The epigenomic landscape regulates gene expression and chromatin dynamics,with histone and RNA modifications playing crucial roles.Although studies have elucidated the interactions among chromatin modifications,DNA me...The epigenomic landscape regulates gene expression and chromatin dynamics,with histone and RNA modifications playing crucial roles.Although studies have elucidated the interactions among chromatin modifications,DNA methylation,and mRNA modifications,the relationships among RNA modifications and their collective influence on RNA metabolism remain poorly understood.Grasping these epigenetic mechanisms is essential for improving crop resilience and productivity.In this study,we explored the co-occurrence and functional interactions of three significant mRNA modifications in Arabidopsis(Arabidopsis thaliana)and rice(Oryza sativa):N^(4)-acetylcytidine(ac^(4)C),N^(6)-methyladenosine(m^(6)A),and 5-methylcytosine(m^(5)C).Our results indicate that these modifications frequently coexist in the same transcripts,exhibiting distinct spatial distributions across species.Notably,the m^(6)A modification enhances the ac^(4)C-mediated destabilization of RNA secondary structures,especially when modifications are clustered,thereby promoting RNA stability.In Arabidopsis,the ac^(4)C modification improved translational efficiency and the m^(6)A modification amplified this effect in a distance-dependent manner;by contrast,in rice the influence of m^(6)A is independent of distance.The m^(5)C modification has minimal impact on RNA structure or stability but modulates m^(6)A-associated transcript stability in a contextdependent manner.Our findings shed light on the dynamic regulatory code of combinatorial RNA modifications,highlighting species-specific mechanisms of post-transcriptional regulation.This research offers valuable insights into the intricate interplay of RNA modifications,with implications for advancing agricultural biotechnology through a deeper understanding of plant RNA functionality.展开更多
基金support from the National Natural Science Foundation of China(32270623)the Natural Science Foundation of Hunan Province(2024JJ2016)+2 种基金Hunan Science and Technology Innovation Plan(2025ZYJ003)China Tobacco Hunan Industrial Co.,Ltd.Research Project(KY2023YC0015)support from the China Tobacco Genome Project(110202101037,JY-14).
文摘The epigenomic landscape regulates gene expression and chromatin dynamics,with histone and RNA modifications playing crucial roles.Although studies have elucidated the interactions among chromatin modifications,DNA methylation,and mRNA modifications,the relationships among RNA modifications and their collective influence on RNA metabolism remain poorly understood.Grasping these epigenetic mechanisms is essential for improving crop resilience and productivity.In this study,we explored the co-occurrence and functional interactions of three significant mRNA modifications in Arabidopsis(Arabidopsis thaliana)and rice(Oryza sativa):N^(4)-acetylcytidine(ac^(4)C),N^(6)-methyladenosine(m^(6)A),and 5-methylcytosine(m^(5)C).Our results indicate that these modifications frequently coexist in the same transcripts,exhibiting distinct spatial distributions across species.Notably,the m^(6)A modification enhances the ac^(4)C-mediated destabilization of RNA secondary structures,especially when modifications are clustered,thereby promoting RNA stability.In Arabidopsis,the ac^(4)C modification improved translational efficiency and the m^(6)A modification amplified this effect in a distance-dependent manner;by contrast,in rice the influence of m^(6)A is independent of distance.The m^(5)C modification has minimal impact on RNA structure or stability but modulates m^(6)A-associated transcript stability in a contextdependent manner.Our findings shed light on the dynamic regulatory code of combinatorial RNA modifications,highlighting species-specific mechanisms of post-transcriptional regulation.This research offers valuable insights into the intricate interplay of RNA modifications,with implications for advancing agricultural biotechnology through a deeper understanding of plant RNA functionality.
