Your search keyword '"Pyramidal cells"' showing total 13,550 results

1. Degraded tactile coding in the Cntnap2 mouse model of autism.

Author

Wang, Han and Feldman, Daniel

Subjects

CP: Neuroscience, autism spectrum disorder, barrel cortex, layer 2/3, longitudinal imaging, representational drift, sensory coding, whisker, Animals, Membrane Proteins, Nerve Tissue Proteins, Somatosensory Cortex, Mice, Autistic Disorder, Disease Models, Animal, Vibrissae, Mice, Knockout, Touch, Mice, Inbred C57BL, Pyramidal Cells, Male, Proto-Oncogene Proteins c-fos

Abstract

Atypical sensory processing is common in autism, but how neural coding is disrupted in sensory cortex is unclear. We evaluate whisker touch coding in L2/3 of somatosensory cortex (S1) in Cntnap2-/- mice, which have reduced inhibition. This classically predicts excess pyramidal cell spiking, but this remains controversial, and other deficits may dominate. We find that c-fos expression is elevated in S1 of Cntnap2-/- mice under spontaneous activity conditions but is comparable to that of control mice after whisker stimulation, suggesting normal sensory-evoked spike rates. GCaMP8m imaging from L2/3 pyramidal cells shows no excess whisker responsiveness, but it does show multiple signs of degraded somatotopic coding. This includes broadened whisker-tuning curves, a blurred whisker map, and blunted whisker point representations. These disruptions are greater in noisy than in sparse sensory conditions. Tuning instability across days is also substantially elevated in Cntnap2-/-. Thus, Cntnap2-/- mice show no excess sensory-evoked activity, but a degraded and unstable tactile code in S1.

Published

2024

2. Intranasal Delivery of Ketamine Induces Cortical Disinhibition.

Author

Qiao, Xin, Grieco, Steven, Xu, Xiangmin, Yu, Zhaoxia, and Holmes, Todd

Subjects

depression, disinhibition, intranasal, ketamine, parvalbumin, visual cortex, Mice, Animals, Ketamine, Pyramidal Cells, Interneurons, Neuronal Plasticity, Parvalbumins

Abstract

Our previous studies find that subcutaneously administered (s.c.) subanesthetic ketamine promotes sustained cortical disinhibition and plasticity in adult mouse binocular visual cortex (bV1). We hypothesized that intranasal delivery (i.n.) of subanesthetic ketamine may have similar actions. To test this, we delivered ketamine (10 mg/kg, i.n.) to adult mice and then recorded excitatory pyramidal neurons or PV+ interneurons in L2/3 of bV1 slices. In pyramidal neurons the baseline IPSC amplitudes from mice treated with ketamine are significantly weaker than those in control mice. Acute bath application of neuregulin-1 (NRG1) to cortical slices increases these IPSC amplitudes in mice treated with ketamine but not in controls. In PV+ interneurons, the baseline EPSC amplitudes from mice treated with ketamine are significantly weaker than those in control mice. Acute bath application of NRG1 to cortical slices increases these EPSC amplitudes in mice treated with ketamine but not in controls. We also found that mice treated with ketamine exhibit increased pCREB staining in L2/3 of bV1. Together, our results show that a single intranasal delivery of ketamine reduces PV+ interneuron excitation and reduces pyramidal neuron inhibition and that these effects are acutely reversed by NRG1. These results are significant as they show that intranasal delivery of ketamine induces cortical disinhibition, which has implications for the treatment of psychiatric, neurologic, and ophthalmic disorders.

Published

2024

3. Loss of spines in the prelimbic cortex is detrimental to working memory in mice with early-life adversity.

Author

Xu, Liping, Liu, Yue, Long, Jingyi, He, Xiulan, Xie, Fanbing, Yin, Qiao, Chen, Michael, Long, Dahong, and Chen, Yuncai

Subjects

Mice, Animals, Memory, Short-Term, Adverse Childhood Experiences, Prefrontal Cortex, Pyramidal Cells, Neurons, Memory Disorders, Dendritic Spines

Abstract

Adverse experiences in early life can shape neuronal structures and synaptic function in multiple brain regions, leading to deficits of distinct cognitive functions later in life. Focusing on the pyramidal cells of the prelimbic cortex (PrL), a main subregion of the medial prefrontal cortex, the impact of early-life adversity (ELA) was investigated in a well-established animal model generated by changing the rearing environment during postnatal days 2 to 9 (P2-P9), a sensitive developmental period. ELA has enduring detrimental impacts on the dendritic spines of PrL pyramidal cells, which is most apparent in a spatially circumscribed region. Specifically, ELA affects both thin and mushroom-type spines, and ELA-provoked loss of spines is observed on selective dendritic segments of PrL pyramidal cells in layers II-III and V-VI. Reduced postsynaptic puncta represented by postsynaptic density protein-95 (PSD-95), but not synaptophysin-labelled presynaptic puncta, in ELA mice supports the selective loss of spines in the PrL. Correlation analysis indicates that loss of spines and postsynaptic puncta in the PrL contributes to the poor spatial working memory of ELA mice, and thin spines may play a major role in working memory performance. To further understand whether loss of spines affects glutamatergic transmission, AMPA- and NMDA-receptor-mediated synaptic currents (EPSCs) were recorded in a group of Thy1-expressing PrL pyramidal cells. ELA mice exhibited a depressed glutamatergic transmission, which is accompanied with a decreased expression of GluR1 and NR1 subunits in the PrL. Finally, upregulating the activation of Thy1-expressing PrL pyramidal cells via excitatory DREADDs can efficiently improve the working memory performance of ELA mice in a T-maze-based task, indicating the potential of a chemogenetic approach in restoring ELA-provoked memory deficits.

Published

2023

4. Targeting aberrant dendritic integration to treat cognitive comorbidities of epilepsy

Author

Masala, Nicola, Pofahl, Martin, Haubrich, André N, Sameen Islam, Khondker Ushna, Nikbakht, Negar, Pasdarnavab, Maryam, Bohmbach, Kirsten, Araki, Kunihiko, Kamali, Fateme, Henneberger, Christian, Golcuk, Kurtulus, Ewell, Laura A, Blaess, Sandra, Kelly, Tony, and Beck, Heinz

Subjects

Biomedical and Clinical Sciences, Biological Psychology, Neurosciences, Psychology, Pharmacology and Pharmaceutical Sciences, Neurodegenerative, Epilepsy, Behavioral and Social Science, Brain Disorders, Basic Behavioral and Social Science, Aetiology, 2.1 Biological and endogenous factors, Neurological, Mice, Animals, Dendrites, Hippocampus, Acetamides, Pyramidal Cells, Action Potentials, epilepsy, dendritic integration, cognitive comorbidities, calcium imaging, dendritic spike, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery, Biomedical and clinical sciences, Health sciences

Abstract

Memory deficits are a debilitating symptom of epilepsy, but little is known about mechanisms underlying cognitive deficits. Here, we describe a Na+ channel-dependent mechanism underlying altered hippocampal dendritic integration, degraded place coding and deficits in spatial memory. Two-photon glutamate uncaging experiments revealed a marked increase in the fraction of hippocampal first-order CA1 pyramidal cell dendrites capable of generating dendritic spikes in the kainate model of chronic epilepsy. Moreover, in epileptic mice dendritic spikes were generated with lower input synchrony, and with a lower threshold. The Nav1.3/1.1 selective Na+ channel blocker ICA-121431 reversed dendritic hyperexcitability in epileptic mice, while the Nav1.2/1.6 preferring anticonvulsant S-Lic did not. We used in vivo two-photon imaging to determine if aberrant dendritic excitability is associated with altered place-related firing of CA1 neurons. We show that ICA-121431 improves degraded hippocampal spatial representations in epileptic mice. Finally, behavioural experiments show that reversing aberrant dendritic excitability with ICA-121431 reverses hippocampal memory deficits. Thus, a dendritic channelopathy may underlie cognitive deficits in epilepsy and targeting it pharmacologically may constitute a new avenue to enhance cognition.

Published

2023

5. Single-nucleus Atlas of Sevoflurane-induced Hippocampal Cell Type– and Sex-specific Effects during Development in Mice

Author

Song, Shao-yong, Peng, Ke, Meng, Xiao-wen, Shan, Xi-sheng, Chen, Qing-cai, Zhao, Wei-ming, Shen, Biyu, Qiu, Hong, Liu, Hong, Liu, Hua-yue, and Ji, Fu-hai

Subjects

Neurosciences, Genetics, Pediatric, Underpinning research, 1.1 Normal biological development and functioning, Male, Female, Animals, Mice, Sevoflurane, Dentate Gyrus, Hippocampus, Neurons, Pyramidal Cells, Clinical Sciences, Anesthesiology

Abstract

BackgroundMultiple neonatal exposures to sevoflurane induce neurocognitive dysfunctions in rodents. The lack of cell type-specific information after sevoflurane exposure limits the mechanistic understanding of these effects. In this study, the authors tested the hypothesis that sevoflurane exposures alter the atlas of hippocampal cell clusters and have neuronal and nonneuronal cell type-specific effects in mice of both sexes.MethodsNeonatal mice were exposed to 3% sevoflurane for 2 h at postnatal days 6, 8, and 10 and analyzed for the exposure effects at postnatal day 37. Single-nucleus RNA sequencing was performed in the hippocampus followed by in situ hybridization to validate the results of RNA sequencing. The Morris Water Maze test was performed to test neurocognitive function.ResultsThe authors found sex-specific distribution of hippocampal cell types in control mice alongside cell type- and sex-specific effects of sevoflurane exposure on distinct hippocampal cell populations. There were important changes in male but not in female mice after sevoflurane exposure regarding the proportions of cornu ammonis 1 neurons (control vs. sevoflurane, males: 79.9% vs. 32.3%; females: 27.3% vs. 24.3%), dentate gyrus (males: 4.2% vs. 23.4%; females: 36.2% vs. 35.8%), and oligodendrocytes (males: 0.6% vs. 6.9%; females: 5.9% vs. 7.8%). In male but not in female mice, sevoflurane altered the number of significantly enriched ligand-receptor pairs in the cornu ammonis 1, cornu ammonis 3, and dente gyrus trisynaptic circuit (control vs. sevoflurane, cornu ammonis 1-cornu ammonis 3: 18 vs. 42 in males and 15 vs. 21 in females; cornu ammonis 1-dentate gyrus: 21 vs. 35 in males and 12 vs. 20 in females; cornu ammonis 3-dentate gyrus: 25 vs. 45 in males and 17 vs. 20 in females), interfered with dentate gyrus granule cell neurogenesis, hampered microglia differentiation, and decreased cornu ammonis 1 pyramidal cell diversity. Oligodendrocyte differentiation was specifically altered in females with increased expressions of Mbp and Mag. In situ hybridization validated the increased expression of common differentially expressed genes.ConclusionsThis single-nucleus RNA sequencing study reveals the hippocampal atlas of mice, providing a comprehensive resource for the neuronal and nonneuronal cell type- and sex-specific effects of sevoflurane during development.Editor’s perspective

Published

2023

6. Multielectrode Cortical Stimulation Selectively Induces Unidirectional Wave Propagation of Excitatory Neuronal Activity in Biophysical Neural Model.

Author

Halgren, Alma, Siegel, Zarek, Golden, Ryan, and Bazhenov, Maksim

Subjects

biophysical model, cortical simulation, multielectrode arrays, network model, stimulation, Neurons, Pyramidal Cells, Brain, Interneurons, Electrodes, Models, Neurological, Electric Stimulation

Abstract

Cortical stimulation is emerging as an experimental tool in basic research and a promising therapy for a range of neuropsychiatric conditions. As multielectrode arrays enter clinical practice, the possibility of using spatiotemporal patterns of electrical stimulation to induce desired physiological patterns has become theoretically possible, but in practice can only be implemented by trial-and-error because of a lack of predictive models. Experimental evidence increasingly establishes traveling waves as fundamental to cortical information-processing, but we lack an understanding of how to control wave properties despite rapidly improving technologies. This study uses a hybrid biophysical-anatomical and neural-computational model to predict and understand how a simple pattern of cortical surface stimulation could induce directional traveling waves via asymmetric activation of inhibitory interneurons. We found that pyramidal cells and basket cells are highly activated by the anodal electrode and minimally activated by the cathodal electrodes, while Martinotti cells are moderately activated by both electrodes but exhibit a slight preference for cathodal stimulation. Network model simulations found that this asymmetrical activation results in a traveling wave in superficial excitatory cells that propagates unidirectionally away from the electrode array. Our study reveals how asymmetric electrical stimulation can easily facilitate traveling waves by relying on two distinct types of inhibitory interneuron activity to shape and sustain the spatiotemporal dynamics of endogenous local circuit mechanisms.SIGNIFICANCE STATEMENT Electrical brain stimulation is becoming increasingly useful to probe the workings of brain and to treat a variety of neuropsychiatric disorders. However, stimulation is currently performed in a trial-and-error fashion as there are no methods to predict how different electrode arrangements and stimulation paradigms will affect brain functioning. In this study, we demonstrate a hybrid modeling approach, which makes experimentally testable predictions that bridge the gap between the microscale effects of multielectrode stimulation and the resultant circuit dynamics at the mesoscale. Our results show how custom stimulation paradigms can induce predictable, persistent changes in brain activity, which has the potential to restore normal brain function and become a powerful therapy for neurological and psychiatric conditions.

