Marker-Assisted Development of a Blue-Grained Substitution Line Carrying the Thinopyrum ponticum Chromosome 4Th(4D) in the Spring Bread Wheat Saratovskaya 29 Background

Gordeeva, E. I.; Бадаева, Е. Д.; Yudina, R. S.; Shchukina, L. V.; Shoeva, O. Y.; Khlestkina, Elena K.

doi:10.3390/agronomy9110723

Cited by 10 publications

(7 citation statements)

References 49 publications

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“…The anthocyanin pigmentation in the aleurone layer of the grains was a substituted blue-grain wheat line based on the Saratovskaya 29 variety, carrying the Thinopyrum ponticum (Podp., syn. Agropyron elongatum Host., Elytrigia pontica Podp., Holub) chromosome 4Th instead of chromosome 4D (s:S29_4Th/4D), containing the dominant allele of the Ba gene (Blue aleuron) [ 23 ]. A two-stage crossing was carried out with recurrent promising varieties of Siberian breeding and breeding line BW 49880.…”

Section: Methodsmentioning

confidence: 99%

Antioxidant Capacity and Profiles of Phenolic Acids in Various Genotypes of Purple Wheat

Шаманин

Tekin-Çakmak

Gordeeva

et al. 2022

Foods

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The total phenolic content, phenolic compositions, and antioxidant capacity in the grain of 40 purple wheat genotypes were studied. In this study, purple wheats were investigated in terms of their composition of free and bound phenolic acids and 2,2-diphenyl-1-picrylhydrazyl radical scavenging capacity. The free phenolic content ranged from 164.25 to 271.05 mg GAE/100 g DW and the bound phenolic content was between 182.89–565.62 mg GAE/100 g wheat. The total phenolic content of purple wheat samples ranged from 352.65 to 771.83 mg GAE/100 g wheat. Gallic acid, protocatechuic acid, catechin, 4-hydroxybenzoic acid, syringic acid, ellagic acid, m-coumaric acid, o-coumaric acid, chrysin, caffeic acid, p-coumaric acid, ferulic acid, quercetin, kaempferol, rutin, sinapic acid, and chlorogenic acid were detected by HPLC system. Gallic acid, benzoic acid derivatives, and dominant phenolics, which are frequently found in cereals, were also dominant in purple wheat samples and were found in free fractions. The antioxidant capacity was assessed using the DPPH method. The antioxidant capacity (AA%) in the free phenolic extracts of the purple wheats was between 39.7% and 59.5%, and the AA% values of bound phenolic extract of the purple wheat varied between 42.6% and 62.7%. This study suggested that purple wheat samples have high phenolic compound content as antioxidant potential and therefore consumption of purple wheat-containing food products may provide health benefits.

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Section: Methodsmentioning

confidence: 99%

Antioxidant Capacity and Profiles of Phenolic Acids in Various Genotypes of Purple Wheat

Шаманин

Tekin-Çakmak

Gordeeva

et al. 2022

Foods

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“…Saratovskaya 29 (S29). Blue grains were represented by two wheat-wheatgrass substitution lines S29 BLUE(4Th-4B) and S29 BLUE (4Th-4D) developed in the S29 background but carrying Ba gene-containing wheatgrass chromosome 4Th, which replaced wheat chromosomes 4B and 4D, respectively [25,26]. Black grains were represented by four lines, two of them-S29 BLACK (4Th-4B) and S29 BLACK (4Th-4D)-have been developed previously in the S29 background by crossing the above-mentioned lines with purple-grained near-isogenic wheat line S29 PURPLE Pp-D1Pp3 carrying introgressions in chromosomes 7D and 2A, onto which the dominant alleles of genes Pp-D1 and Pp3, respectively, have been mapped [47,48].…”

Section: Methodsmentioning

confidence: 99%

“…Two blue-grained lines-S29 BLUE (4Th-4B) and S29 BLUE (4Th-4D)are substitution lines where chromosomes 4B and 4D are substituted with Th. ponticum chromosome 4Th carrying the Ba gene determining the blue pigmentation of grains [25,26]. Two deep-purple-grained, i.e., almost black-grained lines-S29 BLACK (4Th-4B) and S29 BLACK (4Th-4D)-in addition to chromosomes 4B and 4D substituted with 4Th, feature introgressions in chromosomes 7D and 2A, where the dominant alleles of genes Pp-D1 and Pp3, respectively, are located [25].…”

Section: Introductionmentioning

confidence: 99%

“…ponticum chromosome 4Th carrying the Ba gene determining the blue pigmentation of grains [25,26]. Two deep-purple-grained, i.e., almost black-grained lines-S29 BLACK (4Th-4B) and S29 BLACK (4Th-4D)-in addition to chromosomes 4B and 4D substituted with 4Th, feature introgressions in chromosomes 7D and 2A, where the dominant alleles of genes Pp-D1 and Pp3, respectively, are located [25]. Two other black-grained lines-BW BLACK (4Th-4D) and E22 BLACK (4Th-4D)-were developed in the genetic background of breeding line BW49880 (BW) and cv.…”

