A nucleoid-associated protein is involved in the emergence of antibiotic resistance by promoting the frequent exchange of the replicative DNA polymerase in M. smegmatis.
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引用次数: 0
Abstract
Antibiotic resistance in M. tuberculosis exclusively originates from chromosomal mutations, either during normal DNA replication or under stress, when the expression of error-prone DNA polymerases increases to repair damaged DNA. To bypass DNA lesions and catalyze error-prone DNA synthesis, translesion polymerases must be able to access the DNA, temporarily replacing the high-fidelity replicative polymerase. The mechanisms that govern polymerase exchange are not well understood, especially in mycobacteria. Here, using a suite of quantitative fluorescence imaging techniques, we discover that, as in other bacterial species, in M. smegmatis, the replicative polymerase, DnaE1, exchanges at a timescale much faster than that of DNA replication. Interestingly, this fast exchange rate depends on an actinobacteria-specific nucleoid-associated protein (NAP), Lsr2. In cells missing lsr2, DnaE1 exchanges less frequently, and the chromosome is replicated more faithfully. Additionally, in conditions that damage DNA, cells lacking lsr2 load the complex needed to bypass DNA lesions less effectively and, consistently, replicate with higher fidelity but exhibit growth defects. Together, our results show that Lsr2 promotes dynamic flexibility of the mycobacterial replisome, which is critical for robust cell growth and lesion repair in conditions that damage DNA.
结核杆菌的抗生素耐药性完全源于染色体突变,要么是在正常 DNA 复制过程中,要么是在应激状态下,此时易出错 DNA 聚合酶的表达增加,以修复受损 DNA。为了绕过 DNA 病变并催化易出错 DNA 的合成,转座聚合酶必须能够进入 DNA,暂时取代高保真复制聚合酶。聚合酶交换的机制尚不十分清楚,尤其是在分枝杆菌中。在这里,我们利用一套定量荧光成像技术发现,与其他细菌物种一样,在烟曲霉菌中,复制聚合酶 DnaE1 的交换时标比 DNA 复制时标快得多。有趣的是,这种快速的交换速度取决于放线菌特异的核糖体相关蛋白(NAP)Lsr2。在缺少lsr2的细胞中,DnaE1的交换频率较低,而染色体的复制则更加可靠。此外,在损伤 DNA 的条件下,缺乏 lsr2 的细胞装载绕过 DNA 病变所需的复合物的效率较低,复制的保真度也较高,但却表现出生长缺陷。我们的研究结果表明,Lsr2促进了分枝杆菌复制体的动态灵活性,这对细胞的稳健生长以及在DNA受损条件下的病变修复至关重要:与许多其他病原体不同,结核杆菌的水平基因转移能力有限,而水平基因转移是产生抗生素耐药性的主要机制。因此,促进染色体诱变的机制在分枝杆菌中尤为重要。在这里,我们发现 Lsr2(一种核糖体相关蛋白)在模式分枝杆菌 M. smegmatis 的 DNA 复制和诱变过程中发挥着新的作用。我们发现,Lsr2能促进复制DNA聚合酶DnaE1在复制分叉处的快速交换率,并对DnaE2-ImuA'-ImuB转座复合物的有效装载非常重要。如果没有lsr2,M. smegmatis会更忠实地复制染色体,并以较低的速度获得对利福平的抗性,但代价是在DNA损伤剂面前生存能力受损。总之,我们的研究成果证明,Lsr2 是导致分枝杆菌产生抗药性的一个潜在因素。
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