Modelling Net CO2 Assimilation of Two Sphagnum Species From Temperature and Water Content Response

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Grant support

This work was supported by the European Union H2020 through INTERACT Transnational Access [Grant Agreement No. 871120, RESPIRA]. MN was supported by the postdoctoral fellowship Juan de la Cierva-Formacion (FJC2020-043902-I), funded by MCIN/AEI/10.13039/501100011033 and the European Union ('Next Generation EU/PRTR).

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31 de julio de 2025

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Artículo

Publicado en:Physiologia Plantarum. 177 (3): e70325- - 2025-05-01 177(3), DOI: 10.1111/ppl.70325

Autores: Perera-Castro, Alicia V; Nadal, Miquel

Afiliaciones

Ctr Invest & Tecnol Agroalimentaria Aragon CITA, Dept Sistemas Agr Forestales & Medio Ambiente, Zaragoza, Spain - Autor o Coautor

Univ Hohenheim, Inst Biol, Stuttgart, Germany - Autor o Coautor

Univ La Laguna, Dept Bot Ecol & Plant Physiol, San Cristobal la Laguna, Canarias Island, Spain - Autor o Coautor

Univ Lorraine, AgroParisTech, INRAE, UMR Silva, Nancy, France - Autor o Coautor

Resumen

Photosynthesis and respiration respond differently to the combined effects of temperature and water status. Quantifying their responses is crucial to predict the carbon balance of Sphagnum peatlands in different scenarios of climate change. A first approach was done for two Sphagnum species inhabiting a boreal peatland in Finland. Gas exchange at different temperatures and moss hydration were measured to model net assimilation using simultaneous measurements of photosynthesis and dark respiration. In addition, measurements of moss surface temperature at different water content were performed in the field, covering natural conditions of sun exposure and air temperature. We also accounted for the interaction effect between moss canopy temperature and air temperature, radiation, and water content. Our model accurately predicted net assimilation and was used to estimate net primary productivity based on meteorological inputs and moss water content. The two Sphagnum species presented optimum temperatures for net CO2 assimilation around 25 degrees C, with minimum changes at other temperatures. In contrast, dark respiration increased exponentially with temperature, which makes losses of carbon during the night and the duration of dark conditions key determinants in the carbon balance of Sphagnum. The modeled net primary productivity revealed an enhancement of CO2 fixation under warming conditions (averaged +10 degrees C), concomitant to the expected transformation of peatlands from sink to source of CO2. Our model highlighted the importance of respiration restriction in ensuring positive assimilation in Sphagnum. Therefore, day and night temperature oscillation and short night photoperiods are more important than the optimum temperature of photosynthesis for carbon balance.

Palabras clave

<italic>sphagnum</italicBryophytesCambio climáticoCarbon accumulationCarbon balanceContent componentsDesiccation-toleranceFotosíntesisGas-exchangeGrowth-rateMossesPatternPeatlandsPhotoperiodPhotosynthetic responsesPrimary productivityProductividad primaria netaRespirationSphagnumTurba

Indicios de calidad

Impacto bibliométrico. Análisis de la aportación y canal de difusión

El trabajo ha sido publicado en la revista PHYSIOLOGIA PLANTARUM debido a la progresión y el buen impacto que ha alcanzado en los últimos años, según la agencia WoS (JCR), se ha convertido en una referencia en su campo. En el año de publicación del trabajo, 2025, se encontraba en la posición 58/273, consiguiendo con ello situarse como revista Q1 (Primer Cuartil), en la categoría Plant Sciences.

Impacto y visibilidad social

Análisis de liderazgo de los autores institucionales

Este trabajo se ha realizado con colaboración internacional, concretamente con investigadores de: France; Germany.