Your search keyword '"Inhibitory interneuron"' showing total 147 results

1. Glycine and GABAA receptors suppressively regulate the inspiratory-related calcium rise in the thoracic inspiratory cells of the neonatal rat

Author

Mikami, Yoshihiro, Iizuka, Makito, Onimaru, Hiroshi, and Izumizaki, Masahiko

Published

2022

2. Editorial: Cellular and molecular mechanisms that govern assembly, plasticity, and function of GABAergic inhibitory circuits in the mammalian brain

Author

Yasufumi Hayano, Goichi Miyoshi, Anirban Paul, and Hiroki Taniguchi

Subjects

inhibitory interneuron, GABA, neurodevelopmental disorder, cell type, circuit assembly, neuronal circuit, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2025

3. Interneuron FGF13 regulates seizure susceptibility via a sodium channel-independent mechanism

Author

Susan Lin, Aravind R Gade, Hong-Gang Wang, James E Niemeyer, Allison Galante, Isabella DiStefano, Patrick Towers, Jorge Nunez, Maiko Matsui, Theodore H Schwartz, Anjali Rajadhyaksha, and Geoffrey S Pitt

Subjects

sodium channels, epilepsy, inhibitory interneuron, Medicine, Science, Biology (General), QH301-705.5

Abstract

Developmental and epileptic encephalopathies (DEEs), a class of devastating neurological disorders characterized by recurrent seizures and exacerbated by disruptions to excitatory/inhibitory balance in the brain, are commonly caused by mutations in ion channels. Disruption of, or variants in, FGF13 were implicated as causal for a set of DEEs, but the underlying mechanisms were clouded because FGF13 is expressed in both excitatory and inhibitory neurons, FGF13 undergoes extensive alternative splicing producing multiple isoforms with distinct functions, and the overall roles of FGF13 in neurons are incompletely cataloged. To overcome these challenges, we generated a set of novel cell-type-specific conditional knockout mice. Interneuron-targeted deletion of Fgf13 led to perinatal mortality associated with extensive seizures and impaired the hippocampal inhibitory/excitatory balance while excitatory neuron-targeted deletion of Fgf13 caused no detectable seizures and no survival deficits. While best studied as a voltage-gated sodium channel (Nav) regulator, we observed no effect of Fgf13 ablation in interneurons on Navs but rather a marked reduction in K+ channel currents. Re-expressing different Fgf13 splice isoforms could partially rescue deficits in interneuron excitability and restore K+ channel current amplitude. These results enhance our understanding of the molecular mechanisms that drive the pathogenesis of Fgf13-related seizures and expand our understanding of FGF13 functions in different neuron subsets.

Published

2025

4. A brief history of somatostatin interneuron taxonomy or: how many somatostatin subtypes are there, really?

Author

Agmon, Ariel and Barth, Alison L.

Subjects

MORPHOLOGY, GENE expression profiling, SOMATOSTATIN, CEREBRAL cortex, RNA sequencing, INTERNEURONS

Abstract

We provide a brief (and unabashedly biased) overview of the pre-transcriptomic history of somatostatin interneuron taxonomy, followed by a chronological summary of the large-scale, NIH-supported effort over the last ten years to generate a comprehensive, single-cell RNA-seq-based taxonomy of cortical neurons. Focusing on somatostatin interneurons, we present the perspective of experimental neuroscientists trying to incorporate the new classification schemes into their own research while struggling to keep up with the ever-increasing number of proposed cell types, which seems to double every two years. We suggest that for experimental analysis, the most useful taxonomic level is the subdivision of somatostatin interneurons into ten or so "supertypes," which closely agrees with their more traditional classification by morphological, electrophysiological and neurochemical features. We argue that finer subdivisions ("t-types" or "clusters"), based on slight variations in gene expression profiles but lacking clear phenotypic differences, are less useful to researchers and may actually defeat the purpose of classifying neurons to begin with. We end by stressing the need for generating novel tools (mouse lines, viral vectors) for genetically targeting distinct supertypes for expression of fluorescent reporters, calcium sensors and excitatory or inhibitory opsins, allowing neuroscientists to chart the input and output synaptic connections of each proposed subtype, reveal the position they occupy in the cortical network and examine experimentally their roles in sensorimotor behaviors and cognitive brain functions. [ABSTRACT FROM AUTHOR]

Published

2024

5. Cortical circuit dynamics underlying motor skill learning: from rodents to humans.

Author

Kogan, Emily, Lu, Ju, and Zuo, Yi

Subjects

cross-species, dendritic spine, inhibitory interneuron, motor learning, neuron, primary motor cortex, synapse

Abstract

Motor learning is crucial for the survival of many animals. Acquiring a new motor skill involves complex alterations in both local neural circuits in many brain regions and long-range connections between them. Such changes can be observed anatomically and functionally. The primary motor cortex (M1) integrates information from diverse brain regions and plays a pivotal role in the acquisition and refinement of new motor skills. In this review, we discuss how motor learning affects the M1 at synaptic, cellular, and circuit levels. Wherever applicable, we attempt to relate and compare findings in humans, non-human primates, and rodents. Understanding the underlying principles shared by different species will deepen our understanding of the neurobiological and computational basis of motor learning.

Published

2023

6. A brief history of somatostatin interneuron taxonomy or: how many somatostatin subtypes are there, really?

Author

Ariel Agmon and Alison L. Barth

Subjects

somatostatin, cerebral cortex, inhibitory interneuron, transcriptomics (RNA sequencing), taxonomy, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

We provide a brief (and unabashedly biased) overview of the pre-transcriptomic history of somatostatin interneuron taxonomy, followed by a chronological summary of the large-scale, NIH-supported effort over the last ten years to generate a comprehensive, single-cell RNA-seq-based taxonomy of cortical neurons. Focusing on somatostatin interneurons, we present the perspective of experimental neuroscientists trying to incorporate the new classification schemes into their own research while struggling to keep up with the ever-increasing number of proposed cell types, which seems to double every two years. We suggest that for experimental analysis, the most useful taxonomic level is the subdivision of somatostatin interneurons into ten or so “supertypes,” which closely agrees with their more traditional classification by morphological, electrophysiological and neurochemical features. We argue that finer subdivisions (“t-types” or “clusters”), based on slight variations in gene expression profiles but lacking clear phenotypic differences, are less useful to researchers and may actually defeat the purpose of classifying neurons to begin with. We end by stressing the need for generating novel tools (mouse lines, viral vectors) for genetically targeting distinct supertypes for expression of fluorescent reporters, calcium sensors and excitatory or inhibitory opsins, allowing neuroscientists to chart the input and output synaptic connections of each proposed subtype, reveal the position they occupy in the cortical network and examine experimentally their roles in sensorimotor behaviors and cognitive brain functions.

Published

2024

7. The Temporal Lobe Club: Newer Approaches to Treat Temporal Lobe Epilepsy.

Author

Sperling, Michael R., Wu, Chengyuan, Kang, Joon, Makhalova, Julia, Bartolomei, Fabrice, and Southwell, Derek

Subjects

*TEMPORAL lobe epilepsy, *TEMPORAL lobe, *ELECTRIC stimulation, *CATHETER ablation

Abstract

This brief review summarizes presentations at the Temporal Lobe Club Special Interest Group session held in December 2022 at the American Epilepsy Society meeting. The session addressed newer methods to treat temporal epilepsy, including methods currently in clinical use and techniques under investigation. Brief summaries are provided for each of 4 lectures. Dr Chengyuan Wu discussed ablative techniques such as laser interstitial thermal ablation, radiofrequency ablation, focused ultrasound; Dr Joon Kang reviewed neuromodulation techniques including electrical stimulation and focused ultrasound; Dr Julia Makhalova discussed network effects of the aforementioned techniques; and Dr Derek Southwell reviewed inhibitory interneuron transplantation. These summaries are intended to provide a brief overview and references are provided for the reader to learn more about each topic. [ABSTRACT FROM AUTHOR]

Published

2024

8. Layer 1 neocortex: Gating and integrating multidimensional signals.

Author

Huang, Shuhan, Wu, Sherry Jingjing, Sansone, Giulia, Ibrahim, Leena Ali, and Fishell, Gord

Subjects

*NEOCORTEX, *INTERNEURONS, *AFFERENT pathways, *AXONS, *DENDRITIC crystals

Abstract

Layer 1 (L1) of the neocortex acts as a nexus for the collection and processing of widespread information. By integrating ascending inputs with extensive top-down activity, this layer likely provides critical information regulating how the perception of sensory inputs is reconciled with expectation. This is accomplished by sorting, directing, and integrating the complex network of excitatory inputs that converge onto L1. These signals are combined with neuromodulatory afferents and gated by the wealth of inhibitory interneurons that either are embedded within L1 or send axons from other cortical layers. Together, these interactions dynamically calibrate information flow throughout the neocortex. This review will primarily focus on L1 within the primary sensory cortex and will use these insights to understand L1 in other cortical areas. Huang et al. present a review of the structure, connectivity, and function of neocortex's layer 1, highlighting its critical role in gating and integrating diverse signals. [ABSTRACT FROM AUTHOR]

Published

2024

9. Cortical circuit dynamics underlying motor skill learning: from rodents to humans.

Author

Emily Kogan, Ju Lu, and Yi Zuo

Subjects

MOTOR learning, MOTOR ability, NEURAL circuitry, RODENTS, MOTOR cortex, PREMOTOR cortex

Abstract

Motor learning is crucial for the survival of many animals. Acquiring a new motor skill involves complex alterations in both local neural circuits in many brain regions and long-range connections between them. Such changes can be observed anatomically and functionally. The primary motor cortex (M1) integrates information from diverse brain regions and plays a pivotal role in the acquisition and refinement of new motor skills. In this review, we discuss how motor learning affects the M1 at synaptic, cellular, and circuit levels. Wherever applicable, we attempt to relate and compare findings in humans, non-human primates, and rodents. Understanding the underlying principles shared by different species will deepen our understanding of the neurobiological and computational basis of motor learning. [ABSTRACT FROM AUTHOR]

Published

2023

10. The alpha2 nicotinic acetylcholine receptor, a subunit with unique and selective expression in inhibitory interneurons associated with principal cells

Author

Markus M. Hilscher, Sanja Mikulovic, Sharn Perry, Stina Lundberg, and Klas Kullander

Subjects

α2-nicotinic acetylcholine receptor, Inhibitory interneuron, Martinotti cells, OLM cells, Renshaw cells, Therapeutics. Pharmacology, RM1-950

Abstract

Nicotinic acetylcholine receptors (nAChRs) play crucial roles in various human disorders, with the α7, α4, α6, and α3-containing nAChR subtypes extensively studied in relation to conditions such as Alzheimer's disease, Parkinson's disease, nicotine dependence, mood disorders, and stress disorders. In contrast, the α2-nAChR subunit has received less attention due to its more restricted expression and the scarcity of specific agonists and antagonists for studying its function. Nevertheless, recent research has shed light on the unique expression pattern of the Chrna2 gene, which encodes the α2-nAChR subunit, and its involvement in distinct populations of inhibitory interneurons. This review highlights the structure, pharmacology, localization, function, and disease associations of α2-containing nAChRs and points to the unique expression pattern of the Chrna2 gene and its role in different inhibitory interneuron populations. These populations, including the oriens lacunosum moleculare (OLM) cells in the hippocampus, Martinotti cells in the neocortex, and Renshaw cells in the spinal cord, share common features and contribute to recurrent inhibitory microcircuits. Thus, the α2-nAChR subunit's unique expression pattern in specific interneuron populations and its role in recurrent inhibitory microcircuits highlight its importance in various physiological processes. Further research is necessary to uncover the comprehensive functionality of α2-containing nAChRs, delineate their specific contributions to neuronal circuits, and investigate their potential as therapeutic targets for related disorders.

