Hogan J J, Noller H F
Biochemistry. 1978 Feb 21;17(4):587-93. doi: 10.1021/bi00597a005.
We have studied the topography of 16S RNA in the inactive form of the 30S ribosomal subunit (Ginsburg, I., et al. (1973) J. Mol. Biol. 79, 481), using the guanine-specific reagent kethoxal. Oligonucleotides surrounding reactive guanine residues were isolated and quantitated by means of diagonal electrophoresis and sequenced. Comparison of these results with experiments on active or reactivated subunits reveals the following: (1) Most of the sites which are reactive in active 30S subunits are much more reactive (average 13-fold) in inactive subunits. Upon reactivation, these sites return to a less reactive state. Thus, a reversible increase in accessibility of specific 16S RNA sites parallels the reversible loss of protein synthesis activity of 30S subunits. (2) The number of kethoxal-reactive sites in inactive subunits is about twice that of active subunits. The nucleotide sequences and locations of the additional accessible sites in inactive subunits have been determined. (3) Sites that can be located in the 16S RNA sequence are distributed throughout the RNA chain in inactive subunits, in contrast to the clustering observed in active subunits. (4) The sites of kethoxal substitution are single stranded. Yet, of the 30 sites that can be located, 23 were predicted to be base paired in the proposed secondary structure model for 16S RNA (Ehresmann, C., et al. (1975), Nucleic Acids Res. 2, 265).
我们使用鸟嘌呤特异性试剂乙二醛,研究了30S核糖体亚基无活性形式中16S RNA的拓扑结构(金斯堡,I.等人(1973年)《分子生物学杂志》79卷,481页)。分离出围绕反应性鸟嘌呤残基的寡核苷酸,并通过对角线电泳进行定量和测序。将这些结果与活性或再活化亚基的实验结果进行比较,得出以下结论:(1)在活性30S亚基中具有反应性的大多数位点,在无活性亚基中反应性更强(平均13倍)。再活化后,这些位点恢复到反应性较低的状态。因此,特定16S RNA位点可及性的可逆增加与30S亚基蛋白质合成活性的可逆丧失平行。(2)无活性亚基中乙二醛反应性位点的数量约为活性亚基的两倍。已确定无活性亚基中额外可及位点的核苷酸序列和位置。(3)与活性亚基中观察到的聚集情况相反,在无活性亚基中可位于16S RNA序列中的位点分布在整个RNA链上。(4)乙二醛取代位点是单链的。然而,在所确定的30个位点中,预计在16S RNA的二级结构模型(埃雷斯曼,C.等人(1975年),《核酸研究》2卷,265页)中有23个位点是碱基配对的。
