Origin, evolution and diversity of SINA E3 ubiquitin ligases in plants

Abstract

SINA (Seven in absentia) E3 ligases are critical components of the ubiquitin-proteasome system (UPS). They are responsible for ubiquitination and are involved in numerous cellular processes. The functional mechanisms of SINAs have been extensively studied in a few angiosperms. However, our understanding of the origin and evolution of plant SINA genes remain limited. Here we performed a large-scale comprehensive analysis of SINA proteins from various plant lineages. The plant SINA family genes likely originated from a common ancestral gene prior to the divergence of bryophyte and gave rise to two clades. Within clade I, subsequent parallel innovations in lycophytes and ferns resulted in the formation of two branches. All SINA proteins contain an N-terminal cysteine-rich really interesting new gene (RING) domain for ubiquitination, two zinc-finger motifs, and a C-terminal domain required for substrate-binding and dimerization. The SINA genes gains and losses occurred in angiosperms, resulting in an increase in the number of gene copies in eudicots and monocots. The Gossypium genus SINAs showed a tendency for expansion via whole-genome duplication and polyploidy. Finally, global expression patterns revealed the functional diversification of SINA genes in developmental stage and response to hormones and abiotic stresses in Arabidopsis and rice. These findings provide an insight into the evolution and diversification of SINA E3 ligases in plants and enhance our understanding of the role they play in determining substrate specificity and environment stress adaptations in angiosperms.