Fast and Accurate Bacterial Species Identification in Urine Specimens Using LC-MS/MS Mass Spectrometry and Machine Learning

Fast identification of microbial species in clinical samples is essential to provide an appropriate antibiotherapy to the patient and reduce the prescription of broad-spectrum antimicrobials leading to antibioresistances. MALDI-TOF-MS technology has become a tool of choice for microbial identificati...

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Autores principales: Roux-Dalvai, Florence, Gotti, Clarisse, Leclercq, Mickaël, Hélie, Marie-Claude, Boissinot, Maurice, Arrey, Tabiwang N., Dauly, Claire, Fournier, Frédéric, Kelly, Isabelle, Marcoux, Judith, Bestman-Smith, Julie, Bergeron, Michel G., Droit, Arnaud
Formato: Online Artículo Texto
Lenguaje:English
Publicado: The American Society for Biochemistry and Molecular Biology 2019
Materias:
Technological Innovation and Resources
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6885708/
https://www.ncbi.nlm.nih.gov/pubmed/31585987
http://dx.doi.org/10.1074/mcp.TIR119.001559
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author Roux-Dalvai, Florence
Gotti, Clarisse
Leclercq, Mickaël
Hélie, Marie-Claude
Boissinot, Maurice
Arrey, Tabiwang N.
Dauly, Claire
Fournier, Frédéric
Kelly, Isabelle
Marcoux, Judith
Bestman-Smith, Julie
Bergeron, Michel G.
Droit, Arnaud
author_facet Roux-Dalvai, Florence
Gotti, Clarisse
Leclercq, Mickaël
Hélie, Marie-Claude
Boissinot, Maurice
Arrey, Tabiwang N.
Dauly, Claire
Fournier, Frédéric
Kelly, Isabelle
Marcoux, Judith
Bestman-Smith, Julie
Bergeron, Michel G.
Droit, Arnaud
author_sort Roux-Dalvai, Florence
collection PubMed
description Fast identification of microbial species in clinical samples is essential to provide an appropriate antibiotherapy to the patient and reduce the prescription of broad-spectrum antimicrobials leading to antibioresistances. MALDI-TOF-MS technology has become a tool of choice for microbial identification but has several drawbacks: it requires a long step of bacterial culture before analysis (≥24 h), has a low specificity and is not quantitative. We developed a new strategy for identifying bacterial species in urine using specific LC-MS/MS peptidic signatures. In the first training step, libraries of peptides are obtained on pure bacterial colonies in DDA mode, their detection in urine is then verified in DIA mode, followed by the use of machine learning classifiers (NaiveBayes, BayesNet and Hoeffding tree) to define a peptidic signature to distinguish each bacterial species from the others. Then, in the second step, this signature is monitored in unknown urine samples using targeted proteomics. This method, allowing bacterial identification in less than 4 h, has been applied to fifteen species representing 84% of all Urinary Tract Infections. More than 31,000 peptides in 190 samples were quantified by DIA and classified by machine learning to determine an 82 peptides signature and build a prediction model. This signature was validated for its use in routine using Parallel Reaction Monitoring on two different instruments. Linearity and reproducibility of the method were demonstrated as well as its accuracy on donor specimens. Within 4h and without bacterial culture, our method was able to predict the predominant bacteria infecting a sample in 97% of cases and 100% above the standard threshold. This work demonstrates the efficiency of our method for the rapid and specific identification of the bacterial species causing UTI and could be extended in the future to other biological specimens and to bacteria having specific virulence or resistance factors.
