"Chamber #8" - a holistic approach of high-throughput non-destructive assessment of plant roots

Front Plant Sci. 2024 Jan 4:14:1269005. doi: 10.3389/fpls.2023.1269005. eCollection 2023.

Abstract

Introduction: In the past years, it has been observed that the breeding of plants has become more challenging, as the visible difference in phenotypic data is much smaller than decades ago. With the ongoing climate change, it is necessary to breed crops that can cope with shifting climatic conditions. To select good breeding candidates for the future, phenotypic experiments can be conducted under climate-controlled conditions. Above-ground traits can be assessed with different optical sensors, but for the root growth, access to non-destructively measured traits is much more challenging. Even though MRI or CT imaging techniques have been established in the past years, they rely on an adequate infrastructure for the automatic handling of the pots as well as the controlled climate.

Methods: To address both challenges simultaneously, the non-destructive imaging of plant roots combined with a highly automated and standardized mid-throughput approach, we developed a workflow and an integrated scanning facility to study root growth. Our "chamber #8" contains a climate chamber, a material flow control, an irrigation system, an X-ray system, a database for automatic data collection, and post-processing. The goals of this approach are to reduce the human interaction with the various components of the facility to a minimum on one hand, and to automate and standardize the complete process from plant care via measurements to root trait calculation on the other. The user receives standardized phenotypic traits and properties that were collected objectively.

Results: The proposed holistic approach allows us to study root growth of plants in a field-like substrate non-destructively over a defined period and to calculate phenotypic traits of root architecture. For different crops, genotypic differences can be observed in response to climatic conditions which have already been applied to a wide variety of root structures, such as potatoes, cassava, or corn.

Discussion: It enables breeders and scientists non-destructive access to root traits. Additionally, due to the non-destructive nature of X-ray computed tomography, the analysis of time series for root growing experiments is possible and enables the observation of kinetic traits. Furthermore, using this automation scheme for simultaneously controlled plant breeding and non-destructive testing reduces the involvement of human resources.

Keywords: CT; data management; non-destructive testing; phenotyping; roots; x-ray.

Grants and funding

The author(s) declare financial support was received for the research, authorship, and/or publication of this article. The contributions of TW were partially supported by the Bavarian Ministry of Economic affairs, Regional Development and Energy through the Center for Analytics Data Applications (ADA-Center) within the framework of "BAYERN DIGITAL II“ (20-3410-2-9-8). The experiments were supported by the German Federal Ministry for Education and Research (BMBF) within the German-Plant-Phenotyping Network (project identification number 031A053), the Fachagentur Nachwachsende Rohstoffe (FNR) within the research project “Verbundvorhaben: Entwicklung von Bio- und Molekularmarkern zur gezielten Züchtung hitzetoleranter Kartoffelsorten” (project identification number 22010812), the Bill and Melinda Gates Foundation (BMGF) as a subgrant from the Friedrich Alexander-Universität Erlangen-Nürnberg (FAU) within the project “cassava source sink relations” (CASS; project identification number OPP1113365) and the European Union within the Suscrop Call2020 project C4Future “Fortifying and Enhancing Resilience in C4 Crops for Current and Future Climate Change Adversities”.