Published

2023

7. Pyramidal cell types drive functionally distinct cortical activity patterns during decision-making

Author

Musall, Simon, Sun, Xiaonan R, Mohan, Hemanth, An, Xu, Gluf, Steven, Li, Shu-Jing, Drewes, Rhonda, Cravo, Emma, Lenzi, Irene, Yin, Chaoqun, Kampa, Björn M, and Churchland, Anne K

Subjects

Neurosciences, Behavioral and Social Science, Basic Behavioral and Social Science, 1.2 Psychological and socioeconomic processes, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Pyramidal Cells, Neurons, Frontal Lobe, Interneurons, Optogenetics, Psychology, Cognitive Sciences, Neurology & Neurosurgery

Abstract

Understanding how cortical circuits generate complex behavior requires investigating the cell types that comprise them. Functional differences across pyramidal neuron (PyN) types have been observed within cortical areas, but it is not known whether these local differences extend throughout the cortex, nor whether additional differences emerge when larger-scale dynamics are considered. We used genetic and retrograde labeling to target pyramidal tract, intratelencephalic and corticostriatal projection neurons and measured their cortex-wide activity. Each PyN type drove unique neural dynamics, both at the local and cortex-wide scales. Cortical activity and optogenetic inactivation during an auditory decision task revealed distinct functional roles. All PyNs in parietal cortex were recruited during perception of the auditory stimulus, but, surprisingly, pyramidal tract neurons had the largest causal role. In frontal cortex, all PyNs were required for accurate choices but showed distinct choice tuning. Our results reveal that rich, cell-type-specific cortical dynamics shape perceptual decisions.

Published

2023

8. A cell-type-specific alternative splicing regulator shapes synapse properties in a trans-synaptic manner

Author

Traunmüller, Lisa, Schulz, Jan, Ortiz, Raul, Feng, Huijuan, Furlanis, Elisabetta, Gomez, Andrea M, Schreiner, Dietmar, Bischofberger, Josef, Zhang, Chaolin, and Scheiffele, Peter

Subjects

Human Genome, Genetics, Neurosciences, 1.1 Normal biological development and functioning, Underpinning research, Generic health relevance, Neurological, Alternative Splicing, Neurons, Synapses, Pyramidal Cells, Interneurons, Hippocampus, CP: Neuroscience, KHDRBS3, alternative splicing, autism, neurexin, neurodevelopmental disorder, neuroligin, object recognition, synapse formation, synaptic plasticity, Biochemistry and Cell Biology, Medical Physiology

Abstract

The specification of synaptic properties is fundamental for the function of neuronal circuits. "Terminal selector" transcription factors coordinate terminal gene batteries that specify cell-type-specific properties. Moreover, pan-neuronal splicing regulators have been implicated in directing neuronal differentiation. However, the cellular logic of how splicing regulators instruct specific synaptic properties remains poorly understood. Here, we combine genome-wide mapping of mRNA targets and cell-type-specific loss-of-function studies to uncover the contribution of the RNA-binding protein SLM2 to hippocampal synapse specification. Focusing on pyramidal cells and somatostatin (SST)-positive GABAergic interneurons, we find that SLM2 preferentially binds and regulates alternative splicing of transcripts encoding synaptic proteins. In the absence of SLM2, neuronal populations exhibit normal intrinsic properties, but there are non-cell-autonomous synaptic phenotypes and associated defects in a hippocampus-dependent memory task. Thus, alternative splicing provides a critical layer of gene regulation that instructs specification of neuronal connectivity in a trans-synaptic manner.

Published

2023

9. Aging differentially affects LTCC function in hippocampal CA1 and piriform cortex pyramidal neurons

Author

Maziar, Aida, Critch, Tristian NRHY, Ghosh, Sourav, Rajani, Vishaal, Flynn, Cassandra M, Qin, Tian, Reinhardt, Camila, Man, Kwun Nok Mimi, Lee, Amy, Hell, Johannes W, and Yuan, Qi

Subjects

Biological Psychology, Biomedical and Clinical Sciences, Neurosciences, Psychology, Mental Health, Behavioral and Social Science, Neurodegenerative, Basic Behavioral and Social Science, Aging, Neurological, Humans, Rats, Animals, Aged, Nimodipine, Piriform Cortex, Pyramidal Cells, Hippocampus, Calcium Channels, L-Type, aging, hippocampus, L-type calcium channels, piriform cortex, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

Aging is associated with cognitive decline and memory loss in humans. In rats, aging-associated neuronal excitability changes and impairments in learning have been extensively studied in the hippocampus. Here, we investigated the roles of L-type calcium channels (LTCCs) in the rat piriform cortex (PC), in comparison with those of the hippocampus. We employed spatial and olfactory tasks that involve the hippocampus and PC. LTCC blocker nimodipine administration impaired spontaneous location recognition in adult rats (6-9 months). However, the same blocker rescued the spatial learning deficiency in aged rats (19-23 months). In an odor-associative learning task, infusions of nimodipine into either the PC or dorsal CA1 impaired the ability of adult rats to learn a positive odor association. Again, in contrast, nimodipine rescued odor associative learning in aged rats. Aged CA1 neurons had higher somatic expression of LTCC Cav1.2 subunits, exhibited larger afterhyperpolarization (AHP) and lower excitability compared with adult neurons. In contrast, PC neurons from aged rats showed higher excitability and no difference in AHP. Cav1.2 expression was similar in adult and aged PC somata, but relatively higher in PSD95- puncta in aged dendrites. Our data suggest unique features of aging-associated changes in LTCCs in the PC and hippocampus.

Published

2023

10. Creation of Neuronal Ensembles and Cell-Specific Homeostatic Plasticity through Chronic Sparse Optogenetic Stimulation.

Author

Liu, Benjamin, Seay, Michael J, and Buonomano, Dean V

Subjects

Biomedical and Clinical Sciences, Neurosciences, Basic Behavioral and Social Science, Behavioral and Social Science, Mental Health, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Mice, Animals, Optogenetics, Neuronal Plasticity, Neurons, Pyramidal Cells, Homeostasis, computational model, homeostatic plasticity, neural dynamics, neuronal ensembles, Up-states, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Cortical computations emerge from the dynamics of neurons embedded in complex cortical circuits. Within these circuits, neuronal ensembles, which represent subnetworks with shared functional connectivity, emerge in an experience-dependent manner. Here we induced ensembles in ex vivo cortical circuits from mice of either sex by differentially activating subpopulations through chronic optogenetic stimulation. We observed a decrease in voltage correlation, and importantly a synaptic decoupling between the stimulated and nonstimulated populations. We also observed a decrease in firing rate during Up-states in the stimulated population. These ensemble-specific changes were accompanied by decreases in intrinsic excitability in the stimulated population, and a decrease in connectivity between stimulated and nonstimulated pyramidal neurons. By incorporating the empirically observed changes in intrinsic excitability and connectivity into a spiking neural network model, we were able to demonstrate that changes in both intrinsic excitability and connectivity accounted for the decreased firing rate, but only changes in connectivity accounted for the observed decorrelation. Our findings help ascertain the mechanisms underlying the ability of chronic patterned stimulation to create ensembles within cortical circuits and, importantly, show that while Up-states are a global network-wide phenomenon, functionally distinct ensembles can preserve their identity during Up-states through differential firing rates and correlations.SIGNIFICANCE STATEMENT The connectivity and activity patterns of local cortical circuits are shaped by experience. This experience-dependent reorganization of cortical circuits is driven by complex interactions between different local learning rules, external input, and reciprocal feedback between many distinct brain areas. Here we used an ex vivo approach to demonstrate how simple forms of chronic external stimulation can shape local cortical circuits in terms of their correlated activity and functional connectivity. The absence of feedback between different brain areas and full control of external input allowed for a tractable system to study the underlying mechanisms and development of a computational model. Results show that differential stimulation of subpopulations of neurons significantly reshapes cortical circuits and forms subnetworks referred to as neuronal ensembles.

Published

2023

11. Synaptic boutons are smaller in chandelier cell cartridges in autism

Author

Hong, Tiffany, McBride, Erin, Dufour, Brett D, Falcone, Carmen, Doan, Mai, Noctor, Stephen G, and Martínez-Cerdeño, Verónica

Subjects

Biological Psychology, Biomedical and Clinical Sciences, Psychology, Pediatric, Autism, Brain Disorders, Mental Health, Intellectual and Developmental Disabilities (IDD), Neurosciences, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Humans, Presynaptic Terminals, Autistic Disorder, Neurons, Axons, Pyramidal Cells, Prefrontal Cortex, General Science & Technology

Abstract

Chandelier (Ch) cells are cortical interneurons with axon terminal structures known as cartridges that synapse on the axon initial segment of excitatory pyramidal neurons. Previous studies indicate that the number of Ch cells is decreased in autism, and that GABA receptors are decreased in the Ch cell synaptic target in the prefrontal cortex. To further identify Ch cell alterations, we examined whether the length of cartridges, and the number, density, and size of Ch cell synaptic boutons, differed in the prefrontal cortex of cases with autism versus control cases. We collected samples of postmortem human prefrontal cortex (Brodmann Area (BA) 9, 46, and 47) from 20 cases with autism and 20 age- and sex-matched control cases. Ch cells were labeled using an antibody against parvalbumin, a marker that labeles soma, cartridges, and synaptic boutons. We found no significant difference in the average length of cartridges, or in the total number or density of boutons in control subjects vs. subjects with autism. However, we found a significant decrease in the size of Ch cell boutons in those with autism. The reduced size of Ch cell boutons may result in reduced inhibitory signal transmission and impact the balance of excitation to inhibition in the prefrontal cortex in autism.

Published

2023

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

Author

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

Subjects

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

Abstract

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

Published

2023

13. VTA Excitatory Neurons Control Reward-driven Behavior by Modulating Infralimbic Cortical Firing.

Author

Adeyelu, Tolulope, Vaughn, Tashonda, and Ogundele, Olalekan M.

