Redox signalling in plant–nematode interactions: Insights into molecular crosstalk and defense mechanisms.
Hasan, M. S., Lin, C., Marhavy, P., Kyndt, T., & Siddique, S.
Plant, Cell & Environment, 47(8): 2811–2820. 2024.
_eprint: https://onlinelibrary.wiley.com/doi/pdf/10.1111/pce.14925
Paper
doi
link
bibtex
abstract
@article{hasan_redox_2024,
title = {Redox signalling in plant–nematode interactions: {Insights} into molecular crosstalk and defense mechanisms},
volume = {47},
copyright = {© 2024 John Wiley \& Sons Ltd.},
issn = {1365-3040},
shorttitle = {Redox signalling in plant–nematode interactions},
url = {https://onlinelibrary.wiley.com/doi/abs/10.1111/pce.14925},
doi = {10.1111/pce.14925},
abstract = {Plant–parasitic nematodes, specifically cyst nematodes (CNs) and root-knot nematodes (RKNs), pose significant threats to global agriculture, leading to substantial crop losses. Both CNs and RKNs induce permanent feeding sites in the root of their host plants, which then serve as their only source of nutrients throughout their lifecycle. Plants deploy reactive oxygen species (ROS) as a primary defense mechanism against nematode invasion. Notably, both CNs and RKNs have evolved sophisticated strategies to manipulate the host's redox environment to their advantage, with each employing distinct tactics to combat ROS. In this review, we have focused on the role of ROS and its scavenging network in interactions between host plants and CNs and RKNs. Overall, this review emphasizes the complex interplay between plant defense mechanism, redox signalling and nematode survival tactics, suggesting potential avenues for developing innovative nematode management strategies in agriculture.},
language = {en},
number = {8},
urldate = {2024-07-19},
journal = {Plant, Cell \& Environment},
author = {Hasan, M. Shamim and Lin, Ching-Jung and Marhavy, Peter and Kyndt, Tina and Siddique, Shahid},
year = {2024},
note = {\_eprint: https://onlinelibrary.wiley.com/doi/pdf/10.1111/pce.14925},
keywords = {ROS, antioxidants, cyst nematodes, effectors, root-knot nematodes},
pages = {2811--2820},
}
Plant–parasitic nematodes, specifically cyst nematodes (CNs) and root-knot nematodes (RKNs), pose significant threats to global agriculture, leading to substantial crop losses. Both CNs and RKNs induce permanent feeding sites in the root of their host plants, which then serve as their only source of nutrients throughout their lifecycle. Plants deploy reactive oxygen species (ROS) as a primary defense mechanism against nematode invasion. Notably, both CNs and RKNs have evolved sophisticated strategies to manipulate the host's redox environment to their advantage, with each employing distinct tactics to combat ROS. In this review, we have focused on the role of ROS and its scavenging network in interactions between host plants and CNs and RKNs. Overall, this review emphasizes the complex interplay between plant defense mechanism, redox signalling and nematode survival tactics, suggesting potential avenues for developing innovative nematode management strategies in agriculture.
Closing Kok’s cycle of nature’s water oxidation catalysis.
Guo, Y., He, L., Ding, Y., Kloo, L., Pantazis, D. A., Messinger, J., & Sun, L.
Nature Communications, 15(1): 5982. July 2024.
Publisher: Nature Publishing Group
Paper
doi
link
bibtex
abstract
@article{guo_closing_2024,
title = {Closing {Kok}’s cycle of nature’s water oxidation catalysis},
volume = {15},
copyright = {2024 The Author(s)},
issn = {2041-1723},
url = {https://www.nature.com/articles/s41467-024-50210-6},
doi = {10.1038/s41467-024-50210-6},
abstract = {The Mn4CaO5(6) cluster in photosystem II catalyzes water splitting through the Si state cycle (i = 0–4). Molecular O2 is formed and the natural catalyst is reset during the final S3 → (S4) → S0 transition. Only recently experimental breakthroughs have emerged for this transition but without explicit information on the S0-state reconstitution, thus the progression after O2 release remains elusive. In this report, our molecular dynamics simulations combined with density functional calculations suggest a likely missing link for closing the cycle, i.e., restoring the first catalytic state. Specifically, the formation of closed-cubane intermediates with all hexa-coordinate Mn is observed, which would undergo proton release, water dissociation, and ligand transfer to produce the open-cubane structure of the S0 state. Thereby, we theoretically identify the previously unknown structural isomerism in the S0 state that acts as the origin of the proposed structural flexibility prevailing in the cycle, which may be functionally important for nature’s water oxidation catalysis.},
language = {en},
number = {1},
urldate = {2024-07-19},
journal = {Nature Communications},
author = {Guo, Yu and He, Lanlan and Ding, Yunxuan and Kloo, Lars and Pantazis, Dimitrios A. and Messinger, Johannes and Sun, Licheng},
month = jul,
year = {2024},
note = {Publisher: Nature Publishing Group},
keywords = {Bioinorganic chemistry, Catalytic mechanisms, Reaction mechanisms},
pages = {5982},
}
The Mn4CaO5(6) cluster in photosystem II catalyzes water splitting through the Si state cycle (i = 0–4). Molecular O2 is formed and the natural catalyst is reset during the final S3 → (S4) → S0 transition. Only recently experimental breakthroughs have emerged for this transition but without explicit information on the S0-state reconstitution, thus the progression after O2 release remains elusive. In this report, our molecular dynamics simulations combined with density functional calculations suggest a likely missing link for closing the cycle, i.e., restoring the first catalytic state. Specifically, the formation of closed-cubane intermediates with all hexa-coordinate Mn is observed, which would undergo proton release, water dissociation, and ligand transfer to produce the open-cubane structure of the S0 state. Thereby, we theoretically identify the previously unknown structural isomerism in the S0 state that acts as the origin of the proposed structural flexibility prevailing in the cycle, which may be functionally important for nature’s water oxidation catalysis.
