(Advances in agronomy 116) donald l sparks (eds ) advances in agronomy 116 academic press, elsevier (2012)

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(Advances in agronomy 116) donald l  sparks (eds ) advances in agronomy  116 academic press,  elsevier (2012)

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ADVANCES IN AGRONOMY Advisory Board PAUL M BERTSCH RONALD L PHILLIPS University of Kentucky University of Minnesota KATE M SCOW LARRY P WILDING University of California, Davis Texas A&M University Emeritus Advisory Board Members JOHN S BOYER KENNETH J FREY University of Delaware Iowa State University EUGENE J KAMPRATH MARTIN ALEXANDER North Carolina State University Cornell University Prepared in cooperation with the American Society of Agronomy, Crop Science Society of America, and Soil Science Society of America Book and Multimedia Publishing Committee DAVID D BALTENSPERGER, CHAIR LISA K AL-AMOODI CRAIG A ROBERTS WARREN A DICK MARY C SAVIN HARI B KRISHNAN APRIL L ULERY SALLY D LOGSDON Academic Press is an imprint of Elsevier 525 B Street, Suite 1900, San Diego, CA 92101-4495, USA 225 Wyman Street, Waltham, MA 02451, USA 32 Jamestown Road, London, NW1 7BY, UK Radarweg 29, PO Box 211, 1000 AE Amsterdam, The Netherlands First edition 2012 Copyright # 2012 Elsevier Inc All rights reserved No part of this publication may be reproduced, stored in a retrieval system or transmitted in any form or by any means electronic, mechanical, photocopying, recording or otherwise without the prior written permission of the publisher Permissions may be sought directly from Elsevier’s Science & Technology Rights Department in Oxford, UK: phone (+44) (0) 1865 843830; fax (+44) (0) 1865 853333; email: permissions@elsevier.com Alternatively you can submit your request online by visiting the Elsevier web site at http://elsevier.com/locate/permissions, and selecting Obtaining permission to use Elsevier material Notice No responsibility is assumed by the publisher for any injury and/or damage to persons or property as a matter of products liability, negligence or otherwise, or from any use or operation of any methods, products, instructions or ideas contained in the material herein Because of rapid advances in the medical sciences, in particular, independent verification of diagnoses and drug dosages should be made ISBN: 978-0-12-394277-7 ISSN: 0065-2113 (series) For information on all Academic Press publications visit our website at elsevierdirect.com Printed and bound in USA 12 13 14 15 10 CONTRIBUTORS Numbers in Parentheses indicate the pages on which the authors’ contributions begin K J Boote (41) Agronomy Department, University of Florida, Gainesville, Florida, USA Jean-Pierre Caliman (71) PT SMART Research Institute (SMARTRI), Pekanbaru, Riau, Indonesia Qing Chen (1) Department of Plant Nutrition, China Agricultural University, Beijing, PR China Xinping Chen (1) Department of Plant Nutrition, China Agricultural University, Beijing, PR China Franc¸ois Colin (71) Montpellier-SupAgro, UMR-LISAH (Laboratory on Interactions between Soil, Agrosystem and Hydrosystem), Montpellier cedex, France Irina Comte (71) Department of Natural Resource Sciences, Macdonald Campus of McGill University, Ste-Anne-de-Bellevue, Quebec, Canada, and CIRAD (International Cooperation Centre in Agronomic Research for Development), Montpellier cedex, France Zhenling Cui (1) Department of Plant Nutrition, China Agricultural University, Beijing, PR China Mingsheng Fan (1) Department of Plant Nutrition, China Agricultural University, Beijing, PR China Steven J Fonte (123) International Center for Tropical Agriculture (CIAT), Cali, Colombia ¨nberger (71) Olivier Gru IRD (Institut de Recherche pour le De´veloppement), UMR-LISAH, Montpellier cedex, France Rongfeng Jiang (1) Department of Plant Nutrition, China Agricultural University, Beijing, PR China Xiaotang Ju (1) Department of Plant Nutrition, China Agricultural University, Beijing, PR China ix x Contributors Uttam Kumar (41) International Crops Research Institute for the Semi-Arid Tropics (ICRISAT), Patancheru, Andhra Pradesh, India Patrick Lavelle (125) International Center for Tropical Agriculture (CIAT), Cali, Colombia, and Institut de Recherche sur le De´veloppement (IRD)/Universite´ Pierre et Marie Curie (UPMC), Paris, France Xin Li (219) Department of Agronomy, Kansas State University, Manhattan, Kansas, USA Xuejun Liu (1) Department of Plant Nutrition, China Agricultural University, Beijing, PR China Guohua Mi (1) Department of Plant Nutrition, China Agricultural University, Beijing, PR China Pedro Oyarzun (125) EkoRural, Quito, Ecuador Soroush Parsa (125) International Center for Tropical Agriculture (CIAT), Cali, Colombia D Carolina Quintero (125) International Center for Tropical Agriculture (CIAT), Cali, Colombia Idupulapati M Rao (125) International Center for Tropical Agriculture (CIAT), Cali, Colombia Terry J Rose (185) Southern Cross Plant Science, Southern Cross University, Lismore, NSW, Australia Jianbo Shen (1) Department of Plant Nutrition, China Agricultural University, Beijing, PR China Piara Singh (41) International Crops Research Institute for the Semi-Arid Tropics (ICRISAT), Patancheru, Andhra Pradesh, India Steven J Vanek (125) Department of Crop and Soil Science, Cornell University, Ithaca, New York, USA Jiankang Wang (219) Institute of Crop Science and CIMMYT