Abstract
The QTL-allele system underlying two spectral reflectance physiological traits, NDVI (normalized difference vegetation index) and CHL (chlorophyll index), related to plant growth and yield was studied in the Chinese soybean germplasm population (CSGP), which consisted of 341 wild accessions (WA), farmer landraces (LR), and released cultivars (RC). Samples were evaluated in the Photosynthetic System II imaging platform at Nanjing Agricultural University. The NDVI and CHL data were obtained from hyperspectral reflectance images in a randomized incomplete block design experiment with two replicates. The NDVI and CHL ranged from 0.05–0.18 and 1.20–4.78, had averages of 0.11 and 3.57, and had heritabilities of 78.3% and 69.2%, respectively; the values of NDVI and CHL were both significantly higher in LR and RC than in WA. Using the RTM-GWAS (restricted two-stage multi-locus genome-wide association study) method, 38 and 32 QTLs with 89 and 82 alleles and 2–4 and 2–6 alleles per locus were identified for NDVI and CHL, respectively, which explained 48.36% and 51.35% of the phenotypic variation for NDVI and CHL, respectively. The QTL-allele matrices were established and separated into WA, LR, and RC submatrices. From WA to LR + RC, 4 alleles and 2 new loci emerged, and 1 allele was excluded for NDVI, whereas 6 alleles emerged, and no alleles were excluded, in LR + RC for CHL. Recombination was the major motivation of evolutionary differences. For NDVI and CHL, 39 and 32 candidate genes were annotated and assigned to GO groups, respectively, indicating a complex gene network. The NDVI and CHL were upstream traits that were relatively conservative in their genetic changes compared with those of downstream agronomic traits. High-throughput phenotyping integrated with RTM-GWAS provides an efficient procedure for studying the population genetics of traits.
Highlights
With the rapid development of high-throughput genome sequencing technology, high-quality genotype data can be obtained quickly and cheaply, enabling the detection of quantitative trait loci (QTL) at a high level of resolution through genome-wide association studies (GWAS) (Shendure and Ji, 2008; Visscher et al, 2017)
The aims of this study were the following: (i) characterize variation in two spectral reflectance physiological traits, normalized difference vegetation index (NDVI) and chlorophyll index (CHL), in the Chinese soybean germplasm population (CSGP), including wild accessions (WA), cultivated farmer landraces (LR), and released modern cultivars (RC), using the facilities and equipment of the greenhouse high-throughput phenotyping platform (GHTPP) at the Plant Phenomics Research Center (PPRC), Nanjing Agricultural University (NJAU), to compare wild and cultivated soybeans; (ii) explore genetic variation in QTLalleles through association mapping using the novel RTM-GWAS procedure and evolutionary changes from WA to LR and released cultivars (RC); (iii) predict the genetic potentials of the germplasm population through recombination among the accessions; and (iv) predict the candidate genes as well as the gene constitutions of NDVI and CHL in the CSGP based on information in SoyBase1
Phenotype measurements for each accession were taken nine times on different days during growth (DAS6, DAS9, DAS12, and DAS30); the trait heritability at each measurement ranged between 16.0–78.3% and 25.4–69.2% for NDVI and CHL, respectively
Summary
With the rapid development of high-throughput genome sequencing technology, high-quality genotype data can be obtained quickly and cheaply, enabling the detection of quantitative trait loci (QTL) at a high level of resolution through genome-wide association studies (GWAS) (Shendure and Ji, 2008; Visscher et al, 2017). As upstream biological traits often underlie breeding target traits, there is much interest in identifying upstream traits for the control of downstream agronomic traits These upstream traits generally consist of some physiological or biochemical traits that are time-consuming and difficult to identify without the appropriate tools. Both high-quality genotype and phenotype data are required for accurate and powerful QTL detection. The high-throughput phenotyping platform usually consists of several sensors and automatic systems and provides an efficient method for characterizing plant phenotypes (Furbank and Tester, 2011)
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