QTLs Regulating the Contents of Antioxidants, Phenolics, and Flavonoids in Soybean Seeds Share a Common Genomic Region

Li, Man-Wah; Muñoz, Nacira; Wong, Chi-Fai; Wong, Fuk‐Ling; Wong, Kwong-Sen; Wong-Bajracharya, Johanna; Qi, Xiaofeng; Li, Kwan-Pok; Ng, Ming‐Sin; Lam, Hon‐Ming

doi:10.3389/fpls.2016.00854

Cited by 26 publications

(43 citation statements)

References 39 publications

(56 reference statements)

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“…A QTL analysis of the determinants of floral color in cowpea was performed in a biparental mapping population (wild × cultivated crosses; Lo et al, 2018). A single major QTL for floral color, CFcol7, was mapped in a 64-cM region on chromosome Vu07 containing 254 annotated genes, among which a transcription factor, Vigun07g110700, was identified as a homolog of Arabidopsis AT4G09820.1 and Medicago truncatula (Mt) TT8, involved in the regulation of flavonoid biosynthesis (Nesi et al, 2000;Li et al, 2016). In soybean, one QTL for floral pigmentation was identified on linkage group G (Josie et al, 2007).…”

Section: Pigmentation-related Traitsmentioning

confidence: 99%

“…ATP-binding cassette transporters and multidrug and toxic compound extrusion transporters play important roles in the secretion and accumulation of secondary metabolites (Yazaki, 2005;Ku et al, 2020). These transporters are associated with microbe interaction and nutrient accumulation of legumes (Sugiyama et al, 2007;Zhang et al, 2010;Fondevilla et al, 2011;Li et al, 2016).…”

Section: Transportersmentioning

confidence: 99%

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The Effects of Domestication on Secondary Metabolite Composition in Legumes

Contador

et al. 2020

Front. Genet.

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Legumes are rich in secondary metabolites, such as polyphenols, alkaloids, and saponins, which are important defense compounds to protect the plant against herbivores and pathogens, and act as signaling molecules between the plant and its biotic environment. Legume-sourced secondary metabolites are well known for their potential benefits to human health as pharmaceuticals and nutraceuticals. During domestication, the color, smell, and taste of crop plants have been the focus of artificial selection by breeders. Since these agronomic traits are regulated by secondary metabolites, the basis behind the genomic evolution was the selection of the secondary metabolite composition. In this review, we will discuss the classification, occurrence, and health benefits of secondary metabolites in legumes. The differences in their profiles between wild legumes and their cultivated counterparts will be investigated to trace the possible effects of domestication on secondary metabolite compositions, and the advantages and drawbacks of such modifications. The changes in secondary metabolite contents will also be discussed at the genetic level to examine the genes responsible for determining the secondary metabolite composition that might have been lost due to domestication. Understanding these genes would enable breeding programs and metabolic engineering to produce legume varieties with favorable secondary metabolite profiles for facilitating adaptations to a changing climate, promoting beneficial interactions with biotic factors, and enhancing health-beneficial secondary metabolite contents for human consumption.

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Section: Pigmentation-related Traitsmentioning

confidence: 99%

Section: Transportersmentioning

confidence: 99%

The Effects of Domestication on Secondary Metabolite Composition in Legumes

Contador

et al. 2020

Front. Genet.

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“…(2) Other studies on seed antioxidant, phenolics, and flavonoid contents have identified GmMATE1, 2, 4 genes [29]. Astringent taste in soy products is caused by group A saponins.…”

Section: Other Traitsmentioning

confidence: 99%

“…(6) A phosphatase 2C-1 (PP2C-1) allele has been reported from wild soybean to be involved in seed weight and seed size. Apart from these genes many QTLs related to (7) linolenic acid production, (8) yield, height and maturity, (9) soybean cyst nematode, (10) seed yield, seed weight, seed filling period, maturity, plant height, and lodging, (11) salt tolerance, (12) sclerotinia stem rot, (13) root traits, (14) oil and local breeding, (15) shoot fresh weight, (16) seed antioxidant, phenolics and flavonoids, and many other traits have been mapped and identified from wild soybeans or populations developed by crossing wild and cultivated soybeans [24,29,[34][35][36][37][38][39][40][41]. Taking the advantage of higher genetic diversity and identified genes and QTLs for important traits from wild soybean will gear up the soybean yield improvement in changing climatic conditions and modern dietary demands.…”

Section: Other Traitsmentioning

confidence: 99%

Wild Soybeans: An Opportunistic Resource for Soybean Improvement

Nawaz¹,

Yang²,

Chung³

2018

Rediscovery of Landraces as a Resource for the Future

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Reduced genetic diversity in cultivated soybean coupled with changing dietary expectations, climate change, and increase in population demands expansion of current gene pool. Wild soybeans are an opportunistic resource and a rational choice to discover novel genes and gene families for alternative crop production systems and to improve soybean. Multiple agronomic traits, lineage-specific genes, and domestication-related traits have been studied in wild soybeans in contrast to cultivated soybeans, and it has been proved that wild soybeans are an essential genomic resource containing unique and useful genetic resources that have been lost during domestication to expand the gene pool in order to improve soybean. Wild soybean is very often a plant of disturbed habitats of Southeast Asia. The vulnerability of these habitats to agriculture systems and urban expansion causes a reduction in the area of distribution and hence the diversity. To capture the wild soybean genetic diversity in its main distribution areas, a unique and comprehensive germplasm collection, characterization, and conservation platform is direly needed. Chung's Wild Legume Germplasm Collection is preserving and maintaining a representative wild soybean germplasm collection guided by the principles of conservation genetics. These wild legumes and particularly wild soybean is a promising genetic resource for soybean breeders.

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“…In soy, the content and composition of isoflavonoids are subjected to polygenic regulation and highly variable in response to drought, temperature, fertilization, carbon dioxide content and genetic factors [13]. The level of isoflavonoids is higher in wild-growing populations than in cultivated soybean; this situation is thought to be a consequence of domestication [14].…”

Section: Biosynthesis and Regulationmentioning

confidence: 99%

New Insights Regarding the Potential Health Benefits of Isoflavones

Danciu¹,

Suciu²,

Antal³

et al. 2017

Flavonoids - From Biosynthesis to Human Health

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Isoflavones are a class of plant secondary metabolites, with an estrogen-like structure presenting a plethora of biological activities. The chapter discusses important facts about this class of phytoestrogens, from biosynthesis to the latest research about their health benefits. The following major points discussed are: biosynthesis, regulation, isolation, metabolism and bioavailability, isoflavones in diet and intake, and new insights regarding the therapeutic effect including cancer chemoprevention. The chapter ends with a mini review of own research of the anti-inflammatory and chemopreventive activity of isoflavonoid genistein alone and incorporated in modern pharmaceutical formulations. The chapter updates the interested researchers in the field with the latest progress regarding potential health benefits of isoflavones.

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QTLs Regulating the Contents of Antioxidants, Phenolics, and Flavonoids in Soybean Seeds Share a Common Genomic Region

Cited by 26 publications

References 39 publications

The Effects of Domestication on Secondary Metabolite Composition in Legumes

The Effects of Domestication on Secondary Metabolite Composition in Legumes

Wild Soybeans: An Opportunistic Resource for Soybean Improvement

New Insights Regarding the Potential Health Benefits of Isoflavones

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