Subjects

*NEURONS, *REWARD (Psychology), *PREFRONTAL cortex, *PYRAMIDAL neurons, *GLUTAMIC acid, *GLUTAMATE receptors

Abstract

• Putative IL ensembles encode reward through a net suppression of FR. • FR suppression is similar during reward and omitted reward intervals. • VTA glutamate inhibition caused FR increase in IL ensembles. • Loss of IL inhibition is linked with a decrease in reward-target association. The functional dichotomy of anatomical regions of the medial prefrontal cortex (mPFC) has been tested with greater certainty in punishment-driven tasks, and less so in reward-oriented paradigms. In the infralimbic cortex (IL), known for behavioral suppression (STOP), tasks linked with reward or punishment are encoded through firing rate decrease or increase, respectively. Although the ventral tegmental area (VTA) is the brain region governing reward/aversion learning, the link between its excitatory neuron population and IL encoding of reward-linked behavioral expression is unclear. Here, we present evidence that IL ensembles use a population-based mechanism involving broad inhibition of principal cells at intervals when reward is presented or expected. The IL encoding mechanism was consistent across multiple sessions with randomized rewarded target sites. Most IL neurons exhibit FR (Firing Rate) suppression during reward acquisition intervals (T1), and subsequent exploration of previously rewarded targets when the reward is omitted (T2). Furthermore, FR suppression in putative IL ensembles persisted for intervals that followed reward-linked target events. Pairing VTA glutamate inhibition with reward acquisition events reduced the weight of reward-target association expressed as a lower affinity for previously rewarded targets. For these intervals, fewer IL neurons per mouse trial showed FR decrease and were accompanied by an increase in the percentage of units with no change in FR. Together, we conclude that VTA glutamate neurons are likely involved in establishing IL inhibition states that encode reward acquisition, and subsequent reward-target association. [ABSTRACT FROM AUTHOR]

Published

2024

14. Cell-type specific inhibitory plasticity in subicular pyramidal cells.

Author

Guinet, Alix, Grosser, Sabine, Özbay, Duru, Behr, Joachim, and Vida, Imre

Subjects

PYRAMIDAL neurons, COMPLEMENT inhibition, LONG-term potentiation, HIPPOCAMPUS (Brain), SOLITARY nucleus, NEURONS, AMPA receptors

Abstract

The balance between excitation and inhibition is essential to the proper function of cortical circuits. To maintain this balance during dynamic network activity, modulation of the strength of inhibitory synapses is a central requirement. In this study, we aimed to characterize perisomatic inhibition and its plasticity onto pyramidal cells (PCs) in the subiculum, the main output region of the hippocampus. We performed whole-cell patch-clamp recordings from the two main functional PC types, burst (BS) and regular spiking (RS) neurons in acute rat hippocampal slices and applied two different extracellular high-frequency stimulation paradigms: non-associative (presynaptic stimulation only) and associative stimulation (concurrent pre-and postsynaptic stimulation) to induce plasticity. Our results revealed cell type-specific differences in the expression of inhibitory plasticity depending on the induction paradigm: While associative stimulation caused robust inhibitory plasticity in both cell types, non-associative stimulation produced long-term potentiation in RS, but not in BS PCs. Analysis of paired-pulse ratio, variance of IPSPs, and postsynaptic Ca2+ buffering indicated a dominant postsynaptic calcium-dependent signaling and expression of inhibitory plasticity in both PC types. This divergence in inhibitory plasticity complements a stronger inhibition and a higher intrinsic excitability in RS as compared to BS neurons, suggesting differential involvement of the two PC types during network activation and information processing in the subiculum. [ABSTRACT FROM AUTHOR]

Published

2024

15. Porphyran Attenuates Neuronal Loss in the Hippocampal CA1 Subregion Induced by Ischemia and Reperfusion in Gerbils by Inhibiting NLRP3 Inflammasome-Mediated Neuroinflammation.

Author

Kim, Dae Won, Lee, Tae-Kyeong, Ahn, Ji Hyeon, Yang, Se-Ran, Shin, Myoung Cheol, Cho, Jun Hwi, Won, Moo-Ho, Kang, Il Jun, and Park, Joon Ha

Abstract

Porphyran, a sulfated polysaccharide found in various species of marine red algae, has been demonstrated to exhibit diverse bioactivities, including anti-inflammatory effects. However, the protective effects of porphyran against cerebral ischemia and reperfusion (IR) injury have not been investigated. The aim of this study was to examine the neuroprotective effects of porphyran against brain IR injury and its underlying mechanisms using a gerbil model of transient forebrain ischemia (IR in the forebrain), which results in pyramidal cell (principal neuron) loss in the cornu ammonis 1 (CA1) subregion of the hippocampus on day 4 after IR. Porphyran (25 and 50 mg/kg) was orally administered daily for one week prior to IR. Pretreatment with 50 mg/kg of porphyran, but not 25 mg/kg, significantly attenuated locomotor hyperactivity and protected pyramidal cells located in the CA1 area from IR injury. The pretreatment with 50 mg/kg of porphyran significantly suppressed the IR-induced activation and proliferation of microglia in the CA1 subregion. Additionally, the pretreatment significantly inhibited the overexpressions of nucleotide-binding domain, leucine-rich-containing family, pyrin domain-containing protein-3 (NLRP3) inflammasome complex, and pro-inflammatory cytokines (interleukin 1 beta and interleukin 18) induced by IR in the CA1 subregion. Overall, our findings suggest that porphyran exerts neuroprotective effects against brain IR injury, potentially by reducing the reaction (activation) and proliferation of microglia and reducing NLRP3 inflammasome-mediated neuroinflammation. [ABSTRACT FROM AUTHOR]

Published

2024

16. An astrocytic signaling loop for frequency-dependent control of dendritic integration and spatial learning

Author

Bohmbach, Kirsten, Masala, Nicola, Schönhense, Eva M, Hill, Katharina, Haubrich, André N, Zimmer, Andreas, Opitz, Thoralf, Beck, Heinz, and Henneberger, Christian

Subjects

Biomedical and Clinical Sciences, Neurosciences, Neurodegenerative, Brain Disorders, 1.1 Normal biological development and functioning, Underpinning research, Neurological, Animals, Mice, Rats, Astrocytes, Dendrites, Glutamic Acid, Pyramidal Cells, Receptors, N-Methyl-D-Aspartate, Serine, Spatial Learning, CA1 Region, Hippocampal

Abstract

Dendrites of hippocampal CA1 pyramidal cells amplify clustered glutamatergic input by activation of voltage-gated sodium channels and N-methyl-D-aspartate receptors (NMDARs). NMDAR activity depends on the presence of NMDAR co-agonists such as D-serine, but how co-agonists influence dendritic integration is not well understood. Using combinations of whole-cell patch clamp, iontophoretic glutamate application, two-photon excitation fluorescence microscopy and glutamate uncaging in acute rat and mouse brain slices we found that exogenous D-serine reduced the threshold of dendritic spikes and increased their amplitude. Triggering an astrocytic mechanism controlling endogenous D-serine supply via endocannabinoid receptors (CBRs) also increased dendritic spiking. Unexpectedly, this pathway was activated by pyramidal cell activity primarily in the theta range, which required HCN channels and astrocytic CB1Rs. Therefore, astrocytes close a positive and frequency-dependent feedback loop between pyramidal cell activity and their integration of dendritic input. Its disruption in mice led to an impairment of spatial memory, which demonstrated its behavioral relevance.

Published

2022

17. Cell-type-specific integration of feedforward and feedback synaptic inputs in the posterior parietal cortex

Author

Rindner, Daniel J, Proddutur, Archana, and Lur, Gyorgy

Subjects

Biomedical and Clinical Sciences, Neurosciences, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Feedback, Pyramidal Cells, Action Potentials, Synapses, Parietal Lobe, cell-type-specific, computational modeling, cortical layer 5, dual-color optogenetics, feedforward-feedback interaction, multimodal enhancement, posterior parietal cortex, synaptic integration, Psychology, Cognitive Sciences, Neurology & Neurosurgery, Biological psychology

Abstract

The integration of feedforward (sensory) and feedback (top-down) neuronal signals is a principal function of the neocortex. Yet, we have limited insight into how these information streams are combined by individual neurons. Using a two-color optogenetic strategy, we found that layer 5 pyramidal neurons in the posterior parietal cortex receive monosynaptic dual innervation, combining sensory inputs with top-down signals. Subclasses of layer 5 pyramidal neurons integrated these synapses with distinct temporal dynamics. Specifically, regular spiking cells exhibited supralinear enhancement of delayed-but not coincident-inputs, while intrinsic burst-firing neurons selectively boosted coincident synaptic events. These subthreshold integration characteristics translated to a nonlinear summation of action potential firing. Complementing electrophysiology with computational modeling, we found that distinct integration profiles arose from a cell-type-specific interaction of ionic mechanisms and feedforward inhibition. These data provide insight into the cellular properties that guide the nonlinear interaction of distinct long-range afferents in the neocortex.

Published

2022

18. Suppressed prefrontal neuronal firing variability and impaired social representation in IRSp53-mutant mice.

Author

Shin, Jae, Jeong, Yu, Kim, Kyungdeok, Bae, Jung, Noh, Young, Lee, Seungjoon, Choi, Woochul, Paik, Se-Bum, Jung, Min, Lee, Eunee, Kim, Eunjoon, and Kim, Woohyun

Subjects

BAIAP2, IRSp53, firing variability, medial prefrontal cortex, mouse, neuroscience, social behavior, social deficit, Animals, Mice, Neurons, Pyramidal Cells, Prefrontal Cortex, Receptors, N-Methyl-D-Aspartate, Schizophrenia

Abstract

Social deficit is a major feature of neuropsychiatric disorders, including autism spectrum disorders, schizophrenia, and attention-deficit/hyperactivity disorder, but its neural mechanisms remain unclear. Here, we examined neuronal discharge characteristics in the medial prefrontal cortex (mPFC) of IRSp53/Baiap2-mutant mice, which show social deficits, during social approach. We found a decrease in the proportion of IRSp53-mutant excitatory mPFC neurons encoding social information, but not that encoding non-social information. In addition, the firing activity of IRSp53-mutant neurons was less differential between social and non-social targets. IRSp53-mutant excitatory mPFC neurons displayed an increase in baseline neuronal firing, but decreases in the variability and dynamic range of firing as well as burst firing during social and non-social target approaches compared to wild-type controls. Treatment of memantine, an NMDA receptor antagonist that rescues social deficit in IRSp53-mutant mice, alleviates the reduced burst firing of IRSp53-mutant pyramidal mPFC neurons. These results suggest that suppressed neuronal activity dynamics and burst firing may underlie impaired cortical encoding of social information and social behaviors in IRSp53-mutant mice.

Published

2022

19. Oxytocin-Modulated Ion Channel Ensemble Controls Depolarization, Integration and Burst Firing in CA2 Pyramidal Neurons

Author

Liu, Jing-Jing, Eyring, Katherine W, König, Gabriele M, Kostenis, Evi, and Tsien, Richard W

Subjects

Biomedical and Clinical Sciences, Medical Physiology, Neurosciences, Mental Health, Aetiology, Underpinning research, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Mental health, Neurological, Male, Female, Mice, Animals, Oxytocin, Tetrodotoxin, Receptors, Oxytocin, Pyramidal Cells, Potassium Channels, Inwardly Rectifying, Potassium, CA2, hippocampus, ion channel, neuromodulator, oxytocin, sodium channel, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Oxytocin (OXT) and OXT receptor (OXTR)-mediated signaling control excitability, firing patterns, and plasticity of hippocampal CA2 pyramidal neurons, which are pivotal in generation of brain oscillations and social memory. Nonetheless, the ionic mechanisms underlying OXTR-induced effects in CA2 neurons are not fully understood. Using slice physiology in a reporter mouse line and interleaved current-clamp and voltage-clamp experiments, we systematically identified the ion channels modulated by OXT signaling in CA2 pyramidal cells (PYRs) in mice of both sexes and explored how changes in channel conductance support altered electrical activity. Activation of OXTRs inhibits an outward potassium current mediated by inward rectifier potassium channels (I Kir) and thus favoring membrane depolarization. Concomitantly, OXT signaling also diminishes inward current mediated by hyperpolarization-activated cyclic-nucleotide-gated (HCN) channels (I h), providing a hyperpolarizing drive. The combined reduction in both I Kir and I h synergistically elevate the membrane resistance and favor dendritic integration while the membrane potential is restrained from quickly depolarizing from rest. As a result, the responsiveness of CA2 PYRs to synaptic inputs is highly sharpened during OXTR activation. Unexpectedly, OXTR signaling also strongly enhances a tetrodotoxin-resistant (TTX-R), voltage-gated sodium current that helps drive the membrane potential to spike threshold and thus promote rhythmic firing. This novel array of OXTR-stimulated ionic mechanisms operates in close coordination and underpins OXT-induced burst firing, a key step in CA2 PYRs' contribution to hippocampal information processing and broader influence on brain circuitry. Our study deepens our understanding of underpinnings of OXT-promoted social memory and general neuropeptidergic control of cognitive states.SIGNIFICANCE STATEMENT Oxytocin (OXT) plays key roles in reproduction, parenting and social and emotional behavior, and deficiency in OXT receptor (OXTR) signaling may contribute to neuropsychiatric disorders. We identified a novel array of OXTR-modulated ion channels that operate in close coordination to retune hippocampal CA2 pyramidal neurons, enhancing responsiveness to synaptic inputs and sculpting output. OXTR signaling inhibits both potassium conductance (I Kir) and mixed cation conductance (I h), engaging opposing influences on membrane potential, stabilizing it while synergistically elevating membrane resistance and electrotonic spread. OXT signaling also facilitates a tetrodotoxin-resistant (TTX-R) Na+ current, not previously described in hippocampus (HP), engaged on further depolarization. This TTX-R current lowers the spike threshold and supports rhythmic depolarization and burst firing, a potent driver of downstream circuitry.

