Metabolic regulation of polyamines and γ‐aminobutyric acid in relation to spermidine‐induced heat tolerance in white clover

Heat stress decreases crop growth and yield worldwide. Spermidine (Spd) is a small aliphatic amine and acts as a ubiquitous regulator for plant growth, development and stress tolerance. Objectives of this study were to determine effects of exogenous Spd on changes in endogenous polyamine (PA) and γ‐aminobutyric acid (GABA) metabolism, oxidative damage, senescence and heat shock protein (HSP) expression in white clover subjected to heat stress. Physiological and molecular methods, including colorimetric assay, high performance liquid chromatography and qRT‐PCR, were applied. Results showed that exogenous Spd significantly alleviated heat‐induced stress damage. Application of Spd not only increased endogenous putrescine, Spd, spermine and total PA accumulation, but also accelerated PA oxidation and improved glutamic acid decarboxylase activity, leading to GABA accumulation in leaves under heat stress. The Spd-pretreated white clover maintained a significantly higher chlorophyll (Chl) content than untreated plants under heat stress, which could be related to the roles of Spd in up‐regulating genes encoding Chl synthesis (PBGD and Mg‐CHT) and maintaining reduced Chl degradation (PaO and CHLASE) during heat stress. In addition, Spd up‐regulated HSP70, HSP70B and HSP70‐5 expression, which might function in stabilizing denatured proteins and helping proteins to folding correctly in white clover under high temperature stress. In summary, exogenous Spd treatment improves the heat tolerance of white clover by altering endogenous PA and GABA content and metabolism, enhancing the antioxidant system and HSP expression and slowing leaf senescence related to an increase in Chl biosynthesis and a decrease in Chl degradation during heat stress. Spermidine regulates heat tolerance of white clover through altering endogenous polyamines and γ‐aminobutyric acid metabolism, enhancing antioxidant system and heat shock proteins expression, and slowing down leaf senescence during heat stress.