HIV-1 nef保守3'-末端UGA终止密码子的硒依赖性解读

L. Premadasa, Gabrielle P. Dailey, J. Ruzicka, E. Taylor
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引用次数: 4

摘要

HIV-1 nef基因终止于一个3'-UGA终止密码子,这在HIV-1亚型的主要组中是高度保守的,同时还有一个下游的潜在编码区,如果终止密码子被读取,该编码区可以将nef蛋白延长33个氨基酸。病毒mRNA与宿主硒蛋白mRNA之间的反义拴住相互作用(ATIs)是捕获宿主硒半胱氨酸插入序列(SECIS)元件的一种潜在病毒策略(Taylor等,2016)[1]。这种mRNA劫持机制可以通过将帧内UGA停止密码子翻译为硒半胱氨酸(SeC),使病毒编码的硒蛋白模块得以表达。在转染的细胞中,nef的3'端UGA密码子的读取发生在HIV-1 nef表达构建的翻译过程中。这是通过荧光显微镜图像分析和流式细胞术完成的,转染了工程GFP报告基因质粒,其中GFP只能通过UGA密码子的翻译重编码来表达。硫氧还蛋白还原酶1 (TR1) mRNA的SiRNA敲低导致GFP表达减少67%,可能是由于参与硒代半胱氨酸结合的停止密码子读取的成分减少,从而支持了所提出的ATI。在培养基中添加20 nM亚硒酸钠可显著提高pNefATI1质粒结构中的终止密码子读通率,提高率>100%,支持硒参与UGA读通机制的假设。
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Selenium-Dependent Read Through of the Conserved 3'-Terminal UGA Stop Codon of HIV-1 nef.
The HIV-1 nef gene terminates in a 3'-UGA stop codon, which is highly conserved in the main group of HIV-1 subtypes, along with a downstream potential coding region that could extend the nef protein by 33 amino acids, if readthrough of the stop codon occurs. Antisense tethering interactions (ATIs) between a viral mRNA and a host selenoprotein mRNA are a potential viral strategy for the capture of a host selenocysteine insertion sequence (SECIS) element (Taylor et al, 2016) [1]. This mRNA hijacking mechanism could enable the expression of virally encoded selenoprotein modules, via translation of in-frame UGA stop codons as selenocysteine (SeC). Here we show that readthrough of the 3'-terminal UGA codon of nef occurs during translation of HIV-1 nef expression constructs in transfected cells. This was accomplished via fluorescence microscopy image analysis and flow cytometry of HEK 293 cells, transfected with engineered GFP reporter gene plasmid constructs, in which GFP can only be expressed by translational recoding of the UGA codon. SiRNA knockdown of thioredoxin reductase 1 (TR1) mRNA resulted in a 67% decrease in GFP expression, presumably due to reduced availability of the components involved in selenocysteine incorporation for the stop codon readthrough, thus supporting the proposed ATI. Addition of 20 nM sodium selenite to the media significantly enhanced stop codon readthrough in the pNefATI1 plasmid construct, by >100%, supporting the hypothesis that selenium is involved in the UGA readthrough mechanism.
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