Biased Gene Introgression and Adaptation in the Face of Chloroplast Capture in Aquilegia amurensis

Biased Gene Introgression and Adaptation in the Face of Chloroplast Capture in Aquilegia amurensis

-Chloroplast capture, a phenomenon that can occur through interspecific hybridization and introgression, is frequently invoked to explain cytonuclear discordance in plants. However, relatively few studies have documented the mechanisms of cytonuclear coevolution and its potential for driving species...

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Veröffentlicht in:Systematic biology 2024-11, Vol.73 (6), p.886
Hauptverfasser: Wang, Huaying, Zhang, Wei, Yu, Yanan, Fang, Xiaoxue, Zhang, Tengjiao, Xu, Luyuan, Gong, Lei, Xiao, Hongxing
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Sprache:eng
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Adaptation, Physiological - genetics
Aquilegia - genetics
Chloroplasts - genetics
Gene Flow
Genetic Introgression
Hybridization, Genetic
Phylogeny
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container_issue 6
container_start_page 886
container_title Systematic biology
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creator Wang, Huaying
Zhang, Wei
Yu, Yanan
Fang, Xiaoxue
Zhang, Tengjiao
Xu, Luyuan
Gong, Lei
Xiao, Hongxing
description -Chloroplast capture, a phenomenon that can occur through interspecific hybridization and introgression, is frequently invoked to explain cytonuclear discordance in plants. However, relatively few studies have documented the mechanisms of cytonuclear coevolution and its potential for driving species differentiation and possible functional differences in the context of chloroplast capture. To address this crucial question, we chose the Aquilegia genus, which is known for having minimal sterility among species, and inferred that A. amurensis captured the plastome of A. parviflora based on cytonuclear discordance and gene flow between the 2 species. We focused on the introgression region and its differentiation from corresponding regions in closely related species, especially its composition in a chloroplast capture scenario. We found that nuclear genes encoding cytonuclear enzyme complexes (CECs; i.e., organelle-targeted genes) of chloroplast donor species were selectively retained and displaced the original CEC genes in chloroplast-receiving species due to cytonuclear interactions during introgression. Notably, the intrinsic correlation of CEC introgression was a greater degree of evolutionary distance for these CECs between A. amurensis and A. parviflora. Terpene synthase activity genes (GO: 0010333) were overrepresented among the introgressed genes, and more than 30% of these genes were CEC genes. These findings support our observations that floral terpene release pattern is similar between A. amurensis and A. parviflora compared with A. japonica. Our study clarifies the mechanisms of cytonuclear coevolution, species differentiation, and functional differences in the context of chloroplast capture and highlights the potential role of chloroplast capture in adaptation.
doi_str_mv 10.1093/sysbio/syae039
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However, relatively few studies have documented the mechanisms of cytonuclear coevolution and its potential for driving species differentiation and possible functional differences in the context of chloroplast capture. To address this crucial question, we chose the Aquilegia genus, which is known for having minimal sterility among species, and inferred that A. amurensis captured the plastome of A. parviflora based on cytonuclear discordance and gene flow between the 2 species. We focused on the introgression region and its differentiation from corresponding regions in closely related species, especially its composition in a chloroplast capture scenario. We found that nuclear genes encoding cytonuclear enzyme complexes (CECs; i.e., organelle-targeted genes) of chloroplast donor species were selectively retained and displaced the original CEC genes in chloroplast-receiving species due to cytonuclear interactions during introgression. Notably, the intrinsic correlation of CEC introgression was a greater degree of evolutionary distance for these CECs between A. amurensis and A. parviflora. Terpene synthase activity genes (GO: 0010333) were overrepresented among the introgressed genes, and more than 30% of these genes were CEC genes. These findings support our observations that floral terpene release pattern is similar between A. amurensis and A. parviflora compared with A. japonica. 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source MEDLINE; Oxford University Press Journals All Titles (1996-Current)
subjects Adaptation, Physiological - genetics
Aquilegia - genetics
Chloroplasts - genetics
Gene Flow
Genetic Introgression
Hybridization, Genetic
Phylogeny
title Biased Gene Introgression and Adaptation in the Face of Chloroplast Capture in Aquilegia amurensis
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