Trichodesmium Genome Maintains Abundant, Widespread Noncoding DNA in Situ, Despite Oligotrophic Lifestyle

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2015 Apr 2

PMID 25831533

Citations 19

Authors

Nathan Walworth

Ulrike Pfreundt

William C Nelson

Tracy Mincer

John F Heidelberg

Feixue Fu

John B Waterbury

Tijana Glavina Del Rio

Lynne Goodwin

Nikos C Kyrpides

Miriam L Land

Tanja Woyke

David A Hutchins

Wolfgang R Hess

Eric A Webb

Affiliations

Soon will be listed here.

Abstract

Understanding the evolution of the free-living, cyanobacterial, diazotroph Trichodesmium is of great importance because of its critical role in oceanic biogeochemistry and primary production. Unlike the other >150 available genomes of free-living cyanobacteria, only 63.8% of the Trichodesmium erythraeum (strain IMS101) genome is predicted to encode protein, which is 20-25% less than the average for other cyanobacteria and nonpathogenic, free-living bacteria. We use distinctive isolates and metagenomic data to show that low coding density observed in IMS101 is a common feature of the Trichodesmium genus, both in culture and in situ. Transcriptome analysis indicates that 86% of the noncoding space is expressed, although the function of these transcripts is unclear. The density of noncoding, possible regulatory elements predicted in Trichodesmium, when normalized per intergenic kilobase, was comparable and twofold higher than that found in the gene-dense genomes of the sympatric cyanobacterial genera Synechococcus and Prochlorococcus, respectively. Conserved Trichodesmium noncoding RNA secondary structures were predicted between most culture and metagenomic sequences, lending support to the structural conservation. Conservation of these intergenic regions in spatiotemporally separated Trichodesmium populations suggests possible genus-wide selection for their maintenance. These large intergenic spacers may have developed during intervals of strong genetic drift caused by periodic blooms of a subset of genotypes, which may have reduced effective population size. Our data suggest that transposition of selfish DNA, low effective population size, and high-fidelity replication allowed the unusual "inflation" of noncoding sequence observed in Trichodesmium despite its oligotrophic lifestyle.

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