China, Chinese Academy of Agricultural Sciences, Beijing, China Contributors xi Joann K Whalen (71) Department of Natural Resource Sciences, Macdonald Campus of McGill University, Ste-Anne-de-Bellevue, Quebec, Canada Matthias Wissuwa (185) Japan International Research Center for Agricultural Sciences (JIRCAS), Crop Production and Environment Division, Ohwashi, Tsukuba, Ibaraki, Japan Jianming Yu (219) Department of Agronomy, Kansas State University, Manhattan, Kansas, USA Fusuo Zhang (1) Department of Plant Nutrition, China Agricultural University, Beijing, PR China Weifeng Zhang (1) Department of Plant Nutrition, China Agricultural University, Beijing, PR China Chengsong Zhu (217) Department of Agronomy, Kansas State University, Manhattan, Kansas, USA PREFACE Volume 116 contains six excellent reviews dealing with environmental sustainability and food security Chapter is an enlightening review on an integrated nutrient management (INM) approach, developed on more than 20 years of research, to address serious environmental quality challenges, related to excess use of nutrients, in China The INM approach has led to increased nutrient use efficiency and decreased inputs of fertilizers Chapter deals with the effect of climate change factors on crop growth, development, and yield of groundnut Chapter is a comprehensive review on practices used in oil palm plantations and impacts on hydrological changes, nutrient fluxes, and water quality in Indonesia Chapter is an enlightening overview of soil fertility decline in the high Andes of Bolivia, Ecuador, and Peru Approaches are presented to enhance nutrient cycling, crop nutrient uptake, and overall increased productivity Chapter addresses an important global factor affecting future food security, phosphorus utilization efficiency (PUE) by plants The review focuses on grain crops and covers past attempts to improve PUE via plant breeding, and new approaches for improving PUE Chapter is a stimulating review on the importance of computer simulation in plant breeding I am grateful to the authors for their outstanding reviews DONALD L SPARKS Newark, Delaware, USA xiii C H A P T E R O N E Integrated Nutrient Management for Food Security and Environmental Quality in China Fusuo Zhang, Zhenling Cui, Xinping Chen, Xiaotang Ju, Jianbo Shen, Qing Chen, Xuejun Liu, Weifeng Zhang, Guohua Mi, Mingsheng Fan, and Rongfeng Jiang Contents Introduction Principles of INM 2.1 Optimizing nutrient inputs and taking all possible sources of nutrients into consideration 2.2 Dynamically matching soil nutrient supply with crop requirement spatially and temporally 2.3 Effectively reducing N losses in intensive managed Chinese cropping systems 2.4 Taking all possible yield increase measures into consideration Technology and Demonstration of INM in Different Cropping Systems 3.1 INM for intensive wheat and maize system 3.2 INM for paddy rice 3.3 INM for vegetable systems 3.4 INM for orchards Large-Scale Dissemination of INM Summary and Conclusions Acknowledgments References 11 12 15 16 18 21 23 26 29 31 32 32 Abstract While the concept of sustainability as a goal has become widely accepted, the dominant agricultural paradigm still considers high yield and reduced environmental impact being in conflict with one another During the past 49years (1961–2009), the 3.4-fold increase in Chinese agricultural food production can Department of Plant Nutrition, China Agricultural University, Beijing, PR China Advances in Agronomy, Volume 116 ISSN 0065-2113, DOI: 10.1016/B978-0-12-394277-7.00001-4 # 2012 Elsevier Inc All rights reserved Fusuo Zhang et al be partly attributed to a 37-fold increase in N fertilization and a 91-fold increase in P fertilization, but the environment costs have been very high New advances for sustainability of agriculture and ecosystem services will be needed during the coming 50years to improve nutrient use efficiency (NUE) while increasing crop productivity and reducing environmental risk Here, we advocate and develop integrated nutrient management (INM) based on more than 20years of studies In this INM approach, the key components comprise (1) optimizing nutrient inputs by taking all possible nutrient sources into consideration, (2) matching nutrient supply in root zone with crop requirements spatially and temporally, (3) reducing N losses in intensively managed cropping systems, and (4) taking all possible yield-increasing measures into consideration Recent large-scale application of INM for cereal, vegetable, and fruit cropping systems has shed light on how INM can lead to significantly improved NUE, while increasing crop yields and reducing environmental risk The INM has already influenced Chinese agricultural policy and national actions, and resulted in increasing food production with decreased climb of chemical fertilizer consumption at a national scale over recent years The INM can thus be considered an effective agricultural paradigm to ensure food security and improve environmental quality worldwide, especially in countries with rapidly developing economies Abbreviations AEN FNP INM NCP NUE ONR PFPN REN agronomy N efficiency farming practice integrated nutrient management North China Plain nutrient use efficiency optimum N fertilizer rate nitrogen partial factor productivity recovery N efficiency Introduction The Green Revolution helped to create the world’s “Miracle in China,” with 