Exploiting High-Throughput Indoor Phenotyping to Characterize the Founders of a Structured Breeding Population

Overview

Journal Front Plant Sci

Date 2022 Jan 24

PMID 35069637

Authors

Jana Ebersbach

Nazifa Azam Khan

Ian McQuillan

Erin E Higgins

Kyla Horner

Venkat Bandi

Carl Gutwin

Sally Lynne Vail

Steve J Robinson

Isobel A P Parkin

Affiliations

Soon will be listed here.

Abstract

Phenotyping is considered a significant bottleneck impeding fast and efficient crop improvement. Similar to many crops, , an internationally important oilseed crop, suffers from low genetic diversity, and will require exploitation of diverse genetic resources to develop locally adapted, high yielding and stress resistant cultivars. A pilot study was completed to assess the feasibility of using indoor high-throughput phenotyping (HTP), semi-automated image processing, and machine learning to capture the phenotypic diversity of agronomically important traits in a diverse breeding population, SKBnNAM, introduced here for the first time. The experiment comprised 50 spring-type lines, grown and phenotyped in six replicates under two treatment conditions (control and drought) over 38 days in a LemnaTec Scanalyzer 3D facility. Growth traits including plant height, width, projected leaf area, and estimated biovolume were extracted and derived through processing of RGB and NIR images. Anthesis was automatically and accurately scored (97% accuracy) and the number of flowers per plant and day was approximated alongside relevant canopy traits (width, angle). Further, supervised machine learning was used to predict the total number of raceme branches from flower attributes with 91% accuracy (linear regression and Huber regression algorithms) and to identify mild drought stress, a complex trait which typically has to be empirically scored (0.85 area under the receiver operating characteristic curve, random forest classifier algorithm). The study demonstrates the potential of HTP, image processing and computer vision for effective characterization of agronomic trait diversity in , although limitations of the platform did create significant variation that limited the utility of the data. However, the results underscore the value of machine learning for phenotyping studies, particularly for complex traits such as drought stress resistance.

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