Genetic Architecture Underpinning Yield Components and Seed Mineral–Nutrients in Sesame

Teboul, Naama; Gadri, Yaron; Berkovich, Zipi; Reifen, Ram; Peleg, Zvi

doi:10.3390/genes11101221

Cited by 20 publications

(27 citation statements)

References 56 publications

(78 reference statements)

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“…The advantage of using a diversity panel to detect new alleles is exemplified by comparing our results with a bi-parental population that was grown under the same environmental conditions. While Teboul et al [ 3 ] detected six QTLs using the F 2 population (S-91 × S-297), only the genomic region on LG11 was overlap with the current study.…”

Section: Discussioncontrasting

confidence: 59%

“…Sesame is an annual diploid (2n = 2x = 26) species, which belongs to the Sesamum genus from the Pedaliaceae family. Its seeds are comprised of oil (45–60%), proteins (18-25%), carbohydrates (3-25%), and are rich in essential vitamins and mineral-nutrients [ 2 , 3 ]. The seeds are being used for an array of products in the food (e.g., high-quality oil, tahini paste, and cooking and backing) and pharmaceutical industries [ 4 ].…”

Section: Introductionmentioning

confidence: 99%

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Genome-wide association analysis uncovers the genetic architecture of tradeoff between flowering date and yield components in sesame

2021

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Background Unrevealing the genetic makeup of crop morpho-agronomic traits is essential for improving yield quality and sustainability. Sesame (Sesamum indicum L.) is one of the oldest oil-crops in the world. Despite its economic and agricultural importance, it is an ‘orphan crop-plant’ that has undergone limited modern selection, and, as a consequence preserved wide genetic diversity. Here we established a new sesame panel (SCHUJI) that contains 184 genotypes representing wide phenotypic variation and is geographically distributed. We harnessed the natural variation of this panel to perform genome-wide association studies for morpho-agronomic traits under the Mediterranean climate conditions. Results Field-based phenotyping of the SCHUJI panel across two seasons exposed wide phenotypic variation for all traits. Using 20,294 single-nucleotide polymorphism markers, we detected 50 genomic signals associated with these traits. Major genomic region on LG2 was associated with flowering date and yield-related traits, exemplified the key role of the flowering date on productivity. Conclusions Our results shed light on the genetic architecture of flowering date and its interaction with yield components in sesame and may serve as a basis for future sesame breeding programs in the Mediterranean basin.

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Section: Discussioncontrasting

confidence: 59%

Section: Introductionmentioning

confidence: 99%

Genome-wide association analysis uncovers the genetic architecture of tradeoff between flowering date and yield components in sesame

2021

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“…The advantage of using a diversity panel to detect new alleles is exemplified by comparing our results with a bi-parental population that was grown under the same environmental conditions. While Teboul et al (2020) detected six QTLs using the F2 population (S-91 × S-297), only the genomic region on LG11 was overlap with the current study.…”

Section: Genetic Architecture Of Agronomical Traits Reveals Hotspot Of Overlapping Genomic Regionscontrasting

confidence: 49%

“…Seed size (TSW) is known to have moderatehigh heritability in sesame (Uzun et al, 2013;Kalaiyarasi et al, 2019), as was found in the current study (0.88) and other crops, such as wheat (Sukumaran et al, 2018) and pea (Pisum sativum L.; Huang et al, 2017), was associated with only one region in 2020, with no overlap with SNPP and SYPP. Likewise, a small number of associated loci for TSW were found in bi-parental sesame populations (Du et al, 2019;Teboul et al, 2020), which may suggest that this trait is under less complex genetic control or under the regulation of many small-effect genomic regions. The absence of significant genomic signs for TSW (as well as other traits in the current study) indicates that other approaches, such as genomic prediction (Crossa et al, 2017), may contribute to understanding its genetic basis.…”

