Can exploiting natural genetic variation in leaf photosynthesis contribute to increasing rice productivity? A simulation analysis

Rice productivity can be limited by available photosynthetic assimilates from leaves. However, the lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. Engineering for improved leaf photosynthesis has been argued to yield little increase in crop pr...

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Published inPlant, cell and environment Vol. 37; no. 1; pp. 22 - 34
Main Authors GU, JUNFEI, YIN, XINYOU, STOMPH, TJEERD‐JAN, STRUIK, PAUL C.
Format Journal Article
LanguageEnglish
Published Oxford Blackwell 01.01.2014
Wiley Subscription Services, Inc
Subjects
Biological and medical sciences
Biomass
Biotechnology
canopy photosynthesis
co2 assimilation
Computer Simulation
critical-appraisal
crop model
Crop production
Crop yield
crop yields
Fundamental and applied biological sciences. Psychology
GECROS
Gene mapping
Genetic diversity
Genetic Variation
Genotype
introgression lines
leaves
Light
Models, Biological
Oryza - genetics
Oryza - growth & development
Oryza - physiology
Oryza sativa
Oryza sativa L
Photosynthesis
Photosynthesis - genetics
physiological traits
Plant Leaves - genetics
Plant Leaves - growth & development
Plant Leaves - physiology
plant-growth
Quantitative Trait Loci
Rice
rubisco
Simulation analysis
Productivity
Monocotyledones
Genetic variability
GECROS
Plant ecology
Oryza sativa L
Plant leaf
Natural
Modeling
canopy photosynthesis
Cereal crop
Oryza sativa
crop model
Simulation
Gramineae
Analysis
Angiospermae
Spermatophyta
Cultivated plant
Photosynthesis
Canopy(vegetation)
Oryza sativa L
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Abstract Rice productivity can be limited by available photosynthetic assimilates from leaves. However, the lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. Engineering for improved leaf photosynthesis has been argued to yield little increase in crop productivity because of complicated constraints and feedback mechanisms when moving up from leaf to crop level. Here we examined the extent to which natural genetic variation in A can contribute to increasing rice productivity. Using the mechanistic model GECROS, we analysed the impact of genetic variation in A on crop biomass production, based on the quantitative trait loci for various photosynthetic components within a rice introgression line population. We showed that genetic variation in A of 25% can be scaled up equally to crop level, resulting in an increase in biomass of 22–29% across different locations and years. This was probably because the genetic variation in A resulted not only from Rubisco (ribulose 1,5‐bisphosphate carboxylase/oxygenase)‐limited photosynthesis but also from electron transport‐limited photosynthesis; as a result, photosynthetic rates could be improved for both light‐saturated and light‐limited leaves in the canopy. Rice productivity could be significantly improved by mining the natural variation in existing germ‐plasm, especially the variation in parameters determining light‐limited photosynthesis. The lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. We examined the extent to which natural genetic variation in A can contribute to increasing rice productivity, using the mechanistic crop model GECROS. We showed that genetic variation in A of 25% can result in 22‐29% increase in biomass across different locations and years. Rice productivity could be improved by mining the natural variation in existing germplasm, especially the variation in parameters that determine light‐limited photosynthesis. Commentary: We need winners in the race to increase photosynthesis in rice, whether from conventional breeding, biotechnology, or both.
AbstractList Rice productivity can be limited by available photosynthetic assimilates from leaves. However, the lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. Engineering for improved leaf photosynthesis has been argued to yield little increase in crop productivity because of complicated constraints and feedback mechanisms when moving up from leaf to crop level. Here we examined the extent to which natural genetic variation in A can contribute to increasing rice productivity. Using the mechanistic model GECROS, we analysed the impact of genetic variation in A on crop biomass production, based on the quantitative trait loci for various photosynthetic components within a rice introgression line population. We showed that genetic variation in A of 25% can be scaled up equally to crop level, resulting in an increase in biomass of 22-29% across different locations and years. This was probably because the genetic variation in A resulted not only from Rubisco (ribulose 1,5-bisphosphate carboxylase/oxygenase)-limited photosynthesis but also from electron transport-limited photosynthesis; as a result, photosynthetic rates could be improved for both light-saturated and light-limited leaves in the canopy. Rice productivity could be significantly improved by mining the natural variation in existing germ-plasm, especially the variation in parameters determining light-limited photosynthesis. The lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. We examined the extent to which natural genetic variation in A can contribute to increasing rice productivity, using the mechanistic crop model GECROS. We showed that genetic variation in A of 25% can result in 22-29% increase in biomass across different locations and years. Rice productivity could be improved by mining the natural variation in existing germplasm, especially the variation in parameters that determine light-limited photosynthesis. Commentary: We need winners in the race to increase photosynthesis in rice, whether from conventional breeding, biotechnology, or both.
