The circadian clock participates in seasonal growth in Norway spruce (Picea abies).
Lázaro-Gimeno, D., Ferrari, C., Delhomme, N., Johansson, M., Sjölander, J., Singh, R. K., Mutwil, M., & Eriksson, M. E
Tree Physiology, 44(11): tpae139. November 2024.
Paper
doi
link
bibtex
abstract
@article{lazaro-gimeno_circadian_2024,
title = {The circadian clock participates in seasonal growth in {Norway} spruce ({Picea} abies)},
volume = {44},
issn = {1758-4469},
url = {https://doi.org/10.1093/treephys/tpae139},
doi = {10.1093/treephys/tpae139},
abstract = {The boreal forest ecosystems of the northern hemisphere are dominated by conifers, of which Norway spruce (Picea abies [L.] H. Karst.) is one of the most common species. Due to its economic interest to the agroforestry industry, as well as its ecological significance, it is important to understand seasonal growth and biomass production in Norway spruce. Solid evidence that the circadian clock regulates growth in conifers has proved elusive, however, resulting in significant gaps in our knowledge of clock function in these trees. Here, we reassess the impact of the circadian clock on growth in Norway spruce. Using a combination of approaches monitoring the physiology of vegetative growth, transcriptomics and bioinformatics, we determined that the clock could be playing a decisive role in enabling growth, acting in specific developmental processes influenced by season and geographical location to guide bud burst and growth. Thus, the evidence indicates that there is time for spruce.},
number = {11},
urldate = {2024-11-29},
journal = {Tree Physiology},
author = {Lázaro-Gimeno, David and Ferrari, Camilla and Delhomme, Nico and Johansson, Mikael and Sjölander, Johan and Singh, Rajesh Kumar and Mutwil, Marek and Eriksson, Maria E},
month = nov,
year = {2024},
pages = {tpae139},
}
The boreal forest ecosystems of the northern hemisphere are dominated by conifers, of which Norway spruce (Picea abies [L.] H. Karst.) is one of the most common species. Due to its economic interest to the agroforestry industry, as well as its ecological significance, it is important to understand seasonal growth and biomass production in Norway spruce. Solid evidence that the circadian clock regulates growth in conifers has proved elusive, however, resulting in significant gaps in our knowledge of clock function in these trees. Here, we reassess the impact of the circadian clock on growth in Norway spruce. Using a combination of approaches monitoring the physiology of vegetative growth, transcriptomics and bioinformatics, we determined that the clock could be playing a decisive role in enabling growth, acting in specific developmental processes influenced by season and geographical location to guide bud burst and growth. Thus, the evidence indicates that there is time for spruce.
Photosynthetic advantages of conifers in the boreal forest.
Bag, P., Ivanov, A. G., Huner, N. P., & Jansson, S.
Trends in Plant Science. November 2024.
Paper
doi
link
bibtex
abstract
@article{bag_photosynthetic_2024,
title = {Photosynthetic advantages of conifers in the boreal forest},
issn = {1360-1385},
url = {https://www.sciencedirect.com/science/article/pii/S1360138524003005},
doi = {10.1016/j.tplants.2024.10.018},
abstract = {Boreal conifers – the ‘Christmas trees’ – maintain their green needles over the winter by retaining their chlorophyll. These conifers face the toughest challenge in February and March, when subzero temperatures coincide with high solar radiation. To balance the light energy they harvest with the light energy they utilise, conifers deploy various mechanisms in parallel. These include, thylakoid destacking, which facilitates direct energy transfer from Photosystem II (PSII) to Photosystem I (PSI), and excess energy dissipation through sustained nonphotochemical quenching (NPQ). Additionally, they upregulate alternative electron transport pathways to safely reroute excess electrons while maintaining ATP production. From an evolutionary and ecological perspective, we consider these mechanisms as part of a comprehensive photosynthetic alteration, which enhances our understanding of winter acclimation in conifers and their dominance in the boreal forests.},
urldate = {2024-11-28},
journal = {Trends in Plant Science},
author = {Bag, Pushan and Ivanov, Alexander G. and Huner, Norman P. and Jansson, Stefan},
month = nov,
year = {2024},
keywords = {alternative electron transport, conifers, direct energy transfer, flavodiiron proteins, nonphotochemical quenching (NPQ), photosystems},
}
Boreal conifers – the ‘Christmas trees’ – maintain their green needles over the winter by retaining their chlorophyll. These conifers face the toughest challenge in February and March, when subzero temperatures coincide with high solar radiation. To balance the light energy they harvest with the light energy they utilise, conifers deploy various mechanisms in parallel. These include, thylakoid destacking, which facilitates direct energy transfer from Photosystem II (PSII) to Photosystem I (PSI), and excess energy dissipation through sustained nonphotochemical quenching (NPQ). Additionally, they upregulate alternative electron transport pathways to safely reroute excess electrons while maintaining ATP production. From an evolutionary and ecological perspective, we consider these mechanisms as part of a comprehensive photosynthetic alteration, which enhances our understanding of winter acclimation in conifers and their dominance in the boreal forests.
