Your search keyword '"David A. Harmin"' showing total 7 results

1. Modeling human telencephalic development and autism-associated SHANK3 deficiency using organoids generated from single neural rosettes

Author

Yueqi Wang, Simone Chiola, Guang Yang, Chad Russell, Celeste J. Armstrong, Yuanyuan Wu, Jay Spampanato, Paisley Tarboton, H. M. Arif Ullah, Nicolas U. Edgar, Amelia N. Chang, David A. Harmin, Vittoria Dickinson Bocchi, Elena Vezzoli, Dario Besusso, Jun Cui, Elena Cattaneo, Jan Kubanek, and Aleksandr Shcheglovitov

Subjects

Science

Abstract

Our understanding of human brain development in health and disease is limited. The authors generated human brain organoids from stem cell-derived isolated single neural rosettes to study human cortico-striatal development and deficits caused by an autism-associated genetic abnormality in SHANK3.

Published

2022

2. SnapShot-Seq: a method for extracting genome-wide, in vivo mRNA dynamics from a single total RNA sample.

Author

Jesse M Gray, David A Harmin, Sarah A Boswell, Nicole Cloonan, Thomas E Mullen, Joseph J Ling, Nimrod Miller, Scott Kuersten, Yong-Chao Ma, Steven A McCarroll, Sean M Grimmond, and Michael Springer

Subjects

Medicine, Science

Abstract

mRNA synthesis, processing, and destruction involve a complex series of molecular steps that are incompletely understood. Because the RNA intermediates in each of these steps have finite lifetimes, extensive mechanistic and dynamical information is encoded in total cellular RNA. Here we report the development of SnapShot-Seq, a set of computational methods that allow the determination of in vivo rates of pre-mRNA synthesis, splicing, intron degradation, and mRNA decay from a single RNA-Seq snapshot of total cellular RNA. SnapShot-Seq can detect in vivo changes in the rates of specific steps of splicing, and it provides genome-wide estimates of pre-mRNA synthesis rates comparable to those obtained via labeling of newly synthesized RNA. We used SnapShot-Seq to investigate the origins of the intrinsic bimodality of metazoan gene expression levels, and our results suggest that this bimodality is partly due to spillover of transcriptional activation from highly expressed genes to their poorly expressed neighbors. SnapShot-Seq dramatically expands the information obtainable from a standard RNA-Seq experiment.

Published

2014

3. Epigenomic Profiling and Single-Nucleus-RNA-Seq Reveal Cis-Regulatory Elements in Human Retina, Macula and RPE and Non-Coding Genetic Variation

Author

Peter Tao, Evan M. Jones, David A. Harmin, Rui Chen, Rando Allikmets, Michael E. Greenberg, Marty G. Yang, Timothy J. Cherry, Miriam Bauwens, Andrew E. Timms, and Elfride De Baere

Subjects

Retina, medicine.anatomical_structure, Retinal pigment epithelium, Genetic variation, Gene expression, medicine, RNA-Seq, Computational biology, Biology, Phenotype, Transcription factor, Epigenomics

Abstract

Cis-regulatory elements (CREs) orchestrate the dynamic and diverse transcriptional programs that assemble the human central nervous system (CNS) during development and maintain its function throughout life. Genetic variation within CREs plays a central role in phenotypic variation in complex traits including the risk of developing disease. However, the cellular complexity of the human brain has largely precluded the identification of functional regulatory variation within the human CNS. We took advantage of the retina, a well-characterized region of the CNS with reduced cellular heterogeneity, to establish a roadmap for characterizing regulatory variation in the human CNS. This comprehensive resource of tissue-specific regulatory elements, transcription factor binding, and gene expression programs in three regions of the human visual system (retina, macula, retinal pigment epithelium/choroid) reveals features of regulatory element evolution that shape tissue-specific gene expression programs and defines the regulatory elements with the potential to contribute to mendelian and complex disorders of human vision.

Published

2018

4. SnapShot-Seq: A Method for Extracting Genome-Wide, In Vivo mRNA Dynamics from a Single Total RNA Sample

Author

Nicole Cloonan, Jesse M. Gray, Nimrod Miller, David A. Harmin, Scott Kuersten, Yong Chao Ma, Steven A. McCarroll, Michael Springer, Thomas E. Mullen, Sarah A. Boswell, Sean M. Grimmond, and Joseph J. Ling

Subjects

RNA Stability, Transcription, Genetic, RNA Splicing, genetic processes, DNA transcription, lcsh:Medicine, Computational biology, Biology, Gene Splicing, Molecular Genetics, Transcription (biology), Gene expression, Genetics, RNA Precursors, Biflavonoids, Humans, natural sciences, Gene Regulation, RNA, Messenger, lcsh:Science, Multidisciplinary, Sequence Analysis, RNA, Alternative splicing, lcsh:R, Intron, RNA, Computational Biology, High-Throughput Nucleotide Sequencing, Genomics, Models, Theoretical, Introns, Functional Genomics, Alternative Splicing, RNA processing, RNA editing, RNA splicing, lcsh:Q, Genome Expression Analysis, Monte Carlo Method, Research Article, HeLa Cells

Abstract

mRNA synthesis, processing, and destruction involve a complex series of molecular steps that are incompletely understood. Because the RNA intermediates in each of these steps have finite lifetimes, extensive mechanistic and dynamical information is encoded in total cellular RNA. Here we report the development of SnapShot-Seq, a set of computational methods that allow the determination of in vivo rates of pre-mRNA synthesis, splicing, intron degradation, and mRNA decay from a single RNA-Seq snapshot of total cellular RNA. SnapShot-Seq can detect in vivo changes in the rates of specific steps of splicing, and it provides genome-wide estimates of pre-mRNA synthesis rates comparable to those obtained via labeling of newly synthesized RNA. We used SnapShot-Seq to investigate the origins of the intrinsic bimodality of metazoan gene expression levels, and our results suggest that this bimodality is partly due to spillover of transcriptional activation from highly expressed genes to their poorly expressed neighbors. SnapShot-Seq dramatically expands the information obtainable from a standard RNA-Seq experiment.