9% of the world’s arable land feeding 22% of the world population In the past 49years (1961–2009), cereal grain yields have increased 3.5-fold from 1.2 to 5.4thaÀ1, while total grain production has increased 3.4-fold from 110 to 483 million ton (MT) (FAO, 2011) In 1998, grain, meat, and egg production per capita in China exceeded the world average The increased demand in Chinese grain production has affected the global food supply and the natural Nutrient Management in China resource bases required for nutrient production (fossil fuels, mineral sources of P and K) and has attained world recognition However, this 3.4-fold increase in Chinese agricultural food production during the past 49years can be partly attributed to a 48-fold increase in chemical fertilizers from to 49MT, including a 37-fold increase in N fertilizer application and a 91-fold increase in P fertilizer use, and a 442-fold increase in the area of irrigated croplands (Fig 1) Total consumption of chemical fertilizers worldwide increased by 3.9-fold from 32 to 164MT, indicating that 36% of the global increase ($132MT) came from China during the past 49years In the past 10years (2000–2009), 54% of the global increase in chemical fertilizer consumption ($27MT) was contributed by China, including 11MT fertilizer N (54% of the global increase), 2.5 MT fertilizer P (52% of the global increase), and 1.1MT fertilizer K (58% of the global increase) (Figs and 2A,B) Cereal yields in the past 10years have continued to increase with no proportional increases in fertilizer use in many developed countries or regions such as Western Europe (rainfed cereal systems), North America (rainfed and irrigated corn), and Japan and South Korea (irrigated rice) (Dobermann and Cassman, 2005) For example, in the past 10years, chemical fertilizer consumption in the United States increased by only 0.04MT with 0.23% of total fertilizer consumption in 2009 and decreased by 0.32 MT in Western Europe (Fig 2A) By contrast, the application rate of 600 400 60 300 40 200 20 100 1960 1970 1980 1990 2000 Fertilizer consumption (MT) Grain production (MT) 500 80 Grain production Total fertilizer N fertilizer P fertilizer K fertilizer 2010 Year Figure The trend of grain production and chemical fertilizer inputs (N, P, and K fertilizers) in China from 1961 to 2009 The P and K fertilizers are calculated by P2O5 and K2O, respectively Fertilizer consumption is defined as the difference between fertilizer production and exports Source: FAO (2011) and IFA (2011) Fusuo Zhang et al 200 80 Global fertilizer (MT) 160 60 120 40 80 20 40 1960 1970 1980 1990 Year 1970 1980 1990 Year 2000 Regional fertilizer (MT) A 2010 600 B -1 Fertilizer rate (kg ) 500 400 300 200 100 1960 2000 2010 Global fertilizer China United States Western Europe Figure Trend of total chemical fertilizer consumption (A) and fertilizer rate per hectare (B) for global scale, China, United States, and Western European Source: IFA (2011) chemical fertilizers in China was continually increasing and reached 448kg haÀ1 in 2009, which is 2.8, 2.9, and 1.4 times the world average and rates in the United States and Western Europe, respectively (Fig 2B) On the other hand, Chinese cereal crop production has stagnated at approximately 450MT since 1998 From 1998 to 2009, grain yields increased 255 Computer Simulation in Plant Breeding Table A list of software commonly used in computer simulation in plant breeding Name Utility References APSIM Crop modeling McCown et al http://www.apsim info/Wiki/ (1996), Keating et al (2003) Frisch et al (2000) Maurer et al http://www.r-project (2008) org/ http://www.uq.edu Podlich and au/lcafs/qugene/ Cooper (1998) PLABSIM Marker-assisted backcrossing PLABSOFT Plant breeding QU-GENE Genotype-byenvironment interaction and plant breeding E-CELL Whole-cell simulation Tomita et al (1999) Online access http://www.e-cell org/ecell/ Commonly used variables for different runs include the number of QTLs and markers, QTL position on the genetic map, genome size, the effect of each QTL, population size, heritability, degree of epistasis, and environment types After meeting the computational challenge, researchers must analyze and interpret computer output As with statistical software, computer simulation gives us only the numbers, but the numbers require interpretation to be meaningful and practical Computer simulation must be coupled with human intelligence to be useful Summary and Perspectives In summary, the main points we presented in this review included: Computer simulation, a bridge between theory and experimentation, has become a powerful tool in scientific research It can be used to conduct pilot or virtual experiments to verify new theories or provide guidelines for empirical experimentation Huge amounts of information have been generated in crop improvement research during the past several decades, especially significant advances in molecular dissecting of complex traits and high-throughput genotyping techniques Computer simulation can transfer these advancements into plant-breeding practice Computer simulation can compare different breeding strategies, incorporating gene information, cross scheme, propagation method, population 256 Xin Li et al size, selection intensity, and number of generations simultaneously; thus, we can use computer simulation to decide which breeding strategy could lead to higher