Samar G Thabet, Dalia Z Alomari, Henrik Brinch-Pedersen, Ahmad M Alqudah
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This study aimed to expedite biofortification of barley grains by elucidating the genetic basis of Zn, Fe, and Se accumulation in the grains, which will contribute to improved barley nutritional quality.</p><p><strong>Results: </strong>A genome-wide association study (GWAS) was conducted to detect the genetic architecture for grain Zn, Fe, and Se accumulations in 216 spring barley accessions across two years. All the accessions were genotyped by single nucleotide polymorphisms (SNPs) molecular markers. Mineral heritability values ranging from moderate to high were revealed in both environments. Remarkably, there was a high natural phenotypic variation for all micronutrient accumulation in the used population. High-LD SNP markers (222 SNPs) were detected to be associated with all micronutrients in barley grains across the two environments plus BLUEs. 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引用次数: 0
摘要
背景:了解营养、人类健康和植物食物来源之间的关系是公共卫生的重中之重。因此,迫切需要提高大麦(Hordeum vulgare L.)谷物中铁(Fe)、锌(Zn)和硒(Se)等矿物质的含量,以提高大麦谷物的营养价值,克服营养不良及其潜在后果。本研究旨在通过阐明锌、铁和硒在大麦粒中积累的遗传基础,加快大麦粒的生物强化,从而提高大麦粒的营养质量:结果:我们进行了一项全基因组关联研究(GWAS),以检测两年中 216 个春大麦品种的籽粒锌、铁和硒积累的遗传结构。通过单核苷酸多态性(SNPs)分子标记对所有品种进行了基因分型。结果显示,两种环境下矿物质的遗传力值从中等到较高不等。值得注意的是,在使用的群体中,所有微量营养元素积累的自然表型变异都很高。在两种环境和 BLUEs 中,检测到高低密度 SNP 标记(222 个 SNPs)与大麦粒中的所有微量营养元素相关。根据 LD 检测出三个基因组区域,确定了与一个以上性状相关的最有效标记。发现SNP与性状关联最强的基因位于可能参与谷物锌和铁平衡的基因内。两个推测的候选基因分别被注释为碱性螺旋环螺旋(BHLH)家族转录因子和Squamosa启动子结合样蛋白,并被认为是增加谷物锌、铁和硒积累的候选基因:这些发现揭示了大麦籽粒中锌、铁和硒积累的遗传基础,并有可能帮助植物育种者选育出微量元素含量高的品种,以提高籽粒品质,最终改善人类健康。
Genetic analysis toward more nutritious barley grains for a food secure world.
Background: Understanding the relationships between nutrition, human health and plant food source is among the highest priorities for public health. Therefore, enhancing the minerals content such as iron (Fe), zinc (Zn) and selenium (Se) in barley (Hordeum vulgare L.) grains is an urgent need to improve the nutritive value of barley grains in overcoming malnutrition and its potential consequencing. This study aimed to expedite biofortification of barley grains by elucidating the genetic basis of Zn, Fe, and Se accumulation in the grains, which will contribute to improved barley nutritional quality.
Results: A genome-wide association study (GWAS) was conducted to detect the genetic architecture for grain Zn, Fe, and Se accumulations in 216 spring barley accessions across two years. All the accessions were genotyped by single nucleotide polymorphisms (SNPs) molecular markers. Mineral heritability values ranging from moderate to high were revealed in both environments. Remarkably, there was a high natural phenotypic variation for all micronutrient accumulation in the used population. High-LD SNP markers (222 SNPs) were detected to be associated with all micronutrients in barley grains across the two environments plus BLUEs. Three genomic regions were detected based on LD, which were identified for the most effective markers that had associations with more than one trait. The strongest SNP-trait associations were found to be physically located within genes that may be involved in grain Zn and Fe homeostasis. Two putative candidate genes were annotated as Basic helix loop helix (BHLH) family transcription factor and Squamosa promoter binding-like protein, respectively, and have been suggested as candidates for increased grain Zn, Fe, and Se accumulation.
Conclusions: These findings shed a light on the genetic basis of Zn, Fe, and Se accumulation in barley grains and have the potential to assist plant breeders in selecting accessions with high micronutrient concentrations to enhance grain quality and, ultimately human health.
期刊介绍:
Botanical Studies is an open access journal that encompasses all aspects of botany, including but not limited to taxonomy, morphology, development, genetics, evolution, reproduction, systematics, and biodiversity of all plant groups, algae, and fungi. The journal is affiliated with the Institute of Plant and Microbial Biology, Academia Sinica, Taiwan.
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