Published

2014

5. MEF2D Drives Photoreceptor Development through a Genome-wide Competition for Tissue-Specific Enhancers

Author

David A. Harmin, Martin Hemberg, Michael A. Sandberg, Steven W. Flavell, Charlotte E. Lee, Michael E. Greenberg, Annabel C. Boeke, Athar N. Malik, Timothy J. Cherry, Elio Raviola, Milena M. Andzelm, and Basil S. Pawlyk

Subjects

Mef2, Chromatin Immunoprecipitation, genetic structures, Neuroscience(all), Green Fluorescent Proteins, Enhancer RNAs, Biology, Cell fate determination, Retina, 03 medical and health sciences, Mice, 0302 clinical medicine, Electroretinography, Animals, Photoreceptor Cells, Enhancer, Eye Proteins, Gene, 030304 developmental biology, Genetics, Regulation of gene expression, Homeodomain Proteins, Mice, Knockout, 0303 health sciences, Genome, Adaptation, Ocular, MEF2 Transcription Factors, General Neuroscience, Age Factors, Gene Expression Regulation, Developmental, Embryo, Mammalian, Cell biology, Mice, Inbred C57BL, Animals, Newborn, Mutation, Trans-Activators, sense organs, Chromatin immunoprecipitation, 030217 neurology & neurosurgery

Abstract

SummaryOrganismal development requires the precise coordination of genetic programs to regulate cell fate and function. MEF2 transcription factors (TFs) play essential roles in this process but how these broadly expressed factors contribute to the generation of specific cell types during development is poorly understood. Here we show that despite being expressed in virtually all mammalian tissues, in the retina MEF2D binds to retina-specific enhancers and controls photoreceptor cell development. MEF2D achieves specificity by cooperating with a retina-specific factor CRX, which recruits MEF2D away from canonical MEF2 binding sites and redirects it to retina-specific enhancers that lack the consensus MEF2-binding sequence. Once bound to retina-specific enhancers, MEF2D and CRX co-activate the expression of photoreceptor-specific genes that are critical for retinal function. These findings demonstrate that broadly expressed TFs acquire specific functions through competitive recruitment to enhancers by tissue-specific TFs and through selective activation of these enhancers to regulate tissue-specific genes.

6. Genome-Wide Activity-Dependent MeCP2 Phosphorylation Regulates Nervous System Development and Function

Author

Vanessa K. Verdine, Ashley N. Hutchinson, Daniel H. Ebert, Anne E. West, L. Amanda Sadacca, Martin Hemberg, Sonia Cohen, Zhaolan Zhou, David A. Harmin, Michael E. Greenberg, William C. Wetsel, Rachel S. Greenberg, and Harrison W. Gabel

Subjects

Chromatin Immunoprecipitation, congenital, hereditary, and neonatal diseases and abnormalities, Methyl-CpG-Binding Protein 2, Neuroscience(all), Biology, Chromatin remodeling, Article, MECP2, Synapse, 03 medical and health sciences, Mice, 0302 clinical medicine, mental disorders, Animals, Gene Knock-In Techniques, Phosphorylation, 030304 developmental biology, Regulation of gene expression, Neurons, 0303 health sciences, Genome, General Neuroscience, Brain, Gene Expression Regulation, Developmental, Dendrites, Chromatin, Cell biology, nervous system diseases, Mice, Inbred C57BL, Exploratory Behavior, Chromatin immunoprecipitation, 030217 neurology & neurosurgery, Synapse maturation

Abstract

SummaryAutism spectrum disorders such as Rett syndrome (RTT) have been hypothesized to arise from defects in experience-dependent synapse maturation. RTT is caused by mutations in MECP2, a nuclear protein that becomes phosphorylated at S421 in response to neuronal activation. We show here that disruption of MeCP2 S421 phosphorylation in vivo results in defects in synapse development and behavior, implicating activity-dependent regulation of MeCP2 in brain development and RTT. We investigated the mechanism by which S421 phosphorylation regulates MeCP2 function and show by chromatin immunoprecipitation-sequencing that this modification occurs on MeCP2 bound across the genome. The phosphorylation of MeCP2 S421 appears not to regulate the expression of specific genes; rather, MeCP2 functions as a histone-like factor whose phosphorylation may facilitate a genome-wide response of chromatin to neuronal activity during nervous system development. We propose that RTT results in part from a loss of this experience-dependent chromatin remodeling.

7. START: an automated tool for serial analysis of chromatin occupancy data.

Author

Voichita D. Marinescu, Isaac S. Kohane, Tae-Kyung Kim, David A. Harmin, Michael E. Greenberg, and Alberto Riva

Published

2006