Root System Architecture and Its Association with Yield under Different Water Regimes in Durum Wheat

cg.contactF.Bassi@cgiar.orgen_US
cg.contributor.centerInternational Center for Agricultural Research in the Dry Areas - ICARDAen_US
cg.contributor.centerMohammed V University - UM5en_US
cg.contributor.centerUniversity of Queensland, Queensland Alliance for Agriculture and Food Innovation - UQ - Qaafien_US
cg.contributor.centerMohammed V University, Faculty of Science - UM5 - FSRen_US
cg.contributor.crpCGIAR Research Program on Wheat - WHEATen_US
cg.contributor.funderInternational Maize and Wheat Improvement Center - CIMMYTen_US
cg.contributor.projectCRP WHEAT Phase IIen_US
cg.contributor.project-lead-instituteInternational Center for Agricultural Research in the Dry Areas - ICARDAen_US
cg.creator.idBassi, Filippo: 0000-0002-1164-5598en_US
cg.identifier.doihttps://dx.doi.org/10.2135/cropsci2018.01.0076en_US
cg.isijournalISI Journalen_US
cg.issn0011-183Xen_US
cg.issue6en_US
cg.journalCrop Scienceen_US
cg.subject.agrovocyieldsen_US
cg.subject.agrovocroot system architectureen_US
cg.volume58en_US
dc.contributorAlahmad, Samiren_US
dc.contributorBelkadi, Bouchraen_US
dc.contributorFilali-Maltouf, Abdelkarimen_US
dc.contributorHickey, Leeen_US
dc.contributorBassi, Filippoen_US
dc.creatorEl Hassouni, Khaoulaen_US
dc.date.accessioned2019-04-08T16:33:39Z
dc.date.available2019-04-08T16:33:39Z
dc.description.abstractDurum wheat (Triticum durum Desf.) is a major cereal crop grown globally, but its production is often hindered by droughts. Breeding for adapted root system architecture should provide a strategic solution for better capturing moisture. The aim of this research was to adapt low-cost and high-throughput methods for phenotyping root architecture and exploring the genetic variability among 25 durum genotypes. Two protocols were used: the “clear pot” for seminal root and the “pasta strainer” to evaluate mature roots. Analysis of variance revealed significant segregation for all measured traits with strong genetic control. Shallow and deep root classes were determined with different methods and then tested in yield trials at five locations with different water regimes. Simple trait measurements did not correlate to any of the traits consistently across field sites. Multitrait classification instead identified significant superiority of deep-rooted genotypes with 16 to 35% larger grains in environments with limited moisture, but 9 to 24% inferior in the drip irrigated site. Combined multitrait classification identified a 28 to 42% advantage in grain yield for the class with deeper roots at two environments where moisture was limited. Further discrimination revealed that yield advantage of 37 to 38% under low moisture could be achieved by the deepest root types, but that it also caused a 20 to 40% yield penalty in moisture-rich environments compared with the shallowest root types. In conclusion, the proposed methodologies enable low-cost and quick characterization of root behavior in durum wheat with significant distinction of agronomic performance.en_US
dc.identifierhttps://mel.cgiar.org/reporting/downloadmelspace/hash/0ca6ec522c282dd9203b9b170bd51350/v/cedb56f3fd334338f22b5711181f1582en_US
dc.identifier.citationKhaoula El Hassouni, Samir Alahmad, Bouchra Belkadi, Abdelkarim Filali-Maltouf, Lee Hickey, Filippo Bassi. (3/9/2018). Root System Architecture and Its Association with Yield under Different Water Regimes in Durum Wheat. Crop Science, 58 (6), pp. 2331-2346.en_US
dc.identifier.statusOpen accessen_US
dc.identifier.urihttps://hdl.handle.net/20.500.11766/9779
dc.languageenen_US
dc.publisherCrop Science Society of Americaen_US
dc.rightsCC-BY-NC-4.0en_US
dc.sourceCrop Science;58,(2018) Pagination 2331-2346en_US
dc.subjectwater regimesen_US
dc.titleRoot System Architecture and Its Association with Yield under Different Water Regimes in Durum Wheaten_US
dc.typeJournal Articleen_US
dcterms.available2018-09-03en_US
dcterms.extent2331-2346en_US
mel.impact-factor1.635en_US

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