Trait Overview
TraitSeed number per pod
Trait CategoryAnatomy and morphology trait
AbbreviationSDNB
Definition
QTLs[view all 70]
QTLs
Download Table
QTL/MTLLinkage GroupPeakStartStopDatasetMapViewer
qSDNB.Beluga/PHA0399.LG01LG01-73.276.9Bean-Flowering_time_vegetative_growth-Gonzalez-2016View
qSDNB.Beluga/PHA0399.LG02LG02-28.432Bean-Flowering_time_vegetative_growth-Gonzalez-2016View
qSDNB.Beluga/PHA0399.LG06LG06-20.427.5Bean-Flowering_time_vegetative_growth-Gonzalez-2016View
qSDNB.DDR14/Explorer.LG01.13LG0170.19--Pea-Yield_traits-Guindon-2019View
qSDNB.DDR14/Explorer.LG01.13.2LG0176.49--Pea-Yield_traits-Guindon-2019View
qSDNB.Green_pod_cowpea/Xiabao_II.LG05LG0559.8--Cowpea-Yield-Pan-2017View
qSDNB.Green_pod_cowpea/Xiabao_II.LG11LG1148.5--Cowpea-Yield-Pan-2017View
qSDNB.IJR/AFR298.LG01.HS16LG014240.547.5Bean-Heat_stress_response-Vargas-2021View
qSDNB.IJR/AFR298.LG01.HS16.2LG019492.594Bean-Heat_stress_response-Vargas-2021View
qSDNB.IJR/AFR298.LG01.HSCLG012827.529.5Bean-Heat_stress_response-Vargas-2021View
qSDNB.IJR/AFR298.LG01.HSC.2LG019492.594Bean-Heat_stress_response-Vargas-2021View
qSDNB.IJR/AFR298.LG01.NS17LG014140.548.5Bean-Heat_stress_response-Vargas-2021View
qSDNB.IJR/AFR298.LG01.NS17.2LG018780.588.5Bean-Heat_stress_response-Vargas-2021View
qSDNB.JP235863/AusTRCF66514.LG05LG0529--Vigna-Domestication-Dachapak-2018View
qSDNB.JP235863/AusTRCF66514.LG07LG073--Vigna-Domestication-Dachapak-2018View
qSDNB.JP235863/AusTRCF66514.LG07.2LG0747--Vigna-Domestication-Dachapak-2018View
qSDNB.JP235863/AusTRCF66514.LG08LG0846--Vigna-Domestication-Dachapak-2018View
qSDNB.JP235863/AusTRCF66514.LG09LG0925--Vigna-Domestication-Dachapak-2018View
qSDNB.JP81610/JP89083.LG07.F2LG0745.9--Cowpea-Domestication_traits-Kongjaimun-2012View
qSDNB.JP81610/JP89083.LG11.BC1F1LG1136.5--Cowpea-Domestication_traits-Kongjaimun-2012View
qSDNB.JP81610/JP89083.LG11.F2LG1126.6--Cowpea-Domestication_traits-Kongjaimun-2012View
qSDNB.PHA0419/Beluga.LG01LG01-76.984.9Bean-Flowering_time_vegetative_growth-Gonzalez-2016View
qSDNB.Pusa_Dwarf/H2001-4.LG03LG0332.71--Pigeon_pea-Yield-Singh-2020View
qSDNB.Pusa_Dwarf/H2001-4.LG05LG0554.81--Pigeon_pea-Yield-Singh-2020View
qSDNB.Pusa_Dwarf/H2001-4.LG10LG1046.01--Pigeon_pea-Yield-Singh-2020View
qSDNB.SBD377/BGD112.LG1LG01-85.6885.99Chickpea-Seed_traits-Verma-2015View
qSDNB.SBD377/BGD112.LG2LG02-27.428.53Chickpea-Seed_traits-Verma-2015View
qSDNB.SBD377/BGD112.LG5LG05-50.0450.59Chickpea-Seed_traits-Verma-2015View
