Lee Hak Jin, Jhang Seong Tae, Jin Hyung Jong
Department of Life Science, Korea University Graduate School, Seoul 02841, Korea.
Department of Bioscience and Biotechnology, The University of Suwon, Whasung City 18323, Korea.
Antibiotics (Basel). 2021 Mar 5;10(3):264. doi: 10.3390/antibiotics10030264.
Macrolide-lincosamide-streptogramin B antibiotic resistance occurs through the action of erythromycin ribosome methylation (Erm) family proteins, causing problems due to their prevalence and high minimal inhibitory concentration, and feasibilities have been sought to develop inhibitors. Erms exhibit high conservation next to the N-terminal end region (NTER) as in ErmS, 64SQNF67. Side chains of homologous S, Q and F in ErmC' are surface-exposed, located closely together and exhibit intrinsic flexibility; these residues form a motif X. In S64 mutations, S64G, S64A and S64C exhibited 71%, 21% and 20% activity compared to the wild-type, respectively, conferring cell resistance. However, mutants harboring larger side chains did not confer resistance and retain the methylation activity in vitro. All mutants of Q65, Q65N, Q65E, Q65R, and Q65H lost their methyl group transferring activity in vivo and in vitro. At position F67, a size reduction of side-chain (F67A) or a positive charge (F67H) greatly reduced the activity to about 4% whereas F67L with a small size reduction caused a moderate loss, more than half of the activity. The increased size by F67Y and F67W reduced the activity by about 75%. In addition to stabilization of the cofactor, these amino acids could interact with substrate RNA near the methylatable adenine presumably to be catalytically well oriented with the SAM (S-adenosyl-L-methionine). These amino acids together with the NTER beside them could serve as unique potential inhibitor development sites. This region constitutes a divergent element due to the NTER which has variable length and distinct amino acids context in each Erm. The NTER or part of it plays critical roles in selective recognition of substrate RNA by Erms and this presumed target site might assume distinct local structure by induced conformational change with binding to substrate RNA and SAM, and contribute to the specific recognition of substrate RNA.
大环内酯-林可酰胺-链阳菌素B抗生素耐药性是通过红霉素核糖体甲基化(Erm)家族蛋白的作用产生的,由于其普遍性和高最小抑菌浓度而引发问题,因此人们一直在寻求开发抑制剂的可行性。Erm在N端区域(NTER)旁表现出高度保守性,如在ErmS中为64SQNF67。ErmC'中同源的S、Q和F的侧链暴露于表面,紧密相邻且具有内在灵活性;这些残基形成基序X。在S64突变中,S64G、S64A和S64C与野生型相比分别表现出71%、21%和20%的活性,赋予细胞抗性。然而,带有较大侧链的突变体不赋予抗性,并在体外保留甲基化活性。Q65的所有突变体,即Q65N、Q65E、Q65R和Q65H,在体内和体外均失去了甲基转移活性。在F67位置,侧链尺寸减小(F67A)或带正电荷(F67H)会使活性大幅降低至约4%,而尺寸略有减小的F67L导致活性中度丧失,超过一半。F67Y和F67W使尺寸增加导致活性降低约75%。除了稳定辅因子外,这些氨基酸可能与可甲基化腺嘌呤附近的底物RNA相互作用,推测与SAM(S-腺苷-L-甲硫氨酸)具有良好的催化取向。这些氨基酸与其旁边的NTER一起可作为独特的潜在抑制剂开发位点。由于NTER在每个Erm中具有可变长度和不同的氨基酸背景,该区域构成了一个不同的元件。NTER或其一部分在Erm对底物RNA的选择性识别中起关键作用,并且这个假定靶位点可能通过与底物RNA和SAM结合引起的诱导构象变化呈现出不同的局部结构,并有助于底物RNA的特异性识别。
