论文题目: | Negative Regulation of Ectoine Uptake and Catabolism in Sinorhizobium meliloti: Characterization of the EhuR Gene |
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作者: | Yu, Qinli Cai, Hanlin Zhang, Yanfeng He, Yongzhi Chen, Lincai Merritt, Justin Zhang, Shan Dong, Zhiyang |
联系作者: | |
刊物名称: | J Bacteriol |
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年份: | 2016 |
影响因子: | 2.936 |
论文下载: | 下载地址 |
摘要: | Ectoine has osmoprotective effects on Sinorhizobium meliloti that differ from its effects in other bacteria. Ectoine does not accumulate in S. meliloti cells; instead, it is degraded. The products of the ehuABCD-eutABCDE operon were previously discovered to be responsible for the uptake and catabolism of ectoine in S. meliloti However, the mechanism by which ectoine is involved in the regulation of the ehuABCD-eutABCDE operon remains unclear. ehuR, which is upstream of and oriented in the same direction as the ehuABCD-eutABCDE operon, encodes a member of the MocR/GntR family of transcriptional regulators. Quantitative RT-PCR and promoter-lacZ reporter fusion experiments revealed that EhuR represses the transcription of the ehuABCD-eutABCDE operon, but this repression is inhibited in the presence of ectoine. Electrophoretic mobility shift and DNase I footprinting assays revealed that EhuR bound specifically to the DNA regions overlapping the -35 region of the ehuA promoter and the +1 region of the ehuR promoter. Surface plasmon resonance further demonstrated a direct interaction between EhuR and both promoters, although EhuR was found to have a higher affinity for the ehuA promoter than for the ehuR promoter. In vitro, DNA binding by EhuR could be directly inhibited by a degradation product of ectoine. Our work demonstrates that EhuR is an important negative transcriptional regulator involved in the regulation of ectoine uptake and catabolism and is likely regulated by one or more end products of ectoine catabolism. IMPORTANCE: Sinorhizobium meliloti is an important soil bacterium, that displays symbiotic interactions with legume hosts. Ectoine serves as a key osmoprotectant for S. meliloti However, ectoine does not accumulate in the cell; rather, it is degraded. In this study, we characterized the transcriptional regulation of the operon responsible for ectoine uptake and catabolism in S. meliloti We identified and characterized the transcriptional repressor EhuR, which is the first MocR/GntR family member found to be involved in the regulation of compatible solute uptake and catabolism. More importantly, we demonstrated for the first time that an ectoine catabolic end product could modulate EhuR DNA binding activity. Therefore, this work provides new insights into the unique mechanism of ectoine-induced osmoprotection in S. meliloti. |
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