Indispensability of Horizontally Transferred Genes and Its Impact on Bacterial Genome Streamlining

Why are certain bacterial genomes so small and compact? The adaptive genome streamlining hypothesis posits that selection acts to reduce genome size because of the metabolic burden of replicating DNA. To reveal the impact of genome streamlining on cellular traits, we reduced the Escherichia coli gen...

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Published inMolecular biology and evolution Vol. 33; no. 5; pp. 1257 - 1269
Main Authors Karcagi, Ildikó, Draskovits, Gábor, Umenhoffer, Kinga, Fekete, Gergely, Kovács, Károly, Méhi, Orsolya, Balikó, Gabriella, Szappanos, Balázs, Györfy, Zsuzsanna, Fehér, Tamás, Bogos, Balázs, Blattner, Frederick R, Pál, Csaba, Pósfai, György, Papp, Balázs
Format Journal Article
LanguageEnglish
Published United States Oxford University Press 01.05.2016
Subjects
Bacteria
Biological Evolution
Deoxyribonucleic acid
Discoveries
DNA
E coli
Escherichia coli
Escherichia coli - genetics
Evolution, Molecular
Gene Transfer, Horizontal
Genes
Genes, Bacterial
Genome Size
Genome, Bacterial
Genomes
Impact analysis
Nutrients
Phylogeny
genome complexity
genome reduction
adaptive genome streamlining
horizontal gene transfer
genome engineering
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Summary:Why are certain bacterial genomes so small and compact? The adaptive genome streamlining hypothesis posits that selection acts to reduce genome size because of the metabolic burden of replicating DNA. To reveal the impact of genome streamlining on cellular traits, we reduced the Escherichia coli genome by up to 20% by deleting regions which have been repeatedly subjects of horizontal transfer in nature. Unexpectedly, horizontally transferred genes not only confer utilization of specific nutrients and elevate tolerance to stresses, but also allow efficient usage of resources to build new cells, and hence influence fitness in routine and stressful environments alike. Genome reduction affected fitness not only by gene loss, but also by induction of a general stress response. Finally, we failed to find evidence that the advantage of smaller genomes would be due to a reduced metabolic burden of replicating DNA or a link with smaller cell size. We conclude that as the potential energetic benefit gained by deletion of short genomic segments is vanishingly small compared with the deleterious side effects of these deletions, selection for reduced DNA synthesis costs is unlikely to shape the evolution of small genomes.
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These authors contributed equally to this work.
Associate editor: Eduardo Rocha
Present address: Theoretical Biology, Institute of Integrative Biology (IBZ), ETH Zurich, Zurich, Switzerland
ISSN:0737-4038
1537-1719
DOI:10.1093/molbev/msw009