Zhang Chunfen, Zobeck Katie L, Burton Zachary F
Department of Biochemistry and Molecular Biology, Michigan State University, 224 Biochemistry Building, East Lansing, MI 48824-1319, USA.
Mol Cell Biol. 2005 May;25(9):3583-95. doi: 10.1128/MCB.25.9.3583-3595.2005.
The role of the RAP74 alpha1 helix of transcription factor IIF (TFIIF) in stimulating elongation by human RNA polymerase II (RNAP II) was examined using millisecond-phase transient-state kinetics. RAP74 deletion mutants RAP74(1-227), which includes an intact alpha1 helix, and RAP74(1-158), in which the alpha1 helix is deleted, were compared. Analysis of TFIIF RAP74-RAP30 complexes carrying the RAP74(1-158) deletion reveals the role of the alpha1 helix because this mutant has indistinguishable activity compared to TFIIF 74(W164A), which carries a critical point mutation in alpha1. We report adequate two-bond kinetic simulations for the reaction in the presence of TFIIF 74(1-227) + TFIIS and TFIIF 74(1-158) + TFIIS. TFIIF 74(1-158) is defective because it fails to promote forward translocation. Deletion of the RAP74 alpha1 helix results in increased occupancy of the backtracking, cleavage, and restart pathways at a stall position, indicating reverse translocation of the elongation complex. During elongation, TFIIF 74(1-158) fails to support detectable nucleoside triphosphate (NTP)-driven translocation from a stall position and is notably defective in supporting bond completion (NTP-driven translocation coupled to pyrophosphate release) during the processive transition between bonds.
利用毫秒级瞬态动力学研究了转录因子IIF(TFIIF)的RAP74 α1螺旋在刺激人RNA聚合酶II(RNAP II)延伸过程中的作用。比较了RAP74缺失突变体RAP74(1 - 227)(包含完整的α1螺旋)和RAP74(1 - 158)(α1螺旋缺失)。对携带RAP74(1 - 158)缺失的TFIIF RAP74 - RAP30复合物进行分析,揭示了α1螺旋的作用,因为该突变体与在α1中携带关键位点突变的TFIIF 74(W164A)具有难以区分的活性。我们报告了在存在TFIIF 74(1 - 227) + TFIIS和TFIIF 74(1 - 158) + TFIIS的情况下该反应的充分的双键动力学模拟。TFIIF 74(1 - 158)有缺陷,因为它不能促进正向转位。RAP74 α1螺旋的缺失导致在停滞位置回溯、切割和重新起始途径的占有率增加,表明延伸复合物发生了反向转位。在延伸过程中,TFIIF 74(1 - 158)不能支持从停滞位置进行可检测的核苷三磷酸(NTP)驱动的转位,并且在键的连续转变过程中支持键的完成(NTP驱动的转位与焦磷酸释放偶联)方面存在明显缺陷。