Published

2023

11. Delta opioid receptors engage multiple signaling cascades to differentially modulate prefrontal GABA release with input and target specificity.

Author

Alexander RPD and Bender KJ

Abstract

Opioids regulate circuits associated with motivation and reward across the brain. Of the opioid receptor types, delta opioid receptors (DORs) appear to have a unique role in regulating the activity of circuits related to reward without liability for abuse. In neocortex, DORs are expressed primarily in interneurons, including parvalbumin- and somatostatin-expressing interneurons that inhibit somatic and dendritic compartments of excitatory pyramidal cells, respectively. But how DORs regulate transmission from these key interneuron classes is unclear. We found that DORs regulate inhibition from these interneuron classes using different G-protein signaling pathways that both converge on presynaptic calcium channels but regulate distinct aspects of calcium channel function. This imposes different temporal filtering effects, via short-term plasticity, that depend on how calcium channels are regulated. Thus, DORs engage differential signaling cascades to regulate inhibition depending on the postsynaptic target compartment, with different effects on synaptic information transfer in somatic and dendritic domains., Competing Interests: Declaration of interests K.J.B. is on the scientific advisory board (SAB) for Regel Tx and receives research support from Regel Tx and BioMarin Pharmaceutical for projects not related to this work., (Copyright © 2025 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2025

12. Capacitance Measurements of Exocytosis From AII Amacrine Cells in Retinal Slices.

Author

Hartveit E and Veruki ML

Abstract

During neuronal synaptic transmission, the exocytotic release of neurotransmitters from synaptic vesicles in the presynaptic neuron evokes a change in conductance for one or more types of ligand-gated ion channels in the postsynaptic neuron. The standard method of investigation uses electrophysiological recordings of the postsynaptic response. However, electrophysiological recordings can directly quantify the presynaptic release of neurotransmitters with high temporal resolution by measuring the membrane capacitance before and after exocytosis, as fusion of the membrane of presynaptic vesicles with the plasma membrane increases the total capacitance. While the standard technique for capacitance measurement assumes that the presynaptic cell is unbranched and can be represented as a simple resistance-capacitance (RC) circuit, neuronal exocytosis typically occurs at a distance from the soma. Even in such cases, however, it can be possible to detect a depolarization-evoked increase in capacitance. Here, we provide a detailed, step-by-step protocol that describes how "Sine + DC" (direct current) capacitance measurements can quantify the exocytotic release of neurotransmitters from AII amacrine cells in rat retinal slices. The AII is an important inhibitory interneuron of the mammalian retina that plays an important role in integrating rod and cone pathway signals. AII amacrines release glycine from their presynaptic dendrites, and capacitance measurements have been important for understanding the release properties of these dendrites. When the goal is to directly quantify the presynaptic release, there is currently no other competing method available. This protocol includes procedures for measuring depolarization-evoked exocytosis, using both standard square-wave pulses, arbitrary stimulus waveforms, and synaptic input. Key features • Quantification of exocytosis with the Sine + DC technique for visually targeted AII amacrines in retinal slices, using voltage-clamp and whole-cell patch-clamp recording. • Because exocytosis occurs away from the somatic recording electrode, the sine wave frequency must be lower than for the standard Sine + DC technique. • Because AII amacrines are electrically coupled, the sine wave frequency must be sufficiently high to avoid interference from other cells in the electrically coupled network. • The protocol includes procedures for measuring depolarization-evoked exocytosis using standard square-wave pulses, stimulation with arbitrary and prerecorded stimulus waveforms, and activation of synaptic inputs., Competing Interests: Competing interestsThe authors declare no competing interests., (©Copyright : © 2025 The Authors; This is an open access article under the CC BY license.)

Published

2025

13. Dendritic Morphology of an Inhibitory Retinal Interneuron Enables Simultaneous Local and Global Synaptic Integration.

Author

Hartveit, Espen, Veruki, Margaret Lin, and Zandt, Bas-Jan

Subjects

*CAPACITANCE measurement, *MORPHOLOGY, *RESPONSE inhibition, *NEUROPLASTICITY, *DENDRITIC cells

Abstract

Amacrine cells, inhibitory interneurons of the retina, feature synaptic inputs and outputs in close proximity throughout their dendritic trees, making them notable exceptions to prototypical somato-dendritic integration with output transmitted via axonal action potentials. The extent of dendritic compartmentalization in amacrine cells with widely differing dendritic tree morphology, however, is largely unexplored. Combining compartmental modeling, dendritic Ca2+ imaging, targeted microiontophoresis and multielectrode patch-clamp recording (voltage and current clamp, capacitance measurement of exocytosis), we investigated integration in the AII amacrine cell, a narrow-field electrically coupled interneuron that participates in multiple, distinct microcircuits. Physiological experiments were performed with in vitro slices prepared from retinas of both male and female rats. We found that the morphology of the AII enables simultaneous local and global integration of inputs targeted to different dendritic regions. Local integration occurs within spatially restricted dendritic subunits and narrow time windows and is largely unaffected by the strength of electrical coupling. In contrast, global integration across the dendritic tree occurs over longer time periods and is markedly influenced by the strength of electrical coupling. These integrative properties enable AII amacrines to combine local control of synaptic plasticity with location-independent global integration. Dynamic inhibitory control of dendritic subunits is likely to be of general importance for amacrine cells, including cells with small dendritic trees, as well as for inhibitory interneurons in other regions of the CNS. [ABSTRACT FROM AUTHOR]

Published

2022

14. Perinatal Penicillin Exposure Affects Cortical Development and Sensory Processing.

Author

Perna, James, Lu, Ju, Mullen, Brian, Liu, Taohui, Tjia, Michelle, Weiser, Sydney, Ackman, James, and Zuo, Yi

Subjects

DENDRITIC spines, SENSORY processing disorder, SENSORIMOTOR integration, CENTRAL nervous system, PERINEURONAL nets, PYRAMIDAL neurons, NEURAL inhibition

Abstract

The prevalent use of antibiotics in pregnant women and neonates raises concerns about long-term risks for children's health, but their effects on the central nervous system is not well understood. We studied the effects of perinatal penicillin exposure (PPE) on brain structure and function in mice with a therapeutically relevant regimen. We used a battery of behavioral tests to evaluate anxiety, working memory, and sensory processing, and immunohistochemistry to quantify changes in parvalbumin-expressing inhibitory interneurons (PV+ INs), perineuronal nets (PNNs), as well as microglia density and morphology. In addition, we performed mesoscale calcium imaging to study neural activity and functional connectivity across cortical regions, and two-photon imaging to monitor dendritic spine and microglial dynamics. We found that adolescent PPE mice have abnormal sensory processing, including impaired texture discrimination and altered prepulse inhibition. Such behavioral changes are associated with increased spontaneous neural activities in various cortical regions, and delayed maturation of PV+ INs in the somatosensory cortex. Furthermore, adolescent PPE mice have elevated elimination of dendritic spines on the apical dendrites of layer 5 pyramidal neurons, as well as increased ramifications and spatial coverage of cortical microglia. Finally, while synaptic defects are transient during adolescence, behavioral abnormalities persist into adulthood. Our study demonstrates that early-life exposure to antibiotics affects cortical development, leaving a lasting effect on brain functions. [ABSTRACT FROM AUTHOR]

Published

2021

15. Perinatal Penicillin Exposure Affects Cortical Development and Sensory Processing

Author

James Perna, Ju Lu, Brian Mullen, Taohui Liu, Michelle Tjia, Sydney Weiser, James Ackman, and Yi Zuo

Subjects

penicillin, somatosensory cortex, inhibitory interneuron, perineuronal net, dendritic spine, microglia, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The prevalent use of antibiotics in pregnant women and neonates raises concerns about long-term risks for children’s health, but their effects on the central nervous system is not well understood. We studied the effects of perinatal penicillin exposure (PPE) on brain structure and function in mice with a therapeutically relevant regimen. We used a battery of behavioral tests to evaluate anxiety, working memory, and sensory processing, and immunohistochemistry to quantify changes in parvalbumin-expressing inhibitory interneurons (PV+ INs), perineuronal nets (PNNs), as well as microglia density and morphology. In addition, we performed mesoscale calcium imaging to study neural activity and functional connectivity across cortical regions, and two-photon imaging to monitor dendritic spine and microglial dynamics. We found that adolescent PPE mice have abnormal sensory processing, including impaired texture discrimination and altered prepulse inhibition. Such behavioral changes are associated with increased spontaneous neural activities in various cortical regions, and delayed maturation of PV+ INs in the somatosensory cortex. Furthermore, adolescent PPE mice have elevated elimination of dendritic spines on the apical dendrites of layer 5 pyramidal neurons, as well as increased ramifications and spatial coverage of cortical microglia. Finally, while synaptic defects are transient during adolescence, behavioral abnormalities persist into adulthood. Our study demonstrates that early-life exposure to antibiotics affects cortical development, leaving a lasting effect on brain functions.

Published

2021

16. Mechanisms Underlying Target Selectivity for Cell Types and Subcellular Domains in Developing Neocortical Circuits

Author

Alan Y. Gutman-Wei and Solange P. Brown

Subjects

neocortex, pyramidal cell, inhibitory interneuron, synapse formation, development, cell-type specificity, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The cerebral cortex contains numerous neuronal cell types, distinguished by their molecular identity as well as their electrophysiological and morphological properties. Cortical function is reliant on stereotyped patterns of synaptic connectivity and synaptic function among these neuron types, but how these patterns are established during development remains poorly understood. Selective targeting not only of different cell types but also of distinct postsynaptic neuronal domains occurs in many brain circuits and is directed by multiple mechanisms. These mechanisms include the regulation of axonal and dendritic guidance and fine-scale morphogenesis of pre- and postsynaptic processes, lineage relationships, activity dependent mechanisms and intercellular molecular determinants such as transmembrane and secreted molecules, many of which have also been implicated in neurodevelopmental disorders. However, many studies of synaptic targeting have focused on circuits in which neuronal processes target different lamina, such that cell-type-biased connectivity may be confounded with mechanisms of laminar specificity. In the cerebral cortex, each cortical layer contains cell bodies and processes from intermingled neuronal cell types, an arrangement that presents a challenge for the development of target-selective synapse formation. Here, we address progress and future directions in the study of cell-type-biased synaptic targeting in the cerebral cortex. We highlight challenges to identifying developmental mechanisms generating stereotyped patterns of intracortical connectivity, recent developments in uncovering the determinants of synaptic target selection during cortical synapse formation, and current gaps in the understanding of cortical synapse specificity.

