Bellaloui Nacer, Yuan Jiazheng, Knizia Dounya, Song Qijian, Betts Frances, Register Teresa, Williams Earl, Lakhssassi Naoufal, Mazouz Hamid, Nguyen Henry T, Meksem Khalid, Mengistu Alemu, Kassem My Abdelmajid
USDA, Agriculture Research Service, Crop Genetics Research Unit, Stoneville, California, United States of America.
Plant Genomics and Biotechnology Laboratory, Department of Biological and Forensic Sciences, Fayetteville State University, Fayetteville, North Carolina, United States of America.
PLoS One. 2025 Sep 3;20(9):e0331214. doi: 10.1371/journal.pone.0331214. eCollection 2025.
Nitrogen (N), phosphorus (P), and sulfur (S) are essential nutrients for plant health. Deficiencies in N, P, or S in plants lead to lower seed production and seed quality in grain crops, including soybean seed. Soybean seed is a source of protein, oil, essential amino acids, and minerals. These nutrients are essential for plant health, and maintaining N, P, and S levels in soybean seed is crucial for higher seed nutritional value and amino acids quality. There is limited information on genomic regions, candidate genes, and molecular markers associated with soybean seed N, P, and S. Two field experiments were carried out in two locations using a 'Forrest' × 'Williams 82' recombinant inbred lines (RIL) population. A 306 RIL population and 2075 SNP markers were used to create the genetic map. The results showed a wide range of N, P, and S concentrations in both locations among RIL population lines. Based on the broad-sense heritability (H2), 91.7% of seed N concentration variation was due to genetic effects, followed by 48.2% for S seed concentration, and a heritability of close to zero for seed P concentration. Eleven QTL were identified for seed N, seven QTL for seed P, and nine QTL for seed S in two locations. All these QTL had a significant linkage to the trait as their LOD ranged from 2.5 to 6.48 in 2018 and from 2.75 to 128.72 in 2020. Two QTL for seed N (qN-02-[IL-2020] on Chr 4, and qN-03-[IL-2020] on Chr 4 were identified at the marker Gm04_4687302-Gm04_7672403 and Gm04_7672403, and their LOD were 45.06 and 96.98, and their contribution to the phenotypic variation were 45.85% and 48.37%, respectively. The low heritability of P indicated a major interactions between the trait (P) and environment. Except for the seed N, P, and S QTL, identified on Chr 16, 11 QTL reported here were not previously identified and therefore are novel. Several functional genes encoding N-, P-, and S-proteins, enzymes, and transporters were identified and located within the QTL interval. To our knowledge, the QTL identified here on Chr 2 and 6 are novel and were not previously identified. Therefore, QTL, genes, and molecular markers discovered in this research will provide breeders with new knowledge and tools for soybean selection for optimum seed mineral nutritional qualities. Also, this new findings advance our knowledge of physiology and genetics of seed N, S, and P candidate genes for genetic engineering application.
氮(N)、磷(P)和硫(S)是植物健康生长所必需的营养元素。植物中氮、磷或硫的缺乏会导致包括大豆种子在内的谷类作物种子产量降低和种子质量下降。大豆种子是蛋白质、油脂、必需氨基酸和矿物质的来源。这些营养元素对植物健康至关重要,维持大豆种子中的氮、磷和硫水平对于提高种子营养价值和氨基酸质量至关重要。关于与大豆种子氮、磷和硫相关的基因组区域、候选基因和分子标记的信息有限。在两个地点使用‘Forrest’בWilliams 82’重组自交系(RIL)群体进行了两项田间试验。利用一个包含306个RIL个体的群体和2075个单核苷酸多态性(SNP)标记构建了遗传图谱。结果表明,在两个地点的RIL群体品系中,氮、磷和硫的浓度范围很广。基于广义遗传力(H2),种子氮浓度变异的91.7%归因于遗传效应,其次是种子硫浓度的48.2%,而种子磷浓度的遗传力接近零。在两个地点分别鉴定出11个种子氮的数量性状位点(QTL)、7个种子磷的QTL和9个种子硫的QTL。所有这些QTL与该性状都有显著连锁,其似然比检验值(LOD)在2018年为2.5至6.48,在2020年为2.75至128.72。在标记Gm04_4687302 - Gm04_7672403和Gm04_7672403处鉴定出两个种子氮的QTL(位于第4号染色体上的qN - 02 - [IL - 2020]和位于第4号染色体上的qN - 03 - [IL - 2020]),它们的LOD分别为45.06和96.98,对表型变异的贡献率分别为45.85%和48.37%。磷的低遗传力表明该性状(磷)与环境之间存在主要的相互作用。除了在第16号染色体上鉴定出的种子氮、磷和硫的QTL外,这里报道的11个QTL以前未被鉴定,因此是新发现的。在QTL区间内鉴定出了几个编码氮、磷和硫蛋白、酶及转运蛋白的功能基因。据我们所知,这里在第2号和第6号染色体上鉴定出的QTL是新的,以前未被发现。因此,本研究中发现的QTL、基因和分子标记将为育种者提供有关大豆选择以获得最佳种子矿物质营养品质的新知识和工具。此外,这些新发现推进了我们对种子氮、硫和磷候选基因的生理学和遗传学的认识,可用于基因工程应用。
