Molecular advances in bud dormancy in trees.
Ding, J., Wang, K., Pandey, S., Perales, M., Allona, I., Khan, M. R. I., Busov, V. B, & Bhalerao, R. P
Journal of Experimental Botany, 75(19): 6063–6075. October 2024.
Paper
doi
link
bibtex
abstract
@article{ding_molecular_2024,
title = {Molecular advances in bud dormancy in trees},
volume = {75},
issn = {0022-0957},
url = {https://doi.org/10.1093/jxb/erae183},
doi = {10.1093/jxb/erae183},
abstract = {Seasonal bud dormancy in perennial woody plants is a crucial and intricate process that is vital for the survival and development of plants. Over the past few decades, significant advancements have been made in understanding many features of bud dormancy, particularly in model species, where certain molecular mechanisms underlying this process have been elucidated. We provide an overview of recent molecular progress in understanding bud dormancy in trees, with a specific emphasis on the integration of common signaling and molecular mechanisms identified across different tree species. Additionally, we address some challenges that have emerged from our current understanding of bud dormancy and offer insights for future studies.},
number = {19},
urldate = {2024-10-18},
journal = {Journal of Experimental Botany},
author = {Ding, Jihua and Wang, Kejing and Pandey, Shashank and Perales, Mariano and Allona, Isabel and Khan, Md Rezaul Islam and Busov, Victor B and Bhalerao, Rishikesh P},
month = oct,
year = {2024},
pages = {6063--6075},
}
Seasonal bud dormancy in perennial woody plants is a crucial and intricate process that is vital for the survival and development of plants. Over the past few decades, significant advancements have been made in understanding many features of bud dormancy, particularly in model species, where certain molecular mechanisms underlying this process have been elucidated. We provide an overview of recent molecular progress in understanding bud dormancy in trees, with a specific emphasis on the integration of common signaling and molecular mechanisms identified across different tree species. Additionally, we address some challenges that have emerged from our current understanding of bud dormancy and offer insights for future studies.
Exploring the world of small proteins in plant biology and bioengineering.
Petri, L., Van Humbeeck, A., Niu, H., Ter Waarbeek, C., Edwards, A., Chiurazzi, M. J., Vittozzi, Y., & Wenkel, S.
Trends in Genetics. October 2024.
Paper
doi
link
bibtex
abstract
@article{petri_exploring_2024,
title = {Exploring the world of small proteins in plant biology and bioengineering},
issn = {0168-9525},
url = {https://www.sciencedirect.com/science/article/pii/S0168952524002129},
doi = {10.1016/j.tig.2024.09.004},
abstract = {Small proteins are ubiquitous in all kingdoms of life. MicroProteins, initially characterized as small proteins with protein interaction domains that enable them to interact with larger multidomain proteins, frequently modulate the function of these proteins. The study of these small proteins has contributed to a greater comprehension of protein regulation. In addition to sequence homology, sequence-divergent small proteins have the potential to function as microProtein mimics, binding to structurally related proteins. Moreover, a multitude of other small proteins encoded by short open reading frames (sORFs) and peptides, derived from diverse sources such as long noncoding RNAs (lncRNAs) and miRNAs, contribute to a variety of biological processes. The potential of small proteins is evident, offering promising avenues for bioengineering that could revolutionize crop performance and reduce reliance on agrochemicals in future agriculture.},
urldate = {2024-10-18},
journal = {Trends in Genetics},
author = {Petri, Louise and Van Humbeeck, Anne and Niu, Huanying and Ter Waarbeek, Casper and Edwards, Ashleigh and Chiurazzi, Maurizio Junior and Vittozzi, Ylenia and Wenkel, Stephan},
month = oct,
year = {2024},
keywords = {lncRNA, microProteins, sORFs, transcription factor},
}
Small proteins are ubiquitous in all kingdoms of life. MicroProteins, initially characterized as small proteins with protein interaction domains that enable them to interact with larger multidomain proteins, frequently modulate the function of these proteins. The study of these small proteins has contributed to a greater comprehension of protein regulation. In addition to sequence homology, sequence-divergent small proteins have the potential to function as microProtein mimics, binding to structurally related proteins. Moreover, a multitude of other small proteins encoded by short open reading frames (sORFs) and peptides, derived from diverse sources such as long noncoding RNAs (lncRNAs) and miRNAs, contribute to a variety of biological processes. The potential of small proteins is evident, offering promising avenues for bioengineering that could revolutionize crop performance and reduce reliance on agrochemicals in future agriculture.
Cryo–electron microscopy reveals hydrogen positions and water networks in photosystem II.
Hussein, R., Graça, A., Forsman, J., Aydin, A. O., Hall, M., Gaetcke, J., Chernev, P., Wendler, P., Dobbek, H., Messinger, J., Zouni, A., & Schröder, W. P.
Science, 384(6702): 1349–1355. June 2024.
Publisher: American Association for the Advancement of Science
Paper
doi
link
bibtex
abstract
@article{hussein_cryoelectron_2024,
title = {Cryo–electron microscopy reveals hydrogen positions and water networks in photosystem {II}},
volume = {384},
url = {https://www.science.org/doi/10.1126/science.adn6541},
doi = {10.1126/science.adn6541},
abstract = {Photosystem II starts the photosynthetic electron transport chain that converts solar energy into chemical energy and thus sustains life on Earth. It catalyzes two chemical reactions: water oxidation to molecular oxygen and plastoquinone reduction. Coupling of electron and proton transfer is crucial for efficiency; however, the molecular basis of these processes remains speculative owing to uncertain water binding sites and the lack of experimentally determined hydrogen positions. We thus collected high-resolution cryo–electron microscopy data of fully hydrated photosystem II from the thermophilic cyanobacterium Thermosynechococcus vestitus to a final resolution of 1.71 angstroms. The structure reveals several previously undetected partially occupied water binding sites and more than half of the hydrogen and proton positions. This clarifies the pathways of substrate water binding and plastoquinone B protonation.},
number = {6702},
urldate = {2024-10-18},
journal = {Science},
author = {Hussein, Rana and Graça, André and Forsman, Jack and Aydin, A. Orkun and Hall, Michael and Gaetcke, Julia and Chernev, Petko and Wendler, Petra and Dobbek, Holger and Messinger, Johannes and Zouni, Athina and Schröder, Wolfgang P.},
month = jun,
year = {2024},
note = {Publisher: American Association for the Advancement of Science},
pages = {1349--1355},
}
Photosystem II starts the photosynthetic electron transport chain that converts solar energy into chemical energy and thus sustains life on Earth. It catalyzes two chemical reactions: water oxidation to molecular oxygen and plastoquinone reduction. Coupling of electron and proton transfer is crucial for efficiency; however, the molecular basis of these processes remains speculative owing to uncertain water binding sites and the lack of experimentally determined hydrogen positions. We thus collected high-resolution cryo–electron microscopy data of fully hydrated photosystem II from the thermophilic cyanobacterium Thermosynechococcus vestitus to a final resolution of 1.71 angstroms. The structure reveals several previously undetected partially occupied water binding sites and more than half of the hydrogen and proton positions. This clarifies the pathways of substrate water binding and plastoquinone B protonation.