Development of an amplicon nanopore sequencing strategy for detection of mutations conferring intermediate resistance to vancomycin in Staphylococcus aureus strains

Abstract

AbstractStaphylococcus aureus is a major cause of bacteremia and other hospital-acquired infections. The cell-wall active antibiotic vancomycin is commonly used to treat both methicillin-resistant (MRSA) and sensitive (MSSA) infections, but vancomycin intermediate S. aureus (VISA) variants can arise through de novo mutations. Here we performed pilot experiments to develop a combined PCR/long-read sequencing-based method for detection of previously known VISA-causing mutations. We amplified 16 genes (walR, walK, rpoB, graR, graS, vraF, vraG, stpI, vraR, vraS, agrA, sarA, clpP, ccpA, prsA, and yvqF) known from prior studies to be associated with mutations responsible for VISA as 10 amplicons and sequenced amplicon pools as long-reads with Oxford Nanopore adapter ligation on Flongle flow cells. We then detected mutations by mapping reads against a parental consensus or known reference sequence and comparing called variants against a database of known VISA mutations from laboratory selection. There was high (>1000x) coverage of each amplicon in the pool, no relationship between amplicon length and coverage, and the ability to detect the causative mutation (walK 646C>G) in a VISA mutant derived from the USA300 strain (N384-3 from parental strain N384). Mixing mutant (N384-3) and parental (N384) DNA at various ratios from 0 to 1 mutant suggested a mutation detection threshold of roughly the average minor allele frequency of 6.5% at 95% confidence (two standard errors above mean mutation frequency). The study lays the groundwork for direct S. aureus antibiotic phenotype inference using rapid nanopore sequencing from clinical samples.ImportanceBacteremia mortality is known to increase rapidly with time after infection, making rapid diagnostics and treatment necessary. Successful treatment depends on correct administration of antibiotics based on knowledge of strain antibiotic susceptibility. Staphylococcus aureus is a major causative agent of bacteremia and is also increasingly antibiotic resistant. In this work, we develop a method to improve detection of a complex, polygenic antibiotic resistance phenotype in S. aureus, vancomycin-intermediate resistance (VISA) through long-read genomic sequencing of amplicons representing genes most commonly mutated in VISA selection. This method both speeds up VISA determination relative to purely culture-based detection and incorporates the most comprehensive database of VISA genetic determinants known to date.