Published

2021

17. Mechanisms Underlying Target Selectivity for Cell Types and Subcellular Domains in Developing Neocortical Circuits.

Author

Gutman-Wei, Alan Y. and Brown, Solange P.

Subjects

SYNAPTOGENESIS, NEURAL development, PYRAMIDAL neurons, SYNAPSES, ELECTROPHYSIOLOGY, NEURONS, CEREBRAL cortex

Abstract

The cerebral cortex contains numerous neuronal cell types, distinguished by their molecular identity as well as their electrophysiological and morphological properties. Cortical function is reliant on stereotyped patterns of synaptic connectivity and synaptic function among these neuron types, but how these patterns are established during development remains poorly understood. Selective targeting not only of different cell types but also of distinct postsynaptic neuronal domains occurs in many brain circuits and is directed by multiple mechanisms. These mechanisms include the regulation of axonal and dendritic guidance and fine-scale morphogenesis of pre- and postsynaptic processes, lineage relationships, activity dependent mechanisms and intercellular molecular determinants such as transmembrane and secreted molecules, many of which have also been implicated in neurodevelopmental disorders. However, many studies of synaptic targeting have focused on circuits in which neuronal processes target different lamina, such that cell-type-biased connectivity may be confounded with mechanisms of laminar specificity. In the cerebral cortex, each cortical layer contains cell bodies and processes from intermingled neuronal cell types, an arrangement that presents a challenge for the development of target-selective synapse formation. Here, we address progress and future directions in the study of cell-type-biased synaptic targeting in the cerebral cortex. We highlight challenges to identifying developmental mechanisms generating stereotyped patterns of intracortical connectivity, recent developments in uncovering the determinants of synaptic target selection during cortical synapse formation, and current gaps in the understanding of cortical synapse specificity. [ABSTRACT FROM AUTHOR]

Published

2021

18. Dynamic Causal Modeling Self-Connectivity Findings in the Functional Magnetic Resonance Imaging Neuropsychiatric Literature

Author

Andrew D. Snyder, Liangsuo Ma, Joel L. Steinberg, Kyle Woisard, and Frederick G. Moeller

Subjects

dynamic causal modeling, intrinsic connectivity, extrinsic connectivity, effective connectivity, inhibitory interneuron, self-connectivity, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Dynamic causal modeling (DCM) is a method for analyzing functional magnetic resonance imaging (fMRI) and other functional neuroimaging data that provides information about directionality of connectivity between brain regions. A review of the neuropsychiatric fMRI DCM literature suggests that there may be a historical trend to under-report self-connectivity (within brain regions) compared to between brain region connectivity findings. These findings are an integral part of the neurologic model represented by DCM and serve an important neurobiological function in regulating excitatory and inhibitory activity between regions. We reviewed the literature on the topic as well as the past 13 years of available neuropsychiatric DCM literature to find an increasing (but still, perhaps, and inadequate) trend in reporting these results. The focus of this review is fMRI as the majority of published DCM studies utilized fMRI and the interpretation of the self-connectivity findings may vary across imaging methodologies. About 25% of articles published between 2007 and 2019 made any mention of self-connectivity findings. We recommend increased attention toward the inclusion and interpretation of self-connectivity findings in DCM analyses in the neuropsychiatric literature, particularly in forthcoming effective connectivity studies of substance use disorders.

Published

2021

19. Hippocampal Somatostatin Interneurons, Long-Term Synaptic Plasticity and Memory

Author

Eve Honoré, Abdessattar Khlaifia, Anthony Bosson, and Jean-Claude Lacaille

Subjects

somatostatin, inhibitory interneuron, hippocampus, network metaplasticity, long-term potentiation, spatial and contextual memory, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

A distinctive feature of the hippocampal structure is the diversity of inhibitory interneurons. These complex inhibitory interconnections largely contribute to the tight modulation of hippocampal circuitry, as well as to the formation and coordination of neuronal assemblies underlying learning and memory. Inhibitory interneurons provide more than a simple transitory inhibition of hippocampal principal cells (PCs). The synaptic plasticity of inhibitory neurons provides long-lasting changes in the hippocampal network and is a key component of memory formation. The dendrite targeting interneurons expressing the peptide somatostatin (SOM) are particularly interesting in this regard because they display unique long-lasting synaptic changes leading to metaplastic regulation of hippocampal networks. In this article, we examine the actions of the neuropeptide SOM on hippocampal cells, synaptic plasticity, learning, and memory. We address the different subtypes of hippocampal SOM interneurons. We describe the long-term synaptic plasticity that takes place at the excitatory synapses of SOM interneurons, its singular induction and expression mechanisms, as well as the consequences of these changes on the hippocampal network, learning, and memory. We also review evidence that astrocytes provide cell-specific dynamic regulation of inhibition of PC dendrites by SOM interneurons. Finally, we cover how, in mouse models of Alzheimer’s disease (AD), dysfunction of plasticity of SOM interneuron excitatory synapses may also contribute to cognitive impairments in brain disorders.

Published

2021

20. Dynamic Causal Modeling Self-Connectivity Findings in the Functional Magnetic Resonance Imaging Neuropsychiatric Literature.

Author

Snyder, Andrew D., Ma, Liangsuo, Steinberg, Joel L., Woisard, Kyle, and Moeller, Frederick G.

Subjects

FUNCTIONAL magnetic resonance imaging, CAUSAL models, DYNAMIC models, SUBSTANCE abuse

Abstract

Dynamic causal modeling (DCM) is a method for analyzing functional magnetic resonance imaging (fMRI) and other functional neuroimaging data that provides information about directionality of connectivity between brain regions. A review of the neuropsychiatric fMRI DCM literature suggests that there may be a historical trend to under-report self-connectivity (within brain regions) compared to between brain region connectivity findings. These findings are an integral part of the neurologic model represented by DCM and serve an important neurobiological function in regulating excitatory and inhibitory activity between regions. We reviewed the literature on the topic as well as the past 13 years of available neuropsychiatric DCM literature to find an increasing (but still, perhaps, and inadequate) trend in reporting these results. The focus of this review is fMRI as the majority of published DCM studies utilized fMRI and the interpretation of the self-connectivity findings may vary across imaging methodologies. About 25% of articles published between 2007 and 2019 made any mention of self-connectivity findings. We recommend increased attention toward the inclusion and interpretation of self-connectivity findings in DCM analyses in the neuropsychiatric literature, particularly in forthcoming effective connectivity studies of substance use disorders. [ABSTRACT FROM AUTHOR]

Published

2021

21. Hippocampal Somatostatin Interneurons, Long-Term Synaptic Plasticity and Memory.

Author

Honoré, Eve, Khlaifia, Abdessattar, Bosson, Anthony, and Lacaille, Jean-Claude

Subjects

NEUROPLASTICITY, INTERNEURONS, HIPPOCAMPUS (Brain), SOMATOSTATIN, LABORATORY mice, COGNITION disorders

Abstract

A distinctive feature of the hippocampal structure is the diversity of inhibitory interneurons. These complex inhibitory interconnections largely contribute to the tight modulation of hippocampal circuitry, as well as to the formation and coordination of neuronal assemblies underlying learning and memory. Inhibitory interneurons provide more than a simple transitory inhibition of hippocampal principal cells (PCs). The synaptic plasticity of inhibitory neurons provides long-lasting changes in the hippocampal network and is a key component of memory formation. The dendrite targeting interneurons expressing the peptide somatostatin (SOM) are particularly interesting in this regard because they display unique long-lasting synaptic changes leading to metaplastic regulation of hippocampal networks. In this article, we examine the actions of the neuropeptide SOM on hippocampal cells, synaptic plasticity, learning, and memory. We address the different subtypes of hippocampal SOM interneurons. We describe the long-term synaptic plasticity that takes place at the excitatory synapses of SOM interneurons, its singular induction and expression mechanisms, as well as the consequences of these changes on the hippocampal network, learning, and memory. We also review evidence that astrocytes provide cell-specific dynamic regulation of inhibition of PC dendrites by SOM interneurons. Finally, we cover how, in mouse models of Alzheimer's disease (AD), dysfunction of plasticity of SOM interneuron excitatory synapses may also contribute to cognitive impairments in brain disorders. [ABSTRACT FROM AUTHOR]

Published

2021

22. Specific Neuroligin3–αNeurexin1 signaling regulates GABAergic synaptic function in mouse hippocampus

Author

Motokazu Uchigashima, Kohtarou Konno, Emily Demchak, Amy Cheung, Takuya Watanabe, David G Keener, Manabu Abe, Timmy Le, Kenji Sakimura, Toshikuni Sasaoka, Takeshi Uemura, Yuka Imamura Kawasawa, Masahiko Watanabe, and Kensuke Futai

Subjects

trans-synaptic adhesion, electrophysiology, hippocampus, inhibitory interneuron, Medicine, Science, Biology (General), QH301-705.5

Abstract

Synapse formation and regulation require signaling interactions between pre- and postsynaptic proteins, notably cell adhesion molecules (CAMs). It has been proposed that the functions of neuroligins (Nlgns), postsynaptic CAMs, rely on the formation of trans-synaptic complexes with neurexins (Nrxns), presynaptic CAMs. Nlgn3 is a unique Nlgn isoform that localizes at both excitatory and inhibitory synapses. However, Nlgn3 function mediated via Nrxn interactions is unknown. Here we demonstrate that Nlgn3 localizes at postsynaptic sites apposing vesicular glutamate transporter 3-expressing (VGT3+) inhibitory terminals and regulates VGT3+ inhibitory interneuron-mediated synaptic transmission in mouse organotypic slice cultures. Gene expression analysis of interneurons revealed that the αNrxn1+AS4 splice isoform is highly expressed in VGT3+ interneurons as compared with other interneurons. Most importantly, postsynaptic Nlgn3 requires presynaptic αNrxn1+AS4 expressed in VGT3+ interneurons to regulate inhibitory synaptic transmission. Our results indicate that specific Nlgn–Nrxn signaling generates distinct functional properties at synapses.

