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NJAS: Wageningen Journal of Life Sciences Volume 57, 2009 - Issue 1
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Original Article

Combining ecophysiological models and genomics to decipher the GEM-to-P problem

J.W. WhiteUnited States Arid Land Agricultural Research Center, USDA-ARS, 21881 North Cardon Lane, Maricopa, AZ 85138, USACorrespondence[email protected]
Pages 53-58 | Received 10 Dec 2008, Accepted 17 Aug 2009, Published online: 18 Jun 2021

References

  • M.CooperS.C.ChapmanD.W.PodlichG.L.HammerThe GP problem: quantifying gene-to-phenotype relationshipsIn Silico Biol.22002151164
  • P.N.BenfeyT.Mitchell-OldsFrom genotype to phenotype: systems biology meets natural variationScience3202008495497
  • J.W.WhiteG.HoogenboomGene-based approaches to crop simulation: past experiences and future opportunitiesAgron. J.9520035264
  • J.W.JonesG.HoogenboomC.H.PorterK.J.BooteW.D.BatchelorL.A.HuntP.W.WilkensU.SinghA.J.GijsmanJ.T.RitchieThe DSSAT cropping system modelEur. J. Agron.182003235265
  • G.HoogenboomJ.W.JonesP.W.WilkensC.H.PorterW.D.BatchelorL.A.HuntK.J.BooteU.SinghO.UryasevW.T.BowenA.J.GijsmanA.du ToitJ.W.WhiteG.Y.TsujiDecision Support System for Agrotechnology Transfer Version 4.0 [CD-ROM]2004University of HawaiiHonolulu, HI
  • R.L.McCowanG.L.HammerJ.N.G.HargreavesD.P.HolzworthD.M.FreebairnAPSIM: a novel software system for model development, model testing and simulation in agricultural systems researchAgric. Syst.501996255271
  • G.HoogenboomJ.W.WhiteC.D.MessinaFrom genome to crop: integration through simulation modelingField Crops Res.902004145163
  • J.W.WhiteG.HoogenboomM.OttmanModeling phenology of sorghum based on known maturity (Ma) loci, in Farming Systems DesignProceedings of the International ConferenceCatania, Italy, 10–12 Sept. 2007(2007) 83–85. http://www.iemss.org/farmsys07/uploads/Main/Field_farm_scale_CD.pdf (verified 31 March 2008)
  • J.W.WhiteG.HoogenboomSimulating effects of genes for physiological traits in a process-oriented crop modelAgron. J.881996416422
  • J.BealesA.TurnerS.GriffithsJ.SnapeD.LaurieA pseudo-response regulator is misexpressed in the photoperiod insensitive Ppd-D1a mutant of wheat (Triticum aestivum L.)Theoret. Appl. Genet.1152007721733
  • M.H.EllisW.SpielmeyerK.R.GaleG.J.RebetzkeR.A.RichardsPerfect markers for the Rht-B1b and Rht-D1b dwarfing genes in wheatTheoret. Appl. Genet.105200210381042
  • G.HoogenboomJ.W.WhiteJ.Acosta-GallegosR.GaudielJ.R.MyersM.J.SilbernagelEvaluation of a crop simulation model that incorporates gene actionAgron. J.891997613620
  • D.W.StewartE.R.CoberR.L.BernardModeling genetic effects on the photothermal response of soybean phenological developmentAgron. J.9520036570
  • C.D.MessinaJ.W.JonesK.J.BooteC.E.VallejosA gene-based model to simulate soybean development and yield responses to environmentCrop Sci.462006456466
  • J.W.WhiteM.HerndlL.A.HuntT.S.PayneG.HoogenboomSimulation-based analysis of effects of Vrn and Ppd loci on flowering in wheatCrop Sci.482008678687
  • J.W.WhiteK.J.BooteG.HoogenboomP.G.JonesRegression-based evaluation of ecophysiological modelsAgron. J.992007419427
  • X.YinS.D.ChasalowC.J.DourleijnP.StamM.J.KropffCoupling estimated effects of QTLs for physiological traits to a crop growth model: predicting yield variation among recombinant inbred lines in barleyHeredity852000539549
  • J.ChantereauG.TroucheJ.F.RamiM.DeuC.BarroL.GrivetRFLP mapping of QTLs for photoperiod response in tropical sorghumEuphytica1202001183194
