A 4.6 kb Staphylococcus aureus DNA fragment containing DNA gyrase-like genes (grlA and grlB) was cloned and sequenced. The proteins GrlA and GrlB exhibit more than 30% identity with E. coli DNA topoisomerase IV subunits and with the gyrase subunits from S. aureus and Escherichia coli. The combined E. coli cell extracts of GrlA and GrlB overproducing strains catalysed ATP-dependent relaxation and decatenation specific to DNA topoisomerase IV. The temperature-sensitive phenotype of Salmonella typhimurium parC and parE mutants was complemented by the S. aureus grlA and grlB genes, when the two genes were co-expressed. These results show that GrlA and GrlB are the subunits of S. aureus DNA topoisomerase IV. The GyrA subunit of DNA gyrase has been previously defined as a primary target of quinolones based on genetic and biochemical experiments essentially carried out in E. coli. Single-point mutations occurring in the 'quinolone resistance-determining region' (QRDR) of GyrA were found in bacteria exhibiting quinolone resistance, the most common mutation being a substitution of Ser-83 on the E. coli GyrA sequence. We analysed eight S. aureus fluoroquinolone-resistant clinical isolates and observed that mutations in the QRDR of GyrA are not present in the low-quinolone-resistant isolates. In contrast, Ser-80 of GrlA, which corresponds to Ser-83 of E. coli GyrA, is substituted to Phe or Tyr in both high- and low-quinolone-resistant isolates. We propose that DNA topoisomerase IV is a primary target of fluoroquinolones in S. aureus.
Fluoroquinolone-resistant mutants were obtained in vitro from Staphylococcus aureus RN4220 by stepwise selection on increasing concentrations of ciprofloxacin. Results from sequence analysis of the quinolone resistance-determining region of GyrA and of the corresponding region of GrlA, the DNA topoisomerase IV subunit, showed an alteration of Ser-80 to Tyr (corresponding to Ser-83 of Escherichia coli GyrA) or Glu-84 to Lys in GrlA of both low-and high-level quinolone-resistant mutants. Second-step mutants were found to have, in addition to a mutation in grlA, reduced accumulation of norfloxacin or an alteration in GyrA at Ser-84 to Leu or Glu-88 to Lys. Third-step mutants derived from second-step mutants with reduced accumulation were found to have a mutation in gyrA. The results from this study demonstrated that mutations in gyrA or mutations leading to reduced drug accumulation occur after alteration of GrlA, supporting the previous findings
Staphylococcus aureus gyrA and gyrB genes encoding DNA gyrase subunits were cloned and coexpressed in Escherichia coli under the control of the T7 promoter-T7 RNA polymerase system, leading to soluble gyrase which was purified to homogeneity. Purified gyrase was catalytically indistinguishable from the gyrase purified from S. aureus and did not contain detectable amounts of topoisomerases from the E. coli host. Topoisomerase IV subunits GrlA and GrlB from S. aureus were also expressed in E. coli and were separately purified to apparent homogeneity. Topoisomerase IV, which was reconstituted by mixing equimolar amounts of GrlA and GrlB, had both ATP-dependent decatenation and DNA relaxation activities in vitro. This enzyme was more sensitive than gyrase to inhibition by typical fluoroquinolone antimicrobial agents such as ciprofloxacin or sparfloxacin, adding strong support to genetic studies which indicate that topoisomerase IV is the primary target of fluoroquinolones in S. aureus. The results obtained with ofloxacin suggest that this fluoroquinolone could also primarily target gyrase. No cleavable complex could be detected with S. aureus gyrase upon incubation with ciprofloxacin or sparfloxacin at concentrations which fully inhibit DNA supercoiling. This suggests that these drugs do not stabilize the open DNA-gyrase complex, at least under standard in vitro incubation conditions, but are more likely to interfere primarily with the DNA breakage step, contrary to what has been reported with E. coli gyrase. Both S. aureus gyrase-catalyzed DNA supercoiling and S. aureus topoisomerase IV-catalyzed decatenation were dramatically stimulated by potassium glutamate or aspartate (500- and 50-fold by 700 and 350 mM glutamate, respectively), whereas topoisomerase IV-dependent DNA relaxation was inhibited 3-fold by 350 mM glutamate. The relevance of the effect of dicarboxylic amino acids on the activities of type II topoisomerases is discussed with regard to the intracellular osmolite composition of S. aureus.
The extraordinary maturation in high-throughput sequencing technologies has revealed the existence of a complex network of transcripts in eukaryotic organisms, including thousands of long noncoding (lnc) RNAs with little or no protein-coding capacity. Subsequent discoveries have shown that lncRNAs participate in a wide range of molecular processes, controlling gene expression and protein activity though direct interactions with proteins, DNA or other RNA molecules. Although significant advances have been achieved in the understanding of lncRNA biology in the animal kingdom, the functional characterization of plant lncRNAs is still in its infancy and remains a major challenge. In this review, we report emerging functional and mechanistic paradigms of plant lncRNAs and partner molecules, and discuss how cutting-edge technologies may help to identify and classify yet uncharacterized transcripts into functional groups.
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