Published

2020

23. Perinatal Penicillin Exposure Affects Cortical Development and Adolescent Sensory Processing

Author

Perna, James Francis

Subjects

Neurosciences, Dendritic spine, Inhibitory interneuron, Microglia, Penicillin, Somatosensory Cortex

Abstract

ABSTRACTJames Francis Perna IIIPerinatal penicillin exposure affects cortical development and adolescent sensoryprocessingBACKGROUND: Recent epidemiological and experimental work has raised concern thatthe use of antibiotics during early-life may have long-term detrimental consequences forchildren’s metabolic, immunological, and neuropsychological health. The effects of penicillinon the central nervous system (CNS) is not well understood.METHODS: We studied the effects of perinatal penicillin exposure (PPE) on brain structureand function in mice. Mice were maternally exposed to penicillin by administering atherapeutically relevant dose of penicillin to pregnant and nursing dams in their drinkingwater. We used a battery of behavioral tests to evaluate anxiety, working memory, andsensory processing at adolescence and immunohistochemistry to quantify changes inparvalbumin-expressing inhibitory interneurons (PV INs), perineuronal nets (PNNs), as wellas microglia density, morphology, and dynamics. In addition, we used RT-qPCR and ELISAassays to examine systemic and cortical inflammatory states. Furthermore, we performedmesoscale Ca2+ in vivo imaging of awake adolescent mice to study neural activity andfunctional connectivity across cortical regions and two-photon in vivo imaging of sedatedadolescent mice to monitor dendritic spine as well as microglial dynamics.RESULTS: We found that PPE mice had altered sensory processing, including impairedtexture discrimination and augmented prepulse inhibition. These behavioral abnormalitieswere associated with decreased functional connectivity and increased neuronal activitiesacross the cortex as well as within the somatosensory cortex. Furthermore, PPE mice showeddelayed maturation of PV INs in the somatosensory cortex, as well as significantly lowerdensity of dendritic spines on the apical dendrites of layer 5 pyramidal neurons therein drivenby an increased elimination rate. Interestingly, while the density and baseline terminal tipdynamics of cortical microglia were not altered, their ramifications and spatial coverageswere significantly increased in the PPE mouse brain, resulting in overlapping territoriesbetween neighboring microglia.CONCLUSION: This work demonstrates that early-life penicillin exposure can disruptcortical development and neuronal circuit formation, leaving lasting effects on brainfunctions. More generally, it broadens our awareness of how the neurobiological andbehavioral development of our children may be vulnerable to early-life antibiotic exposure.Furthermore, it offers insight into a potential mechanistic chain linking antibiotic exposure,microbiota perturbation, immunological signaling, neuronal development, and behavior aswell as exploring the potential to exploit the gut-brain interaction to treat neurological andbehavioral malfunctions, thus, helping to ensure that children exposed to antibiotics have thehealth and wellbeing to live free from disease or disability.

Published

2021

24. CCKergic Tufted Cells Differentially Drive Two Anatomically Segregated Inhibitory Circuits in the Mouse Olfactory Bulb.

Author

Xicui Sun, Xiang Liu, Starr, Eric R., and Shaolin Liu

Subjects

*OLFACTORY bulb, *GRANULE cells, *NEURAL circuitry, *NEURAL transmission, *DENDRITES, *NEURONS

Abstract

Delineation of functional synaptic connections is fundamental to understanding sensory processing. Olfactory signals are synaptically processed initially in the olfactory bulb (OB) where neural circuits are formed among inhibitory' interneurons and the output neurons mitral cells (MCs) and tufted cells (TCs). TCs function in parallel with but differently from MCs and are further classified into multiple subpopulations based on their anatomic and functional heterogeneities. Here, we combined optogenetics with electrophysiology' to characterize the synaptic transmission from a subpopulation of TCs, which exclusively express the neuropeptide choleq'stokinin (CCK), to two groups of spatially segregated GABAergic interneurons, granule cells (GCs) and glomerular interneurons in mice of both sexes with four major findings. First, CCKergic TCs receive direct input from the olfactory sensory' neurons (OSNs). This monosynaptic transmission exhibits high fidelity in response to repetitive OSN input. Second, CCKergic TCs drive GCs through two functionally distinct types of monosynaptic connections: (1) dendrodendritic synapses onto GC distal dendrites via their lateral dendrites in the superficial external plexiform layer (EPL); (2) axodendritic synapses onto GC proximal dendrites via their axon collaterals or terminals in the internal plexiform layer (IPL) on both sides of each bulb. Third, CCKergic TCs monosynaptically excite two subpopulations of inhibitory' glomerular interneurons via dendrodendritic synapses. Finally, sniff-like patterned activation of CCKergic TCs induces robust frequency-dependent depression of the dendrodendritic synapses but facilitation of the axodendritic synapses. These results demonstrated important roles of the CCKergic TCs in olfactory processing by orchestrating OB inhibitory' activities. [ABSTRACT FROM AUTHOR]

Published

2020

25. A Role for Dystonia-Associated Genes in Spinal GABAergic Interneuron Circuitry

Author

Juliet Zhang, Jarret A.P. Weinrich, Jeffrey B. Russ, John D. Comer, Praveen K. Bommareddy, Richard J. DiCasoli, Christopher V.E. Wright, Yuqing Li, Peter J. van Roessel, and Julia A. Kaltschmidt

Subjects

spinal cord, neuronal circuitry, inhibitory interneuron, GABApre neuron, synapses, Klhl14, Tor1a, dystonia, Biology (General), QH301-705.5

Abstract

Spinal interneurons are critical modulators of motor circuit function. In the dorsal spinal cord, a set of interneurons called GABApre presynaptically inhibits proprioceptive sensory afferent terminals, thus negatively regulating sensory-motor signaling. Although deficits in presynaptic inhibition have been inferred in human motor diseases, including dystonia, it remains unclear whether GABApre circuit components are altered in these conditions. Here, we use developmental timing to show that GABApre neurons are a late Ptf1a-expressing subclass and localize to the intermediate spinal cord. Using a microarray screen to identify genes expressed in this intermediate population, we find the kelch-like family member Klhl14, implicated in dystonia through its direct binding with torsion-dystonia-related protein Tor1a. Furthermore, in Tor1a mutant mice in which Klhl14 and Tor1a binding is disrupted, formation of GABApre sensory afferent synapses is impaired. Our findings suggest a potential contribution of GABApre neurons to the deficits in presynaptic inhibition observed in dystonia.

Published

2017

26. The alpha2 nicotinic acetylcholine receptor, a subunit with unique and selective expression in inhibitory interneurons associated with principal cells

Author

Hilscher, Markus M, Mikulovic, Sanja, Perry, Sharn, Lundberg, Stina, Kullander, Klas, Hilscher, Markus M, Mikulovic, Sanja, Perry, Sharn, Lundberg, Stina, and Kullander, Klas

Abstract

Nicotinic acetylcholine receptors (nAChRs) play crucial roles in various human disorders, with the alpha 7, alpha 4, alpha 6, and alpha 3-containing nAChR subtypes extensively studied in relation to conditions such as Alzheimer's disease, Parkinson's disease, nicotine dependence, mood disorders, and stress disorders. In contrast, the alpha 2-nAChR subunit has received less attention due to its more restricted expression and the scarcity of specific agonists and antagonists for studying its function. Nevertheless, recent research has shed light on the unique expression pattern of the Chrna2 gene, which encodes the alpha 2-nAChR subunit, and its involvement in distinct populations of inhibitory interneurons. This review highlights the structure, pharmacology, localization, function, and disease associations of alpha 2-containing nAChRs and points to the unique expression pattern of the Chrna2 gene and its role in different inhibitory interneuron populations. These populations, including the oriens lacunosum moleculare (OLM) cells in the hippocampus, Martinotti cells in the neocortex, and Renshaw cells in the spinal cord, share common features and contribute to recurrent inhibitory microcircuits. Thus, the alpha 2-nAChR subunit's unique expression pattern in specific interneuron populations and its role in recurrent inhibitory microcircuits highlight its importance in various physiological processes. Further research is necessary to uncover the comprehensive functionality of alpha 2-containing nAChRs, delineate their specific contributions to neuronal circuits, and investigate their potential as therapeutic targets for related disorders.

Published

2023

27. Capacitance measurement of dendritic exocytosis in an electrically coupled inhibitory retinal interneuron: an experimental and computational study

Author

Espen Hartveit, Margaret Lin Veruki, and Bas‐Jan Zandt

Subjects

AII amacrine cell, capacitance, compartmental model, exocytosis, glycine, inhibitory interneuron, Physiology, QP1-981

Abstract

Abstract Exocytotic release of neurotransmitter can be quantified by electrophysiological recording from postsynaptic neurons. Alternatively, fusion of synaptic vesicles with the cell membrane can be measured as increased capacitance by recording directly from a presynaptic neuron. The “Sine + DC” technique is based on recording from an unbranched cell, represented by an electrically equivalent RC‐circuit. It is challenging to extend such measurements to branching neurons where exocytosis occurs at a distance from a somatic recording electrode. The AII amacrine is an important inhibitory interneuron of the mammalian retina and there is evidence that exocytosis at presynaptic lobular dendrites increases the capacitance. Here, we combined electrophysiological recording and computer simulations with realistic compartmental models to explore capacitance measurements of rat AII amacrine cells. First, we verified the ability of the “Sine + DC” technique to detect depolarization‐evoked exocytosis in physiological recordings. Next, we used compartmental modeling to demonstrate that capacitance measurements can detect increased membrane surface area at lobular dendrites. However, the accuracy declines for lobular dendrites located further from the soma due to frequency‐dependent signal attenuation. For sine wave frequencies ≥1 kHz, the magnitude of the total releasable pool of synaptic vesicles will be significantly underestimated. Reducing the sine wave frequency increases overall accuracy, but when the frequency is sufficiently low that exocytosis can be detected with high accuracy from all lobular dendrites (~100 Hz), strong electrical coupling between AII amacrines compromises the measurements. These results need to be taken into account in studies with capacitance measurements from these and other electrically coupled neurons.

Published

2019

28. Inhibition in Simple Cell Receptive Fields Is Broad and OFF-Subregion Biased.

Author

Taylor, M. Morgan, Sedigh-Sarvestani, Madineh, Vigeland, Leif, Palmer, Larry A., and Contreras, Diego

Subjects

*CORTEX (Botany), *CELL analysis, *ANTIPHASE boundaries, *EXCITATION (Physiology), *AROUSAL (Physiology)

Abstract

Inhibition in thalamorecipient layer 4 simple cells of primary visual cortex is believed to play important roles in establishing visual response properties and integrating visual inputs across their receptive fields (RFs). Simple cell RFs are characterized by nonoverlapping, spatially restricted subregions in which visual stimuli can either increase or decrease the firing rate of the cell, depending on contrast. Inhibition is believed to be triggered exclusively from visual stimulation of individual RF subregions. However, this view is at odds with the known anatomy of layer 4 interneurons in visual cortex and differs from recent findings in mouse visual cortex. Here we show with in vivo intracellular recordings in cats that while excitation is restricted to RF subregions, inhibition spans the width of simple cell RFs. Consequently, excitatory stimuli within a subregion concomitantly drive excitation and inhibition. Furthermore, we found that the distribution of inhibition across the RF is stronger toward OFF subregions. This inhibitory OFF-subregion bias has a functional consequence on spatial integration of inputs across the RF. A model based on the known anatomy of layer 4 demonstrates that the known proportion and connectivity of inhibitory neurons in layer 4 of primary visual cortex is sufficient to explain broad inhibition with an OFF-subregion bias while generating a variety of phase relations, including antiphase, between excitation and inhibition in response to drifting gratings. [ABSTRACT FROM AUTHOR]

Published

2018

29. PHF24 is expressed in the inhibitory interneurons in rats

Author

Takehito Kaneko, Jyoji Yamate, Yuki Numakura, Miyuu Tanaka, Risa Uemura, Takashi Kuramoto, Takashi Yamamoto, Takeshi Izawa, Tadao Serikawa, Tomoji Mashimo, and Mitsuru Kuwamura

