Keywords: decoding modules, SNP array, phosphorylation, polyamine profiling

Latest 14 Papers

Charge reversal at the Lhcb2 N-terminus impairs phosphorylation and PSI-LHCII complex formation

Authors: Srivastava, A., Schiphorst, C., Berentsen, J., Verhoeven, D., Leeuwen, J. v., Longoni, F., Saccon, F., Wientjes, E.

Date: 2025-12-25 · Version: 1

DOI: 10.64898/2025.12.25.696481

Model Organism: Arabidopsis thaliana

state transitions Lhcb2 N‑terminal charge phosphorylation Arabidopsis thaliana thylakoid ultrastructure

Universal modules for decoding amplitude and frequency of Ca2+ signals in plants

Authors: Vergara-Valladares, F., Rubio-Melendez, M. E., Charpentier, M., Michard, E., Dreyer, I.

Date: 2025-12-16 · Version: 1

DOI: 10.64898/2025.12.13.694100

Model Organism: General

calcium signaling EF‑hand Ca2+ binding protein decoding modules plant calcium sensors signal amplitude and frequency

Brassinosteroids promote sugar synthesis by inhibiting BIN2 phosphorylation of phosphoenolpyruvate carboxykinase

Authors: Zhang, H., Aizezi, Y., Bessho-Uehara, K., Chaudhary, A., Trinh, C. S., Xu, S.-L., Wang, Z.-Y.

Date: 2025-10-23 · Version: 1

DOI: 10.1101/2025.10.22.683954

Model Organism: Arabidopsis thaliana

brassinosteroids phosphoenolpyruvate carboxykinase phosphorylation gluconeogenesis Arabidopsis thaliana

Guard Cell-Enriched Phosphoproteome Reveals Phosphorylation of Endomembrane Proteins in Closed Stomata

Authors: Pullen, A.-M., Lyons, S., Mordant, A., Herring, L. E., Akpa, B., Rojas-Pierce, M.

Date: 2025-10-15 · Version: 1

DOI: 10.1101/2025.10.15.682613

Model Organism: General

stomatal aperture guard cells phosphorylation endomembrane trafficking proteomics

Uncovering the Molecular Regulation of Seed Development and Germination in Endangered Legume Paubrasilia echinata Through Proteomic and Polyamine Analyses

Authors: Vettorazzi, R. G., Carrari-Santos, R., Sousa, K. R., Oliveira, T. R., Grativol, C., Olimpio, G., Venancio, T. M., Pinto, V. B., Quintanilha-Peixoto, G., Silveira, V., Santa-Catarna, C.

Date: 2025-10-15 · Version: 1

DOI: 10.1101/2025.10.13.682162

Model Organism: Paubrasilia echinata

seed maturation proteomics polyamine profiling stress tolerance LEA proteins

EPP1 is an ancestral component of the plant Common SymbiosisPathway

Authors: Rich, M. K., Vernie, T., Tiwari, M., Chauderon, L., Causse, J., Pellen, T., Boussaroque, A., Bianconi, M. E., Vandenbussche, M., Chambrier, P., Le Ru, A., Castel, B., Nagalla, S., Cullimore, J., Keller, J., Valdes-Lopez, O., Mbengue, M., Ane, J.-M., Delaux, P.-M.

Date: 2025-10-02 · Version: 1

DOI: 10.1101/2025.09.30.679610

Model Organism: Multi-species

EPP1 common symbiosis pathway arbuscular mycorrhizal fungi phosphorylation intracellular plant-microbe symbiosis

A century of breeding has preserved genetic variation, accumulated favorable alleles, and shaped the Rht gene portfolio in North American spring wheat

Authors: Gill, H. S., Blecha, S., Conley, E., Brault, C., Fiedler, J., Cook, J., Glover, K., Green, A., Read, A. C., Anderson, J. A.

Date: 2025-09-23 · Version: 1

DOI: 10.1101/2025.09.22.677111

Model Organism: Triticum aestivum

Hard red spring wheat genetic diversity Rht dwarfing genes SNP array KASP genotyping

ABI5 Binding Proteins are substrates of key components in the ABA core signaling pathway

Authors: Finkelstein, R. R., Lynch, T., Erickson McNally, B. J., Losic, T., Lundquist, J.

Date: 2025-08-16 · Version: 2

DOI: 10.1101/2024.10.11.617944

Model Organism: Arabidopsis thaliana

ABA signaling ABI5‑Binding Proteins phosphorylation SnRK2 kinases protein stability

G3BP1 Phosphorylation Regulates Plant Immunity in Arabidopsis

Authors: Hirt, H., Abdulhakim, F., Abdulfaraj, A., Rayapuram, N.

Date: 2025-05-08 · Version: 1

DOI: 10.1101/2025.05.06.652493

Model Organism: Arabidopsis thaliana

MAPK signaling AtG3BP1 phosphorylation plant immunity stomatal defense

A moss N-Acetyltransferase-MAPK protein controls 2D to 3D developmental transition via acetylation and phosphorylation changes

Authors: de Luxan Hernandez, C., Ammitsoe, T. J., Kanne, J. V., Stanimirovic, S., Roux, M., Weeks, Z., Schutzbier, M., Dürnberger, G., Roitinger, E., Zhang, L., Spadiut, O., Ishikawa, M., Hasebe, M., Moody, L., Dagdas, Y., Rodriguez, E., Petersen, M.

Date: 2025-05-03 · Version: 1

DOI: 10.1101/2025.05.02.650421

Model Organism: Physcomitrium patens

post-translational modifications acetylation phosphorylation 2D-to-3D transition Physcomitrium patens

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