Your search keyword '"Pyramidal Neuron"' showing total 10 results

1. SUMOylation of NaV1.2 channels regulates the velocity of backpropagating action potentials in cortical pyramidal neurons

Author

Kotler, Oron, Khrapunsky, Yana, Shvartsman, Arik, Dai, Hui, Plant, Leigh D, Goldstein, Steven AN, and Fleidervish, Ilya

Subjects

Biomedical and Clinical Sciences, Neurosciences, Underpinning research, 1.1 Normal biological development and functioning, Mice, Animals, Action Potentials, Sumoylation, Pyramidal Cells, Neurons, Axon Initial Segment, SUMO, pyramidal neuron, axon initial segment, persistent sodium current, action potential, backpropagation, Mouse, mouse, neuroscience, Biochemistry and Cell Biology, Biological sciences, Biomedical and clinical sciences, Health sciences

Abstract

Voltage-gated sodium channels located in axon initial segments (AIS) trigger action potentials (AP) and play pivotal roles in the excitability of cortical pyramidal neurons. The differential electrophysiological properties and distributions of NaV1.2 and NaV1.6 channels lead to distinct contributions to AP initiation and propagation. While NaV1.6 at the distal AIS promotes AP initiation and forward propagation, NaV1.2 at the proximal AIS promotes the backpropagation of APs to the soma. Here, we show the small ubiquitin-like modifier (SUMO) pathway modulates Na+ channels at the AIS to increase neuronal gain and the speed of backpropagation. Since SUMO does not affect NaV1.6, these effects were attributed to SUMOylation of NaV1.2. Moreover, SUMO effects were absent in a mouse engineered to express NaV1.2-Lys38Gln channels that lack the site for SUMO linkage. Thus, SUMOylation of NaV1.2 exclusively controls INaP generation and AP backpropagation, thereby playing a prominent role in synaptic integration and plasticity.

Published

2023

2. FMRP regulates the subcellular distribution of cortical dendritic spine density in a non-cell-autonomous manner

Author

Bland, Katherine M, Aharon, Adam, Widener, Eden L, Song, M Irene, Casey, Zachary O, Zuo, Yi, and Vidal, George S

Subjects

Biomedical and Clinical Sciences, Neurosciences, Brain Disorders, Fragile X Syndrome, Rare Diseases, Mental Health, Intellectual and Developmental Disabilities (IDD), Neurological, Animals, Cerebral Cortex, Dendritic Spines, Female, Fragile X Mental Retardation Protein, Heterozygote, Male, Mice, Mice, Knockout, Mosaicism, Pyramidal Cells, X Chromosome Inactivation, Fmr1, Dendritic spine, Dendrite, Layer V, Layer 5, Pyramidal neuron, Cerebral cortex, Mosaic, Cell-autonomous, Clinical Sciences, Neurology & Neurosurgery, Biochemistry and cell biology

Abstract

Fragile X syndrome (FXS) is the most common form of intellectual disability that arises from the dysfunction of a single gene-Fmr1. The main neuroanatomical correlate of FXS is elevated dendritic spine density on cortical pyramidal neurons, which has been modeled in Fmr1-/Y mice. However, the cell-autonomous contribution of Fmr1 on cortical dendritic spine density has not been assessed. Even less is known about the role of Fmr1 in heterozygous female mosaic mice, which are a putative model for human Fmr1 full mutation carriers (i.e., are heterozygous for the full Fmr1-silencing mutation). In this neuroanatomical study, spine density in cortical pyramidal neurons of Fmr1+/- and Fmr1-/Y mice was studied at multiple subcellular compartments, layers, and brain regions. Spine density in Fmr1+/- mice is higher than WT but lower than Fmr1-/Y. Not all subcellular compartments in layer V Fmr1+/- and Fmr1-/Y cortical pyramidal neurons are equally affected: the apical dendrite, a key subcellular compartment, is principally affected over basal dendrites. Within apical dendrites, spine density is differentially affected across branch orders. Finally, identification of FMRP-positive and FMRP-negative neurons within Fmr1+/- permitted the study of the cell-autonomous effect of Fmr1 on spine density. Surprisingly, layer V cortical pyramidal spine density between FMRP-positive and FMRP-negative neurons does not differ, suggesting that the regulation of the primary neuroanatomical defect of FXS-elevated spine density-is non-cell-autonomous.

