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Metabolic Footprinting As a Tool for Discriminating Between Brewing Yeasts

Overview
Journal Yeast
Publisher Wiley
Specialty Microbiology
Date 2007 May 31
PMID 17534862
Citations 20
Authors
Georgina A Pope
Donald A MacKenzie
Marianne Defernez
Miguel A M M Aroso
Linda J Fuller
Fred A Mellon
Warwick B Dunn
Marie Brown
Royston Goodacre
Douglas B Kell
Marcus E Marvin
Edward J Louis
Ian N Roberts
Affiliations
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Abstract

The characterization of industrial yeast strains by examining their metabolic footprints (exometabolomes) was investigated and compared to genome-based discriminatory methods. A group of nine industrial brewing yeasts was studied by comparing their metabolic footprints, genetic fingerprints and comparative genomic hybridization profiles. Metabolic footprinting was carried out by both direct injection mass spectrometry (DIMS) and gas chromatography time-of-flight mass spectrometry (GC-TOF-MS), with data analysed by principal components analysis (PCA) and canonical variates analysis (CVA). The genomic profiles of the nine yeasts were compared by PCR-restriction fragment length polymorphism (PCR-RFLP) analysis, genetic fingerprinting using amplified fragment length polymorphism (AFLP) analysis and microarray comparative genome hybridizations (CGH). Metabolomic and genomic analysis comparison of the nine brewing yeasts identified metabolomics as a powerful tool in separating genotypically and phenotypically similar strains. For some strains discrimination not achieved genomically was observed metabolomically.

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