Subjects

Central Nervous System, inhibitory interneuron, 0301 basic medicine, Calbindins, Original, Immunoelectron microscopy, Gene Expression, Endogenous retrovirus, Biology, GABAB receptor, Inhibitory postsynaptic potential, Calbindin, Epileptogenesis, General Biochemistry, Genetics and Molecular Biology, PHF24, 03 medical and health sciences, 0302 clinical medicine, Interneurons, Seizures, Animals, mutant rat, Genetic Association Studies, gamma-Aminobutyric Acid, Homeodomain Proteins, General Veterinary, Intracellular Signaling Peptides and Proteins, General Medicine, Immunohistochemistry, Olfactory Bulb, Rats, Inbred F344, Olfactory bulb, Cell biology, Disease Models, Animal, 030104 developmental biology, Spinal Cord, nervous system, Calbindin 2, epilepsy, Animal Science and Zoology, Calretinin, 030217 neurology & neurosurgery, Signal Transduction

Abstract

Noda epileptic rat (NER) is a mutant model for epilepsy that exhibits spontaneous generalized tonic-clonic seizure. Epileptogenesis of NER remains to be elucidated; but it is detected an insertion of an endogenous retrovirus sequence in intron 2 of the PHD finger protein 24 (Phf24) gene, encoding Gαi-interacting protein (GINIP). Phf24 is a strong candidate gene for epileptogenesis in NER. PHF24 modulates GABAB signaling through interacting with Gαi protein. To clarify the epileptogenesis of NER, we investigated a distribution of PHF24-expressing cells in the central nerve system (CNS). While broad expression of PHF24 was observed in the CNS, characteristic expression was noted in the periglomerular layer of the olfactory bulb and the lamina II of the spinal cord in the control rats. These cells showed co-expression with calbindin or calretinin, inhibitory interneuron markers. In the olfactory bulb, 15.6% and 41.2% of PHF24-positive neurons co-expressed calbindin and calretinin, respectively. Immunoelectron microscopy revealed that PHF24 was located in the presynaptic terminals, synaptic membranes and cytoplasmic matrix of neuronal soma. Our data suggested PHF24 is expressed in the inhibitory interneurons and may play important roles in modulation of the GABAB signaling.

Published

2021

30. Primal-size neural circuits in meta-periodic interaction

Author

Yoram Baram

Subjects

Random graph, Quantitative Biology::Neurons and Cognition, Computer science, Working memory, Cognitive Neuroscience, 05 social sciences, Human brain, Topology, 050105 experimental psychology, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Asynchronous communication, Biological neural network, medicine, 0501 psychology and cognitive sciences, Inhibitory interneuron, 030217 neurology & neurosurgery, Network approach, Research Article, Electronic circuit

Abstract

Experimental observations of simultaneous activity in large cortical areas have seemed to justify a large network approach in early studies of neural information codes and memory capacity. This approach has overlooked, however, the segregated nature of cortical structure and functionality. Employing graph-theoretic results, we show that, given the estimated number of neurons in the human brain, there are only a few primal sizes that can be attributed to neural circuits under probabilistically sparse connectivity. The significance of this finding is that neural circuits of relatively small primal sizes in cyclic interaction, implied by inhibitory interneuron potentiation and excitatory inter-circuit potentiation, generate relatively long non-repetitious sequences of asynchronous primal-length periods. The meta-periodic nature of such circuit interaction translates into meta-periodic firing-rate dynamics, representing cortical information. It is finally shown that interacting neural circuits of primal sizes 7 or less exhaust most of the capacity of the human brain, with relatively little room to spare for circuits of larger primal sizes. This also appears to ratify experimental findings on the human working memory capacity.

Published

2020

31. Gene Therapy in Models of Severe Epilepsy due to Sodium Channelopathy

Author

Ethan M. Goldberg

Subjects

0301 basic medicine, business.industry, Sodium, Genetic enhancement, Sodium channel gene, chemistry.chemical_element, Pharmacology, medicine.disease, Severe epilepsy, Current Literature in Basic Science, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Dravet syndrome, chemistry, Channelopathy, medicine, Inhibitory interneuron, Neurology (clinical), business, Research Articles, 030217 neurology & neurosurgery, Research Article

Abstract

dCas9-Based Scn1a Gene Activation Restores Inhibitory Interneuron Excitability and Attenuates Seizures in Dravet Syndrome MiceColasante G, Lignani G, Brusco S, et al. Mol Ther. 2020;28(1):235-253. doi:10.1016/j.ymthe.2019.08.018Dravet syndrome (DS) is a severe epileptic encephalopathy caused mainly by heterozygous loss-of-function mutations of the SCN1A gene, indicating haploinsufficiency as the pathogenic mechanism. Here, we tested whether catalytically dead Cas9 (dCas9)-mediated Scn1a gene activation can rescue Scn1a haploinsufficiency in a mouse DS model and restore physiological levels of its gene product, the Nav1.1 voltage-gated sodium channel. We screened single guide RNAs (sgRNAs) for their ability to stimulate Scn1a transcription in association with the dCas9 activation system. We identified a specific sgRNA that increases Scn1a gene expression levels in cell lines and primary neurons with high specificity. Nav1.1 protein levels were augmented, as was the ability of wild-type immature GABAergic interneurons to fire action potentials. A similar enhancement of Scn1a transcription was achieved in mature DS interneurons, rescuing their ability to fire. To test the therapeutic potential of this approach, we delivered the Scn1a-dCas9 activation system to DS pups using adeno-associated viruses. Parvalbumin interneurons recovered their firing ability, and febrile seizures were significantly attenuated. Our results pave the way for exploiting dCas9-based gene activation as an effective and targeted approach to DS and other disorders resulting from altered gene dosage.Scn8a Antisense Oligonucleotide Is Protective in Mouse Models of SCN8A Encephalopathy and Dravet syndromeLenk GM, Jafar Nejad P, Hill SF, et al. Ann Neurol. 2020;87(3):339-346. doi:10.1002/ana.25676SCN8A encephalopathy is a developmental and epileptic encephalopathy caused by de novo gain-of-function mutations of sodium channel Nav 1.6 that result in neuronal hyperactivity. Affected individuals exhibit early-onset drug-resistant seizures, developmental delay, and cognitive impairment. This study was carried out to determine whether reducing the abundance of the Scn8a transcript with an antisense oligonucleotide (ASO) would delay seizure onset and prolong survival in a mouse model of SCN8A encephalopathy. Antisense oligonucleotide treatment was tested in a conditional mouse model with Cre-dependent expression of the pathogenic patient SCN8A mutation p.Arg1872Trp (R1872 W). This model exhibits early onset of seizures, rapid progression, and 100% penetrance. An Scn1a+/− haploinsufficient mouse model of Dravet syndrome was also treated. Antisense oligonucleotide was administered by intracerebroventricular injection at postnatal day 2, followed in some cases by stereotactic injection at postnatal day 30. We observed a dose-dependent increase in length of survival from 15 to 65 days in the Scn8a-R1872W/+ mice treated with ASO. Electroencephalographic recordings were normal prior to seizure onset. Weight gain and activity in an open field were unaffected, but treated mice were less active in a wheel running assay. A single treatment with Scn8a ASO extended survival of Dravet syndrome mice from 3 weeks to >5 months. Reduction of Scn8a transcript by 25% to 50% delayed seizure onset and lethality in mouse models of SCN8A encephalopathy and Dravet syndrome. Reduction of SCN8A transcript is a promising approach to treatment of intractable childhood epilepsies.

Published

2020

32. Circuit-selective cell-autonomous regulation of inhibition in pyramidal neurons by Ste20-like kinase

Author

Pedro Royero, Anne Quatraccioni, Rieke Früngel, Mariella Hurtado Silva, Arco Bast, Thomas Ulas, Marc Beyer, Thoralf Opitz, Joachim L. Schultze, Mark E. Graham, Marcel Oberlaender, Albert Becker, Susanne Schoch, and Heinz Beck

Subjects

inhibitory interneuron, feedback inhibition, Neuroscience [CP], Pyramidal Cells, Ste20-like kinase, cortical pyramidal neuron, inhibitory circuit, ddc:610, patch-clamp RNA sequencing, feedforward inhibition, General Biochemistry, Genetics and Molecular Biology

Abstract

Maintaining an appropriate balance between excitation and inhibition is critical for neuronal information processing. Cortical neurons can cell-autonomously adjust the inhibition they receive to individual levels of excitatory input, but the underlying mechanisms are unclear. We describe that Ste20-like kinase (SLK) mediates cell-autonomous regulation of excitation-inhibition balance in the thalamocortical feedforward circuit, but not in the feedback circuit. This effect is due to regulation of inhibition originating from parvalbumin-expressing interneurons, while inhibition via somatostatin-expressing interneurons is unaffected. Computational modeling shows that this mechanism promotes stable excitatory-inhibitory ratios across pyramidal cells and ensures robust and sparse coding. Patch-clamp RNA sequencing yields genes differentially regulated by SLK knockdown, as well as genes associated with excitation-inhibition balance participating in transsynaptic communication and cytoskeletal dynamics. These data identify a mechanism for cell-autonomous regulation of a specific inhibitory circuit that is critical to ensure that a majority of cortical pyramidal cells participate in information coding.

Published

2022

33. Connections between EM2-containing terminals and GABA/µ-opioid receptor co-expressing neurons in the rat spinal trigeminal caudal nucleus

Author

Meng-Ying eLi, Zheng-Yu eWu, Ya-Cheng eLu, Jun-Bin eYin, Jian eWang, Ting eZhang, Yu-Lin eDong, and Feng eWang

Subjects

synapse, inhibitory interneuron, endomorphin 2, γ-amino butyric acid, µ opioid receptor, spinal trigeminal caudal nucleus, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Endomorphin-2 (EM2) demonstrates a potent antinociceptive effect via the µ-opioid receptor (MOR). To provide morphological evidence for the pain control effect of EM2, the synaptic connections between EM2-immunoreactive (IR) axonal terminals and γ-amino butyric acid (GABA)/ MOR co-expressing neurons in lamina II of the spinal trigeminal caudal nucleus (Vc) were investigated in the rat. Dense EM2-, MOR- and GABA-IR fibers and terminals were mainly observed in lamina II of the Vc. Within lamina II, GABA- and MOR-neuronal cell bodies were also encountered. The results of immunofluorescent histochemical triple-staining showed that approximately 14.2% or 18.9% of GABA-IR or MOR-IR neurons also showed MOR- or GABA-immunopositive staining in lamina II; approximately 45.2% and 36.1% of the GABA-IR and MOR-IR neurons, respectively, expressed FOS protein in their nuclei induced by injecting formalin into the left lower lip of the mouth. Most of the GABA/MOR, GABA/FOS and MOR/FOS double-labeled neurons made close contacts with EM2-IR fibers and terminals. Immuno-electron microscopy confirmed that the EM2-IR terminals formed synapses with GABA-IR or MOR-IR dendritic processes and neuronal cell bodies in lamina II of the Vc. These results suggest that EM2 might participate in pain transmission and modulation by binding to MOR-IR and GABAergic inhibitory interneuron in lamina II of the Vc to exert inhibitory effect on the excitatory interneuron in lamina II and projection neurons in laminae I and III.