Published

2021

3. Nicotine excites VIP interneurons to disinhibit pyramidal neurons in auditory cortex.

Author

Askew, Caitlin E, Lopez, Alberto J, Wood, Marcelo A, and Metherate, Raju

Subjects

Pyramidal Cells, Auditory Cortex, Interneurons, Animals, Mice, Nicotine, Vasoactive Intestinal Peptide, Nicotinic Agonists, Female, Male, Inhibitory Postsynaptic Potentials, VIP, interneuron, nicotine, nicotinic acetylcholine receptor, parvalbumin, pyramidal neuron, somatostatin, Neurosciences, Cognitive Sciences, Neurology & Neurosurgery

Abstract

Nicotine activates nicotinic acetylcholine receptors and improves cognitive and sensory function, in part by its actions in cortical regions. Physiological studies show that nicotine amplifies stimulus-evoked responses in sensory cortex, potentially contributing to enhancement of sensory processing. However, the role of specific cell types and circuits in the nicotinic modulation of sensory cortex remains unclear. Here, we performed whole-cell recordings from pyramidal (Pyr) neurons and inhibitory interneurons expressing parvalbumin (PV), somatostatin (SOM), and vasoactive intestinal peptide (VIP) in mouse auditory cortex, in vitro. Bath application of nicotine strongly depolarized and excited VIP neurons, weakly depolarized Pyr neurons, and had no effect on the membrane potential of SOM or PV neurons. The use of receptor antagonists showed that nicotine's effects on VIP and Pyr neurons were direct and indirect, respectively. Nicotine also enhanced the frequency of spontaneous inhibitory postsynaptic currents (sIPSCs) in Pyr, VIP, and SOM, but not PV, cells. Using Designer Receptors Exclusively Activated by Designer Drugs (DREADDs), we show that chemogenetic inhibition of VIP neurons prevents nicotine's effects on Pyr neurons. Since VIP cells preferentially contact other inhibitory interneurons, we suggest that nicotine drives VIP cell firing to disinhibit Pyr cell somata, potentially making Pyr cells more responsive to auditory stimuli. In parallel, activation of VIP cells also directly inhibits Pyr neurons, likely altering integration of other synaptic inputs. These cellular and synaptic mechanisms likely contribute to nicotine's beneficial effects on cognitive and sensory function.

Published

2019

4. Multimodal synaptic integration in the posterior parietal cortex

Author

Rindner, Daniel Jun

Subjects

Neurosciences, Dual color, Layer 5, Optogenetics, Posterior parietal cortex, Pyramidal neuron, Synaptic integration

