Genetic parameters and gain from selection in sweet potato genotypes with high beta-carotene content

Otoboni, Maria Eduarda Facioli; Oliveira, Darllan Junior Luiz Santos Ferreira de; Vargas, Pablo Forlán; Pavan, Bruno Ettore; Andrade, M.I.

doi:10.1590/1984-70332020v20n3a42

Cited by 8 publications

(7 citation statements)

References 22 publications

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“…High heritability is essential for successful selection, allowing breeders to use the most appropriate selection strategies (OTOBONI et al, 2020). Heritability in sweet potatoes is important because dominance and epistatic effects are maintained by vegetative propagation (GONÇALVES NETO et al, 2012).…”

Section: Resultsmentioning

confidence: 99%

Agronomic Characterization of Sweet Potato Genotypes Obtained Through Crossbreeding

et al. 2022

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The average national sweet potato yield of Brazil falls below the productive potential of the crop because of the cultivation of local and unimproved varieties. To improve this, more productive cultivars must be adopted along with adequate culture treatments. This study was conducted between January and May 2019 in Selvíria, Mato Grosso do Sul, Brazil, to characterize sweet potato genotypes obtained through crossbreeding. The experimental design consisted of randomized blocks containing 264 genotypes, the control (‘Beauregard’), and two replicates. Plant harvesting began 127 d after planting. After harvesting, the roots were washed and dried in a covered area ready for evaluation. The total, commercial, and non-commercial yield; total, commercial, and non-commercial root number; root dry matter content; and dry matter productivity were evaluated. The genotypes CERAT16-20, CERAT31-1, and CERAT21-2 are promising in terms of root production for household consumption because of their high productivity of commercial roots. In contrast, genotypes CERAT16-20, CERAT31-1, CERAT25-17, CERAT25-12, CERAT21-2, CERAT29-26, CERAT34- 4, CERAT31-11, and CERAT24-8 are promising for industry because of the high production of dry mass per hectare. The main components, total number of commercial roots, production of non-commercial roots, mass of commercial roots, total production of dry mass of roots, mass of roots, and total production of roots have a low contribution to the discrimination of the genotypes; therefore, their analysis can be discarded in future studies, under the same soil and climate conditions, thus reducing workload, expense, and time.

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Section: Resultsmentioning

confidence: 99%

Agronomic Characterization of Sweet Potato Genotypes Obtained Through Crossbreeding

et al. 2022

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“…MY, RDM, and FC were considered the major characteristics of marketable roots, with FC representing the core trait-of-interest in the present study, which aimed at selecting high-yielding and highly adaptive genotypes with a high β-carotene content (indicated by orange flesh color). As this study focuses on household consumption, RDM was selected to meet the preferences of Brazilian consumers', who favor sweetpotatoes with a high dry matter content (Otoboni, Oliveira, Vargas, Pavan, & Andrade, 2020).…”

Section: Methodsmentioning

confidence: 99%

Genotype × environment interaction for the agronomic performance of high β-carotene sweetpotato

et al. 2022

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Sweetpotato (Ipomoea batatas L.) is an important tuber vegetable for human health worldwide owing to its nutritional value and productivity. Consumption of orange-fleshed sweetpotato is beneficial to combat vitamin A deficiency in the world, including Brazil, as these tubers are rich in β-carotene, a precursor of vitamin A. The genotype × environment interaction is one of the greatest challenges in plant breeding, specifically in the selection and approval of cultivars. In this context, adaptability and stability analyses are warranted to evaluate the performance of various genotypes in terms of general or specific adaptations to certain environments and to identify genotypes responsive to environmental variations. Thus, the objective of this study was to evaluate the genotype × environment interaction as well as to estimate the adaptability and stability of sweetpotato genotypes for identifying and selecting promising candidates for breeding. The experiments were performed in four environments: Vera Cruz in São Paulo, Selvíria in Mato Grosso do Sul, and one organic and another intercropped production system in Sete Barras in São Paulo. A randomized block design with two replicates was adopted. A total of 265 genotypes were tested, and the orange-fleshed sweetpotato cultivar ‘Beauregard’ was used as the control. The additive main effects and multiplicative interaction model was used to study environmental stratification, adaptability, and stability. The genotype × environment interaction was evident in all environments. The genotypes CERAT21-13 (marketable root yield, 22.30 t ha-1 in the four environments), CERAT29-26 (27.74 t ha-1), and CERAT52-22 (20.24 t ha-1) were the most adapted in general to the four environments. CERAT25-23, CERAT29-23, and CERAT29-26 were the most adapted to the environment in Vera Cruz; CERAT29-26, CERAT34-14, and CERAT56-32 to the environment in Selvíria; and CERAT31-10, CERAT35-19, and CERAT52-22 to the two environments in Sete Barras.

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“…A successful breeding program for SP implies a careful selection of germplasms (genetic diversity) and the systematic evaluation of phenotypic traits (ideotypes) sensitive to environmental stressors and crop agronomic performance indicators [ 32 , 33 , 34 ]. It is noteworthy that genetic breeding programs aiming to produce new SP varieties remain challenged since it is an allohexaploid crop [ 5 , 26 , 27 , 28 ] with a large chromosome number (2n = 6x = 90), a complex sporophytic self-and cross-incompatibility and a high degree of genomic duplication [ 35 , 36 ].…”

Section: Introductionmentioning

confidence: 99%

“…The total/specific content of carotenoids (provitamin A) in SP varies substantially by plant part, varietal (genotype/phenotype), and food processing. In general, SP is recognized as an excellent source of provitamin A (β > α carotenes, 829-43200 IU) [ 20 , 21 , 32 , 60 ]. Orange-fleshed SP (OFSP; Figure 1 ) stands as the best SP source of β-carotene and total carotenoids, and certain varietals, such as Tomlins, Owori, Bechoff, Menya, and Westby varietals rank higher (20–364 µg/g DW) than other recognized β-carotene sources such as carrots (43.5–88.4 µg·g −1 dw) or mango (10.9–12.1 µg·g −1 dw) [ 61 ].…”

Section: Introductionmentioning

confidence: 99%

Sweet Potato (Ipomoea batatas L.) Phenotypes: From Agroindustry to Health Effects

Escobar-Puentes

Palomo

Rodríguez

et al. 2022

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Sweet potato (SP; Ipomoea batatas (L.) Lam) is an edible tuber native to America and the sixth most important food crop worldwide. China leads its production in a global market of USD 45 trillion. SP domesticated varieties differ in specific phenotypic/genotypic traits, yet all of them are rich in sugars, slow digestible/resistant starch, vitamins, minerals, bioactive proteins and lipids, carotenoids, polyphenols, ascorbic acid, alkaloids, coumarins, and saponins, in a genotype-dependent manner. Individually or synergistically, SP’s phytochemicals help to prevent many illnesses, including certain types of cancers and cardiovascular disorders. These and other topics, including the production and market diversification of raw SP and its products, and SP’s starch as a functional ingredient, are briefly discussed in this review.

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Genetic parameters and gain from selection in sweet potato genotypes with high beta-carotene content

Cited by 8 publications

References 22 publications

Agronomic Characterization of Sweet Potato Genotypes Obtained Through Crossbreeding

Agronomic Characterization of Sweet Potato Genotypes Obtained Through Crossbreeding

Genotype × environment interaction for the agronomic performance of high β-carotene sweetpotato

Sweet Potato (Ipomoea batatas L.) Phenotypes: From Agroindustry to Health Effects

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