Itsko Mark, Schaaper Roel M
Genome Integrity and Structural Biology Laboratory, National Institute of Environmental Health Sciences, Research Triangle Park, North Carolina, USA.
J Bacteriol. 2016 May 13;198(11):1631-44. doi: 10.1128/JB.00218-16. Print 2016 Jun 1.
Our laboratory recently discovered that Escherichia coli cells starved for the DNA precursor dGTP are killed efficiently (dGTP starvation) in a manner similar to that described for thymineless death (TLD). Conditions for specific dGTP starvation can be achieved by depriving an E. coli optA1 gpt strain of the purine nucleotide precursor hypoxanthine (Hx). To gain insight into the mechanisms underlying dGTP starvation, we conducted genome-wide gene expression analyses of actively growing optA1 gpt cells subjected to hypoxanthine deprivation for increasing periods. The data show that upon Hx withdrawal, the optA1 gpt strain displays a diminished ability to derepress the de novo purine biosynthesis genes, likely due to internal guanine accumulation. The impairment in fully inducing the purR regulon may be a contributing factor to the lethality of dGTP starvation. At later time points, and coinciding with cell lethality, strong induction of the SOS response was observed, supporting the concept of replication stress as a final cause of death. No evidence was observed in the starved cells for the participation of other stress responses, including the rpoS-mediated global stress response, reinforcing the lack of feedback of replication stress to the global metabolism of the cell. The genome-wide expression data also provide direct evidence for increased genome complexity during dGTP starvation, as a markedly increased gradient was observed for expression of genes located near the replication origin relative to those located toward the replication terminus.
Control of the supply of the building blocks (deoxynucleoside triphosphates [dNTPs]) for DNA replication is important for ensuring genome integrity and cell viability. When cells are starved specifically for one of the four dNTPs, dGTP, the process of DNA replication is disturbed in a manner that can lead to eventual death. In the present study, we investigated the transcriptional changes in the bacterium E. coli during dGTP starvation. The results show increasing DNA replication stress with an increased time of starvation, as evidenced by induction of the bacterial SOS system, as well as a notable lack of induction of other stress responses that could have saved the cells from cell death by slowing down cell growth.
我们实验室最近发现,缺乏DNA前体dGTP的大肠杆菌细胞会以类似于无胸腺死亡(TLD)的方式被有效杀死(dGTP饥饿)。通过剥夺大肠杆菌optA1 gpt菌株的嘌呤核苷酸前体次黄嘌呤(Hx),可以实现特定的dGTP饥饿条件。为了深入了解dGTP饥饿背后的机制,我们对处于活跃生长状态的optA1 gpt细胞进行了全基因组基因表达分析,这些细胞经历了不同时长的次黄嘌呤剥夺。数据表明,在撤去Hx后,optA1 gpt菌株解除对从头嘌呤生物合成基因抑制的能力减弱,这可能是由于内部鸟嘌呤积累所致。完全诱导purR调控子的受损可能是dGTP饥饿致死的一个促成因素。在后期时间点,与细胞致死同时发生的是,观察到SOS应答的强烈诱导,这支持了复制应激是最终死亡原因的概念。在饥饿细胞中未观察到其他应激应答参与的证据,包括由rpoS介导的全局应激应答,这强化了复制应激对细胞全局代谢缺乏反馈的观点。全基因组表达数据还为dGTP饥饿期间基因组复杂性增加提供了直接证据,因为相对于位于复制终点的基因,在复制起点附近的基因表达梯度明显增加。
控制DNA复制的构建模块(脱氧核苷三磷酸 [dNTPs])的供应对于确保基因组完整性和细胞活力很重要。当细胞特异性缺乏四种dNTP之一dGTP时,DNA复制过程会以可能导致最终死亡的方式受到干扰。在本研究中,我们调查了大肠杆菌在dGTP饥饿期间的转录变化。结果表明,随着饥饿时间的增加,DNA复制应激增加,这通过细菌SOS系统的诱导得以证明,同时明显缺乏其他应激应答的诱导,而这些应激应答本可以通过减缓细胞生长使细胞免于死亡。