qSDNB.SBD377/BGD112.LG8LG08-28.6230.1Chickpea-Seed_traits-Verma-2015View
qSDNB.Tiber/Starozagorski.LG02.2013LG0285.2--Bean-Drought_response-Sedlar-2020View
qSDNB.Tiber/Starozagorski.LG02.2014LG0285.2--Bean-Drought_response-Sedlar-2020View
qSDNB.Tiber/Starozagorski.LG07.2013LG0769.6--Bean-Drought_response-Sedlar-2020View
qSDNB.Tiber/Starozagorski.LG07.2014LG0743.2--Bean-Drought_response-Sedlar-2020View
qSDNB.Tiber/Starozagorski.LG08.2014LG0838.3--Bean-Drought_response-Sedlar-2020View
qSDNB.Tvu2185/Tvu6642.LG08LG08108--Cowpea-Yield-Garciaoliviera-2020View
qSDNB.Tvu2185/Tvu6642.LG09LG094--Cowpea-Yield-Garciaoliviera-2020View
qSDNB.Tvu2185/Tvu6642.LG09.2LG0958--Cowpea-Yield-Garciaoliviera-2020View
qSDNB.Tvu2185/Tvu6642.LG11LG1179--Cowpea-Yield-Garciaoliviera-2020View
qSDPD.29HxVf136.LG10----Faba-Agronomic_Traits-Avila-2005-
qSDPD.CDCCentennial_x_CDCSage.LG2LG22--Pea-Flowering_Traits-Huang-2017View
qSDPD.CDCCentennial_x_CDCSage.LG3.1LG3148.2--Pea-Flowering_Traits-Huang-2017View
qSDPD.CDCCentennial_x_CDCSage.LG3.2LG3133--Pea-Flowering_Traits-Huang-2017View
qSDPD.CDCCentennial_x_CDCSage.LG4.1LG4224.7--Pea-Flowering_Traits-Huang-2017View
qSDPD.CDCCentennial_x_CDCSage.LG4.2LG4259--Pea-Flowering_Traits-Huang-2017View
qSDPD.CDCCentennial_x_CDCSage.LG4.3LG4262--Pea-Flowering_Traits-Huang-2017View
qSDPD.ConsensusMap_2013.LGI.2007.1----Faba-Economical_traits-Satovic-2013-
qSDPD.ConsensusMap_2013.LGI.2007.2----Faba-Economical_traits-Satovic-2013-
qSDPD.ConsensusMap_2013.LGII.2007----Faba-Economical_traits-Satovic-2013-
qSDPD.ConsensusMap_2013.LGVI.2007----Faba-Economical_traits-Satovic-2013-
qSDPD.ConsensusMap_2013.LGVI.2008----Faba-Economical_traits-Satovic-2013-
qSDPD.ICC4958xICC1882.LG3.IR.1----Chickpea-Drought_Tolerance-Varshney- 2014-
qSDPD.ICC4958xICC1882.LG4.RF.1----Chickpea-Drought_Tolerance-Varshney- 2014-
qSDPD.iCC4958xICC1882.LG7.RF.1----Chickpea-Drought_Tolerance-Varshney- 2014-
qSDPD.ICC4958_x_ICC1882-RIL.LG04.RF.1----Chickpea-QTL_Drought_Tolerance-Jaganathan-2015-
qSDPD.ICC4958_x_ICC1882-RIL.LG04.RF.2----Chickpea-QTL_Drought_Tolerance-Jaganathan-2015-
qSDPD.ICC4958_x_ICC1882-RIL.LG04.RF.3----Chickpea-QTL_Drought_Tolerance-Jaganathan-2015-
qSDPD.ICC4958_x_ICC1882-RIL.LG04.RF.4----Chickpea-QTL_Drought_Tolerance-Jaganathan-2015-
qSDPD.Pea-JI1491xCameor-RIL.LGI.Dij09LG153.748.363.8Pea-Frost_Tolerance-Klein-2014View
