Morphological and microsatellite marker-based characterization and diversity analysis of novel vegetable soybean [Glycine max (L.) Merrill].

BACKGROUND: Vegetable soybean seeds are among the most popular and nutrient-dense beans in the world due to their delicious flavor, high yield, superior nutritional value, and low trypsin content. There is significant potential for this crop that Indian farmers do not fully appreciate because of the limited germplasm range. Therefore, the current study aims to identify the diverse lines of vegetable soybean and explore the diversity produced by hybridizing grain and vegetable-type soybean varieties. Indian researchers have not yet published work describing and analysing novel vegetable soybean for microsatellite markers and morphological traits. METHODS AND RESULTS: Sixty polymorphic SSR markers and 19 morphological traits were used to evaluate the genetic diversity of 21 newly developed vegetable soybean genotypes. A total of 238 alleles, ranging from 2 to 8, were found, with a mean of 3.97 alleles per locus. The polymorphism information content varied from 0.05 to 0.85, with an average of 0.60. A variation of 0.25-0.58 with a mean of 0.43 was observed for Jaccard's dissimilarity coefficient. CONCLUSION: The diverse genotypes identified can be helpful to understand the genetics of vegetable soybean traits and can be used in improvement programs; study also explains the utility of SSR markers for diversity analysis of vegetable soybean. Here, we identified the highly informative SSRs with PIC > 0.80 (satt199, satt165, satt167, satt191, satt183, satt202, and satt126), which apply to genetic structure analysis, mapping strategies, polymorphic marker surveys, and background selection in genomics-assisted breeding.

Genetics and mapping of seed coat impermeability in soybean using inter-specific populations.

Seed coat impermeability (SCI) in soybean is associated with seed viability under storage and quality of processed products. Understanding genetics and identification of linked molecular markers would facilitate need-based utilization of seed coat impermeability. Two impermeable wild type (G. soja Sieb. and Zucc.) accessions viz. PI 424079 and PI 136620 were crossed with a permeable cultivated (G. max) variety JS335 to generate the mapping populations. Genetic analysis of the F1:2 and F2:3 seeds of the crosses indicated that SCI is controlled by a single gene/major QTL, and impermeability is dominant over permeability. Presence of seeds with intermediate permeability indicated role of some minor genes/QTLs. A set of 204 inter-specific recombinant inbred line (RILs) (F7) was used to map SCI with 207 SSR markers. Phenotyping through rapid imbibition approach (seed imbibition for 6 h), seven QTLs were mapped on chromosomes (Chrs.) 2, 5, 12, 13 and 16 in the seeds stored for 1-3 years, while through slow imbibition method (seed imbibition for 7 days), five QTLs were mapped on Chrs. 2, 9, 10 and 20. Phenotypic variation explained (PVE) by the QTLs ranged from 5.96 to 39.67%. Two major and stable QTLs viz., qScI-h2-1 and qScI-h2-2 that mapped in tandem on Chr.2 jointly explained 43.09-62.92% of the variations in impermeability. Seven minor QTLs identified here were novel and two (qScI-h5, and qScI-h16) were consistent. It is the first report of mapping impermeability using two imbibition approaches together in 200 plus inter-specific RILs in soybean. The study will pave the way for developing genotypes with restricted permeability, enhanced seed viability, and improved seeds quality.