Ahmed Wareed, Sala Claudia, Hegde Shubhada R, Jha Rajiv Kumar, Cole Stewart T, Nagaraja Valakunja
Department of Microbiology and Cell Biology, Indian Institute of Science, Bangalore, India.
Ecole Polytechnique Federale de Lausanne, Global Health Institute, Station 19, Lausanne, Switzerland.
PLoS Genet. 2017 May 2;13(5):e1006754. doi: 10.1371/journal.pgen.1006754. eCollection 2017 May.
Movement of the transcription machinery along a template alters DNA topology resulting in the accumulation of supercoils in DNA. The positive supercoils generated ahead of transcribing RNA polymerase (RNAP) and the negative supercoils accumulating behind impose severe topological constraints impeding transcription process. Previous studies have implied the role of topoisomerases in the removal of torsional stress and the maintenance of template topology but the in vivo interaction of functionally distinct topoisomerases with heterogeneous chromosomal territories is not deciphered. Moreover, how the transcription-induced supercoils influence the genome-wide recruitment of DNA topoisomerases remains to be explored in bacteria. Using ChIP-Seq, we show the genome-wide occupancy profile of both topoisomerase I and DNA gyrase in conjunction with RNAP in Mycobacterium tuberculosis taking advantage of minimal topoisomerase representation in the organism. The study unveils the first in vivo genome-wide interaction of both the topoisomerases with the genomic regions and establishes that transcription-induced supercoils govern their recruitment at genomic sites. Distribution profiles revealed co-localization of RNAP and the two topoisomerases on the active transcriptional units (TUs). At a given locus, topoisomerase I and DNA gyrase were localized behind and ahead of RNAP, respectively, correlating with the twin-supercoiled domains generated. The recruitment of topoisomerases was higher at the genomic loci with higher transcriptional activity and/or at regions under high torsional stress compared to silent genomic loci. Importantly, the occupancy of DNA gyrase, sole type II topoisomerase in Mtb, near the Ter domain of the Mtb chromosome validates its function as a decatenase.
转录机器沿着模板移动会改变DNA拓扑结构,导致DNA中积累超螺旋。在转录RNA聚合酶(RNAP)前方产生的正超螺旋以及在其后方积累的负超螺旋会施加严重的拓扑限制,阻碍转录过程。先前的研究暗示了拓扑异构酶在消除扭转应力和维持模板拓扑结构中的作用,但功能不同的拓扑异构酶与异质染色体区域的体内相互作用尚未得到阐明。此外,转录诱导的超螺旋如何影响细菌中DNA拓扑异构酶在全基因组范围内的募集仍有待探索。利用染色质免疫沉淀测序(ChIP-Seq)技术,我们利用结核分枝杆菌中拓扑异构酶表达量极低这一特点,展示了拓扑异构酶I和DNA促旋酶在全基因组范围内与RNAP的结合情况。该研究揭示了这两种拓扑异构酶首次在体内与基因组区域的全基因组相互作用,并确定转录诱导的超螺旋控制它们在基因组位点的募集。分布图谱显示RNAP和这两种拓扑异构酶在活跃转录单元(TUs)上共定位。在给定基因座处,拓扑异构酶I和DNA促旋酶分别位于RNAP的后方和前方,这与产生的双超螺旋结构域相关。与沉默的基因组位点相比,在具有较高转录活性的基因组位点和/或处于高扭转应力区域,拓扑异构酶的募集更高。重要的是,结核分枝杆菌中唯一的II型拓扑异构酶DNA促旋酶在结核分枝杆菌染色体的Ter结构域附近的占据情况验证了其作为解连环酶的功能。
