Physiological dominance of the scion in shaping root architecture under suboptimal temperature

BackgroundNon-optimal temperatures have become a major constraint on plant development under rapidly changing climatic conditions. Both sub- and supra-optimal temperatures reduce physiological activity, alter plant morphology, lead to plant mortality, and ultimately decrease crop productivity. Temperature-tolerant plants employ physiological and morphological mechanisms to mitigate such stress. In this study, we aimed to identify the source of temperature tolerance in warm-climate adapted melon (Cucumis melo L.). ResultsSuboptimal temperature-tolerant accession (Ananas Yoqneam; AY) and susceptible accession (PI414723) were reciprocally grafted and grown under controlled temperature regimes of 16 {degrees}C, 25 {degrees}C, and 35 {degrees}C. Physiological and morphological traits were measured to characterize tolerance mechanisms and whole-plant responses. Temperature emerged as the dominant factor governing plant performance. Whereas non-grafted parental lines maintained consistent differences across all temperature regimes, reciprocal graft combinations diverged mainly under suboptimal (16 {degrees}C) conditions. Under these temperatures, scion identity strongly determined whole-plant performance through biochemical limitations. ConclusionThese results highlight the importance of scion-derived traits in abiotic stress tolerance and their downstream influence on root function.