  • M.ReymondB.MullerA.LeonardiA.CharcossetF.TardieuCombining quantitative trait loci analysis and an ecophysiological model to analyze the genetic variability of the responses of maize leaf growth to temperature and water deficitPlant Physiol.1312003664675
  • P.WenzlJ.CarlingD.KudrnaD.JaccoudE.HuttnerA.KleinhofsA.KilianDiversity Arrays Technology (DArT) for whole-genome profiling of barleyProc. Natl. Acad. Sci.101200499159920
  • J.–L.JanninkJ.B.WalshAssociation mapping in plant populationsM.S.KangQuantitative Genetics, Genomics and Plant Breeding2002CABIWallingford5968
  • J.CrossaJ.BurguenoS.DreisigackerM.VargasS.A.Herrera-FoesselM.LillemoR.P.SinghR.TrethowanM.WarburtonJ.FrancoM.ReynoldsJ.CrouchR.OrtizAssociation analysis of historical bread wheat germplasm using additive genetic covariance of relatives and population structureGenetics107200718891913
  • G.HoogenboomJ.W.WhiteImproving physiological assumptions of simulation models by using gene-based approachesAgron. J.9520038289
  • G.L.HammerT.R.SinclairS.C.ChapmanE.Van OosteromOn systems thinking, systems biology, and the in silico plantPlant Physiol.1342004909911
  • X.YinP.C.StruikM.J.KropffRole of crop physiology in predicting gene-to-phenotype relationshipsTrends Plant Sci.92004426432
  • J.W.WhiteFrom genome to wheat: emerging opportunities for modelling wheat growth and developmentEur. J. Agron.2520067988
  • Y.WangJ.LiMolecular basis of plant architectureAnnu. Rev. Plant Biol.592008253279
  • F.TurckF.FornaraG.CouplandRegulation and identity of florigen: flowering locus T moves center stageAnnu. Rev. Plant Biol.592008573594
  • M.E.SalvucciB.P.DeRidderA.R.J.PortisEffect of activase level and isoform on the thermotolerance of photosynthesis in ArabidopsisJ. Exp. Bot.57200637933799
  • E.Baena-GonzalezJ.SheenConvergent energy and stress signalingTrends Plant Sci.132008474482
  • K.MuraiM.MiyamaeH.KatoS.TakumiY.OgiharaWAP1, a wheat APETALA1 homolog, plays a central role in the phase transition from vegetative to reproductive growthPlant Cell Physiol.44200312551265
  • T.ImaizumiS.A.KayPhotoperiodic control of flowering: not only by coincidenceTrends Plant Sci.112006550558
  • J.L.CaddelD.E.WeibelPhotoperiodism in sorghumAgron. J.641972473476
  • G.AlagarswamyD.M.ReddyG.SwaminathanDurations of the photoperiod-sensitive and -insensitive phases of time to panicle initiation in sorghumField Crops Res.551998110
  • S.T.CollinsonR.H.EllisR.J.SummerfieldE.H.RobertsDurations of the photoperiod-sensitive and photoperiod-insensitive phases of development to flowering in four cultivars of rice (Oryza sativa L.)Ann. Bot.701992339346
  • J.A.AlcaldeM.F.LarraínTiming of photoperiod sensitivity in relation to floral initiation in contrasting genotypes of pea (Pisum sativum L.)Field Crops Res.962006348354
  • J.R.QuinbyJ.D.HeskethR.L.VoigtInfluence of temperature and photoperiod on floral initiation and leaf number in sorghumCrop Sci.131973243246
  • W.CaoD.N.MossTemperature and daylength interaction on phyllochron in wheat and barleyCrop Sci.29198910461048
  • J.W.WhiteJ.KornegayC.CajiaoInheritance of temperature sensitivity of the photoperiod response in common bean (Phaseolus vulgaris)Euphytica91199658
  • T.A.LaFargeI.J.BroadG.L.HammerTillering in grain sorghum over a wide range of population densities: identification of a common hierarchy for tiller emergence, leaf area development and fertilityAnn. Bot.9020028798
  • K.A.FranklinG.C.WhitelamPhytochromes and shade-avoidance responses in plantsAnn. Bot.962005169175