genetic gain Computer simulation can be applied to gene mapping to validate the effectiveness of new mapping methods or assess the factors influencing mapping power (e.g., population type and size, marker number and density, heritability, and number of QTLs) Computer simulation can also help us determine the significance threshold and CI, which otherwise would be difficult to calculate analytically Plant-breeding simulation platforms are potent tools that can simulate the whole plant-breeding process They use genetic and GEI information to, for instance, predict cross performance and compare selection methods, thus enhancing our ability to make decisions about plant breeding Computer simulation can integrate crop physiological models, environmental information, and genetic composition of different crops to fill the gap between genotype and phenotype We can use computer simulation to predict the performance of different cultivars in TPEs and thus facilitate the plant-breeding process When coupled with climate simulation models, crop models can be used to predict the possible influences of climate change on crop production, which can subsequently provide guidelines for plant breeding With the exponential increase in computational power and decrease in the price of that power, computer simulation will become more common, but custom programs tailored for specific purposes will still need to be developed At the beginning of the second decade of the twenty-first century, we are closer than at any other point in history to deciphering various mysteries in life science Huge amounts of information in genetics, genomics, biochemistry, molecular biology, and bioinformatics are now available, but only some of this information has been applied to plant breeding The practical goal of scientific research is more than just explaining the mechanisms underlying life phenomena—it is learning to manipulate those mechanisms to benefit humankind Plant breeders have the challenge of determining how to take advantage of this knowledge to make crop improvement more efficient and enhance genetic gain Research in establishing genotype–phenotype relationship and developing new breeding methods has been proposed to realize the potential brought about by ultrahigh-throughput genomic technologies in plant breeding (Yu, 2009), and computer simulation undoubtedly will be a key part of this process As a tool, computer simulation will aid decision-making and resource allocation through transferring experimental results from laboratory to agricultural production and by predicting the outcome of breeding decisions, directing gene mapping, and tackling GEI and climate change Computer Simulation in Plant Breeding 257 ACKNOWLEDGMENTS This work was supported by the Agriculture and Food Research Initiative Competitive Grant (2011-03587) from the USDA National Institute of Food and Agriculture, the Plant Feedstock Genomics Program (DE-SC0002259) of the U.S Department of Energy, and the Plant Genome Program (DBI-0820610) of the National Science 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Production Systems sIMulator (APSIM), 249–251, 250f Agroecological intensification Andean region, 163–165 plant breeding, 152–157 Alternative glycolytic pathways, PUE, 206 American Palm Oil Council (APOC), 85 Andean soil fertility biological function biochar, 150–151 composts, 151 import substitution, 151–152 inoculation, 144 microbial and faunal communities, 144–145 microbial inoculants, 147 organic matter management, 144 P-solubilizing activity, 149 soil fauna, 152 symbioses, 145–146 biophysical limitations and risks climate, 127–128, 128f soil environment, characterization of, 127–128, 129f challenges and threats, 131–132 crop growth factors, 162 cropping systems, 126–127 ecologically based intensification, 132–133 mass balance erosion, 135–137 fertilizer application, 138–139 nitrogen flow diagram, 133–135, 134f nutrient availability/uptake vs time, 137, 137f nutrient dynamics and synchronization composting, 140–141 fertilizer application, 139 nutrient management strategies, 142 organic resources, 139–140 physiochemical environment aggregation, 142–143 liming, 143–144 pH, 143–144 plant breeding, 152–157 socioeconomic and cultural setting, 129–130 spatial and temporal organization, farms, 157–161 APSIM See Agricultural Production Systems sIMulator (APSIM) Arachis hypogaea L See Groundnut crop Arbuscular mycorrhizae (AM), 145–146 Assess site-specific yield potential (ASYP), 89 Average yields, palm oil production, 92–93, 92t B Barley seed metabolism, 252 Bayesian mapping, 245–246 Best linear unbiased prediction (BLUP), 228, 229 Biochar, 143–144, 150–151 Biological function, soil biochar, 150–151 composts, 151 import substitution, 151–152 inoculation, 144 microbial and faunal communities, 144–145 microbial inoculants, 147 organic matter management, 144 P-solubilizing activity, 149 soil fauna, 152 symbioses, 145–146 Bornean orangutans, 75–76 Breeding methods early selection, 225 genome-wide selection goal of, 235 vs MARS, 235–236, 236f marker-assisted backcross, 231–234 marker-assisted selection influencing factors, 226–228 vs phenotypic selection, 228–230 MARS, 231 MODPED, 225–226 SELBLK, 225–226 SSD, 225 C Cangahua soils, 142–143 Cation exchange capacity (CEC), 143–144 Composite interval mapping (CIM), 243–244 Composting, anerobic methods, 140–141 Computer