Published

2022

20. Selective Inhibitory Circuit Dysfunction after Chronic Frontal Lobe Contusion.

Author

Nolan, Amber L, Sohal, Vikaas S, and Rosi, Susanna

Subjects

Neurosciences, Mental Health, Acquired Cognitive Impairment, Physical Injury - Accidents and Adverse Effects, Basic Behavioral and Social Science, Brain Disorders, Behavioral and Social Science, Traumatic Head and Spine Injury, Traumatic Brain Injury (TBI), Aetiology, 2.1 Biological and endogenous factors, 1.1 Normal biological development and functioning, Underpinning research, Mental health, Neurological, Good Health and Well Being, Animals, Contusions, Female, Frontal Lobe, Interneurons, Male, Mice, Parvalbumins, Pyramidal Cells, Somatostatin, disinhibition, optogenetics, orbitofrontal cortex, selective vulnerability, somatostatin inhibitory neurons, traumatic brain injury, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Traumatic brain injury (TBI) is a leading cause of neurologic disability; the most common deficits affect prefrontal cortex-dependent functions such as attention, working memory, social behavior, and mental flexibility. Despite this prevalence, little is known about the pathophysiology that develops in frontal cortical microcircuits after TBI. We investigated whether alterations in subtype-specific inhibitory circuits are associated with cognitive inflexibility in a mouse model of frontal lobe contusion in both male and female mice that recapitulates aberrant mental flexibility as measured by deficits in rule reversal learning. Using patch-clamp recordings and optogenetic stimulation, we identified selective vulnerability in the non-fast-spiking and somatostatin-expressing (SOM+) subtypes of inhibitory neurons in layer V of the orbitofrontal cortex 2 months after injury. These subtypes exhibited reduced intrinsic excitability and a decrease in their synaptic output onto pyramidal neurons, respectively. By contrast, the fast-spiking and parvalbumin-expressing interneurons did not show changes in intrinsic excitability or synaptic output, respectively. Impairments in non-fast-spiking/SOM+ inhibitory circuit function were also associated with network hyperexcitability. These findings provide evidence for selective disruptions within specific inhibitory microcircuits that may guide the development of novel therapeutics for TBI.SIGNIFICANCE STATEMENT TBI frequently leads to chronic deficits in cognitive and behavioral functions that involve the prefrontal cortex, yet the maladaptive changes that occur in these cortical microcircuits are unknown. Our data indicate that alterations in subtype-specific inhibitory circuits, specifically vulnerability in the non-fast-spiking/somatostatin-expressing interneurons, occurs in the orbitofrontal cortex in the context of chronic deficits in reversal learning. These neurons exhibit reduced excitability and synaptic output, whereas the other prominent inhibitory population in layer V, the fast-spiking/parvalbumin-expressing interneurons as well as pyramidal neurons are not affected. Our work offers mechanistic insight into the subtype-specific function of neurons that may contribute to mental inflexibility after TBI.

Published

2022

21. Cell-type specific inhibitory plasticity in subicular pyramidal cells

Author

Alix Guinet, Sabine Grosser, Duru Özbay, Joachim Behr, and Imre Vida

Subjects

subiculum, pyramidal cells, GABAergic inhibition, synaptic plasticity, hippocampus, rat, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The balance between excitation and inhibition is essential to the proper function of cortical circuits. To maintain this balance during dynamic network activity, modulation of the strength of inhibitory synapses is a central requirement. In this study, we aimed to characterize perisomatic inhibition and its plasticity onto pyramidal cells (PCs) in the subiculum, the main output region of the hippocampus. We performed whole-cell patch-clamp recordings from the two main functional PC types, burst (BS) and regular spiking (RS) neurons in acute rat hippocampal slices and applied two different extracellular high-frequency stimulation paradigms: non-associative (presynaptic stimulation only) and associative stimulation (concurrent pre-and postsynaptic stimulation) to induce plasticity. Our results revealed cell type-specific differences in the expression of inhibitory plasticity depending on the induction paradigm: While associative stimulation caused robust inhibitory plasticity in both cell types, non-associative stimulation produced long-term potentiation in RS, but not in BS PCs. Analysis of paired-pulse ratio, variance of IPSPs, and postsynaptic Ca2+ buffering indicated a dominant postsynaptic calcium-dependent signaling and expression of inhibitory plasticity in both PC types. This divergence in inhibitory plasticity complements a stronger inhibition and a higher intrinsic excitability in RS as compared to BS neurons, suggesting differential involvement of the two PC types during network activation and information processing in the subiculum.

Published

2024

22. GABAergic CA1 neurons are more stable following context changes than glutamatergic cells.

Author

Schuette, Peter J, Ikebara, Juliane M, Maesta-Pereira, Sandra, Torossian, Anita, Sethi, Ekayana, Kihara, Alexandre H, Kao, Jonathan C, Reis, Fernando MCV, and Adhikari, Avishek

Subjects

Hippocampus, Pyramidal Cells, Interneurons, Animals, Mice, Female, Male, CA1 Region, Hippocampal, GABAergic Neurons, Neurosciences

Abstract

The CA1 region of the hippocampus contains both glutamatergic pyramidal cells and GABAergic interneurons. Numerous reports have characterized glutamatergic CAMK2A cell activity, showing how these cells respond to environmental changes such as local cue rotation and context re-sizing. Additionally, the long-term stability of spatial encoding and turnover of these cells across days is also well-characterized. In contrast, these classic hippocampal experiments have never been conducted with CA1 GABAergic cells. Here, we use chronic calcium imaging of male and female mice to compare the neural activity of VGAT and CAMK2A cells during exploration of unaltered environments and also during exposure to contexts before and after rotating and changing the length of the context across multiple recording days. Intriguingly, compared to CAMK2A cells, VGAT cells showed decreased remapping induced by environmental changes, such as context rotations and contextual length resizing. However, GABAergic neurons were also less likely than glutamatergic neurons to remain active and exhibit consistent place coding across recording days. Interestingly, despite showing significant spatial remapping across days, GABAergic cells had stable speed encoding between days. Thus, compared to glutamatergic cells, spatial encoding of GABAergic cells is more stable during within-session environmental perturbations, but is less stable across days. These insights may be crucial in accurately modeling the features and constraints of hippocampal dynamics in spatial coding.

Published

2022

23. Highly unstable heterogeneous representations in VIP interneurons of the anterior cingulate cortex.

Author

Johnson, Connor, Kretsge, Lisa, Yen, William, Sriram, Balaji, OConnor, Alexandra, Liu, Ruichen, Jimenez, Jessica, Phadke, Rhushikesh, Wingfield, Kelly, Yeung, Charlotte, Jinadasa, Tushare, Nguyen, Thanh, Cho, Eun, Fuchs, Erelle, Spevack, Eli, Velasco, Berta, Hausmann, Frances, Fournier, Luke, Brack, Alison, Melzer, Sarah, and Cruz-Martín, Alberto

Subjects

Animals, Gyrus Cinguli, Interneurons, Mice, Neurons, Pyramidal Cells, Vasoactive Intestinal Peptide

Abstract

A hallmark of the anterior cingulate cortex (ACC) is its functional heterogeneity. Functional and imaging studies revealed its importance in the encoding of anxiety-related and social stimuli, but it is unknown how microcircuits within the ACC encode these distinct stimuli. One type of inhibitory interneuron, which is positive for vasoactive intestinal peptide (VIP), is known to modulate the activity of pyramidal cells in local microcircuits, but it is unknown whether VIP cells in the ACC (VIPACC) are engaged by particular contexts or stimuli. Additionally, recent studies demonstrated that neuronal representations in other cortical areas can change over time at the level of the individual neuron. However, it is not known whether stimulus representations in the ACC remain stable over time. Using in vivo Ca2+ imaging and miniscopes in freely behaving mice to monitor neuronal activity with cellular resolution, we identified individual VIPACC that preferentially activated to distinct stimuli across diverse tasks. Importantly, although the population-level activity of the VIPACC remained stable across trials, the stimulus-selectivity of individual interneurons changed rapidly. These findings demonstrate marked functional heterogeneity and instability within interneuron populations in the ACC. This work contributes to our understanding of how the cortex encodes information across diverse contexts and provides insight into the complexity of neural processes involved in anxiety and social behavior.

Published

2022

24. Behavioral Timescale Cooperativity and Competitive Synaptic Interactions Regulate the Induction of Complex Spike Burst-Dependent Long-Term Potentiation.

Author

O'Dell, Thomas J

Subjects

Biomedical and Clinical Sciences, Neurosciences, Action Potentials, Animals, Hippocampus, Long-Term Potentiation, Male, Mice, Neuronal Plasticity, Pyramidal Cells, Synapses, complex spike burst, cooperativity, eligibility trace, LTP, synaptic competition, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Although Hebbian LTP has an important role in memory formation, the properties of Hebbian LTP cannot fully account for, and in some cases seem incompatible with, fundamental properties of associative learning. Importantly, findings from computational and neurophysiological studies suggest that burst-dependent forms of plasticity, where dendritic spikes and bursts of action potentials provide the postsynaptic depolarization needed for LTP induction, may overcome some of the limitations of conventional Hebbian LTP. Thus, I investigated how excitatory synapses onto CA1 pyramidal cells interact during the induction of complex spike (CS) burst-dependent LTP in hippocampal slices from male mice. Consistent with previous findings, theta-frequency trains of synaptic stimulation induce a Hebbian form of plasticity where postsynaptic CS bursts provide the depolarization needed for NMDAR activation and LTP induction. However, in contrast to conventional Hebbian plasticity, where cooperative LTP induction requires coactivation of synapses on a timescale of tens of milliseconds, cooperative interactions between synapses activated several seconds apart can induce CS burst-dependent LTP. A novel, retroactive form of heterosynaptic plasticity, where activation of one group of synapses triggers LTP induction at other synapses that were active seconds earlier, also contributes to cooperativity in CS burst-dependent LTP. Moreover, competitive synaptic interactions that emerge during prolonged bouts of postsynaptic CS bursting potently regulate CS burst-dependent LTP. Together, the unusual properties of synaptic cooperativity and competition in CS burst-dependent LTP enable Hebbian synapses to operate and interact on behavioral timescales.SIGNIFICANCE STATEMENT While EPSP-evoked complex spike (CS) bursting induces LTP at excitatory synapses onto hippocampal CA1 pyramidal cells, the properties of synaptic interactions during the induction of CS burst-dependent LTP have not been investigated. Here I report that interactions between independent synaptic inputs during the induction of CS burst-dependent LTP exhibit a number of novel, computationally relevant properties. Unlike conventional Hebbian LTP, the induction of CS burst-dependent LTP is regulated by proactive and retroactive cooperative interactions between synapses activated several seconds apart. Moreover, activity-dependent, competitive interactions between synapses allow strongly activated synapses to suppress LTP induction at more weakly activated synapses. Thus, CS burst-dependent LTP exhibits a number of the unique properties that overcome significant limitations of standard Hebbian plasticity rules.

Published

2022

25. Tuning instability of non-columnar neurons in the salt-and-pepper whisker map in somatosensory cortex

Author

Wang, Han Chin, LeMessurier, Amy M, and Feldman, Daniel E

Subjects

Biomedical and Clinical Sciences, Neurosciences, Physical Sciences, Neurological, Mice, Animals, Vibrissae, Somatosensory Cortex, Neurons, Pyramidal Cells, Wakefulness, Rodentia

Abstract

Rodent sensory cortex contains salt-and-pepper maps of sensory features, whose structure is not fully known. Here we investigated the structure of the salt-and-pepper whisker somatotopic map among L2/3 pyramidal neurons in somatosensory cortex, in awake mice performing one-vs-all whisker discrimination. Neurons tuned for columnar (CW) and non-columnar (non-CW) whiskers were spatially intermixed, with co-tuned neurons forming local (20 µm) clusters. Whisker tuning was markedly unstable in expert mice, with 35-46% of pyramidal cells significantly shifting tuning over 5-18 days. Tuning instability was highly concentrated in non-CW tuned neurons, and thus was structured in the map. Instability of non-CW neurons was unchanged during chronic whisker paralysis and when mice discriminated individual whiskers, suggesting it is an inherent feature. Thus, L2/3 combines two distinct components: a stable columnar framework of CW-tuned cells that may promote spatial perceptual stability, plus an intermixed, non-columnar surround with highly unstable tuning.

