Allelic Diversity of Acetyl Coenzyme A Carboxylase accD/bccp Genes Implicated in Nuclear-Cytoplasmic Conflict in the Wild and Domesticated Pea (Pisum sp.)

Nováková, Eliška; Zablatzká, Lenka; Brus, Jan; Nesrstová, Viktorie; Hanáček, Pavel; Kalendar, Ruslan; Cvrčková, Fatima; Majeský, Ľuboš; Smýkal, Petr

doi:10.3390/ijms20071773

Cited by 14 publications

(9 citation statements)

References 87 publications

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“…The primary gene pool for domesticated pea (Harlan & de Wet, 1971) consists of the P. sativum / elatius complex (Smýkal et al, 2017; Trněný et al, 2018), although because of the existent nuclear–cytoplasmic conflict (Bogdanova, Galieva, & Kosterin, 2009; Nováková et al, 2019), there are some barriers to gene flow. A secondary gene pool (crosses with less success and lower fertility) extends to the other species in the genus, P. fulvum and P. abyssinicum .…”

Section: Peamentioning

confidence: 99%

Potential and limits of exploitation of crop wild relatives for pea, lentil, and chickpea improvement

Coyne¹,

Kumar²,

Wettberg

et al. 2020

Legume Science

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Legumes represent the second most important family of crop plants after grasses, accounting for approximately 27% of the world's crop production. Past domestication processes resulted in a high degree of relatedness between modern varieties of crops, leading to a narrower genetic base of cultivated germplasm prone to pests and diseases. Crop wild relatives (CWRs) harbor genetic diversity tested by natural selection in a range of environments. To fully understand and exploit local adaptation in CWR, studies in geographical centers of origin combining ecology, physiology, and genetics are needed. With the advent of modern genomics and computation, combined with systematic phenotyping, it is feasible to revisit wild accessions and landraces and prioritize their use for breeding, providing sources of disease resistances; tolerances of drought, heat, frost, and salinity abiotic stresses; nutrient densities across major and minor elements; and food quality traits. Establishment of hybrid populations with CWRs gives breeders a considerable benefit of a prebreeding tool for identifying and harnessing wild alleles and provides extremely valuable long-term resources. There is a need of further collecting and both ex situ and in situ conservation of CWR diversity of these taxa in the face of habitat loss and degradation and climate change. In this review, we focus on three legume crops domesticated in the Fertile Crescent, pea, chickpea, and lentil, and summarize the current state and potential of their respective CWR taxa for crop improvement.

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Section: Peamentioning

confidence: 99%

Potential and limits of exploitation of crop wild relatives for pea, lentil, and chickpea improvement

Coyne¹,

Kumar²,

Wettberg

et al. 2020

Legume Science

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“…from P. sativum L. but had a 0.76% divergence in between Pisum abyssinicum A. Braun and P. sativum L. Interestingly, accD emerged as one of the few regions with sufficient variability to discriminate among closely related species. Previous work has documented high variability due to insertions of tandem repeats and has linked the region to nuclear-cytoplasmic conflict in the wild and domesticated pea ( Nováková et al, 2019 ). Additionally, fragmentation and deletion of this region has been documented in several plant plastid genomes, with accD being completely deleted in the maize and wheat plastomes, and partially in rice ( Maier et al, 1995 ; Harris et al, 2013 ).…”

Section: Resultsmentioning

confidence: 99%

Validation of a Triplex Quantitative Polymerase Chain Reaction Assay for Detection and Quantification of Traditional Protein Sources, Pisum sativum L. and Glycine max (L.) Merr., in Protein Powder Mixtures

et al. 2021

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Several botanicals have been traditionally used as protein sources, including the leguminous Pisum sativum L. and Glycine max (L.) Merr. While a rich history exists of cultivating these plants for their whole, protein-rich grain, modern use as powdered supplements present a new challenge in material authentication. The absence of clear morphological identifiers of an intact plant and the existence of long, complex supply chains behoove industry to create quick, reliable analytical tools to identify the botanical source of a protein product (many of which contain multiple sources). The utility of molecular tools for plant-based protein powder authentication is gaining traction, but few validated tools exist. Multiplex quantitative polymerase chain reaction (qPCR) can provide an economical means by which sources can be identified and relative proportions quantified. We followed established guidelines for the design, optimization, and validation of qPCR assay, and developed a triplex qPCR assay that can amplify and quantify pea and soy DNA targets, normalized by a calibrator. The assay was evaluated for analytical specificity, analytical sensitivity, efficiency, precision, dynamic range, repeatability, and reproducibility. We tested the quantitative ability of the assay using pea and soy DNA mixtures, finding exceptional quantitative linearity for both targets – 0.9983 (p < 0.0001) for soy and 0.9915 (p < 0.0001) for pea. Ratios based on mass of protein powder were also tested, resulting in non-linear patterns in data that suggested the requirement of further sample preparation optimization or algorithmic correction. Variation in fragment size within different lots of commercial protein powder samples was also analyzed, revealing low SD among lots. Ultimately, this study demonstrated the utility of qPCR in the context of protein powder mixtures and highlighted key considerations to take into account for commercial implementation.

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“…truncatula., harbors the AccA locus coding for alpha subunit of carboxyltransferase of acetyl-CoA carboxylase [91]. Allelic polymorphism in the candidate genes was extensively studied [92].…”

Section: Molecular Genetic Analysis Of Nuclear-plastid Incompatibilitmentioning

confidence: 99%

Genetic and Molecular Genetic Basis of Nuclear-Plastid Incompatibilities

Богданова

2019

Plants

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Genetic analysis of nuclear-cytoplasm incompatibilities is not straightforward and requires an elaborated experimental design. A number of species have been genetically studied, but notable advances in genetic mapping of nuclear loci involved in nuclear-plastid incompatibility have been achieved only in wheat and pea. This review focuses on the study of the genetic background underlying nuclear-plastid incompatibilities, including cases where the molecular genetic basis of such incompatibility has been unveiled, such as in tobacco, Oenothera, pea, and wheat.

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Allelic Diversity of Acetyl Coenzyme A Carboxylase accD/bccp Genes Implicated in Nuclear-Cytoplasmic Conflict in the Wild and Domesticated Pea (Pisum sp.)

Cited by 14 publications

References 87 publications

Potential and limits of exploitation of crop wild relatives for pea, lentil, and chickpea improvement

Potential and limits of exploitation of crop wild relatives for pea, lentil, and chickpea improvement

Validation of a Triplex Quantitative Polymerase Chain Reaction Assay for Detection and Quantification of Traditional Protein Sources, Pisum sativum L. and Glycine max (L.) Merr., in Protein Powder Mixtures

Genetic and Molecular Genetic Basis of Nuclear-Plastid Incompatibilities

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