Stomata on leaf epidermis formed by pairs of guard cells control CO
2 intake and water transpiration, and respond to different environmental conditions. Stress-induced stomatal closure is mediated via an intricate hormone network in guard cells. Although methyl jasmonate (MeJA) has been intensively studied for its function in plant defense, the molecular mechanisms underlying its function in stomatal movement are not fully understood. Here we report the effects of MeJA on
Brassica napus stomatal movement and H
2O
2 production. Using the isobaric tags for relative and absolute quantitation (iTRAQ) approach, we have identified 84 MeJA-responsive proteins in
B. napus guard cells. Most of the genes encoding these proteins contain jasmonate-responsive elements in the promoters, indicating that they are potentially regulated at the transcriptional level. Among the identified proteins, five protein changes after MeJA treatment were validated using Western blot analysis. The identification of the MeJA-responsive proteins has revealed interesting molecular mechanisms underlying MeJA function in guard cells, which include homeostasis of H
2O
2 production and scavenging, signaling through calcium oscillation and protein (de)phosphorylation, gene transcription, protein modification, energy balance, osmoregulation, and cell shape modulation. The knowledge of the MeJA-responsive proteins has improved our understanding of MeJA signaling in stomatal movement, and it may be applied to crop engineering for enhanced yield and stress tolerance.
Keywords:
Brassica napus; guard cells; methyl jasmonate; iTRAQ; proteomics; stomatal movement