Rice productivity can be limited by available photosynthetic assimilates from leaves. However, the lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. Engineering for improved leaf photosynthesis has been argued to yield little increase in crop productivity because of complicated constraints and feedback mechanisms when moving up from leaf to crop level. Here we examined the extent to which natural genetic variation in A can contribute to increasing rice productivity. Using the mechanistic model GECROS, we analysed the impact of genetic variation in A on crop biomass production, based on the quantitative trait loci for various photosynthetic components within a rice introgression line population. We showed that genetic variation in A of 25% can be scaled up equally to crop level, resulting in an increase in biomass of 22–29% across different locations and years. This was probably because the genetic variation in A resulted not only from Rubisco (ribulose 1,5‐bisphosphate carboxylase/oxygenase)‐limited photosynthesis but also from electron transport‐limited photosynthesis; as a result, photosynthetic rates could be improved for both light‐saturated and light‐limited leaves in the canopy. Rice productivity could be significantly improved by mining the natural variation in existing germ‐plasm, especially the variation in parameters determining light‐limited photosynthesis. The lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. We examined the extent to which natural genetic variation in A can contribute to increasing rice productivity, using the mechanistic crop model GECROS. We showed that genetic variation in A of 25% can result in 22‐29% increase in biomass across different locations and years. Rice productivity could be improved by mining the natural variation in existing germplasm, especially the variation in parameters that determine light‐limited photosynthesis. Commentary: We need winners in the race to increase photosynthesis in rice, whether from conventional breeding, biotechnology, or both.
Rice productivity can be limited by available photosynthetic assimilates from leaves. However, the lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. Engineering for improved leaf photosynthesis has been argued to yield little increase in crop productivity because of complicated constraints and feedback mechanisms when moving up from leaf to crop level. Here we examined the extent to which natural genetic variation in A can contribute to increasing rice productivity. Using the mechanistic model GECROS, we analysed the impact of genetic variation in A on crop biomass production, based on the quantitative trait loci for various photosynthetic components within a rice introgression line population. We showed that genetic variation in A of 25% can be scaled up equally to crop level, resulting in an increase in biomass of 22-29% across different locations and years. This was probably because the genetic variation in A resulted not only from Rubisco (ribulose 1,5-bisphosphate carboxylase/oxygenase)-limited photosynthesis but also from electron transport-limited photosynthesis; as a result, photosynthetic rates could be improved for both light-saturated and light-limited leaves in the canopy. Rice productivity could be significantly improved by mining the natural variation in existing germ-plasm, especially the variation in parameters determining light-limited photosynthesis.Rice productivity can be limited by available photosynthetic assimilates from leaves. However, the lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. Engineering for improved leaf photosynthesis has been argued to yield little increase in crop productivity because of complicated constraints and feedback mechanisms when moving up from leaf to crop level. Here we examined the extent to which natural genetic variation in A can contribute to increasing rice productivity. Using the mechanistic model GECROS, we analysed the impact of genetic variation in A on crop biomass production, based on the quantitative trait loci for various photosynthetic components within a rice introgression line population. We showed that genetic variation in A of 25% can be scaled up equally to crop level, resulting in an increase in biomass of 22-29% across different locations and years. This was probably because the genetic variation in A resulted not only from Rubisco (ribulose 1,5-bisphosphate carboxylase/oxygenase)-limited photosynthesis but also from electron transport-limited photosynthesis; as a result, photosynthetic rates could be improved for both light-saturated and light-limited leaves in the canopy. Rice productivity could be significantly improved by mining the natural variation in existing germ-plasm, especially the variation in parameters determining light-limited photosynthesis.
