Brown E A, Day S P, Jansen R W, Lemon S M
Department of Medicine, University of North Carolina, Chapel Hill 27599-7030.
J Virol. 1991 Nov;65(11):5828-38. doi: 10.1128/JVI.65.11.5828-5838.1991.
Although the lengthy 5' nontranslated regions (5'NTRs) of other picornaviral RNAs form highly ordered structures with important functions in viral translation, little is known about the 5'NTR of hepatitis A virus (HAV). We determined the nearly complete 5'NTR nucleotide sequences of two genetically divergent HAV strains (PA21 and CF53) and included these data in a comparative phylogenetic analysis of the HAV 5'NTR. We identified covariant nucleotide substitutions predictive of conserved secondary structures and used this information to develop a model of the 5'NTR secondary structure, which was further refined by thermodynamic predictions and nuclease digestion experiments. According to this model, the 5'NTR comprises six major structural domains. Domains I and II (bases 1 to 95) contain a 5'-terminal hairpin and two stem-loops followed by a single-stranded and highly variable pyrimidine-rich tract (bases 96 to 154). The remainder of the 5'NTR (domains III to VI, bases 155 to 734) contains several complex stem-loops, one of which may form a pseudoknot, and terminates in a highly conserved region containing an oligopyrimidine tract preceding the putative start codon by 13 bases. To determine which structural elements might function as an internal ribosome entry site, RNA transcripts representing the HAV 5'NTR with progressive 5' deletions were translated in rabbit reticulocyte lysates. The translation product was truncated, unprocessed P1 polyprotein. Removal of the 5'-terminal 354 bases of the 5'NTR had little effect on translation. However, deletion to base 447 slightly decreased translation, while deletion to base 533 almost completely abolished it. These data indicate that sequences 3' of base 355 play an important role in the translation mechanism utilized by genomic-length HAV RNA. Significantly, this region shares several conserved structural features with the internal ribosome entry site element of murine encephalomyocarditis virus.
尽管其他小核糖核酸病毒RNA的冗长5'非翻译区(5'NTR)形成了在病毒翻译中具有重要功能的高度有序结构,但关于甲型肝炎病毒(HAV)的5'NTR却知之甚少。我们确定了两种基因不同的HAV毒株(PA21和CF53)几乎完整的5'NTR核苷酸序列,并将这些数据纳入HAV 5'NTR的比较系统发育分析中。我们鉴定出了预测保守二级结构的协变核苷酸替换,并利用这些信息构建了5'NTR二级结构模型,该模型通过热力学预测和核酸酶消化实验进一步完善。根据该模型,5'NTR由六个主要结构域组成。结构域I和II(第1至95位碱基)包含一个5'末端发夹结构和两个茎环结构,随后是一个单链且高度可变的富含嘧啶的区域(第96至154位碱基)。5'NTR的其余部分(结构域III至VI,第155至734位碱基)包含几个复杂的茎环结构,其中一个可能形成假结,并在一个高度保守的区域终止,该区域在假定的起始密码子之前13个碱基处包含一个寡嘧啶序列。为了确定哪些结构元件可能作为内部核糖体进入位点,在兔网织红细胞裂解物中翻译了代表具有渐进性5'缺失的HAV 5'NTR的RNA转录本。翻译产物是截短的、未加工的P1多聚蛋白。去除5'NTR的5'末端354个碱基对翻译影响不大。然而,缺失至第447位碱基会使翻译略有下降,而缺失至第533位碱基几乎完全消除了翻译。这些数据表明,第355位碱基下游的序列在基因组长度的HAV RNA所利用的翻译机制中起重要作用。值得注意的是,该区域与小鼠脑心肌炎病毒的内部核糖体进入位点元件具有几个保守的结构特征。
