Phenotypic Library-based Microbial Source Tracking Methods: Efficacy in the California Collaborative Study

Overview

Journal J Water Health

Specialties Environmental Health
Public Health

Date 2004 Sep 24

PMID 15382721

Citations 18

Authors

Valerie J Harwood

Bruce Wiggins

Charles Hagedorn

R D Ellender

Jan Gooch

James Kern

Mansour Samadpour

Annie C H Chapman

Brian J Robinson

Brian C Thompson

Affiliations

Soon will be listed here.

Abstract

As part of a larger microbial source tracking (MST) study, several laboratories used library-based, phenotypic subtyping techniques to analyse fecal samples from known sources (human, sewage, cattle, dogs and gulls) and blinded water samples that were contaminated with the fecal sources. The methods used included antibiotic resistance analysis (ARA) of fecal streptococci, enterococci, fecal coliforms and E. coli; multiple antibiotic resistance (MAR) and Kirby-Bauer antibiotic susceptibility testing of E. coli; and carbon source utilization for fecal streptococci and E. coli. Libraries comprising phenotypic patterns of indicator bacteria isolated from known fecal sources were used to predict the sources of isolates from water samples that had been seeded with fecal material from the same sources as those used to create the libraries. The accuracy of fecal source identification in the water samples was assessed both with and without a cut-off termed the minimum detectable percentage (MDP). The libraries (approximately 300 isolates) were not large enough to avoid the artefact of source-independent grouping, but some important conclusions could still be drawn. Use of a MDP decreased the percentage of false-positive source identifications, and had little effect on the high percentage of true-positives in the most accurate libraries. In general, the methods were more prone to false-positive than to false-negative errors. The most accurate method, with a true-positive rate of 100% and a false-positive rate of 39% when analysed with a MDP, was ARA of fecal streptococci. The internal accuracy of the libraries did not correlate with the accuracy of source prediction in water samples, showing that one should not rely solely on parameters such as the average rate of correct classification of a library to indicate its predictive capabilities.

Citing Articles

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Quantification of Microbial Source Tracking and Pathogenic Bacterial Markers in Water and Sediments of Tiaoxi River (Taihu Watershed).

Vadde K, McCarthy A, Rong R, Sekar R Front Microbiol. 2019; 10:699.

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Toward Forensic Uses of Microbial Source Tracking.

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Li X, Harwood V, Nayak B, Weidhaas J Appl Environ Microbiol. 2016; 82(5):1625-1635.

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Toolbox Approaches Using Molecular Markers and 16S rRNA Gene Amplicon Data Sets for Identification of Fecal Pollution in Surface Water.

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