Akademik Veri Yönetim Sistemi
PLANT CELL REPORTS, cilt.43, sa.9, ss.1-16, 2026 (SCI-Expanded, Scopus)
Fruit ripening in tomato (Solanum lycopersicum) is a complex developmental process coordinated by a hierarchical network of transcription factors and the phytohormone ethylene. In this study, we identified and characterized SlERF-RD1 (Solyc02g077790), a member of the AP2/ERF superfamily, as a strategic negative regulator of ripening and a coordinator of plant architecture. Transcriptomic meta-analysis revealed that SlERF-RD1 is highly sensitive to ethylene and displays spatiotemporal enrichment in locular tissues, suggesting an early role in the ripening cascade. Stable overexpression of SlERF-RD1 in tomato resulted in a significantly delayed onset of ripening, characterized by a 40–47% reduction in climacteric ethylene production and altered, tissue-specific carotenoid accumulation. Molecular analysis showed that these phenotypes are driven by the transcriptional down-regulation of the master regulator SlRIN and the rate-limiting carotenoid gene SlPSY1. Notably, SlERF-RD1-OE fruits maintained superior firmness during late ripening stages, which was correlated with the significant suppression of the cell wall-modifying genes SlPG2A and SlEXP1. Furthermore, we identified Solyc01g108880 as a novel co-expressed target that is up-regulated explicitly at the red-ripe stage, suggesting a late-stage cell wall reinforcement mechanism. Beyond fruit attributes, SlERF-RD1 overexpression reconfigured plant architecture into a more compact canopy and accelerated the floral transition by up-regulating SlSFT. Our findings demonstrate that SlERF-RD1 promotes an asynchronous, firm-ripe fruit phenotype, while supporting optimized vegetative growth. This study highlights SlERF-RD1 as a high-potential target for genetic strategies aimed at enhancing both crop architecture and post-harvest shelf-life.