Plant breeding and climate changes

Ceccarelli, Salvatore; Grando, S.; Maatougui, M.; Michael, M.; Slash, M.; Haghparast, Reza; Rahmanian, Maryam; Taheri, Alireza; Al-Yassin, Adnan; Benbelkacem, A.; Labdi, Mohamed; Mimoun, H.; Nachit, M. M.

doi:10.1017/s0021859610000651

Cited by 307 publications

(195 citation statements)

References 69 publications

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“…The development of genotypes with better performance at high temperatures, high CO 2 concentration, and under water and salt stress has become a challenge that must be met with a certain urgency due to the ongoing climate changes (Ceccarelli et al 2010). However, facing these challenges and developing soybean cultivars with the desirable traits requires a diversification of the genetic background of the current breeding population by incorporating new genetic backgrounds from other countries.…”

Section: Resultsmentioning

confidence: 99%

Genetic diversity in Brazilian soybean germplasm

Gwinner

Setotaw

Pasqual

et al. 2017

Crop Breed. Appl. Biotechnol.

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Section: Resultsmentioning

confidence: 99%

Genetic diversity in Brazilian soybean germplasm

Gwinner

Setotaw

Pasqual

et al. 2017

Crop Breed. Appl. Biotechnol.

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“…The use of such varieties in organic agriculture promotes an input substitution approach increasing the risk for conventionalisation [28]. The diffusion of selection processes across different environmental conditions incorporating the direct involvement of farmers has great potential to develop crop varieties better adapted to different organic and low input farming systems [29]. Decentralized and Participatory Plant Breeding (PPB) is a promising approach for developing innovation in plant breeding following the agroecological paradigm.…”

Section: Plant Breeding As An Example Of Knowledge Management In Two mentioning

confidence: 99%

“…PPB has been carried out traditionally with small farmers in developing countries [25,30,31]. More recently it has been proposed as an alternative breeding approach for organic and low input farming in Europe [32] with a focus on adaptation to climate change [29]. PPB is often criticized for the high investment in time and resources required to build farmer networks, but in a context where farmers are already embedded in social networks such investments can be significantly lower and may not entail additional efforts for dissemination or marketing of the varieties released [33].…”

Section: Plant Breeding As An Example Of Knowledge Management In Two mentioning

confidence: 99%

Changes in Knowledge Management Strategies Can Support Emerging Innovative Actors in Organic Agriculture: The Case of Participatory Plant Breeding in Europe

Ortolani

Bocci

Bàrberi

et al. 2017

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Abstract:The "transfer of technology", typical of a top-down linear process of innovation cannot be used in the new contexts of sustainability, characterised by uncertainty and complexity. There is a need to redefine categories and concepts around which innovation and agricultural policies are built, as those currently in use provide only a partial representation of reality. Innovation paradigms underpinning technological development and public policies design will have a direct impact on decisions regarding which agricultural models will ultimately be supported. Looking at local learning capacity and systems of relations can help to understand the potential to develop innovation within a specific context. This work contributes to the definition of new actors who are developing innovation for sustainability in rural areas. The study focuses on the knowledge systems of farmers who are applying alternative breeding strategies: it uses a network approach to explore the knowledge system in which individual farmers are embedded in order to understand their specific relational features. Three main conclusions emerge from the study: for enhancing the agro-ecological innovation paradigm there is a need to define the 'innovation broker', to revise the evaluation system of public research and to integrate innovation and agricultural policies.

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“…Plant breeding is considered to be a substantial tool for adaptation strategies to climate change (Ceccarelli et al, 2010). Breeding for new varieties better adapted to thermal shocks (heat, cold) and drought is often suggested as the major long-term adaptation.…”

Section: Genetics and Plant Breedingmentioning

confidence: 99%

“…Breeding for new varieties better adapted to thermal shocks (heat, cold) and drought is often suggested as the major long-term adaptation. The breeding strategies aim at improved water efficiency, improved drought stress tolerance, and increased responsiveness to higher atmospheric [CO 2 ] (Ceccarelli et al, 2010;Ziska et al, 2012). However, prospective results of plant breeding are unforeseeable and the impact assessment strongly depends on the assumptions made on breeding progress (Graß et al, 2015).…”

Section: Genetics and Plant Breedingmentioning

confidence: 99%

Sunflower crop and climate change: vulnerability, adaptation, and mitigation potential from case-studies in Europe

Debaeke¹,

Casadebaig²,

Flénet

et al. 2017

OCL

101

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-Climate change is characterized by higher temperatures, elevated atmospheric CO 2 concentrations, extreme climatic hazards, and less water available for agriculture. Sunflower, a springsown crop often cultivated in southern and eastern regions of Europe, could be more vulnerable to the direct effect of heat stress at anthesis and drought during its growing cycle, both factors resulting in severe yield loss, oil content decrease, and fatty acid alterations. Adaptations through breeding (earliness, stress tolerance), crop management (planting dates), and shifting of growing areas could be developed, assessed and combined to partly cope with these negative impacts. New cultivation opportunities could be expected in northern parts of Europe where sunflower is not grown presently and where it could usefully contribute to diversify cereal-based cropping systems. In addition, sunflower crop could participate to the mitigation solution as a low greenhouse gas emitter compared to cereals and oilseed rape. Sunflower crop models should be revised to account for these emerging environmental factors in order to reduce the uncertainties in yield and oil predictions. The future of sunflower in Europe is probably related to its potential adaptation to climate change but also to its competitiveness and attractiveness for food and energy.Keywords: CO 2 / temperature / crop model / biotic stress / water deficit Résumé -Culture du tournesol et changement climatique : vulnérabilité, adaptation et potentiel d'atténuation via des études de cas en Europe. Le changement climatique se caractérise par des températures élevées, de plus fortes concentrations atmosphériques en CO 2 , des risques climatiques extrêmes et moins d'eau disponible pour l'agriculture. Le tournesol, culture semée au printemps dans le sud et l'est de l'Europe, pourrait être plus exposé à l'avenir aux fortes températures et à un déficit hydrique marqué dès la floraison, avec pour conséquences des pertes de rendement, une diminution de la teneur en huile et une altération de la composition en acides gras. Des adaptations sont possibles à court et moyen terme par la sélection (précocité, tolérance aux stress), la conduite de culture (date de semis) et le déplacement des zones de production, permettant de faire face en partie aux impacts négatifs attendus. Ainsi le tournesol pourrait être cultivé plus au nord participant utilement à la nécessaire diversification des bassins céréaliers. En outre, la culture de tournesol étant faiblement émettrice de gaz à effet de serre par rapport aux céréales ou au colza pourrait contribuer davantage à la solution climatique apportée par l'agriculture. Les modèles de culture devraient être revus pour mieux tenir compte de ces facteurs environnementaux émergents si l'on veut réduire les incertitudes dans les prédictions de rendement et de teneur en huile. L'avenir du tournesol en Europe est probablement lié à son potentiel d'adaptation au changement climatique, mais dépendra aussi de sa compétitivité et de son attractivité en t...

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Plant breeding and climate changes

Cited by 307 publications

References 69 publications

Genetic diversity in Brazilian soybean germplasm

Genetic diversity in Brazilian soybean germplasm

Changes in Knowledge Management Strategies Can Support Emerging Innovative Actors in Organic Agriculture: The Case of Participatory Plant Breeding in Europe

Sunflower crop and climate change: vulnerability, adaptation, and mitigation potential from case-studies in Europe

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