Abstract
BackgroundResveratrol (Res), a phytoalexin, has been widely reported to participate in plant resistance to fungal infections. However, little information is available on its role in abiotic stress, especially in iron deficiency stress. Malus baccata is widely used as apple rootstock in China, but it is sensitive to iron deficiency.ResultsIn this study, we investigated the role of exogenous Res in M. baccata seedings under iron deficiency stress. Results showed that applying 100 μM exogenous Res could alleviate iron deficiency stress. The seedlings treated with Res had a lower etiolation rate and higher chlorophyll content and photosynthetic rate compared with the apple seedlings without Res treatment. Exogenous Res increased the iron content in the roots and leaves by inducing the expression of MbAHA genes and improving the H+-ATPase activity. As a result, the rhizosphere pH decreased, iron solubility increased, the expression of MbFRO2 and MbIRT1 was induced, and the ferric-chelated reductase activity was enhanced to absorb large amounts of Fe2+ into the root cells under iron deficiency conditions. Moreover, exogenous Res application increased the contents of IAA, ABA, and GA3 and decreased the contents of DHZR and BL for responding to iron deficiency stress indirectly. In addition, Res functioned as an antioxidant that strengthened the activities of antioxidant enzymes and thus eliminated reactive oxygen species production induced by iron deficiency stress.ConclusionResveratrol improves the iron deficiency adaptation of M. baccata seedlings mainly by regulating iron absorption.
Highlights
Resveratrol (Res), a phytoalexin, has been widely reported to participate in plant resistance to fungal infections
Fe is abundant in soil, it mainly exists in the form of low-bioavailability ferric iron (Fe3+), especially in
Different concentrations of exogenous Res could alleviate the chlorosis to different degrees
Summary
Resveratrol (Res), a phytoalexin, has been widely reported to participate in plant resistance to fungal infections. Little information is available on its role in abiotic stress, especially in iron deficiency stress. Iron (Fe) is one of the most essential micronutrients for plant growth, and it plays a vital role in several important physiological processes, such as chlorophyll biosynthesis, photosynthesis, and antioxidative defense [1, 2]. Fe is abundant in soil, it mainly exists in the form of low-bioavailability ferric iron (Fe3+), especially in Plants develop a series of mechanisms during their long-term struggle with environmental stresses. To cope with Fe deficiency stress, plants adopt two strategies for absorbing and translocating Fe [3, 5]. Plants that adopt Mechanism I usually include dicotyledons and nongramineous monocots [6]. These plants absorb Fe mainly through three processes.
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