Abstract

Integration of feedforward and feedback synaptic input is a core feature of neural circuits. Proper interaction between these pathways is critical for nearly all cognitive processes, ranging from basic sensory perception to goal-oriented behaviors including decision making, learning, attention shifting, and working memory. Due to a technical inability to selectively manipulate feedforward and feedback synaptic pathways, previous efforts to examine their interaction rely on passive measures of neural activity in human and other animals, revealing a signature, transient enhancement of neural signals during periods of top-down control. In a largely non-overlapping body of work, detailed studies of dendritic physiology have uncovered basic mechanisms underlying nonlinear enhancement of synaptic input, albeit largely agnostic to input identity. Taking advantage of recent advances in multicolor optogenetics, my thesis aims to uncover cellular mechanisms which explain the neural enhancement observed during top-down modulation. In Chapter 1, I report procedural improvements to a dual-color optogenetic approach for selectively stimulating feedforward and feedback afferents. I demonstrate an exhaustive test of experimental parameters influencing crosstalk, and lastly propose a “lookup table” strategy which minimizes cross-activation of synaptic pathways. Next, in Chapter 2 I explore how deep-layer neurons integrate synaptic input from feedforward and feedback sources, using dual-color optogenetics to expand on decades of synaptic integration work based on electrical stimulation methods. I show that layer 5 pyramidal cells in the posterior parietal cortex (PPC) receive monosynaptic dual innervation, combining inputs from sensory and frontal cortex. I then describe the distinct temporal dynamics by which subclasses of layer 5 pyramidal neurons integrate these synapses. Specifically, regular spiking (RS) cells exhibit supralinear enhancement of delayed, but not coincident inputs, while intrinsic burst firing (IB) neurons selectively boost coincident synaptic events. In explanation of this difference, I next present pharmacological and computational modelling data collected in collaboration with a postdoc in the Lur lab, indicating that distinct integration profiles arise from a cell-type specific interaction of ionic mechanisms and feedforward inhibition. Finally, in Chapter 3 I address how nonlinear enhancement of converging synaptic pathways may generate persistent firing, a neural hallmark of working memory in the PPC. In this Chapter I mimic the effect of optogenetically-evoked synaptic input via direct electrical activation of single cells, showing that projection-specific cells corresponding to RS and IB subtypes have differential propensity for persistent firing. Namely, cells corresponding to the IB subtype display longer-lasting, higher-frequency spike firing than RS during periods of sustained activation, which was not driven by differences in network connectivity between the cell types. I end with speculation of the intrinsic mechanisms which may position IB cells as preferentially engaged during periods of persistent firing.

Published

2023

5. The Planar Cell Polarity Transmembrane Protein Vangl2 Promotes Dendrite, Spine and Glutamatergic Synapse Formation in the Mammalian Forebrain.

Author

Okerlund, Nathan D, Stanley, Robert E, and Cheyette, Benjamin NR

Subjects

Dendrite, Forebrain, Planar cell polarity, Pyramidal neuron, Spine, Synapse, Vangl2, Wnt

Abstract

The transmembrane protein Vangl2, a key regulator of the Wnt/planar cell polarity (PCP) pathway, is involved in dendrite arbor elaboration, dendritic spine formation and glutamatergic synapse formation in mammalian central nervous system neurons. Cultured forebrain neurons from Vangl2 knockout mice have simpler dendrite arbors, fewer total spines, less mature spines and fewer glutamatergic synapse inputs on their dendrites than control neurons. Neurons from mice heterozygous for a semidominant Vangl2 mutation have similar but not identical phenotypes, and these phenotypes are also observed in Golgi-stained brain tissue from adult mutant mice. Given increasing evidence linking psychiatric pathophysiology to these subneuronal sites and structures, our findings underscore the relevance of core PCP proteins including Vangl2 to the underlying biology of major mental illnesses and their treatment.

Published

2016

6. The Planar Cell Polarity Transmembrane Protein Vangl2 Promotes Dendrite, Spine and Glutamatergic Synapse Formation in the Mammalian Forebrain

Author

Okerlund, Nathan D, Stanley, Robert E, and Cheyette, Benjamin NR

Subjects

Biochemistry and Cell Biology, Biomedical and Clinical Sciences, Biological Sciences, Neurosciences, Genetics, 1.1 Normal biological development and functioning, Underpinning research, Neurological, Good Health and Well Being, Dendrite, Forebrain, Planar cell polarity, Pyramidal neuron, Spine, Synapse, Vangl2, Wnt

Abstract

The transmembrane protein Vangl2, a key regulator of the Wnt/planar cell polarity (PCP) pathway, is involved in dendrite arbor elaboration, dendritic spine formation and glutamatergic synapse formation in mammalian central nervous system neurons. Cultured forebrain neurons from Vangl2 knockout mice have simpler dendrite arbors, fewer total spines, less mature spines and fewer glutamatergic synapse inputs on their dendrites than control neurons. Neurons from mice heterozygous for a semidominant Vangl2 mutation have similar but not identical phenotypes, and these phenotypes are also observed in Golgi-stained brain tissue from adult mutant mice. Given increasing evidence linking psychiatric pathophysiology to these subneuronal sites and structures, our findings underscore the relevance of core PCP proteins including Vangl2 to the underlying biology of major mental illnesses and their treatment.

