Lee S S, Kang C
Department of Life Science, Korea Advanced Institute of Science and Technology, Taejon.
J Biol Chem. 1993 Sep 15;268(26):19299-304.
Bacteriophage T7 and SP6 RNA polymerases and their promoters share a high degree of their primary structure homology, but each polymerase exclusively recognizes its own promoter sequence. To reveal the molecular basis of this specificity, 4 base pairs at positions -12, -10, -9, and -8 of the T7 promoter were substituted individually and multiply by SP6 promoter-specific base pairs, and 3 base pairs at -10, -9, and -8 of the SP6 promoter were replaced by T7 promoter-specific base pairs. Promoter activities of 28 sequences were measured in vitro with T7 and SP6 polymerases separately under optimal conditions at 6 mM MgCl2. Single and double substitutions at -12 and -10 do not significantly affect the T7 promoter activity, although they are almost exclusively conserved among T7 genomic promoters. Changes at -10 of SP6 promoter hardly affect the activity. However, any T7 variants that contain either or both changes at -9 and -8 show greatly reduced activity. Interestingly, the double substitution at -9 and -8 yields significant SP6 promoter activities and virtually no T7 promoter activity. Furthermore, the SP6 promoter variants with both T7-specific -9C and -8T show good T7 promoter activities, although they still show some SP6 promoter activities. However, under high salt conditions (either 20 mM MgCl2 or 100 mM NaCl plus 6 mM MgCl2), they show only slight SP6 promoter activity. No other SP6 variants show any T7 promoter activity. All these results indicate that the 2 base pairs at -9 and -8 of both the T7 and SP6 promoters are the primary (if not the only) determinants of specificity and that the hierarchy of importance of positions for promoter activity is -8, -9 > > -10 > -12. Also, a phylogenic relationship among the T3, T7, K11, and SP6 promoters is suggested based on dissimilarities in their sequences from -12 to -8.
噬菌体T7和SP6 RNA聚合酶及其启动子在一级结构上具有高度同源性,但每种聚合酶只能特异性识别其自身的启动子序列。为了揭示这种特异性的分子基础,将T7启动子-12、-10、-9和-8位的4个碱基对分别或多个替换为SP6启动子特异性碱基对,并将SP6启动子-10、-9和-8位的3个碱基对替换为T7启动子特异性碱基对。在6 mM MgCl₂的最佳条件下,分别用T7和SP6聚合酶在体外测量了28个序列的启动子活性。-12和-10位的单碱基和双碱基替换对T7启动子活性影响不显著,尽管这些碱基在T7基因组启动子中几乎完全保守。SP6启动子-10位的变化对活性影响很小。然而,任何在-9和-8位有一个或两个变化的T7变体活性都大大降低。有趣的是,-9和-8位的双碱基替换产生了显著的SP6启动子活性,而几乎没有T7启动子活性。此外,具有T7特异性-9C和-8T的SP6启动子变体显示出良好的T7启动子活性,尽管它们仍然显示出一些SP6启动子活性。然而,在高盐条件下(20 mM MgCl₂或100 mM NaCl加6 mM MgCl₂),它们仅显示出轻微的SP6启动子活性。没有其他SP6变体显示出任何T7启动子活性。所有这些结果表明,T7和SP6启动子-9和-8位的2个碱基对是特异性的主要(如果不是唯一)决定因素,并且启动子活性位置的重要性顺序为-8、-9 >> -10 > -12。此外,基于T3、T7、K11和SP6启动子从-12到-8序列的差异,推测了它们之间的系统发育关系。
