AI Article Synopsis
- Phenolamides are important plant metabolites that help tomatoes adapt to stress, but their metabolism and regulation are not well understood, particularly in the context of breeding and domestication.
- The study identified two gene clusters involved in phenolamide metabolism and found that a specific gene (SlMYB13) helps regulate their accumulation, which in turn enhances drought tolerance in tomatoes.
- Findings indicate that during the domestication process, key genes related to phenolamide production were negatively selected, resulting in reduced phenolamide levels and drought resistance in cultivated tomatoes.
Article Abstract
Among plant metabolites, phenolamides, which are conjugates of hydroxycinnamic acid derivatives and polyamines, play important roles in plant adaptation to abiotic and biotic stresses. However, the molecular mechanisms underlying phenolamide metabolism and regulation as well as the effects of domestication and breeding on phenolamide diversity in tomato remain largely unclear. In this study, we performed a metabolite-based genome-wide association study and identified two biosynthetic gene clusters (BGC7 and BGC11) containing 12 genes involved in phenolamide metabolism, including four biosynthesis genes (two 4CL genes, one C3H gene, and one CPA gene), seven decoration genes (five AT genes and two UGT genes), and one transport protein gene (DTX29). Using gene co-expression network analysis we further discovered that SlMYB13 positively regulates the expression of two gene clusters, thereby promoting phenolamide accumulation. Genetic and physiological analyses showed that BGC7, BGC11 and SlMYB13 enhance drought tolerance by enhancing scavenging of reactive oxygen species and increasing abscisic acid content in tomato. Natural variation analysis suggested that BGC7, BGC11 and SlMYB13 were negatively selected during tomato domestication and improvement, leading to reduced phenolamide content and drought tolerance of cultivated tomato. Collectively, our study discovers a key mechanism of phenolamide biosynthesis and regulation in tomato and reveals that crop domestication and improvement shapes metabolic diversity to affect plant environmental adaptation.
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| http://dx.doi.org/10.1016/j.molp.2024.02.003 | DOI Listing |
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