Your search keyword '"Homeostatic plasticity"' showing total 665 results

1. Retinoic acid-mediated homeostatic plasticity in the nucleus accumbens core contributes to incubation of cocaine craving.

Author

Wunsch AM, Hwang EK, Funke JR, Baker R, Moutier A, Milovanovic M, Green TA, and Wolf ME

Subjects

Animals, Male, Rats, Receptors, AMPA metabolism, Retinoic Acid 4-Hydroxylase metabolism, Signal Transduction, RNA, Small Interfering administration & dosage, Cues, Drug-Seeking Behavior drug effects, Neurons metabolism, Neurons drug effects, Nucleus Accumbens metabolism, Nucleus Accumbens drug effects, Craving drug effects, Craving physiology, Tretinoin pharmacology, Tretinoin metabolism, Neuronal Plasticity drug effects, Neuronal Plasticity physiology, Self Administration, Cocaine administration & dosage, Cocaine pharmacology, Homeostasis physiology, Cocaine-Related Disorders metabolism, Rats, Sprague-Dawley

Abstract

Rationale: Incubation of cocaine craving refers to the progressive intensification of cue-induced craving during abstinence from cocaine self-administration. We showed previously that homomeric GluA1 Ca 2+ -permeable AMPARs (CP-AMPAR) accumulate in excitatory synapses of nucleus accumbens core (NAcc) medium spiny neurons (MSN) after ∼1 month of abstinence and thereafter their activation is required for expression of incubation. Therefore, it is important to understand mechanisms underlying CP-AMPAR plasticity., Objectives: We hypothesize that CP-AMPAR upregulation represents a retinoic acid (RA)-dependent form of homeostatic plasticity, previously described in other brain regions, in which a reduction in neuronal activity disinhibits RA synthesis, leading to GluA1 translation and CP-AMPAR synaptic insertion. We tested this using viral vectors to bidirectionally manipulate RA signaling in NAcc during abstinence following extended-access cocaine self-administration., Results: We used shRNA targeted to the RA degradative enzyme Cyp26b1 to increase RA signaling. This treatment accelerated incubation; rats expressed incubation on abstinence day (AD) 15, when it is not yet detected in control rats. It also accelerated CP-AMPAR synaptic insertion measured with slice physiology. CP-AMPARs were detected in Cyp26b1 shRNA-expressing MSN, but not control MSN, on AD15-18. Next, we used shRNA targeted to the major RA synthetic enzyme Aldh1a1 to reduce RA signaling. In MSN expressing Aldh1a1 shRNA, synaptic CP-AMPARs were reduced in late withdrawal (AD42-60) compared to controls. However, we did not detect an effect of this manipulation on incubated cocaine seeking (AD40)., Conclusions: These findings support the hypothesis that increased RA signaling during abstinence contributes to CP-AMPAR accumulation and incubation of cocaine craving., (© 2024. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2024

2. Homeostatic metaplasticity induced by the combination of two inhibitory brain stimulation techniques: Continuous theta burst and transcranial static magnetic stimulation.

Author

Arias P, Adán-Arcay L, Madinabeitia-Mancebo E, and Cudeiro J

Subjects

Humans, Male, Female, Adult, Young Adult, Homeostasis physiology, Neural Inhibition physiology, Theta Rhythm physiology, Transcranial Magnetic Stimulation methods, Evoked Potentials, Motor physiology, Neuronal Plasticity physiology, Motor Cortex physiology

Abstract

Aftereffects of non-invasive brain stimulation techniques may be brain state-dependent. Either continuous theta-burst stimulation (cTBS) as transcranial static magnetic field stimulation (tSMS) reduce cortical excitability. Our objective was to explore the aftereffects of tSMS on a M1 previously stimulated with cTBS. The interaction effect of two inhibitory protocols on cortical excitability was tested on healthy volunteers (n = 20), in two different sessions. A first application cTBS was followed by real-tSMS in one session, or sham-tSMS in the other session. When intracortical inhibition was tested with paired-pulse transcranial magnetic stimulation, LICI (ie., long intracortical inhibition) increased, although the unconditioned motor-evoked potential (MEP) remained stable. These effects were observed in the whole sample of participants regardless of the type of static magnetic field stimulation (real or sham) applied after cTBS. Subsequently, we defined a group of good-responders to cTBS (n = 9) on whom the unconditioned MEP amplitude reduced after cTBS and found that application of real-tSMS (subsequent to cTBS) increased the unconditioned MEP. This MEP increase was not found when sham-tSMS followed cTBS. The interaction of tSMS with cTBS seems not to take place at inhibitory cortical interneurons tested by LICI, since LICI was not differently affected after real and sham tSMS. Our results indicate the existence of a process of homeostatic plasticity when tSMS is applied after cTBS. This work suggests that tSMS aftereffects arise at the synaptic level and supports further investigation into tSMS as a useful tool to restore pathological conditions with altered cortical excitability., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

3. Facilitation of Early and Middle Latency SEP after tDCS of M1: No Evidence of Primary Somatosensory Homeostatic Plasticity.

Author

Zolezzi DM, Larsen DB, Zamorano AM, and Graven-Nielsen T

Subjects

Humans, Male, Female, Adult, Young Adult, Electroencephalography methods, Neuronal Plasticity physiology, Evoked Potentials, Somatosensory physiology, Transcranial Direct Current Stimulation methods, Motor Cortex physiology, Homeostasis physiology, Somatosensory Cortex physiology

Abstract

Homeostatic plasticity is a mechanism that stabilizes cortical excitability within a physiological range. Most homeostatic plasticity protocols have primed and tested the homeostatic response of the primary motor cortex (M1). This study investigated if a homeostatic response could be recorded from the primary sensory cortex (S1) after inducing homeostatic plasticity in M1. In 31 healthy participants, homeostatic plasticity was induced over M1 with a priming and testing block of transcranial direct current stimulation (tDCS) in two different sessions (anodal and cathodal). S1 excitability was assessed by early (N20, P25) and middle-latency (N33-P45) somatosensory evoked potentials (SEP) extracted from 4 electrodes (CP5, CP3, P5, P3). Baseline and post-measures (post-priming, 0-min, 10-min, and 20-min after homeostatic induction) were taken. Anodal M1 homeostatic plasticity induction significantly facilitated the N20-P25, P45 peak, and N33-P45 early SEP components up to 20-min post-induction, without any indication of a homeostatic response (i.e., reduced SEP). Cathodal homeostatic induction did not induce any significant effect on early or middle latency SEPs. M1 homeostatic plasticity induction by anodal stimulation protocol to the primary motor cortex did not induce a homeostatic response in SEPs., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

4. Diverging from the Norm: Reevaluating What Miniature Excitatory Postsynaptic Currents Tell Us about Homeostatic Synaptic Plasticity.

