A comprehensive review on epigenetic and epitranscriptomic-mediated regulation of antibiotic resistance

P. K. Giri, Shahil Alam, Madhav Dhakal
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Abstract

Antibiotic resistance is the leading cause of death globally, with a higher possibility of the emergence of highly resistant pathogens, leading to epidemics. Several antibiotic resistance mechanisms have been discovered, such as enhanced efflux of antibiotics, reduced influx of antibiotics, alteration of antibiotics or their targets, and adaptation to antibiotics. However, this mechanism cannot fully explain the development of antibiotic resistance because the genes associated with this mechanism have been elucidated. However, the factors governing their regulation are not yet fully understood. Recent studies have highlighted the epigenetic and epitranscriptomic roles of antibiotic resistance development-associated genes. Epigenetic modification is associated with DNA modification, whereas epitranscriptomic modification is associated with RNA modification to control gene expression by regulating various biological phenomena such as splicing, translation, and stability. Therefore, this review will focus on the discovery of epigenetic modifications, particularly by DNA methyltransferases, such as restriction-modification (R-M) systems associated with methyltransferases, orphan DNA methyltransferases, and nucleoid-associated proteins that contribute to the development of antibiotic resistance. This scrutinization further expands to epitranscriptomic modification of non-coding RNA, which has a role in the regulation of antibiotic resistance. Epitranscriptomic modification of ribosomal RNA (rRNA), which is a major target of antibiotics, has been well explored. while non-coding RNA such as cis and trans small non coding RNA, and riboswitches are poorly explored. This epigenetic and epitranscriptomic modification will help to understand the regulation of antibiotic resistance-associated genes, which will help to identify key regulators of antibiotic resistance, paving the way for new antibiotic discovery, leading to decreased antibiotic mortality globally.
表观遗传学和表观转录组介导的抗生素耐药性调控综述
抗生素耐药性是全球死亡的主要原因,高耐药性病原体的出现更有可能导致流行病。目前已发现几种抗生素耐药性机制,如抗生素外流增强、抗生素流入减少、抗生素或其靶点改变以及对抗生素的适应。然而,这种机制并不能完全解释抗生素耐药性的产生,因为与这种机制相关的基因已经被阐明。然而,它们的调控因素尚未完全明了。最近的研究强调了抗生素耐药性发展相关基因的表观遗传学和表观转录组学作用。表观遗传修饰与 DNA 修饰有关,而表转录组修饰与 RNA 修饰有关,通过调节剪接、翻译和稳定性等各种生物现象来控制基因表达。因此,本综述将重点关注表观遗传修饰的发现,尤其是 DNA 甲基转移酶的修饰,如与甲基转移酶相关的限制性修饰(R-M)系统、DNA 甲基转移酶孤儿以及导致抗生素耐药性产生的核糖体相关蛋白。这一研究进一步扩展到非编码 RNA 的表转录组修饰,这种修饰在抗生素耐药性的调控中发挥作用。核糖体 RNA(rRNA)是抗生素的主要靶标,其表观转录组学修饰已经得到了深入探讨。而对顺式和反式小非编码 RNA 以及核糖开关等非编码 RNA 的研究则较少。这种表观遗传学和表观转录组学修饰将有助于了解抗生素耐药性相关基因的调控,这将有助于确定抗生素耐药性的关键调控因子,为发现新的抗生素铺平道路,从而降低全球抗生素死亡率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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