Enviromic assembly increases accuracy and reduces costs of the genomic prediction for yield plasticity in maize

Quantitative genetics states that phenotypic variation is a consequence of the interaction between genetic and environmental factors. Predictive breeding is based on this statement, and because of this, ways of modeling genetic effects are still evolving. At the same time, the same refinement must b...

Full description

Bibliographic Details
Main Authors:	Costa-Neto, Germano, Crossa, José, Fritsche-Neto, Roberto
Format:	Journal Article
Language:	Inglés
Published:	Frontiers Media 2021
Subjects:	plant science adaptability climate-smart genomic selection selective phenotyping
Online Access:	https://hdl.handle.net/10568/164183

Similar Items: Enviromic assembly increases accuracy and reduces costs of the genomic prediction for yield plasticity in maize

Quick Look
Envirome-wide associations enhance multi-year genome-based prediction of historical wheat breeding data
Quick Look
Optimizing quantitative trait loci introgression in elite rice germplasms: Comparing methods and population sizes to develop new recipients via stochastic simulations
Quick Look
Enviromics: bridging different sources of data, building one framework
Quick Look
A marker weighting approach for enhancing within-family accuracy in genomic prediction
Quick Look
Optimizing self-pollinated crop breeding employing genomic selection: From schemes to updating training sets
Quick Look
Optimizing QTL introgression via stochastic simulations: an example of the IRRI rice breeding program
Quick Look
EnvRtype: a software to interplay enviromics and quantitative genomics in agriculture
Quick Look
Data augmentation enhances plant-genomic-enabled predictions
Quick Look
Enviromic prediction is useful to define the limits of climate adaptation: A case study of common bean in Brazil
Quick Look
Genomic prediction of cross performance in RTB crops: a module in Bioflow
Quick Look
Classification of plant growth‐promoting bacteria inoculation status and prediction of growth‐related traits in tropical maize using hyperspectral image and genomic data
Quick Look
Accuracy of quantitative trait nucleotide (QTN) prediction by surrounding SNPs
Quick Look
Combining high-throughput phenotyping and genomic information to increase prediction and selection accuracy in wheat breeding
Quick Look
Genotype performance estimation in targeted production environments by using sparse genomic prediction
Quick Look
Integration of physiological and remote sensing traits for improved genomic prediction of wheat yield
Quick Look
Feature engineering of environmental covariates improves plant genomic-enabled prediction
Quick Look
Expanding genomic prediction in plant breeding: harnessing big data, machine learning, and advanced software
Quick Look
Smart breeding driven by big data, artificial intelligence, and integrated genomic-enviromic prediction
Quick Look
Boosting genomic prediction transferability with sparse testing
Quick Look
Machine learning algorithms translate big data into predictive breeding accuracy
Quick Look
Optimizing genomic prediction with transfer learning under a ridge regression framework
Quick Look
Genomic Selection model to predict grain Zn concentrations
Quick Look
Editorial: Enviromics in plant breeding
Quick Look
Phenotypic evaluation of a multi-location cassava breeding trial to improve a genomic selection training population