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2. Genetic context drives age‐related disparities in synaptic maintenance and structure across cortical and hippocampal neuronal circuits.

Author

Heuer, Sarah E., Nickerson, Emily W., Howell, Gareth R., and Bloss, Erik B.

Subjects
NEURAL circuitry, COGNITIVE aging, PYRAMIDAL neurons, THETA rhythm, SUCCESSFUL aging, HIPPOCAMPUS (Brain)
Abstract

The disconnection of neuronal circuitry through synaptic loss is presumed to be a major driver of age‐related cognitive decline. Age‐related cognitive decline is heterogeneous, yet whether genetic mechanisms differentiate successful from unsuccessful cognitive decline through maintenance or vulnerability of synaptic connections remains unknown. Previous work using rodent and primate models leveraged various techniques to imply that age‐related synaptic loss is widespread on pyramidal cells in prefrontal cortex (PFC) circuits but absent on those in area CA1 of the hippocampus. Here, we examined the effect of aging on synapses on projection neurons forming a hippocampal‐cortico‐thalamic circuit important for spatial working memory tasks from two genetically distinct mouse strains that exhibit susceptibility (C57BL/6J) or resistance (PWK/PhJ) to cognitive decline during aging. Across both strains, synapse density on CA1‐to‐PFC projection neurons appeared completely intact with age. In contrast, we found synapse loss on PFC‐to‐nucleus reuniens (RE) projection neurons from aged C57BL/6J but not PWK/PhJ mice. Moreover, synapses from aged PWK/PhJ mice but not from C57BL/6J exhibited altered morphologies that suggest increased efficiency to drive depolarization in the parent dendrite. Our findings suggest resistance to age‐related cognitive decline results in part by age‐related synaptic adaptations, and identification of these mechanisms in PWK/PhJ mice could uncover new therapeutic targets for promoting successful cognitive aging and extending human health span. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Control of hippocampal synaptic plasticity by microglia–dendrite interactions depends on genetic context in mouse models of Alzheimer's disease.

Author

Heuer, Sarah E., Keezer, Kelly J., Hewes, Amanda A., Onos, Kristen D., Graham, Kourtney C., Howell, Gareth R., and Bloss, Erik B.

Abstract

INTRODUCTION: Human data suggest susceptibility and resilience to features of Alzheimer's disease (AD) such as microglia activation and synaptic dysfunction are under genetic control. However, causal relationships between these processes, and how genomic diversity modulates them remain systemically underexplored in mouse models. METHODS: AD‐vulnerable hippocampal neurons were virally labeled in inbred (C57BL/6J) and wild‐derived (PWK/PhJ) APP/PS1 and wild‐type mice, and brain microglia depleted from 4 to 8 months of age. Dendrites were assessed for synapse plasticity changes by evaluating spine densities and morphologies. RESULTS: In C57BL/6J, microglia depletion blocked amyloid‐induced synaptic density and morphology changes. At a finer scale, synaptic morphology on individual branches was dependent on microglia–dendrite physical interactions. Conversely, synapses from PWK/PhJ mice showed remarkable stability in response to amyloid, and no evidence of microglia contact‐dependent changes on dendrites. DISCUSSION: These results demonstrate that microglia‐dependent synaptic alterations in specific AD‐vulnerable projection pathways are differentially controlled by genetic context. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Genetic context controls microglia‐induced neuronal damage in Alzheimer's disease.

Author

Heuer, Sarah E, Keezer, Kelly J, Hewes, Amanda, Onos, Kristen D, Bloss, Erik B, and Howell, Gareth R

