Phylogenomics Reveals an Anomalous Distribution of USP Genes in Metazoans

Date

2011

Authors

Foret, Sylvain
Seneca, Francois O
de Jong, Danielle
Bieller, Annette
Hemmrich, Georg
Augustin, Rene
Hayward, David
Ball, Eldon
Bosch, Thomas CG
Agata, Kiyokazu

Journal Title

Journal ISSN

Volume Title

Publisher

Society for Molecular Biology Evolution

Abstract

Members of the universal stress protein (USP) family were originally identified in stressed bacteria on the basis of a shared domain, which has since been reported in a phylogenetically diverse range of prokaryotes, fungi, protists, and plants. Although not previously characterized in metazoans, here we report that USP genes are distributed in animal genomes in a unique pattern that reflects frequent independent losses and independent expansions. Multiple USP loci are present in urochordates as well as all Cnidaria and Lophotrochozoa examined, but none were detected in any of the available ecdysozoan or non-urochordate deuterostome genome data. The vast majority of the metazoan USPs are short, single-domain proteins and are phylogenetically distinct from the prokaryotic, plant, protist, and fungal members of the protein family. Whereas most of the metazoan USP genes contain introns, with few exceptions those in the cnidarian Hydra are intronless and cluster together in phylogenetic analyses. Expression patterns were determined for several cnidarian USPs, including two genes belonging to the intronless clade, and these imply diverse functions. The apparent paradox of implied diversity of roles despite high overall levels of sequence (and implied structural) similarity parallels the situation in bacteria. The absence of USP genes in ecdysozoans and most deuterostomes may be a consequence of functional redundancy or specialization in taxon-specific roles.

Description

Keywords

Keywords: heat shock protein; hybrid protein; unclassified drug; universal stress protein; article; controlled study; Deuterostomia; gene locus; gene sequence; metazoon; nonhuman; phylogenetic tree; phylogenomics; protein domain; sequence homology; taxon; Urochorda Cnidaria; gene loss; universal stress protein; Urmetazoa; USP

Citation

Source

Molecular Biology and Evolution

Type

Journal article

Book Title

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Restricted until

2037-12-31