Section: Genetic Architecture Of Agronomical Traits Reveals Hotspot Of Overlapping Genomic Regionsmentioning

confidence: 99%

“…Sesame is an annual diploid (2n=2x=26) species, which belongs to the Sesamum genus from the Pedaliaceae family. Its seeds are comprised of oil (45-60%), proteins (18-25%), carbohydrate (3-25%), and rich with essential vitamins and mineral-nutrients (Anilakumar et al, 2010;Teboul et al, 2020). The seeds are being used for an array of products in the food (e.g., high-quality oil, tahini paste, and cooking and backing) and pharmaceutical industries (Mushtaq, 2020).…”

Section: Introductionmentioning

confidence: 99%

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Genome-wide association uncovers the genetic architecture of tradeoff between flowering date and yield components in sesame

Sabag

Morota

Peleg

2021

Preprint

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Unrevealing the genetic makeup of crop morpho-agronomic traits is essential for improving yield quality and sustainability. Sesame (Sesamum indicum L.), one of the oldest oil-crops in the world, which despite its economical and agricultural importance, is an ‘orphan crop-plant’ that undergone limited modern selection, thus, preserving wide genetic diversity. Here we harnessed this natural variation in a newly developed sesame panel (SCHUJI) to perform genome-wide association studies for morpho-agronomic traits under the Mediterranean climate conditions. Field-based phenotyping of the SCHUJI panel across two seasons exposed wide phenotypic variation for all traits. Using 20,294 single-nucleotide polymorphism markers, we detected 50 genomic signals associated with these traits. Major genomic region on LG2 was associated with flowering date and yield-related traits, exemplified the key role of the flowering date on productivity. Our results shed light on the genetic architecture of flowering date and its interaction with yield components in sesame and may serve as a basis for future sesame breeding programs in the Mediterranean basin.

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Leveraging genomics and temporal high‐throughput phenotyping to enhance association mapping and yield prediction in sesame

Sabag,

Bi,

Sahoo

et al. 2024

The Plant Genome

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Sesame (Sesamum indicum) is an important oilseed crop with rising demand owing to its nutritional and health benefits. There is an urgent need to develop and integrate new genomic‐based breeding strategies to meet these future demands. While genomic resources have advanced genetic research in sesame, the implementation of high‐throughput phenotyping and genetic analysis of longitudinal traits remains limited. Here, we combined high‐throughput phenotyping and random regression models to investigate the dynamics of plant height, leaf area index, and five spectral vegetation indices throughout the sesame growing seasons in a diversity panel. Modeling the temporal phenotypic and additive genetic trajectories revealed distinct patterns corresponding to the sesame growth cycle. We also conducted longitudinal genomic prediction and association mapping of plant height using various models and cross‐validation schemes. Moderate prediction accuracy was obtained when predicting new genotypes at each time point, and moderate to high values were obtained when forecasting future phenotypes. Association mapping revealed three genomic regions in linkage groups 6, 8, and 11, conferring trait variation over time and growth rate. Furthermore, we leveraged correlations between the temporal trait and seed‐yield and applied multi‐trait genomic prediction. We obtained an improvement over single‐trait analysis, especially when phenotypes from earlier time points were used, highlighting the potential of using a high‐throughput phenotyping platform as a selection tool. Our results shed light on the genetic control of longitudinal traits in sesame and underscore the potential of high‐throughput phenotyping to detect a wide range of traits and genotypes that can inform sesame breeding efforts to enhance yield.

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Genetic Architecture Underpinning Yield Components and Seed Mineral–Nutrients in Sesame

Cited by 20 publications

References 56 publications

Genome-wide association analysis uncovers the genetic architecture of tradeoff between flowering date and yield components in sesame

Genome-wide association analysis uncovers the genetic architecture of tradeoff between flowering date and yield components in sesame

Genome-wide association uncovers the genetic architecture of tradeoff between flowering date and yield components in sesame

Leveraging genomics and temporal high‐throughput phenotyping to enhance association mapping and yield prediction in sesame

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