Toward uncovering an operating system in plant organs.
Davis, G. V., de Souza Moraes, T., Khanapurkar, S., Dromiack, H., Ahmad, Z., Bayer, E. M., Bhalerao, R. P., Walker, S. I., & Bassel, G. W.
Trends in Plant Science, 29(7): 742–753. July 2024.
Paper
doi
link
bibtex
abstract
@article{davis_toward_2024,
title = {Toward uncovering an operating system in plant organs},
volume = {29},
issn = {1360-1385},
url = {https://www.sciencedirect.com/science/article/pii/S1360138523003655},
doi = {10.1016/j.tplants.2023.11.006},
abstract = {Molecular motifs can explain information processing within single cells, while how assemblies of cells collectively achieve this remains less well understood. Plant fitness and survival depend upon robust and accurate decision-making in their decentralised multicellular organ systems. Mobile agents, including hormones, metabolites, and RNAs, have a central role in coordinating multicellular collective decision-making, yet mechanisms describing how cell–cell communication scales to organ-level transitions is poorly understood. Here, we explore how unified outputs may emerge in plant organs by distributed information processing across different scales and using different modalities. Mathematical and computational representations of these events are also explored toward understanding how these events take place and are leveraged to manipulate plant development in response to the environment.},
number = {7},
urldate = {2024-07-17},
journal = {Trends in Plant Science},
author = {Davis, Gwendolyn V. and de Souza Moraes, Tatiana and Khanapurkar, Swanand and Dromiack, Hannah and Ahmad, Zaki and Bayer, Emmanuelle M. and Bhalerao, Rishikesh P. and Walker, Sara I. and Bassel, George W.},
month = jul,
year = {2024},
keywords = {Cellular Automata, collective behaviour, decentralised information processing, decision-making, plant development},
pages = {742--753},
}
Molecular motifs can explain information processing within single cells, while how assemblies of cells collectively achieve this remains less well understood. Plant fitness and survival depend upon robust and accurate decision-making in their decentralised multicellular organ systems. Mobile agents, including hormones, metabolites, and RNAs, have a central role in coordinating multicellular collective decision-making, yet mechanisms describing how cell–cell communication scales to organ-level transitions is poorly understood. Here, we explore how unified outputs may emerge in plant organs by distributed information processing across different scales and using different modalities. Mathematical and computational representations of these events are also explored toward understanding how these events take place and are leveraged to manipulate plant development in response to the environment.
Obscurity of chlorophyll tails - Is chlorophyll with farnesyl tail incorporated into PSII complexes?.
Graça, A. T., Lihavainen, J., Hussein, R., & Schröder, W. P.
Physiologia Plantarum, 176(4): e14428. July 2024.
Publisher: John Wiley & Sons, Ltd
Paper
doi
link
bibtex
abstract
@article{graca_obscurity_2024,
title = {Obscurity of chlorophyll tails - {Is} chlorophyll with farnesyl tail incorporated into {PSII} complexes?},
volume = {176},
issn = {0031-9317},
url = {https://onlinelibrary.wiley.com/doi/10.1111/ppl.14428},
doi = {10.1111/ppl.14428},
abstract = {Abstract Chlorophyll is essential in photosynthesis, converting sunlight into chemical energy in plants, algae, and certain bacteria. Its structure, featuring a porphyrin ring enclosing a central magnesium ion, varies in forms like chlorophyll a, b, c, d, and f, allowing light absorption at a broader spectrum. With a 20-carbon phytyl tail (except for chlorophyll c), chlorophyll is anchored to proteins. Previous findings suggested the presence of chlorophyll with a modified farnesyl tail in thermophilic cyanobacteria Thermosynechoccocus vestitus. In our Arabidopsis thaliana PSII cryo-EM map, specific chlorophylls showed incomplete phytyl tails, suggesting potential farnesyl modifications. However, further high-resolution mass spectrometry (HRMS) analysis in A. thaliana and T. vestitus did not confirm the presence of any farnesyl tails. Instead, we propose the truncated tails in PSII models may result from binding pocket flexibility rather than actual modifications.},
number = {4},
urldate = {2024-07-17},
journal = {Physiologia Plantarum},
author = {Graça, André T. and Lihavainen, Jenna and Hussein, Rana and Schröder, Wolfgang P.},
month = jul,
year = {2024},
note = {Publisher: John Wiley \& Sons, Ltd},
pages = {e14428},
}
Abstract Chlorophyll is essential in photosynthesis, converting sunlight into chemical energy in plants, algae, and certain bacteria. Its structure, featuring a porphyrin ring enclosing a central magnesium ion, varies in forms like chlorophyll a, b, c, d, and f, allowing light absorption at a broader spectrum. With a 20-carbon phytyl tail (except for chlorophyll c), chlorophyll is anchored to proteins. Previous findings suggested the presence of chlorophyll with a modified farnesyl tail in thermophilic cyanobacteria Thermosynechoccocus vestitus. In our Arabidopsis thaliana PSII cryo-EM map, specific chlorophylls showed incomplete phytyl tails, suggesting potential farnesyl modifications. However, further high-resolution mass spectrometry (HRMS) analysis in A. thaliana and T. vestitus did not confirm the presence of any farnesyl tails. Instead, we propose the truncated tails in PSII models may result from binding pocket flexibility rather than actual modifications.