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mSphere. 2020 Feb 12;5(1):e00979-19. doi: 10.1128/mSphere.00979-19.
3
Substitution of cysteines in the yeast viral killer toxin K1 precursor reveals novel insights in heterodimer formation and immunity.半胱氨酸取代酵母病毒杀伤毒素 K1 前体中的半胱氨酸揭示了异二聚体形成和免疫的新见解。
Sci Rep. 2019 Sep 11;9(1):13127. doi: 10.1038/s41598-019-49621-z.
4
A Rapid Method for Sequencing Double-Stranded RNAs Purified from Yeasts and the Identification of a Potent K1 Killer Toxin Isolated from .从酵母中提取的双链 RNA 的快速测序方法及从. 中分离出的强 K1 杀伤毒素的鉴定
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K66 Killer System Evidences Expanded Assortment of Helper and Satellite Viruses.K66 杀手系统证据扩展了辅助和卫星病毒的种类。
Viruses. 2018 Oct 16;10(10):564. doi: 10.3390/v10100564.
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Expression of K1 Toxin Derivatives in Saccharomyces cerevisiae Mimics Treatment with Exogenous Toxin and Provides a Useful Tool for Elucidating K1 Mechanisms of Action and Immunity.在酿酒酵母中表达 K1 毒素衍生物可模拟外源性毒素的处理,为阐明 K1 的作用机制和免疫提供了有用的工具。
Toxins (Basel). 2017 Oct 27;9(11):345. doi: 10.3390/toxins9110345.
7
Variation and Distribution of L-A Helper Totiviruses in Saccharomyces sensu stricto Yeasts Producing Different Killer Toxins.产不同类型杀伤毒素酿酒酵母中 L-A helper 长尾噬菌体的变异与分布。
Toxins (Basel). 2017 Oct 11;9(10):313. doi: 10.3390/toxins9100313.
8
New Insights into the Genome Organization of Yeast Killer Viruses Based on "Atypical" Killer Strains Characterized by High-Throughput Sequencing.基于高通量测序鉴定的“非典型”杀伤株,揭示酵母杀伤病毒基因组结构的新见解。
Toxins (Basel). 2017 Sep 19;9(9):292. doi: 10.3390/toxins9090292.
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The frenemies within: viruses, retrotransposons and plasmids that naturally infect Saccharomyces yeasts.体内的亦敌亦友:天然感染酿酒酵母的病毒、逆转录转座子和质粒
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10
Relationships and Evolution of Double-Stranded RNA Totiviruses of Yeasts Inferred from Analysis of L-A-2 and L-BC Variants in Wine Yeast Strain Populations.从葡萄酒酵母菌株群体中L-A-2和L-BC变体分析推断酵母双链RNA病毒的关系与进化
Appl Environ Microbiol. 2017 Feb 1;83(4). doi: 10.1128/AEM.02991-16. Print 2017 Feb 15.

来自奇异酵母的 K74 杀伤毒素的表达受毒素编码 M74 双链 RNA 5'非翻译末端区的调节。

Expression of the K74 Killer Toxin from Saccharomyces paradoxus Is Modulated by the Toxin-Encoding M74 Double-Stranded RNA 5' Untranslated Terminal Region.

机构信息

Instituto de Biología Funcional y Genómica (IBFG), Consejo Superior de Investigaciones Científicas/Universidad de Salamanca, Salamanca, Spain.

Escuela Politécnica Superior de Zamora, Universidad de Salamanca, Salamanca, Spain.

出版信息

Appl Environ Microbiol. 2022 Apr 26;88(8):e0203021. doi: 10.1128/aem.02030-21. Epub 2022 Apr 7.

