescent DNA microarray technology. Changes in gene expression were studied by the addition of fusaricidin. Samples were taken at 5, 20, and 170 min after the addition of fusaricidin and compared with an untreated control sample taken at 5 min. When a 3-fold change (p value log ratio ,0.05) relative to the control was used as a cutoff value, 18, 415, and 415 genes (approximately 0.44 , 10.11 , and 10.11 of all B. subtilis genes, respectively) were identified as significantly induced by fusaricidin at the respective time points.RNA Preparation and Micro.Ften using B. subtilis as a model organism [7,8]. In this report, we combined transcriptomic analyses with studies of the genetic and physiological responses of B. subtilis to fusaricidins. The profiling revealed that fusaricidins strongly activated SigA, a protein that regulates RNA polymerase to control cell growth. Kinetic analyses of transcriptional responses showed that differentially regulated genes represent several metabolic pathways, including those regulating proline levels, ion transport, amino acid transport, and nucleotide metabolism.Materials and Methods Bacterial Strain and MediaB. subtilis 168 was stored in our laboratory. LB (Luria-Bertani) medium (10-g tryptone, 5-g yeast extract, and 10-g NaCl per liter of distilled H2O) was used to grow B. subtilis cultures.Mechanisms of Fusaricidins to Bacillus subtilisFigure 1. Time points of the transcriptome experiments. A and B are duplicate control samples; D and E are duplicate samples treated with fusaricidin after the 7-h culture of B. subtilis 168. doi:10.1371/journal.pone.0050003.gFigure 2. Protein-protein interaction networks at 5 min using the string analysis. doi:10.1371/journal.pone.0050003.gMechanisms of Fusaricidins to Bacillus subtilisFigure 3. The rapid-response pathways of B. subtilis to the fusaricidin treatment. Fus, fusaricidin. The red columns indicate the hypothetical proteins translated from the genes in the corresponding blue ellipses. doi:10.1371/journal.pone.0050003.gGrowth ConditionsIn our experiments, B. subtilis 168 was used, stored at 220uC in 25 1313429 glycerol. It was inoculated in LB medium and grown overnight at 37uC and 200 rpm. Then, the seed culture was used to inoculate 10 mL of fresh LB medium. To study the effect of fusaricidin on B. subtilis 168 cells and the corresponding transcriptomic profiles, fusaricidin (1.713 mg/mL) was added at an OD600 of approximately 1.30 at the exponential growth phase (7-h culture period). Two independently cultured replicates were performed, respectively. Samples were taken to measure the OD600 at designated time points (5, 20, and 170 min) and to extract RNA for the following experiments.MISP AnalysisThe differentially expressed genes chosen with a coefficient of variation .0.1 were distributed over the MIPS functional categories for their classification (http://mips.gsf.de/projects/).Results and Discussion B. subtilis 168 Cell Growth was Inhibited by FusaricidinChanges in cell growth (measured as change in cell concentration) were studied for 3.5 h after the addition of fusaricidin (,1 minimal inhibitory concentration [MIC], 1.713 1407003 mg/mL). As shown in Figure 1, the replicates of the cells treated with fusaricidin grew more slowly; by contrast, the replication of the control was continuous. This indicates that fusaricidin is toxic to B. subtilis 168. The influence of fusaricidin on the transcriptome of logarithmically growing B. subtilis cells was quantified using fluorescent DNA microarray technology. Changes in gene expression were studied by the addition of fusaricidin. Samples were taken at 5, 20, and 170 min after the addition of fusaricidin and compared with an untreated control sample taken at 5 min. When a 3-fold change (p value log ratio ,0.05) relative to the control was used as a cutoff value, 18, 415, and 415 genes (approximately 0.44 , 10.11 , and 10.11 of all B. subtilis genes, respectively) were identified as significantly induced by fusaricidin at the respective time points.RNA Preparation and Micro.