Molecular architecture of the developing mouse brain

Irina Khven, Gioele La Manno
NATURE PORTFOLIO, 2021
Article

Résumé

The mammalian brain develops through a complex interplay of spatial cues generated by diffusible morphogens, cell-cell interactions and intrinsic genetic programs that result in probably more than a thousand distinct cell types. A complete understanding of this process requires a systematic characterization of cell states over the entire spatiotemporal range of brain development. The ability of single-cell RNA sequencing and spatial transcriptomics to reveal the molecular heterogeneity of complex tissues has therefore been particularly powerful in the nervous system. Previous studies have explored development in specific brain regions(1-8), the whole adult brain(9) and even entire embryos(10). Here we report a comprehensive single-cell transcriptomic atlas of the embryonic mouse brain between gastrulation and birth. We identified almost eight hundred cellular states that describe a developmental program for the functional elements of the brain and its enclosing membranes, including the early neuroepithelium, region-specific secondary organizers, and both neurogenic and gliogenic progenitors. We also used in situ mRNA sequencing to map the spatial expression patterns of key developmental genes. Integrating the in situ data with our single-cell clusters revealed the precise spatial organization of neural progenitors during the patterning of the nervous system. A comprehensive single-cell transcriptomic atlas of the mouse brain between gastrulation and birth identifies hundreds of cellular states and reveals the spatiotemporal organization of brain development.

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https://infoscience.epfl.ch/record/287865?ln=fr

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Irina Khven, Gioele La Manno
NATURE PORTFOLIO, 2021
Article

Résumé

Official source

https://infoscience.epfl.ch/record/287865?ln=fr

À propos de ce résultat

Concepts associés (18)

Concepts associés

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Publications associées (11)

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Clonal relations in the mouse brain revealed by single-cell and spatial transcriptomics

Gioele La Manno

Ratz et al. present an easy-to-use method to barcode progenitor cells, enabling profiling of cell phenotypes and clonal relations using single-cell and spatial transcriptomics, providing an integrated approach for understanding brain architecture. The mammalian brain contains many specialized cells that develop from a thin sheet of neuroepithelial progenitor cells. Single-cell transcriptomics revealed hundreds of molecularly diverse cell types in the nervous system, but the lineage relationships between mature cell types and progenitor cells are not well understood. Here we show in vivo barcoding of early progenitors to simultaneously profile cell phenotypes and clonal relations in the mouse brain using single-cell and spatial transcriptomics. By reconstructing thousands of clones, we discovered fate-restricted progenitor cells in the mouse hippocampal neuroepithelium and show that microglia are derived from few primitive myeloid precursors that massively expand to generate widely dispersed progeny. We combined spatial transcriptomics with clonal barcoding and disentangled migration patterns of clonally related cells in densely labeled tissue sections. Our approach enables high-throughput dense reconstruction of cell phenotypes and clonal relations at the single-cell and tissue level in individual animals and provides an integrated approach for understanding tissue architecture.

NATURE PORTFOLIO2022

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Vesicular transport involves SNARE (soluble- N-ethylmaleimide-sensitive-factor-attachment-protein-receptor) proteins on transport vesicles and on target membranes. Syntaxin 13 is a SNARE enriched in brain, associated with recycling endosomes; its overexpression in PC12 cells promotes neurite outgrowth. This suggests an important role for receptor recycling during neuronal differentiation. Here we describe the spatiotemporal pattern of syntaxin 13 expression during mouse brain development. During early embryogenesis (E12-E15), it was found in the forebrain ventricular zone and in primary motor and sensory neurons in the brainstem, spinal cord and sensory ganglia. In the forebrain at E15, syntaxin 13 was not detected in neuroblasts in the intermediate zone of the embryonic hemispheric wall, while there was labeling in cortical neurons in deeper layers starting at E15-18, and progressively in later-generated neurons up to layer II around P6. Syntaxin 13 reached maximal expression in all brain divisions at about P7, followed by a decrease, with heterogeneous neuron populations displaying various staining intensities in adult brain. While usually restricted to the soma of neurons, we transiently detected syntaxin 13 in dendrites of pyramidal neurons during the first postnatal week. In conclusion, the developmentally regulated syntaxin 13 expression in various neuronal populations is consistent with its involvement in endocytic trafficking and neurite outgrowth.

2002

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Although stem cells hold tremendous potential for clinical applications, their in vitro manipulation remains very challenging. In vivo, stem cells reside in intricate 3D microenvironments, termed niche, in which many local and systemic extrinsic factors are integrated by the cells to induce controlled fate choices. Niche factors must not only be presented to stem cells in the correct composition, but also in a dynamic and spatially heterogeneous manner to evoke the appropriate response. However, state-of-the-art in vitro culture platforms fail to capture such microenvironmental complexity. In this thesis, a novel hydrogel-based microchip technology was invented to recapitulate in vitro the complexity of native stem cell niches. In this system, stem cells can be exposed to gradients of soluble or extracellular matrix (ECM)-tethered biomolecules. As a first proof of principle, this platform was used to locally influence the behavior of mouse embryonic stem cells (mESC) by exposing them to soluble, matrix-tethered or cell-secreted leukemia inhibitory factor (LIF). mESCs grown in synthetic 3D gels were found to respond to LIF gradients in a spatially regulated manner. In two subsequent studies, the microchip technology was utilized to recapitulate embryonic processes that are characterized by highly dynamic and spatially controlled morphogenetic processes that can currently not be modelled in a 3D context in vitro. First, an in vitro model of the developing central nervous system was conceived. In the developing vertebrate neural tube, dorsoventral identity of neural progenitors is defined by counter gradients of sonic hedgehog (Shh) and bone morphogenetic protein 7 (BMP7). Using the developing neural plate of chick embryos as a model system, a dedicated microchip was developed for exposing the neural progenitors in these tissues to gradients of Shh and BMP7. This approach allowed achieving, for the first time, ex vivo dorsoventral patterning. Secondly, a similar approach was employed towards modeling early human development in vitro. To this end, colonies of human embryonic stem cells (hESC) were exposed to opposing gradients of BMP4 and Noggin which induced mesendoderm differentiation exclusively in specific regions of the multicellular constructs. This study revealed the power of the developed platform to spatially control hESCs self-patterning. In a last set of experiments, the microchip technology was applied to mimic the complex molecular and cellular make-up of the bone marrow niche that regulates the activity of hematopoietic stem cells (HSC). A microchip system was successfully designed to capture the main anatomic features of native bone marrow niches with spatially separated compartments that supported either HSC dormancy or activation. Taken together, this thesis presents a set of innovative microengineering concepts for recapitulating the spatiotemporal complexity of native stem cell microenvironments. The platforms introduced here represent important additions to the currently rather limited set of in vitro tools for the study of complex multicellular phenomena in developmental biology, tissue engineering and regenerative medicine.

EPFL2017

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EPFL2017