Heritable Variation of Foliar Spectral Reflectance Enhances Genomic Prediction of Hydrogen Cyanide in a Genetically Structured Population of Eucalyptus

Paulina Ballesta; Sunny Ahmar; Gustavo A Lobos; Daniel Mieres-Castro; Felipe Jiménez-Aspee; Freddy Mora-Poblete

doi:10.3389/fpls.2022.871943

Heritable Variation of Foliar Spectral Reflectance Enhances Genomic Prediction of Hydrogen Cyanide in a Genetically Structured Population of Eucalyptus

Front Plant Sci. 2022 Mar 31:13:871943. doi: 10.3389/fpls.2022.871943. eCollection 2022.

Authors

Paulina Ballesta¹, Sunny Ahmar¹, Gustavo A Lobos², Daniel Mieres-Castro¹, Felipe Jiménez-Aspee³, Freddy Mora-Poblete⁴

Affiliations

¹ The National Fund for Scientific and Technological Development, Talca, Chile.
² Plant Breeding and Phenomic Center, Faculty of Agricultural Sciences, Universidad de Talca, Talca, Chile.
³ Department of Food Biofunctionality, Institute of Nutritional Sciences, University of Hohenheim, Stuttgart, Germany.
⁴ Institute of Biological Sciences, University of Talca, Talca, Chile.

Abstract

Plants produce a wide diversity of specialized metabolites, which fulfill a wide range of biological functions, helping plants to interact with biotic and abiotic factors. In this study, an integrated approach based on high-throughput plant phenotyping, genome-wide haplotypes, and pedigree information was performed to examine the extent of heritable variation of foliar spectral reflectance and to predict the leaf hydrogen cyanide content in a genetically structured population of a cyanogenic eucalyptus (Eucalyptus cladocalyx F. Muell). In addition, the heritable variation (based on pedigree and genomic data) of more of 100 common spectral reflectance indices was examined. The first profile of heritable variation along the spectral reflectance curve indicated the highest estimate of genomic heritability ( $h_{g}^{2}$ =0.41) within the visible region of the spectrum, suggesting that several physiological and biological responses of trees to environmental stimuli (ex., light) are under moderate genetic control. The spectral reflectance index with the highest genomic-based heritability was leaf rust disease severity index 1 ( $h_{g}^{2}$ =0.58), followed by the anthocyanin reflectance index and the Browning reflectance index ( $h_{g}^{2}$ =0.54). Among the Bayesian prediction models based on spectral reflectance data, Bayes B had a better goodness of fit than the Bayes-C and Bayesian ridge regression models (in terms of the deviance information criterion). All models that included spectral reflectance data outperformed conventional genomic prediction models in their predictive ability and goodness-of-fit measures. Finally, we confirmed the proposed hypothesis that high-throughput phenotyping indirectly capture endophenotypic variants related to specialized metabolites (defense chemistry), and therefore, generally more accurate predictions can be made integrating phenomics and genomics.

Keywords: defense chemistry; genomic and phenomic prediction; genomic heritability; specialized metabolite; spectral reflectance indexes; spectroradiometer.