Author

Koesters AG, Rich MM, and Engisch KL

Subjects

Mice, Animals, Excitatory Postsynaptic Potentials physiology, Synapses physiology, Homeostasis physiology, Neurons physiology, Neuronal Plasticity physiology

Abstract

The idea that the nervous system maintains a set point of network activity and homeostatically returns to that set point in the face of dramatic disruption-during development, after injury, in pathologic states, and during sleep/wake cycles-is rapidly becoming accepted as a key plasticity behavior, placing it alongside long-term potentiation and depression. The dramatic growth in studies of homeostatic synaptic plasticity of miniature excitatory synaptic currents (mEPSCs) is attributable, in part, to the simple yet elegant mechanism of uniform multiplicative scaling proposed by Turrigiano and colleagues: that neurons sense their own activity and globally multiply the strength of every synapse by a single factor to return activity to the set point without altering established differences in synaptic weights. We have recently shown that for mEPSCs recorded from control and activity-blocked cultures of mouse cortical neurons, the synaptic scaling factor is not uniform but is close to 1 for the smallest mEPSC amplitudes and progressively increases as mEPSC amplitudes increase, which we term divergent scaling . Using insights gained from simulating uniform multiplicative scaling, we review evidence from published studies and conclude that divergent synaptic scaling is the norm rather than the exception. This conclusion has implications for hypotheses about the molecular mechanisms underlying synaptic scaling., Competing Interests: Declaration of Conflicting InterestsThe authors declared no potential conflicts of interest with respect to the research, authorship, and/or publication of this article.

Published

2024

5. Evidence that Alzheimer's Disease Is a Disease of Competitive Synaptic Plasticity Gone Awry.

Author

Huang Z

Subjects

Humans, Animals, Apolipoproteins E genetics, Apolipoproteins E metabolism, Brain metabolism, Neurons metabolism, Neurons physiology, Neuronal Plasticity physiology, Alzheimer Disease metabolism, Amyloid beta-Peptides metabolism, Synapses physiology, Synapses metabolism

Abstract

Mounting evidence indicates that a physiological function of amyloid-β (Aβ) is to mediate neural activity-dependent homeostatic and competitive synaptic plasticity in the brain. I have previously summarized the lines of evidence supporting this hypothesis and highlighted the similarities between Aβ and anti-microbial peptides in mediating cell/synapse competition. In cell competition, anti-microbial peptides deploy a multitude of mechanisms to ensure both self-protection and competitor elimination. Here I review recent studies showing that similar mechanisms are at play in Aβ-mediated synapse competition and perturbations in these mechanisms underpin Alzheimer's disease (AD). Specifically, I discuss evidence that Aβ and ApoE, two crucial players in AD, co-operate in the regulation of synapse competition. Glial ApoE promotes self-protection by increasing the production of trophic monomeric Aβ and inhibiting its assembly into toxic oligomers. Conversely, Aβ oligomers, once assembled, promote the elimination of competitor synapses via direct toxic activity and amplification of "eat-me" signals promoting the elimination of weak synapses. I further summarize evidence that neuronal ApoE may be part of a gene regulatory network that normally promotes competitive plasticity, explaining the selective vulnerability of ApoE expressing neurons in AD brains. Lastly, I discuss evidence that sleep may be key to Aβ-orchestrated plasticity, in which sleep is not only induced by Aβ but is also required for Aβ-mediated plasticity, underlining the link between sleep and AD. Together, these results strongly argue that AD is a disease of competitive synaptic plasticity gone awry, a novel perspective that may promote AD research.

Published

2024

6. A human in vitro neuronal model for studying homeostatic plasticity at the network level.

Author

Yuan X, Puvogel S, van Rhijn JR, Ciptasari U, Esteve-Codina A, Meijer M, Rouschop S, van Hugte EJH, Oudakker A, Schoenmaker C, Frega M, Schubert D, Franke B, and Nadif Kasri N

Subjects

Humans, Rats, Animals, Cells, Cultured, Neurons metabolism, Coculture Techniques, Tetrodotoxin pharmacology, Neuronal Plasticity physiology, Induced Pluripotent Stem Cells

Abstract

Mechanisms that underlie homeostatic plasticity have been extensively investigated at single-cell levels in animal models, but are less well understood at the network level. Here, we used microelectrode arrays to characterize neuronal networks following induction of homeostatic plasticity in human induced pluripotent stem cell (hiPSC)-derived glutamatergic neurons co-cultured with rat astrocytes. Chronic suppression of neuronal activity through tetrodotoxin (TTX) elicited a time-dependent network re-arrangement. Increased expression of AMPA receptors and the elongation of axon initial segments were associated with increased network excitability following TTX treatment. Transcriptomic profiling of TTX-treated neurons revealed up-regulated genes related to extracellular matrix organization, while down-regulated genes related to cell communication; also astrocytic gene expression was found altered. Overall, our study shows that hiPSC-derived neuronal networks provide a reliable in vitro platform to measure and characterize homeostatic plasticity at network and single-cell levels; this platform can be extended to investigate altered homeostatic plasticity in brain disorders., Competing Interests: Declaration of interests B.F. has received educational speaking fees from Medice., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2023

7. The duration effect of short-term monocular deprivation measured by binocular rivalry and binocular combination.

Author

Prosper A, Pasqualetti M, Morrone MC, and Lunghi C

Subjects

Adult, Humans, Vision, Binocular, Vision, Monocular, Neuronal Plasticity, Dominance, Ocular

Abstract

The ocular dominance shift observed after short-term monocular deprivation is a widely used measure of visual homeostatic plasticity in adult humans. Binocular rivalry and binocular combination techniques are used interchangeably to characterize homeostatic plasticity, sometimes leading to contradictory results. Here we directly compare the effect of short-term monocular deprivation on ocular dominance measured by either binocular rivalry or binocular combination and its dependence on the duration of deprivation (15 or 120 min) in the same group of participants. Our results show that both binocular rivalry and binocular combination provide reliable estimates of ocular dominance, which are strongly correlated across techniques both before and after deprivation. Moreover, while 15 min of monocular deprivation induce a larger shift of ocular dominance when measured using binocular combination compared to binocular rivalry, for both techniques, the shift in ocular dominance exhibits a strong dependence on the duration of monocular deprivation, with longer deprivation inducing a larger and longer-lasting shift in ocular dominance. Taken together, our results indicate that both binocular rivalry and binocular combination offer very consistent and reliable measurements of both ocular dominance and the effect short-term monocular deprivation., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2023

8. A transcriptional constraint mechanism limits the homeostatic response to activity deprivation in mammalian neocortex.