Published

2022

26. Long-term transverse imaging of the hippocampus with glass microperiscopes

Author

Redman, William T, Wolcott, Nora S, Montelisciani, Luca, Luna, Gabriel, Marks, Tyler D, Sit, Kevin K, Yu, Che-Hang, Smith, Spencer, and Goard, Michael J

Subjects

Biomedical and Clinical Sciences, Neurosciences, Mental Health, Biomedical Imaging, Neurological, Animals, Dendrites, Hippocampus, Mice, Neurons, Pyramidal Cells, hippocampus, two-photon imaging, place cell, Mouse, mouse, neuroscience, Biochemistry and Cell Biology, Biological sciences, Biomedical and clinical sciences, Health sciences

Abstract

The hippocampus consists of a stereotyped neuronal circuit repeated along the septal-temporal axis. This transverse circuit contains distinct subfields with stereotyped connectivity that support crucial cognitive processes, including episodic and spatial memory. However, comprehensive measurements across the transverse hippocampal circuit in vivo are intractable with existing techniques. Here, we developed an approach for two-photon imaging of the transverse hippocampal plane in awake mice via implanted glass microperiscopes, allowing optical access to the major hippocampal subfields and to the dendritic arbor of pyramidal neurons. Using this approach, we tracked dendritic morphological dynamics on CA1 apical dendrites and characterized spine turnover. We then used calcium imaging to quantify the prevalence of place and speed cells across subfields. Finally, we measured the anatomical distribution of spatial information, finding a non-uniform distribution of spatial selectivity along the DG-to-CA1 axis. This approach extends the existing toolbox for structural and functional measurements of hippocampal circuitry.

Published

2022

27. Simulation Investigations of Pyramidal Cells Layer Effect on Conscious Visual Perception

Author

Koprinkova-Hristova, Petia, Nedelcheva, Simona, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Georgiev, Ivan, editor, Datcheva, Maria, editor, Georgiev, Krassimir, editor, and Nikolov, Geno, editor

Published

2023

28. Induction of input-specific spine shrinkage on dendrites of rodent hippocampal CA1 neurons using two-photon glutamate uncaging

Author

Jang, Jinyoung, Anisimova, Margarita, Oh, Won Chan, and Zito, Karen

Subjects

Information and Computing Sciences, Biomedical and Clinical Sciences, Machine Learning, Neurosciences, Mental Health, Animals, CA1 Region, Hippocampal, Dendritic Spines, Female, Glutamic Acid, Male, Mice, Mice, Inbred C57BL, Photons, Pyramidal Cells, Rats, Rats, Sprague-Dawley, Cell Biology, Microscopy, Neuroscience

Abstract

Shrinkage and loss of dendritic spines are vital components of the neuronal plasticity that supports learning. To investigate the mechanisms of spine shrinkage and loss, Oh and colleagues established a two-photon glutamate uncaging protocol that reliably induces input-specific spine shrinkage on dendrites of rodent hippocampal CA1 pyramidal neurons. Here, we provide a detailed description of that protocol and also an optimized version that can be used to induce input- and synapse-specific shrinkage of dendritic spines at physiological Ca2+ levels. For complete details on the use and execution of this protocol, please refer to Oh et al. (2013), Stein et al. (2015), Stein et al. (2020), and Stein et al. (2021).

Published

2021

29. Hippocampal gamma and sharp-wave ripple oscillations are altered in a Cntnap2 mouse model of autism spectrum disorder

Author

Paterno, Rosalia, Marafiga, Joseane Righes, Ramsay, Harrison, Li, Tina, Salvati, Kathryn A, and Baraban, Scott C

Subjects

Mental Health, Brain Disorders, Neurosciences, Autism, Intellectual and Developmental Disabilities (IDD), Basic Behavioral and Social Science, Pediatric, Prevention, Behavioral and Social Science, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Aetiology, Underpinning research, Mental health, Neurological, Action Potentials, Animals, Autism Spectrum Disorder, Disease Models, Animal, Gamma Rhythm, Hippocampus, Interneurons, Male, Membrane Proteins, Mice, Mice, Inbred C57BL, Mice, Knockout, Mice, Transgenic, Nerve Tissue Proteins, Pyramidal Cells, Spatial Behavior, Synaptic Transmission, EEG, autism, biomarker, cntnap2, gamma, hippocampus, inhibition, interneurons, oscillations, sharp wave ripples, Biochemistry and Cell Biology, Medical Physiology

Abstract

Impaired synaptic neurotransmission may underly circuit alterations contributing to behavioral autism spectrum disorder (ASD) phenotypes. A critical component of impairments reported in somatosensory and prefrontal cortex of ASD mouse models are parvalbumin (PV)-expressing fast-spiking interneurons. However, it remains unknown whether PV interneurons mediating hippocampal networks crucial to navigation and memory processing are similarly impaired. Using PV-labeled transgenic mice, a battery of behavioral assays, in vitro patch-clamp electrophysiology, and in vivo 32-channel silicon probe local field potential recordings, we address this question in a Cntnap2-null mutant mouse model representing a human ASD risk factor gene. Cntnap2-/- mice show a reduction in hippocampal PV interneuron density, reduced inhibitory input to CA1 pyramidal cells, deficits in spatial discrimination ability, and frequency-dependent circuit changes within the hippocampus, including alterations in gamma oscillations, sharp-wave ripples, and theta-gamma modulation. Our findings highlight hippocampal involvement in ASD and implicate interneurons as a potential therapeutical target.

Published

2021

30. Tau reduction affects excitatory and inhibitory neurons differently, reduces excitation/inhibition ratios, and counteracts network hypersynchrony

Author

Chang, Che-Wei, Evans, Mark D, Yu, Xinxing, Yu, Gui-Qiu, and Mucke, Lennart

Subjects

Biological Sciences, Alzheimer's Disease, Dementia, Acquired Cognitive Impairment, Aging, Brain Disorders, Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD), Neurosciences, Neurodegenerative, Aetiology, Development of treatments and therapeutic interventions, 2.1 Biological and endogenous factors, 5.1 Pharmaceuticals, Neurological, Alzheimer Disease, Animals, Cells, Cultured, Epilepsy, Excitatory Postsynaptic Potentials, Female, Inhibitory Postsynaptic Potentials, Interneurons, Male, Mice, 129 Strain, Mice, Inbred C57BL, Mice, Knockout, Neural Inhibition, Neural Pathways, Neuronal Plasticity, Pyramidal Cells, Somatosensory Cortex, Time Factors, tau Proteins, Alzheimer’s disease, axon initial segment, epilepsy, excitation-inhibition balance, hypersynchrony, interneurons, intrinsic excitability, neuronal plasticity, pyramidal cells, tau, Biochemistry and Cell Biology, Medical Physiology, Biological sciences

Abstract

The protein tau has been implicated in many brain disorders. In animal models, tau reduction suppresses epileptogenesis of diverse causes and ameliorates synaptic and behavioral abnormalities in various conditions associated with excessive excitation-inhibition (E/I) ratios. However, the underlying mechanisms are unknown. Global genetic ablation of tau in mice reduces the action potential (AP) firing and E/I ratio of pyramidal cells in acute cortical slices without affecting the excitability of these cells. Tau ablation reduces the excitatory inputs to inhibitory neurons, increases the excitability of these cells, and structurally alters their axon initial segments (AISs). In primary neuronal cultures subjected to prolonged overstimulation, tau ablation diminishes the homeostatic response of AISs in inhibitory neurons, promotes inhibition, and suppresses hypersynchrony. Together, these differential alterations in excitatory and inhibitory neurons help explain how tau reduction prevents network hypersynchrony and counteracts brain disorders causing abnormally increased E/I ratios.

Published

2021

31. Postnatal Development of the Hippocampus in Male Albino Rats: A Histomorphometric Study.

Author

Ahmed Othman, Asmaa Ibrahim, Ali Baraka, Aya Abdrabo, Hafez, Kawther Ahmed, and Mostafa Sadek, Ashraf Mohamed

Subjects

*HIPPOCAMPUS development, *LIMBIC system, *ALBINISM, *ADULT development, *LEARNING, *PYRAMIDAL neurons

Abstract

Introduction: In recent years, deterioration in cognitive, learning, and memory become one of the significant problems in human life. Hippocampus is a pivotal part of the brain’s limbic system which serves a critical role in memory, learning process and regulating the emotions. In most regions of the brain, neurons are generated only at specific periods of early development, and not born in the adulthood. In contrast, hippocampal neurons are generated throughout development and adult life. Aim of the Study: Was to assess the postnatal development of the hippocampal formation. Material and Methods: Twenty-four male albino pups were divided into four groups. Ages day 1, week 1, week 2 and week3, all the pups were sacrificed; the brain were dissected and processed for histological and morphometric methods. Results: The general architecture of the hippocampus proper with its polymorphic, pyramidal, and molecular layers was present at day1, whereas the details of the adult structure appeared at week 2. There was a statistically significant increase in the thickness of the PL of the CA1 in group II compared to group I. There was a statistically non-significant increase in the number of pyramidal cells of CA1 in group II compared to group I, while in group IV there was a statistically non-significant decrease in number of cells compared to group III. Conclusion: The important sequences of events in the growth and maturation of the hippocampal formation in male albino rat occurred in the first 2 postnatal weeks. In addition, the period of weaning in group IV(week3) and mother separation could affect negatively the maturity of the hippocampus at this period in a form of increase apoptosis of pyramidal cells. [ABSTRACT FROM AUTHOR]

Published

2023

32. The Impact of SST and PV Interneurons on Nonlinear Synaptic Integration in the Neocortex.

Author

Dorsett, Christopher, Philpot, Benjamin D, Smith, Spencer LaVere, and Smith, Ikuko T

Subjects

Pyramidal Cells, Neocortex, Interneurons, Animals, Mice, Somatostatin, Parvalbumins, dendrites, inhibition, interneurons, nonlinearity, synaptic integration, Neurosciences, Neurological

Abstract

Excitatory synaptic inputs arriving at the dendrites of a neuron can engage active mechanisms that nonlinearly amplify the depolarizing currents. This supralinear synaptic integration is subject to modulation by inhibition. However, the specific rules by which different subtypes of interneurons affect the modulation have remained largely elusive. To examine how inhibition influences active synaptic integration, we optogenetically manipulated the activity of the following two subtypes of interneurons: dendrite-targeting somatostatin-expressing (SST) interneurons; and perisomatic-targeting parvalbumin-expressing (PV) interneurons. In acute slices of mouse primary visual cortex, electrical stimulation evoked nonlinear synaptic integration that depended on NMDA receptors. Optogenetic activation of SST interneurons in conjunction with electrical stimulation resulted in predominantly divisive inhibitory gain control, reducing the magnitude of the supralinear response without affecting its threshold. PV interneuron activation, on the other hand, had a minimal effect on the supralinear response. Together, these results delineate the roles for SST and PV neurons in active synaptic integration. Differential effects of inhibition by SST and PV interneurons likely increase the computational capacity of the pyramidal neurons in modulating the nonlinear integration of synaptic output.

Published

2021

33. Differential Excitability of PV and SST Neurons Results in Distinct Functional Roles in Inhibition Stabilization of Up States.

