Hyperspectral Reflectance-Derived Relationship Matrices for Genomic Prediction of Grain Yield in Wheat

Hyperspectral reflectance phenotyping and genomic selection are two emerging technologies that have the potential to increase plant breeding efficiency by improving prediction accuracy for grain yield. Hyperspectral cameras quantify canopy reflectance across a wide range of wavelengths that are associated with numerous biophysical and biochemical processes in plants. Genomic selection models utilize genome-wide marker or pedigree information to predict the genetic values of breeding lines. In this study, we propose a multi-kernel GBLUP approach to genomic selection that uses genomic marker-, pedigree-, and hyperspectral reflectance-derived relationship matrices to model the genetic main effects and genotype × environment (G × E) interactions across environments within a bread wheat (Triticum aestivum L.) breeding program. We utilized an airplane equipped with a hyperspectral camera to phenotype five differentially managed treatments of the yield trials conducted by the Bread Wheat Improvement Program of the International Maize and Wheat Improvement Center (CIMMYT) at Ciudad Obregón, México over four breeding cycles. We observed that single-kernel models using hyperspectral reflectance-derived relationship matrices performed similarly or superior to marker- and pedigree-based genomic selection models when predicting within and across environments. Multi-kernel models combining marker/pedigree information with hyperspectral reflectance phentoypes had the highest prediction accuracies; however, improvements in accuracy over marker- and pedigree-based models were marginal when correcting for days to heading. Our results demonstrate the potential of using hyperspectral imaging to predict grain yield within a multi-environment context and also support further studies on the integration of hyperspectral reflectance phenotyping into breeding programs.

[1]  José Crossa,et al.  Multitrait, Random Regression, or Simple Repeatability Model in High‐Throughput Phenotyping Data Improve Genomic Prediction for Wheat Grain Yield , 2017, The plant genome.

[2]  Jeffrey W. White,et al.  Field-based phenomics for plant genetics research , 2012 .

[3]  José Crossa,et al.  Genomic Bayesian functional regression models with interactions for predicting wheat grain yield using hyper-spectral image data , 2017, Plant Methods.

[4]  C. Bastien,et al.  Phenomic Selection Is a Low-Cost and High-Throughput Method Based on Indirect Predictions: Proof of Concept on Wheat and Poplar , 2018, G3: Genes, Genomes, Genetics.

[5]  José Crossa,et al.  A reaction norm model for genomic selection using high-dimensional genomic and environmental data , 2013, Theoretical and Applied Genetics.

[6]  José Crossa,et al.  Genomic Prediction of Breeding Values when Modeling Genotype × Environment Interaction using Pedigree and Dense Molecular Markers , 2012 .

[7]  Christian A. Gueymard,et al.  Interdisciplinary applications of a versatile spectral solar irradiance model: A review , 2004 .

[8]  A. Strahler,et al.  Monitoring vegetation phenology using MODIS , 2003 .

[9]  J Crossa,et al.  Genomic prediction in CIMMYT maize and wheat breeding programs , 2013, Heredity.

[10]  Anne-Katrin Mahlein,et al.  Supplemental Blue LED Lighting Array to Improve the Signal Quality in Hyperspectral Imaging of Plants , 2015, Sensors.

[11]  J. Poland,et al.  Single‐Step Genomic and Pedigree Genotype × Environment Interaction Models for Predicting Wheat Lines in International Environments , 2017, The plant genome.

[12]  Qin Zhang,et al.  A Review of Imaging Techniques for Plant Phenotyping , 2014, Sensors.

[13]  G. de los Campos,et al.  Genomic Selection in Plant Breeding: Methods, Models, and Perspectives. , 2017, Trends in plant science.

[14]  A. Viña,et al.  Comparison of different vegetation indices for the remote assessment of green leaf area index of crops , 2011 .

[15]  R. Bernardo Breeding for Quantitative Traits in Plants , 2002 .

[16]  Robert J. Elshire,et al.  A Robust, Simple Genotyping-by-Sequencing (GBS) Approach for High Diversity Species , 2011, PloS one.

[17]  Carolyn J. Lawrence-Dill,et al.  The Quest for Understanding Phenotypic Variation via Integrated Approaches in the Field Environment1[OPEN] , 2016, Plant Physiology.

[18]  Rick L. Lawrence,et al.  Wheat yield estimates using multi-temporal NDVI satellite imagery , 2002 .