Author

Valakh V, Wise D, Zhu XA, Sha M, Fok J, Van Hooser SD, Schectman R, Cepeda I, Kirk R, O'Toole SM, and Nelson SB

Subjects

Mice, Animals, Synaptic Transmission physiology, Homeostasis physiology, Mice, Knockout, Seizures genetics, Synapses physiology, Mammals, Neuronal Plasticity physiology, Neocortex

Abstract

Healthy neuronal networks rely on homeostatic plasticity to maintain stable firing rates despite changing synaptic drive. These mechanisms, however, can themselves be destabilizing if activated inappropriately or excessively. For example, prolonged activity deprivation can lead to rebound hyperactivity and seizures. While many forms of homeostasis have been described, whether and how the magnitude of homeostatic plasticity is constrained remains unknown. Here, we uncover negative regulation of cortical network homeostasis by the PARbZIP family of transcription factors. In cortical slice cultures made from knockout mice lacking all three of these factors, the network response to prolonged activity withdrawal measured with calcium imaging is much stronger, while baseline activity is unchanged. Whole-cell recordings reveal an exaggerated increase in the frequency of miniature excitatory synaptic currents reflecting enhanced upregulation of recurrent excitatory synaptic transmission. Genetic analyses reveal that two of the factors, Hlf and Tef , are critical for constraining plasticity and for preventing life-threatening seizures. These data indicate that transcriptional activation is not only required for many forms of homeostatic plasticity but is also involved in restraint of the response to activity deprivation., Competing Interests: VV, DW, XZ, MS, JF, SV, RS, IC, RK, SO No competing interests declared, SN Reviewing editor, eLife, (© 2023, Valakh et al.)

Published

2023

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

Author

Liu B, Seay MJ, and Buonomano DV

Subjects

Mice, Animals, Neurons physiology, Pyramidal Cells physiology, Homeostasis physiology, Optogenetics, Neuronal Plasticity physiology

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., (Copyright © 2023 the authors.)

Published

2023

10. Paradoxical self-sustained dynamics emerge from orchestrated excitatory and inhibitory homeostatic plasticity rules.

Author

Soldado-Magraner S, Seay MJ, Laje R, and Buonomano DV

Subjects

Brain, Homeostasis, Learning, Models, Neurological, Nerve Net, Neuronal Plasticity

Abstract

Self-sustained neural activity maintained through local recurrent connections is of fundamental importance to cortical function. Converging theoretical and experimental evidence indicates that cortical circuits generating self-sustained dynamics operate in an inhibition-stabilized regime. Theoretical work has established that four sets of weights ( W E←E , W E←I , W I←E , and W I←I ) must obey specific relationships to produce inhibition-stabilized dynamics, but it is not known how the brain can appropriately set the values of all four weight classes in an unsupervised manner to be in the inhibition-stabilized regime. We prove that standard homeostatic plasticity rules are generally unable to generate inhibition-stabilized dynamics and that their instability is caused by a signature property of inhibition-stabilized networks: the paradoxical effect. In contrast, we show that a family of "cross-homeostatic" rules overcome the paradoxical effect and robustly lead to the emergence of stable dynamics. This work provides a model of how-beginning from a silent network-self-sustained inhibition-stabilized dynamics can emerge from learning rules governing all four synaptic weight classes in an orchestrated manner.

Published

2022

11. Synaptic tagging: homeostatic plasticity goes Hebbian.

Author

Colameo D and Schratt G

Subjects

Homeostasis physiology, Neurons physiology, Neuronal Plasticity physiology, Synapses physiology

Abstract

Distinct plasticity mechanisms enable neurons to effectively process information also when facing global perturbations in network activity. In this issue of The EMBO Journal, Dubes et al (2022) provide a molecular mechanism whereby individual synapses during periods of chronic inactivity are "tagged" for future strengthening. These results lend further support to the idea that local, nonmultiplicative mechanisms play an important role in homeostatic synaptic plasticity as has been demonstrated for Hebbian-like synaptic plasticity., (©2022 The Authors.)

Published

2022

12. Distinct molecular pathways govern presynaptic homeostatic plasticity.

Author

Nair AG, Muttathukunnel P, and Müller M

Subjects

Animals, Drosophila Proteins genetics, Drosophila melanogaster, Excitatory Postsynaptic Potentials, Neuromuscular Junction physiology, Receptors, Glutamate chemistry, Receptors, Glutamate genetics, Receptors, Glutamate metabolism, Signal Transduction, Drosophila Proteins metabolism, Homeostasis, Neuronal Plasticity, Neurotransmitter Agents metabolism, Presynaptic Terminals physiology, Synapses physiology, Synaptic Transmission

Abstract

Presynaptic homeostatic plasticity (PHP) stabilizes synaptic transmission by counteracting impaired neurotransmitter receptor function through neurotransmitter release potentiation. PHP is thought to be triggered by impaired receptor function and to involve a stereotypic signaling pathway. However, here we demonstrate that different receptor perturbations that similarly reduce synaptic transmission result in different responses at the Drosophila neuromuscular junction. While receptor inhibition by the glutamate receptor (GluR) antagonist γ-D-glutamylglycine (γDGG) is not compensated by PHP, the GluR inhibitors Philanthotoxin-433 (PhTx) and Gyki-53655 (Gyki) induce compensatory PHP. Intriguingly, PHP triggered by PhTx and Gyki involve separable signaling pathways, including inhibition of distinct GluR subtypes, differential modulation of the active-zone scaffold Bruchpilot, and short-term plasticity. Moreover, while PHP upon Gyki treatment does not require genes promoting PhTx-induced PHP, it involves presynaptic protein kinase D. Thus, synapses not only respond differentially to similar activity impairments, but achieve homeostatic compensation via distinct mechanisms, highlighting the diversity of homeostatic signaling., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

