Genetic diversity and population structure analysis in cultivated soybean (Glycine max [L.] Merr.) using SSR and EST-SSR markers

Rani, Reena; Raza, Ghulam; Tung, Muhammad Haseeb; Rizwan, Muhammad; Ashfaq, Hamza; Shimelis, Hussein; Razzaq, Muhammad Khuram; Arif, Muhammad

doi:10.1371/journal.pone.0286099

Cited by 8 publications

(5 citation statements)

References 56 publications

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“…The average PIC for the 25 SSRs studied was 0.625, indicating a high polymorphic level. Among twenty-five SSRs, Satt371, Satt243, Satt244, Satt458, and Sat288 were previously successfully used to assess genetic diversity in different soybean collections [55][56][57][58][59]. The results showed that only five SSRs were required to distinguish all nineteen accessions from Kazakhstan (Figure S2, which is comparable with reports using other crops [60].…”

Section: Analysis Of Population Structure and Polymorphism Level In T...supporting

confidence: 70%

Genetic Diversity Analysis of Soybean Collection Using Simple Sequence Repeat Markers

Zatybekov,

Yermagambetova,

Genievskaya

et al. 2023

Plants

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Soybean [Glycine max (L.) Merr.] is a nutrient-rich crop that offers a sustainable source of dietary protein and edible oil. Determining the level of genetic diversity and relationships between various genetic resources involved in breeding programs is very important in crop improvement strategies. This study evaluated 100 soybean accessions with diverse origins for 10 important agronomic traits, including plant height (PH), an important plant adaptation-related trait impacting yield, in conditions in southeastern Kazakhstan for 2 years. The comparison of different groups of PH (tall, middle, and short) using a t-test suggested that the group of plants with the tallest PH provided a higher yield (p < 0.001) in relatively dry field conditions. The genetic diversity of the accessions was estimated using 25 simple sequence repeat (SSR) markers previously known to be associated with plant height. The results showed a significant variation among different groups of origin for all measured agronomic traits, as well as high genetic diversity, with the PIC (polymorphism information content) varying from 0.140 to 0.732, with an average of 0.524. Nei’s diversity index ranged between 0.152 and 0.747, with an average of 0.526. The principal coordinate analysis (PCoA) of the studied soybean collection showed that Kazakhstan accessions were genetically distant from European, East Asian, and North American cultivars. Twelve out of twenty-five SSR markers demonstrated significant associations with ten studied agronomic traits, including PH (p < 0.05). Six SSRs with pleiotropic effects for studied traits were selected, and their haplotypes with phenotypic effects were generated for each soybean accession. The obtained results can be used in soybean improvement programs, including molecular-assisted breeding projects.

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Section: Analysis Of Population Structure and Polymorphism Level In T...supporting

confidence: 70%

Genetic Diversity Analysis of Soybean Collection Using Simple Sequence Repeat Markers

Zatybekov,

Yermagambetova,

Genievskaya

et al. 2023

Plants

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“…Q1 contained most of the R-lines (pollinators), while Q2 possessed all Blines except for one R-line (Fig 3A and 3B). Individuals with a score for clusters membership coefficient more than 0.80 are considered as pure, while those who scored less than 0.80 was considered as admixture [41,42]. In the case of the R-lines cluster (Q1), 67 accessions were identified, out of which 58 were pure and nine were admixtures.…”

Section: Bayesian Model-based Population Stratificationmentioning

confidence: 99%

Understanding genetic diversity in drought-adaptive hybrid parental lines in pearl millet

