Benítez-Páez Alfonso, Cárdenas-Brito Sonia, Corredor Mauricio, Villarroya Magda, Armengod María Eugenia
Grupo de Análisis Bioinformático, GABi, Centro de Investigación y Desarrollo en Biotecnología, CIDBIO, Bogotá, D.C, Colombia.
Grupo de Genética y Bioquímica de Microorganismos, GEBIOMIC, Universidad de Antioquia, Medellín, Colombia.
Biomedica. 2014 Apr;34 Suppl 1:41-9. doi: 10.1590/S0120-41572014000500006.
Aminoglycosides like streptomycin are well-known for binding at specific regions of ribosome RNA and then acting as translation inhibitors. Nowadays, several pathogens have been detected to acquire an undefined strategy involving mutation at non structural ribosome genes like those acting as RNA methylases. rsmG is one of those genes which encodes an AdoMet-dependent methyltransferase responsible for the synthesis of m 7 G527 in the 530 loop of bacterial 16S rRNA. This loop is universally conserved, plays a key role in ribosomal accuracy, and is a target for streptomycin binding. Loss of the m 7 G527 modification confers low-level streptomycin resistance and may affect ribosomal functioning.
After taking into account genetic information indicating that some clinical isolates of human pathogens show streptomycin resistance associated with mutations at rsmG , we decided to explore new hot spots for mutation capable of impairing the RsmG in vivo function and of promoting low-level streptomycin resistance.
To gain insights into the molecular and genetic mechanism of acquiring this aminoglycoside resistance phenotype and the emergence of high-level streptomycin resistance in rsmG mutants, we mutated Escherichia coli rsmG and also performed a genotyping study on rpsL from several isolates showing the ability to grow at higher streptomycin concentrations than parental strains.
We found that the mutations at rpsL were preferentially present in these mutants, and we observed a clear synergy between rsmG and rpsL genes to induce streptomycin resistance.
We contribute to understand a common mechanism that is probably transferable to other ribosome RNA methylase genes responsible for modifications at central sites for ribosome function.
像链霉素这样的氨基糖苷类药物因能结合核糖体RNA的特定区域并作为翻译抑制剂而闻名。如今,已检测到几种病原体获得了一种不明策略,涉及核糖体非结构基因的突变,如那些作为RNA甲基转移酶的基因。rsmG就是其中一个基因,它编码一种依赖S-腺苷甲硫氨酸的甲基转移酶,负责在细菌16S rRNA的530环中合成m7G527。这个环普遍保守,在核糖体准确性中起关键作用,并且是链霉素结合的靶点。m7G527修饰的缺失赋予低水平链霉素抗性,并可能影响核糖体功能。
考虑到遗传信息表明人类病原体的一些临床分离株显示出与rsmG突变相关的链霉素抗性,我们决定探索能够损害RsmG体内功能并促进低水平链霉素抗性的新突变热点。
为了深入了解获得这种氨基糖苷类抗性表型的分子和遗传机制以及rsmG突变体中高水平链霉素抗性的出现,我们对大肠杆菌rsmG进行了突变,并对来自几个分离株的rpsL进行了基因分型研究,这些分离株显示出在比亲本菌株更高的链霉素浓度下生长的能力。
我们发现rpsL突变优先存在于这些突变体中,并且我们观察到rsmG和rpsL基因之间在诱导链霉素抗性方面有明显的协同作用。
我们有助于理解一种可能可转移到其他负责核糖体功能中心位点修饰的核糖体RNA甲基转移酶基因的共同机制。
