RT Journal Article
SR Electronic
T1 Targeted chromosomal barcoding establishes direct genotype-phenotype associations for antibiotic resistance in <em>Mycobacterium abscessus</em>
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 2022.12.01.518803
DO 10.1101/2022.12.01.518803
A1 Calvet-Seral, Juan
A1 Crespo-Yuste, Estefanía
A1 Mathys, Vanessa
A1 Rodriguez-Villalobos, Hector
A1 Ceyssens, Pieter-Jan
A1 Martin, Anandi
A1 Gonzalo-Asensio, Jesús
YR 2022
UL http://biorxiv.org/content/early/2022/12/05/2022.12.01.518803.abstract
AB A bedaquiline resistant Mycobacterium abscessus isolate was sequenced and a candidate mutation in the atpE gene was identified as responsible for the antibiotic resistance phenotype. To establish a direct genotype-phenotype relationship of this D29A mutation, we developed a recombineering-based method consisting of the specific replacement of the desired mutation in the bacterial chromosome. As surrogate bacteria, we used two M. abscessus antibiotic susceptible strains: ATCC19977, and the SL541 clinical isolate. The allelic exchange substrates used in recombineering carried either the sole D29A mutation, or a genetic barcode of silent mutations in codons flanking the D29A mutation. After selection of bedaquiline resistant M. abscessus colonies, transformed with both substrates, we obtained equivalent numbers of recombinants. These resistant colonies were analyzed by allele-specific PCR, and Sanger sequencing, demonstrating that the presence of the genetic barcode is linked to the targeted incorporation of the desired mutation in its chromosomal location. All recombinants displayed the same minimal inhibitory concentration to bedaquiline than the original isolate, from which the D29A mutation was identified. Finally, to demonstrate the broad applicability of this method, we confirmed the association of bedaquiline resistance with the atpE A64P mutation, performed in independent M. abscessus strains and by independent researchers.