Abstract

Background: The activation of microglia and the loss of synapses have emerged as key events in Alzheimer's disease (AD) progression, yet the relationship between these processes is not clear. Previous studies suggest genetic variation controls microglial activation in AD mouse models, so we evaluated how the elimination of brain microglia influenced synapses on hippocampal pyramidal cells across two genetically distinct AD mouse models. Method: Using a viral approach, we labeled hippocampal neurons that project to the frontal cortex by expressing GFP in young (3m) inbred C57BL/6J and genetically distinct PWK/PhJ female mice with or without a transgenic (APP/PS1) allele that drives amyloid pathology. At 4m we placed half of the mice on diet formulated with CSF1R inhibitor PLX5622 to deplete brain microglia. At 8m, a time when plaque pathology is present in transgenic mice, we examined cognition using the delayed spatial task. We then analyzed the density and morphology of spines across multiple dendritic domains, as well as amyloid plaques and markers of disease‐associated (DAM) and interferon responding (IRM) states of IBA1+ microglia. Result: While spatial cognition was unaffected by PLX5622, we identified B6.APP/PS1 as susceptible and PWK.APP/PS1 as resilient to cognitive deficits at 8m. Across both strains, PLX5622 depleted hippocampal microglia but did not affect amyloid plaques. In contrast, we observed strain differences in spine synapse density and morphology. Compared to spine stability across PWK wild‐type (WT) and APP/PS1 mice, we measured increased density of small spines in B6.APP/PS1 mice (compared to WT). B6.APP/PS1 mice showed reduced spine density with PLX5622, whereas PWK.APP/PS1 mice remained unaltered. These changes in spine density corresponded to DAM being resistant to depletion with PLX5622 in APP/PS1 mice (especially B6), whereas IRM were susceptible, suggesting a neuroprotective role for IRM. Conclusion: We show here that genetic context determines how synapses on CA1 projection neurons respond to the depletion of brain microglia and AD transgenes. Since PWK.APP/PS1 are resistant to hippocampal neuronal damage with robust microglia activation, this strain can be leveraged to further study mechanisms of resilience to AD cognitive deficits and neuropathological damage that can be harnessed for better AD therapeutic treatments. [ABSTRACT FROM AUTHOR]

Published
2023
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12. Revealing the Synaptic Hodology of Mammalian Neural Circuits With Multiscale Neurocartography.

Author

Bloss, Erik B. and Hunt, David L.

Subjects
NEURAL circuitry, CENTRAL nervous system, MICROSCOPY, ELECTRON microscopy, SYNAPSES, IMAGE analysis
Abstract

The functional features of neural circuits are determined by a combination of properties that range in scale from projections systems across the whole brain to molecular interactions at the synapse. The burgeoning field of neurocartography seeks to map these relevant features of brain structure—spanning a volume ∼20 orders of magnitude—to determine how neural circuits perform computations supporting cognitive function and complex behavior. Recent technological breakthroughs in tissue sample preparation, high-throughput electron microscopy imaging, and automated image analyses have produced the first visualizations of all synaptic connections between neurons of invertebrate model systems. However, the sheer size of the central nervous system in mammals implies that reconstruction of the first full brain maps at synaptic scale may not be feasible for decades. In this review, we outline existing and emerging technologies for neurocartography that complement electron microscopy-based strategies and are beginning to derive some basic organizing principles of circuit hodology at the mesoscale, microscale, and nanoscale. Specifically, we discuss how a host of light microscopy techniques including array tomography have been utilized to determine both long-range and subcellular organizing principles of synaptic connectivity. In addition, we discuss how new techniques, such as two-photon serial tomography of the entire mouse brain, have become attractive approaches to dissect the potential connectivity of defined cell types. Ultimately, principles derived from these techniques promise to facilitate a conceptual understanding of how connectomes, and neurocartography in general, can be effectively utilized toward reaching a mechanistic understanding of circuit function. [ABSTRACT FROM AUTHOR]

Published
2019
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13. Cell-Type Specific Changes in Glial Morphology and Glucocorticoid Expression During Stress and Aging in the Medial Prefrontal Cortex.

Author

Chan, Thomas E., Grossman, Yael S., Bloss, Erik B., Janssen, William G., Lou, Wendy, McEwen, Bruce S., Dumitriu, Dani, and Morrison, John H.

