Department of Chemistry and Biochemistry, UCLA, Los Angeles, California 90095, USA.
Molecular Biology Institute, UCLA, Los Angeles, California 90095, USA.
RNA. 2021 Dec;27(12):1545-1556. doi: 10.1261/rna.078880.121. Epub 2021 Sep 8.
The expression of bromodomain-containing proteins that regulate chromatin structure and accessibility must be tightly controlled to ensure the appropriate regulation of gene expression. In the yeast , Bromodomain Factor 2 ( expression is extensively regulated post-transcriptionally during stress by RNase III-mediated decay (RMD), which is triggered by cleavage of the mRNA in the nucleus by the RNase III homolog Rnt1p. Previous studies have shown that RMD-mediated down-regulation of is hyperactivated in osmotic stress conditions, yet the mechanisms driving the enhanced nuclear cleavage of RNA under these conditions remain unknown. Here, we show that RMD hyperactivation can be detected in multiple stress conditions that inhibit mRNA export, and that Rnt1p remains primarily localized in the nucleus during salt stress. We show that globally inhibiting mRNA nuclear export by anchoring away mRNA biogenesis or export factors out of the nucleus can recapitulate RMD hyperactivation in the absence of stress. RMD hyperactivation requires Rnt1p nuclear localization but does not depend on the gene endogenous promoter, and its efficiency is affected by the structure of the stem-loop cleaved by Rnt1p. Because multiple stress conditions have been shown to mediate global inhibition of mRNA export, our results suggest that the hyperactivation of RMD is primarily the result of the increased nuclear retention of the mRNA during stress.
调控染色质结构和可及性的溴结构域蛋白的表达必须受到严格控制,以确保基因表达的适当调节。在酵母中,Bromodomain Factor 2(表达受到广泛的转录后调控,在应激条件下通过 RNase III 介导的降解(RMD)进行调控,这是由 RNase III 同源物 Rnt1p 在核内切割 mRNA 触发的。先前的研究表明,在渗透胁迫条件下,RMD 介导的 下调被过度激活,但在这些条件下驱动 RNA 核内切割增强的机制仍不清楚。在这里,我们表明 RMD 过度激活可以在抑制 mRNA 输出的多种应激条件下检测到,并且在盐胁迫期间 Rnt1p 主要定位于核内。我们表明,通过将 mRNA 生物发生或输出因子锚定在核外,全局抑制 mRNA 核输出可以在没有应激的情况下再现 RMD 过度激活。RMD 过度激活需要 Rnt1p 的核定位,但不依赖于 Rnt1p 切割的茎环结构的内源性启动子,其效率受 Rnt1p 切割的茎环结构的影响。由于多种应激条件已被证明可以介导全局抑制 mRNA 输出,我们的结果表明,RMD 的过度激活主要是应激过程中 mRNA 在核内滞留增加的结果。
