Antibiotics Resistance Genes
DOI:
https://doi.org/10.33687/ricosbiol.02.02.0031Keywords:
Antibiotic. resistance, resistance genes, horizontal gene switch, Cellular genetic factors, Plasmid, environmental tracking, antimicrobial resistance, one healtAbstract
Antibiotic resistance has become one of the most pressing worldwide fitness issues, jeopardizing the effectiveness of contemporary medication. Resistance genes, commonly observed in cellular genetic factors such as plasmids, transposons, and integrons, are imperative to the spread of resistance across bacterial populations. Those genes allow the microorganism to continue to exist with exposure to antibiotics, rendering well-known treatments useless. The overuse and misuse of antibiotics in human medication, agriculture, and veterinary practices have contributed significantly to the fast emergence of resistant lines. The resistance mechanisms encompass antibiotic degradation by enzymes, modification of antibiotic objectives, reduced drug uptake, and activation of efflux pumps that expel antibiotics from the bacterial cell.
Horizontal gene transfer (HGT), through approaches that include conjugation, transformation, and transduction, permits the big distribution of resistance genes across bacterial species, enhancing their patience in the environment. The continuous movement of resistance genes among people, animals, and the environment complicates efforts to govern resistance. Advances in molecular biology techniques, such as subsequent-generation sequencing, have facilitated the identification and characterization of resistance genes, offering precious insights into their diversity, evolution, and capacity reservoirs. Environmental monitoring has revealed the presence of resistance genes in various ecosystems, including water, soil, flora, and fauna, emphasizing the interconnected nature of human, animal, and environmental health—referred to as the only health technique. Combating antibiotic resistance requires a coordinated, multidisciplinary effort that integrates surveillance, stewardship, and the improvement of novel healing techniques.
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Copyright (c) 2024 Rehan Naqvi, Dr. Sambreen Zameer Khanzada, Dr. Zameer Ahmed Khanzada, Dr. Geetha Kumari Das
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