Your search keyword '"Fabio Sacher"' showing total 3 results

1. A single-cell transcriptomic atlas of the developing chicken limb

Author

Christian Feregrino, Fabio Sacher, Oren Parnas, and Patrick Tschopp

Subjects

scRNA-seq, Gene expression, Cellular transcriptomics, Autopod patterning, Digits, Interdigit, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Through precise implementation of distinct cell type specification programs, differentially regulated in both space and time, complex patterns emerge during organogenesis. Thanks to its easy experimental accessibility, the developing chicken limb has long served as a paradigm to study vertebrate pattern formation. Through decades’ worth of research, we now have a firm grasp on the molecular mechanisms driving limb formation at the tissue-level. However, to elucidate the dynamic interplay between transcriptional cell type specification programs and pattern formation at its relevant cellular scale, we lack appropriately resolved molecular data at the genome-wide level. Here, making use of droplet-based single-cell RNA-sequencing, we catalogue the developmental emergence of distinct tissue types and their transcriptome dynamics in the distal chicken limb, the so-called autopod, at cellular resolution. Results Using single-cell RNA-sequencing technology, we sequenced a total of 17,628 cells coming from three key developmental stages of chicken autopod patterning. Overall, we identified 23 cell populations with distinct transcriptional profiles. Amongst them were small, albeit essential populations like the apical ectodermal ridge, demonstrating the ability to detect even rare cell types. Moreover, we uncovered the existence of molecularly distinct sub-populations within previously defined compartments of the developing limb, some of which have important signaling functions during autopod pattern formation. Finally, we inferred gene co-expression modules that coincide with distinct tissue types across developmental time, and used them to track patterning-relevant cell populations of the forming digits. Conclusions We provide a comprehensive functional genomics resource to study the molecular effectors of chicken limb patterning at cellular resolution. Our single-cell transcriptomic atlas captures all major cell populations of the developing autopod, and highlights the transcriptional complexity in many of its components. Finally, integrating our data-set with other single-cell transcriptomics resources will enable researchers to assess molecular similarities in orthologous cell types across the major tetrapod clades, and provide an extensive candidate gene list to functionally test cell-type-specific drivers of limb morphological diversification.

Published

2019

2. Extracellular matrix gene expression signatures as cell type and cell state identifiers

Author

Patrick Tschopp, Collin Y. Ewald, Christian Feregrino, and Fabio Sacher

Subjects

Cell type, Histology, QH301-705.5, Cellular differentiation, Cell, Biophysics, Biology, Biochemistry, Article, Extracellular matrix, Transcriptome, Gene expression, scRNA-seq, Genetics, medicine, Biology (General), Molecular Biology, Transcription factor, Gene, Limb development, Matreotype, Cell Biology, Embryonic stem cell, Cell biology, Matrisome, medicine.anatomical_structure

Abstract

Transcriptomic signatures based on cellular mRNA expression profiles can be used to categorize cell types and states. Yet whether different functional groups of genes perform better or worse in this process remains largely unexplored. Here we test the core matrisome – that is, all genes coding for structural proteins of the extracellular matrix – for its ability to delineate distinct cell types in embryonic single-cell RNA-sequencing (scRNA-seq) data. We show that even though expressed core matrisome genes correspond to less than 2% of an entire cellular transcriptome, their RNA expression levels suffice to recapitulate essential aspects of cell type-specific clustering. Notably, using scRNA-seq data from the embryonic limb, we demonstrate that core matrisome gene expression outperforms random gene subsets of similar sizes and can match and exceed the predictive power of transcription factors. While transcription factor signatures generally perform better in predicting cell types at early stages of chicken and mouse limb development, i.e., when cells are less differentiated, the information content of the core matrisome signature increases in more differentiated cells. Moreover, using cross-species analyses, we show that these cell type-specific signatures are evolutionarily conserved. Our findings suggest that each cell type produces its own unique extracellular matrix, or matreotype, which becomes progressively more refined and cell type-specific as embryonic tissues mature., Matrix Biology Plus, 10, ISSN:2590-0285

Published

2021

3. A Single-cell Transcriptomic Atlas of the Developing Chicken Limb

Author

Patrick Tschopp, Christian Feregrino, Oren Parnas, and Fabio Sacher

Subjects

0106 biological sciences, Apical ectodermal ridge, Cell type, Candidate gene, lcsh:QH426-470, Organogenesis, lcsh:Biotechnology, Biology, Proteomics, 01 natural sciences, Transcriptome, Autopod patterning, 03 medical and health sciences, 0302 clinical medicine, Perichondrium, lcsh:TP248.13-248.65, biology.animal, scRNA-seq, Digits, Interdigit, Genetics, Animals, Gene, Phalanges, Body Patterning, 030304 developmental biology, 0303 health sciences, Gene Expression Regulation, Developmental, Vertebrate, Extremities, lcsh:Genetics, Evolutionary biology, Cellular transcriptomics, Gene expression, Single-Cell Analysis, DNA microarray, Chickens, Functional genomics, 030217 neurology & neurosurgery, Signal Transduction, Transcription Factors, Research Article, 010606 plant biology & botany, Biotechnology

Abstract

BackgroundThrough precise implementation of distinct cell type specification programs, differentially regulated in both space and time, complex patterns emerge during organogenesis. Thanks to its easy experimental accessibility, the developing chicken limb has long served as a paradigm to study vertebrate pattern formation. Through decades’ worth of research, we now have a firm grasp on the molecular mechanisms driving limb formation at the tissue-level. However, to elucidate the dynamic interplay between transcriptional cell type specification programs and pattern formation at its relevant cellular scale, we lack appropriately resolved molecular data at the genome-wide level. Here, making use of droplet-based single-cell RNA-sequencing, we catalogue the developmental emergence of distinct tissue types and their transcriptome dynamics in the distal chicken limb, the so-called autopod, at cellular resolution.ResultsUsing single-cell RNA-sequencing technology, we sequenced a total of 17,628 cells coming from three key developmental stages of chicken autopod patterning. Overall, we identified 23 cell populations with distinct transcriptional profiles. Amongst them were small, albeit essential populations like the apical ectodermal ridge, demonstrating the ability to detect even rare cell types. Moreover, we uncovered the existence of molecularly distinct sub-populations within previously defined compartments of the developing limb, some of which have important signaling functions during autopod pattern formation. Finally, we inferred gene co-expression modules that coincide with distinct tissue types across developmental time, and used them to track patterning-relevant cell populations of the forming digits.ConclusionsWe provide a comprehensive functional genomics resource to study the molecular effectors of chicken limb patterning at cellular resolution. Our single-cell transcriptomic atlas captures all major cell populations of the developing autopod, and highlights the transcriptional complexity in many of its components. Finally, integrating our data-set with other single-cell transcriptomics resources will enable researchers to assess molecular similarities in orthologous cell types across the major tetrapod clades, and provide an extensive candidate gene list to functionally test cell-type-specific drivers of limb morphological diversification.

Published

2019