Subjects
MICROGLIA, GLUCOCORTICOIDS, PREFRONTAL cortex, PSYCHOLOGICAL stress, AGING
Abstract

Repeated exposure to stressors is known to produce large-scale remodeling of neurons within the prefrontal cortex (PFC). Recent work suggests stress-related forms of structural plasticity can interact with aging to drive distinct patterns of pyramidal cell morphological changes. However, little is known about how other cellular components within PFC might be affected by these challenges. Here, we examined the effects of stress exposure and aging on medial prefrontal cortical glial subpopulations. Interestingly, we found no changes in glial morphology with stress exposure but a profound morphological change with aging. Furthermore, we found an upregulation of non-nuclear glucocorticoid receptors (GR) with aging, while nuclear levels remained largely unaffected. Both changes are selective for microglia, with no stress or aging effect found in astrocytes. Lastly, we show that the changes found within microglia inversely correlated with the density of dendritic spines on layer III pyramidal cells. These findings suggest microglia play a selective role in synaptic health within the aging brain. [ABSTRACT FROM AUTHOR]

Published
2018
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14. Persistence of coordinated LTP and dendritic spine enlargement at mature hippocampal CA1 synapses requires N-cadherin

Author

Bozdagi, Ozlem, Wang, Xiao-bin, Nikitczuk, Jessica S., Anderson, Tonya R., Bloss, Erik B., Radice, Glenn L., Zhou, Qiang, Benson, Deanna L., and Huntley, George W.

Subjects
Mice, Knockout, Patch-Clamp Techniques, Dendritic Spines, Pyramidal Cells, Long-Term Potentiation, Biophysics, Action Potentials, Excitatory Postsynaptic Potentials, In Vitro Techniques, Cadherins, Article, Electric Stimulation, Statistics, Nonparametric, Mice, Inbred C57BL, Mice, Synapses, Animals, Microscopy, Immunoelectron, CA1 Region, Hippocampal
Abstract

Persistent changes in spine shape are coupled to long-lasting synaptic plasticity in hippocampus. The molecules that coordinate such persistent structural and functional plasticity are unknown. Here, we generated mice in which the cell adhesion molecule N-cadherin was conditionally ablated from postnatal, excitatory synapses in hippocampus. We applied to adult mice of either sex a combination of whole-cell recording, 2-photon microscopy, and spine morphometric analysis to show that postnatal ablation of N-cadherin has profound effects on the stability of coordinated spine enlargement and long-term potentiation (LTP) at mature CA1 synapses, with no effects on baseline spine density or morphology, baseline properties of synaptic neurotransmission, or long-term depression (LTD). Thus, N-cadherin couples persistent spine structural modifications with long-lasting synaptic functional modifications associated selectively with LTP, revealing unexpectedly distinct roles at mature synapses in comparison with earlier, broader functions in synapse and spine development.

Published
2010

15. Structured Dendritic Inhibition Supports Branch-Selective Integration in CA1 Pyramidal Cells.

Author

Bloss, Erik B., Cembrowski, Mark S., Karsh, Bill, Colonell, Jennifer, Fetter, Richard D., and Spruston, Nelson

Subjects
*DENDRITIC cells, *PYRAMIDAL neurons, *NEURAL circuitry, *NEURAL physiology, *GABAERGIC neurons, *ELECTRON microscopy
Abstract

Summary Neuronal circuit function is governed by precise patterns of connectivity between specialized groups of neurons. The diversity of GABAergic interneurons is a hallmark of cortical circuits, yet little is known about their targeting to individual postsynaptic dendrites. We examined synaptic connectivity between molecularly defined inhibitory interneurons and CA1 pyramidal cell dendrites using correlative light-electron microscopy and large-volume array tomography. We show that interneurons can be highly selective in their connectivity to specific dendritic branch types and, furthermore, exhibit precisely targeted connectivity to the origin or end of individual branches. Computational simulations indicate that the observed subcellular targeting enables control over the nonlinear integration of synaptic input or the initiation and backpropagation of action potentials in a branch-selective manner. Our results demonstrate that connectivity between interneurons and pyramidal cell dendrites is more precise and spatially segregated than previously appreciated, which may be a critical determinant of how inhibition shapes dendritic computation. Video Abstract [ABSTRACT FROM AUTHOR]

Published
2016
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16. Inhibitory Gating of Input Comparison in the CA1 Microcircuit.

Author

Milstein, Aaron D., Bloss, Erik B., Apostolides, Pierre F., Vaidya, Sachin P., Dilly, Geoffrey A., Zemelman, Boris V., and Magee, Jeffrey C.

