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新生RNA中的结构导致T7 RNA聚合酶的滑动转录终止。

Structure in nascent RNA leads to termination of slippage transcription by T7 RNA polymerase.

作者信息

Kuzmine I, Gottlieb P A, Martin C T

机构信息

Department of Chemistry, University of Massachusetts, 710 North Pleasant Street, Amherst, MA 01003-4510, USA.

出版信息

Nucleic Acids Res. 2001 Jun 15;29(12):2601-6. doi: 10.1093/nar/29.12.2601.

DOI:10.1093/nar/29.12.2601
PMID:11410669
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC55752/
Abstract

T7 RNA polymerase presents a very simple model system for the study of fundamental aspects of transcription. Some time ago it was observed that in the presence of only GTP as a substrate, on a template encoding the initial sequence GGGA., T7 RNA polymerase will synthesize a 'ladder' of poly-G RNA products. At each step, the ratio of elongation to product release is consistently approximately 0.75 until the RNA reaches a length of approximately 13-14 nt, at which point this ratio drops precipitously. One model to explain this drop in complex stability suggests that the nascent RNA may be structurally hindered by the protein; the RNA may be exiting via a pathway not taken by normally synthesized RNA and therefore becomes sterically destabilized. The fact that the length of RNA at which this occurs is close to the length at which the transition to a stably elongating complex occurs might have led to other mechanistic proposals. Here we show instead that elongation falls off due to the cooperative formation of structure in the nascent RNA, most likely an intramolecular G-quartet structure. Replacement of GTP by 7-deaza-GTP completely abolishes this transition and G-ladder synthesis continues with a constant efficiency of elongation beyond the limit of detection. The polymerase-DNA complex creates no barrier to the growth of the nascent (slippage) RNA, rather termination is similar to that which occurs in rho-independent termination.

摘要

T7 RNA聚合酶为转录基本方面的研究提供了一个非常简单的模型系统。不久前人们观察到,在仅以GTP作为底物的情况下,在编码初始序列GGGA.的模板上,T7 RNA聚合酶会合成一个多聚G RNA产物的“梯状”结构。在每一步中,延伸与产物释放的比率始终约为0.75,直到RNA达到约13 - 14个核苷酸的长度,此时该比率会急剧下降。一种解释这种复合物稳定性下降的模型表明,新生RNA可能在结构上受到蛋白质的阻碍;RNA可能通过正常合成的RNA未采用的途径退出,因此在空间上变得不稳定。这种情况发生时RNA的长度与向稳定延伸复合物转变时的长度相近这一事实可能引发了其他机制上的推测。相反,我们在此表明,延伸效率下降是由于新生RNA中结构的协同形成,最有可能是分子内G - 四联体结构。用7 - 脱氮GTP取代GTP完全消除了这种转变,并且G梯状结构的合成以超过检测极限的恒定延伸效率继续进行。聚合酶 - DNA复合物对新生(滑动)RNA的生长没有阻碍,相反,终止类似于在不依赖ρ因子的终止中发生的情况。

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