Automation in accession classification of Brazilian Capsicum germplasm through artificial neural networks

Ferreira, Mariane Gonçalves; Azevedo, Alcinei Místico; Siman, Luhan I.; Silva, Gustavo Henrique da; Carneiro, Cristiana Leonor da Silva; Alves, Flávia Maria; Delazari, Fábio Teixeira; Silva, Derly José Henriques da; Nick, Carlos

doi:10.1590/1678-992x-2015-0451

Cited by 5 publications

(4 citation statements)

References 16 publications

(22 reference statements)

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“…Breeding for desired traits in crops has long been a time-consuming, labor-intensive, and expensive process. Breeders study generations of plants and identify and modify desired genetic traits, as they assess how traits are expressed in offspring [ 57 , 58 ]. The application of computational intelligence and machine learning to identify optimal suites of observable characteristics (phenotypes) can enable informed decisions and achieve outcomes of great relevance in breeding programs.…”

Section: Resultsmentioning

confidence: 99%

Prediction of the importance of auxiliary traits using computational intelligence and machine learning: A simulation study

Silva

Cruz

et al. 2021

PLoS ONE

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The present study evaluated the importance of auxiliary traits of a principal trait based on phenotypic information and previously known genetic structure using computational intelligence and machine learning to develop predictive tools for plant breeding. Data of an F2 population represented by 500 individuals, obtained from a cross between contrasting homozygous parents, were simulated. Phenotypic traits were simulated based on previously established means and heritability estimates (30%, 50%, and 80%); traits were distributed in a genome with 10 linkage groups, considering two alleles per marker. Four different scenarios were considered. For the principal trait, heritability was 50%, and 40 control loci were distributed in five linkage groups. Another phenotypic control trait with the same complexity as the principal trait but without any genetic relationship with it and without pleiotropy or a factorial link between the control loci for both traits was simulated. These traits shared a large number of control loci with the principal trait, but could be distinguished by the differential action of the environment on them, as reflected in heritability estimates (30%, 50%, and 80%). The coefficient of determination were considered to evaluate the proposed methodologies. Multiple regression, computational intelligence, and machine learning were used to predict the importance of the tested traits. Computational intelligence and machine learning were superior in extracting nonlinear information from model inputs and quantifying the relative contributions of phenotypic traits. The R2 values ranged from 44.0% - 83.0% and 79.0% - 94.0%, for computational intelligence and machine learning, respectively. In conclusion, the relative contributions of auxiliary traits in different scenarios in plant breeding programs can be efficiently predicted using computational intelligence and machine learning.

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Section: Resultsmentioning

confidence: 99%

Prediction of the importance of auxiliary traits using computational intelligence and machine learning: A simulation study

Silva

Cruz

et al. 2021

PLoS ONE

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“…Genetic improvement for desired traits in different crops has been a time-consuming, laborious and expensive process. Breeders study generations of plants and identify and modify desired genetic traits as they assess how traits are expressed in offspring [27]. The application of computational intelligence and machine learning to identify ideal sets of observable characteristics (phenotypes) can allow informed decisions and achieve highly relevant results in breeding programs.…”

Section: Discussionmentioning

confidence: 99%

“…It is noteworthy that the characteristics used in this study are di cult to obtain and their evaluation can be costly if there is a greater number of genotypes to be evaluated. In this context, the study of the most important characteristics in the prediction becomes necessary, since it is possible to reduce the physical effort, cost, use of labor, and time in the experimentation [27].…”

Section: Discussionmentioning

confidence: 99%

Computational Intelligence to Study the Importance of Predictors in White Oat ( <i>Avena Sativa</i> L.)

Júnior¹,

Sant’Anna²,

Silva³

et al. 2021

SSRN Journal

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“…The Federal University of Viçosa (UFV) has a germplasm collection with about 860 tomato subsamples from six different species (Silva et al, 2001). This collection is the genetic basis for UFV tomato pre-breeding programs and has been widely used to search for genes that confer resistance to pests and diseases (Oliveira et al, 2009;Aguilera et al, 2011aAguilera et al, , b, 2014Ferreira et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

The combination of data as a strategy to determine the diversity of tomato subsambples

Aguilera¹,

Marim²,

Setotaw³

et al. 2019

Amaz. Jour. of Plant Resear.

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The estimation of genetic diversity by qualitative, quantitative, and molecular data and their combination are important in characterizing germplasm collections for pre-breeding purposes, mainly for the identification of divergent parents. For this purpose, we assessed a population of 94 tomato subsamples from UFV Vegetable Germplasm Bank (BGH-UFV) using 10 ISSR markers and agronomic data (three qualitative and six quantitative traits). Data revealed the existence of genetic diversity in germplasm considering the three data classes. Principal coordinates analysis (PCoA) confirmed the genetic variability of the subsamples, explaining 27% of the variability in the first two PCoAs. The Bayesian based clustering analyses using the STRUTURE software verified the existence of a structured population, with three populations. The mantel test for the correlation produced by the three data classes showed highly significant correlation (r = 0.31, P<0.001) among quantitative and molecular data. The Tocher method of clustering for each dissimilarity matrices showed that the clustering patterns were dependent on the data classes. According to the results we found, it is possible to predict the best combinations of parents that can provide maximum gain in a breeding program. Besides the combine use of the quantitative, qualitative and molecular data, using multivariate and Bayesian method of clustering is an efficient method to study the genetic diversity of tomato plants in the germplasm bank.

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Automation in accession classification of Brazilian Capsicum germplasm through artificial neural networks

Cited by 5 publications

References 16 publications

Prediction of the importance of auxiliary traits using computational intelligence and machine learning: A simulation study

Prediction of the importance of auxiliary traits using computational intelligence and machine learning: A simulation study

Computational Intelligence to Study the Importance of Predictors in White Oat ( <i>Avena Sativa</i> L.)

The combination of data as a strategy to determine the diversity of tomato subsambples

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