Subjects
*NEURAL circuitry, *FEEDFORWARD neural networks, *SYNAPSES, *DENDRITES, *HIPPOCAMPUS (Brain), *ENTORHINAL cortex
Abstract

Summary Spatial and temporal features of synaptic inputs engage integration mechanisms on multiple scales, including presynaptic release sites, postsynaptic dendrites, and networks of inhibitory interneurons. Here we investigate how these mechanisms cooperate to filter synaptic input in hippocampal area CA1. Dendritic recordings from CA1 pyramidal neurons reveal that proximal inputs from CA3 as well as distal inputs from entorhinal cortex layer III (ECIII) sum sublinearly or linearly at low firing rates due to feedforward inhibition, but sum supralinearly at high firing rates due to synaptic facilitation, producing a high-pass filter. However, during ECIII and CA3 input comparison, supralinear dendritic integration is dynamically balanced by feedforward and feedback inhibition, resulting in suppression of dendritic complex spiking. We find that a particular subpopulation of CA1 interneurons expressing neuropeptide Y (NPY) contributes prominently to this dynamic filter by integrating both ECIII and CA3 input pathways and potently inhibiting CA1 pyramidal neuron dendrites. [ABSTRACT FROM AUTHOR]

Published
2015
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17. High-performance probes for light and electron microscopy.

Author

Viswanathan, Sarada, Williams, Megan E, Bloss, Erik B, Stasevich, Timothy J, Speer, Colenso M, Nern, Aljoscha, Pfeiffer, Barret D, Hooks, Bryan M, Li, Wei-Ping, English, Brian P, Tian, Teresa, Henry, Gilbert L, Macklin, John J, Patel, Ronak, Gerfen, Charles R, Zhuang, Xiaowei, Wang, Yalin, Rubin, Gerald M, and Looger, Loren L

Subjects
ELECTRON microscopy, MICROSCOPY, FLUORESCENT proteins, IMMUNOGLOBULIN G, EPITOPES, BRAIN mapping, RNA sequencing
Abstract

We describe an engineered family of highly antigenic molecules based on GFP-like fluorescent proteins. These molecules contain numerous copies of peptide epitopes and simultaneously bind IgG antibodies at each location. These 'spaghetti monster' fluorescent proteins (smFPs) distributed well in neurons, notably into small dendrites, spines and axons. smFP immunolabeling localized weakly expressed proteins not well resolved with traditional epitope tags. By varying epitope and scaffold, we generated a diverse family of mutually orthogonal antigens. In cultured neurons and mouse and fly brains, smFP probes allowed robust, orthogonal multicolor visualization of proteins, cell populations and neuropil. smFP variants complement existing tracers and greatly increase the number of simultaneous imaging channels, and they performed well in advanced preparations such as array tomography, super-resolution fluorescence imaging and electron microscopy. In living cells, the probes improved single-molecule image tracking and increased yield for RNA-seq. These probes facilitate new experiments in connectomics, transcriptomics and protein localization. [ABSTRACT FROM AUTHOR]

Published
2015
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18. Clinically Relevant Hormone Treatments Fail to Induce Spinogenesis in Prefrontal Cortex of Aged Female Rhesus Monkeys.

Author

Ohm, Daniel T., Bloss, Erik B., Janssen, William G., Dietz, Karen C., Wadsworth, Shannon, Lou, Wendy, Gee, Nancy A., Lasley, Bill L., Rapp, Peter R., and Morrison, John H.

Subjects
*ANIMAL models in research, *ESTROGEN, *COGNITION, *NEURAL circuitry, *DEMENTIA, *PRIMATE trade
Abstract

Preclinical animal models have provided strong evidence that estrogen (E) therapy (ET) enhances cognition and induces spinogenesis in neuronal circuits. However, clinical studies have been inconsistent, with some studies revealing adverse effects of ET, including an increased risk of dementia. In an effort to bridge this disconnect between the preclinical and clinical data, we have developed a nonhuman primate (NHP) model of ET combined with high-resolution dendritic spine analysis of dorsolateral prefrontal cortical (dlPFC) neurons. Previously, we reported cyclic ET in aged, ovariectomized NHPs increased spine density on dlPFC neurons. Here, we report that monkeys treated with cyclic E treatment paired with cyclic progesterone (P), continuous E combined with P (either cyclic or continuous), or unopposed continuous E failed to increase spines on dlPFC neurons. Given that the most prevalent form of ET prescribed to women is a combined and continuous E and P, these data bring into convergence the human neuropsychological findings and preclinical neurobi-ological evidence that standard hormone therapy in women is unlikely to yield the synaptic benefit presumed to underlie the cognitive enhancement reported in animal models. [ABSTRACT FROM AUTHOR]

Published
2012
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19. Evidence for Reduced Experience-Dependent Dendritic Spine Plasticity in the Aging Prefrontal Cortex.