Kandarkar,

Palaniappan,

Satpathy

et al. 2024

PLoS ONE

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Information on genetic diversity and population structure is helpful to strategize enhancing the genetic base of hybrid parental lines in breeding programs. The present study determined the population structure and genetic diversity of 109 pearl millet hybrid parental lines, known for their better adaptation and performance in drought-prone environments, using 16,472 single nucleotide polymorphic (SNP) markers generated from GBS (genotyping-by-sequencing) platforms. The SNPs were distributed uniformly across the pearl millet genome and showed considerable genetic diversity (0.337), expected heterozygosity (0.334), and observed heterozygosity (0.031). Most of the pairs of lines (78.36%) had Identity-by-State (IBS) based genetic distances of more than 0.3, indicating a significant amount of genetic diversity among the parental lines. Bayesian model-based population stratification, neighbor-joining phylogenetic analysis, and principal coordinate analysis (PCoA) differentiated all hybrid parental lines into two clear-cut major groups, one each for seed parents (B-lines) and pollinators (R-lines). Majority of parental lines sharing common parentages were found grouped in the same cluster. Analysis of molecular variance (AMOVA) revealed 7% of the variation among subpopulations, and 93% of the variation was attributable to within sub-populations. Chromosome 3 had the highest number of LD regions. Genomic LD decay distance was 0.69 Mb and varied across the different chromosomes. Genetic diversity based on 11 agro-morphological and grain quality traits also suggested that the majority of the B- and R-lines were grouped into two major clusters with few overlaps. In addition, the combined analysis of phenotypic and genotypic data showed similarities in the population grouping patterns. The present study revealed the uniqueness of most of the inbred lines, which can be a valuable source of new alleles and help breeders to utilize these inbred lines for the development of hybrids in drought-prone environments.

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“…In addition to being used for genetic diversity analysis [12], molecular markers can also be used in gene mapping analysis [34,35], fingerprinting analysis [36], and mutant gene detection [37]. The use of molecular markers in soybean genetic diversity analysis was carried out in previous studies including Rani et al [38] on 96 soybean accessions with 96 SSR and EST-SSR markers, Jain et al [39] on 24 soybean genotypes with 18 RAPD markers, Sulistyo et al [40] on 40 soybean accessions with 13 SSR markers, Slamet et al [41] on 40 soybean genotypes using 20 SSR markers, and Agam et al [42] on 11 mutant soybean genotypes with 12 RAPD markers.…”

Section: Introductionmentioning

confidence: 99%

Diversity Analysis of 53 Soybean Accessions Introduced from China Based on Morphological Characteristics and SSR Markers

Dyah,

Wibisono,

Terryana

et al. 2024

Curr. Appl. Sci. Technol.

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Indonesia still faces challenges in meeting its national soybean demand. Genetic diversity can provide new resources to improve soybean production and quality. Genetic diversity of 53 soybean accessions introduced from China, based on morphological characteristics and 17 SSR markers, was analyzed in this study. Principal component analysis (PCA) conducted on morphological characters produced a total diversity value of 64.67% and identified four main components. Based on phylogenetic analysis and principal coordinate analysis (PCoA) two accessions showed low genetic similarity of 78% (China cult-55 and Mi yang niu mao huang), which indicated that they could be selected as parents for plant breeding programs. In addition, 772 SSR alleles at an average of 45 alleles per locus were detected. The average heterozygosity was 0.83, and the average polymorphic information content (PIC) value was 0.96. All SSR markers showed a PIC value > 0.8, indicating their informativeness in analyzing genetic diversity of soybean. The phylogenetic analysis indicated a genetic similarity of 82% and the accessions were grouped into two main clusters. The phylogenetic analysis depicted that several accessions could be grouped based on the growth type and origin. The results of morphological characterization and molecular markers in the analysis of genetic diversity are beneficial for selecting parental crosses when developing new varieties.

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Genetic diversity and population structure analysis in cultivated soybean (Glycine max [L.] Merr.) using SSR and EST-SSR markers

Cited by 8 publications

References 56 publications

Genetic Diversity Analysis of Soybean Collection Using Simple Sequence Repeat Markers

Genetic Diversity Analysis of Soybean Collection Using Simple Sequence Repeat Markers

Understanding genetic diversity in drought-adaptive hybrid parental lines in pearl millet

Diversity Analysis of 53 Soybean Accessions Introduced from China Based on Morphological Characteristics and SSR Markers

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