克里克摆动配对与沃森-克里克配对的堆积:tRNA螺旋茎末端G-U配对的稳定性规则及其与密码子-反密码子摆动相互作用的关系。
Stacking of Crick Wobble pair and Watson-Crick pair: stability rules of G-U pairs at ends of helical stems in tRNAs and the relation to codon-anticodon Wobble interaction.
作者信息
Mizuno H, Sundaralingam M
出版信息
Nucleic Acids Res. 1978 Nov;5(11):4451-61. doi: 10.1093/nar/5.11.4451.
Abstract
The occurrence of the noncomplementary G-U base pair at the end of a helix is found to be governed by stacking interactions. As a rule, a G-U pair with G on the 5'-side of a Watson-Crick base pair exhibits strikingly greater stacking overlap with the Watson-Crick base pair than a G-U pair on the 3'-side of a Watson-Crick base pair. The former arrangement is expected to be more stable and indeed is observed 29 times out of 32 in the known transfer RNA molecules. In accordance with this rule, the major wobble base pairs G-U or I-U in codon-anticodon interactions have G or I on the 5'-side of the anticodon. Similarly, in initiator tRNAs, this rule is obeyed where now the G is the first letter of the codon (5'-side). In the situation where U is in the wobble position of the anticodon, it is usually substituted at C(5) andmay also have a 2-thio group and it can read one to four codons depending on its modifications. A G at the wobble position of the anticodon can recognize the two codons ending with U or C and modification of G (unless it is I) does not change its reading properties.
摘要
研究发现,螺旋末端非互补的G-U碱基对的出现受堆积相互作用的支配。通常,在沃森-克里克碱基对5'侧带有G的G-U对,与沃森-克里克碱基对的堆积重叠明显大于在沃森-克里克碱基对3'侧的G-U对。预计前一种排列更稳定,在已知的转运RNA分子中,32次中有29次观察到这种情况。根据这一规则,密码子-反密码子相互作用中的主要摆动碱基对G-U或I-U,在反密码子的5'侧带有G或I。同样,在起始tRNA中,也遵循这一规则,此时G是密码子的第一个字母(5'侧)。在反密码子的摆动位置为U的情况下,它通常在C(5)处被取代,也可能有一个2-硫基,并且根据其修饰情况可以识别一到四个密码子。反密码子摆动位置的G可以识别以U或C结尾的两个密码子,G的修饰(除非它是I)不会改变其阅读特性。
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