Linking Plasmid-based Beta-lactamases to Their Bacterial Hosts Using Single-cell Fusion PCR

Overview

Journal Elife

Specialty Biology

Date 2021 Jul 20

PMID 34282723

Citations 14

Authors

Peter J Diebold

Felicia N New

Michael Hovan

Michael J Satlin

Ilana L Brito

Affiliations

Soon will be listed here.

Abstract

The horizonal transfer of plasmid-encoded genes allows bacteria to adapt to constantly shifting environmental pressures, bestowing functional advantages to their bacterial hosts such as antibiotic resistance, metal resistance, virulence factors, and polysaccharide utilization. However, common molecular methods such as short- and long-read sequencing of microbiomes cannot associate extrachromosomal plasmids with the genome of the host bacterium. Alternative methods to link plasmids to host bacteria are either laborious, expensive, or prone to contamination. Here we present the One-step Isolation and Lysis PCR (OIL-PCR) method, which molecularly links plasmid-encoded genes with the bacterial 16S rRNA gene via fusion PCR performed within an emulsion. After validating this method, we apply it to identify the bacterial hosts of three clinically relevant beta-lactamases within the gut microbiomes of neutropenic patients, as they are particularly vulnerable multidrug-resistant infections. We successfully detect the known association of a multi-drug resistant plasmid with , as well as the novel associations of two low-abundance genera, and . Further investigation with OIL-PCR confirmed that our detection of is due to its physical association with as opposed to directly harboring the beta-lactamase genes. Here we put forth a robust, accessible, and high-throughput platform for sensitively surveying the bacterial hosts of mobile genes, as well as detecting physical bacterial associations such as those occurring within biofilms and complex microbial communities.

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