Natural resource landscapes of a marine bacterium reveal distinct fitness‐determining genes across the genome

Summary Heterotrophic bacteria exploit diverse microhabitats in the ocean, from particles to transient gradients. Yet the degree to which genes and pathways can contribute to an organism's fitness on such complex and variable natural resource landscapes remains poorly understood. Here, we deter...

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Bibliographic Details
Published in:Environmental microbiology 2017-06, Vol.19 (6), p.2422-2433
Main Authors: Takemura, Alison F., Corzett, Christopher H., Hussain, Fatima, Arevalo, Philip, Datta, Manoshi, Yu, Xiaoqian, Le Roux, Frederique, Polz, Martin F.
Format: Article
Language:English
Subjects:
Algae
Alginates - metabolism
Alginic acid
Anabolism
Animals
Apocyclops
Aquatic crustaceans
Bacteria
Buffers
Carbohydrates
Cell walls
Clonal deletion
Colonization
Complexity
Composition
Copepoda - microbiology
Fitness
Fucus - microbiology
Gene deletion
Genes
Genetic Fitness - genetics
Genome, Bacterial - genetics
Genomes
Glucose
Glucose - metabolism
Habitats
Heterotrophic bacteria
Life Sciences
Microhabitat
Microhabitats
Mutation
Natural resources
Polysaccharides
Protein biosynthesis
Proteins
Redundancy
Reproductive fitness
Seaweed meal
Substrates
Transcription
Vibrio - genetics
Vibrio - growth & development
Vibrio - physiology
Walls
Waterborne diseases
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Summary:Summary Heterotrophic bacteria exploit diverse microhabitats in the ocean, from particles to transient gradients. Yet the degree to which genes and pathways can contribute to an organism's fitness on such complex and variable natural resource landscapes remains poorly understood. Here, we determine the gene‐by‐gene fitness of a generalist saprophytic marine bacterium (Vibrio sp. F13 9CS106) on complex resources derived from its natural habitats – copepods (Apocyclops royi) and brown algae (Fucus vesiculosus) – and as reference substrates, glucose and the polysaccharide alginate, derived from brown algal cell walls. We find that resource complexity strongly buffers fitness costs of mutations, and that anabolic rather than catabolic pathways are more stringently required, likely due to functional redundancy in the latter. Moreover, while carbohydrate‐rich algae requires several synthesis pathways, protein‐rich Apocyclops does not, suggesting this ancestral habitat for Vibrios is a replete medium with metabolically redundant substrates. We also identify a candidate fitness trade‐off for algal colonization: deletion of mshA increases mutant fitness. Our results demonstrate that gene fitness depends on habitat composition, and suggest that this generalist uses distinct resources in different natural habitats. The results further indicate that substrate replete conditions may lead to relatively relaxed selection on catabolic genes.
ISSN:1462-2912
1462-2920
DOI:10.1111/1462-2920.13765