RNase HI overproduction is required for efficient full-length RNA synthesis in the absence of topoisomerase I in Escherichia coli

It has long been known that Escherichia coli cells deprived of topoisomerase I (topA null mutants) do not grow. Because mutations reducing DNA gyrase activity and, as a consequence, negative supercoiling, occur to compensate for the loss of topA function, it has been assumed that excessive negative supercoiling is somehow involved in the growth inhibition of topA null mutants. However, how excess negative supercoiling inhibits growth is still unknown. We have previously shown that the overproduction of RNase HI, an enzyme that degrades the RNA portion of an R-loop, can partially compensate for the growth defects because of the absence of topoisomerase I. In this article, we have studied the effects of gyrase reactivation on the physiology of actively growing topA null cells. We found that growth immediately and almost completely ceases upon gyrase reactivation, unless RNase HI is overproduced. Northern blot analysis shows that the cells have a significantly reduced ability to accumulate full-length mRNAs when RNase HI is not overproduced. Interestingly, similar phenotypes, although less severe, are also seen when bacterial cells lacking RNase HI activity are grown and treated in the same way. All together, our results suggest that excess negative supercoiling promotes the formation of R-loops, which, in turn, inhibit RNA synthesis.     

Constitutive stable DNA replication in Escherichia coli cells lacking type 1A topoisomerase activity

Type 1A topoisomerases (topos) are ubiquitous enzymes involved in supercoiling regulation and in the maintenance of genome stability. Escherichia coli possesses two type 1A enzymes, topo I (topA) and topo III (topB). Cells lacking both enzymes form very long filaments and have severe chromosome segregation and growth defects. We previously found that RNase HI overproduction or a dnaT::aph mutation could significantly correct these phenotypes. This leads us to hypothesize that they were related to unregulated replication originating from R-loops, i.e. constitutive stable DNA replication (cSDR). cSDR, first observed in rnhA (RNase HI) mutants, is characterized by its persistence for several hours following protein synthesis inhibition and by its requirement for primosome components, including DnaT. Here, to visualize and measure cSDR, the incorporation of the nucleotide analog ethynyl deoxyuridine (EdU) during replication in E. coli cells pre-treated with protein synthesis inhibitors, was revealed by “click” labeling with Alexa Fluor^® 488 in fixed cells, and flow cytometry analysis. cSDR was detected in rnhA mutants, but not in wild-type strains, and the number of cells undergoing cSDR was significantly reduced by the introduction of the dnaT::aph mutation. cSDR was also found in topA, double topA topB but not in topB null cells. This result is consistent with the established function of topo I in the inhibition of R-loop formation. Moreover, our finding that topB rnhA mutants are perfectly viable demonstrates that topo III is not uniquely required during cSDR. Thus, either topo I or III can provide the type 1A topo activity that is specifically required during cSDR to allow chromosome segregation.     

TDRD3 promotes DHX9 chromatin recruitment and R-loop resolution

R-loops, which consist of a DNA/RNA hybrid and a displaced single-stranded DNA (ssDNA), are increasingly recognized as critical regulators of chromatin biology. R-loops are particularly enriched at gene promoters, where they play important roles in regulating gene expression. However, the molecular mechanisms that control promoter-associated R-loops remain unclear. The epigenetic ‘reader’ Tudor domain-containing protein 3 (TDRD3), which recognizes methylarginine marks on histones and on the C-terminal domain of RNA polymerase II, was previously shown to recruit DNA topoisomerase 3B (TOP3B) to relax negatively supercoiled DNA and prevent R-loop formation. Here, we further characterize the function of TDRD3 in R-loop metabolism and introduce the DExH-box helicase 9 (DHX9) as a novel interaction partner of the TDRD3/TOP3B complex. TDRD3 directly interacts with DHX9 via its Tudor domain. This interaction is important for recruiting DHX9 to target gene promoters, where it resolves R-loops in a helicase activity-dependent manner to facilitate gene expression. Additionally, TDRD3 also stimulates the helicase activity of DHX9. This stimulation relies on the OB-fold of TDRD3, which likely binds the ssDNA in the R-loop structure. Thus, DHX9 functions together with TOP3B to suppress promoter-associated R-loops. Collectively, these findings reveal new functions of TDRD3 and provide important mechanistic insights into the regulation of R-loop metabolism.     