13. Developmental Regulation of Homeostatic Plasticity in Mouse Primary Visual Cortex.

Author

Wen W and Turrigiano GG

Subjects

Animals, Female, Male, Mice, Mice, Inbred C57BL, Homeostasis physiology, Neurogenesis physiology, Neuronal Plasticity physiology, Primary Visual Cortex physiology

Abstract

Homeostatic plasticity maintains network stability by adjusting excitation, inhibition, or the intrinsic excitability of neurons, but the developmental regulation and coordination of these distinct forms of homeostatic plasticity remains poorly understood. A major contributor to this information gap is the lack of a uniform paradigm for chronically manipulating activity at different developmental stages. To overcome this limitation, we used designer receptors exclusively activated by designer drugs (DREADDs) to directly suppress neuronal activity in layer2/3 (L2/3) of mouse primary visual cortex of either sex at two important developmental timepoints: the classic visual system critical period [CP; postnatal day 24 (P24) to P29], and adulthood (P45 to P55). We show that 24 h of DREADD-mediated activity suppression simultaneously induces excitatory synaptic scaling up and intrinsic homeostatic plasticity in L2/3 pyramidal neurons during the CP, consistent with previous observations using prolonged visual deprivation. Importantly, manipulations known to block these forms of homeostatic plasticity when induced pharmacologically or via visual deprivation also prevented DREADD-induced homeostatic plasticity. We next used the same paradigm to suppress activity in adult animals. Surprisingly, while excitatory synaptic scaling persisted into adulthood, intrinsic homeostatic plasticity was completely absent. Finally, we found that homeostatic changes in quantal inhibitory input onto L2/3 pyramidal neurons were absent during the CP but were present in adults. Thus, the same population of neurons can express distinct sets of homeostatic plasticity mechanisms at different development stages. Our findings suggest that homeostatic forms of plasticity can be recruited in a modular manner according to the evolving needs of a developing neural circuit. SIGNIFICANCE STATEMENT Developing brain circuits are subject to dramatic changes in inputs that could destabilize activity if left uncompensated. This compensation is achieved through a set of homeostatic plasticity mechanisms that provide slow, negative feedback adjustments to excitability. Given that circuits are subject to very different destabilizing forces during distinct developmental stages, the forms of homeostatic plasticity present in the network must be tuned to these evolving needs. Here we developed a method to induce comparable homeostatic compensation during distinct developmental windows and found that neurons in the juvenile and mature brain engage strikingly different forms of homeostatic plasticity. Thus, homeostatic mechanisms can be recruited in a modular manner according to the developmental needs of the circuit., (Copyright © 2021 the authors.)

Published

2021

14. Mechanisms of Plasticity in Subcortical Visual Areas.

Author

Duménieu M, Marquèze-Pouey B, Russier M, and Debanne D

Subjects

Animals, Geniculate Bodies physiology, Humans, Neuronal Plasticity genetics, Retina physiology, Synapses physiology, Cerebral Cortex physiology, Neuronal Plasticity physiology, Visual Pathways physiology

Abstract

Visual plasticity is classically considered to occur essentially in the primary and secondary cortical areas. Subcortical visual areas such as the dorsal lateral geniculate nucleus (dLGN) or the superior colliculus (SC) have long been held as basic structures responsible for a stable and defined function. In this model, the dLGN was considered as a relay of visual information travelling from the retina to cortical areas and the SC as a sensory integrator orienting body movements towards visual targets. However, recent findings suggest that both dLGN and SC neurons express functional plasticity, adding unexplored layers of complexity to their previously attributed functions. The existence of neuronal plasticity at the level of visual subcortical areas redefines our approach of the visual system. The aim of this paper is therefore to review the cellular and molecular mechanisms for activity-dependent plasticity of both synaptic transmission and cellular properties in subcortical visual areas.

Published

2021

15. Pervasive compartment-specific regulation of gene expression during homeostatic synaptic scaling.

Author

Colameo D, Rajman M, Soutschek M, Bicker S, von Ziegler L, Bohacek J, Winterer J, Germain PL, Dieterich C, and Schratt G

Subjects

Animals, Gene Expression, Gene Expression Regulation, Neurons, Rats, Neuronal Plasticity genetics, Synapses

Abstract

Synaptic scaling is a form of homeostatic plasticity which allows neurons to adjust their action potential firing rate in response to chronic alterations in neural activity. Synaptic scaling requires profound changes in gene expression, but the relative contribution of local and cell-wide mechanisms is controversial. Here we perform a comprehensive multi-omics characterization of the somatic and process compartments of primary rat hippocampal neurons during synaptic scaling. We uncover both highly compartment-specific and correlating changes in the neuronal transcriptome and proteome. Whereas downregulation of crucial regulators of neuronal excitability occurs primarily in the somatic compartment, structural components of excitatory postsynapses are mostly downregulated in processes. Local inhibition of protein synthesis in processes during scaling is confirmed for candidate synaptic proteins. Motif analysis further suggests an important role for trans-acting post-transcriptional regulators, including RNA-binding proteins and microRNAs, in the local regulation of the corresponding mRNAs. Altogether, our study indicates that, during synaptic scaling, compartmentalized gene expression changes might co-exist with neuron-wide mechanisms to allow synaptic computation and homeostasis., (© 2021 The Authors. Published under the terms of the CC BY 4.0 license.)

Published

2021

16. Mechanisms regulating input-output function and plasticity of neurons in the absence of FMRP.

Author

Booker SA and Kind PC

Subjects

Animals, Fragile X Syndrome pathology, Humans, Neurons pathology, Fragile X Mental Retardation Protein genetics, Fragile X Syndrome genetics, Neuronal Plasticity genetics, Neurons physiology

Abstract

The function of brain circuits relies on high-fidelity information transfer within neurons. Synaptic inputs arrive primarily at dendrites, where they undergo integration and summation throughout the somatodendritic domain, ultimately leading to the generation of precise patterns of action potentials. Emerging evidence suggests that the ability of neurons to transfer synaptic information and modulate their output is impaired in a number of neurodevelopmental disorders including Fragile X Syndrome. In this review we summarise recent findings that have revealed the pathophysiological and plasticity mechanisms that alter the ability of neurons in sensory and limbic circuits to reliably code information in the absence of FMRP. We examine which aspects of this transform may result directly from the loss of FMRP and those that a result from compensatory or homeostatic alterations to neuronal function. Dissection of the mechanisms leading to altered input-output function of neurons in the absence of FMRP and their effects on regulating neuronal plasticity throughout development could have important implications for potential therapies for Fragile X Syndrome, including directing the timing and duration of different treatment options., (Copyright © 2021. Published by Elsevier Inc.)