simulation, plant breeding breeding methods early selection, 225 genome-wide selection, 234–237 265 266 Computer simulation, plant breeding (cont.) marker-assisted backcross, 231–234 marker-assisted selection, 226–230 MARS, 231 MODPED, 225–226 SELBLK, 225–226 SSD, 225 classification of, 222 climate change, 252–254 computation and software issues, 254–255, 255t crop modeling advantages, 248–249 APSIM, 249–251, 250f uses, 248 example, 222 gene mapping association mapping, 243–244 Bayesian mapping, 245–246 confidence interval, 243 joint linkage and linkage disequilibrium mapping, 245 linkage analysis, 243–244 meta-analysis, 240–241 missing markers, 240 population size and marker density, 238–239, 239f significance threshold, 241–242 gene network and genotype-by-environment interaction E(N:K) model, 246–247 QU-GENE, 247 origin of, 221 random number generation, 223f virtual plants and E-cell, 251–252 Critical tissue P concentration, 191 Crop breeding, 155 CROPGRO models, groundnut climatic effects on root growth, 64 pod addition, seed growth, and partitioning intensity, 63–64 reproductive progression, 61–62 vegetative development, 61 vegetative expansion and photosynthesis processes, 62–63 Crop modeling advantages, 248–249 APSIM, 249–251, 250f uses, 248 Cropping system, INM fertilizer rates, 16–17 management strategy, 17 nitrogen efficiency, 16 nutrient resource characteristics, 16, 17t orchards, 26–29 paddy rice, 21–22 vegetable systems, 23–26 wheat and maize, 18–21 Crude palm oil (CPO), 74 Index D Deforestation, 75–76 Deterministic simulation, 222 E E-cell system, 252 Elaeis guineensis cultivation See Oil palm cultivation E(N:K) model, 246–247 Environmental stakes, oil palm cultivation agricultural policies, 80–81 deforestation and loss of biodiversity, 75–76 GHG emissions and carbon storage, 78 peatland degradation, 76–77 water pollution, 79–80 F False discovery rate (FDR), 242 Fertilizer management, oil palm cultivation, 86 Food production, 30–31 Forest clearing, hydrological impacts of, 111, 112f Foster system, 90 G Gene mapping, plant breeding association mapping, 243–244 Bayesian mapping, 245–246 confidence interval, 243 joint linkage and linkage disequilibrium mapping, 245 linkage analysis, 243–244 meta-analysis, 240–241 missing markers, 240 population size and marker density, 238–239, 239f significance threshold, 241–242 General circulation models (GCMs), 253 Grain crop genotypes, PUE, 187, 188t Grain PUE, screening for, 200 Greenhouse gas (GHG) emissions, 78 Groundnut crop canopy expansion and growth processes leaf area and stem elongation, 46–47 leaf senescence, 47 leaf thickness, 45 net assimilation and growth rates, 49–50 photosynthesis, 48–49 stomatal conductance and transpiration, 47–48 CROPGRO models climatic effects on root growth, 64 pod addition, seed growth, and partitioning intensity, 63–64 reproductive progression, 61–62 vegetative development, 61 267 Index vegetative expansion and photosynthesis processes, 62–63 harvest index, 58–59 reproductive development and growth appearance of flowers, pegs, and pods, 50–51 number of pegs, pods, and seeds, 54–55 pod and seed growth rates and their size, 55–56 pollen production and viability and fruit-set, 53–54 rate of flower production, 51–52 root growth, 59–60 root-to-shoot ratio, 60–61 shelling percentage, 59 total dry matter, pod, and seed yield, 56–58 vegetative development germination and emergence processes, 43–44 leaf appearance and leaf number, 44–45 H Harvest index (HI), 189–191 Hydrological processes, oil palm evapotranspiration, 95–96 forest clearing, hydrological impacts of, 111, 112f hydrological cycle, 93, 94f interception, 94–95 leaching and goundwater facility annual rainfall, annual runoff and nutrient losses, 97–98, 99t, 100t plot-scale study, 101–103 soil texture, 98–101, 102t precipitation, 94 qualitative description, 111, 113t soil infiltration deforestation, 96–97 hydraulic conductivities, 96 soil types and locations, 97, 97t stream flow, 108–109 stream water quality, 109–111, 110t surface runoff and soil erosion, 103–108, 104t, 106t, 107t I Import substitution, 151–152 Inclusive composite interval mapping (ICIM), 244 Industrial vs smallholder plantations, oil palm, 82 In silico mapping, 244–245 Integrated nutrient management (INM) chemical fertilizer consumption, 3–4, 4f conceptual model, 6, 6f in cropping system fertilizer rates, 16–17 management strategy, 17 nitrogen efficiency, 16 nutrient resource characteristics, 16, 17t orchards, 26–29 paddy rice, 21–22 vegetable systems, 23–26 wheat and maize, 18–21 fertilizer rate per hectare, 3–4, 4f grain production and chemical fertilizer inputs, 2, 3f large-scale dissemination environmental pollution, 30–31 factors, 29–30 partial factor productivity, 30, 30f principles of crop yields, 15–16 mobilization and acquisition, 6–7 nitrogen fertilization, 7–8 N loss reduction, Chinese cropping systems, 12–15 NO-3, 7–8 nutrient input optimization, 9–11 rhizosphere/root-zone nutrient management, 8, 9f soil nutrient supply matching, 11–12 L Leaf analysis, 89 Least square method, 226–227 LOD drop-off method, 243 Lupinus mutabilis, 145–146, 155–156 M Mapping as you go (MAYG) method, 227–228 Marker-assisted backcross (MABC), 231–234 Marker-assisted recurrent selection (MARS), 231 Marker-assisted selection (MAS) breeding methods influencing factors, 226–228 vs phenotypic selection, 228–230 PUE, 209–210 