Large-Scale Identification and Characterization Analysis of <i>VQ</i> Family Genes in Plants, Especially Gymnosperms

VQ motif-containing (VQ) proteins are a class of transcription regulatory cofactors widely present in plants, playing crucial roles in growth and development, stress response, and defense. Although there have been some reports on the member identification and functional research of <i>VQ</i> genes in some plants, there is still a lack of large-scale identification and clear graphical presentation of their basic characterization information to help us to better understand this family. Especially in gymnosperms, the <i>VQ</i> family genes and their evolutionary relationships have not yet been reported. In this study, we systematically identified 2469 <i>VQ</i> genes from 56 plant species, including bryophytes, gymnosperms, and angiosperms, and analyzed their molecular and evolutionary features. We found that amino acids are only highly conserved in the VQ domain, while other positions are relatively variable; most <i>VQ</i> genes encode relatively small proteins and do not have introns. The GC content in Poaceae plants is the highest (up to 70%); these VQ proteins can be divided into nine subgroups. In particular, we analyzed the molecular characteristics, chromosome distribution, duplication events, and expression levels of <i>VQ</i> genes in three gymnosperms: <i>Ginkgo biloba</i>, <i>Taxus chinensis</i>, and <i>Pinus tabuliformis</i>. In gymnosperms, <i>VQ</i> genes are classified into 11 groups, with highly similar motifs in each group; most VQ proteins have less than 300 amino acids and are predicted to be located in nucleus. Tandem duplication is an important driving force for the expansion of the <i>VQ</i> gene family, and the evolutionary processes of most <i>VQ</i> genes and duplication events are relatively independent; some candidate <i>VQ</i> genes are preliminarily screened, and they are likely to be involved in plant growth and stress and defense responses. These results provide detailed information and powerful references for further understanding and utilizing the <i>VQ</i> family genes in various plants.