Published

2021

17. Amyloid-Beta Mediates Homeostatic Synaptic Plasticity.

Author

Galanis C, Fellenz M, Becker D, Bold C, Lichtenthaler SF, Müller UC, Deller T, and Vlachos A

Subjects

Animals, Female, Homeostasis physiology, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Amyloid beta-Protein Precursor metabolism, Brain physiology, Neuronal Plasticity physiology

Abstract

The physiological role of the amyloid-precursor protein (APP) is insufficiently understood. Recent work has implicated APP in the regulation of synaptic plasticity. Substantial evidence exists for a role of APP and its secreted ectodomain APPsα in Hebbian plasticity. Here, we addressed the relevance of APP in homeostatic synaptic plasticity using organotypic tissue cultures prepared from APP mice of both sexes. In the absence of APP, dentate granule cells failed to strengthen their excitatory synapses homeostatically. Homeostatic plasticity is rescued by amyloid-β and not by APPsα, and it is neither observed in -/- mice of both sexes. In the absence of APP, dentate granule cells failed to strengthen their excitatory synapses homeostatically. Homeostatic plasticity is rescued by amyloid-β and not by APPsα, and it is neither observed in APP +/+ tissue treated with β- or γ-secretase inhibitors nor in synaptopodin-deficient cultures lacking the Ca 2+ -dependent molecular machinery of the spine apparatus. Together, these results suggest a role of APP processing via the amyloidogenic pathway in homeostatic synaptic plasticity, representing a function of relevance for brain physiology as well as for brain states associated with increased amyloid-β levels., Competing Interests: The authors declare no competing financial interests., (Copyright © 2021 Galanis et al.)

Published

2021

18. Changes in Presynaptic Gene Expression during Homeostatic Compensation at a Central Synapse.

Author

Harrell ER, Pimentel D, and Miesenböck G

Subjects

Animals, Animals, Genetically Modified, Arthropod Antennae innervation, Arthropod Antennae metabolism, Drosophila, Female, Gene Expression, Homeostasis physiology, Neuronal Plasticity physiology, Presynaptic Terminals metabolism, Synapses genetics, Synapses metabolism

Abstract

Homeostatic matching of pre- and postsynaptic function has been observed in many species and neural structures, but whether transcriptional changes contribute to this form of trans-synaptic coordination remains unknown. To identify genes whose expression is altered in presynaptic neurons as a result of perturbing postsynaptic excitability, we applied a transcriptomics-friendly, temperature-inducible Kir2.1-based activity clamp at the first synaptic relay of the Drosophila olfactory system, a central synapse known to exhibit trans-synaptic homeostatic matching. Twelve hours after adult-onset suppression of activity in postsynaptic antennal lobe projection neurons of males and females, we detected changes in the expression of many genes in the third antennal segment, which houses the somata of presynaptic olfactory receptor neurons. These changes affected genes with roles in synaptic vesicle release and synaptic remodeling, including several implicated in homeostatic plasticity at the neuromuscular junction. At 48 h and beyond, the transcriptional landscape tilted toward protein synthesis, folding, and degradation; energy metabolism; and cellular stress defenses, indicating that the system had been pushed to its homeostatic limits. Our analysis suggests that similar homeostatic machinery operates at peripheral and central synapses and identifies many of its components. The presynaptic transcriptional response to genetically targeted postsynaptic perturbations could be exploited for the construction of novel connectivity tracing tools. SIGNIFICANCE STATEMENT Homeostatic feedback mechanisms adjust intrinsic and synaptic properties of neurons to keep their average activity levels constant. We show that, at a central synapse in the fruit fly brain, these mechanisms include changes in presynaptic gene expression that are instructed by an abrupt loss of postsynaptic excitability. The trans-synaptically regulated genes have roles in synaptic vesicle release and synapse remodeling; protein synthesis, folding, and degradation; and energy metabolism. Our study establishes a role for transcriptional changes in homeostatic synaptic plasticity, points to mechanistic commonalities between peripheral and central synapses, and potentially opens new opportunities for the development of connectivity-based gene expression systems., (Copyright © 2021 Harrell et al.)

Published

2021

19. Intrinsic plasticity and birdsong learning.

Author

Daou A and Margoliash D

Subjects

Action Potentials, Animals, Cell Membrane, High Vocal Center physiology, Homeostasis, Brain physiology, Finches, Music, Neural Pathways physiology, Neuronal Plasticity physiology

Abstract

Although information processing and storage in the brain is thought to be primarily orchestrated by synaptic plasticity, other neural mechanisms such as intrinsic plasticity are available. While a number of recent studies have described the plasticity of intrinsic excitability in several types of neurons, the significance of non-synaptic mechanisms in memory and learning remains elusive. After reviewing plasticity of intrinsic excitation in relation to learning and homeostatic mechanisms, we focus on the intrinsic properties of a class of basal-ganglia projecting song system neurons in zebra finch, how these related to each bird's unique learned song, how these properties change over development, and how they are maintained dynamically to rapidly change in response to auditory feedback perturbations. We place these results in the broader theme of learning and changes in intrinsic properties, emphasizing the computational implications of this form of plasticity, which are distinct from synaptic plasticity. The results suggest that exploring reciprocal interactions between intrinsic and network properties will be a fruitful avenue for understanding mechanisms of birdsong learning., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

20. EphrinB2 and GRIP1 stabilize mushroom spines during denervation-induced homeostatic plasticity.

Author

Bissen D, Kracht MK, Foss F, Hofmann J, and Acker-Palmer A

Subjects

Animals, Cell Membrane metabolism, Denervation, Mice, Inbred C57BL, Receptor, EphB4 metabolism, Receptors, AMPA metabolism, Mice, Adaptor Proteins, Signal Transducing metabolism, Dendritic Spines metabolism, Ephrin-B2 metabolism, Homeostasis, Nerve Tissue Proteins metabolism, Neuronal Plasticity physiology