MARS See Marker-assisted recurrent selection (MARS) Microbial symbioses, 154–155 Mitochondrial electron transport pathways, PUE, 206 Modified pedigree/bulk selection method (MODPED), 225–226 Multiple interval mapping (MIM), 244 Mycorrhizal inoculation, impacts of, 147–149, 148t N Nested association mapping (NAM), 245 Nucleus estate scheme (NES), 82 Nutrient dynamics and synchronization, soil fertility 268 Index Nutrient dynamics and synchronization, soil fertility (cont.) composting, 140–141 fertilizer application, 139 nutrient management strategies, 142 organic resources, 139–140 Nutrient use efficiency (NUE), 15 O Off-the-shelf software, 254 Oil palm cultivation climate and soil conditions, 81–82 environmental stakes agricultural policies, 80–81 deforestation and loss of biodiversity, 75–76 GHG emissions and carbon storage, 78 peatland degradation, 76–77 water pollution, 79–80 expansion of future expansion, 74–75 in Indonesia, 74, 75f palm oil utilization, 74 fertilizer management chemical fertilizer, 90 organic fertilizer, 90–92 hydrological processes evapotranspiration, 95–96 forest clearing, hydrological impacts of, 111, 112f hydrological cycle, 93, 94f interception, 94–95 leaching and goundwater facility, 97–103 precipitation, 94 qualitative description, 111, 113t soil infiltration, 96–97, 97t stream flow, 108–109 stream water quality, 109–111, 110t surface runoff and soil erosion, 103–108, 104t, 106t, 107t land clearing and site preparation, 82–83, 84f nutrient-demand assessment fertilizer management, 86 soil nutrient supply, 86–89, 88t positive and negative aspects, 73 production systems, 82 synthesis, 92–93 water and soil management, 83–85 On-field crop residue retention, 137–138 Orchards basal fertilization, 28 controlling N and P fertilization, 27–28 deficiency, 27 management, 28 misuse of fertilizers, 27 nutrient inputs, 27 P Paddy rice basal and top-dressing, 22 fertilizer N application rate, 21 INM performance, China, 22, 23f soil N supply capacity, 22 Palm kernel oil, 74 Palm oil mill effluent (POME), 79–80 P-deficiency stress response mechanisms, 206–207 Peatland degradation ecological functions, 77 oil palm conversion, 77 peatland formation, 76 PER See Phosphorus-efficiency ratio (PER) Phalaris sp, 136–137 Phosphorus acquisition efficiency (PAE) crop cultivars, 206–207 vs PUE, 208 Phosphorus-efficiency ratio (PER), 189, 195–196 Phosphorus utilization efficiency (PUE) agronomic implications, 189–191 classification, 189 definitions, 189, 190t, 195–196 grain crop genotypes, 187, 188t marker-assisted selection, 209–210 mechanism and physiology alternative glycolytic pathways and mitochondrial electron transport pathways, 206 P-deficiency stress response mechanisms, 206–207 remobilization and scavenging, of P, 205–206 vs PAE, 208 physiological implications reproductive stage, 195 vegetative stage, 192–194, 193t screening grain PUE, 200 vegetative PUE, 197–200 Physiochemical environment, soil aggregation, 142–143 liming, 143–144 pH, 143–144 Plant-growth-promoting microbes (PGPM), 146, 149–150 Plasma, 82 P-LIM-GROW model, 202–204, 203f Potassium fluxes, oil palm plantation, 86–89, 89f Pseudorandom number generator, 254–255 P-stress levels outcomes, PUE, 202–204 P-deficient crops, 201–202 PUE See Phosphorus utilization efficiency (PUE) 269 Index R Remobilization and scavenging, of P, 205–206 Root PUE definition, 192 variation, vegetative crop growth, 193t Roundtable on Sustainable Palm Oil (RSPO), 80 S Screening grain PUE, 200 P-stress levels, 201–204 vegetative PUE P uptake nullification, genotypes, 198–200 shoot PUE vs shoot P content, 197, 198f, 199f Selected bulk selection method (SELBLK), 225–226 Shoot PUE control of, 192 correlation coefficients, 196t vs shoot P content, 198f, 199f variation, vegetative crop growth, 193t Single seed descent (SSD), 225 Soil aggregation, 142–143 Soil degradation, 131 Soil infiltration deforestation, 96–97 hydraulic conductivities, 96 soil types and locations, 97, 97t Spatial and temporal organization, farms, 157–161 SSD See Single seed descent (SSD) Standing stock biomass, in oil palm plantation, 86, 87t Stochastic simulation, 222 Sumatran orangutans, 75–76 T Trichoderma, 145–146 Trifolium spp, 145–146 V Vegetable systems characteristics, 23–24 chili pepper and cucumber yield, 24–25, 24f fertigation techniques, 26 in-season root-zone N management, 25, 25f P management strategy, 26 Vegetative PUE, screening P uptake nullification, genotypes, 198–200 shoot PUE vs shoot P content, 197, 198f, 199f Vermicomposting, 140–141 Virtual plants, 252 W Wacho rozado, 136–137 Water management, oil palm cultivation, 83–85 Wheat and maize system factors, 20–21 grain yields, 18 INM performance, North China Plain, 19–20, 20f model of, in-season root-zone, 18–19, 19f soil N tests, 18–19 ... elementsa a Management strategy Trace elements include boron (B), chlorine (Cl), copper (Cu), iron (Fe), manganese (Mn), molybdenum (Mo), nickel (Ni), and zinc (Zn), respectively In China, maintenance... chlorine (Cl), copper (Cu), iron (Fe), manganese (Mn), molybdenum (Mo), nickel (Ni), and zinc (Zn) is based on their plant availability in both soil and plant Their available contents in soil and... Tropical Agriculture (CIAT), Cali, Colombia D Carolina Quintero (12 5) International Center for Tropical Agriculture (CIAT), Cali, Colombia Idupulapati M Rao (12 5) International Center for Tropical