R-loop-dependent replication and genomic instability in bacteria

DNA replication, the faithful copying of genetic material, must be tightly regulated to produce daughter cells with intact copies of the chromosome(s). This regulated replication is initiated by binding of specific proteins at replication origins, such as DnaA to oriC in bacteria. However, unregulated replication can sometimes be initiated at other sites, which can threaten genomic stability. One of the first systems of unregulated replication to be described is the one activated in Escherichia coli mutants lacking RNase HI (rnhA). In fact, rnhA mutants can replicate their chromosomes in a DnaA- and oriC-independent process. Because this replication occurs in cells lacking RNase HI, it is proposed that RNA from R-loops is used as a DNA polymerase primer. Replication from R-loops has recently attracted increased attention due to the advent of DNA:RNA hybrid immunoprecipitation coupled with high-throughput DNA sequencing that revealed the high prevalence of R-loop formation in many organisms, and the demonstration that R-loops can severely threaten genomic stability. Although R-loops have been linked to genomic instability mostly via replication stress, evidence of their toxic effects via unregulated replication has also been presented. Replication from R-loops may also beneficially trigger stress-induced mutagenesis (SIM) that assists bacterial adaptation to stress. Here, we describe the cis- and trans-acting elements involved in R-loop-dependent replication in bacteria, with an emphasis on new data obtained with type 1A topoisomerase mutants and new available technologies. Furthermore, we discuss about the mechanism(s) by which R-loops can reshape the genome with both negative and positive outcomes.     

Roles of Type 1A Topoisomerases in Genome Maintenance in Escherichia coli

In eukaryotes, type 1A topoisomerases (topos) act with RecQ-like helicases to maintain the stability of the genome. Despite having been the first type 1A enzymes to be discovered, much less is known about the involvement of the E. coli topo I (topA) and III (topB) enzymes in genome maintenance. These enzymes are thought to have distinct cellular functions: topo I regulates supercoiling and R-loop formation, and topo III is involved in chromosome segregation. To better characterize their roles in genome maintenance, we have used genetic approaches including suppressor screens, combined with microscopy for the examination of cell morphology and nucleoid shape. We show that topA mutants can suffer from growth-inhibitory and supercoiling-dependent chromosome segregation defects. These problems are corrected by deleting recA or recQ but not by deleting recJ or recO, indicating that the RecF pathway is not involved. Rather, our data suggest that RecQ acts with a type 1A topo on RecA-generated recombination intermediates because: 1-topo III overproduction corrects the defects and 2-recQ deletion and topo IIII overproduction are epistatic to recA deletion. The segregation defects are also linked to over-replication, as they are significantly alleviated by an oriC::aph suppressor mutation which is oriC-competent in topA null but not in isogenic topA⁺ cells. When both topo I and topo III are missing, excess supercoiling triggers growth inhibition that correlates with the formation of extremely long filaments fully packed with unsegregated and diffuse DNA. These phenotypes are likely related to replication from R-loops as they are corrected by overproducing RNase HI or by genetic suppressors of double topA rnhA mutants affecting constitutive stable DNA replication, dnaT::aph and rne::aph, which initiates from R-loops. Thus, bacterial type 1A topos maintain the stability of the genome (i) by preventing over-replication originating from oriC (topo I alone) and R-loops and (ii) by acting with RecQ.     

R环的形成及对基因组稳定性的影响

R-环是由一个RNA:DNA杂交体和一条单链状态的DNA分子共同组成的三链核酸结构。其中, RNA:DNA杂交体的形成起因于基因转录所合成的RNA分子不能与模板分开, 或RNA分子重新与一段双链DNA分子中的一条链杂交。在基因转录过程中, 当转录泡遇到富含G碱基的非模板链区或位于某些与人类疾病有关的三核苷酸卫星DNA时, 转录泡后方累积的负超螺旋可促进R环形成。同时, 新生RNA分子未被及时加工、成熟或未被快速转运到细胞质等因素也会催生R环。研究表明, 细胞拥有多种管理R环的方法, 可以有效地管理R环的形成和处理已经形成的R环, 以尽量避免R环对DNA复制、基因突变和同源重组产生不利影响。文章重点分析了R-环的形成机制及R环对DNA复制、基因突变和同源重组的影响, 并针对R-环诱导的DNA复制在某些三核苷酸重复扩增有关的神经肌肉退行性疾病发生过程中的作用进行了分析和讨论。     

Viability of Escherichia coli topA mutants lacking DNA topoisomerase I

The viability of the topA mutants lacking DNA topoisomerase I was thought to depend on the presence of compensatory mutations in Escherichia coli but not Salmonella typhimurium or Shigella flexneri. This apparent discrepancy in topA requirements in different bacteria prompted us to reexamine the topA requirements in E. coli. We find that E. coli strains bearing topA mutations, introduced into the strains by DNA-mediated gene replacement, are viable at 37 or 42 degrees C without any compensatory mutations. These topA(-) cells exhibit cold sensitivity in their growth, however, and this cold sensitivity phenotype appears to be caused by excessive negative supercoiling of intracellular DNA. In agreement with previous results (Zhu, Q., Pongpech, P., and DiGate, R. J. (2001) Proc. Natl. Acad. Sci. U. S. A. 98, 9766-9771), E. coli cells lacking both type IA DNA topoisomerases I and III are found to be nonviable, indicating that the two type IA enzymes share a critical cellular function.