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停滞的RNA聚合酶II对新生RNA的切割并不需要延伸复合物在DNA上向上游移位。

Nascent RNA cleavage by arrested RNA polymerase II does not require upstream translocation of the elongation complex on DNA.

作者信息

Gu W, Powell W, Mote J, Reines D

机构信息

Graduate Program in Biochemistry & Molecular Biology, Emory University, Atlanta, Georgia.

出版信息

J Biol Chem. 1993 Dec 5;268(34):25604-16.

PMID:7503982
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3373964/
Abstract

Obstacles incurred by RNA polymerase II during primary transcript synthesis have been identified in vivo and in vitro. Transcription past these impediments requires SII, an RNA polymerase II-binding protein. SII also activates a nuclease in arrested elongation complexes and this nascent RNA shortening precedes transcriptional readthrough. Here we show that in the presence of SII and nucleotides, transcript cleavage is detected during SII-dependent elongation but not during SII-independent transcription. Thus, under typical transcription conditions, SII is necessary but insufficient to activate RNA cleavage. RNA cleavage could serve to move RNA polymerase II away from the transcriptional impediment and/or permit RNA polymerase II multiple attempts at RNA elongation. By mapping the positions of the 3'-ends of RNAs and the elongation complex on DNA, we demonstrate that upstream movement of RNA polymerase II is not required for limited RNA shortening (seven to nine nucleotides) and reactivation of an arrested complex. Arrested complexes become elongation competent after removal of no more than nine nucleotides from the nascent RNA's 3'-end. Further cleavage of nascent RNA, however, does result in "backward" translocation of the enzyme. We also show that one round of RNA cleavage is insufficient for full readthrough at an arrest site, consistent with a previously suggested mechanism of SII action.

摘要

RNA聚合酶II在初级转录本合成过程中遇到的障碍已在体内和体外得到确认。转录越过这些障碍需要SII,一种RNA聚合酶II结合蛋白。SII还能激活停滞延伸复合物中的核酸酶,并且这种新生RNA缩短先于转录通读。在此我们表明,在存在SII和核苷酸的情况下,在依赖SII的延伸过程中可检测到转录本切割,但在不依赖SII的转录过程中则检测不到。因此,在典型的转录条件下,SII对于激活RNA切割是必要的,但并不充分。RNA切割可能有助于使RNA聚合酶II远离转录障碍和/或使RNA聚合酶II能够多次尝试进行RNA延伸。通过绘制RNA的3'末端位置以及DNA上的延伸复合物,我们证明有限的RNA缩短(7至9个核苷酸)和停滞复合物的重新激活并不需要RNA聚合酶II向上游移动。从新生RNA的3'末端去除不超过9个核苷酸后,停滞复合物就会具备延伸能力。然而,新生RNA的进一步切割确实会导致该酶“向后”易位。我们还表明,一轮RNA切割不足以在停滞位点实现完全通读,这与先前提出的SII作用机制一致。

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