Carboxylation capacity is the main limitation of carbon assimilation in High Arctic shrubs

Abstract Increases in shrub height, biomass and canopy cover are key whole‐plant features of warming‐induced vegetation change in tundra. We investigated leaf functional traits underlying photosynthetic capacity of Arctic shrub species, particularly its main limiting processes such as mesophyll cond...

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Published in:Plant, Cell & Environment
Main Authors: Paillassa, Jennifer, Pepin, Steeve, Ethier, Gilbert, Lamarque, Laurent J., Maire, Vincent
Format: Article in Journal/Newspaper
Language:English
Published: Wiley 2024
Subjects:
Tundra
Online Access:http://dx.doi.org/10.1111/pce.15097
https://onlinelibrary.wiley.com/doi/pdf/10.1111/pce.15097
id crwiley:10.1111/pce.15097
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spelling crwiley:10.1111/pce.15097 2024-09-15T18:39:40+00:00 Carboxylation capacity is the main limitation of carbon assimilation in High Arctic shrubs Paillassa, Jennifer Pepin, Steeve Ethier, Gilbert Lamarque, Laurent J. Maire, Vincent 2024 http://dx.doi.org/10.1111/pce.15097 https://onlinelibrary.wiley.com/doi/pdf/10.1111/pce.15097 en eng Wiley http://onlinelibrary.wiley.com/termsAndConditions#vor Plant, Cell & Environment ISSN 0140-7791 1365-3040 journal-article 2024 crwiley https://doi.org/10.1111/pce.15097 2024-08-30T04:10:29Z Abstract Increases in shrub height, biomass and canopy cover are key whole‐plant features of warming‐induced vegetation change in tundra. We investigated leaf functional traits underlying photosynthetic capacity of Arctic shrub species, particularly its main limiting processes such as mesophyll conductance. In this nutrient‐limited ecosystem, we expect leaf nitrogen concentration to be the main limiting factor for photosynthesis. We measured the net photosynthetic rate at saturated light (A sat ) in three Salix species throughout a glacial valley in High‐Arctic tundra and used a causal approach to test relationships between leaf stomatal and mesophyll conductances (g sc , g m ), carboxylation capacity (Vc max ), nitrogen and phosphorus concentration (N area , P area ) and leaf mass ratio (LMA). Arctic Salix species showed no difference in A sat compared to a global data set, while being characterized by higher N area , P area and LMA. Vc max , g sc and g m independently increased A sat , with Vc max as its main limitation. We highlighted a nitrogen‐influenced pathway for increasing photosynthesis in the two prostrate mesic habitat species. In contrast, the erect wetland habitat Salix richardsonii mainly increased A sat with increasing g sc . Overall, our study revealed high photosynthetic capacities of Arctic Salix species but contrasting regulatory pathways that may influence shrub ability to respond to environmental changes in High Arctic tundra. Article in Journal/Newspaper Tundra Wiley Online Library Plant, Cell & Environment
institution Open Polar
collection Wiley Online Library
op_collection_id crwiley
language English
description Abstract Increases in shrub height, biomass and canopy cover are key whole‐plant features of warming‐induced vegetation change in tundra. We investigated leaf functional traits underlying photosynthetic capacity of Arctic shrub species, particularly its main limiting processes such as mesophyll conductance. In this nutrient‐limited ecosystem, we expect leaf nitrogen concentration to be the main limiting factor for photosynthesis. We measured the net photosynthetic rate at saturated light (A sat ) in three Salix species throughout a glacial valley in High‐Arctic tundra and used a causal approach to test relationships between leaf stomatal and mesophyll conductances (g sc , g m ), carboxylation capacity (Vc max ), nitrogen and phosphorus concentration (N area , P area ) and leaf mass ratio (LMA). Arctic Salix species showed no difference in A sat compared to a global data set, while being characterized by higher N area , P area and LMA. Vc max , g sc and g m independently increased A sat , with Vc max as its main limitation. We highlighted a nitrogen‐influenced pathway for increasing photosynthesis in the two prostrate mesic habitat species. In contrast, the erect wetland habitat Salix richardsonii mainly increased A sat with increasing g sc . Overall, our study revealed high photosynthetic capacities of Arctic Salix species but contrasting regulatory pathways that may influence shrub ability to respond to environmental changes in High Arctic tundra.
format Article in Journal/Newspaper
author Paillassa, Jennifer
Pepin, Steeve
Ethier, Gilbert
Lamarque, Laurent J.
Maire, Vincent
spellingShingle Paillassa, Jennifer
Pepin, Steeve
Ethier, Gilbert
Lamarque, Laurent J.
Maire, Vincent
Carboxylation capacity is the main limitation of carbon assimilation in High Arctic shrubs
author_facet Paillassa, Jennifer
Pepin, Steeve
Ethier, Gilbert
Lamarque, Laurent J.
Maire, Vincent
author_sort Paillassa, Jennifer
title Carboxylation capacity is the main limitation of carbon assimilation in High Arctic shrubs
title_short Carboxylation capacity is the main limitation of carbon assimilation in High Arctic shrubs
title_full Carboxylation capacity is the main limitation of carbon assimilation in High Arctic shrubs
title_fullStr Carboxylation capacity is the main limitation of carbon assimilation in High Arctic shrubs
title_full_unstemmed Carboxylation capacity is the main limitation of carbon assimilation in High Arctic shrubs
title_sort carboxylation capacity is the main limitation of carbon assimilation in high arctic shrubs
publisher Wiley
publishDate 2024
url http://dx.doi.org/10.1111/pce.15097
https://onlinelibrary.wiley.com/doi/pdf/10.1111/pce.15097
genre Tundra
genre_facet Tundra
op_source Plant, Cell & Environment
ISSN 0140-7791 1365-3040
op_rights http://onlinelibrary.wiley.com/termsAndConditions#vor
op_doi https://doi.org/10.1111/pce.15097
container_title Plant, Cell & Environment
_version_ 1810484016778838016

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