  • J.B.R.EversJ.VosC.FournierB.AndrieuM.ChelleP.C.StruikAn architectural model of spring wheat: evaluation of the effects of population density and shading on model parameterization and performanceEcol. Modell.2002007308320
  • R.RichardsA tiller inhibitor gene in wheat and its effect on plant growthAustral. J. Agric. Res.391988749757
  • B.YuZ.LinH.LiX.LiJ.LiY.WangX.ZhangZ.ZhuW.ZhaiX.WangD.XieC.SunTAC1, a major quantitative trait locus controlling tiller angle in riceThe Plant J.522007891898
  • F.W.T.Penning De VriesA.H.M.BrunstingH.H.Van LaarProducts requirements and efficiency of biosynthesis a quantitative approachJ. Theoret. Biol.451974339377
  • G.SarathR.MitchellS.SattlerD.FunnellJ.PedersenR.GrayboschK.VogelOpportunities and roadblocks in utilizing forages and small grains for liquid fuelsJ. Indust. Microbiol. Biotech.200710.1007/s10295-007-0296-3
  • J.S.AmthorEfficiency of lignin biosynthesis: a quantitative analysisAnn. Bot.912003673695
  • P.V.MinorskyAchieving the in silico plant. Systems biology and the future of plant biological researchPlant Physiol.1322003404409
  • S.HoopsS.SahleR.GaugesC.LeeJ.PahleN.SimusM.SinghalL.XuP.MendesU.KummerCOPASI—a complex pathway simulatorBioinformatics22200630673074
  • K.TakahashiK.KaizuB.HuM.TomitaA multi-algorithm, multi-timescale method for cell simulationBioinformatics202004538546
  • M.HuckaThe systems biology markup language (SBML): a medium for representation and exchange of biochemical network modelsBioinformatics192003524531
  • S.M.WelchJ.L.RoeZ.A.DongGenetic neural network model of flowering time control in Arabidopsis thalianaAgron. J.9520037181
  • S.M.WelchJ.L.RoeS.DasZ.DongR.HeM.B.KirkhamMerging genomic control networks and soil-plant-atmosphere-continuum modelsAgric. Syst.862005243274
  • J.C.W.LockeM.M.SouthernL.Kozma-BognarV.HibberdP.E.BrownM.S.TurnerA.J.MillarExtension of a genetic network model by iterative experimentation and mathematical analysisMolec. Syst. Biol.120052005.0013
  • R.A.Fd. Réaumur, Observations du thermomètre, faites a Paris pendant l’année 1735, comparés avec celles qui ont été faites sous la ligne, a l’Isle de France, a Alger et en quelques-unes de nos isles de I’ Amérique. Mémoires de l’Académie des Sciences, Paris (1735) 545–576.
  • W.W.GarnerH.A.AllardEffect of the relative length of day and night and other factors of the environment on growth and reproduction in plantsJ. Agric. Res.181920553641
  • Arabidopsis Genome InitiativeAnalysis of the genome sequence of the flowering plant Arabidopsis thalianaNature (London)4082000796815
  • M.AxtellJ.A.SnyderD.P.BartelCommon functions for diverse small RNAs of land plantsPlant Cell19200717501769
  • A.S.N.ReddyAlternative splicing of pre-messenger RNAs in plants in the Genomic EraAnn. Rev. Plant Biol.582007267294
  • J.BenderPlant epigeneticsCurr. Biol.122002R412R414
  • D.R.KaplanFundamental concepts of leaf morphology and morphogenesis: a contribution to the interpretation of molecular genetic mutantsInt. J. Plant Sci.1622001465474
  • C.T.de WitF.W.T.Penning de VriesCrop growth models without hormonesNether. J. Agric. Sci.311983313323
  • Drosophila 12 Genomes ConsortiumEvolution of genes and genomes on the Drosophila phylogenyNature4502007203218
  • S.I.WrightI.V.BiS.G.SchroederM.YamasakiJ.F.DoebleyM.D.McMullenB.S.GautThe effects of artificial selection on the maize genomeScience308200513101314
  • A.Eyre-WalkerThe genomic rate of adaptive evolutionTrends Ecol. Evol.212006569575

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