Abstract

Despite decades of work, much remains elusive about molecular events at the interplay between physiological and structural changes underlying neuronal plasticity. Here, we combined repetitive live imaging and expansion microscopy in organotypic brain slice cultures to quantitatively characterize the dynamic changes of the intracellular versus surface pools of GluA2-containing α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors (AMPARs) across the different dendritic spine types and the shaft during hippocampal homeostatic plasticity. Mechanistically, we identify ephrinB2 and glutamate receptor interacting protein (GRIP) 1 as mediating AMPAR relocation to the mushroom spine surface following lesion-induced denervation. Moreover, stimulation with the ephrinB2 specific receptor EphB4 not only prevents the lesion-induced disappearance of mushroom spines but is also sufficient to shift AMPARs to the surface and rescue spine recovery in a GRIP1 dominant-negative background. Thus, our results unravel a crucial role for ephrinB2 during homeostatic plasticity and identify a potential pharmacological target to improve dendritic spine plasticity upon injury., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

21. Kainate Receptors, Homeostatic Gatekeepers of Synaptic Plasticity.

Author

Valbuena S and Lerma J

Subjects

Homeostasis, Long-Term Potentiation, Synapses metabolism, Synaptic Transmission, Neuronal Plasticity, Receptors, Kainic Acid metabolism

Abstract

Extensive research over the past decades has characterized multiple forms of synaptic plasticity, identifying them as key processes that allow the brain to operate in a dynamic manner. Within the wide variety of synaptic plasticity modulators, kainate receptors are receiving increasing attention, given their diversity of signaling mechanisms and cellular expression profile. Here, we summarize the experimental evidence about the involvement of kainate receptor signaling in the regulation of short- and long-term plasticity, from the perspective of the regulation of neurotransmitter release. In light of this evidence, we propose that kainate receptors may be considered homeostatic modulators of neurotransmitter release, able to bidirectionally regulate plasticity depending on the functional history of the synapse., Competing Interests: Declaration of Competing Interest Since one of the authors is the Editor of the Journal, we declare that the peer review of this manuscript has been handled independently and that the Editor-in-Chief has not been involved in editorial decisions concerning this paper., (Copyright © 2019 IBRO. Published by Elsevier Ltd. All rights reserved.)

Published

2021

22. Metabotropic Modulation of Potassium Channels During Synaptic Plasticity.

Author

Fernández-Fernández D and Lamas JA

Subjects

Long-Term Potentiation, Synapses, Synaptic Transmission, Neuronal Plasticity, Potassium Channels

Abstract

Besides their primary function mediating the repolarization phase of action potentials, potassium channels exquisitely and ubiquitously regulate the resting membrane potential of neurons and therefore have a key role establishing their intrinsic excitability. This group of proteins is composed of a very diverse collection of voltage-dependent and -independent ion channels, whose specific distribution is finely tuned at the level of the synapse. Both at the presynaptic and postsynaptic membranes, different types of potassium channels are subjected to modulation by second messenger signaling cascades triggered by metabotropic receptors, which in this way serve as a link between neurotransmitter actions and changes in the neuron membrane excitability. On the one hand, by regulating the resting membrane potential of the postsynaptic membrane, potassium channels appear to be critical towards setting the threshold for the induction of long-term potentiation and depression. On the other hand, these channels maintain the presynaptic membrane potential under control, therefore influencing the probability of neurotransmitter release underlying different forms of short-term plasticity. In the present review, we examine in detail the role of metabotropic receptors translating their activation by different neurotransmitters into a final effect modulating several types of potassium channels. Furthermore, we evaluate the consequences that this interplay has on the induction and maintenance of different forms of synaptic plasticity., (Copyright © 2020 IBRO. Published by Elsevier Ltd. All rights reserved.)

Published

2021

23. The role of astrocyte-mediated plasticity in neural circuit development and function.

Author

Perez-Catalan NA, Doe CQ, and Ackerman SD

Subjects

Animals, Humans, Neurogenesis, Neurons, Synapses, Astrocytes, Neuronal Plasticity

Abstract

Neuronal networks are capable of undergoing rapid structural and functional changes called plasticity, which are essential for shaping circuit function during nervous system development. These changes range from short-term modifications on the order of milliseconds, to long-term rearrangement of neural architecture that could last for the lifetime of the organism. Neural plasticity is most prominent during development, yet also plays a critical role during memory formation, behavior, and disease. Therefore, it is essential to define and characterize the mechanisms underlying the onset, duration, and form of plasticity. Astrocytes, the most numerous glial cell type in the human nervous system, are integral elements of synapses and are components of a glial network that can coordinate neural activity at a circuit-wide level. Moreover, their arrival to the CNS during late embryogenesis correlates to the onset of sensory-evoked activity, making them an interesting target for circuit plasticity studies. Technological advancements in the last decade have uncovered astrocytes as prominent regulators of circuit assembly and function. Here, we provide a brief historical perspective on our understanding of astrocytes in the nervous system, and review the latest advances on the role of astroglia in regulating circuit plasticity and function during nervous system development and homeostasis.

Published

2021

24. Homeostatic plasticity in the retina is associated with maintenance of night vision during retinal degenerative disease.

Author

Leinonen H, Pham NC, Boyd T, Santoso J, Palczewski K, and Vinberg F

Subjects

Animals, Cells, Cultured, Female, Male, Mice, Mice, Inbred C57BL, Mutation genetics, Retina cytology, Retina metabolism, Retinal Bipolar Cells cytology, Retinal Bipolar Cells metabolism, Retinitis Pigmentosa metabolism, Rhodopsin genetics, Rhodopsin metabolism, Transcriptome genetics, Neuronal Plasticity physiology, Night Vision physiology, Retina physiology, Retinitis Pigmentosa physiopathology

Abstract

Neuronal plasticity of the inner retina has been observed in response to photoreceptor degeneration. Typically, this phenomenon has been considered maladaptive and may preclude vision restoration in the blind. However, several recent studies utilizing triggered photoreceptor ablation have shown adaptive responses in bipolar cells expected to support normal vision. Whether such homeostatic plasticity occurs during progressive photoreceptor degenerative disease to help maintain normal visual behavior is unknown. We addressed this issue in an established mouse model of Retinitis Pigmentosa caused by the P23H mutation in rhodopsin. We show robust modulation of the retinal transcriptomic network, reminiscent of the neurodevelopmental state, and potentiation of rod - rod bipolar cell signaling following rod photoreceptor degeneration. Additionally, we found highly sensitive night vision in P23H mice even when more than half of the rod photoreceptors were lost. These results suggest retinal adaptation leading to persistent visual function during photoreceptor degenerative disease., Competing Interests: HL, NP, TB, JS, KP, FV No competing interests declared, (© 2020, Leinonen et al.)