Published

2014

34. Acetylcholine release and inhibitory interneuron activity in hippocampal CA1

Author

A. Rory McQuiston

Subjects

Acetylcholine, Hippocampus, muscarinic, nicotinic, inhibitory interneuron, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Acetylcholine release in the central nervous system (CNS) has an important role in attention, recall and memory formation. One region influenced by acetylcholine is the hippocampus, which receives inputs from the medial septum and diagonal band of Broca complex (MS/DBB). Release of acetylcholine from the MS/DBB can directly affect several elements of the hippocampus including glutamatergic and GABAergic neurons, presynaptic terminals, postsynaptic receptors and astrocytes. A significant portion of acetylcholine’s effect likely results from the modulation of GABAergic inhibitory interneurons, which have crucial roles in controlling excitatory inputs, synaptic integration, rhythmic coordination of principal neurons and outputs in the hippocampus. Acetylcholine affects interneuron function in large part by altering their membrane potential via muscarinic and nicotinic receptor activation. This minireview describes recent data from mouse hippocampus that investigated changes in CA1 interneuron membrane potentials following acetylcholine release. The interneuron subtypes affected, the receptor subtypes activated, and the potential outcome on hippocampal CA1 network function is discussed.

Published

2014

35. Neocortical inhibitory interneuron subtypes are differentially attuned to synchrony- and rate-coded information

Author

Blake A. Richards, Matthew M Tran, Michael M. Kohl, Luke Y. Prince, Lydia Saad, Dorian Grey, Helen Chasiotis, and Jeehyun Kwag

Subjects

Patch-Clamp Techniques, Interneuron, genetic structures, QH301-705.5, Medicine (miscellaneous), Mice, Transgenic, Neocortex, Biology, Somatosensory system, Neural circuits, General Biochemistry, Genetics and Molecular Biology, Article, Mice, Interneurons, medicine, Animals, Biology (General), musculoskeletal, neural, and ocular physiology, fungi, Somatosensory Cortex, Cellular neuroscience, Optogenetics, medicine.anatomical_structure, nervous system, Optical stimulation, Excitatory postsynaptic potential, Inhibitory interneuron, Whisker system, General Agricultural and Biological Sciences, Neuroscience

Abstract

Neurons can carry information with both the synchrony and rate of their spikes. However, it is unknown whether distinct subtypes of neurons are more sensitive to information carried by synchrony versus rate, or vice versa. Here, we address this question using patterned optical stimulation in slices of somatosensory cortex from mouse lines labelling fast-spiking (FS) and regular-spiking (RS) interneurons. We used optical stimulation in layer 2/3 to encode a 1-bit signal using either the synchrony or rate of activity. We then examined the mutual information between this signal and the interneuron responses. We found that for a synchrony encoding, FS interneurons carried more information in the first five milliseconds, while both interneuron subtypes carried more information than excitatory neurons in later responses. For a rate encoding, we found that RS interneurons carried more information after several milliseconds. These data demonstrate that distinct interneuron subtypes in the neocortex have distinct sensitivities to synchrony versus rate codes., In order to address whether distinct subtypes of neurons are more sensitive to information carried by synchrony versus rate, Prince et al. used optical stimulation in slices of somatosensory cortex from mouse lines labelling fast-spiking (FS) and regular-spiking (RS) interneurons. They demonstrated that FS and RS interneurons had differential sensitivity to changes in synchrony and rate, which advances our understanding of neural processing in the neocortex.

Published

2021

36. Misexpression of Ptf1a in Cortical Pyramidal Cells In Vivo Promotes an Inhibitory Peptidergic Identity.

Author

Russ, Jeffrey B., Borromeo, Mark D., Kollipara, Rahul K., Bommareddy, Praveen K., Johnson, Jane E., and Kaltschmidt, Julia A.

Subjects

*PANCREATIC proteins, *TRANSCRIPTION factors, *EXPRESSIVE behavior, *RNA sequencing, *PYRAMIDAL neurons, *INTERNEURONS

Abstract

The intracellular transcriptional milieu wields considerable influence over the induction of neuronal identity. The transcription factor Ptf1a has been proposed to act as an identity "switch" between developmentally related precursors in the spinal cord (Glasgow et al., 2005; Huang et al., 2008), retina (Fujitani et al., 2006; Dullin et al., 2007; Nakhai et al., 2007; Lelièvre et al., 2011), and cerebellum (Hoshino et al., 2005; Pascual et al., 2007; Yamada et al., 2014), where it promotes an inhibitory over an excitatory neuronal identity. In this study, we investigate the potency of Ptf1a to cell autonomously confer a specific neuronal identity outside of its endogenous environment, using mouse in utero electroporation and a conditional genetic strategy to misexpress Ptf1a exclusively in developing cortical pyramidal cells. Transcriptome profiling of Ptf1a-misexpressing cells using RNA-seq reveals that Ptf1a significantly alters pyramidal cell gene expression, upregulating numerous Ptf1a-dependent inhibitory interneuron markers and ultimately generating a gene expression profile that resembles the transcriptomes of both Ptf1a-expressing spinal interneurons and endogenous cortical interneurons. Using RNA-seq and in situ hybridization analyses, we also show that Ptf1a induces expression of the peptidergic neurotransmitter nociceptin, while minimally affecting the expression of genes linked to other neurotransmitter systems. Moreover, Ptf1a alters neuronal morphology, inducing the radial redistribution and branching of neurites in cortical pyramidal cells. Thus Ptf1a is sufficient, even in a dramatically different neuronal precursor, to cell autonomously promote characteristics of an inhibitory peptidergic identity, providing the first example of a single transcription factor that can direct an inhibitory peptidergic fate. [ABSTRACT FROM AUTHOR]

Published

2015

37. Multimodal patterns of inhibitory activity in cerebellar cortex

Author

Rainer W. Friedrich and Chie Satou

Subjects

0301 basic medicine, Biology, Inhibitory postsynaptic potential, dimensionality, Article, 03 medical and health sciences, symbols.namesake, Cerebellar Cortex, Golgi cells, 0302 clinical medicine, Text mining, gain control, Interneurons, Cerebellum, medicine, gap junctions, Neurons, electrical coupling, business.industry, population codes, General Neuroscience, inhibitory interneurons, Golgi apparatus, inhibition, 030104 developmental biology, medicine.anatomical_structure, nervous system, Cerebellar cortex, symbols, Inhibitory interneuron, Neuron, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

Summary Inhibitory neurons orchestrate the activity of excitatory neurons and play key roles in circuit function. Although individual interneurons have been studied extensively, little is known about their properties at the population level. Using random-access 3D two-photon microscopy, we imaged local populations of cerebellar Golgi cells (GoCs), which deliver inhibition to granule cells. We show that population activity is organized into multiple modes during spontaneous behaviors. A slow, network-wide common modulation of GoC activity correlates with the level of whisking and locomotion, while faster (, Graphical abstract, Highlights • Inhibitory circuit population activity is organized on multiple spatiotemporal scales • Slow circuit-wide Golgi cell activation reflects general level of behavioral activity • Multidimensional differential population activity encodes behavioral information • Electrically coupled Golgi cell circuit model reproduces population-level properties, Inhibitory interneurons orchestrate the activity of neural circuits, but little is known about their population dynamics. By using 3D random-access calcium imaging, Gurnani and Silver show that cerebellar Golgi cell circuits exhibit multidimensional activity with common and distributed modes. A biologically detailed circuit model implicates electrical coupling in shaping the population dynamics.

Published

2021

38. Long-term down-regulation of GABA decreases orientation selectivity without affecting direction selectivity in mouse primary visual cortex

Author

Kenta M Hagihara and Kenichi eOhki

Subjects

V1, calcium imaging, primary visual cortex, two-photon imaging, inhibitory interneuron, orientation selectivity, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Inhibitory interneurons play important roles in the development of brain functions. In the visual cortex, functional maturation of inhibitory interneurons is essential for ocular dominance plasticity. However, roles of inhibitory interneurons in the development of orientation and direction selectivity, fundamental properties of primary visual cortex, are less understood. We examined orientation and direction selectivity of neurons in GAD67-GFP (Δneo) mice, in which expression of GABA in the brain is decreased in the newborn. We used in vivo two-photon calcium imaging to examine visual response of neurons in these mice and found that long-term decrease of GABA led to increase of response amplitude to non-preferred orientation of visual stimuli, which decreased orientation selectivity. In contrast, direction selectivity was not affected. These results suggest that orientation selectivity is decreased in mice with GABA down-regulation during development.

Published

2013

39. Specific Neuroligin3–αNeurexin1 signaling regulates GABAergic synaptic function in mouse hippocampus

Author

Yuka Imamura Kawasawa, Timmy Le, Masahiko Watanabe, Takeshi Uemura, Emily Demchak, Amy Cheung, Kenji Sakimura, David G Keener, Kohtarou Konno, Kensuke Futai, Toshikuni Sasaoka, Manabu Abe, Takuya Watanabe, and Motokazu Uchigashima

Subjects

0301 basic medicine, Gene isoform, inhibitory interneuron, Male, Mouse, QH301-705.5, hippocampus, Science, Cell Adhesion Molecules, Neuronal, Hippocampus, Nerve Tissue Proteins, Neurotransmission, Inhibitory postsynaptic potential, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Mice, 0302 clinical medicine, Postsynaptic potential, Animals, Biology (General), GABAergic Neurons, CA1 Region, Hippocampal, Neural Cell Adhesion Molecules, General Immunology and Microbiology, Cell adhesion molecule, Chemistry, General Neuroscience, Calcium-Binding Proteins, Membrane Proteins, General Medicine, electrophysiology, trans-synaptic adhesion, Cell biology, Mice, Inbred C57BL, 030104 developmental biology, Gene Knockdown Techniques, Synapses, Excitatory postsynaptic potential, Medicine, GABAergic, Female, 030217 neurology & neurosurgery, Research Article, Neuroscience

Abstract

Synapse formation and regulation require signaling interactions between pre- and postsynaptic proteins, notably cell adhesion molecules (CAMs). It has been proposed that the functions of neuroligins (Nlgns), postsynaptic CAMs, rely on the formation of trans-synaptic complexes with neurexins (Nrxns), presynaptic CAMs. Nlgn3 is a unique Nlgn isoform that localizes at both excitatory and inhibitory synapses. However, Nlgn3 function mediated via Nrxn interactions is unknown. Here we demonstrate that Nlgn3 localizes at postsynaptic sites apposing vesicular glutamate transporter 3-expressing (VGT3+) inhibitory terminals and regulates VGT3+ inhibitory interneuron-mediated synaptic transmission in mouse organotypic slice cultures. Gene expression analysis of interneurons revealed that the αNrxn1+AS4 splice isoform is highly expressed in VGT3+ interneurons as compared with other interneurons. Most importantly, postsynaptic Nlgn3 requires presynaptic αNrxn1+AS4 expressed in VGT3+ interneurons to regulate inhibitory synaptic transmission. Our results indicate that specific Nlgn–Nrxn signaling generates distinct functional properties at synapses.

