A shared transcriptional code orchestrates temporal patterning of the central nervous system

Sagner, Andreas; Zhang, Isabel; Watson, Thomas; Lazaro, Jorge; Melchionda, Manuela; Briscoe, James

doi:10.1371/journal.pbio.3001450

Cited by 60 publications

(43 citation statements)

References 117 publications

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“…(B) Mammalian temporal patterning and neurons generated in each temporal window. Upper panel: Birth date of cortical projection neurons ( Caviness, 1982 ) and V1 spinal interneuron ( Stam et al, 2012 ) with temporal transcription factor expression in neural progenitors at each temporal window ( Sagner et al, 2021 ); lower panel: Birth date of retinal cells and corresponding temporal transcription factors in retinal progenitors [RGC: retinal ganglion cell; HC: horizontal cell; AC: amacrine cell; Rod: rod cell (photoreceptor); BC: bipolar cell; MC: Müller cell] ( Elliott et al, 2008 ; Mattar et al, 2015 ; Javed et al, 2020 ). (C) Different regions in the fly nervous system undergo different cascades of temporal factors to generate different types of neurons.…”

Section: Spatiotemporal Patterning and Cell Fate Determinationmentioning

confidence: 99%

“…In mammals, recent studies have systematically discovered a set of birthdate markers that are shared between different cell types in the hindbrain and spinal cord of human and mouse ( Delile et al, 2019 ; Osseward et al, 2021 ; Rayon et al, 2021 ; Figure 2B ), and the expression of these markers are consistent with known subtypes within several cardinal classes of spinal neurons ( Roy et al, 2012 ; Bikoff et al, 2016 ; Hayashi et al, 2018 ). Some of these birthdate markers are required for early-vs. late-born neuronal fate in neurons (e.g., in the mammalian cortex, Satb2 is required for later-born callosal neurons from layer 2 to 5, and Fezf2 and Ctip2 are necessary for early-born ones in layer 5) ( Chen et al, 2005 , 2008 ; Alcamo et al, 2008 ; Britanova et al, 2008 ) and in progenitors (e.g., Nfia and Nfib for the generation of late-born neurons in the retina and ventral spinal interneurons) ( Xie et al, 2020 ; Sagner et al, 2021 ). Consistent with the idea that neural progenitor temporal factors specify the fate of daughter neurons, cortical neurons inherit the gene modules that are present in radial glia at the stage when the neurons were generated ( Telley et al, 2019 ), and the late-born fate regulators Nfia/b/x directly regulate late-born fate associated genes in the mammalian retina ( Clark et al, 2019 ; Xie et al, 2020 ; Lyu et al, 2021 ).…”

Section: Spatiotemporal Patterning and Cell Fate Determinationmentioning

confidence: 99%

“…The recent advent of high-throughput profiling techniques not only made possible the discovery of a shared set of temporal regulators across different vertebrate neuronal tissues ( Lu et al, 2020 ; Sagner et al, 2021 ) but also opened the opportunity to understand the gene regulatory networks governed by these temporal factors ( Telley et al, 2019 ; Lyu et al, 2021 ) and other birthdate-specific post-mitotic regulators ( Di Bella et al, 2021 ). Our rapidly expanding knowledge of the molecular logic of spatiotemporal integration and fate specification in various species will set the stage for more comparative studies, such as the investigation of how the targets of conserved spatiotemporal regulators differ between species, how novel spatial domains or temporal windows emerge, and, ultimately, how new cell types are generated during development and evolution.…”

Section: Spatiotemporal Patterning and Evolution Of New Cell Typesmentioning

confidence: 99%

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Integration of Spatial and Temporal Patterning in the Invertebrate and Vertebrate Nervous System

Chen

Κωνσταντινίδης

2022

Front. Neurosci.

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The nervous system is one of the most sophisticated animal tissues, consisting of thousands of interconnected cell types. How the nervous system develops its diversity from a few neural stem cells remains a challenging question. Spatial and temporal patterning mechanisms provide an efficient model through which diversity can be generated. The molecular mechanism of spatiotemporal patterning has been studied extensively in Drosophila melanogaster, where distinct sets of transcription factors define the spatial domains and temporal windows that give rise to different cell types. Similarly, in vertebrates, spatial domains defined by transcription factors produce different types of neurons in the brain and neural tube. At the same time, different cortical neuronal types are generated within the same cell lineage with a specific birth order. However, we still do not understand how the orthogonal information of spatial and temporal patterning is integrated into the progenitor and post-mitotic cells to combinatorially give rise to different neurons. In this review, after introducing spatial and temporal patterning in Drosophila and mice, we discuss possible mechanisms that neural progenitors may use to integrate spatial and temporal information. We finally review the functional implications of spatial and temporal patterning and conclude envisaging how small alterations of these mechanisms can lead to the evolution of new neuronal cell types.

