影响酿酒酵母中[PSI+]朊病毒从头出现的遗传和环境因素。

Genetic and environmental factors affecting the de novo appearance of the [PSI+] prion in Saccharomyces cerevisiae.

作者信息

Derkatch I L, Bradley M E, Zhou P, Chernoff Y O, Liebman S W

机构信息

Department of Biological Sciences, University of Illinois at Chicago 60607, USA.

出版信息

Genetics. 1997 Oct;147(2):507-19. doi: 10.1093/genetics/147.2.507.

DOI:10.1093/genetics/147.2.507

PMID:9335589

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1208174/

Abstract

It has previously been shown that yeast prion [PSI+] is cured by GuHCl, although reports on reversibility of curing were contradictory. Here we show that GuHCl treatment of both [PSI+] and [psi-] yeast strains results in two classes of [psi-] derivatives: Pin+, in which [PSI+] can be reinduced by Sup35p overproduction, and Pin-, in which overexpression of the complete SUP35 gene does not lead to the [PSI+] appearance. However, in both Pin+ and Pin- derivatives [PSI+] is reinduced by overproduction of a short Sup35p N-terminal fragment, thus, in principle, [PSI+] curing remains reversible in both cases. Neither suppression nor growth inhibition caused by SUP35 overexpression in Pin+ [psi-] derivatives are observed in Pin- [psi-] derivatives. Genetic analyses show that the Pin+ phenotype is determined by a non-Mendelian factor, which, unlike the [PSI+] prion, is independent of the Sup35p N-terminal domain. A Pin- [psi-] derivative was also generated by transient inactivation of the heat shock protein, Hsp104, while [PSI+] curing by Hsp104 overproduction resulted exclusively in Pin+ [psi-] derivatives. We hypothesize that in addition to the [PSI+] prion-determining domain in the Sup35p N-terminus, there is another self-propagating conformational determinant in the C-proximal part of Sup35p and that this second prion is responsible for the Pin+ phenotype.

摘要

此前已有研究表明，酵母朊病毒[PSI+]可被盐酸胍（GuHCl）治愈，尽管关于治愈可逆性的报道相互矛盾。在此我们表明，用GuHCl处理[PSI+]和[psi-]酵母菌株均会产生两类[psi-]衍生物：Pin+，其中通过过量表达Sup35p可重新诱导出[PSI+]；以及Pin-，其中完整SUP35基因的过表达不会导致[PSI+]出现。然而，在Pin+和Pin-衍生物中，通过过量表达短的Sup35p N端片段均可重新诱导出[PSI+]，因此原则上，在这两种情况下[PSI+]的治愈仍具有可逆性。在Pin- [psi-]衍生物中未观察到Pin+ [psi-]衍生物中因SUP35过表达引起的抑制作用或生长抑制。遗传分析表明，Pin+表型由一个非孟德尔因子决定，该因子与[PSI+]朊病毒不同，独立于Sup35p N端结构域。通过热休克蛋白Hsp104的瞬时失活也产生了一种Pin- [psi-]衍生物，而通过过量表达Hsp104治愈[PSI+]仅产生Pin+ [psi-]衍生物。我们推测，除了Sup35p N端的[PSI+]朊病毒决定结构域外，在Sup35p的C端近端还有另一个自我传播的构象决定因子，并且这种第二种朊病毒负责Pin+表型。

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本文引用的文献

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