Agritrop
Accueil

The case for improving crop carbon sink strength or plasticity for a CO2-rich future

Dingkuhn Michael, Luquet Delphine, Fabre Denis, Muller Bertrand, Yin Xinyou, Paul Matthew J.. 2020. The case for improving crop carbon sink strength or plasticity for a CO2-rich future. Current Opinion in Plant Biology, 56, n.spéc. Biotic interactions AGRI 2019 : 259-272.

Article de revue ; Article de recherche ; Article de revue à facteur d'impact
[img] Version publiée - Anglais
Accès réservé aux personnels Cirad
Utilisation soumise à autorisation de l'auteur ou du Cirad.
Dingkuhn_et_al_COPB2020_Sinks_for_CO2.pdf

Télécharger (1MB) | Demander une copie
[img]
Prévisualisation
Version post-print - Anglais
Sous licence Licence Creative Commons.
ID596382.pdf

Télécharger (557kB) | Prévisualisation

Quartile : Outlier, Sujet : PLANT SCIENCES

Résumé : Atmospheric CO2 concentration [CO2] has increased from 260 to 280 μmol mol−1 (level during crop domestication up to the industrial revolution) to currently 400 and will reach 550 μmol mol−1 by 2050. C3 crops are expected to benefit from elevated [CO2] (e-CO2) thanks to photosynthesis responsiveness to [CO2] but this may require greater sink capacity. We review recent literature on crop e-CO2 responses, related source-sink interactions, how abiotic stresses potentially interact, and prospects to improve e-CO2 response via breeding or genetic engineering. Several lines of evidence suggest that e-CO2 responsiveness is related either to sink intrinsic capacity or adaptive plasticity, for example, involving enhanced branching. Wild relatives and old cultivars mostly showed lower photosynthetic rates, less downward acclimation of photosynthesis to e-CO2 and responded strongly to e-CO2 due to greater phenotypic plasticity. While reverting to such archaic traits would be an inappropriate strategy for breeding, we argue that substantial enhancement of vegetative sink vigor, inflorescence size and/or number and root sinks will be necessary to fully benefit from e-CO2. Potential ideotype features based on enhanced sinks are discussed. The generic 'feast-famine' sugar signaling pathway may be suited to engineer sink strength tissue-specifically and stage-specifically and help validate ideotype concepts. Finally, we argue that models better accounting for acclimation to e-CO2 are needed to predict which trait combinations should be targeted by breeders for a CO2-rich world.

Mots-clés Agrovoc : séquestration du carbone, amélioration des plantes, génie génétique

Classification Agris : F60 - Physiologie et biochimie végétale

Champ stratégique Cirad : CTS 2 (2019-) - Transitions agroécologiques

Auteurs et affiliations

  • Dingkuhn Michael, CIRAD-BIOS-UMR AGAP (FRA) - auteur correspondant
  • Luquet Delphine, CIRAD-BIOS-UMR AGAP (FRA) ORCID: 0000-0002-2543-7140
  • Fabre Denis, CIRAD-BIOS-UMR AGAP (FRA) ORCID: 0000-0002-6222-2587
  • Muller Bertrand, CIRAD-BIOS-UMR AGAP (MDG)
  • Yin Xinyou, Wageningen University and Research Centre (NLD)
  • Paul Matthew J., Rothamsted Research (GBR)

Source : Cirad-Agritrop (https://agritrop.cirad.fr/596382/)

Voir la notice (accès réservé à Agritrop) Voir la notice (accès réservé à Agritrop)

[ Page générée et mise en cache le 2024-12-18 ]