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1.
Development ; 148(21)2021 11 01.
Article in English | MEDLINE | ID: mdl-34739029

ABSTRACT

Genome 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.


Subject(s)
Deep Learning , Embryonic Development/genetics , Phenotype , Animals , Craniofacial Abnormalities/embryology , Craniofacial Abnormalities/genetics , Craniofacial Abnormalities/pathology , Disease Models, Animal , Image Processing, Computer-Assisted , Mice , Microscopy , Mutation , Neural Networks, Computer , Neurodevelopmental Disorders/genetics , Neurodevelopmental Disorders/pathology , Polycystic Kidney Diseases/embryology , Polycystic Kidney Diseases/genetics , Polycystic Kidney Diseases/pathology , Xenopus Proteins/genetics , Xenopus laevis
2.
Eur Respir J ; 63(2)2024 Feb.
Article in English | MEDLINE | ID: mdl-38212077

ABSTRACT

BACKGROUND: Fibroblast-to-myofibroblast conversion is a major driver of tissue remodelling in organ fibrosis. Distinct lineages of fibroblasts support homeostatic tissue niche functions, yet their specific activation states and phenotypic trajectories during injury and repair have remained unclear. METHODS: We combined spatial transcriptomics, multiplexed immunostainings, longitudinal single-cell RNA-sequencing and genetic lineage tracing to study fibroblast fates during mouse lung regeneration. Our findings were validated in idiopathic pulmonary fibrosis patient tissues in situ as well as in cell differentiation and invasion assays using patient lung fibroblasts. Cell differentiation and invasion assays established a function of SFRP1 in regulating human lung fibroblast invasion in response to transforming growth factor (TGF)ß1. MEASUREMENTS AND MAIN RESULTS: We discovered a transitional fibroblast state characterised by high Sfrp1 expression, derived from both Tcf21-Cre lineage positive and negative cells. Sfrp1 + cells appeared early after injury in peribronchiolar, adventitial and alveolar locations and preceded the emergence of myofibroblasts. We identified lineage-specific paracrine signals and inferred converging transcriptional trajectories towards Sfrp1 + transitional fibroblasts and Cthrc1 + myofibroblasts. TGFß1 downregulated SFRP1 in noninvasive transitional cells and induced their switch to an invasive CTHRC1+ myofibroblast identity. Finally, using loss-of-function studies we showed that SFRP1 modulates TGFß1-induced fibroblast invasion and RHOA pathway activity. CONCLUSIONS: Our study reveals the convergence of spatially and transcriptionally distinct fibroblast lineages into transcriptionally uniform myofibroblasts and identifies SFRP1 as a modulator of TGFß1-driven fibroblast phenotypes in fibrogenesis. These findings are relevant in the context of therapeutic interventions that aim at limiting or reversing fibroblast foci formation.


Subject(s)
Idiopathic Pulmonary Fibrosis , Myofibroblasts , Mice , Animals , Humans , Myofibroblasts/metabolism , Fibroblasts/metabolism , Lung/metabolism , Idiopathic Pulmonary Fibrosis/metabolism , Cell Differentiation , Transforming Growth Factor beta1/metabolism , Extracellular Matrix Proteins/metabolism , Membrane Proteins/genetics , Membrane Proteins/metabolism
3.
Nat Commun ; 11(1): 3559, 2020 07 16.
Article in English | MEDLINE | ID: mdl-32678092

ABSTRACT

The cell type specific sequences of transcriptional programs during lung regeneration have remained elusive. Using time-series single cell RNA-seq of the bleomycin lung injury model, we resolved transcriptional dynamics for 28 cell types. Trajectory modeling together with lineage tracing revealed that airway and alveolar stem cells converge on a unique Krt8 + transitional stem cell state during alveolar regeneration. These cells have squamous morphology, feature p53 and NFkB activation and display transcriptional features of cellular senescence. The Krt8+ state appears in several independent models of lung injury and persists in human lung fibrosis, creating a distinct cell-cell communication network with mesenchyme and macrophages during repair. We generated a model of gene regulatory programs leading to Krt8+ transitional cells and their terminal differentiation to alveolar type-1 cells. We propose that in lung fibrosis, perturbed molecular checkpoints on the way to terminal differentiation can cause aberrant persistence of regenerative intermediate stem cell states.


Subject(s)
Alveolar Epithelial Cells/metabolism , Keratin-8/metabolism , Pulmonary Alveoli/physiology , Pulmonary Fibrosis/pathology , Regeneration , Stem Cells/metabolism , Alveolar Epithelial Cells/cytology , Animals , Cell Communication , Disease Models, Animal , Female , Gene Expression Profiling , Humans , Keratin-8/genetics , Lung Injury/chemically induced , Lung Injury/metabolism , Lung Injury/pathology , Mice , Mice, Inbred C57BL , Pulmonary Alveoli/cytology , Pulmonary Fibrosis/metabolism , Single-Cell Analysis , Stem Cells/cytology
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