Quantitative trait loci associated with amino acid concentration and in vitro protein digestibility in pea (Pisum sativum L.)

Zhou, Junsheng; Wan, Zhongyang; Gali, Krishna Kishore; Jha, Alok; Nickerson, Michael T.; House, James D.; Tar’an, Bunyamin; Warkentin, Thomas D.

doi:10.3389/fpls.2023.1083086

Cited by 4 publications

(1 citation statement)

References 35 publications

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“…While the effects of the R locus (wrinkling of seeds) are easily observable, other loci governing seed nutrition, such as the Low-phytate ( Lpa ) locus for phytic acid synthesis (Shunmugam et al 2015 ), the VicB locus for vicilin control (Lycett et al 1983 ), and the Pea Albumin 1 ( PA1 ) and Pea Albumin 2 ( PA2 ) loci for albumin regulation (Eyraud et al 2013 ; Vigeolas et al 2008 ), have received foundational research attention but prove challenging for current breeding applications. Recently, Zhou et al utilized the recombinant inbred line population PR-25 to identify several QTLs associated with amino acid concentration and in vitro protein digestibility in peas (Zhou et al 2023 ). In contrast, traits affecting the morphology of pea seeds, which are readily visible, are more easily harnessed in breeding.…”

Section: Seeds and Podsmentioning

confidence: 99%

Innovations in functional genomics and molecular breeding of pea: exploring advances and opportunities

Chen,

Shi,

Sun

et al. 2024

aBIOTECH

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The garden pea (Pisum sativum L.) is a significant cool-season legume, serving as crucial food sources, animal feed, and industrial raw materials. The advancement of functional genomics over the past two decades has provided substantial theoretical foundations and progress to pea breeding. Notably, the release of the pea reference genome has enhanced our understanding of plant architecture, symbiotic nitrogen fixation (SNF), flowering time, floral organ development, seed development, and stress resistance. However, a considerable gap remains between pea functional genomics and molecular breeding. This review summarizes the current advancements in pea functional genomics and breeding while highlighting the future challenges in pea molecular breeding.

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Section: Seeds and Podsmentioning

confidence: 99%

Innovations in functional genomics and molecular breeding of pea: exploring advances and opportunities

Chen,

Shi,

Sun

et al. 2024

aBIOTECH

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Characterizing Dry Pea (Pisum sativum L.) for Improved Nutritional Traits and the Potential for Biofortification

Windsor,

Boatwright,

Boyles

et al. 2024

Legume Science

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Dry pea (Pisum sativum L.) is a highly nutritious cool season food legume or pulse crop within the Fabaceae family that features high levels of protein (20%–25%), prebiotic carbohydrates, and a range of minerals and vitamins. Dry pea is cultivated globally in temperate climates and consumed as a whole food, snack, or protein powder. Dry pea is featured in plant‐based meat items such as the “beyond” branded plant‐based meats. Dry pea is an excellent candidate for plant‐based protein alternatives due to the high protein and low‐fat concentrations present in the mature seed, but improvements are still needed for more widespread use. Breeding efforts are ongoing to further improve dry pea proteins' quality, quantity, and digestibility through biofortification. Global dry pea germplasm contains a wide array of accessions that are vital for dry pea breeding efforts focused on developing cultivars enriched with the most bioavailable forms of plant‐based proteins. The objective of this review is to summarize prior research exploring the factors that contribute to the nutritional value of the dry pea—especially protein quality and quantity.

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Epistasis and pleiotropy‐induced variation for plant breeding

Dwivedi,

Heslop‐Harrison,

Amas

et al. 2024

Plant Biotechnology Journal

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SummaryEpistasis refers to nonallelic interaction between genes that cause bias in estimates of genetic parameters for a phenotype with interactions of two or more genes affecting the same trait. Partitioning of epistatic effects allows true estimation of the genetic parameters affecting phenotypes. Multigenic variation plays a central role in the evolution of complex characteristics, among which pleiotropy, where a single gene affects several phenotypic characters, has a large influence. While pleiotropic interactions provide functional specificity, they increase the challenge of gene discovery and functional analysis. Overcoming pleiotropy‐based phenotypic trade‐offs offers potential for assisting breeding for complex traits. Modelling higher order nonallelic epistatic interaction, pleiotropy and non‐pleiotropy‐induced variation, and genotype × environment interaction in genomic selection may provide new paths to increase the productivity and stress tolerance for next generation of crop cultivars. Advances in statistical models, software and algorithm developments, and genomic research have facilitated dissecting the nature and extent of pleiotropy and epistasis. We overview emerging approaches to exploit positive (and avoid negative) epistatic and pleiotropic interactions in a plant breeding context, including developing avenues of artificial intelligence, novel exploitation of large‐scale genomics and phenomics data, and involvement of genes with minor effects to analyse epistatic interactions and pleiotropic quantitative trait loci, including missing heritability.

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Quantitative trait loci associated with amino acid concentration and in vitro protein digestibility in pea (Pisum sativum L.)

Cited by 4 publications

References 35 publications

Innovations in functional genomics and molecular breeding of pea: exploring advances and opportunities

Innovations in functional genomics and molecular breeding of pea: exploring advances and opportunities

Characterizing Dry Pea (Pisum sativum L.) for Improved Nutritional Traits and the Potential for Biofortification

Epistasis and pleiotropy‐induced variation for plant breeding

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