Genomic approaches for improving grain zinc and iron content in wheat

Genomic approaches for improving grain zinc and iron content in wheat

More than three billion people worldwide suffer from iron deficiency associated anemia and an equal number people suffer from zinc deficiency. These conditions are more prevalent in Sub-Saharan Africa and South Asia. In developing countries, children under the age of five with stunted growth and pregnant or lactating women were found to be at high risk of zinc and iron deficiencies. Biofortification, defined as breeding to develop varieties of staple food crops whose grain contains higher levels of micronutrients such as iron and zinc, are one of the most promising, cost-effective and sustainable ways to improve the health in resource-poor households, particularly in rural areas where families consume some part of what they grow. Biofortification through conventional breeding in wheat, particularly for grain zinc and iron, have made significant contributions, transferring important genes and quantitative trait loci (QTLs) from wild and related species into cultivated wheat. Nonetheless, the quantitative, genetically complex nature of iron and zinc levels in wheat grain limits progress through conventional breeding, making it difficult to attain genetic gain both for yield and grain mineral concentrations. Wheat biofortification can be achieved by enhancing mineral uptake, source-to-sink translocation of minerals and their deposition into grains, and the bioavailability of the minerals. A number of QTLs with major and minor effects for those traits have been detected in wheat; introducing the most effective into breeding lines will increase grain zinc and iron concentrations. New approaches to achieve this include marker assisted selection and genomic selection. Faster breeding approaches need to be combined to simultaneously increase grain mineral content and yield in wheat breeding lines.

