info:eu-repo/semantics/article
Long-lasting primed state in maize plants: Salicylic acid and steroid signaling pathways as key players in the early activation of immune responses in silks
Fecha
2018-12Registro en:
Agostini, Romina Belén; Postigo, Agustina; Rius, Sebastian Pablo; Rech, Gabriel E.; Campos Bermudez, Valeria Alina; et al.; Long-lasting primed state in maize plants: Salicylic acid and steroid signaling pathways as key players in the early activation of immune responses in silks; American Phytopathological Society; Molecular Plant-Microbe Interactions; 32; 1; 12-2018; 90-106
0894-0282
CONICET Digital
CONICET
Autor
Agostini, Romina Belén
Postigo, Agustina
Rius, Sebastian Pablo
Rech, Gabriel E.
Campos Bermudez, Valeria Alina
Vargas, Walter Alberto
Resumen
In the present study, we investigated the induced systemic resistance (ISR) activated by the beneficial fungus Trichoderma atroviride in maize plants, and the early immunological responses triggered after challenge with the ear rot pathogen Fusarium verticillioides. By transcriptional analysis, we were able to identify the gene core set specifically modulated in silks of maize plants expressing ISR. Our results showed that the main transcriptional reprogramming falls into genes involved in five main functional categories: cell structure or cell wall, amino acid and protein metabolism, stress responses, signaling, and transport. Among these ISR-related genes, it is important to highlight novel findings regarding hormone metabolism and signaling. The expression of hormone-dependent genes was in good agreement with the abscisic acid, jasmonic acid, and salicylic acid (SA) levels detected in the plants under study. The experimental design allowed the identification of novel regulatory elements related to a heightened state of defense in silks and suggests that steroids and SA are central components of a master regulatory network controlling the immunity of silks during ISR. The results presented also provide evidence about the molecular mechanisms used by maize silks against F. verticillioides to counteract pathogenic development and host invasion, including pathogenesis-related genes, plant cell-wall reinforcement, fungal cell-wall-degrading enzymes and secondary metabolism.