Author

Bloss, Erik B., Janssen, William G., Ohm, Daniel T., Yuk, Frank J., Wadsworth, Shannon, Saardi, Karl M., McEwen, Bruce S., and Morrison, John H.

Subjects
*PREFRONTAL cortex, *NERVOUS system, *DEVELOPMENTAL biology, *NEUROBIOLOGY, *FRONTAL lobe, *AGING
Abstract

Cognitive functions that require the prefrontal cortex are highly sensitive to aging in humans, nonhuman primates, and rodents, although the neurobiological correlates of this vulnerability remain largely unknown. It has been proposed that dendritic spines represent the primary site of structural plasticity in the adult brain, and recent data have supported the hypothesis that aging is associated with alterations of dendritic spine morphology and plasticity in prefrontal cortex. However, no study to date has directly examined whether aging alters the capacity for experience-dependent spine plasticity in aging prefrontal neurons. To address this possibility, we used young, middle-aged, and aged rats in a behavioral stress paradigm known to produce spine remodeling in prefrontal cortical neurons. In young rats, stress resulted in dendritic spine loss and altered patterns of spine morphology; in contrast, spines from middle-aged and aged animals were remarkably stable and did not show evidence of remodeling. The loss of stress-induced spine plasticity observed in aging rats occurred alongside robust age-related reductions in spine density and shifts in remaining spine morphology. Together, the data presented here provide the first evidence that experience-dependent spine plasticity is altered by aging in prefrontal cortex, and support a model in which dendritic spines become progressively less plastic in the aging brain. [ABSTRACT FROM AUTHOR]

Published
2011
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20. Persistence of Coordinated Long-Term Potentiation and Dendritic Spine Enlargement at Mature Hippocampal CA1 Synapses Requires N-Cadherin.

Author

Bozdagi, Ozlem, Xiao-bin Wang, Nikitczuk, Jessica S., Anderson, Tonya R., Bloss, Erik B., Radice, Glenn L., Qiang Zhou, Benson, Deanna L., and Huntley, George W.

Subjects
HIPPOCAMPUS (Brain), SPINE, CADHERINS, DENDRITIC cells, SYNAPSES
Abstract

Persistent changes in spine shape are coupled to long-lasting synaptic plasticity in hippocampus. The molecules that coordinate such persistent structural and functional plasticity are unknown. Here, we generated mice in which the cell adhesion molecule N-cadherin was conditionally ablated from postnatal, excitatory synapses in hippocampus. We applied to adult mice of either sex a combination of whole-cell recording, two-photon microscopy, and spine morphometric analysis to show that postnatal ablation of N-cadherin has profound effects on the stability of coordinated spine enlargement and long-term potentiation (LTP) at mature CA1 synapses, with no effects on baseline spine density or morphology, baseline properties of synaptic neurotransmission, or long-term depression. Thus, N-cadherin couples persistent spine structural modifications with long-lasting synaptic functional modifications associated selectively with LTP, revealing unexpectedly distinct roles at mature synapses in comparison with earlier, broader functions in synapse and spine development. [ABSTRACT FROM AUTHOR]

Published
2010
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21. Interactive Effects of Stress and Aging on Structural Plasticity in the Prefrontal Cortex.

Author

Bloss, Erik B., Janssen, William G., McEwen, Bruce S., and Morrison, John H.