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  • Series Page

  • Copyright

  • Contributors

  • Preface

  • Integrated Nutrient Management for Food Security and Environmental Quality in China

    • Introduction

    • Principles of INM

      • Optimizing nutrient inputs and taking all possible sources of nutrients into consideration

      • Dynamically matching soil nutrient supply with crop requirement spatially and temporally

      • Effectively reducing N losses in intensive managed Chinese cropping systems

      • Taking all possible yield increase measures into consideration

    • Technology and Demonstration of INM in Different Cropping Systems

      • INM for intensive wheat and maize system

      • INM for paddy rice

      • INM for vegetable systems

      • INM for orchards

    • Large-Scale Dissemination of INM

    • Summary and Conclusions

    • Acknowledgments

    • References

  • Effect of Climate Change Factors on Processes of Crop Growth and Development and Yield of Groundnut Arachis hypogaea L.

    • Abstract

    • Introduction

    • Vegetative Development

      • Germination and emergence

      • Leaf appearance and leaf number

    • Canopy Expansion and Growth Processes

      • Leaf thickness

      • Leaf area and stem elongation

      • Leaf senescence

      • Stomatal conductance and transpiration

      • Photosynthesis

      • Net assimilation and growth rates

    • Reproductive Development and Growth

      • Appearance of flowers, pegs, and pods

      • Rate of flower production

      • Pollen production and viability and fruit-set

      • Number of pegs, pods, and seeds

      • Pod and seed growth rates and their size

    • Total Dry Matter, Pod, and Seed Yield

    • Harvest Index and Shelling Percentage

      • Harvest index

      • Shelling percentage

    • Root Growth and Root-to-Shoot Ratio

      • Root growth

      • Root-to-shoot ratio

    • Synthesis of the Review for Improving the CROPGRO or Other Models for Groundnut

      • Vegetative development

      • Reproductive progression

      • Vegetative expansion and photosynthesis processes

      • Pod addition, seed growth, and partitioning intensity

      • Climatic effects on root growth

    • Concluding Comments

    • Acknowledgments

    • References

  • Agricultural Practices in Oil Palm Plantations and Their Impact on Hydrological Changes, Nutrient Fluxes and Water Quality in Indonesia: A Review