Author

Romero-Sosa, Juan L, Motanis, Helen, and Buonomano, Dean V

Subjects

Biomedical and Clinical Sciences, Neurosciences, Brain Disorders, Mental Health, Neurological, Action Potentials, Animals, Computer Simulation, Feedback, Physiological, Mice, Models, Neurological, Neurons, Optogenetics, Parvalbumins, Pyramidal Cells, Somatostatin, Transfection, inhibition, neural dynamics, neural network model, PV, SST, Up states, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Up states are the best studied example of an emergent neural dynamic regime. Computational models based on a single class of inhibitory neurons indicate that Up states reflect bistable dynamic systems in which positive feedback is stabilized by strong inhibition and predict a paradoxical effect in which increased drive to inhibitory neurons results in decreased inhibitory activity. To date, however, computational models have not incorporated empirically defined properties of parvalbumin (PV) and somatostatin (SST) neurons. Here we first experimentally characterized the frequency-current (F-I) curves of pyramidal (Pyr), PV, and SST neurons from mice of either sex, and confirmed a sharp difference between the threshold and slopes of PV and SST neurons. The empirically defined F-I curves were incorporated into a three-population computational model that simulated the empirically derived firing rates of pyramidal, PV, and SST neurons. Simulations revealed that the intrinsic properties were sufficient to predict that PV neurons are primarily responsible for generating the nontrivial fixed points representing Up states. Simulations and analytical methods demonstrated that while the paradoxical effect is not obligatory in a model with two classes of inhibitory neurons, it is present in most regimes. Finally, experimental tests validated predictions of the model that the Pyr ↔ PV inhibitory loop is stronger than the Pyr ↔ SST loop.SIGNIFICANCE STATEMENT Many cortical computations, such as working memory, rely on the local recurrent excitatory connections that define cortical circuit motifs. Up states are among the best studied examples of neural dynamic regimes that rely on recurrent excitatory excitation. However, this positive feedback must be held in check by inhibition. To address the relative contribution of PV and SST neurons, we characterized the intrinsic input-output differences between these classes of inhibitory neurons and, using experimental and theoretical methods, show that the higher threshold and gain of PV leads to a dominant role in network stabilization.

Published

2021

34. Molecular and functional properties of cortical astrocytes during peripherally induced neuroinflammation

Author

Diaz-Castro, Blanca, Bernstein, Alexander M, Coppola, Giovanni, Sofroniew, Michael V, and Khakh, Baljit S

Subjects

Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD), Brain Disorders, Genetics, Behavioral and Social Science, Acquired Cognitive Impairment, Aging, Neurosciences, Dementia, Neurological, Alzheimer Disease, Anhedonia, Animals, Astrocytes, Cell Communication, Cerebral Cortex, Inflammation, Lipopolysaccharides, Mice, Inbred C57BL, Neurons, Phenotype, Pyramidal Cells, Transcription, Genetic, LPS, RNA-seq, anhedonia, astrocyte, astrocyte reactivity, brain endothelial cell, cell communication, microglia, neuroinflammation, neuron, prefrontal cortex, Biochemistry and Cell Biology, Medical Physiology

Abstract

Astrocytic contributions to neuroinflammation are widely implicated in disease, but they remain incompletely explored. We assess medial prefrontal cortex (PFC) and visual cortex (VCX) astrocyte and whole-tissue gene expression changes in mice following peripherally induced neuroinflammation triggered by a systemic bacterial endotoxin, lipopolysaccharide, which produces sickness-related behaviors, including anhedonia. Neuroinflammation-mediated behavioral changes and astrocyte-specific gene expression alterations peak when anhedonia is greatest and then reverse to normal. Notably, region-specific molecular identities of PFC and VCX astrocytes are largely maintained during reactivity changes. Gene pathway analyses reveal alterations of diverse cell signaling pathways, including changes in cell-cell interactions of multiple cell types that may underlie the central effects of neuroinflammation. Certain astrocyte molecular signatures accompanying neuroinflammation are shared with changes reported in Alzheimer's disease and mouse models. However, we find no evidence of altered neuronal survival or function in the PFC even when neuroinflammation-induced astrocyte reactivity and behavioral changes are significant.

Published

2021

35. Paradoxical hyperexcitability from NaV1.2 sodium channel loss in neocortical pyramidal cells

Author

Spratt, Perry WE, Alexander, Ryan PD, Ben-Shalom, Roy, Sahagun, Atehsa, Kyoung, Henry, Keeshen, Caroline M, Sanders, Stephan J, and Bender, Kevin J

Subjects

Neurodegenerative, Brain Disorders, Epilepsy, Neurosciences, Intellectual and Developmental Disabilities (IDD), Aetiology, 2.1 Biological and endogenous factors, Neurological, Action Potentials, Animals, Dendrites, Gene Deletion, Mice, Inbred C57BL, Mice, Knockout, NAV1.2 Voltage-Gated Sodium Channel, Neocortex, Pyramidal Cells, NaV1.2, SCN2A, autism, autism spectrum disorder, dendrite, dynamic clamp, epilepsy, prefrontal cortex, pyramidal cell, Biochemistry and Cell Biology, Medical Physiology

Abstract

Loss-of-function variants in the gene SCN2A, which encodes the sodium channel NaV1.2, are strongly associated with autism spectrum disorder and intellectual disability. An estimated 20%-30% of children with these variants also suffer from epilepsy, with altered neuronal activity originating in neocortex, a region where NaV1.2 channels are expressed predominantly in excitatory pyramidal cells. This is paradoxical, as sodium channel loss in excitatory cells would be expected to dampen neocortical activity rather than promote seizure. Here, we examined pyramidal neurons lacking NaV1.2 channels and found that they were intrinsically hyperexcitable, firing high-frequency bursts of action potentials (APs) despite decrements in AP size and speed. Compartmental modeling and dynamic-clamp recordings revealed that NaV1.2 loss prevented potassium channels from properly repolarizing neurons between APs, increasing overall excitability by allowing neurons to reach threshold for subsequent APs more rapidly. This cell-intrinsic mechanism may, therefore, account for why SCN2A loss-of-function can paradoxically promote seizure.

Published

2021

36. Adult glut3 homozygous null mice survive to demonstrate neural excitability and altered neurobehavioral responses reminiscent of neurodevelopmental disorders

Author

Shin, Bo-Chul, Cepeda, Carlos, Eghbali, Mason, Byun, Shin Yun, Levine, Michael S, and Devaskar, Sherin U

Subjects

Biomedical and Clinical Sciences, Biological Psychology, Neurosciences, Psychology, Pharmacology and Pharmaceutical Sciences, Behavioral and Social Science, Basic Behavioral and Social Science, Mental Health, Brain Disorders, Genetics, Mental health, Neurological, Animals, Behavior, Animal, Brain, Disease Models, Animal, Female, Glucose Transporter Type 3, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Neurodevelopmental Disorders, Pyramidal Cells, Glutamate-excitatory neurons, Neurodevelopmental disorders, Loss-of-function polymorphisms, Seizure activity, Clinical Sciences, Neurology & Neurosurgery, Biological psychology

Abstract

Since GLUT3 is vital for fueling neurotransmission, we examined in-vivo the adult phenotype carrying the conditional homozygous glut3 gene mutation (KO) in glutamate-excitatory neurons. These KO mice demonstrated sex-specific differences in brain and body weights (p = 0.0001 and p = 0.01 each) with reduced GLUT3 protein in cerebral cortices and brain stem (p = 0.005). In patch clamp studies the glut3 KO mice displayed a shorter latency to and enhanced paroxysmal activity (p = 0.01 and p = 0.015 each) in pyramidal neurons upon application of a GABAA antagonist, supporting hyperexcitability. Further, associated changes in neurobehavior consisted of reduced latency to fall in the rotorod motor test related to incoordination, increased distance traveled in total and periphery versus center in open field testing suggesting hyperactivity with anxiety (p = 0.0013 in male, p = 0.045 in female), reduced time freezing reminiscent of disrupted contextual fear conditioning (p = 0.0033), decreased time in target quadrant seen with spatial cognitive memory water maze testing (p = 0.034), and enhanced sociability particularly for novelty reflecting a lack of inhibition/impulsivity (p = 0.038). Some of these features were equally pronounced in males and females (cognitive) while others were seen in females (anxiety and impulsivity). We conclude that GLUT3 in adult glutamate-excitatory neurons is essential for maintaining neurotransmitory equipoise regulating excitation with maintenance of motor coordination and activity, cognition, spatial memory and normal fear for both contextual events and novelty with tempered sociability. While sex-specificity was forthcoming for some of these behaviors, our findings collectively suggest that loss-of-function glut3 gene mutations or polymorphisms may underlie an endophenotype of attention deficit-hyperactivity disorder.

Published

2021

37. Neuroprotective effect of water lily (Nymphaea pubescens Willd) seed ethanolic extract against trimethyltin-induced cognitive impairment and neurodegeneration in mice

Author

Dinda Fadhilah Belahusna, Putra Santoso, and Resti Rahayu

Subjects

catalase activity, malondialdehyde, neuroprotective effect, neurodegenerative drugs, pyramidal cells, cerebral cortex, Medicine (General), R5-920, Therapeutics. Pharmacology, RM1-950

Abstract

Introduction: Cognitive impairments are profound outcomes of neurodegenerative disease, a global health issue. Water lily (Nymphaea pubescens, Nymphaeaceae) extracts have been reported to counteract oxidative stress. However, their protective effects against neurodegenerative disease remain to be fully investigated. The current study aimed to determine the neuroprotective effect of water lily seed ethanolic extract on trimethyltin (TMT)-induced cognitive impairment and neurodegeneration in a mouse model. Methods: A single dose of TMT (0.6 mg/kg BW) was intraperitoneally injected to young adult male mice followed by daily oral treatments with different doses of water lily seed extract (0, 100, 200, and 400 mg/kg BW) for 28 days. Thereafter, cognitive behaviors were assessed, malondialdehyde (MDA) levels and catalase (CAT) activities were determined, followed by histopathological examination of the brain. Results: The results revealed that, compared to the non-treated group, the water lily extract at doses of 100–400 mg/kg BW was effective in counteracting the decline in memory and spatial cognition of TMT-induced impairment (P

Published

2023

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

Author

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

Subjects

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

Abstract

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

Published

2021

39. Iron Deficiency and Iron Excess Differently Affect Dendritic Architecture of Pyramidal Neurons in the Hippocampus of Piglets.

Author

Perng, Vivian, Li, Chong, Klocke, Carolyn R, Navazesh, Shya E, Pinneles, Danna K, Lein, Pamela J, and Ji, Peng

Subjects

Intestinal Mucosa, Duodenum, Hippocampus, Pyramidal Cells, Dendrites, Animals, Swine, Anemia, Iron-Deficiency, Iron, Dietary, Gene Expression Regulation, Dose-Response Relationship, Drug, Female, Male, dendritic arborization, hippocampal iron, iron deficiency, iron overload, piglet model, Digestive Diseases, Pediatric, Nutrition, Genetics, Hematology, Neurosciences, Animal Production, Food Sciences, Nutrition and Dietetics, Nutrition & Dietetics

Abstract

BackgroundBoth iron deficiency and overload may adversely affect neurodevelopment.ObjectivesThe study assessed how changes in early-life iron status affect iron homeostasis and cytoarchitecture of hippocampal neurons in a piglet model.MethodsOn postnatal day (PD) 1, 30 Hampshire × Yorkshire crossbreed piglets (n = 15/sex) were stratified by sex and litter and randomly assigned to experimental groups receiving low (L-Fe), adequate (A-Fe), or high (H-Fe) levels of iron supplement during the pre- (PD1-21) and postweaning periods (PD22-35). Pigs in the L-Fe, A-Fe, and H-Fe groups orally received 0, 1, and 30 mg Fe · kg weight-1 · d-1 preweaning and were fed a diet containing 30, 125, and 1000 mg Fe/kg postweaning, respectively. Heme indexes were analyzed weekly, and gene and protein expressions of iron regulatory proteins in duodenal mucosa, liver, and hippocampus were analyzed through qRT-PCR and western blot, respectively, on PD35. Hippocampal neurons stained using the Golgi-Cox method were traced and their dendritic arbors reconstructed in 3-D using Neurolucida. Dendritic complexity was quantified using Sholl and branch order analyses.ResultsPigs in the L-Fe group developed iron deficiency anemia (hemoglobin = 8.2 g/dL, hematocrit = 20.1%) on PD35 and became stunted during week 5 with lower final body weight than H-Fe group pigs (6.6 compared with 9.6 kg, P

Published

2021

40. Porphyran Attenuates Neuronal Loss in the Hippocampal CA1 Subregion Induced by Ischemia and Reperfusion in Gerbils by Inhibiting NLRP3 Inflammasome-Mediated Neuroinflammation

Author

Dae Won Kim, Tae-Kyeong Lee, Ji Hyeon Ahn, Se-Ran Yang, Myoung Cheol Shin, Jun Hwi Cho, Moo-Ho Won, Il Jun Kang, and Joon Ha Park

Subjects

hippocampus, microglia, NLRP3 inflammasome complex, pro-inflammatory cytokines, pyramidal cells, sulfated polysaccharide, Biology (General), QH301-705.5

Abstract

Porphyran, a sulfated polysaccharide found in various species of marine red algae, has been demonstrated to exhibit diverse bioactivities, including anti-inflammatory effects. However, the protective effects of porphyran against cerebral ischemia and reperfusion (IR) injury have not been investigated. The aim of this study was to examine the neuroprotective effects of porphyran against brain IR injury and its underlying mechanisms using a gerbil model of transient forebrain ischemia (IR in the forebrain), which results in pyramidal cell (principal neuron) loss in the cornu ammonis 1 (CA1) subregion of the hippocampus on day 4 after IR. Porphyran (25 and 50 mg/kg) was orally administered daily for one week prior to IR. Pretreatment with 50 mg/kg of porphyran, but not 25 mg/kg, significantly attenuated locomotor hyperactivity and protected pyramidal cells located in the CA1 area from IR injury. The pretreatment with 50 mg/kg of porphyran significantly suppressed the IR-induced activation and proliferation of microglia in the CA1 subregion. Additionally, the pretreatment significantly inhibited the overexpressions of nucleotide-binding domain, leucine-rich-containing family, pyrin domain-containing protein-3 (NLRP3) inflammasome complex, and pro-inflammatory cytokines (interleukin 1 beta and interleukin 18) induced by IR in the CA1 subregion. Overall, our findings suggest that porphyran exerts neuroprotective effects against brain IR injury, potentially by reducing the reaction (activation) and proliferation of microglia and reducing NLRP3 inflammasome-mediated neuroinflammation.

