Exploring Evolutionary Pathways and Abiotic Stress Responses Through Genome-Wide Identification and Analysis of the Alternative Oxidase (AOX) Gene Family in Common Oat ()

Overview

Journal Int J Mol Sci

Publisher MDPI

Specialties Biochemistry
Chemistry
Molecular Biology

Date 2024 Sep 14

PMID 39273329

Authors

Boyang Liu

Zecheng Zhang

Jinghan Peng

Haipeng Mou

Zhaoting Wang

Yixin Dao

Tianqi Liu

Dandan Kong

Siyu Liu

Yanli Xiong

Yi Xiong

Junming Zhao

Zhixiao Dong

Youjun Chen

Xiao Ma

Affiliations

Soon will be listed here.

Abstract

The alternative oxidase (AOX), a common terminal oxidase in the electron transfer chain (ETC) of plants, plays a crucial role in stress resilience and plant growth and development. Oat (), an important crop with high nutritional value, has not been comprehensively studied regarding the AsAOX gene family. Therefore, this study explored the responses and potential functions of the AsAOX gene family to various abiotic stresses and their potential evolutionary pathways. Additionally, we conducted a genome-wide analysis to explore the evolutionary conservation and divergence of AOX gene families among three species (, , ) and four species (, , , and ). We identified 12 AsAOX, 9 AiAOX, and 4 AlAOX gene family members. Phylogenetic, motif, domain, gene structure, and selective pressure analyses revealed that most AsAOXs, AiAOXs, and AlAOXs are evolutionarily conserved. We also identified 16 AsAOX segmental duplication pairs, suggesting that segmental duplication may have contributed to the expansion of the AsAOX gene family, potentially preserving these genes through subfunctionalization. Chromosome polyploidization, gene structural variations, and gene fragment recombination likely contributed to the evolution and expansion of the AsAOX gene family as well. Additionally, we hypothesize that may have potential function in resisting wounding and heat stresses, while could be specifically involved in mitigating wounding stress. might contribute to resistance against chromium and waterlogging stresses. may have potential fuction in mitigating ABA-mediated stress. and are most likely to have potential function in mitigating salt and drought stresses, respectively. This study elucidates the potential evolutionary pathways of the AsAOXs gene family, explores their responses and potential functions to various abiotic stresses, identifies potential candidate genes for future functional studies, and facilitates molecular breeding applications in .

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