    • Abstract

    • Introduction

    • Expansion of Oil Palm Cultivation in Indonesia and Environmental Stakes

      • Expansion of oil palm cultivation

        • Palm oil utilization

        • Extent of oil palm cultivation in Indonesia: 1911 to present

        • Expected future expansion of oil palm cultivation

      • Environmental stakes

        • Deforestation and loss of biodiversity

        • Peatland degradation

          • Peatland formation

          • Peatland ecological functions

          • Peatland conversion to oil palm

        • GHG emissions and carbon storage

        • Water pollution

        • Agricultural policies

        • Implications for future research

    • Oil Palm Cultivation

      • Climate and soil conditions

      • Production systems: Industrial versus smallholder plantations

      • Land clearing and site preparation

      • Water and soil management

      • Nutrient-demand assessment

      • Fertilizer management

        • Chemical fertilizer

        • Organic fertilizer

      • Synthesis

    • Hydrological Processes and Associated Nutrient Transfers in Oil Palm Plantations

      • Precipitation in Indonesia

      • Interception

      • Evapotranspiration

      • Soil infiltration, leaching, and groundwater quality

        • Soil infiltration

        • Leaching and groundwater quality

      • Surface runoff and erosion

      • Stream flow and stream water quality

        • Stream flow

        • Stream water quality

      • Synthesis

    • Conclusion

    • Acknowledgments

    • References

  • Pathways to Agroecological Intensification of Soil Fertility Management by Smallholder Farmers in the Andean Highlands

    • Abstract

    • Introduction: Agricultural and Soil Fertility Issues in the High Andes

      • Cropping systems of the Andes

      • Biophysical limitations and risks

      • Socioeconomic and cultural setting of Andean agriculture

      • Current challenges and emerging threats

      • Ecologically based intensification in the Andean context

    • Examining Soil Fertility and Management Strategies in Smallholder Systems

      • General concept of soil fertility

      • Approaches to examining soil fertility

        • Mass balance

        • Short-term nutrient dynamics and synchronization

        • Physiochemical environment of soils

        • Biological functioning of soils

        • Plant breeding for agroecological intensification and climate change

        • Spatial and temporal organization of farms

    • Additional Considerations for Soil Fertility Interventions

      • Need to incorporate co-limiting crop growth factors

      • Integrating local needs and knowledge into soil fertility research

    • Conclusions and Recommendations

      • Outlook for agroecological intensification in the Andean context

      • Recommendations for future research and interventions

    • Acknowledgments

    • References

  • Rethinking Internal Phosphorus Utilization Efficiency: A New Approach Is Needed to Improve PUE in Grain Crops

    • Abstract

    • Introduction

    • Defining PUE: Terms, Units, and Assumptions

      • Criteria with agronomic implications

      • Criteria with physiological implications

        • PUE at the vegetative stage

        • PUE at the reproductive stage

      • Defining the utilization of P as "efficiency"

    • Quantifying PUE of Crop Genotypes Using Criteria with Physiological Implications

      • Screening for vegetative PUE

        • Traditional screening systems

        • A modified nutrient solution screening technique to nullify differences in P uptake among genotypes

      • Screening for grain PUE

    • P-Stress Levels in Screening Studies and the Utility of PUE in Low, Medium, and High P Input Systems

      • P-deficient crops suffer a range of stress levels

      • What are the likely outcomes of improved PUE in P-deficient plants?

    • Mechanisms and Physiology of PUE

      • Remobilization and scavenging of P

      • Alternative glycolytic pathways and mitochondrial electron transport pathways

      • Exploiting P-deficiency stress response mechanisms

    • Conclusions and Future Prospective

      • PAE versus PUE-Does one offer better chances of success?

      • Screening methods, targets, and possible results

      • Marker-assisted selection-A paradigm shift in breeding suited for PUE

      • Remaining questions

    • References

  • Computer Simulation in Plant Breeding

    • Abstract

    • Introduction

      • An urgent need in plant breeding

        • Three eras in plant-breeding history

        • A gap between our knowledge and plant-breeding practice

      • Computer simulation

        • Origin of computer simulation

        • Classification of computer simulation

        • An example

      • Joining computer simulation with plant breeding

    • Applying Computer Simulation to Plant Breeding

      • Comparing breeding methods

        • Finding the best breeding scheme

        • Factors influencing marker-assisted selection

        • Phenotypic selection versus marker-assisted selection

        • Marker-assisted recurrent selection

        • Marker-assisted backcross

        • Genome-wide selection

      • Gene mapping

        • Factors influencing mapping efficiency

          • Population size and marker density

          • Missing marker information

          • Meta-analysis

        • Significance threshold and confidence interval

          • Significance threshold

          • Confidence interval of QTL position

        • Brief summary of mapping methods

          • Linkage analysis

          • Association mapping

          • Joint linkage and linkage disequilibrium mapping

          • Bayesian mapping

      • Gene network and genotype-by-environment interaction

        • EN:K model

        • Plant-breeding simulations with QU-GENE

      • Crop physiology and crop modeling

        • Crop modeling

        • Virtual plants and E-cell

        • Climate change

    • Computation and Software Issues

    • Summary and Perspectives

    • Acknowledgments

    • References

  • Index

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