Vidhyadhar Nandana, Nadra Al-Husini, Arti Vaishnav, Kulathungage H Dilrangi, Jared M Schrader
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引用次数: 0
摘要
RNase E是细菌中最常见的RNA衰变核酸酶,可设定全局mRNA衰变速率,并为RNA降解体复合物和BR体的形成提供支架。为了正确设定全球 mRNA 的衰变速率,研究发现大肠杆菌和邻近γ-蛋白细菌的 RNase E 可通过其 mRNA 的 5' UTR 的衰变来自动调节 RNase E 的水平。虽然在 Rfam 数据库中的其他细菌群中不存在 5' UTR,但我们发现α-新月杆菌 RNase E 含有类似的 5' UTR 结构,这种结构促进了 RNase E 的自动调节。在这两种细菌中,RNase E 的 C 端 IDR 是发生适当的自动调节所必需的,而且该 IDR 也是 RNase E 相分离、产生 BR 体所必需和足够的。利用体外纯化的 RNase E,我们发现 IDR 促进相分离的能力与 5' UTR 裂解的增强相关,这表明 RNase E 与 5' UTR 的相分离增强了自动调节。最后,通过生长竞争实验,我们发现具有自动调节能力的菌株能迅速击败具有 5' UTR 突变且不能自动调节的菌株,这表明自动调节能促进细胞的最佳适应性。
Caulobacter crescentus RNase E condensation contributes to autoregulation and fitness.
RNase E is the most common RNA decay nuclease in bacteria, setting the global mRNA decay rate and scaffolding formation of the RNA degradosome complex and BR-bodies. To properly set the global mRNA decay rate, RNase E from Escherichia coli and neighboring γ-proteobacteria were found to autoregulate RNase E levels via the decay of its mRNA's 5' untranslated region (UTR). While the 5' UTR is absent from other groups of bacteria in the Rfam database, we identified that the α-proteobacterium Caulobacter crescentus RNase E contains a similar 5' UTR structure that promotes RNase E autoregulation. In both bacteria, the C-terminal intrinsically disordered region (IDR) of RNase E is required for proper autoregulation to occur, and this IDR is also necessary and sufficient for RNase E to phase-separate, generating BR-bodies. Using in vitro purified RNase E, we find that the IDR's ability to promote phase separation correlates with enhanced 5' UTR cleavage, suggesting that phase separation of RNase E with the 5' UTR enhances autoregulation. Finally, using growth competition experiments, we find that a strain capable of autoregulation rapidly outcompetes a strain with a 5' UTR mutation that cannot autoregulate, suggesting autoregulation promotes optimal cellular fitness.
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