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Bibliographic Details
Main Authors: Roy, C., Kumar, S., Ranjan, R.D., Kumhar, S.R., Velu, G.
Format: Article biblioteca
Language:English
Published: Frontiers 2022
Subjects:AGRICULTURAL SCIENCES AND BIOTECHNOLOGY, Genome-Wide Association Study, New Breeding Techniques, Genomic Selection, BIOFORTIFICATION, MARKER-ASSISTED SELECTION, MALNUTRITION, BREEDING, QUANTITATIVE TRAIT LOCI MAPPING, SPEED BREEDING, ZINC, IRON, WHEAT,
Online Access:https://hdl.handle.net/10883/22326
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spelling dig-cimmyt-10883-223262024-01-23T15:06:29Z Genomic approaches for improving grain zinc and iron content in wheat Roy, C. Kumar, S. Ranjan, R.D. Kumhar, S.R. Velu, G. AGRICULTURAL SCIENCES AND BIOTECHNOLOGY Genome-Wide Association Study New Breeding Techniques Genomic Selection BIOFORTIFICATION MARKER-ASSISTED SELECTION MALNUTRITION BREEDING QUANTITATIVE TRAIT LOCI MAPPING SPEED BREEDING ZINC IRON WHEAT More than three billion people worldwide suffer from iron deficiency associated anemia and an equal number people suffer from zinc deficiency. These conditions are more prevalent in Sub-Saharan Africa and South Asia. In developing countries, children under the age of five with stunted growth and pregnant or lactating women were found to be at high risk of zinc and iron deficiencies. Biofortification, defined as breeding to develop varieties of staple food crops whose grain contains higher levels of micronutrients such as iron and zinc, are one of the most promising, cost-effective and sustainable ways to improve the health in resource-poor households, particularly in rural areas where families consume some part of what they grow. Biofortification through conventional breeding in wheat, particularly for grain zinc and iron, have made significant contributions, transferring important genes and quantitative trait loci (QTLs) from wild and related species into cultivated wheat. Nonetheless, the quantitative, genetically complex nature of iron and zinc levels in wheat grain limits progress through conventional breeding, making it difficult to attain genetic gain both for yield and grain mineral concentrations. Wheat biofortification can be achieved by enhancing mineral uptake, source-to-sink translocation of minerals and their deposition into grains, and the bioavailability of the minerals. A number of QTLs with major and minor effects for those traits have been detected in wheat; introducing the most effective into breeding lines will increase grain zinc and iron concentrations. New approaches to achieve this include marker assisted selection and genomic selection. Faster breeding approaches need to be combined to simultaneously increase grain mineral content and yield in wheat breeding lines. 2022-12-08T17:21:53Z 2022-12-08T17:21:53Z 2022 Article Published Version https://hdl.handle.net/10883/22326 10.3389/fgene.2022.1045955 English Climate adaptation & mitigation Accelerated Breeding Genetic Innovation Bill & Melinda Gates Foundation (BMGF) CGIAR Trust Fund Foreign, Commonwealth & Development Office (FCDO) https://hdl.handle.net/10568/127590 CIMMYT manages Intellectual Assets as International Public Goods. The user is free to download, print, store and share this work. In case you want to translate or create any other derivative work and share or distribute such translation/derivative work, please contact CIMMYT-Knowledge-Center@cgiar.org indicating the work you want to use and the kind of use you intend; CIMMYT will contact you with the suitable license for that purpose Open Access Switzerland Frontiers 13 1664-8021 Frontiers in Genetics 1045955
institution CIMMYT
collection DSpace
country México
countrycode MX
component Bibliográfico
access En linea
databasecode dig-cimmyt
tag biblioteca
region America del Norte
libraryname CIMMYT Library
language English
topic AGRICULTURAL SCIENCES AND BIOTECHNOLOGY
Genome-Wide Association Study
New Breeding Techniques
Genomic Selection
BIOFORTIFICATION
MARKER-ASSISTED SELECTION
MALNUTRITION
BREEDING
QUANTITATIVE TRAIT LOCI MAPPING
SPEED BREEDING
ZINC
IRON
WHEAT
AGRICULTURAL SCIENCES AND BIOTECHNOLOGY
Genome-Wide Association Study
New Breeding Techniques
Genomic Selection
BIOFORTIFICATION
MARKER-ASSISTED SELECTION
MALNUTRITION
BREEDING
QUANTITATIVE TRAIT LOCI MAPPING
SPEED BREEDING
ZINC
IRON
WHEAT
spellingShingle AGRICULTURAL SCIENCES AND BIOTECHNOLOGY
Genome-Wide Association Study
New Breeding Techniques
Genomic Selection
BIOFORTIFICATION
MARKER-ASSISTED SELECTION
MALNUTRITION
BREEDING
QUANTITATIVE TRAIT LOCI MAPPING
SPEED BREEDING
ZINC
IRON
WHEAT
AGRICULTURAL SCIENCES AND BIOTECHNOLOGY
Genome-Wide Association Study
New Breeding Techniques
Genomic Selection
BIOFORTIFICATION
MARKER-ASSISTED SELECTION
MALNUTRITION
BREEDING
QUANTITATIVE TRAIT LOCI MAPPING
SPEED BREEDING
ZINC
IRON
WHEAT
Roy, C.
Kumar, S.
Ranjan, R.D.
Kumhar, S.R.
Velu, G.
Genomic approaches for improving grain zinc and iron content in wheat
description More than three billion people worldwide suffer from iron deficiency associated anemia and an equal number people suffer from zinc deficiency. These conditions are more prevalent in Sub-Saharan Africa and South Asia. In developing countries, children under the age of five with stunted growth and pregnant or lactating women were found to be at high risk of zinc and iron deficiencies. Biofortification, defined as breeding to develop varieties of staple food crops whose grain contains higher levels of micronutrients such as iron and zinc, are one of the most promising, cost-effective and sustainable ways to improve the health in resource-poor households, particularly in rural areas where families consume some part of what they grow. Biofortification through conventional breeding in wheat, particularly for grain zinc and iron, have made significant contributions, transferring important genes and quantitative trait loci (QTLs) from wild and related species into cultivated wheat. Nonetheless, the quantitative, genetically complex nature of iron and zinc levels in wheat grain limits progress through conventional breeding, making it difficult to attain genetic gain both for yield and grain mineral concentrations. Wheat biofortification can be achieved by enhancing mineral uptake, source-to-sink translocation of minerals and their deposition into grains, and the bioavailability of the minerals. A number of QTLs with major and minor effects for those traits have been detected in wheat; introducing the most effective into breeding lines will increase grain zinc and iron concentrations. New approaches to achieve this include marker assisted selection and genomic selection. Faster breeding approaches need to be combined to simultaneously increase grain mineral content and yield in wheat breeding lines.
format Article
topic_facet AGRICULTURAL SCIENCES AND BIOTECHNOLOGY
Genome-Wide Association Study
New Breeding Techniques
Genomic Selection
BIOFORTIFICATION
MARKER-ASSISTED SELECTION
MALNUTRITION
BREEDING
QUANTITATIVE TRAIT LOCI MAPPING
SPEED BREEDING
ZINC
IRON
WHEAT
author Roy, C.
Kumar, S.
Ranjan, R.D.
Kumhar, S.R.
Velu, G.
author_facet Roy, C.
Kumar, S.
Ranjan, R.D.
Kumhar, S.R.
Velu, G.
author_sort Roy, C.
title Genomic approaches for improving grain zinc and iron content in wheat
title_short Genomic approaches for improving grain zinc and iron content in wheat
title_full Genomic approaches for improving grain zinc and iron content in wheat
title_fullStr Genomic approaches for improving grain zinc and iron content in wheat
title_full_unstemmed Genomic approaches for improving grain zinc and iron content in wheat
title_sort genomic approaches for improving grain zinc and iron content in wheat
publisher Frontiers
publishDate 2022
url https://hdl.handle.net/10883/22326
work_keys_str_mv AT royc genomicapproachesforimprovinggrainzincandironcontentinwheat
AT kumars genomicapproachesforimprovinggrainzincandironcontentinwheat
AT ranjanrd genomicapproachesforimprovinggrainzincandironcontentinwheat
AT kumharsr genomicapproachesforimprovinggrainzincandironcontentinwheat
AT velug genomicapproachesforimprovinggrainzincandironcontentinwheat
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