Microbial domestication signatures of Lactococcus lactis can be reproduced by experimental evolution

Autor:	Johan E. T. van Hylckama Vlieg, Marjo J. C. Starrenburg, Herwig Bachmann, Michiel Kleerebezem, Douwe Molenaar
Přispěvatelé:	Molecular Cell Physiology, AIMMS
Rok vydání:	2011
Předmět:	Transposable element Transcription Genetic amino-acid biosynthesis dairy environment Biology Microbiology Genome Evolution Molecular Transcriptome Plasmid Microbiologie lactobacillus-bulgaricus Genetics Point Mutation Host-Microbe Interactomics SDG 2 - Zero Hunger Gene Genetics (clinical) streptococcus-thermophilus subsp lactis escherichia-coli populations Experimental evolution Research complete genome sequence mutator alleles Lactococcus lactis food and beverages Gene Expression Regulation Bacterial biology.organism_classification Transformation (genetics) Genetic Loci gene inactivation WIAS term experimental evolution Dairy Products Genome Bacterial
Zdroj:	Bachmann, H, Starrenburg, M J, Molenaar, D, Kleerebezem, M & van Hylckama Vlieg, J E T 2012, ' Microbial domestication signatures of Lactococcus lactis can be reproduced by experimental evolution. ', Genome Research, no. 22, pp. 115-124 . https://doi.org/10.1101/gr.121285.111 Genome Research 22 (2012) 1 Genome Research, 22(1), 115-124 Genome Research, 115-124. Cold Spring Harbor Laboratory Press ISSUE=22;STARTPAGE=115;ENDPAGE=124;ISSN=1088-9051;TITLE=Genome Research
ISSN:	1088-9051
DOI:	10.1101/gr.121285.111
Popis:	Experimental evolution is a powerful approach to unravel how selective forces shape microbial genotypes and phenotypes. To this date, the available examples focus on the adaptation to conditions specific to the laboratory. The lactic acid bacterium Lactococcus lactis naturally occurs on plants and in dairy environments, and it is proposed that dairy strains originate from the plant niche. Here we investigate the adaptation of a L. lactis strain isolated from a plant to a dairy niche by propagating it for 1000 generations in milk. Two out of three independently evolved strains displayed significantly increased acidification rates and biomass yields in milk. Genome resequencing, revealed six, seven, and 28 mutations in the three strains, including point mutations in loci related to amino acid biosynthesis and transport and in the gene encoding MutL, which is involved in DNA mismatch repair. Two strains lost a conjugative transposon containing genes important in the plant niche but dispensable in milk. A plasmid carrying an extracellular protease was introduced by transformation. Although improving growth rate and growth yield significantly, the plasmid was rapidly lost. Comparative transcriptome and phenotypic analyses confirmed that major physiological changes associated with improved growth in milk relate to nitrogen metabolism and the loss or down-regulation of several pathways involved in the utilization of complex plant polymers. Reproducing the transition from the plant to the dairy niche through experimental evolution revealed several genome, transcriptome, and phenotype signatures that resemble those seen in strains isolated from either niche.
Databáze:	OpenAIRE
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