Novel Tools for Adjusting Spatial Variability in the Early Sugarcane Breeding Stage.

Danilo Eduardo Cursi,Thiago Luis Brasco,Hermann Paulo Hoffmann,Durval Dourado Neto,Rodrigo Gazaffi,Lucas Rios Do Amaral

doi:10.3389/fpls.2021.749533

Abstract

The detection of spatial variability in field trials has great potential for accelerating plant breeding progress due to the possibility of better controlling non-genetic variation. Therefore, we aimed to evaluate a digital soil mapping approach and a high-density soil sampling procedure for identifying and adjusting spatial dependence in the early sugarcane breeding stage. Two experiments were conducted in regions with different soil classifications. High-density sampling of soil physical and chemical properties was performed in a regular grid to investigate the structure of spatial variability. Soil apparent electrical conductivity (ECa) was measured in both experimental areas with an EM38-MK2® sensor. In addition, principal component analysis (PCA) was employed to reduce the dimensionality of the physical and chemical soil data sets. After conducting the PCA and obtaining different thematic maps, we determined each experimental plot’s exact position within the field. Tons of cane per hectare (TCH) data for each experiment were obtained and analyzed using mixed linear models. When environmental covariates were considered, a previous forward model selection step was applied to incorporate the variables. The PCA based on high-density soil sampling data captured part of the total variability in the data for Experimental Area 1 and was suggested to be an efficient index to be incorporated as a covariate in the statistical model, reducing the experimental error (residual variation coefficient, CVe). When incorporated into the different statistical models, the ECa information increased the selection accuracy of the experimental genotypes. Therefore, we demonstrate that the genetic parameter increased when both approaches (spatial analysis and environmental covariates) were employed.

Highlights

Field experiments are essential in plant breeding programs to estimate the genetic parameters and select the best individuals
The objective of this study was to evaluate the efficiency of a digital soil mapping approach and a high-density soil sampling procedure to improve selection in the early sugarcane breeding stage
The experimental areas considered in this study belong to the Sugarcane Breeding Program of the Federal University of São Carlos (UFSCar), one of the ten federal university members of the Interuniversity Network for the Development of the Sugarcane Industry in Brazil (RIDESA)

Summary

Introduction

Field experiments are essential in plant breeding programs to estimate the genetic parameters and select the best individuals. Plant breeding pipelines incorporate new techniques, such as those derived from genomics, that can support the identification of superior individuals due to genetic factors (Balsalobre et al, 2017; Crossa et al, 2017, 2021; Barreto et al, 2019; Yadav et al, 2020). Controlling for environmental factors (nongenetic variation) can improve the selection accuracy in field experiments, reducing the experimental error with increasing genetic gain (Crossa et al, 2021; Hoarau et al, 2021; Resende et al, 2021). The lack of high-throughput data with accessible prices is one of the main reasons that phenotyping routinely impedes acquiring these kinds of data. Other factors make environmental detailing difficult; for example, Xu (2016) explained that the major environmental conditions are dynamic and can change throughout the crop cycle, and when data are acquired, they are usually considered at the experimental station level and not the plot level (Xu, 2016)

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