Rice productivity can be limited by available photosynthetic assimilates from leaves. However, the lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. Engineering for improved leaf photosynthesis has been argued to yield little increase in crop productivity because of complicated constraints and feedback mechanisms when moving up from leaf to crop level. Here we examined the extent to which natural genetic variation in A can contribute to increasing rice productivity. Using the mechanistic model GECROS, we analysed the impact of genetic variation in A on crop biomass production, based on the quantitative trait loci for various photosynthetic components within a rice introgression line population. We showed that genetic variation in A of 25% can be scaled up equally to crop level, resulting in an increase in biomass of 22-29% across different locations and years. This was probably because the genetic variation in A resulted not only from Rubisco (ribulose 1,5-bisphosphate carboxylase/oxygenase)-limited photosynthesis but also from electron transport-limited photosynthesis; as a result, photosynthetic rates could be improved for both light-saturated and light-limited leaves in the canopy. Rice productivity could be significantly improved by mining the natural variation in existing germ-plasm, especially the variation in parameters determining light-limited photosynthesis. The lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. We examined the extent to which natural genetic variation in A can contribute to increasing rice productivity, using the mechanistic crop model GECROS. We showed that genetic variation in A of 25% can result in 22-29% increase in biomass across different locations and years. Rice productivity could be improved by mining the natural variation in existing germplasm, especially the variation in parameters that determine light-limited photosynthesis. Commentary: We need winners in the race to increase photosynthesis in rice, whether from conventional breeding, biotechnology, or both. [PUBLICATION ABSTRACT]
Rice productivity can be limited by available photosynthetic assimilates from leaves. However, the lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. Engineering for improved leaf photosynthesis has been argued to yield little increase in crop productivity because of complicated constraints and feedback mechanisms when moving up from leaf to crop level. Here we examined the extent to which natural genetic variation in A can contribute to increasing rice productivity. Using the mechanistic model GECROS, we analysed the impact of genetic variation in A on crop biomass production, based on the quantitative trait loci for various photosynthetic components within a rice introgression line population. We showed that genetic variation in A of 25% can be scaled up equally to crop level, resulting in an increase in biomass of 22-29% across different locations and years. This was probably because the genetic variation in A resulted not only from Rubisco (ribulose 1,5-bisphosphate carboxylase/oxygenase)-limited photosynthesis but also from electron transport-limited photosynthesis; as a result, photosynthetic rates could be improved for both light-saturated and light-limited leaves in the canopy. Rice productivity could be significantly improved by mining the natural variation in existing germ-plasm, especially the variation in parameters determining light-limited photosynthesis.
Rice productivity can be limited by available photosynthetic assimilates from leaves. However, the lack of significant correlation between crop yield and leaf photosynthetic rate (A) is noted frequently. Engineering for improved leaf photosynthesis has been argued to yield little increase in crop productivity because of complicated constraints and feedback mechanisms whenmoving up from leaf to crop level.Herewe examined the extent to which natural genetic variation in A can contribute to increasing rice productivity. Using the mechanistic model GECROS,we analysed the impact of genetic variation inAon crop biomass production, based on the quantitative trait loci for various photosynthetic components within a rice introgression line population.We showed that genetic variation in A of 25% can be scaled up equally to crop level, resulting in an increase in biomass of 22–29% across different locations and years. This was probably because the genetic variation in A resulted not only from Rubisco (ribulose 1,5-bisphosphate carboxylase/oxygenase)-limited photosynthesis but also from electron transport-limited photosynthesis; as a result, photosynthetic rates could be improved for both light-saturated and light-limited leaves in the canopy. Rice productivity could be significantly improved by mining the natural variation in existing germ-plasm, especially the variation in parameters determining light-limited photosynthesis.
