Editorial: Accelerating Genetic Gains in Pulses

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cg.contributor.affiliationInternational Center for Agricultural Research in the Dry Areasen
cg.contributor.affiliationUniversity of Tennesseeen
cg.contributor.affiliationIndian Council of Agricultural Research, Indian Institute of Pulses Researchen
cg.contributor.affiliationNational Research Council Canadaen
cg.contributor.donorCGIAR Trust Funden
cg.contributor.initiativeAccelerated Breeding
cg.contributor.initiativeFragility to Resilience in Central and West Asia and North Africa
cg.creator.identifierAgrawal, Shiv Kumar: 0000-0001-8407-3562
cg.creator.identifierBaum, Michael: 0000-0002-8248-6088
cg.identifier.doihttps://doi.org/10.3389/fpls.2022.879377en
cg.isijournalISI Journalen
cg.issn1664-462Xen
cg.journalFrontiers in Plant Scienceen
cg.reviewStatusPeer Reviewen
cg.subject.actionAreaResilient Agrifood Systems
cg.subject.actionAreaGenetic Innovation
cg.subject.impactAreaNutrition, health and food security
cg.subject.sdgSDG 2 - Zero hungeren
cg.volume13en
dc.contributor.authorPratap, Adityaen
dc.contributor.authorAgrawal, Shiv Kumaren
dc.contributor.authorPolowick, Patricia L.en
dc.contributor.authorBlair, Matthew W.en
dc.contributor.authorBaum, Michaelen
dc.date.accessioned2022-12-16T21:50:26Zen
dc.date.available2022-12-16T21:50:26Zen
dc.identifier.urihttps://hdl.handle.net/10568/126057
dc.titleEditorial: Accelerating Genetic Gains in Pulsesen
dcterms.abstractLegumes, members of the Fabaceae/Leguminosae family, are the third largest family of higher plants with almost 20,000 species belonging to 650 genera, and are ubiquitous all over the world. Among all legumes, pulse crops or food legumes fall into the four clades of the subfamily Papilionoideae which include aeschynomenoids/dalbergiods, genistoids, hologalegina, and phaseoloids/millettoids. They are distinctive due to their positive impact on agricultural and environmental sustainability and have a prominent role in promoting human and animal health, soil amelioration, cropping system diversification, and sustenance of rural livelihoods (Pratap et al., 2021a). These also provide protein isolates that are increasingly being used in the food industry as functional ingredients suitable for vegan diets (Robinson et al., 2019). The inclusion of pulses in rotation with cereals helps to improve system yields, enhance net carbon sequestration, and lower the carbon footprint. Nonetheless, in addition to being an excellent source of protein, starch, and micronutrients, pulses also contain anti-nutritional compounds that can interfere with the absorption of minerals (Moore et al., 2018) and also the digestion of protein (Clemente et al., 2015). Realizing their importance, significant research has been dedicated to their genetic amelioration, thereby turning them into mainstream crops from so-called “orphan legumes”. Classical plant breeding methods led to the development of more than 3,800 improved varieties of different pulse crops globally, with improved attributes of grain yield, crop duration, stress resistance, nutrition quality, etc. However, despite this effort, the increase in average pulse yields (from 637 to 1,009 kg/ha) has been modest compared to dramatic increases in cereal productivity (from 1,353 to 4,074 kg/ha) between 1961 and 2017 (Kumar et al., 2020). Among legumes, Koester et al. (2014) studied 80 years of historical data of soybean breeding at the Crop Research and Education Center in Urbana, USA and reported a genetic gain of 26.5 kg ha−1 year−1 , attributing the gain in grain yield to increases in light interception, energy conversion, and partitioning efficiencies. Productivity gains in pulses have been recorded when especially considered along with the markedly reduced duration of the improved varieties, leading to increased cropping intensity, while genetic gains have been recorded for traits imparting resistance to major biotic and abiotic stresses, herbicide tolerance, larger seeds, and improved nutritional quality. This resulted in the growth, in terms of production and productivity, in major pulse-producing countries. For example, India witnessed the highest growth in production in mung bean (178%), followed by chickpea (125%), urdbean (90%), pigeonpea (51%), and lentil (34%) in the last 15 years (Gaur, 2021). Notably, breeding in most pulses has remained confined to the exploitation of genetic variation within the primary gene pool, which has resulted in a narrow genetic base in most of them.en
dcterms.accessRightsOpen Access
dcterms.available2022-04-07
dcterms.bibliographicCitationAditya Pratap, Shiv Kumar Agrawal, Patricia L. Polowick, Matthew W. Blair, Michael Baum. (7/4/2022). Editorial: Accelerating Genetic Gains in Pulses. Frontiers in Plant Science, 13.en
dcterms.formatPDFen
dcterms.issued1970-01-01
dcterms.languageen
dcterms.licenseCC-BY-4.0
dcterms.publisherFrontiers Mediaen
dcterms.subjectfood securityen
dcterms.subjecthealthen
dcterms.subjectimprovementen
dcterms.subjectlegumesen
dcterms.subjectnutritionen
dcterms.subjectplant breedingen
dcterms.subjectpulsesen
dcterms.subjectgoal 2 zero hungeren
dcterms.subjectlegumeen
dcterms.subjectqtlsen
dcterms.typeJournal Article

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