Subjects
*PSYCHOLOGICAL stress, *AGING, *NERVOUS system, *COGNITION, *NEURONS
Abstract

Neuronal networks in the prefrontal cortex mediate the highest levels of cognitive processing and decision making, and the capacity to perform these functions is among the cognitive features most vulnerable to aging. Despite much research, the neurobiological basis of age-related compromised prefrontal function remains elusive. Many investigators have hypothesized that exposure to stress may accelerate cognitive aging, though few studies have directly tested this hypothesis and even fewer have investigated a neuronal basis for such effects. It is known that in young animals, stress causes morphological remodeling of prefrontal pyramidal neurons that is reversible. The present studies sought to determine whether age influences the reversibility of stress-induced morphological plasticity in rat prefrontal neurons. We hypothesized that neocortical structural resilience is compromised in normal aging. To directly test this hypothesis we used a well characterized chronic restraint stress paradigm, with an additional group allowed to recover from the stress paradigm, in 3-, 12-, and 20-month-old male rats. In young animals, stress induced reductions of apical dendritic length and branch number, which were reversed with recovery; in contrast, middle-aged and aged rats failed to show reversible morphological remodeling when subjected to the same stress and recovery paradigm. The data presented here provide evidence that aging is accompanied by selective impairments in long-term neocortical morphological plasticity. [ABSTRACT FROM AUTHOR]

Published
2010
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22. Regulation of the nicotinic receptor alpha7 subunit by chronic stress and corticosteroids

Author

Hunter, Richard G., Bloss, Erik B., McCarthy, Katharine J., and McEwen, Bruce S.

Subjects
*NICOTINIC receptors, *CORTICOSTEROIDS, *PSYCHOLOGICAL stress, *GENETIC regulation, *HIPPOCAMPUS (Brain), *MESSENGER RNA, *ADRENALECTOMY, *GLUCOCORTICOID receptors, *GENE expression
Abstract

Abstract: The α7 subunit of the nicotinic acetylcholine receptor (NAchRα7) is one of the principal brain receptors for nicotine and is thought to be a mediator of nicotine''s pro-cognitive effects. While nicotine is known to interact with the stress axis, little is known about the effect of stress or corticosteroids on the expression in the hippocampus, a brain region important to both cognition and stress reactivity. We examined the effects of chronic (21day) restraint stress (CRS) and adrenalectomy with hormone replacement with the selective mineralocorticoid receptor (MR) agonist aldosterone, the selective glucocorticoid receptor (GR) agonist RU28,362 or corticosterone for 7days, on the hippocampal expression of NAchRα7 mRNA and protein, as measured by 125I α-Bungarotoxin autoradiography. We found that CRS increased the levels of NAchRα7 mRNA in the CA1, CA3 and dentate gyrus while levels of the protein were lowered by the same treatment. Corticosteroid replacement showed a GR specific increase in NAchRα7 mRNA, consistent with a corticosteroid mediated effect of CRS. While the mechanism behind these observations is as yet unclear, they may be neuroprotective against the damaging effects of CRS or an example of adaptation to the allostatic load produced by CRS. [Copyright &y& Elsevier]

Published
2010
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23. Hippocampal and thalamic afferents form distinct synaptic microcircuits in the mouse infralimbic frontal cortex.

Author

Graham, Kourtney, Spruston, Nelson, and Bloss, Erik B.

Abstract

The selection of goal-directed behaviors is supported by neural circuits located within the frontal cortex. Frontal cortical afferents arise from multiple brain areas, yet the cell-type-specific targeting of these inputs is unclear. Here, we use monosynaptic retrograde rabies mapping to examine the distribution of afferent neurons targeting distinct classes of local inhibitory interneurons and excitatory projection neurons in mouse infralimbic frontal cortex. Interneurons expressing parvalbumin, somatostatin, or vasoactive intestinal peptide receive a large proportion of inputs from the hippocampus, while interneurons expressing neuron-derived neurotrophic factor receive a large proportion of inputs from thalamic regions. A similar dichotomy is present among the four different excitatory projection neurons. These results show a prominent bias among long-range hippocampal and thalamic afferent systems in their targeting to specific sets of frontal cortical neurons. Moreover, they suggest the presence of two distinct local microcircuits that control how different inputs govern frontal cortical information processing. [Display omitted] • Neurons in the infralimbic (IL) cortex mediate flexible forms of behavior • IL neurons receive input from multiple brain regions • Rabies mapping identifies inputs to inhibitory and excitatory neurons • Hippocampal and thalamic afferents differentially target specific IL neurons Patterns of synaptic connectivity govern the functional properties of neural circuits. Graham et al. map the afferent neurons targeting eight specific cell classes in mouse infralimbic cortex. Inputs from the hippocampus and thalamus are differentially targeted to specific neurons, suggesting two distinct synaptic microcircuits control circuit transformations. [ABSTRACT FROM AUTHOR]

