Systemin - Signal Transduction

Signal Transduction

Although the receptors for systemins and HypSys remain poorly understood, we have a better understanding of the signal transduction that occurs once the peptide had bound to its receptor. Jasmonic acid is an essential, albeit late component, in the systemin and wound-signalling pathways. In tomato, the signal is transduced from the receptor by mitogen-activated protein kinases (MAPKs). Cosilencing of two MAPKs, MPK1 and MPK2, in tomato compromised their defence response against insect larvae compared to wild type plants. Cosilencing these genes also decreased production of jasmonic acid and of jasmonic acid-dependent defence genes. Applying methyl jasmonate to cosilenced plants rescued them, indicating that jasmonates are the signal responsible for causing changes in gene expression. The alkalisation of the apoplast is a downstream effect of signalling processing by MAPKs. Applying fusicoccin, which activates the H+ ATPase inhibited by systemin, along with systemin still activates MAPKs, even though the pH of the apoplast does not change.

Within minutes of systemin perception, the cytosolic Ca2+ concentration increases, and linolenic acid is released from cell membranes after a phospholipase has been activated. Linolenic acid is then converted to jasmonic acid via the octadecanoid pathway and jasmonic acid activates defensive genes. Production of methyl jasmonate is induced by systemins and also upregulates systemin precursor genes creating a feedback loop, amplifying the defensive signal. Methyl jasmonate is volatile and can therefore activate systemic acquired resistance in neighbouring plants, preparing their defences for attack. These signalling events are analogous to the cytokine-mediated inflammatory immune response in animals. When the inflammatory response is activated in animals, MAPKs are activated which in turn activate phospholipases. Lipids in the membrane are converted to arachidonic acid and then to prostaglandins, which are analogs of jasmonic acid. Both pathways can be inhibited by suramin.

Early experiments with radiolabelled systemin in tomato demonstrated that it is transported through the phloem sap in tomato plants and was therefore thought to be the systemic signal that activated systemic acquired resistance. This view was challenged by grafting experiments which showed that mutants deficient in jasmonic acid biosynthesis and perception were unable to activate systemic acquired resistance. It is now thought that jasmonic acid is the systemic signal and that systemin upregulates the pathways for jasmonic acid synthesis.