Rice productivity can be limited by available photosynthetic assimilates from leaves. However, the lack of significant correlation between crop yield and leaf photosynthetic rate ( A ) is noted frequently. Engineering for improved leaf photosynthesis has been argued to yield little increase in crop productivity because of complicated constraints and feedback mechanisms when moving up from leaf to crop level. Here we examined the extent to which natural genetic variation in A can contribute to increasing rice productivity. Using the mechanistic model GECROS , we analysed the impact of genetic variation in A on crop biomass production, based on the quantitative trait loci for various photosynthetic components within a rice introgression line population. We showed that genetic variation in A of 25% can be scaled up equally to crop level, resulting in an increase in biomass of 22–29% across different locations and years. This was probably because the genetic variation in A resulted not only from R ubisco (ribulose 1,5‐bisphosphate carboxylase/oxygenase)‐limited photosynthesis but also from electron transport‐limited photosynthesis; as a result, photosynthetic rates could be improved for both light‐saturated and light‐limited leaves in the canopy. Rice productivity could be significantly improved by mining the natural variation in existing germ‐plasm, especially the variation in parameters determining light‐limited photosynthesis. The lack of significant correlation between crop yield and leaf photosynthetic rate ( A ) is noted frequently. We examined the extent to which natural genetic variation in A can contribute to increasing rice productivity, using the mechanistic crop model GECROS. We showed that genetic variation in A of 25% can result in 22‐29% increase in biomass across different locations and years. Rice productivity could be improved by mining the natural variation in existing germplasm, especially the variation in parameters that determine light‐limited photosynthesis. Commentary: We need winners in the race to increase photosynthesis in rice, whether from conventional breeding, biotechnology, or both.
Author YIN, XINYOU
STOMPH, TJEERD‐JAN
GU, JUNFEI
STRUIK, PAUL C.
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  fullname: GU, JUNFEI
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  givenname: XINYOU
  surname: YIN
  fullname: YIN, XINYOU
  organization: Wageningen University
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  givenname: TJEERD‐JAN
  surname: STOMPH
  fullname: STOMPH, TJEERD‐JAN
  organization: Wageningen University
– sequence: 4
  givenname: PAUL C.
  surname: STRUIK
  fullname: STRUIK, PAUL C.
  organization: Wageningen University
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Issue 1
Keywords Productivity
Monocotyledones
Genetic variability
GECROS
Plant ecology
Oryza sativa L
Plant leaf
Natural
Modeling
canopy photosynthesis
Cereal crop
Oryza sativa
crop model
Simulation
Gramineae
Analysis
Angiospermae
Spermatophyta
Cultivated plant
Photosynthesis
Canopy(vegetation)
Oryza sativa L
Language English
License http://onlinelibrary.wiley.com/termsAndConditions#vor
CC BY 4.0
2013 John Wiley & Sons Ltd.
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References 2004; 86
1976; 40
2004a; 27
2010; 13
1997; 20
2002; 130
2000; 44
2011; 62
1995; 77
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2012a; 63
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2008; 108
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2005
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1995; 18
2006; 171
2009; 118
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1980; 149
2010; 42
2009; 57
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2004; 135
2005; 165
1999; 39
1988; 26
1970; 23
2001; 19
2006; 29
2011; 23
1998; 91
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2004b; 55
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e_1_2_6_32_1
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e_1_2_6_34_1
e_1_2_6_17_1
Day W. (e_1_2_6_10_1) 1988; 26
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24004407 - Plant Cell Environ. 2014 Jan;37(1):19-21
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Snippet Rice productivity can be limited by available photosynthetic assimilates from leaves. However, the lack of significant correlation between crop yield and leaf...
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SubjectTerms Biological and medical sciences
Biomass
Biotechnology
canopy photosynthesis
co2 assimilation
Computer Simulation
critical-appraisal
crop model
Crop production
Crop yield
crop yields
Fundamental and applied biological sciences. Psychology
GECROS
Gene mapping
Genetic diversity
Genetic Variation
Genotype
introgression lines
leaves
Light
Models, Biological
Oryza - genetics
Oryza - growth & development
Oryza - physiology
Oryza sativa
Oryza sativa L
Photosynthesis
Photosynthesis - genetics
physiological traits
Plant Leaves - genetics
Plant Leaves - growth & development
Plant Leaves - physiology
plant-growth
Quantitative Trait Loci
Rice
rubisco
Simulation analysis
Title Can exploiting natural genetic variation in leaf photosynthesis contribute to increasing rice productivity? A simulation analysis
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fpce.12173
https://www.ncbi.nlm.nih.gov/pubmed/23937619
https://www.proquest.com/docview/1462885178
https://www.proquest.com/docview/1465178913
https://www.proquest.com/docview/1534839950
http://www.narcis.nl/publication/RecordID/oai:library.wur.nl:wurpubs%2F445446
Volume 37
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