Published

2016

7. Mice lacking doublecortin and doublecortin-like kinase 2 display altered hippocampal neuronal maturation and spontaneous seizures

Author

Kerjan, Géraldine, Koizumi, Hiroyuki, Han, Edward B, Dubé, Celine M, Djakovic, Stevan N, Patrick, Gentry N, Baram, Tallie Z, Heinemann, Stephen F, and Gleeson, Joseph G

Subjects

Epilepsy, Brain Disorders, Neurosciences, Neurodegenerative, 2.1 Biological and endogenous factors, Aetiology, Neurological, Animals, Cell Differentiation, Cell Polarity, Dendrites, Doublecortin Domain Proteins, Doublecortin Protein, Hippocampus, Interneurons, Mice, Mice, Knockout, Microtubule-Associated Proteins, Neurons, Neuropeptides, Protein Serine-Threonine Kinases, Proto-Oncogene Proteins c-fos, Pyramidal Cells, Seizures, Somatostatin, Survival Analysis, Synapses, Weaning, gamma-Aminobutyric Acid, epilepsy, receptive field, pyramidal neuron, dendrites, delamination

Abstract

Mutations in doublecortin (DCX) are associated with intractable epilepsy in humans, due to a severe disorganization of the neocortex and hippocampus known as classical lissencephaly. However, the basis of the epilepsy in lissencephaly remains unclear. To address potential functional redundancy with murin Dcx, we targeted one of the closest homologues, doublecortin-like kinase 2 (Dclk2). Here, we report that Dcx; Dclk2-null mice display frequent spontaneous seizures that originate in the hippocampus, with most animals dying in the first few months of life. Elevated hippocampal expression of c-fos and loss of somatostatin-positive interneurons were identified, both known to correlate with epilepsy. Dcx and Dclk2 are coexpressed in developing hippocampus, and, in their absence, there is dosage-dependent disrupted hippocampal lamination associated with a cell-autonomous simplification of pyramidal dendritic arborizations leading to reduced inhibitory synaptic tone. These data suggest that hippocampal dysmaturation and insufficient receptive field for inhibitory input may underlie the epilepsy in lissencephaly, and suggest potential therapeutic strategies for controlling epilepsy in these patients.

Published

2009

8. Mice lacking doublecortin and doublecortin-like kinase 2 display altered hippocampal neuronal maturation and spontaneous seizures.

Author

Kerjan, Géraldine, Koizumi, Hiroyuki, Han, Edward B, Dubé, Celine M, Djakovic, Stevan N, Patrick, Gentry N, Baram, Tallie Z, Heinemann, Stephen F, and Gleeson, Joseph G

Subjects

Hippocampus, Pyramidal Cells, Neurons, Dendrites, Interneurons, Synapses, Animals, Mice, Knockout, Mice, Seizures, gamma-Aminobutyric Acid, Somatostatin, Protein-Serine-Threonine Kinases, Neuropeptides, Microtubule-Associated Proteins, Proto-Oncogene Proteins c-fos, Survival Analysis, Cell Differentiation, Cell Polarity, Weaning, epilepsy, receptive field, pyramidal neuron, dendrites, delamination, Knockout, MD Multidisciplinary

Abstract

Mutations in doublecortin (DCX) are associated with intractable epilepsy in humans, due to a severe disorganization of the neocortex and hippocampus known as classical lissencephaly. However, the basis of the epilepsy in lissencephaly remains unclear. To address potential functional redundancy with murin Dcx, we targeted one of the closest homologues, doublecortin-like kinase 2 (Dclk2). Here, we report that Dcx; Dclk2-null mice display frequent spontaneous seizures that originate in the hippocampus, with most animals dying in the first few months of life. Elevated hippocampal expression of c-fos and loss of somatostatin-positive interneurons were identified, both known to correlate with epilepsy. Dcx and Dclk2 are coexpressed in developing hippocampus, and, in their absence, there is dosage-dependent disrupted hippocampal lamination associated with a cell-autonomous simplification of pyramidal dendritic arborizations leading to reduced inhibitory synaptic tone. These data suggest that hippocampal dysmaturation and insufficient receptive field for inhibitory input may underlie the epilepsy in lissencephaly, and suggest potential therapeutic strategies for controlling epilepsy in these patients.

