Comprehensive analysis of retinal development at single cell resolution identifies NFI factors as essential for mitotic exit and specification of late-born cells
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Brian S. Clark | Genevieve L. Stein-O’Brien | L. Goff | E. Fertig | Fion Shiau | Gabrielle H. Cannon | E. Davis | Thomas Sherman | F. Rajaii | Rebecca E. James-Esposito | R. Gronostajski | S. Blackshaw | G. Stein-O’Brien
[1] R. W. Young. Cell proliferation during postnatal development of the retina in the mouse. , 1985, Brain research.
[2] R. W. Young. Cell differentiation in the retina of the mouse , 1985, The Anatomical record.
[3] Constance L. Cepko,et al. A common progenitor for neurons and glia persists in rat retina late in development , 1987, Nature.
[4] C. Cepko,et al. Lineage-independent determination of cell type in the embryonic mouse retina , 1990, Neuron.
[5] C. Cepko,et al. Quantitative analysis of proliferation and cell cycle length during development of the rat retina , 1996, Developmental dynamics : an official publication of the American Association of Anatomists.
[6] C. Barnstable,et al. The subcellular localization of Otx2 is cell-type specific and developmentally regulated in the mouse retina. , 2000, Brain research. Molecular brain research.
[7] F. J. Livesey,et al. Vertebrate neural cell-fate determination: Lessons from the retina , 2001, Nature Reviews Neuroscience.
[8] Seth Blackshaw,et al. Comprehensive Analysis of Photoreceptor Gene Expression and the Identification of Candidate Retinal Disease Genes , 2001, Cell.
[9] Yasuo Tano,et al. Otx2 homeobox gene controls retinal photoreceptor cell fate and pineal gland development , 2003, Nature Neuroscience.
[10] C. Cepko,et al. Genetic analysis of the homeodomain transcription factor Chx10 in the retina using a novel multifunctional BAC transgenic mouse reporter. , 2004, Developmental biology.
[11] L. Ohno-Machado,et al. Genomic Analysis of Mouse Retinal Development , 2004, PLoS biology.
[12] J. Rubenstein,et al. Dlx1 and Dlx2 function is necessary for terminal differentiation and survival of late-born retinal ganglion cells in the developing mouse retina , 2005, Development.
[13] C. Cepko,et al. Notch activity permits retinal cells to progress through multiple progenitor states and acquire a stem cell property , 2006, Proceedings of the National Academy of Sciences.
[14] David J. Anderson,et al. The Transcription Factor NFIA Controls the Onset of Gliogenesis in the Developing Spinal Cord , 2006, Neuron.
[15] Michael F. Ochs,et al. Determining Transcription Factor Activity from Microarray Data using Bayesian Markov Chain Monte Carlo Sampling , 2007, MedInfo.
[16] J. Baizer,et al. The transcription factor Nfix is essential for normal brain development , 2008, BMC Developmental Biology.
[17] Geoffrey E. Hinton,et al. Visualizing Data using t-SNE , 2008 .
[18] Michael B. Stadler,et al. Individual Retinal Progenitor Cells Display Extensive Heterogeneity of Gene Expression , 2008, PloS one.
[19] Michael B. Stadler,et al. The transcriptome of retinal Müller glial cells , 2008, The Journal of comparative neurology.
[20] M. Cayouette,et al. Ikaros Confers Early Temporal Competence to Mouse Retinal Progenitor Cells , 2008, Neuron.
[21] H. Okano,et al. Cell types to order: temporal specification of CNS stem cells , 2009, Current Opinion in Neurobiology.
[22] J. N. Kay,et al. Birthdays of retinal amacrine cell subtypes are systematically related to their molecular identity and soma position , 2009, The Journal of comparative neurology.
[23] T. Reh,et al. Acheate‐scute like 1 (Ascl1) is required for normal delta‐like (Dll) gene expression and notch signaling during retinal development , 2009, Developmental dynamics : an official publication of the American Association of Anatomists.
[24] M. Kondo,et al. Blimp1 Suppresses Chx10 Expression in Differentiating Retinal Photoreceptor Precursors to Ensure Proper Photoreceptor Development , 2010, The Journal of Neuroscience.
[25] Jie Ding,et al. CoGAPS: an R/C++ package to identify patterns and biological process activity in transcriptomic data , 2010, Bioinform..