Published

2024

41. Interrogating the Etiology of Sporadic Alzheimer's Disease Using Aging Rhesus Macaques: Cellular, Molecular, and Cortical Circuitry Perspectives.

Author

Datta, Dibyadeep

Subjects

*NEURAL circuitry, *RHESUS monkeys, *ALZHEIMER'S disease, *AMYLOID plaque, *GENETIC regulation, *RYANODINE receptors, *CALCIUM channels

Abstract

Aging is the most significant risk factor for neurodegenerative disorders such as Alzheimer's disease (AD) associated with profound socioeconomic and personal costs. Consequently, there is an urgent need for animal models that recapitulate the age-related spatial and temporal complexity and patterns of pathology identical to human AD. Our research in aging nonhuman primate models involving rhesus macaques has revealed naturally occurring amyloid and tau pathology, including the formation of amyloid plaques and neurofibrillary tangles comprising hyperphosphorylated tau. Moreover, rhesus macaques exhibit synaptic dysfunction in association cortices and cognitive impairments with advancing age, and thus can be used to interrogate the etiological mechanisms that generate neuropathological cascades in sporadic AD. Particularly, unique molecular mechanisms (eg, feedforward cyclic adenosine 3ʹ,5ʹ-monophosphate [cAMP]-Protein kinase A (PKA)-calcium signaling) in the newly evolved primate dorsolateral prefrontal cortex are critical for persistent firing required for subserving higher-order cognition. For example, dendritic spines in primate dorsolateral prefrontal cortex contain a specialized repertoire of proteins to magnify feedforward cAMP-PKA-calcium signaling such as N -methyl- d -aspartic acid receptors and calcium channels on the smooth endoplasmic reticulum (eg, ryanodine receptors). This process is constrained by phosphodiesterases (eg, PDE4) that hydrolyze cAMP and calcium-buffering proteins (eg, calbindin) in the cytosol. However, genetic predispositions and age-related insults exacerbate feedforward cAMP-Protein kinase A-calcium signaling pathways that induce a myriad of downstream effects, including the opening of K+ channels to weaken network connectivity, calcium-mediated dysregulation of mitochondria, and activation of inflammatory cascades to eliminate synapses, thereby increasing susceptibility to atrophy. Therefore, aging rhesus macaques provide an invaluable model to explore novel therapeutic strategies in sporadic AD. [ABSTRACT FROM AUTHOR]

Published

2023

42. Proanthocyanidins induce analgesic and anxiolytic effects in spared nerve injured mice by decreasing in vivo firing rate of pyramidal cells in the insular cortex.

Author

Pan Wang, Hua-Xing Si, Da-Yu Zhu, Ke-Ke Xing, Jian Wang, Ting-Ting Cao, Han Zhao, Xiao-Die Liu, Ming-Ming Zhang, and Tao Chen

Subjects

PYRAMIDAL neurons, INSULAR cortex, PROANTHOCYANIDINS, CENTRAL nervous system, NERVES, PAIN

Abstract

Neuropathic pain is one of the most common symptoms of clinical pain that often accompanied by severe emotional changes such as anxiety. However, the treatment for comorbidity of chronic pain and anxiety is limited. Proanthocyanidins (PACs), a group of polyphenols enriched in plants and foods, have been reported to cause pain-alleviating effects. However, whether and how PACs induce analgesic and anxiolytic effects in the central nervous system remain obscure. In the present study, we observed that microinjection of PACs into the insular cortex (IC) inhibited mechanical and spontaneous pain sensitivity and anxiety-like behaviors in mice with spared nerve injury. Meanwhile, PACs application exclusively reduced the FOS expression in the pyramidal cells but not interneurons in the IC. In vivo electrophysiological recording of the IC further showed that PACS application inhibited the firing rate of spikes of pyramidal cells of IC in neuropathic pain mice. In summary, PACs induce analgesic and anxiolytic effects by inhibiting the spiking of pyramidal cells of the IC in mice with neuropathic pain, which should provide new evidence of PACs as the potential clinical treatment of chronic pain and anxiety comorbidity. [ABSTRACT FROM AUTHOR]

Published

2023

43. Postsynaptic Serine Racemase Regulates NMDA Receptor Function

Author

Wong, Jonathan M, Folorunso, Oluwarotimi O, Barragan, Eden V, Berciu, Cristina, Harvey, Theresa L, Coyle, Joseph T, Balu, Darrick T, and Gray, John A

Subjects

Biomedical and Clinical Sciences, Neurosciences, Neurological, Age Factors, Animals, CA1 Region, Hippocampal, Dendrites, Female, Male, Mice, Mice, Knockout, Neuronal Plasticity, Pyramidal Cells, Racemases and Epimerases, Receptors, N-Methyl-D-Aspartate, Synapses, Synaptic Transmission, GluN2A, glycine, NR2A, NR2B, plasticity, Srr, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

d-serine is the primary NMDAR coagonist at mature forebrain synapses and is synthesized by the enzyme serine racemase (SR). However, our understanding of the mechanisms regulating the availability of synaptic d-serine remains limited. Though early studies suggested d-serine is synthesized and released from astrocytes, more recent studies have demonstrated a predominantly neuronal localization of SR. More specifically, recent work intriguingly suggests that SR may be found at the postsynaptic density, yet the functional implications of postsynaptic SR on synaptic transmission are not yet known. Here, we show an age-dependent dendritic and postsynaptic localization of SR and d-serine by immunohistochemistry and electron microscopy in mouse CA1 pyramidal neurons. In addition, using a single-neuron genetic approach in SR conditional KO mice from both sexes, we demonstrate a cell-autonomous role for SR in regulating synaptic NMDAR function at Schaffer collateral (CA3)-CA1 synapses. Importantly, single-neuron genetic deletion of SR resulted in the elimination of LTP at 1 month of age, which could be rescued by exogenous d-serine. Interestingly, there was a restoration of LTP by 2 months of age that was associated with an upregulation of synaptic GluN2B. Our findings support a cell-autonomous role for postsynaptic neuronal SR in regulating synaptic NMDAR function and suggests a possible autocrine mode of d-serine action.SIGNIFICANCE STATEMENT NMDARs are key regulators of neurodevelopment and synaptic plasticity and are unique in their requirement for binding of a coagonist, which is d-serine at most forebrain synapses. However, our understanding of the mechanisms regulating synaptic d-serine availability remains limited. d-serine is synthesized in the brain by the neuronal enzyme serine racemase (SR). Here, we show dendritic and postsynaptic localization of SR and d-serine in CA1 pyramidal neurons. In addition, using single-neuron genetic deletion of SR, we establish a role of postsynaptic SR in regulating NMDAR function. These results support an autocrine mode of d-serine action at synapses.

Published

2020

44. Differential Short-Term Plasticity of PV and SST Neurons Accounts for Adaptation and Facilitation of Cortical Neurons to Auditory Tones

Author

Seay, Michael J, Natan, Ryan G, Geffen, Maria N, and Buonomano, Dean V

Subjects

Biomedical and Clinical Sciences, Neurosciences, Clinical Sciences, Basic Behavioral and Social Science, Behavioral and Social Science, Brain Disorders, 1.1 Normal biological development and functioning, Underpinning research, Neurological, Acoustic Stimulation, Algorithms, Animals, Auditory Cortex, Computer Simulation, Male, Mice, Neuronal Plasticity, Neurons, Optogenetics, Parvalbumins, Pyramidal Cells, Somatostatin, adaptation, auditory cortex, parvalbumin, short-term synaptic plasticity, somatostatin, temporal, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Cortical responses to sensory stimuli are strongly modulated by temporal context. One of the best studied examples of such modulation is sensory adaptation. We first show that in response to repeated tones pyramidal (Pyr) neurons in male mouse auditory cortex (A1) exhibit facilitating and stable responses, in addition to adapting responses. To examine the potential mechanisms underlying these distinct temporal profiles, we developed a reduced spiking model of sensory cortical circuits that incorporated the signature short-term synaptic plasticity (STP) profiles of the inhibitory parvalbumin (PV) and somatostatin (SST) interneurons. The model accounted for all three temporal response profiles as the result of dynamic changes in excitatory/inhibitory balance produced by STP, primarily through shifts in the relative latency of Pyr and inhibitory neurons. Transition between the three response profiles was possible by changing the strength of the inhibitory PV→Pyr and SST→Pyr synapses. The model predicted that a unit's latency would be related to its temporal profile. Consistent with this prediction, the latency of stable units was significantly shorter than that of adapting and facilitating units. Furthermore, because of the history-dependence of STP the model generated a paradoxical prediction: that inactivation of inhibitory neurons during one tone would decrease the response of A1 neurons to a subsequent tone. Indeed, we observed that optogenetic inactivation of PV neurons during one tone counterintuitively decreased the spiking of Pyr neurons to a subsequent tone 400 ms later. These results provide evidence that STP is critical to temporal context-dependent responses in the sensory cortex.SIGNIFICANCE STATEMENT Our perception of speech and music depends strongly on temporal context, i.e., the significance of a stimulus depends on the preceding stimuli. Complementary neural mechanisms are needed to sometimes ignore repetitive stimuli (e.g., the tic of a clock) or detect meaningful repetition (e.g., consecutive tones in Morse code). We modeled a neural circuit that accounts for diverse experimentally-observed response profiles in auditory cortex (A1) neurons, based on known forms of short-term synaptic plasticity (STP). Whether the simulated circuit reduced, maintained, or enhanced its response to repeated tones depended on the relative dominance of two different types of inhibitory cells. The model made novel predictions that were experimentally validated. Results define an important role for STP in temporal context-dependent perception.

Published

2020

45. Amnesia for context fear is caused by widespread disruption of hippocampal activity

Author

Krueger, Jamie N, Wilmot, Jacob H, Teratani-Ota, Yusuke, Puhger, Kyle R, Nemes, Sonya E, Crestani, Ana P, Lafreniere, Marrisa M, and Wiltgen, Brian J

Subjects

Biological Psychology, Psychology, Neurosciences, Basic Behavioral and Social Science, Behavioral and Social Science, Mental Health, 1.1 Normal biological development and functioning, 1.2 Psychological and socioeconomic processes, 2.1 Biological and endogenous factors, Neurological, Mental health, Amnesia, Animals, Conditioning, Psychological, Designer Drugs, Fear, GABAergic Neurons, Hippocampus, Memory, Episodic, Mental Recall, Mice, Optogenetics, Pyramidal Cells, Receptors, Drug, Context fear, Retrieval, Memory, Chemogenetics, Medical and Health Sciences, Psychology and Cognitive Sciences, Behavioral Science & Comparative Psychology, Biological psychology, Cognitive and computational psychology

Abstract

The hippocampus plays an essential role in the formation and retrieval of episodic memories in humans and contextual memories in animals. However, amnesia is not always observed when this structure is compromised. To determine why this is the case, we compared the effects of several different circuit manipulations on memory retrieval and hippocampal activity. Mice were first trained on context fear conditioning and then optogenetic and chemogenetic tools were used to alter activity during memory retrieval. We found that retrieval was only impaired when manipulations caused widespread changes (increases or decreases) in hippocampal activity. Widespread increases occurred when pyramidal cells were excited and widespread decreases were found when GABAergic neurons were stimulated. Direct hyperpolarization of excitatory neurons only moderately reduced activity and did not produce amnesia. Surprisingly, widespread decreases in hippocampal activity did not prevent retrieval if they occurred gradually prior to testing. This suggests that intact brain regions can express contextual memories if they are given adequate time to compensate for the loss of the hippocampus.