Published

2009

9. Dopamine D3 receptor modulation of prefrontal cells and circuits

Author

Clarkson, Rebecca Lauren

Subjects

Neurosciences, Cell classification, Dopamine, Machine learning, Prefrontal cortex, Pyramidal neuron

Abstract

Prefrontal circuits process input from the internal and external world and use these inputs to guide decision-making and subsequent goal-directed behavior. The ability of the prefrontal cortex (PFC) to flexibly guide appropriate behaviors, including updating expectations of reward and punishment, is highly sensitive to neuromodulators such as dopamine. Therefore, elucidating the cellular expression of dopamine receptors on prefrontal projection neurons is critical for understanding how dopamine can act on the prefrontal network, and thereby regulate cognitive and behavioral processes. Dopamine acts in part to regulate the activity of prefrontal layer 5 (L5) principal cells via D1-family (D1/D5) or D2-family (D2/D3/D4) receptors. Recent work indicates that D1- and D2-receptors (D1R/D2R) are expressed in largely separate subclasses of L5 pyramidal cell and that these subclasses have unique electrophysiological features and projection patterns, and are modulated by dopamine via distinct mechanisms. How other dopamine receptor classes are distributed in mPFC is unknown. D3R signaling is critically important for prefrontal executive function, as manipulations perturbing prefrontal D3Rs affect high level cognitive processes such as anxiety and reversal learning. However, the mechanisms by which D3Rs regulate prefrontal cells and circuits remains unknown. By applying a supervised machine learning approach to electrophysiological recordings from dopamine receptor reporter lines, I determine that D3R-expressing (D3+) pyramidal neurons are electrophysiologically distinct from D1R- and D2R-expressing neurons, and therefore likely represent a separate cell subclass. With anatomical tracing techniques, I demonstrate that L5 D3+ neurons are an intratelencephalic cell type. Further experiments reveal that D3R activation within this cell class can regulate calcium channels in the axon initial segment, thereby suppressing action potential burst generation. This provides a mechanism by which modulation via D2-family receptors could directly affect PFC output to other cortical areas.

Published

2017

10. Dissection of Medial Prefrontal Cortex Circuitry and its Dopaminergic Modulation

Author

Gee, Steven

Subjects

Neurosciences, Dopamine, Prefrontal Cortex, Pyramidal Neuron

Abstract

The prefrontal cortex (PFC) is comprised of a network of excitatory and inhibitory neurons that are critical for a number of cognitive processes including the ability to make decisions. PFC dysfunction causes deficits in these domains and major aspects of psychiatric disorders. Notably, layer V of the PFC is thought to play an important role in regulating these higher order processes and contains heterogeneous subpopulations of pyramidal neurons with distinct morphologies and projections. Layer V of PFC is also the major site of dopaminergic modulation. However, unlike the striatum, where D1 or D2 receptors are known to differentially express in separate projection subtypes of medium spiny neurons, the distribution of D1 and D2Rs in layer V projection neurons within PFC is unclear. Notably, Dopamine D2 receptors (D2Rs) play major roles in both normal and pathological PFC function. Thus, knowing their expression and effects in layer V neurons can provide helpful insights into important mechanisms that underlie prefrontal activity, and ultimately cognitive function. Chapter 1 of this thesis examines the expression of D1Rs and D2Rs in layer V projection subtypes. We also describe a novel mechanism by which D2R activation can drastically enhance the excitability of a D2R-expressing layer V pyramidal subtype. In Chapter 2, we explore differences in how long range excitation and feedforward inhibition is processed in D2R-expressing and D2R-lacking layer V pyramidal neurons. We propose that these differences might confer these subtypes with separate computational properties important for normal PFC function.

Published

2014