Biohybrid Energy Storage Circuits Based on Electronically Functionalized Plant Roots.
Parker, D., Dar, A. M., Armada-Moreira, A., Bernacka Wojcik, I., Rai, R., Mantione, D., & Stavrinidou, E.
ACS Applied Materials & Interfaces, 16(45): 61475–61483. November 2024.
Publisher: American Chemical Society
Paper
doi
link
bibtex
abstract
@article{parker_biohybrid_2024,
title = {Biohybrid {Energy} {Storage} {Circuits} {Based} on {Electronically} {Functionalized} {Plant} {Roots}},
volume = {16},
issn = {1944-8244},
url = {https://doi.org/10.1021/acsami.3c16861},
doi = {10.1021/acsami.3c16861},
abstract = {Biohybrid systems based on plants integrate plant structures and processes into technological components targeting more sustainable solutions. Plants’ biocatalytic machinery, for example, has been leveraged for the organization of electronic materials directly in the vasculature and roots of living plants, resulting in biohybrid electrochemical devices. Among other applications, energy storage devices were demonstrated where the charge storage electrodes were seamlessly integrated into the plant tissue. However, the capacitance and the voltage output of a single biohybrid supercapacitor are limited. Here, we developed biohybrid circuits based on functionalized conducting roots, extending the performance of plant based biohybrid energy storage systems. We show that root-supercapacitors can be combined in series and in parallel configuration, achieving up to 1.5 V voltage output or up to 11 mF capacitance, respectively. We further demonstrate that the supercapacitors circuit can be charged with an organic photovoltaic cell, and that the stored charge can be used to power an electrochromic display or a bioelectronic device. Furthermore, the functionalized roots degrade in composting similarly to native roots. The proof-of-concept demonstrations illustrate the potential of this technology to achieve more sustainable solutions for powering low consumption devices such as bioelectronics for agriculture or IoT applications.},
number = {45},
urldate = {2024-11-22},
journal = {ACS Applied Materials \& Interfaces},
author = {Parker, Daniela and Dar, Abdul Manan and Armada-Moreira, Adam and Bernacka Wojcik, Iwona and Rai, Rajat and Mantione, Daniele and Stavrinidou, Eleni},
month = nov,
year = {2024},
note = {Publisher: American Chemical Society},
pages = {61475--61483},
}
Biohybrid systems based on plants integrate plant structures and processes into technological components targeting more sustainable solutions. Plants’ biocatalytic machinery, for example, has been leveraged for the organization of electronic materials directly in the vasculature and roots of living plants, resulting in biohybrid electrochemical devices. Among other applications, energy storage devices were demonstrated where the charge storage electrodes were seamlessly integrated into the plant tissue. However, the capacitance and the voltage output of a single biohybrid supercapacitor are limited. Here, we developed biohybrid circuits based on functionalized conducting roots, extending the performance of plant based biohybrid energy storage systems. We show that root-supercapacitors can be combined in series and in parallel configuration, achieving up to 1.5 V voltage output or up to 11 mF capacitance, respectively. We further demonstrate that the supercapacitors circuit can be charged with an organic photovoltaic cell, and that the stored charge can be used to power an electrochromic display or a bioelectronic device. Furthermore, the functionalized roots degrade in composting similarly to native roots. The proof-of-concept demonstrations illustrate the potential of this technology to achieve more sustainable solutions for powering low consumption devices such as bioelectronics for agriculture or IoT applications.