BACKGROUND The drug resistance rate of clinical Helicobacter pylori ( H. pylori ) isolates has increased. However, the mechanism of drug resistance remains unclear. In this study, drug-resistant H. pylori strains were isolated from different areas and different populations of Chinese for genomic analysis. AIM To investigate drug-resistant genes in H. pylori and find the genes for the early diagnosis of clarithromycin resistance. METHODS Three drug-resistant H. pylori strains were isolated from patients with gastritis in Bama County, China. Minimal inhibitory concentrations of clarithromycin, metronidazole, and levofloxacin were determined and complete genome sequencing was performed with annotation. Hp1181 and hp1184 genes were found in these strains and then detected by reverse transcription polymerase chain reaction. The relationships between hp1181 or hp1184 and clarithromycin resistance were ascertained with gene mutant and drug-resistant strains. The homology of the strains with hp26695 was assessed through complete genome detection and identification. Differences in genome sequences, gene quantity, and gene characteristics were detected amongst the three strains. Prediction and analysis of the function of drug-resistant genes indicated that the RNA expression of hp1181 and hp1184 increased in the three strains, which was the same in the artificially induced clarithromycin-resistant bacteria. After gene knockout, the drug sensitivity of the strains was assessed. RESULTS The strains showing a high degree of homology with hp26695 , hp1181 , and hp1184 genes were found in these strains; the expression of the genes hp1184 and hp1181 was associated with clarithromycin resistance. CONCLUSION Hp1181 and hp1184 mutations may be the earliest and most persistent response to clarithromycin resistance, and they may be the potential target genes for the diagnosis, prevention, and treatment of clarithromycin resistance.
Background: The resistance rate of clinical Helicobacter pylori (Hp) isolates has increased, however, the mechanism of drug resistance is unclear. In this study, we isolated drug-resistant Hp strains isolated from different areas and different populations of China for genomic analysis.Objectives: The aim of this study was to investigate drug resistance in Hp from Bama County, Guangxi, China.Methods: Minimal inhibitory concentrations (MICs) of clarithromycin, metronidazole and levofloxacin were determined and complete genome sequencing was performed with annotation. The presence of hp1181 and hp1184 genes was detected by RT-PCR. The relationships between hp1181, hp1184 and clarithromycin resistance were confirmed by gene mutation and drug-resistant strains. Results: Three drug-resistant Hp strains were isolated from patients with gastritis in Bama County. The strains showed a high degree of homology with hp26695 through complete genome detection and identification. Differences in genome sequences, gene quantity and gene characteristics were detected amongst the three strains. Prediction and analysis of the function on drug-resistant genes indicated that the RNA expression of hp1181 and hp1184 increased in the three strains that were the same in the artificially induced clarithromycin-resistant bacteria. After gene knockout, the drug sensitivity of the strains increased significantly.Conclusions: The expressions of the genes hp1184 and hp1181 were associated with clarithromycin resistance in the Hp from Bama, Guangxi.
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