Deep learning is widely applicable to phenotyping embryonic development and disease.

Thomas Naert,Fritjof Helmchen,Fabian F Voigt,Özgün Çiçek,Nikko-Ideen Shaidani,Marko Vujanovic,Olaf Ronneberger,Thomas Brox,Michael M Kaminski,Helen Rankin Willsey,Daniel Prata,Kelli Grand,Soeren S Lienkamp,Yuxiao Xu,Marko E Horb,Max Bürgi,Friedhelm Hildebrandt,Johannes Loffing,Paulina Ogar

doi:10.1242/dev.199664

Abstract

ABSTRACTGenome editing simplifies the generation of new animal models for congenital disorders. However, the detailed and unbiased phenotypic assessment of altered embryonic development remains a challenge. Here, we explore how deep learning (U-Net) can automate segmentation tasks in various imaging modalities, and we quantify phenotypes of altered renal, neural and craniofacial development in Xenopus embryos in comparison with normal variability. We demonstrate the utility of this approach in embryos with polycystic kidneys (pkd1 and pkd2) and craniofacial dysmorphia (six1). We highlight how in toto light-sheet microscopy facilitates accurate reconstruction of brain and craniofacial structures within X. tropicalis embryos upon dyrk1a and six1 loss of function or treatment with retinoic acid inhibitors. These tools increase the sensitivity and throughput of evaluating developmental malformations caused by chemical or genetic disruption. Furthermore, we provide a library of pre-trained networks and detailed instructions for applying deep learning to the reader's own datasets. We demonstrate the versatility, precision and scalability of deep neural network phenotyping on embryonic disease models. By combining light-sheet microscopy and deep learning, we provide a framework for higher-throughput characterization of embryonic model organisms. This article has an associated ‘The people behind the papers’ interview.

Highlights

Congenital inherited diseases pose a tremendous burden on society (Boyle et al, 2018)
By combining light-sheet microscopy and deep learning, we provide a framework for higher-throughput characterization of embryonic model organisms
We show automated analysis of a range of imaging modalities, including bright-field, fluorescence, focal laser scanning and light-sheet microscopy, which allowed in toto phenotyping of genome-edited X. tropicalis embryos

Summary

Introduction

Congenital inherited diseases pose a tremendous burden on society (Boyle et al, 2018). Renewed efforts to uncover the molecular mechanisms that underlie congenital inherited diseases are fueled by the ability to quickly generate and characterize new animal models of human genetic conditions (Naert and Vleminckx, 2018c). Recent advances, such as CRISPR/Cas allow for high-throughput interrogation of gene functions in early embryonic development (Jinek et al, 2012; Nakayama et al, 2013). Xenopus is increasingly employed to model congenital diseases and pediatric cancer (Hoff et al, 2013; Lienkamp et al, 2012; Naert et al, 2016, 2020a; Nasr et al, 2019; Szenker-Ravi et al, 2018; Willsey et al, 2020, 2021)

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