Section: Introductionmentioning

confidence: 99%

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Phytochemical Analysis of Phenolics, Sterols, and Terpenes in Colored Wheat Grains by Liquid Chromatography with Tandem Mass Spectrometry

et al. 2021

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The colored grain of wheat (Triticum aestivum L.) contains a large number of polyphenolic compounds that are biologically active ingredients. The purpose of this work was a comparative metabolomic study of extracts from anthocyaninless (control), blue, and deep purple (referred to here as black) grains of seven genetically related wheat lines developed for the grain anthocyanin pigmentation trait. To identify target analytes in ethanol extracts, high-performance liquid chromatography was used in combination with Bruker Daltonics ion trap mass spectrometry. The results showed the presence of 125 biologically active compounds of a phenolic (85) and nonphenolic (40) nature in the grains of T. aestivum (seven lines). Among them, a number of phenolic compounds affiliated with anthocyanins, coumarins, dihydrochalcones, flavan-3-ols, flavanone, flavones, flavonols, hydroxybenzoic acids, hydroxycinnamic acids, isoflavone, lignans, other phenolic acids, stilbenes, and nonphenolic compounds affiliated with alkaloids, carboxylic acids, carotenoids, diterpenoids, essential amino acids, triterpenoids, sterols, nonessential amino acids, phytohormones, purines, and thromboxane receptor antagonists were found in T. aestivum grains for the first time. A comparative analysis of the diversity of the compounds revealed that the lines do not differ from each other in the proportion of phenolic (53.3% to 70.3% of the total number of identified compounds) and nonphenolic compounds (46.7% to 29.7%), but diversity of the compounds was significantly lower in grains of the control line. Even though the lines are genetically closely related and possess similar chemical profiles, some line-specific individual compounds were identified that constitute unique chemical fingerprints and allow to distinguish each line from the six others. Finally, the influence of the genotype on the chemical profiles of the wheat grains is discussed.

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“…MAS also demonstrated its efficacy in creating barley with certain alleles of anthocyanin regulatory genes [18]. For breeding blue-grained wheat, besides molecular markers, FISH or C-banding are needed since the Ba gene is alien for wheat and can be inherited from wheat lines with either 4B or 4D chromosome substituted by the Thinopyrum ponticum chromosome 4 [96,97]. Unlike bread wheat, barley has its own Ba gene.…”

Section: Phenolic Compounds and Avenanthramidesmentioning

confidence: 99%

Wheat, Barley, and Oat Breeding for Health Benefit Components in Grain

Лоскутов

Khlestkina

2021

Plants

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Cereal grains provide half of the calories consumed by humans. In addition, they contain important compounds beneficial for health. During the last years, a broad spectrum of new cereal grain-derived products for dietary purposes emerged on the global food market. Special breeding programs aimed at cultivars utilizable for these new products have been launched for both the main sources of staple foods (such as rice, wheat, and maize) and other cereal crops (oat, barley, sorghum, millet, etc.). The breeding paradigm has been switched from traditional grain quality indicators (for example, high breadmaking quality and protein content for common wheat or content of protein, lysine, and starch for barley and oat) to more specialized ones (high content of bioactive compounds, vitamins, dietary fibers, and oils, etc.). To enrich cereal grain with functional components while growing plants in contrast to the post-harvesting improvement of staple foods with natural and synthetic additives, the new breeding programs need a source of genes for the improvement of the content of health benefit components in grain. The current review aims to consider current trends and achievements in wheat, barley, and oat breeding for health-benefiting components. The sources of these valuable genes are plant genetic resources deposited in genebanks: landraces, rare crop species, or even wild relatives of cultivated plants. Traditional plant breeding approaches supplemented with marker-assisted selection and genetic editing, as well as high-throughput chemotyping techniques, are exploited to speed up the breeding for the desired genotуpes. Biochemical and genetic bases for the enrichment of the grain of modern cereal crop cultivars with micronutrients, oils, phenolics, and other compounds are discussed, and certain cases of contributions to special health-improving diets are summarized. Correlations between the content of certain bioactive compounds and the resistance to diseases or tolerance to certain abiotic stressors suggest that breeding programs aimed at raising the levels of health-benefiting components in cereal grain might at the same time match the task of developing cultivars adapted to unfavorable environmental conditions.

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Marker-Assisted Development of a Blue-Grained Substitution Line Carrying the Thinopyrum ponticum Chromosome 4Th(4D) in the Spring Bread Wheat Saratovskaya 29 Background

Cited by 10 publications

References 49 publications

Antioxidant Capacity and Profiles of Phenolic Acids in Various Genotypes of Purple Wheat

Antioxidant Capacity and Profiles of Phenolic Acids in Various Genotypes of Purple Wheat

Phytochemical Analysis of Phenolics, Sterols, and Terpenes in Colored Wheat Grains by Liquid Chromatography with Tandem Mass Spectrometry

Wheat, Barley, and Oat Breeding for Health Benefit Components in Grain

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