TopoRoot: a Method for Computing Hierarchy and Fine-grained Traits of Maize Roots from 3D Imaging

Overview

Journal Plant Methods

Publisher Biomed Central

Specialty Biology

Date 2021 Dec 14

PMID 34903248

Citations 7

Authors

Dan Zeng

Mao Li

Ni Jiang

Yiwen Ju

Hannah Schreiber

Erin Chambers

David Letscher

Tao Ju

Christopher N Topp

Affiliations

Soon will be listed here.

Abstract

Background: 3D imaging, such as X-ray CT and MRI, has been widely deployed to study plant root structures. Many computational tools exist to extract coarse-grained features from 3D root images, such as total volume, root number and total root length. However, methods that can accurately and efficiently compute fine-grained root traits, such as root number and geometry at each hierarchy level, are still lacking. These traits would allow biologists to gain deeper insights into the root system architecture.

Results: We present TopoRoot, a high-throughput computational method that computes fine-grained architectural traits from 3D images of maize root crowns or root systems. These traits include the number, length, thickness, angle, tortuosity, and number of children for the roots at each level of the hierarchy. TopoRoot combines state-of-the-art algorithms in computer graphics, such as topological simplification and geometric skeletonization, with customized heuristics for robustly obtaining the branching structure and hierarchical information. TopoRoot is validated on both CT scans of excavated field-grown root crowns and simulated images of root systems, and in both cases, it was shown to improve the accuracy of traits over existing methods. TopoRoot runs within a few minutes on a desktop workstation for images at the resolution range of 400^3, with minimal need for human intervention in the form of setting three intensity thresholds per image.

Conclusions: TopoRoot improves the state-of-the-art methods in obtaining more accurate and comprehensive fine-grained traits of maize roots from 3D imaging. The automation and efficiency make TopoRoot suitable for batch processing on large numbers of root images. Our method is thus useful for phenomic studies aimed at finding the genetic basis behind root system architecture and the subsequent development of more productive crops.

Citing Articles

TopoRoot+: computing whorl and soil line traits of field-excavated maize roots from CT imaging.

Ju Y, Liu A, Oestreich K, Wang T, Topp C, Ju T Plant Methods. 2024; 20(1):132.

PMID: 39187896 PMC: 11348750. DOI: 10.1186/s13007-024-01240-0.

A system for the study of roots 3D kinematics in hydroponic culture: a study on the oscillatory features of root tip.

Simonetti V, Ravazzolo L, Ruperti B, Quaggiotti S, Castiello U Plant Methods. 2024; 20(1):50.

PMID: 38561757 PMC: 10983651. DOI: 10.1186/s13007-024-01178-3.

Non-destructive, whole-plant phenotyping reveals dynamic changes in water use efficiency, photosynthesis, and rhizosphere acidification of sorghum accessions under osmotic stress.

Ginzburg D, Cox J, Rhee S Plant Direct. 2024; 8(3):e571.

PMID: 38464685 PMC: 10918709. DOI: 10.1002/pld3.571.

Topological data analysis reveals a core gene expression backbone that defines form and function across flowering plants.

Palande S, Kaste J, Roberts M, Segura Aba K, Claucherty C, Dacon J PLoS Biol. 2023; 21(12):e3002397.

PMID: 38051702 PMC: 10723737. DOI: 10.1371/journal.pbio.3002397.

Quantification of the three-dimensional root system architecture using an automated rotating imaging system.

Wu Q, Wu J, Hu P, Zhang W, Ma Y, Yu K Plant Methods. 2023; 19(1):11.

PMID: 36732764 PMC: 9896698. DOI: 10.1186/s13007-023-00988-1.

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