Published

2020

40. Differences in Noradrenaline Receptor Expression Across Different Neuronal Subtypes in Macaque Frontal Eye Field

Author

Max Lee, Adrienne Mueller, and Tirin Moore

Subjects

genetic structures, Receptor expression, Neuroscience (miscellaneous), Macaque, neuromodulators, working memory, lcsh:RC321-571, lcsh:QM1-695, Cellular and Molecular Neuroscience, biology.animal, immunofluorescence, Receptor, Prefrontal cortex, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, microcircuit, Original Research, biology, Working memory, Pyramidal Neuron, macaque, food and beverages, lcsh:Human anatomy, Visual spatial attention, attention, Neuroanatomy, nervous system, Inhibitory interneuron, Anatomy, Neuroscience

Abstract

Cognitive functions such as attention and working memory are modulated by noradrenaline receptors in the prefrontal cortex (PFC). The frontal eye field (FEF) has been shown to play an important role in visual spatial attention. However, little is known about the underlying circuitry. The aim of this study was to characterize the expression of noradrenaline receptors on different pyramidal neuron and inhibitory interneuron subtypes in macaque FEF. Using immunofluorescence, we found broad expression of noradrenaline receptors across all layers of the FEF. Differences in the expression of different noradrenaline receptors were observed across different inhibitory interneuron subtypes. No significant differences were observed in the expression of noradrenaline receptors across different pyramidal neuron subtypes. However, we found that putative long-range projecting pyramidal neurons expressed all noradrenaline receptor subtypes at a much higher proportion than any of the other neuronal subtypes. Nearly all long-range projecting pyramidal neurons expressed all types of noradrenaline receptor, suggesting that there is no receptor-specific machinery acting on these long-range projecting pyramidal neurons. This pattern of expression among long-range projecting pyramidal neurons suggests a mechanism by which noradrenergic modulation of FEF activity influences attention and working memory.

Published

2020

41. Deep brain stimulation of the anterior nuclei of the thalamus can alleviate seizure severity and induce hippocampal GABAergic neuronal changes in a pilocarpine-induced epileptic mouse brain.

Author

Bae S, Lim HK, Jeong Y, Kim SG, Park SM, Shon YM, and Suh M

Subjects

Mice, Animals, Pilocarpine toxicity, Seizures chemically induced, Seizures therapy, Hippocampus physiology, Deep Brain Stimulation methods, Anterior Thalamic Nuclei physiology, Epilepsy

Abstract

Deep brain stimulation (DBS) of the anterior nucleus of the thalamus (ANT) has been widely used as an effective treatment for refractory temporal lobe epilepsy. Despite its promising clinical outcome, the exact mechanism of how ANT-DBS alleviates seizure severity has not been fully understood, especially at the cellular level. To assess effects of DBS, the present study examined electroencephalography (EEG) signals and locomotor behavior changes and conducted immunohistochemical analyses to examine changes in neuronal activity, number of neurons, and neurogenesis of inhibitory neurons in different hippocampal subregions. ANT-DBS alleviated seizure activity, abnormal locomotor behaviors, reduced theta-band, increased gamma-band EEG power in the interictal state, and increased the number of neurons in the dentate gyrus (DG). The number of parvalbumin- and somatostatin-expressing inhibitory neurons was recovered to the level in DG and CA1 of naïve mice. Notably, BrdU-positive inhibitory neurons were increased. In conclusion, ANT-DBS not only could reduce the number of seizures, but also could induce neuronal changes in the hippocampus, which is a key region involved in chronic epileptogenesis. Importantly, our results suggest that ANT-DBS may lead to hippocampal subregion-specific cellular recovery of GABAergic inhibitory neurons., (© The Author(s) 2022. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2022

42. Short promoters in viral vectors drive selective expression in mammalian inhibitory neurons, but do not restrict activity to specific inhibitory cell-types

Author

Jason L Nathanson, Roberto Jappelli, Eric D Scheeff, Gerard Manning, Kunihiko Obata, Sydney Brenner, and Edward M Callaway

Subjects

transcription factor, Cortex, Viral vector, Promoter, fugu, inhibitory interneuron, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Short cell-type specific promoter sequences are important for targeted gene therapy and studies of brain circuitry. We report on the ability of short promoter sequences to drive fluorescent protein expression in specific types of mammalian cortical inhibitory neurons using adeno-associated virus (AAV) and lentivirus (LV) vectors. We tested many gene regulatory sequences derived from fugu (Takifugu rubripes), mouse, human, and synthetic composite regulatory elements. All fugu compact promoters expressed in mouse cortex, with only the somatostatin (SST) and the neuropeptide Y (NPY) promoters largely restricting expression to GABAergic neurons. However these promoters did not control expression in inhibitory cells in a subtype specific manner. We also tested mammalian promoter sequences derived from genes putatively coexpressed or coregulated within three major inhibitory interneuron classes (PV, SST, VIP). In contrast to the fugu promoters, many of the mammalian sequences failed to express, and only the promoter from gene A930038C07Rik conferred restricted expression, although as in the case of the fugu sequences, this too was not inhibitory neuron subtype specific. Lastly and more promisingly, a synthetic sequence consisting of a composite regulatory element assembled with PAX6 E1.1 binding sites, NRSE and a minimal CMV promoter showed markedly restricted expression to a small subset of mostly inhibitory neurons, but whose commonalities are unknown.

Published

2009

43. Origin of intrinsic irregular firing in cortical interneurons.

Author

Stiefel, Klaus M., Englitz, Bernhard, and Sejnowski, Terrence J.

Subjects

*INTERNEURONS, *HIGHER nervous activity, *NEURONS, *PYRAMIDAL tract, *GAUSSIAN function, *ORNSTEIN-Uhlenbeck process, *CORTICAL blindness, *ANALYSIS of covariance

Abstract

Cortical spike trains are highly irregular both during ongoing, spontaneous activity and when driven at high firing rates. There is uncertainty about the source of this irregularity, ranging from intrinsic noise sources in neurons to collective effects in large-scale cortical networks. Cortical interneurons display highly irregular spike times (coefficient of variation of the interspike intervals >1) in response to dc-current injection in vitro. This is in marked contrast to cortical pyramidal cells, which spike highly irregularly in vivo, but regularly in vitro. We show with in vitro recordings and computational models that this is due to the fast activation kinetics of interneuronal K+ currents. This explanation holds over a wide parameter range and with Gaussian white, power-law, and Ornstein-Uhlenbeck noise. The intrinsically irregular spiking of interneurons could contribute to the irregularity of the cortical network. [ABSTRACT FROM AUTHOR]

Published

2013

44. Developmental trajectory of the endocannabinoid system in human dorsolateral prefrontal cortex.

Author

Long, Leonora E., Lind, Jonna, Webster, Maree, and Weickert, Cynthia Shannon

Subjects

*PREFRONTAL cortex, *MESSENGER RNA, *CANNABINOIDS, *NEURAL transmission, *ANANDAMIDE

Abstract

Background: Endocannabinoids provide control over cortical neurotransmission. We investigated the developmental expression of key genes in the endocannabinoid system across human postnatal life and determined whether they correspond to the development of markers for inhibitory interneurons, which shape cortical development. We used microarray with qPCR validation and in situ hybridisation to quantify mRNA for the central endocannabinoid receptor CB1R, endocannabinoid synthetic enzymes (DAGLα for 2-arachidonylglycerol [2-AG] and NAPE-PLD for anandamide), and inactivating enzymes (MGL and ABHD6 for 2-AG and FAAH for anandamide) in human dorsolateral prefrontal cortex (39 days - 49 years). Results: CB1R mRNA decreases until adulthood, particularly in layer II, after peaking between neonates and toddlers. DAGLα mRNA expression is lowest in early life and adulthood, peaking between school age and young adulthood. MGL expression declines after peaking in infancy, while ABHD6 increases from neonatal age. NAPE-PLD and FAAH expression increase steadily after infancy, peaking in adulthood. Conclusions: Stronger endocannabinoid regulation of presynaptic neurotransmission in both supragranular and infragranular cortical layers as indexed through higher CB1R mRNA may occur within the first few years of human life. After adolescence, higher mRNA levels of the anandamide synthetic and inactivating enzymes NAPE-PLD and FAAH suggest that a late developmental switch may occur where anandamide is more strongly regulated after adolescence than earlier in life. Thus, expression of key genes in the endocannabinoid system changes with maturation of cortical function. [ABSTRACT FROM AUTHOR]

Published

2012

45. Synchrony in Silicon: The Gamma Rhythm.

Author

Arthur, John V. and Boahen, Kwabena A.

Subjects

*SYNCHRONIZATION, *SILICON, *GAMMA (Electronic computer system), *NEURAL circuitry, *INTERNEURONS, *RESPONSE inhibition, *COMPLEMENTARY metal oxide semiconductors

Abstract

In this paper, we present a network of silicon interneurons that synchronize in the gamma frequency range (20-80 Hz). The gamma rhythm strongly influences neuronal spike timing within many brain regions, potentially playing a crucial role in computation. Yet it has largely been ignored in neuromorphic systems, which use mixed analog and digital circuits to model neurobiology in silicon. Our neurons synchronize by using shunting inhibition (conductance based) with a synaptic rise time. Synaptic rise time promotes synchrony by delaying the effect of inhibition, providing an opportune period for interneurons to spike together. Shunting inhibition, through its voltage dependence, inhibits interneurons that spike out of phase more strongly (delaying the spike further), pushing them into phase (in the next cycle). We characterize the interneuron, which consists of soma (cell body) and synapse circuits, fabricated in a 0.25-pm complementary metal-oxide-semiconductor (CMOS). Further, we show that synchronized interneurons (population of 256) spike with a period that is proportional to the synaptic rise time. We use these interneurons to entrain model excitatory principal neurons and to implement a form of object binding. [ABSTRACT FROM AUTHOR]

Published

2007

46. Spike-Timing-Dependent Plasticity of Neocortical Excitatory Synapses on Inhibitory Interneurons Depends on Target Cell Type.

