Your search keyword '"neuron progenitor"' showing total 4 results

1. Cell Surface N-Glycans Influence Electrophysiological Properties and Fate Potential of Neural Stem Cells.

Author

Yale, Andrew R, Nourse, Jamison L, Lee, Kayla R, Ahmed, Syed N, Arulmoli, Janahan, Jiang, Alan YL, McDonnell, Lisa P, Botten, Giovanni A, Lee, Abraham P, Monuki, Edwin S, Demetriou, Michael, and Flanagan, Lisa A

Subjects

Brain, Astrocytes, Cell Membrane, Animals, Mice, N-Acetylneuraminic Acid, Acetylglucosamine, Fucose, Polysaccharides, Cell Differentiation, Cell Proliferation, Cell Size, Cell Survival, Gene Expression Regulation, Glycosylation, Cell Lineage, Stem Cell Niche, Neurogenesis, Electrophysiological Phenomena, Neural Stem Cells, L-PHA, MGAT, astrocyte progenitor, biophysical, branch, dielectrophoresis, glycosylation, membrane capacitance, mouse, neuron progenitor, Brain Disorders, Regenerative Medicine, Stem Cell Research, Stem Cell Research - Nonembryonic - Non-Human, Neurosciences, 1.1 Normal biological development and functioning, Underpinning research, Biochemistry and Cell Biology, Clinical Sciences

Abstract

Understanding the cellular properties controlling neural stem and progenitor cell (NSPC) fate choice will improve their therapeutic potential. The electrophysiological measure whole-cell membrane capacitance reflects fate bias in the neural lineage but the cellular properties underlying membrane capacitance are poorly understood. We tested the hypothesis that cell surface carbohydrates contribute to NSPC membrane capacitance and fate. We found NSPCs differing in fate potential express distinct patterns of glycosylation enzymes. Screening several glycosylation pathways revealed that the one forming highly branched N-glycans differs between neurogenic and astrogenic populations of cells in vitro and in vivo. Enhancing highly branched N-glycans on NSPCs significantly increases membrane capacitance and leads to the generation of more astrocytes at the expense of neurons with no effect on cell size, viability, or proliferation. These data identify the N-glycan branching pathway as a significant regulator of membrane capacitance and fate choice in the neural lineage.

Published

2018

2. Membrane biophysics define neuron and astrocyte progenitors in the neural lineage.

Author

Nourse, J, Prieto, J, Dickson, A, Lu, J, Flanagan, L, Lee, Abraham, Demetriou, Michael, Tombola, Francesco, and Pathak, Medha

Subjects

Astrocyte progenitor, Biophysical properties, Dielectrophoresis, Electrophysiological properties, Glycosylation, Neural stem cell, Neuron progenitor, Animals, Astrocytes, Biophysical Phenomena, Cell Lineage, Cell Membrane, Cell Separation, Cell Size, Electrophysiological Phenomena, Glycosylation, Membrane Potentials, Mice, Microfluidics, Neural Stem Cells, Neurons

Abstract

Neural stem and progenitor cells (NSPCs) are heterogeneous populations of self-renewing stem cells and more committed progenitors that differentiate into neurons, astrocytes, and oligodendrocytes. Accurately identifying and characterizing the different progenitor cells in this lineage has continued to be a challenge for the field. We found previously that populations of NSPCs with more neurogenic progenitors (NPs) can be distinguished from those with more astrogenic progenitors (APs) by their inherent biophysical properties, specifically the electrophysiological property of whole cell membrane capacitance, which we characterized with dielectrophoresis (DEP). Here, we hypothesize that inherent electrophysiological properties are sufficient to define NPs and APs and test this by determining whether isolation of cells solely by these properties specifically separates NPs and APs. We found NPs and APs are enriched in distinct fractions after separation by electrophysiological properties using DEP. A single round of DEP isolation provided greater NP enrichment than sorting with PSA-NCAM, which is considered an NP marker. Additionally, cell surface N-linked glycosylation was found to significantly affect cell fate-specific electrophysiological properties, providing a molecular basis for the cell membrane characteristics. Inherent plasma membrane biophysical properties are thus sufficient to define progenitor cells of differing fate potential in the neural lineage, can be used to specifically isolate these cells, and are linked to patterns of glycosylation on the cell surface.

Published

2014

3. Characterization of a subpopulation of developing cortical interneurons from human iPSCs within serum-free embryoid bodies.

