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剪接多腺苷酸化因子 Cft1 和 SPX 结构域蛋白是裂殖酵母肌醇焦磷酸毒性的作用因子。

Cleavage-Polyadenylation Factor Cft1 and SPX Domain Proteins Are Agents of Inositol Pyrophosphate Toxicosis in Fission Yeast.

机构信息

Department of Microbiology and Immunology, Weill Cornell Medical College, New York, New York, USA.

Molecular Biology Program, Sloan-Kettering Institute, New York, New York, USA.

出版信息

mBio. 2022 Feb 22;13(1):e0347621. doi: 10.1128/mbio.03476-21. Epub 2022 Jan 11.

DOI:10.1128/mbio.03476-21
PMID:35012333
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8749416/
Abstract

Inositol pyrophosphate (IPP) dynamics govern expression of the fission yeast phosphate homeostasis regulon via their effects on lncRNA-mediated transcription interference. The growth defects (ranging from sickness to lethality) elicited by fission yeast mutations that inactivate IPP pyrophosphatase enzymes are exerted via the agonistic effects of too much 1,5-IP8 on RNA 3'-processing and transcription termination. To illuminate determinants of IPP toxicosis, we conducted a genetic screen for spontaneous mutations that suppressed the sickness of Asp1 pyrophosphatase mutants. We identified a missense mutation, C823R, in the essential Cft1 subunit of the cleavage and polyadenylation factor complex that suppresses even lethal Asp1 IPP pyrophosphatase mutations, thereby fortifying the case for 3'-processing/termination as the target of IPP toxicity. The suppressor screen also identified Gde1 and Spx1 (SPAC6B12.07c), both of which have an IPP-binding SPX domain and both of which are required for lethality elicited by Asp1 mutations. A survey of other SPX proteins in the proteome identified the Vtc4 and Vtc2 subunits of the vacuolar polyphosphate polymerase as additional agents of IPP toxicosis. Gde1, Spx1, and Vtc4 contain enzymatic modules (glycerophosphodiesterase, RING finger ubiquitin ligase, and polyphosphate polymerase, respectively) fused to their IPP-sensing SPX domains. Structure-guided mutagenesis of the IPP-binding sites and the catalytic domains of Gde1 and Spx1 indicated that both modules are necessary to elicit IPP toxicity. Whereas Vtc4 polymerase catalytic activity is required for IPP toxicity, its IPP-binding site is not. Epistasis analysis, transcriptome profiling, and assays of Pho1 expression implicate Spx1 as a transducer of IP8 signaling to the 3'-processing/transcription termination machinery. Impeding the catabolism of the inositol pyrophosphate (IPP) signaling molecule IP8 is cytotoxic to fission yeast. Here, by performing a genetic suppressor screen, we identified several cellular proteins required for IPP toxicosis. Alleviation of IPP lethality by a missense mutation in the essential Cft1 subunit of the cleavage and polyadenylation factor consolidates previous evidence that toxicity results from IP8 action as an agonist of RNA 3'-processing and transcription termination. Novel findings are that IP8 toxicity depends on IPP-sensing SPX domain proteins with associated enzymatic functions: Gde1 (glycerophosphodiesterase), Spx1 (ubiquitin ligase), and Vtc2/4 (polyphosphate polymerase). The effects of Spx1 deletion on phosphate homeostasis imply a role for Spx1 in communicating an IP8-driven signal to the transcription and RNA processing apparatus.

摘要

肌醇六磷酸(IPP)动力学通过其对长链非编码 RNA 介导的转录干扰的影响来控制裂殖酵母磷酸盐稳态调控基因的表达。通过对使 IPP 焦磷酸酶失活的裂殖酵母突变体的生长缺陷(从生病到致死)的研究发现,太多的 1,5-IPP8 对 RNA 3'加工和转录终止有激动作用。为了阐明 IPP 毒性的决定因素,我们进行了自发突变的遗传筛选,以抑制 Asp1 焦磷酸酶突变体的病态。我们在必需的 Cft1 亚基中发现了一个错义突变 C823R,该突变抑制了即使是致命的 Asp1 IPP 焦磷酸酶突变,从而加强了 3'加工/终止是 IPP 毒性的靶标的说法。抑制筛选还鉴定了 Gde1 和 Spx1(SPAC6B12.07c),它们都具有 IPP 结合的 SPX 结构域,并且都需要 Asp1 突变引起的致死性。对蛋白质组中的其他 SPX 蛋白的调查发现,液泡多聚磷酸盐聚合酶的 Vtc4 和 Vtc2 亚基是 IPP 毒性的另一种物质。Gde1、Spx1 和 Vtc4 分别含有酶模块(甘油磷酸二酯酶、RING 指泛素连接酶和多聚磷酸酶)融合到它们的 IPP 感应 SPX 结构域。对 Gde1 和 Spx1 的 IPP 结合位点和催化结构域进行结构导向诱变表明,两个模块都需要引发 IPP 毒性。虽然 Vtc4 聚合酶的催化活性是 IPP 毒性所必需的,但它的 IPP 结合位点不是必需的。表型分析、转录组分析和 Pho1 表达分析表明,Spx1 作为 IP8 信号向 3'加工/转录终止机制的转导子。 抑制肌醇焦磷酸盐 (IPP) 信号分子 IP8 的分解代谢对裂殖酵母具有细胞毒性。在这里,通过进行遗传抑制筛选,我们鉴定了几种细胞蛋白,这些蛋白在 IPP 毒性中是必需的。必需的 Cft1 亚基中错义突变的切割和多聚腺苷酸化因子的缓解 IPP 致死性,巩固了先前的证据,即毒性是由 IP8 作为 RNA 3'加工和转录终止的激动剂的作用引起的。新的发现是,IPP 毒性取决于具有相关酶功能的 IPP 感应 SPX 结构域蛋白:Gde1(甘油磷酸二酯酶)、Spx1(泛素连接酶)和 Vtc2/4(多聚磷酸盐聚合酶)。Spx1 缺失对磷酸盐稳态的影响暗示了 Spx1 在将 IP8 驱动的信号传递给转录和 RNA 加工装置方面的作用。

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