Kothari Ashish, Kumar Prashant, Gaurav Amit, Kaushal Karanvir, Pandey Atul, Yadav Shashi Ranjan Mani, Jain Neeraj, Omar Balram Ji
Department of Microbiology, All India Institute of Medical Sciences, Rishikesh 249203, India.
Department of Biochemistry, All India Institute of Medical Sciences, Rishikesh 249203, India.
J Hazard Mater. 2023 Feb 5;443(Pt B):130260. doi: 10.1016/j.jhazmat.2022.130260. Epub 2022 Oct 27.
The emergence of multidrug-resistant bacteria is currently posing a significant threat to global public health. By testing for resistance to different antibiotic classes, we discovered that the majority of clinical bacteria are multidrug-resistant. These clinical multidrug-resistant species have antibiotic resistance genes on their plasmids that can be horizontally transferred to various antibiotic susceptible environmental bacterial species, resulting in antibiotic-resistant transconjugates. Furthermore, we discovered that the presence of an optimal concentration of antibiotics or heavy metal (arsenic) facilitates horizontal gene transfer through the formation of transconjugants. Notably, the addition of a conjugation inhibitor (2-hexadecynoic acid, a synthetic fatty acid) completely blocked the formation of antibiotic or arsenic-induced transconjugants. We discovered a high level of arsenic in water from the Shukratal region, Uttarakhand, India, which corresponded to a high serum level of arsenic in clinically infected individuals from the Shukratal region compared to other locations in Uttarakhand. Importantly, bacterial strains isolated from infected people who drink water from the Shukratal region with high arsenic levels were found to be more antibiotic-resistant than strains isolated from other sites. We discovered that bacterial strains isolated from individuals with high serum arsenic levels are significantly more resistant to antibiotics than individuals with low serum arsenic levels within the Shurkratal. This research sheds light on imminent threats to global health in which improper clinical, industrial, and other waste disposal, increased antibiotic concentrations in the environment, and increased human interference can easily transform commensal and pathogenic bacteria found in environmental niches into life-threatening multidrug-resistant superbugs.
多重耐药菌的出现目前正对全球公共卫生构成重大威胁。通过检测对不同抗生素类别的耐药性,我们发现大多数临床细菌具有多重耐药性。这些临床多重耐药菌在其质粒上带有抗生素耐药基因,这些基因可水平转移至各种对抗生素敏感的环境细菌物种,从而产生耐药性接合子。此外,我们发现最佳浓度的抗生素或重金属(砷)的存在会通过接合子的形成促进水平基因转移。值得注意的是,添加一种接合抑制剂(2-十六碳炔酸,一种合成脂肪酸)可完全阻断抗生素或砷诱导的接合子的形成。我们在印度北阿坎德邦舒克拉塔尔地区的水中发现了高浓度的砷,与北阿坎德邦的其他地区相比,该地区临床感染个体的血清砷水平也较高。重要的是,从饮用高砷水平的舒克拉塔尔地区水的感染者中分离出的细菌菌株比从其他地点分离出的菌株更具抗生素耐药性。我们发现,在舒克拉塔尔地区,从血清砷水平高的个体中分离出的细菌菌株比血清砷水平低的个体对抗生素的耐药性明显更强。这项研究揭示了对全球健康的紧迫威胁,即临床、工业和其他废物处理不当、环境中抗生素浓度增加以及人类干扰增加,可能轻易地将环境生态位中发现的共生菌和病原菌转变为危及生命的多重耐药超级细菌。