Funct Plant Biol. 2025 Mar;pii: FP24294. [Epub ahead of print]52
Junping Gao,
Ying Wang,
Xinxi He,
Long Chen,
Shuaibin Wang,
Xinyao Zhang,
Sirui Zhu,
Xiaoxu Li,
Xiaonian Yang,
Wenxuan Pu,
Yuanyuan Li.
The biochemical and transcriptional regulatory mechanisms of chlorophyll metabolism have been extensively studied, but the translational regulatory mechanisms remain poorly understood. In this study, we found that Nt DHS1 deficiency in N. tabacum resulted in smaller leaves and increased leaf chlorophyll content. Protein content determination experiments revealed that the global protein synthesis of the Ntdhs1 mutant was decreased. A ribosome profiling sequence (Ribo-seq) assay showed that the translation level of genes related to cell growth was significantly reduced, while the translation level of chlorophyll metabolism related genes was significantly increased in Ntdhs1 mutant. Biochemical analysis further demonstrated that Nt DHS interacts with the translation initiation factor Nt eIF5A. Moreover, the Nteif5a1 mutant exhibited phenotypes similar to the Ntdhs1 mutant, including a reduced translation level of cell growth related genes and increased translation level of chlorophyll metabolism related genes. Our studies suggest that the Nt DHS-Nt eIF5A complex regulates leaf senescence by modulating the translation of specific genes.