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spelling pubmed-68857082019-12-03 Fast and Accurate Bacterial Species Identification in Urine Specimens Using LC-MS/MS Mass Spectrometry and Machine Learning Roux-Dalvai, Florence Gotti, Clarisse Leclercq, Mickaël Hélie, Marie-Claude Boissinot, Maurice Arrey, Tabiwang N. Dauly, Claire Fournier, Frédéric Kelly, Isabelle Marcoux, Judith Bestman-Smith, Julie Bergeron, Michel G. Droit, Arnaud Mol Cell Proteomics Technological Innovation and Resources Fast identification of microbial species in clinical samples is essential to provide an appropriate antibiotherapy to the patient and reduce the prescription of broad-spectrum antimicrobials leading to antibioresistances. MALDI-TOF-MS technology has become a tool of choice for microbial identification but has several drawbacks: it requires a long step of bacterial culture before analysis (≥24 h), has a low specificity and is not quantitative. We developed a new strategy for identifying bacterial species in urine using specific LC-MS/MS peptidic signatures. In the first training step, libraries of peptides are obtained on pure bacterial colonies in DDA mode, their detection in urine is then verified in DIA mode, followed by the use of machine learning classifiers (NaiveBayes, BayesNet and Hoeffding tree) to define a peptidic signature to distinguish each bacterial species from the others. Then, in the second step, this signature is monitored in unknown urine samples using targeted proteomics. This method, allowing bacterial identification in less than 4 h, has been applied to fifteen species representing 84% of all Urinary Tract Infections. More than 31,000 peptides in 190 samples were quantified by DIA and classified by machine learning to determine an 82 peptides signature and build a prediction model. This signature was validated for its use in routine using Parallel Reaction Monitoring on two different instruments. Linearity and reproducibility of the method were demonstrated as well as its accuracy on donor specimens. Within 4h and without bacterial culture, our method was able to predict the predominant bacteria infecting a sample in 97% of cases and 100% above the standard threshold. This work demonstrates the efficiency of our method for the rapid and specific identification of the bacterial species causing UTI and could be extended in the future to other biological specimens and to bacteria having specific virulence or resistance factors. The American Society for Biochemistry and Molecular Biology 2019-12 2019-10-04 /pmc/articles/PMC6885708/ /pubmed/31585987 http://dx.doi.org/10.1074/mcp.TIR119.001559 Text en © 2019 Roux-Dalvai et al. Published by The American Society for Biochemistry and Molecular Biology, Inc. https://creativecommons.org/licenses/by/4.0/Author's Choice—Final version open access under the terms of the Creative Commons CC-BY license (https://creativecommons.org/licenses/by/4.0/) .
spellingShingle Technological Innovation and Resources
Roux-Dalvai, Florence
Gotti, Clarisse
Leclercq, Mickaël
Hélie, Marie-Claude
Boissinot, Maurice
Arrey, Tabiwang N.
Dauly, Claire
Fournier, Frédéric
Kelly, Isabelle
Marcoux, Judith
Bestman-Smith, Julie
Bergeron, Michel G.
Droit, Arnaud
Fast and Accurate Bacterial Species Identification in Urine Specimens Using LC-MS/MS Mass Spectrometry and Machine Learning
title Fast and Accurate Bacterial Species Identification in Urine Specimens Using LC-MS/MS Mass Spectrometry and Machine Learning
title_full Fast and Accurate Bacterial Species Identification in Urine Specimens Using LC-MS/MS Mass Spectrometry and Machine Learning
title_fullStr Fast and Accurate Bacterial Species Identification in Urine Specimens Using LC-MS/MS Mass Spectrometry and Machine Learning
title_full_unstemmed Fast and Accurate Bacterial Species Identification in Urine Specimens Using LC-MS/MS Mass Spectrometry and Machine Learning
title_short Fast and Accurate Bacterial Species Identification in Urine Specimens Using LC-MS/MS Mass Spectrometry and Machine Learning
title_sort fast and accurate bacterial species identification in urine specimens using lc-ms/ms mass spectrometry and machine learning
topic Technological Innovation and Resources
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6885708/
https://www.ncbi.nlm.nih.gov/pubmed/31585987
http://dx.doi.org/10.1074/mcp.TIR119.001559
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