Author

Nestor, Michael W., Jacob, Samson, Sun, Bruce, Prè, Deborah, Sproul, Andrew A., Seong Im Hong, Woodard, Chris, Zimmer, Matthew, Chinchalongporn, Vorapin, Arancio, Ottavio, and Noggle, Scott A.

Subjects

*CEREBRAL cortex, *INDUCED pluripotent stem cells, *INTERNEURONS, *CELL aggregation, *GABA, *CALRETININ, *IMMUNOCYTOCHEMISTRY, *GANGLIA

Abstract

Production and isolation of forebrain interneuron progenitors are essential for understanding cortical development and developing cell-based therapies for developmental and neurodegenerative disorders. We demonstrate production of a population of putative calretinin-positive bipolar interneurons that express markers consistent with caudal ganglionic eminence identities. Using serum-free embryoid bodies (SFEBs) generated from human inducible pluripotent stem cells (iPSCs), we demonstrate that these interneuron progenitors exhibit morphological, immunocytochemical, and electrophysiological hallmarks of developing cortical interneurons. Finally, we develop a fluorescence-activated cell-sorting strategy to isolate interneuron progenitors from SFEBs to allow development of a purified population of these cells. Identification of this critical neuronal cell type within iPSC-derived SFEBs is an important and novel step in describing cortical development in this iPSC preparation. [ABSTRACT FROM AUTHOR]

Published

2015

4. Cell Surface N-Glycans Influence Electrophysiological Properties and Fate Potential of Neural Stem Cells

Author

Lisa P. McDonnell, Syed N. Ahmed, Kayla R. Lee, Jamison L. Nourse, Giovanni A. Botten, Michael A. Demetriou, Alan Y.L. Jiang, Edwin S. Monuki, Janahan Arulmoli, Andrew R Yale, Lisa A. Flanagan, and Abraham P. Lee

Subjects

0301 basic medicine, Glycosylation, Cell, Regulator, Biochemistry, neuron progenitor, chemistry.chemical_compound, Mice, Neural Stem Cells, Stem Cell Niche, lcsh:QH301-705.5, Membrane potential, MGAT, lcsh:R5-920, biology, Brain, Cell Differentiation, Neural stem cell, Cell biology, medicine.anatomical_structure, lcsh:Medicine (General), Glycan, glycosylation, Cell Survival, Neurogenesis, Article, Acetylglucosamine, 03 medical and health sciences, membrane capacitance, Polysaccharides, Genetics, medicine, Animals, Cell Lineage, Progenitor cell, mouse, Cell Proliferation, Cell Size, Fucose, dielectrophoresis, Cell Membrane, Cell Biology, biophysical, branch, L-PHA, N-Acetylneuraminic Acid, Electrophysiological Phenomena, carbohydrates (lipids), Electrophysiology, 030104 developmental biology, lcsh:Biology (General), chemistry, Gene Expression Regulation, Astrocytes, biology.protein, astrocyte progenitor, Developmental Biology

Abstract

Summary Understanding the cellular properties controlling neural stem and progenitor cell (NSPC) fate choice will improve their therapeutic potential. The electrophysiological measure whole-cell membrane capacitance reflects fate bias in the neural lineage but the cellular properties underlying membrane capacitance are poorly understood. We tested the hypothesis that cell surface carbohydrates contribute to NSPC membrane capacitance and fate. We found NSPCs differing in fate potential express distinct patterns of glycosylation enzymes. Screening several glycosylation pathways revealed that the one forming highly branched N-glycans differs between neurogenic and astrogenic populations of cells in vitro and in vivo. Enhancing highly branched N-glycans on NSPCs significantly increases membrane capacitance and leads to the generation of more astrocytes at the expense of neurons with no effect on cell size, viability, or proliferation. These data identify the N-glycan branching pathway as a significant regulator of membrane capacitance and fate choice in the neural lineage., Highlights • Biophysical property membrane capacitance reflects fate bias in the neural lineage • N-Glycan branching identifies cells with different fates in vitro and in vivo • N-Glycan branching accounts for capacitance differences reflecting fate • Branching affects fate, leading to more differentiated astrocytes and fewer neurons, Flanagan and colleagues tested glycosylation contributions to a unique, fate-specific electrophysiological property of neural stem cells. They found the N-glycan branching pathway generating highly branched N-glycans associated with astrocyte fate. Enhanced branching shifted the electrophysiological property and fate potential of neural stem cells toward astrocytes, revealing the importance of N-glycan branching to neural stem cell differentiation.

Published

2017