[26] T. Reh,et al. Blimp1 controls photoreceptor versus bipolar cell fate choice during retinal development , 2010, Development.
[27] Felix Carbonell,et al. Reconstruction of rat retinal progenitor cell lineages in vitro reveals a surprising degree of stochasticity in cell fate decisions , 2011, Development.
[28] S. Wood. Fast stable restricted maximum likelihood and marginal likelihood estimation of semiparametric generalized linear models , 2011 .
[29] T. Reh,et al. Genome-Wide Analysis of Müller Glial Differentiation Reveals a Requirement for Notch Signaling in Postmitotic Cells to Maintain the Glial Fate , 2011, PloS one.
[30] Song Liu,et al. Mesenchymal nuclear factor I B regulates cell proliferation and epithelial differentiation during lung maturation. , 2011, Developmental biology.
[31] Euiseok J. Kim,et al. Ascl1 expression defines a subpopulation of lineage-restricted progenitors in the mammalian retina , 2011, Development.
[32] R. Gronostajski,et al. Sox9 and NFIA Coordinate a Transcriptional Regulatory Cascade during the Initiation of Gliogenesis , 2012, Neuron.
[33] W. Harris,et al. How Variable Clones Build an Invariant Retina , 2012, Neuron.
[34] T. Glaser,et al. Math5 defines the ganglion cell competence state in a subpopulation of retinal progenitor cells exiting the cell cycle. , 2012, Developmental biology.
[35] W. Harris,et al. Biasing Amacrine Subtypes in the Atoh7 Lineage through Expression of Barhl2 , 2012, The Journal of Neuroscience.
[36] François Guillemot,et al. Molecular control of neurogenesis: a view from the mammalian cerebral cortex. , 2012, Cold Spring Harbor perspectives in biology.
[37] S. Scholpp,et al. Neurogenesis in zebrafish – from embryo to adult , 2013, Neural Development.
[38] Michael F. Ochs,et al. Matrix factorization for transcriptional regulatory network inference , 2012, 2012 IEEE Symposium on Computational Intelligence in Bioinformatics and Computational Biology (CIBCB).
[39] Kevin T. Beier,et al. Transcription factor Olig2 defines subpopulations of retinal progenitor cells biased toward specific cell fates , 2012, Proceedings of the National Academy of Sciences.
[40] Stephen T. C. Wong,et al. The miR-223/Nuclear Factor I-A Axis Regulates Glial Precursor Proliferation and Tumorigenesis in the CNS , 2013, The Journal of Neuroscience.
[41] C. Doe,et al. Temporal fate specification and neural progenitor competence during development , 2013, Nature Reviews Neuroscience.
[42] C. Cepko,et al. Otx2 and Onecut1 promote the fates of cone photoreceptors and horizontal cells and repress rod photoreceptors. , 2013, Developmental cell.
[43] V. Lefebvre,et al. Transcription Factors SOX4 and SOX11 Function Redundantly to Regulate the Development of Mouse Retinal Ganglion Cells* , 2013, The Journal of Biological Chemistry.
[44] W. Harris,et al. Progenitor Competence: Genes Switching Places , 2013, Cell.
[45] J. L. Mateo,et al. Epigenomic enhancer annotation reveals a key role for NFIX in neural stem cell quiescence , 2013, Genes & development.
[46] D. Geman,et al. Learning Dysregulated Pathways in Cancers from Differential Variability Analysis , 2014, Cancer informatics.
[47] M. Wegner,et al. Mutual Antagonism Between Sox10 and NFIA Regulates Diversification of Glial Lineages and Glioma Sub-Types , 2014, Nature Neuroscience.
[48] X. Mu,et al. Isl1 and Pou4f2 Form a Complex to Regulate Target Genes in Developing Retinal Ganglion Cells , 2014, PloS one.
[49] Cole Trapnell,et al. The dynamics and regulators of cell fate decisions are revealed by pseudotemporal ordering of single cells , 2014, Nature Biotechnology.
[50] Wieland B Huttner,et al. The cell biology of neurogenesis: toward an understanding of the development and evolution of the neocortex. , 2014, Annual review of cell and developmental biology.
