Transcriptome-based variations effectively untangling the intraspecific relationships and selection signals in Xinyang Maojian tea population

Cheng, Lin; Li, Mengge; Wang, Yachao; Han, Qunwei; Hao, Yanlin; Qiao, Zhen; Zhang, Wei; Qiu, Lin; Gong, An-Dong; Zhang, Zhihan; Li, Tao; Luo, Shuhong; Tang, Linshuang; Liu, Daliang; Yin, Hong; Liang, S.; Balbuena, Tiago Santana; Zhao, Yiyong

doi:10.3389/fpls.2023.1114284

Cited by 3 publications

(1 citation statement)

References 116 publications

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“…As innovative genetic elements, they drive functional and phenotypic diversity and significantly influence the evolutionary processes of organisms 24, 25 . Studying LSGs relies on a stable and reliable phylogenetic foundation, with low copy nuclear genes being particularly effective in discerning phylogenetic relationships among angiosperms 26, 27, 28 . Compared to morphological, anatomical, and cytological traits, as well as mitochondrial and chloroplast genomic markers, nuclear genes exhibit greater variability and longer sequence lengths.…”

Section: Introductionmentioning

confidence: 99%

The Origin and Evolution of Orphan Genes: A Case Study in Tea Plant Family

Cheng,

Hao,

Han

et al. 2024

Preprint

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Orphan genes and transcription factor genes (TFs) are pervasive across genomes, play pivotal roles as regulators in a myriad of biological processes. Despite their ubiquity, the evolutionary trajectories and functional divergence of these genes remain largely unexplored. Theaceae family, encompassing the economically and culturally significant tea plant, presents a unique opportunity to study these dynamics. Here, we decoded a nearly complete, chromosome-scale reference genome of Stewartia gemmata spanning 2.95 Gb. This study is enhanced by integrating the genome of S. gemmata, an early-diverging species within Theaceae, crucial for phylogenomic analyses and understanding the functional dynamics of orphan genes in this family. Our analysis confirmed the absence of a recent specific whole-genome duplication (WGD) event, with tandem duplications emerging as the predominant mechanism for gene duplication at ancestral nodes within Theaceae. By conducting an extensive comparative genomics analysis across 13 Theaceae and comparing these with a wide array of eukaryotic and prokaryotic proteins, we identified 37,618 orphan genes and 25,884 TFs in Theaceae. Interestingly, some orphan genes appear to have ancient origins in tea plant ancestors, suggesting relatively early origins with frequent gains and losses, conversely, many others seem more specific and recent. Notably, the orphan genes are characterized by shorter lengths, fewer exons and functional domains than TFs, implying relatively simpler functional roles. These orphan genes demonstrate diverse cellular localization and functions as predicted by GO/KEGG analysis, and are implicated in environmental response and flavor formation in tea plants. This study not only sheds light on the distinct evolutionary histories and functional divergences between orphan genes and TFs in Theaceae, but also contributes to our understanding of the genetic complexity and adaptability of this economically and culturally valuable plant family.

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