qSDPD.Pea-JI1491xCameor-RIL.LGIV.Dij09LG470.752.775.3Pea-Frost_Tolerance-Klein-2014View
qSDPD.Pea-JI1491xCameor-RIL.LGVII.DIj08LG739.310.742.6Pea-Frost_Tolerance-Klein-2014View
qSDPD.Pea-JI1491xCameor-RIL.LGVII.Dij09LG749.93957.3Pea-Frost_Tolerance-Klein-2014View
qSDPD.Pea-JI1491xCameor-RIL.LGVII.Dij10LG740.320.148.9Pea-Frost_Tolerance-Klein-2014View
qSDPD.Vf6xVf27.LG02.2007LG02230.63--Faba-QTL_Flowering_Yield-Cruz-Izquierdo-2012View
qSDPD.Vf6xVf27.LG04.2007.1LG0436.19--Faba-QTL_Flowering_Yield-Cruz-Izquierdo-2012View
qSDPD.Vf6xVf27.LG04.2007.2LG0459.95--Faba-QTL_Flowering_Yield-Cruz-Izquierdo-2012View
qSDPD.Vf6xVf27.LG05.2007LG0584.53--Faba-QTL_Flowering_Yield-Cruz-Izquierdo-2012View
qSDPD.Vf6xVf27.LG05.2008LG0588.53--Faba-QTL_Flowering_Yield-Cruz-Izquierdo-2012View
qSDPD.Wt10245xWt11238.LGIILGII-7578Pea-Yield_protein_content-Krajewski-2012View
qSDPD.Wt11238xWt3557.LGIILGII-621Pea-Yield_protein_content-Krajewski-2012View
Seeds per pod-SppLG1-38.7-naView
YearPublication
2011Gowda SJM, Radhika P, Mhase LB, Jamadagni BM, Gupta VS, Kadoo NY. Mapping of QTLs governing agronomic and yield traits in chickpea. J Appl Genetics. 2011; 52:9-21.
2012Krajewski P, Bocianowski J, Gawłowska M, Kaczmarek Z, Pniewski T, Święcicki W, Wolko B. QTL for yield components and protein content: a multienvironment study of two pea (Pisum sativum L.) populations. Euphytica. 2012; 183(3):323-336.
2012Cruz-Izquierdo S, Avila CM, Satovic Z, Palomino C, Gutierrez N, Ellwood SR, Phan HTT, Cubero JI, Torres AM. Comparative genomics to bridge Vicia faba with model and closely-related legume species: stability of QTLs for flowering and yield-related traits. Theoretical and applied genetics. 2012; 125(8):1767-1782.
2015Jaganathan D, Thudi M, Kale S, Azam S, Roorkiwal M, Gaur PM, Kishor PBK, Nguyen H, Sutton T, Varshney RK. Genotyping-by-sequencing based intra-specific genetic map refines a ‘‘QTL-hotspot” region for drought tolerance in chickpea. Molecular genetics and genomics. 2015; 290(2):559-571.
2013Satovic Z, Avila CM, Cruz-Izquierdo S, Diaz-Ruiz R, Garcia-Ruiz M, Palomino C, Gutierrez N, Vitale S, Ocana-Moral S, Gutierrez MV, Cubero JI, Torres AM. A reference consensus genetic map for molecular markers and economically important traits in faba bean (Vicia faba L.). 2013; 14:932.
2005Avila CM, Satovic Z, Sillero JC, Nadal S, Rubiales D, Moreno MT, Torres, AM. QTL Detection for Agronomic Traits in Faba Bean (Vicia faba L.). 2005; 70(3):65-73.
