Prospects for Genetic Improvement to Increase Lowland Rice Yields with Less Water and Nitrogen

Peng, Shaobing; Bouman, B.A.M.

doi:10.1007/1-4020-5906-x_20

Cited by 28 publications

(23 citation statements)

References 47 publications

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“…In the past, most progress in the improvement of rice yield potential was achieved when water and nutrients were amply supplied (Peng and Bouman, 2007). China has been at the forefront in developing high-yielding varieties using semidwarf, hybrid, and new plant type breeding approaches.…”

Section: Research Strategies For Increasing Rice Production In China mentioning

confidence: 99%

“…Therefore, it is not easy to achieve high yields with the "super" rice varieties consistently across seasons and locations. Because of water scarcity and environmental concerns, the challenge is to increase rice yield with less water and less chemicals (Peng and Bouman, 2007). To achieve this goal, new breeding techniques such as marker-aided selection, transformation, and genetic engineering should be combined effectively with the empirical breeding method.…”

Section: Research Strategies For Increasing Rice Production In China mentioning

confidence: 99%

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Current Status and Challenges of Rice Production in China

Peng

Tang

Zou

2009

Plant Production Science

603

310

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: Rice production in China has more than tripled in the past fi ve decades mainly due to increased grain yield rather than increased planting area. This increase has come from the development of high-yielding varieties and improved crop management practices such as nitrogen fertilization and irrigation. However, yield stagnation of rice has been observed in the past ten years in China. As its population rises, China will need to produce about 20% more rice by 2030 in order to meet its domestic needs if rice consumption per capita stays at the current level. This is not an easy task because several trends and problems in the Chinese rice production system constrain the sustainable increase in total rice production. Key trends include a decline in arable land, increasing water scarcity, global climate change, labor shortages, and increasing consumer demand for high-quality rice (which often comes from low-yielding varieties). The major problems confronting rice production in China are narrow genetic background, overuse of fertilizers and pesticides, breakdown of irrigation infrastructure, oversimplifi ed crop management, and a weak extension system. Despite these challenges, good research strategies can drive increased rice production in China. These include the development of new rice varieties with high yield potential, improvement of resistances to major diseases and insects, and to major abiotic stresses such as drought and heat, and the establishment of integrated crop management. We believe that a sustainable increase in rice production is achievable in China with the development of new technology through rice research.

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Section: Research Strategies For Increasing Rice Production In China mentioning

confidence: 99%

Section: Research Strategies For Increasing Rice Production In China mentioning

confidence: 99%

Current Status and Challenges of Rice Production in China

Peng

Tang

Zou

2009

Plant Production Science

603

310

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“…The N-economy of a crop is the result of many processes occurring in the soil, crop and atmosphere and can be quantified by a wide variety of parameters (Peng and Bouman 2007;Spiertz and Vos 2005). In this study, we determined N-uptake in relation to DMyield, physiological N use efficiency, and N-dilution in biomass over time.…”

Section: Introductionmentioning

confidence: 99%

Nitrogen economy in relay intercropping systems of wheat and cotton

et al. 2007

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“…Surprisingly, the variation in parameter values for nitrogenuse efficiencies does not differ much between low-and highinput systems. Genetic improvements of rice are most effective in enhancing physiological N-use efficiencies (Peng and Bouman, 2007), while applying best management practices can raise apparent N recoveries (Campbell et al, 1995;Cassman et al, 1993) It is concluded that N supply should match N demand in time and space -not only for single crops, but for a crop rotation as an integrated system -to achieve a higher agronomic NUE. Alleviating factors that limit growth -such as drought, flooding, pests and diseases -will be most effective in increasing the apparent N recovery.…”

Section: Synchronization Of N Demand and N Supplymentioning

confidence: 99%

“…-improved resource use; a better timing of nitrogen and water supply by time-and site-specific management can avoid stress at critical growth stages. More productivity per unit of water will lead to increased yields and thus higher NUE (Peng and Bouman, 2007). -improved cropping systems; farmers can vary the timing of sowing/planting and the choice of crops in a cropping sequence to make a better match of the genetic make-up of a crop and the growing conditions determined by climate, soil and pests (Hobbs et al, 2008;Ladha et al, 2005).…”

Section: Nitrogen Use Crop Growth and Yieldmentioning

confidence: 99%

Nitrogen, sustainable agriculture and food security. A review

Spiertz

2010

Agron. Sustain. Dev.

280

148

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-The impact of modern agriculture on natural resources has become a major global concern. Population growth and expanding demand for agricultural products constantly increase the pressure on land and water resources. A major point of concern for many intensively managed agricultural systems with high external inputs is the low resource-use efficiency, especially for nitrogen. A high input combined with a low efficiency ultimately results in environmental problems such as soil degradation, eutrophication, pollution of groundwater, and emission of ammonia and greenhouse gases. Evidently, there is a need for a transition of current agricultural systems into highly resource-use efficient systems that are profitable, but at the same time ecologically safe and socially acceptable. Here, opportunities to improve nitrogenuse efficiency in cropping and farming systems are analyzed and discussed. In the past and present, increased productivity of the major plant production systems has been derived from genetic improvement, and from greater use of external inputs such as energy, fertilizers, pesticides and irrigation water. Aiming at improving resource-use efficiencies, in high-input systems the focus should be on more yield with less fertilizer N. In low-input systems additional use of N fertilizer may be required to increase yield level and yield stability. Developing production systems that meet the goals of sustainable agriculture requires research on different scales, from single crops to diverse cropping and farming systems. It is concluded that N supply should match N demand in time and space, not only for single crops but for a crop rotation as an integrated system, in order to achieve a higher agronomic N-use efficiency. A combination of quantitative systems research, development of best practices and legislation will be needed to develop more environmentally-friendly agricultural systems. The growing complexity of managing N in sustainable agricultural systems calls for problem-oriented, interdisciplinary research. productivity / nitrogen-use efficiency / cropping systems / biodiversity / land use / environment

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Prospects for Genetic Improvement to Increase Lowland Rice Yields with Less Water and Nitrogen

Cited by 28 publications

References 47 publications

Current Status and Challenges of Rice Production in China

Current Status and Challenges of Rice Production in China

Nitrogen economy in relay intercropping systems of wheat and cotton

Nitrogen, sustainable agriculture and food security. A review

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