Published

2020

25. Presynaptic Homeostasis Opposes Disease Progression in Mouse Models of ALS-Like Degeneration: Evidence for Homeostatic Neuroprotection.

Author

Orr BO, Hauswirth AG, Celona B, Fetter RD, Zunino G, Kvon EZ, Zhu Y, Pennacchio LA, Black BL, and Davis GW

Subjects

Amyotrophic Lateral Sclerosis metabolism, Amyotrophic Lateral Sclerosis pathology, Animals, Disease Models, Animal, Disease Progression, Drosophila melanogaster, Mice, Mice, Knockout, Neuromuscular Junction metabolism, Epithelial Sodium Channels metabolism, Homeostasis physiology, Neuronal Plasticity physiology, Neuroprotection physiology, Presynaptic Terminals metabolism

Abstract

Progressive synapse loss is an inevitable and insidious part of age-related neurodegenerative disease. Typically, synapse loss precedes symptoms of cognitive and motor decline. This suggests the existence of compensatory mechanisms that can temporarily counteract the effects of ongoing neurodegeneration. Here, we demonstrate that presynaptic homeostatic plasticity (PHP) is induced at degenerating neuromuscular junctions, mediated by an evolutionarily conserved activity of presynaptic ENaC channels in both Drosophila and mouse. To assess the consequence of eliminating PHP in a mouse model of ALS-like degeneration, we generated a motoneuron-specific deletion of Scnn1a, encoding the ENaC channel alpha subunit. We show that Scnn1a is essential for PHP without adversely affecting baseline neural function or lifespan. However, Scnn1a knockout in a degeneration-causing mutant background accelerated motoneuron loss and disease progression to twice the rate observed in littermate controls with intact PHP. We propose a model of neuroprotective homeostatic plasticity, extending organismal lifespan and health span., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

26. Homeostatic plasticity fails at the intersection of autism-gene mutations and a novel class of common genetic modifiers.

Author

Genç Ö, An JY, Fetter RD, Kulik Y, Zunino G, Sanders SJ, and Davis GW

Subjects

Animals, Drosophila Proteins genetics, Drosophila melanogaster genetics, Genes genetics, Genetic Predisposition to Disease genetics, Homeostasis genetics, Humans, Mutation genetics, Risk Factors, Synaptic Transmission genetics, Autistic Disorder genetics, Neuronal Plasticity genetics

Abstract

We identify a set of common phenotypic modifiers that interact with five independent autism gene orthologs ( RIMS1 , CHD8 , CHD2 , WDFY3 , ASH1L ) causing a common failure of presynaptic homeostatic plasticity (PHP) in Drosophila . Heterozygous null mutations in each autism gene are demonstrated to have normal baseline neurotransmission and PHP. However, PHP is sensitized and rendered prone to failure. A subsequent electrophysiology-based genetic screen identifies the first known heterozygous mutations that commonly genetically interact with multiple ASD gene orthologs, causing PHP to fail. Two phenotypic modifiers identified in the screen, PDPK1 and PPP2R5D, are characterized. Finally, transcriptomic, ultrastructural and electrophysiological analyses define one mechanism by which PHP fails; an unexpected, maladaptive up-regulation of CREG , a conserved, neuronally expressed, stress response gene and a novel repressor of PHP. Thus, we define a novel genetic landscape by which diverse, unrelated autism risk genes may converge to commonly affect the robustness of synaptic transmission., Competing Interests: ÖG, JA, RF, YK, GZ, SS No competing interests declared, GD Reviewing editor, eLife, (© 2020, Genç et al.)

Published

2020

27. Autism-Associated Shank3 Is Essential for Homeostatic Compensation in Rodent V1.

Author

Tatavarty V, Torrado Pacheco A, Groves Kuhnle C, Lin H, Koundinya P, Miska NJ, Hengen KB, Wagner FF, Van Hooser SD, and Turrigiano GG

Subjects

Animals, Antimanic Agents pharmacology, Autistic Disorder genetics, Behavior, Animal drug effects, Excitatory Postsynaptic Potentials drug effects, Excitatory Postsynaptic Potentials genetics, Gene Knockdown Techniques, Glycogen Synthase Kinase 3 antagonists & inhibitors, Grooming drug effects, Homeostasis drug effects, Lithium Compounds pharmacology, Mice, Mice, Knockout, Microfilament Proteins, Nerve Tissue Proteins drug effects, Neural Pathways, Neuronal Plasticity drug effects, Neurons metabolism, Rats, Sodium Channel Blockers pharmacology, Tetrodotoxin pharmacology, Visual Cortex cytology, Visual Cortex metabolism, Homeostasis genetics, Nerve Tissue Proteins genetics, Neuronal Plasticity genetics, Neurons drug effects, Visual Cortex drug effects

Abstract

Mutations in Shank3 are strongly associated with autism spectrum disorders and neural circuit changes in several brain areas, but the cellular mechanisms that underlie these defects are not understood. Homeostatic forms of plasticity allow central circuits to maintain stable function during experience-dependent development, leading us to ask whether loss of Shank3 might impair homeostatic plasticity and circuit-level compensation to perturbations. We found that Shank3 loss in vitro abolished synaptic scaling and intrinsic homeostatic plasticity, deficits that could be rescued by treatment with lithium. Further, Shank3 knockout severely compromised the in vivo ability of visual cortical circuits to recover from perturbations to sensory drive. Finally, lithium treatment ameliorated a repetitive self-grooming phenotype in Shank3 knockout mice. These findings demonstrate that Shank3 loss severely impairs the ability of central circuits to harness homeostatic mechanisms to compensate for perturbations in drive, which, in turn, may render them more vulnerable to such perturbations., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

28. M-Current Inhibition in Hippocampal Excitatory Neurons Triggers Intrinsic and Synaptic Homeostatic Responses at Different Temporal Scales.

