Genetius - Plant Biology Papers

Latest 2 Papers

Primary metabolism determines the outcome of salicylic acid-mediated immune induction

Authors: Zhang, Q., Xie, Y., Karapetyan, S., Wang, J., Mwimba, M., Yoo, H., Dong, X.

Date: 2025-10-14 · Version: 1

DOI: 10.1101/2025.10.13.682132

Category: Plant Biology

Model Organism: General

▶ AI Summary

The study identified twenty survival of SA-induced death (ssd) mutants that are defective in starch, glucose, nitrate metabolism, and circadian regulation, leading to excessive carbohydrate accumulation and susceptibility to salicylic acid (SA)-induced death in prolonged darkness. Glucose application rescues SA‑treated plants by antagonizing oxidative stress and restoring metabolic balance, as revealed by transcriptomic analyses that link SA‑induced cell death to effector‑triggered immunity pathways.

salicylic acid circadian regulation starch and glucose metabolism oxidative stress glucose rescue

Impaired methyl recycling induces substantial shifts in sulfur utilization in Arabidopsis

Authors: Tremblay, B. J.-M., Adeel, S. A., Saechao, M., Dong, Y., Andrianasolo, E., Steele, J. M., Traa, A., Yogadasan, N., Waduwara-Jayabahu, I., Katzenback, B. A., Hell, R., Wirtz, M., Moffatt, B. A.

Date: 2025-03-13 · Version: 1

DOI: 10.1101/2025.03.09.642221

Category: Plant Biology

Model Organism: General

▶ AI Summary

Reduced activity of methylthioadenosine (MTA) nucleosidase causes MTA over‑accumulation in reproductive tissues, leading to lowered cysteine, methionine, and S‑adenosylmethionine levels and altered sulfur and energy metabolism. These metabolic disturbances trigger misregulation of cell‑cycle progression, widespread down‑regulation of developmental genes, and genome‑wide changes in DNA methylation patterns, highlighting the extensive role of MTA recycling in plant growth and methyl‑index maintenance.

sulfur metabolism methylthioadenosine nucleosidase methionine/S‑adenosylmethionine biosynthesis DNA methylation reproductive development