Published

2020

46. CRL5-dependent regulation of the small GTPases ARL4C and ARF6 controls hippocampal morphogenesis

Author

Han, Jisoo S, Hino, Keiko, Li, Wenzhe, Reyes, Raenier V, Canales, Cesar P, Miltner, Adam M, Haddadi, Yasmin, Sun, Junqing, Chen, Chao-Yin, La Torre, Anna, and Simó, Sergi

Subjects

Biochemistry and Cell Biology, Biomedical and Clinical Sciences, Biological Sciences, Mental Health, Neurosciences, ADP-Ribosylation Factor 6, ADP-Ribosylation Factors, Animals, Cell Membrane, Cell Movement, Cullin Proteins, Dendrites, Guanine Nucleotide Exchange Factors, Hippocampus, Mice, Monomeric GTP-Binding Proteins, Morphogenesis, Neurogenesis, Pyramidal Cells, Signal Transduction, Ubiquitin-Protein Ligases, hippocampal development, CRL5, ARL4C, ARF6, pyramidal neuron migration

Abstract

The small GTPase ARL4C participates in the regulation of cell migration, cytoskeletal rearrangements, and vesicular trafficking in epithelial cells. The ARL4C signaling cascade starts by the recruitment of the ARF-GEF cytohesins to the plasma membrane, which, in turn, bind and activate the small GTPase ARF6. However, the role of ARL4C-cytohesin-ARF6 signaling during hippocampal development remains elusive. Here, we report that the E3 ubiquitin ligase Cullin 5/RBX2 (CRL5) controls the stability of ARL4C and its signaling effectors to regulate hippocampal morphogenesis. Both RBX2 knockout and Cullin 5 knockdown cause hippocampal pyramidal neuron mislocalization and development of multiple apical dendrites. We used quantitative mass spectrometry to show that ARL4C, Cytohesin-1/3, and ARF6 accumulate in the RBX2 mutant telencephalon. Furthermore, we show that depletion of ARL4C rescues the phenotypes caused by Cullin 5 knockdown, whereas depletion of CYTH1 or ARF6 exacerbates overmigration. Finally, we show that ARL4C, CYTH1, and ARF6 are necessary for the dendritic outgrowth of pyramidal neurons to the superficial strata of the hippocampus. Overall, we identified CRL5 as a key regulator of hippocampal development and uncovered ARL4C, CYTH1, and ARF6 as CRL5-regulated signaling effectors that control pyramidal neuron migration and dendritogenesis.

Published

2020

47. Astrocytic Ephrin-B1 Controls Excitatory-Inhibitory Balance in Developing Hippocampus

Author

Nguyen, Amanda Q, Sutley, Samantha, Koeppen, Jordan, Mina, Karen, Woodruff, Simone, Hanna, Sandy, Vengala, Alekya, Hickmott, Peter W, Obenaus, Andre, and Ethell, Iryna M

Subjects

Intellectual and Developmental Disabilities (IDD), Neurosciences, Pediatric, Brain Disorders, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Animals, Astrocytes, Disks Large Homolog 4 Protein, Ephrin-B1, Excitatory Postsynaptic Potentials, Hippocampus, Inhibitory Postsynaptic Potentials, Male, Membrane Proteins, Mice, Mice, Inbred C57BL, Pyramidal Cells, Social Behavior, Vesicular Glutamate Transport Protein 1, Vesicular Inhibitory Amino Acid Transport Proteins, astrocyte, development, ephrin, excitatory-inhibitory balance, hippocampus, synapse, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Astrocytes are implicated in synapse formation and elimination, which are associated with developmental refinements of neuronal circuits. Astrocyte dysfunctions are also linked to synapse pathologies associated with neurodevelopmental disorders and neurodegenerative diseases. Although several astrocyte-derived secreted factors are implicated in synaptogenesis, the role of contact-mediated glial-neuronal interactions in synapse formation and elimination during development is still unknown. In this study, we examined whether the loss or overexpression of the membrane-bound ephrin-B1 in astrocytes during postnatal day (P) 14-28 period would affect synapse formation and maturation in the developing hippocampus. We found enhanced excitation of CA1 pyramidal neurons in astrocyte-specific ephrin-B1 KO male mice, which coincided with a greater vGlut1/PSD95 colocalization, higher dendritic spine density, and enhanced evoked AMPAR and NMDAR EPSCs. In contrast, EPSCs were reduced in CA1 neurons neighboring ephrin-B1-overexpressing astrocytes. Overexpression of ephrin-B1 in astrocytes during P14-28 developmental period also facilitated evoked IPSCs in CA1 neurons, while evoked IPSCs and miniature IPSC amplitude were reduced following astrocytic ephrin-B1 loss. Lower numbers of parvalbumin-expressing cells and a reduction in the inhibitory VGAT/gephyrin-positive synaptic sites on CA1 neurons in the stratum pyramidale and stratum oriens layers of KO hippocampus may contribute to reduced inhibition and higher excitation. Finally, dysregulation of excitatory/inhibitory balance in KO male mice is most likely responsible for impaired sociability observed in these mice. The ability of astrocytic ephrin-B1 to influence both excitatory and inhibitory synapses during development can potentially contribute to developmental refinement of neuronal circuits.SIGNIFICANCE STATEMENT This report establishes a link between astrocytes and the development of excitatory and inhibitory balance in the mouse hippocampus during early postnatal development. We provide new evidence that astrocytic ephrin-B1 differentially regulates development of excitatory and inhibitory circuits in the hippocampus during early postnatal development using a multidisciplinary approach. The ability of astrocytic ephrin-B1 to influence both excitatory and inhibitory synapses during development can potentially contribute to developmental refinement of neuronal circuits and associated behaviors. Given widespread and growing interest in the astrocyte-mediated mechanisms that regulate synapse development, and the role of EphB receptors in neurodevelopmental disorders, these findings establish a foundation for future studies of astrocytes in clinically relevant conditions.

Published

2020

48. Inhibition of impulsive action by projection-defined prefrontal pyramidal neurons

Author

Li, Bing, Nguyen, Thao Phuong, Ma, Chenyan, and Dan, Yang

Subjects

Biological Psychology, Biomedical and Clinical Sciences, Neurosciences, Psychology, Brain Disorders, 1.1 Normal biological development and functioning, Underpinning research, Neurological, Animals, Basal Ganglia, Behavior, Animal, Impulsive Behavior, Inhibition, Psychological, Interneurons, Mice, Neurons, Optogenetics, Prefrontal Cortex, Pyramidal Cells, Subthalamic Nucleus, Visual Cortex, prefrontal cortex, impulsive behavior, subthalamic nucleus, lateral hypothalamus, two-photon calcium imaging

Abstract

The prefrontal cortex (PFC) plays a critical role in curbing impulsive behavior, but the underlying circuit mechanism remains incompletely understood. Here we show that a subset of dorsomedial PFC (dmPFC) layer 5 pyramidal neurons, which project to the subthalamic nucleus (STN) of the basal ganglia, play a key role in inhibiting impulsive responses in a go/no-go task. Projection-specific labeling and calcium imaging showed that the great majority of STN-projecting neurons were preferentially active in no-go trials when the mouse successfully withheld licking responses, but lateral hypothalamus (LH)-projecting neurons were more active in go trials with licking; visual cortex (V1)-projecting neurons showed only weak task-related activity. Optogenetic activation and inactivation of STN-projecting neurons reduced and increased inappropriate licking, respectively, partly through their direct innervation of the STN, but manipulating LH-projecting neurons had the opposite effects. These results identify a projection-defined subtype of PFC pyramidal neurons as key mediators of impulse control.

Published

2020

49. Age-Related Changes in Synaptic Plasticity Associated with Mossy Fiber Terminal Integration during Adult Neurogenesis

Author

Murray, Karl D, Liu, Xiao-Bo, King, Anna N, Luu, Julie D, and Cheng, Hwai-Jong

Subjects

Biological Psychology, Biomedical and Clinical Sciences, Psychology, Stem Cell Research - Nonembryonic - Non-Human, Pediatric, Neurosciences, Stem Cell Research, 1.1 Normal biological development and functioning, Underpinning research, Neurological, Animals, Mice, Hippocampus, Mossy Fibers, Hippocampal, Neurogenesis, Neuronal Plasticity, Pyramidal Cells, Synapses, aging, conditional transgenic, giant synapse, stratum lucidum, synaptogenesis

Abstract

Mouse hippocampus retains the capacity for neurogenesis throughout lifetime, but such plasticity decreases with age. Adult hippocampal neurogenesis (AHN) involves the birth, maturation, and synaptic integration of newborn granule cells (GCs) into preexisting hippocampal circuitry. While functional integration onto adult-born GCs has been extensively studied, maturation of efferent projections onto CA3 pyramidal cells is less understood, particularly in aged brain. Here, using combined light and reconstructive electron microscopy (EM), we describe the maturation of mossy fiber bouton (MFB) connectivity with CA3 pyramidal cells in young adult and aged mouse brain. We found mature synaptic contacts of newborn GCs were formed in both young and aged brains. However, the dynamics of their spatiotemporal development and the cellular process by which these cells functionally integrated over time were different. In young brain newborn GCs either formed independent nascent MFB synaptic contacts or replaced preexisting MFBs, but these contacts were pruned over time to a mature state. In aged brain only replacement of preexisting MFBs was observed and new contacts were without evidence of pruning. These data illustrate that functional synaptic integration of AHN occurs in young adult and aged brain, but with distinct dynamics. They suggest elimination of preexisting connectivity is required for the integration of adult-born GCs in aged brain.

Published

2020

50. Dysfunction of cortical GABAergic neurons leads to sensory hyper-reactivity in a Shank3 mouse model of ASD

Author

Chen, Qian, Deister, Christopher A, Gao, Xian, Guo, Baolin, Lynn-Jones, Taylor, Chen, Naiyan, Wells, Michael F, Liu, Runpeng, Goard, Michael J, Dimidschstein, Jordane, Feng, Shijing, Shi, Yiwu, Liao, Weiping, Lu, Zhonghua, Fishell, Gord, Moore, Christopher I, and Feng, Guoping

Subjects

Mental Health, Intellectual and Developmental Disabilities (IDD), Autism, Neurosciences, Brain Disorders, Aetiology, 2.1 Biological and endogenous factors, 1.1 Normal biological development and functioning, Underpinning research, Neurological, Mental health, Action Potentials, Animals, Autism Spectrum Disorder, Disease Models, Animal, GABAergic Neurons, Mice, Microfilament Proteins, Nerve Tissue Proteins, Physical Stimulation, Pyramidal Cells, Sensory Thresholds, Somatosensory Cortex, Touch, Touch Perception, Psychology, Cognitive Sciences, Neurology & Neurosurgery

Abstract

Hyper-reactivity to sensory input is a common and debilitating symptom in individuals with autism spectrum disorders (ASD), but the neural basis underlying sensory abnormality is not completely understood. Here we examined the neural representations of sensory perception in the neocortex of a Shank3B-/- mouse model of ASD. Male and female Shank3B-/- mice were more sensitive to relatively weak tactile stimulation in a vibrissa motion detection task. In vivo population calcium imaging in vibrissa primary somatosensory cortex (vS1) revealed increased spontaneous and stimulus-evoked firing in pyramidal neurons but reduced activity in interneurons. Preferential deletion of Shank3 in vS1 inhibitory interneurons led to pyramidal neuron hyperactivity and increased stimulus sensitivity in the vibrissa motion detection task. These findings provide evidence that cortical GABAergic interneuron dysfunction plays a key role in sensory hyper-reactivity in a Shank3 mouse model of ASD and identify a potential cellular target for exploring therapeutic interventions.

Published

2020