During transcription, the topological conformation of double-helical DNA changes: As RNA polymerase moving forward, the DNA segment ahead of RNA polymerase is constrained with positive supercoils, and the DNA part behind transcription machinery becomes negatively supercoiled (i.e. defined as the “twin-domain supercoiling model”). Occasionally, the nascent RNA inserts into negatively supercoiled DNA helix and thus hybridizing to the template DNA. This structure is called R-loop, containing the RNA-DNA hybrid, non-template ssDNA, and junctions of ssDNA and dsDNA regions. Based on our and other previous studies, though R-loop plays critical roles in DNA replication, transcription and gene expression, but it is also a hazardous source with excess amount of R-loop that may lead to genome instability and poor cell growth. Therefore, there are factors in cells tightly regulate the R-loop formation. Here, using bacteria E. coli as a genetic model system and according to twin-domain supercoiling model, we decided to focus first on the topological regulatory enzymes such as DNA topoisomerase I (TopA) and gyrase, which can resolve negative and positive supercoils respectively. To detect the R-loop formation, we had employed the following 4 assays: (i) S9.6 antibody; (ii) AID-stimulated mutagenesis (ASM); (iii) bacterial filamentation and (iv) reporter DNA supercoiling assays. Specifically, the S9.6 antibody recognizing the RNA-DNA hybrid was used as a direct tool to detect R-loops. The ASM assay was established by ectopic expression of AID to induce deamination of cytosine to uracil on the single-stranded DNA (ssDNA) portion of R-loop, thus leading to higher mutation rates and ASM fold, those indirectly represent the amount of R-loop. As expected, we found that the TopA-deficient cells have a higher level of S9.6 signal and an elevated ASM fold, suggesting that TopA had a role in suppressing R-loop formation, possibly through its activity in specifically resolving negative supercoils. It is known that DNA damage activates SOS response, increases expression of repair factors and arrest of cell division (causing a filamentation phenotype). Consistent with the notion that R-loop might lead to DNA damage and activation of SOS response, we had found that TopA deficiency resulted in cellular filamentous morphology. Also, since negative supercoiling might allow the formation of R-loop, it is presumable that R-loop formation is accompanied with hyper-negative supercoils. We found that TopA deficiency appeared to be hyper-negatively supercoiled in supercoiling assay. In sum, we suggested that TopA plays a dominant role in the suppressing of R-loop formation. Surprisingly, in a gyrase temperature-sensitive mutant strain RFM445 [gyrB203 (Ts) gyrB221 (CouR)], the elevated RNA-DNA hybrid signal, cellular filamentation phenotypes and hyper-negative supercoiling were found in a higher cultivation temperature (37°C, presumably a lower gyrase activity condition) compared to the lower one (28°C). However, the cellular filamentous phenotype might also result from the gyrase deficiency and corresponding DNA replication, chromosome segregation problems … and so on. In conclusion, our results thus suggest that excess amount of R-loop might lead to elevated cellular filamentation, higher mutagenesis rate and hyper-negative supercoiling phenotypes. TopA functions mainly in inhibition of R-loop formation and thus plays a significant role in maintaining genome stability, while the functional role of gyrase on R-loop still needs further investigations.