The gram-positive soil bacterium Bacillus subtilis often faces increases in the salinity in its natural habitats. A transcriptional profiling approach was utilized to investigate both the initial reaction to a sudden increase in salinity elicited by the addition of 0.4 M NaCl and the cellular adaptation reactions to prolonged growth at high salinity (1.2 M NaCl). Following salt shock, a sigB mutant displayed immediate and transient induction and repression of 75 and 51 genes, respectively. Continuous propagation of this strain in the presence of 1.2 M NaCl triggered the induction of 123 genes and led to the repression of 101 genes. In summary, our studies revealed (i) an immediate and transient induction of the SigW regulon following salt shock, (ii) a role of the DegS/DegU two-component system in sensing high salinity, (iii) a high-salinity-mediated iron limitation, and (iv) a repression of chemotaxis and motility genes by high salinity, causing severe impairment of the swarming capability of B. subtilis cells. Initial adaptation to salt shock and continuous growth at high salinity share only a limited set of induced and repressed genes. This finding strongly suggests that these two phases of adaptation require distinctively different physiological adaptation reactions by the B. subtilis cell. The large portion of genes with unassigned functions among the high-salinity-induced or -repressed genes demonstrates that major aspects of the cellular adaptation of B. subtilis to high salinity are unexplored so far.
The soil bacterium Bacillus subtilis frequently encounters a reduction in temperature in its natural habitats. Here, a combined transcriptomic and proteomic approach has been used to analyse the adaptational responses of B. subtilis to low temperature. Propagation of B. subtilis in minimal medium at 15 6C triggered the induction of 279 genes and the repression of 301 genes in comparison to cells grown at 37 6C. The analysis thus revealed profound adjustments in the overall gene expression profile in chill-adapted cells. Important transcriptional changes in low-temperature-grown cells comprise the induction of the SigB-controlled general stress regulon, the induction of parts of the early sporulation regulons (SigF, SigE and SigG) and the induction of a regulatory circuit (RapA/PhrA and Opp) that is involved in the fine-tuning of the phosphorylation status of the Spo0A response regulator. The analysis of chill-stress-repressed genes revealed reductions in major catabolic (glycolysis, oxidative phosphorylation, ATP synthesis) and anabolic routes (biosynthesis of purines, pyrimidines, haem and fatty acids) that likely reflect the slower growth rates at low temperature. Low-temperature repression of part of the SigW regulon and of many genes with predicted functions in chemotaxis and motility was also noted. The proteome analysis of chill-adapted cells indicates a major contribution of post-transcriptional regulation phenomena in adaptation to low temperature. Comparative analysis of the previously reported transcriptional responses of cold-shocked B. subtilis cells with this data revealed that cold shock and growth in the cold constitute physiologically distinct phases of the adaptation of B. subtilis to low temperature.
SummaryStilbene synthase genes (STS) have previously been used to enhance disease resistance in plants. In order to study the effects of modified STS expression patterns in plants, heterologous promoters were fused to an STS gene and the chimeric genes were transferred to tobacco. Very high constitutive expression of STS mediated by a duplicated upstream region of the 35S RNA promoter from CaMV affected secondary biosynthetic pathways. STS overexpression caused altered flower pigmentation and male sterility, probably due to competition between the introduced STS and the endogenous chalcone synthase for the substrates 4-coumaroyl CoA and malonyl CoA. Furthermore, tobacco plants with tapetum-specific STS expression were male-sterUe. Thus, STS genes are promising tools in strategies for engineering altered flower colours and the development of a novel hybrid seed system.
Pseudomonas syringae pv. glycinea PG4180 causes bacterial blight of soybean and produces the phytotoxin coronatine (COR) in a temperature-dependent manner. COR consists of a polyketide, coronafacic acid (CFA), and an amino acid derivative, coronamic acid, and is produced optimally at 18 degrees C whereas no detectable synthesis occurs at 28 degrees C. We investigated the impact of temperature on PG4180 during compatible and incompatible interactions with soybean and tobacco plants, respectively. After spray inoculation, PG4180 caused typical bacterial blight symptoms on soybean plants when the bacteria were grown at 18 degrees C prior to inoculation but not when derived from cultures grown at 28 degrees C. The disease outcome was quantified by determination of bacterial populations in planta. The temperature effect was not observed when PG4180 was artificially infiltrated into soybean leaves, indicating that the pre-inoculation temperature and phytotoxin synthesis were important for bacterial invasion via natural plant openings. In the incompatible interaction, PG4180 elicited the hypersensitive response (HR) on tobacco plants regardless of the bacterial pre-inoculation temperature. However, the HR was significantly delayed when tobacco plants were treated with cells of the CFA-overproducing derivative, PG4180.N9, which were derived from cultures grown at 18 degrees C, compared with parallels incubated at 28 degrees C. CFA biosynthesis by PG4180.N9 was optimal at 18 degrees C and negligible at 28 degrees C. The impact of CFA synthesis on the HR was studied with different growth media, mutants, and transconjugants of PG4180, indicating that the amount of synthesized CFA but not that of COR influenced the outcome of the HR. Feeding experiments with purified coronafacoyl compounds suggested that the observed delay of the HR was mediated by CFA, shedding further light on CFA's putative role as a molecular mimic of the plant signaling molecule, jasmonic acid.
The plant-pathogenic bacterium Pseudomonas syringae pv. glycinea PG4180.N9 synthesizes high levels of the polyketide phytotoxin coronatine (COR) at 18°C, whereas no detectable toxin is produced at 28°C. Previously, we reported that the temperature-sensitive activation of three promoters within the COR biosynthetic gene cluster might explain thermoregulation of COR biosynthesis. The present study was aimed at furthering our understanding of the transcriptional as well as the posttranslational effects of temperature on expression ofcmaB, which encodes an enzyme involved in COR biosynthesis. Transcriptional fusions using a promoterless glucuronidase gene and Northern blot analyses were used to monitor promoter activities and transcript abundance for the cmaABT operon during bacterial growth at 18 and 28°C. Promoter activity and transcription rates were maximal when cells were incubated at 18°C and sampled at mid-logarithmic phase. Transcription declined moderately during the transition to stationary phase but remained higher at 18°C than at 28°C. Western blot analysis indicated that CmaB accumulated in the late stationary phase of P. syringae cultures grown at 18°C but not in cultures incubated at 28°C. Temperature shift experiments indicated that CmaB stability was more pronounced at 18°C than at 28°C. Although temperature has a strong impact on transcription of COR biosynthetic genes, we propose that thermoregulation of protein stability might also control COR synthesis.
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