Abstract
It is important that antibiotics prescriptions are based on antimicrobial susceptibility data to ensure effective treatment outcomes. The increasing availability of next-generation sequencing, bacterial whole genome sequencing (WGS) can facilitate a more reliable and faster alternative to traditional phenotyping for the detection and surveillance of AMR. This work proposes a machine learning approach that can predict the minimum inhibitory concentration (MIC) for a given antibiotic, here ciprofloxacin, on the basis of both genome-wide mutation profiles and profiles of acquired antimicrobial resistance genes. We analysed 704 Escherichia coli genomes combined with their respective MIC measurements for ciprofloxacin originating from different countries. The four most important predictors found by the model, mutations in gyrA residues Ser83 and Asp87, a mutation in parC residue Ser80 and presence of the qnrS1 gene, have been experimentally validated before. Using only these four predictors in a linear regression model, 65% and 93% of the test samples’ MIC were correctly predicted within a two- and a four-fold dilution range, respectively. The presented work does not treat machine learning as a black box model concept, but also identifies the genomic features that determine susceptibility. The recent progress in WGS technology in combination with machine learning analysis approaches indicates that in the near future WGS of bacteria might become cheaper and faster than a MIC measurement.
Highlights
It is important that antibiotics prescriptions are based on antimicrobial susceptibility data to ensure effective treatment outcomes
We focus on predicting a quantitative measure of ciprofloxacin resistance (MIC) for a geographically diverse population of E. coli using machine learning
We present an accurate method for predicting ciprofloxacin resistance for E. coli
Summary
It is important that antibiotics prescriptions are based on antimicrobial susceptibility data to ensure effective treatment outcomes. The increasing availability of next-generation sequencing, bacterial whole genome sequencing (WGS) can facilitate a more reliable and faster alternative to traditional phenotyping for the detection and surveillance of AMR. This work proposes a machine learning approach that can predict the minimum inhibitory concentration (MIC) for a given antibiotic, here ciprofloxacin, on the basis of both genome-wide mutation profiles and profiles of acquired antimicrobial resistance genes. More advanced analysis methods such as machine learning need to be applied to allow for accurate prediction. Machine learning has been applied to predict resistance from WGS data in several settings To date, these methods have been restricted mostly to assign bacteria to binary categories, i.e. susceptible or non-susceptible[8,12,13,14,15,16,17,18]. A resistance prediction method would preferably output a continuous estimate of resistance similar to MIC, instead of binary classification (S/R), as a number of studies already p roposed[19,20,21,22]
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