Published
2021
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24. Hippocampal Pyramidal Neurons Comprise Two Distinct Cell Types that Are Countermodulated by Metabotropic Receptors

Author

Graves, Austin R., Moore, Shannon J., Bloss, Erik B., Mensh, Brett D., Kath, William L., and Spruston, Nelson

Subjects
*HIPPOCAMPUS (Brain), *NEURONS, *NEUROSCIENCES, *ACETYLCHOLINE, *SYNERGETICS, *NEURAL transmission, *COGNITIVE ability
Abstract

Summary: Relating the function of neuronal cell types to information processing and behavior is a central goal of neuroscience. In the hippocampus, pyramidal cells in CA1 and the subiculum process sensory and motor cues to form a cognitive map encoding spatial, contextual, and emotional information, which they transmit throughout the brain. Do these cells constitute a single class or are there multiple cell types with specialized functions? Using unbiased cluster analysis, we show that there are two morphologically and electrophysiologically distinct principal cell types that carry hippocampal output. We show further that these two cell types are inversely modulated by the synergistic action of glutamate and acetylcholine acting on metabotropic receptors that are central to hippocampal function. Combined with prior connectivity studies, our results support a model of hippocampal processing in which the two pyramidal cell types are predominantly segregated into two parallel pathways that process distinct modalities of information. [ABSTRACT FROM AUTHOR]

Published
2012
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26. Control of hippocampal synaptic plasticity by microglia-dendrite interactions depends on genetic context in mouse models of Alzheimer's disease.

Author

Heuer SE, Keezer KJ, Hewes AA, Onos KD, Graham KC, Howell GR, and Bloss EB

Subjects
Humans, Mice, Animals, Microglia metabolism, Amyloid beta-Protein Precursor metabolism, Mice, Transgenic, Mice, Inbred C57BL, Hippocampus metabolism, Disease Models, Animal, Neuronal Plasticity genetics, Synapses metabolism, Amyloid metabolism, Dendrites metabolism, Alzheimer Disease genetics, Alzheimer Disease metabolism
Abstract

Introduction: Human data suggest susceptibility and resilience to features of Alzheimer's disease (AD) such as microglia activation and synaptic dysfunction are under genetic control. However, causal relationships between these processes, and how genomic diversity modulates them remain systemically underexplored in mouse models., Methods: AD-vulnerable hippocampal neurons were virally labeled in inbred (C57BL/6J) and wild-derived (PWK/PhJ) APP/PS1 and wild-type mice, and brain microglia depleted from 4 to 8 months of age. Dendrites were assessed for synapse plasticity changes by evaluating spine densities and morphologies., Results: In C57BL/6J, microglia depletion blocked amyloid-induced synaptic density and morphology changes. At a finer scale, synaptic morphology on individual branches was dependent on microglia-dendrite physical interactions. Conversely, synapses from PWK/PhJ mice showed remarkable stability in response to amyloid, and no evidence of microglia contact-dependent changes on dendrites., Discussion: These results demonstrate that microglia-dependent synaptic alterations in specific AD-vulnerable projection pathways are differentially controlled by genetic context., (© 2023 The Authors. Alzheimer's & Dementia published by Wiley Periodicals LLC on behalf of Alzheimer's Association.)

Published
2024
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27. Genetic context drives age-related disparities in synaptic maintenance and structure across cortical and hippocampal neuronal circuits.