[51] C. Cepko. Intrinsically different retinal progenitor cells produce specific types of progeny , 2014, Nature Reviews Neuroscience.
[52] Marko Repic,et al. Proliferation control in neural stem and progenitor cells , 2015, Nature Reviews Neuroscience.
[53] Evan Z. Macosko,et al. Highly Parallel Genome-wide Expression Profiling of Individual Cells Using Nanoliter Droplets , 2015, Cell.
[54] P. Mattar,et al. A Conserved Regulatory Logic Controls Temporal Identity in Mouse Neural Progenitors , 2015, Neuron.
[55] L. Richards,et al. NFIX Regulates Proliferation and Migration Within the Murine SVZ Neurogenic Niche. , 2015, Cerebral cortex.
[56] Lars E. Borm,et al. Molecular Diversity of Midbrain Development in Mouse, Human, and Stem Cells , 2016, Cell.
[57] Brian S. Clark,et al. Multiple intrinsic factors act in concert with Lhx2 to direct retinal gliogenesis , 2016, Scientific Reports.
[58] Toru Ogata,et al. Zbtb20 promotes astrocytogenesis during neocortical development , 2016, Nature Communications.
[59] Brian S. Clark,et al. Lhx2 Is an Essential Factor for Retinal Gliogenesis and Notch Signaling , 2016, The Journal of Neuroscience.
[60] Lauren A. Laboissonniere,et al. Expression Profiling of Developing Zebrafish Retinal Cells. , 2016, Zebrafish.
[61] Evan Z. Macosko,et al. Comprehensive Classification of Retinal Bipolar Neurons by Single-Cell Transcriptomics , 2016, Cell.
[62] Luca Scrucca,et al. mclust 5: Clustering, Classification and Density Estimation Using Gaussian Finite Mixture Models , 2016, R J..
[63] Grace X. Y. Zheng,et al. Massively parallel digital transcriptional profiling of single cells , 2016, Nature Communications.
[64] Hannah A. Pliner,et al. Reversed graph embedding resolves complex single-cell trajectories , 2017, Nature Methods.
[65] P. Rigollet,et al. Reconstruction of developmental landscapes by optimal-transport analysis of single-cell gene expression sheds light on cellular reprogramming , 2017, bioRxiv.
[66] Vijender Chaitankar,et al. Molecular Anatomy of the Developing Human Retina. , 2017, Developmental cell.
[67] Lauren A. Laboissonniere,et al. Single cell transcriptome profiling of developing chick retinal cells , 2017, The Journal of comparative neurology.
[68] Michael F. Ochs,et al. PatternMarkers & GWCoGAPS for novel data-driven biomarkers via whole transcriptome NMF , 2016, bioRxiv.
[69] R. Wilson,et al. The Dynamic Epigenetic Landscape of the Retina During Development, Reprogramming, and Tumorigenesis , 2017, Neuron.
[70] Alex A. Pollen,et al. Spatiotemporal gene expression trajectories reveal developmental hierarchies of the human cortex , 2017, Science.
[71] Aedín C. Culhane,et al. Enter the matrix: factorization uncovers knowledge from omics Names/Affiliations , 2018 .
[72] L. Goff,et al. Variation in Activity State, Axonal Projection, and Position Define the Transcriptional Identity of Individual Neocortical Projection Neurons. , 2018, Cell reports.
[73] Leland McInnes,et al. UMAP: Uniform Manifold Approximation and Projection for Dimension Reduction , 2018, ArXiv.
[74] Christoph Hafemeister,et al. Developmental diversification of cortical inhibitory interneurons , 2017, Nature.
[75] Alexander V. Favorov,et al. Enter the Matrix: Factorization Uncovers Knowledge from Omics , 2018, Trends in genetics : TIG.
[76] Jie Qiao,et al. A single-cell RNA-seq survey of the developmental landscape of the human prefrontal cortex , 2018, Nature.
[77] Alexander V. Favorov,et al. Integrated time course omics analysis distinguishes immediate therapeutic response from acquired resistance , 2018, Genome Medicine.
[78] David Fenyö,et al. A toolbox of immunoprecipitation-grade monoclonal antibodies to human transcription factors , 2018, Nature Methods.
[79] S. Blackshaw,et al. In Vivo Electroporation of Developing Mouse Retina. , 2018, Methods in molecular biology.