[19]  Marco Lopez-Cruz,et al.  Increased Prediction Accuracy in Wheat Breeding Trials Using a Marker × Environment Interaction Genomic Selection Model , 2015, G3: Genes, Genomes, Genetics.

[20]  P. Horton,et al.  REGULATION OF LIGHT HARVESTING IN GREEN PLANTS. , 1996, Annual review of plant physiology and plant molecular biology.

[21]  Lorena González Pérez,et al.  Canopy Temperature and Vegetation Indices from High-Throughput Phenotyping Improve Accuracy of Pedigree and Genomic Selection for Grain Yield in Wheat , 2016, G3: Genes, Genomes, Genetics.

[22]  N. Gobron,et al.  Designing optimal spectral indices: A feasibility and proof of concept study , 1999 .

[23]  Robert D. Finn,et al.  The Pfam protein families database: towards a more sustainable future , 2015, Nucleic Acids Res..

[24]  Pablo J. Zarco-Tejada,et al.  Multi-Temporal and Spectral Analysis of High-Resolution Hyperspectral Airborne Imagery for Precision Agriculture: Assessment of Wheat Grain Yield and Grain Protein Content , 2018, Remote. Sens..

[25]  J. Araus,et al.  Spectral vegetation indices as nondestructive tools for determining durum wheat yield. , 2000 .

[26]  M. Sorrells,et al.  Using Genomic Prediction to Characterize Environments and Optimize Prediction Accuracy in Applied Breeding Data , 2013 .

[27]  M. Calus,et al.  Genomic Prediction in Animals and Plants: Simulation of Data, Validation, Reporting, and Benchmarking , 2013, Genetics.

[28]  M. Goddard,et al.  Prediction of total genetic value using genome-wide dense marker maps. , 2001, Genetics.

[29]  G. de los Campos,et al.  Predicting grain yield using canopy hyperspectral reflectance in wheat breeding data , 2017, Plant Methods.

[30]  D. Raes,et al.  The effect of tillage, crop rotation and residue management on maize and wheat growth and development evaluated with an optical sensor , 2011 .

[31]  Anatoly A. Gitelson,et al.  Monitoring Maize (Zea mays L.) Phenology with Remote Sensing , 2004 .

[32]  J. Araus,et al.  Field high-throughput phenotyping: the new crop breeding frontier. , 2014, Trends in plant science.

[33]  M. Tester,et al.  Phenomics--technologies to relieve the phenotyping bottleneck. , 2011, Trends in plant science.

[34]  Lorena González Pérez,et al.  Use of Hyperspectral Image Data Outperforms Vegetation Indices in Prediction of Maize Yield , 2017 .

[35]  Suchismita Mondal,et al.  Combining High‐Throughput Phenotyping and Genomic Information to Increase Prediction and Selection Accuracy in Wheat Breeding , 2018, The plant genome.

[36]  Naiqian Zhang,et al.  Development and Deployment of a Portable Field Phenotyping Platform , 2016 .

[37]  Jeffrey W. White,et al.  Development and evaluation of a field-based high-throughput phenotyping platform. , 2013, Functional plant biology : FPB.

[38]  Jeffrey B. Endelman,et al.  Ridge Regression and Other Kernels for Genomic Selection with R Package rrBLUP , 2011 .

[39]  J. Schjoerring,et al.  Reflectance measurement of canopy biomass and nitrogen status in wheat crops using normalized difference vegetation indices and partial least squares regression , 2003 .

[40]  D. Goodin,et al.  Application of unmanned aerial systems for high throughput phenotyping of large wheat breeding nurseries , 2016, Plant Methods.

[41]  José Crossa,et al.  High-throughput phenotyping and genomic selection: the frontiers of crop breeding converge. , 2012, Journal of integrative plant biology.

[42]  M. Stitt,et al.  Genomic and metabolic prediction of complex heterotic traits in hybrid maize , 2012, Nature Genetics.

[43]  José Crossa,et al.  Genomic Selection in Wheat Breeding using Genotyping‐by‐Sequencing , 2012 .

[44]  Jean-Luc Jannink,et al.  Shrinkage Estimation of the Realized Relationship Matrix , 2012, G3: Genes | Genomes | Genetics.

[45]  H. Lichtenthaler CHLOROPHYLL AND CAROTENOIDS: PIGMENTS OF PHOTOSYNTHETIC BIOMEMBRANES , 1987 .

[46]  R Core Team,et al.  R: A language and environment for statistical computing. , 2014 .