2013Varshney RK, Thudi M, Nayak SN, Gaur PM, Kashiwagi J, Krishnamurthy L, Jaganathan D, Koppolu J, Bohra A, Tripathi S, Rathore S, Jukanti AK, Jayalakshmi V, Vemula A, Singh SJ, Yasin M, Sheshshayee MS, Viswanatha KP. Genetic dissection of drought tolerance in chickpea (Cicer arietinum L.). Theoretical Applied Genetics. 2013; 127(2):445–462.
2015Verma S, Gupta S, Bandhiwal N, Kumar T, Bharadwaj C, Bhatia S. High-density linkage map construction and mapping of seed trait QTLs in chickpea (Cicer arietinum L.) using Genotyping-by-Sequencing (GBS). Scientific reports. 2015; 5:17512.
2014Klein A, Houtin H, Rond C, Marget P, Jacquin F, Boucherot K, Huart M, Riviere N, Boutet G, Lejeune-Henaut I, Burstin J. QTL analysis of frost damage in pea suggests different mechanisms involved in frost tolerance. Theoretical and Applied Genetics. 2014; 127(6):1319-1330.
2017Huang S, Gali KK, Tar'an B, Warkentin TD, Bueckert RA. Pea Phenology: Crop Potential in a Warming Environment. Crop Science. 2017.
2018Dachapak S, Tomooka N, Somta P, Naito K, Kaga A, Srinives P. QTL analysis of domestication syndrome in zombi pea (Vigna vexillata), an underutilized legume crop. PloS one. 2018; 13(12):e0200116.
2017Pan L, Wang N, Wu Z, Guo R, Yu X, Zheng Y, Xia Q, Gui S, Chen C. A High Density Genetic Map Derived from RAD Sequencing and Its Application in QTL Analysis of Yield-Related Traits in. Frontiers in plant science. 2017; 8:1544.
2016González AM, Yuste-Lisbona FJ, Saburido S, Bretones S, De Ron AM, Lozano R, Santalla M. Major Contribution of Flowering Time and Vegetative Growth to Plant Production in Common Bean As Deduced from a Comparative Genetic Mapping. Frontiers in plant science. 2016; 7:1940.
2012Kongjaimun A, Kaga A, Tomooka N, Somta P, Vaughan DA, Srinives P. The genetics of domestication of yardlong bean, Vigna unguiculata (L.) Walp. ssp. unguiculata cv.-gr. sesquipedalis. Annals of botany. 2012 May; 109(6):1185-200.
2020Singh S, Mahato AK, Jayaswal PK, Singh N, Dheer M, Goel P, Raje RS, Yasin JK, Sreevathsa R, Rai V, Gaikwad K, Singh NK. A 62K genic-SNP chip array for genetic studies and breeding applications in pigeonpea (Cajanus cajan L. Millsp.).. Scientific reports. 2020 Mar 18; 10(1):4960.
2019Guindon MF, Martin E, Cravero V, Gali KK, Warkentin TD, Cointry E. Linkage map development by GBS, SSR, and SRAP techniques and yield-related QTLs in pea. Molecular breeding. 2019; 39(4):54.
2020Garcia-Oliveira AL, Zana Zate Z, Olasanmi B, Boukar O, Gedil M, Fatokun C. Genetic dissection of yield associated traits in a cross between cowpea and yard-long bean (Vigna unguiculata (L.) Walp.) based on DArT markers.. Journal of genetics. 2020; 99.
2020Sedlar A, Zupin M, Maras M, Razinger J, Sustar-Vozlic J, Pipan B, Meglic V. QTL Mapping for Drought-Responsive Agronomic Traits Associated with Physiology, Phenology, and Yield in an Andean Intra-Gene Pool Common Bean Population. Agronomy. 2020; 10:225.
2021Vargas Y, Mayor-Duran VM, Buendia HF, Ruiz-Guzman H, Raatz B. Physiological and genetic characterization of heat stress effects in a common bean RIL population.. PloS one. 2021; 16(4):e0249859.