Author

Heuer SE, Nickerson EW, Howell GR, and Bloss EB

Abstract

The disconnection of neuronal circuits through synaptic loss is presumed to be a major driver of age-related cognitive decline. Age-related cognitive decline is heterogeneous, yet whether genetic mechanisms differentiate successful from unsuccessful cognitive decline through synaptic structural mechanisms remains unknown. Previous work using rodent and primate models leveraged various techniques to suggest that age-related synaptic loss is widespread on pyramidal cells in prefrontal cortex (PFC) circuits but absent on those in area CA1 of the hippocampus. Here, we examined the effect of aging on synapses on projection neurons forming a hippocampal-cortico-thalamic circuit important for spatial working memory tasks from two genetically distinct mouse strains that exhibit susceptibility (C57BL/6J) or resistance (PWK/PhJ) to cognitive decline during aging. Across both strains, synapses on the CA1-to-PFC projection neurons appeared completely intact with age. In contrast, we found synapse loss on PFC-to-nucleus reuniens (RE) projection neurons from aged C57BL/6J but not PWK/PhJ mice. Moreover, synapses from aged PWK/PhJ mice but not from C57BL/6J exhibited morphological changes that suggest increased synaptic efficiency to depolarize the parent dendrite. Our findings suggest resistance to age-related cognitive decline results in part by age-related synaptic adaptations, and identification of these mechanisms in PWK/PhJ mice could uncover new therapeutic targets for promoting successful cognitive aging and extending human health span., Competing Interests: Competing Interest statement The authors have no conflicts or competing interests to declare.

Published
2023
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28. Genetic context controls early microglia-synaptic interactions in mouse models of Alzheimer's disease.

Author

Heuer SE, Keezer KJ, Hewes AA, Onos KD, Graham KC, Howell GR, and Bloss EB

Abstract

Common features of Alzheimer's disease (AD) include amyloid pathology, microglia activation and synaptic dysfunction, however, the causal relationships amongst them remains unclear. Further, human data suggest susceptibility and resilience to AD neuropathology is controlled by genetic context, a factor underexplored in mouse models. To this end, we leveraged viral strategies to label an AD-vulnerable neuronal circuit in CA1 dendrites projecting to the frontal cortex in genetically diverse C57BL/6J (B6) and PWK/PhJ (PWK) APP/PS1 mouse strains and used PLX5622 to non-invasively deplete brain microglia. Reconstructions of labeled neurons revealed microglia-dependent changes in dendritic spine density and morphology in B6 wild-type (WT) and APP/PS1 yet a marked stability of spines across PWK mice. We further showed that synaptic changes depend on direct microglia-dendrite interactions in B6. APP/PS1 but not PWK. APP/PS1 mice. Collectively, these results demonstrate that microglia-dependent synaptic alterations in a specific AD-vulnerable projection pathway are differentially controlled by genetic context.

Published
2023
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29. Hippocampal kainate receptors.

Author

Bloss EB and Hunter RG

Subjects
Animals, Epilepsy metabolism, Glutamic Acid metabolism, Humans, Mental Disorders metabolism, Neuronal Plasticity, Rats, Hippocampus metabolism, Receptors, Kainic Acid metabolism
Abstract

Glutamate is the major fast excitatory amino acid transmitter in the CNS, and exerts its action through receptors that function as ion channels such as NMDA receptors (NMDARs), AMPA receptors (AMPARs), and kainate receptors (KARs), and also through signaling cascades via metabotropic receptors. Of the ionotropic receptors, NMDARs and AMPARs have been extensively studied for decades, while relatively fewer studies have focused on the role of the KARs in the glutamatergic synapse. Despite this, there is considerable experimental data that suggest a major role for KARs in modulating synaptic transmission and plasticity, particularly in the hippocampal formation, as well as an involvement in disease states. KARs mediate most aspects of kainate-induced seizures and excitotoxic cell death, and thus, are a rational drug target for antiepileptic drug discovery. Recent data from human studies have also highlighted a role for KARs in certain psychiatric diseases, such as schizophrenia and major depression, and a recent association of KAR gene variants with response to antidepressants has brought considerable interest in developing a clearer understanding of KAR action in the brain. We have recently found that exposure to stress and stress hormone administration can produce contrasting changes in KAR subunit expression in the rat hippocampus, suggesting that a modification of hippocampal KARs by stress may be a mechanism for predisposing individuals to stress-related psychiatric diseases. Here, we review the anatomical and functional characteristics of hippocampal KARs, their role in synaptic plasticity, their regulation by certain hormones, and briefly review what is known about their involvement in disease states such as epilepsy and depression., (Copyright 2010 Elsevier Inc. All rights reserved.)

Published
2010
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