Author

Jiang-teng Lu, Cheng-yu Li, Jian-Ping Zhao, Mu-ming Poo, and Xiao-hui Zhang

Subjects

*NEUROPLASTICITY, *SYNAPSES, *NEOCORTEX, *INTERNEURONS, *GLUTAMIC acid, *NEURAL stimulation, *NEUROSCIENCES

Abstract

Repetitive correlated spiking can induce long-term potentiation (LTP) and long-term depression (LTD) of many excitatory synapses on glutamatergic neurons, in a manner that depends on the timing of presynaptic and postsynaptic spiking. However, it is mostly unknown whether and how such spike-timing-dependent plasticity (STDP) operates at neocortical excitatory synapses on inhibitory interneurons, which have diverse physiological and morphological characteristics. In this study, we found that these synapses exhibit target-cell-dependent STDP. In layer 2/3 of the somatosensory cortex, the pyramidal cell (PC) forms divergent synapses on fast spiking (FS) and low-threshold spiking (LTS) interneurons that exhibit short-term synaptic depression and facilitation in response to high-frequency stimulation, respectively. At PC-LTS synapses, repetitive correlated spiking induced LTP or LTD, depending on the timing of presynaptic and postsynaptic spiking. However, regardless of the timing and frequency of spiking, correlated activity induced only LTD at PC-FS synapses. This target-cell-specific STDP was not caused by the difference in the short-term plasticity between these two types of synapses. Activation of postsynaptic NMDA subtype of glutamate receptors (NMDARs) was required for LTP induction at PC-LTS synapses, whereas activation of metabotropic glutamate receptors was required for LTD induction at both PC-LTS and PC-FS synapses. Additional analysis of synaptic currents suggests that LTP and LTD of PC-LTS synapses, but not LTD of PC-FS synapses, involves presynaptic modifications. Such dependence of both the induction and expression of STDP on the type of postsynaptic interneurons may contribute to differential processing and storage of information in cortical local circuits. [ABSTRACT FROM AUTHOR]

Published

2007

47. Distinct Subtypes of Somatostatin-Containing Neocortical Interneurons Revealed in Transgenic Mice.

Author

Yunyong Ma, Hang Hu, Berrebi, Albert S., Mathers, Peter H., and Agmon, Ariel

Subjects

*GABA, *NEURONS, *GREEN fluorescent protein, *GENE expression, *ELECTROPHYSIOLOGY

Abstract

GABA-releasing inhibitory interneurons in the cerebral cortex can be classified by their neurochemical content, firing patterns, or axonal targets, to name the most common criteria, but whether classifications using different criteria converge on the same neuronal subtypes, and how many such subtypes exist, is a matter of much current interest and considerable debate. To address these issues, we generated transgenic mice expressing green fluorescent protein (GFP) under control of the GAD67 promoter. In two of these lines, named X94 and X98, GFP expression in the barrel cortex was restricted to subsets of somatostatin-containing (SOM+) GABAergic interneurons, similar to the previously reported "GIN" line (Oliva et al., 2000), but the laminar distributions of GFP-expressing (GFP+) cell bodies in the X94, X98, and GIN lines were distinct and nearly complementary. We compared neurochemical content and axonal distribution patterns of GFP+ neurons among the three lines and analyzed in detail electrophysiological properties in a dataset of 150 neurons recorded in whole-cell, current-clamp mode. By all criteria, there was nearly perfect segregation of X94 and X98 GFP+ neurons, whereas GIN GFP+ neurons exhibited intermediate properties. In the X98 line, GFP expression was found in infragranular, calbindin-containing, layer 1-targeting ("Martinotti") cells that had a propensity to fire low-threshold calcium spikes, whereas X94 GFP+ cells were stuttering interneurons with quasi fast-spiking properties, residing in and targeting the thalamo-recipient neocortical layers. We conclude that much of the variability previously attributed to neocortical SOM+ interneurons can be accounted for by their natural grouping into distinct subtypes. [ABSTRACT FROM AUTHOR]

Published

2006

48. M174. REDUCED CHEMOKINE SIGNALLING CAPACITY IS ASSOCIATED WITH INHIBITORY INTERNEURON DYSFUNCTION IN SUBCORTICAL BRAIN REGIONS IN SCHIZOPHRENIA AND BIPOLAR DISORDER

Author

Christin Weissleder, Maree J. Webster, and Cynthia Shannon Weickert

Subjects

Chemokine, Poster Session II, biology, business.industry, AcademicSubjects/MED00810, medicine.disease, Psychiatry and Mental health, Signalling, Schizophrenia, mental disorders, biology.protein, medicine, Inhibitory interneuron, Bipolar disorder, business, Neuroscience

Abstract

Background The subependymal zone (SEZ) adjacent to the lateral ventricles represents the largest reservoir of postnatally-generated cortical and striatal inhibitory interneurons in the human brain. Expression of markers representing the generation of neuronal progenitors from neural stem cells is reduced in the adult SEZ in schizophrenia and bipolar disorder; however, underlying mechanisms and relationships to inhibitory interneuron dysfunction remain unknown. Stem cell maintenance, neuronal migration and cell survival are regulated by signaling of the CXC motif chemokine 12 (CXCL12) through CXC motif chemokine receptors 4 (CXCR4) and 7 (CXCR7), which are increasingly implicated in the pathophysiology of psychiatric disorders. Methods Post-mortem tissue was obtained from 33 schizophrenia, 32 bipolar disorder and 33 control cases from the Stanley Medical Research Institute. SEZ and caudate nucleus tissue was dissected from 60 µm sections for RNA isolation and cDNA synthesis. Gene expression of CXCL12, CXCR4 and CXCR7 were determined by quantitative polymerase chain reactions. Semi-partial correlations were performed to assess whether CXC chemokine family member mRNAs may correlate with markers of neural stem cells (PROM1, GFAPD), neuronal progenitors (SOX2, ASCL1) and inhibitory interneurons (CALB2, NPY) in the SEZ and caudate nucleus. Results In the SEZ, CXCL12 mRNA was decreased in schizophrenia compared to controls and bipolar disorder (14–24%, all p≤0.03). CXCR4 and CXCR7 mRNAs were both decreased in schizophrenia and bipolar disorder compared to controls (9–33%, all p≤0.05). CXCL12, CXCR4 and CXCR7 expression positively correlated with PROM1, GFAPD, SOX2 and ASCL1 mRNAs (0.28≥sr≤0.61). In the caudate nucleus, CXCL12 mRNA was decreased in schizophrenia and bipolar disorder compared to controls (19–26%, all p≤0.05). CXCR4 mRNA was decreased in schizophrenia compared to controls (20%, p=0.01), while CXCR7 expression did not significantly differ across diagnostic groups. CALB2 and NPY mRNAs were increased in bipolar disorder compared to controls (13–27%, all p≤0.05). CXCR4 expression positively correlated with CALB2 mRNA (sr=0.26), while CXCR7 expression negatively correlated with NPY mRNA (sr=0.26). Discussion These findings provide the first molecular evidence of decreased CXC chemokine family member expression in the SEZ and caudate nucleus in psychiatric disorders, with exacerbated deficits in schizophrenia compared to bipolar disorder. Dysregulated CXC chemokine family member expression may hamper neural stem cell maintenance and neuronal differentiation, which may contribute to inhibitory interneuron dysfunction in psychiatric disorders. Future work will determine the cellular localisation of CXCR4 and CXCR7 expression in the SEZ and caudate nucleus to disentangle the regulatory role of CXCL12 signalling in the generation, migration and survival of inhibitory interneurons in the human brain.

Published

2020

49. Preexisting hippocampal network dynamics constrain optogenetically induced place fields

Author

György Buzsáki, Euisik Yoon, Kanghwan Kim, Sam McKenzie, Roman Huszár, and Daniel F. English

Subjects

0303 health sciences, Computer science, Dentate gyrus, Sensory system, Hippocampal formation, Optogenetics, Network dynamics, 03 medical and health sciences, Neural activity, 0302 clinical medicine, medicine.anatomical_structure, Neuronal circuits, Lateral inhibition, Attractor, medicine, Inhibitory interneuron, Pyramidal cell, Neuroscience, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

SummaryNeuronal circuits face a fundamental tension between maintaining existing structure and changing to accommodate new information. Memory models often emphasize the need to encode novel patterns of neural activity imposed by “bottom-up” sensory drive. In such models, learning is achieved through synaptic alterations, a process which potentially interferes with previously stored knowledge 1-3. Alternatively, neuronal circuits generate and maintain a preconfigured stable dynamic, sometimes referred to as an attractor, manifold, or schema 4-7, with a large reservoir of patterns available for matching with novel experiences 8-13. Here, we show that incorporation of arbitrary signals is constrained by pre-existing circuit dynamics. We optogenetically stimulated small groups of hippocampal neurons as mice traversed a chosen segment of a linear track, mimicking the emergence of place fields 1,14,15, while simultaneously recording the activity of stimulated and non-stimulated neighboring cells. Stimulation of principal neurons in CA1, but less so CA3 or the dentate gyrus, induced persistent place field remapping. Novel place fields emerged in both stimulated and non-stimulated neurons, which could be predicted from sporadic firing in the new place field location and the temporal relationship to peer neurons prior to the optogenetic perturbation. Circuit modification was reflected by altered spike transmission between connected pyramidal cell – inhibitory interneuron pairs, which persisted during post-experience sleep. We hypothesize that optogenetic perturbation unmasked sub-threshold, pre-existing place fields16,17. Plasticity in recurrent/lateral inhibition may drive learning through rapid exploration of existing states.

Published

2019

50. Capacitance measurement of dendritic exocytosis in an electrically coupled inhibitory retinal interneuron: an experimental and computational study

Author

Bas-Jan Zandt, Margaret Lin Veruki, and Espen Hartveit

Subjects

inhibitory interneuron, retina, Patch-Clamp Techniques, Interneuron, presynaptic, Physiology, AII amacrine cell, capacitance, 030204 cardiovascular system & hematology, Inhibitory postsynaptic potential, Synaptic vesicle, Capacitance, Exocytosis, lcsh:Physiology, 03 medical and health sciences, 0302 clinical medicine, Neuronal Plasticity and Repair, Postsynaptic potential, Interneurons, Physiology (medical), medicine, Neural Circuits and Systems, Animals, Computer Simulation, Original Research, lcsh:QP1-981, Chemistry, Cell Membrane, Dendrites, Rats, Electrophysiology, medicine.anatomical_structure, Amacrine Cells, Biophysics, Soma, Female, Sensory Neuroscience, exocytosis, compartmental model, 030217 neurology & neurosurgery, glycine

Abstract

Exocytotic release of neurotransmitter can be quantified by electrophysiological recording from postsynaptic neurons. Alternatively, fusion of synaptic vesicles with the cell membrane can be measured as increased capacitance by recording directly from a presynaptic neuron. The “Sine + DC” technique is based on recording from an unbranched cell, represented by an electrically equivalent RC-circuit. It is challenging to extend such measurements to branching neurons where exocytosis occurs at a distance from a somatic recording electrode. The AII amacrine is an important inhibitory interneuron of the mammalian retina and there is evidence that exocytosis at presynaptic lobular dendrites increases the capacitance. Here, we combined electrophysiological recording and computer simulations with realistic compartmental models to explore capacitance measurements of rat AII amacrine cells. First, we verified the ability of the “Sine + DC” technique to detect depolarizationevoked exocytosis in physiological recordings. Next, we used compartmental modeling to demonstrate that capacitance measurements can detect increased membrane surface area at lobular dendrites. However, the accuracy declines for lobular dendrites located further from the soma due to frequency-dependent signal attenuation. For sine wave frequencies ≥1 kHz, the magnitude of the total releasable pool of synaptic vesicles will be significantly underestimated. Reducing the sine wave frequency increases overall accuracy, but when the frequency is sufficiently low that exocytosis can be detected with high accuracy from all lobular dendrites (~100 Hz), strong electrical coupling between AII amacrines compromises the measurements. These results need to be taken into account in studies with capacitance measurements from these and other electrically coupled neurons. publishedVersion

Published

2019