DOI:10.1128/aem.02030-21
PMID:35389250
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9040610/
Abstract

Yeast killer toxins are widely distributed in nature, conferring a competitive advantage to the producer yeasts over nonkiller ones when nutrients are scarce. Most of these toxins are encoded on double-stranded RNAs (dsRNAs) generically called M. L-A members of the viral family act as helper viruses to maintain M, providing the virion proteins that separately encapsidate and replicate L-A and M genomes. M genomes are organized in three regions, a 5' region coding the preprotoxin, followed by an internal poly(A) stretch and a 3' noncoding region. In this work, we report the characterization of K74 toxin encoded on M74 dsRNA from Saccharomyces paradoxus Q74.4. In M74, there is a 5' upstream sequence of 141 nucleotides (nt), which contains regulatory signals for internal translation of the preprotoxin open reading frame (ORF) at the second AUG codon. The first AUG close to the 5' end is not functional. For K74 analysis, M74 viruses were first introduced into laboratory strains of Saccharomyces cerevisiae. We show here that the mature toxin is an α/β heterodimer linked by disulfide bonds. Though the toxin (or preprotoxin) confers immunity to the carrier, cells with increased K74 loads have a sick phenotype that may lead to cell death. Thus, a fine-tuning of K74 production by the upstream regulatory sequence is essential for the host cell to benefit from the toxin it produces and, at the same time, to safely avoid damage by an excess of toxin. Killer yeasts produce toxins to which they are immune by mechanisms not well understood. This self-immunity, however, is compromised in certain strains, which secrete an excess of toxin, leading to sick cells or suicidal phenotypes. Thus, a fine-tuning of toxin production has to be achieved to reach a balance between the beneficial effect of toxin production and the stress imposed on the host metabolism. K74 toxin from S. paradoxus is very active against Saccharomyces uvarum, among other yeasts, but an excess of toxin production is deleterious for the host. Here, we report that the presence of a 5' 141-nt upstream sequence downregulates K74 toxin precursor translation, decreasing toxin levels 3- to 5-fold. Thus, this is a special case of translation regulation performed by sequences on the M74 genome itself, which have been presumably incorporated into the viral RNA during evolution for that purpose.

摘要

酵母杀伤毒素广泛存在于自然界中,当营养物质匮乏时,赋予了生产者酵母相对于非杀伤性酵母的竞争优势。这些毒素大多数都编码在双链 RNA(dsRNA)上,这些 dsRNA 通常被称为 M.L-A 成员,它们是病毒家族的一部分,作为辅助病毒来维持 M,提供分别封装和复制 L-A 和 M 基因组的病毒粒子蛋白。M 基因组组织在三个区域中,5' 区域编码前原毒素,然后是内部 poly(A) 延伸和 3' 非编码区域。在这项工作中,我们报告了来自酿酒酵母 Q74.4 的 M74 dsRNA 编码的 K74 毒素的特征。在 M74 中,有一个 141 个核苷酸(nt)的 5' 上游序列,其中包含内部翻译前原毒素开放阅读框(ORF)的调控信号,在第二个 AUG 密码子处。靠近 5' 端的第一个 AUG 不起作用。对于 K74 的分析,首先将 M74 病毒引入酿酒酵母的实验室菌株中。我们在这里表明,成熟的毒素是通过二硫键连接的α/β 异二聚体。尽管毒素(或前原毒素)赋予载体免疫性,但增加 K74 负荷的细胞表现出病态,可能导致细胞死亡。因此,上游调节序列对 K74 产生的精细调节对于宿主细胞从其产生的毒素中受益至关重要,同时还可以安全地避免因毒素过量而造成的损害。杀伤性酵母通过尚未完全理解的机制产生对其免疫的毒素。然而,这种自我免疫在某些菌株中受到损害,这些菌株会分泌过量的毒素,导致细胞生病或自杀表型。因此,必须对毒素的产生进行精细的调节,以在毒素产生的有益作用和对宿主代谢造成的压力之间达到平衡。来自 S. paradoxus 的 K74 毒素对酿酒酵母 uvarum 等酵母非常有效,但过量的毒素产生对宿主有害。在这里,我们报告说,存在一个 141 个核苷酸的 5' 上游序列会下调 K74 毒素前体的翻译,使毒素水平降低 3-5 倍。因此,这是 M74 基因组本身的序列进行翻译调节的一个特殊情况,这些序列在进化过程中可能被整合到病毒 RNA 中以达到这种目的。