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Section: Spatiotemporal Patterning and Cell Fate Determinationmentioning

confidence: 99%

Section: Spatiotemporal Patterning and Cell Fate Determinationmentioning

confidence: 99%

Section: Spatiotemporal Patterning and Evolution Of New Cell Typesmentioning

confidence: 99%

See 1 more Smart Citation

Integration of Spatial and Temporal Patterning in the Invertebrate and Vertebrate Nervous System

Chen

Κωνσταντινίδης

2022

Front. Neurosci.

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“…How gene expression programs controlling quiescence, proliferation, self-renewal, and differentiation can be both stable and plastic is the subject of much study, often focusing on understanding the transcriptional networks that maintain cell identity and the inputs that destabilize these networks and allow cells to change fate. Our understanding of these networks has grown and is continually being refined, showing that various stable network states exist and explaining transitions between these states ( Kim et al, 2008 ; Moignard et al, 2013 ; Theunissen and Jaenisch, 2017 ; Kim et al, 2020 ; Sagner et al, 2021 ). Furthermore, we have gained considerable understanding of the epigenetic changes that reinforce these transcriptional changes and ensure that stem cells maintain plasticity in gene expression while differentiating cells gradually become restricted in potential ( Lunyak and Rosenfeld, 2008 ; Ohbo and Tomizawa, 2015 ; Theunissen and Jaenisch, 2017 ; Ding et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

mRNA Translation Is Dynamically Regulated to Instruct Stem Cell Fate

Wang

Amoyel

2022

Front. Mol. Biosci.

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Stem cells preserve tissue homeostasis by replacing the cells lost through damage or natural turnover. Thus, stem cells and their daughters can adopt two identities, characterized by different programs of gene expression and metabolic activity. The composition and regulation of these programs have been extensively studied, particularly by identifying transcription factor networks that define cellular identity and the epigenetic changes that underlie the progressive restriction in gene expression potential. However, there is increasing evidence that post-transcriptional mechanisms influence gene expression in stem cells and their progeny, in particular through the control of mRNA translation. Here, we review the described roles of translational regulation in controlling all aspects of stem cell biology, from the decision to enter or exit quiescence to maintaining self-renewal and promoting differentiation. We focus on mechanisms controlling global translation rates in cells, mTOR signaling, eIF2ɑ phosphorylation, and ribosome biogenesis and how they allow stem cells to rapidly change their gene expression in response to tissue needs or environmental changes. These studies emphasize that translation acts as an additional layer of control in regulating gene expression in stem cells and that understanding this regulation is critical to gaining a full understanding of the mechanisms that underlie fate decisions in stem cells.

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“…1A) (26,36). Descriptions of similar temporal patterning systems are emerging in mammalian neural stem cells, but they remain much less characterized (4,(37)(38)(39).…”

Section: Introductionmentioning

confidence: 99%

Regulation of developmental hierarchy inDrosophilaneural stem cell tumors by COMPASS and Polycomb complexes

2022

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COMPASS and Polycomb complexes are antagonistic chromatin complexes that are frequently inactivated in cancers, but how these events affect the cellular hierarchy, composition, and growth of tumors is unclear. These characteristics can be systematically investigated in Drosophila neuroblast tumors in which cooption of temporal patterning induces a developmental hierarchy that confers cancer stem cell (CSC) properties to a subset of neuroblasts retaining an early larval temporal identity. Here, using single-cell transcriptomics, we reveal that the trithorax/MLL1/2-COMPASS–like complex guides the developmental trajectory at the top of the tumor hierarchy. Consequently, trithorax knockdown drives larval-to-embryonic temporal reversion and the marked expansion of CSCs that remain locked in a spectrum of early temporal states. Unexpectedly, this phenotype is amplified by concomitant inactivation of Polycomb repressive complex 2 genes, unleashing tumor growth. This study illustrates how inactivation of specific COMPASS and Polycomb complexes cooperates to impair tumor hierarchies, inducing CSC plasticity, heterogeneity, and expansion.

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A shared transcriptional code orchestrates temporal patterning of the central nervous system

Cited by 60 publications

References 117 publications

Integration of Spatial and Temporal Patterning in the Invertebrate and Vertebrate Nervous System

Integration of Spatial and Temporal Patterning in the Invertebrate and Vertebrate Nervous System

mRNA Translation Is Dynamically Regulated to Instruct Stem Cell Fate

Regulation of developmental hierarchy inDrosophilaneural stem cell tumors by COMPASS and Polycomb complexes

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