Genomic adaptations in information processing underpin trophic strategy in a whole-ecosystem nutrient enrichment experiment

Okie, Jordan G.; Poret-Peterson, Amisha T.; Lee, Zarraz M. P.; Richter, Alexander; Alcaraz, Luis D.; Eguiarte, Luis E.; Siefert, Janet L.; Souza, Valeria; Dupont, Chris L.; Elser, James J.

Abstract

Several universal genomic traits affect trade-offs in the capacity, cost, and efficiency of the biochemical information processing that underpins metabolism and reproduction. We analyzed the role of these traits in mediating the responses of a planktonic microbial community to nutrient enrichment in an oligotrophic, phosphorus-deficient pond in Cuatro Cienegas, Mexico. This is one of the first whole-ecosystem experiments to involve replicated metagenomic assessment. Mean bacterial genome size, GC content, total number of tRNA genes, total number of rRNA genes, and codon usage bias in ribosomal protein sequences were all higher in the fertilized treatment, as predicted on the basis of the assumption that oligotrophy favors lower information-processing costs whereas copiotrophy favors higher processing rates. Contrasting changes in trait variances also suggested differences between traits in mediating assembly under copiotrophic versus oligotrophic conditions. Trade-offs in information-processing traits are apparently sufficiently pronounced to play a role in community assembly because the major components of metabolism-information, energy, and nutrient requirements-are fine-tuned to an organism's growth and trophic strategy.

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Título según WOS: ID WOS:000516555700001 Not found in local WOS DB
Título de la Revista: ELIFE
Volumen: 9
Editorial: eLIFE SCIENCES PUBL LTD
Fecha de publicación: 2020
DOI:

10.7554/eLife.49816

Notas: ISI