Author

Lezmy J, Gelman H, Katsenelson M, Styr B, Tikochinsky E, Lipinsky M, Peretz A, Slutsky I, and Attali B

Subjects

Animals, Female, Male, Mice, Mice, Inbred BALB C, Potassium Channels metabolism, Hippocampus physiology, Homeostasis physiology, Neuronal Plasticity physiology, Pyramidal Cells physiology, Synaptic Transmission physiology

Abstract

Persistent alterations in neuronal activity elicit homeostatic plastic changes in synaptic transmission and/or intrinsic excitability. However, it is unknown whether these homeostatic processes operate in concert or at different temporal scales to maintain network activity around a set-point value. Here we show that chronic neuronal hyperactivity, induced by M-channel inhibition, triggered intrinsic and synaptic homeostatic plasticity at different timescales in cultured hippocampal pyramidal neurons from mice of either sex. Homeostatic changes of intrinsic excitability occurred at a fast timescale (1-4 h) and depended on ongoing spiking activity. This fast intrinsic adaptation included plastic changes in the threshold current and a distal relocation of FGF14, a protein physically bridging Na v 1.6 and K v 7.2 channels along the axon initial segment. In contrast, synaptic adaptations occurred at a slower timescale (∼2 d) and involved decreases in miniature EPSC amplitude. To examine how these temporally distinct homeostatic responses influenced hippocampal network activity, we quantified the rate of spontaneous spiking measured by multielectrode arrays at extended timescales. M-Channel blockade triggered slow homeostatic renormalization of the mean firing rate (MFR), concomitantly accompanied by a slow synaptic adaptation. Thus, the fast intrinsic adaptation of excitatory neurons is not sufficient to account for the homeostatic normalization of the MFR. In striking contrast, homeostatic adaptations of intrinsic excitability and spontaneous MFR failed in hippocampal GABAergic inhibitory neurons, which remained hyperexcitable following chronic M-channel blockage. Our results indicate that a single perturbation such as M-channel inhibition triggers multiple homeostatic mechanisms that operate at different timescales to maintain network mean firing rate. SIGNIFICANCE STATEMENT Persistent alterations in synaptic input elicit homeostatic plastic changes in neuronal activity. Here we show that chronic neuronal hyperexcitability, induced by M-type potassium channel inhibition, triggered intrinsic and synaptic homeostatic plasticity at different timescales in hippocampal excitatory neurons. The data indicate that the fast adaptation of intrinsic excitability depends on ongoing spiking activity but is not sufficient to provide homeostasis of the mean firing rate. Our results show that a single perturbation such as M-channel inhibition can trigger multiple homeostatic processes that operate at different timescales to maintain network mean firing rate., (Copyright © 2020 the authors.)

Published

2020

29. Differential Scaling of Synaptic Molecules within Functional Zones of an Excitatory Synapse during Homeostatic Plasticity.

Author

Venkatesan S, Subramaniam S, Rajeev P, Chopra Y, Jose M, and Nair D

Subjects

Animals, Homeostasis, Mice, Nerve Tissue Proteins genetics, Neurons, Rats, Receptors, AMPA, Neuronal Plasticity, Synapses

Abstract

Homeostatic scaling is a form of synaptic plasticity where individual synapses scale their strengths to compensate for global suppression or elevation of neuronal activity. This process can be studied by measuring miniature EPSP (mEPSP) amplitudes and frequencies following the regulation of activity in neuronal cultures. Here, we demonstrate a quantitative approach to characterize multiplicative synaptic scaling using immunolabelling of hippocampal neuronal cultures treated with tetrodotoxin (TTX) or bicuculline to extract scaling factors for various synaptic proteins. This approach allowed us to directly examine the scaling of presynaptic and postsynaptic scaffolding molecules along with neurotransmitter receptors in primary cultures from mouse and rat hippocampal neurons. We show robust multiplicative scaling of synaptic scaffolding molecules namely, Shank2, PSD95, Bassoon, and AMPA receptor subunits and quantify their scaling factors. We use super-resolution microscopy to calculate scaling factors of surface expressed GluA2 within functional zones of the synapse and show that there is differential and correlated scaling of GluA2 levels within the spine, the postsynaptic density (PSD), and the perisynaptic regions. Our method opens a novel paradigm to quantify relative molecular changes of synaptic proteins within distinct subsynaptic compartments from a large number of synapses in response to alteration of neuronal activity, providing anatomic insights into the intricacies of variability in strength of individual synapses., (Copyright © 2020 Venkatesan et al.)

Published

2020

30. No neuron is an island: Homeostatic plasticity and over-constraint in a neural circuit.

Author

Voicu H and Mauk MD

Subjects

Animals, Computer Simulation, Humans, Synapses physiology, Cerebellum physiology, Homeostasis, Models, Neurological, Neuronal Plasticity, Purkinje Cells physiology

Abstract

To support computation the activity of neurons must vary within a useful range, which highlights one potential value of homeostatic plasticity. The interconnectedness of the brain, however, introduces the possibility that combinations of homeostatic mechanisms can produce over-constraint in which not all set points can be satisfied. We use a simulation of the cerebellum to investigate the potential for such conflict and its consequences. In this instance the conflict produces perpetual drift and eventual saturation of synaptic weights. We show that these problems can be resolved for this network by a particular combination of sites and rules for plasticity. We also show that simulations that implement these rules for homeostatic plasticity are more resistant to forgetting. These results illustrate the general principle that homeostatic plasticity within a system must not set up conflicts in which mutually exclusive set points exist and that one consequence can be perpetual induction of plasticity., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2020

31. Tyrosine phosphorylation of the AMPA receptor subunit GluA2 gates homeostatic synaptic plasticity.

Author

Yong AJH, Tan HL, Zhu Q, Bygrave AM, Johnson RC, and Huganir RL

Subjects

Adaptor Proteins, Signal Transducing, Animals, Male, Mice, Mice, Knockout, Nerve Tissue Proteins metabolism, Phosphorylation, Protein Transport, Synapses metabolism, alpha-Amino-3-hydroxy-5-methyl-4-isoxazolepropionic Acid metabolism, Homeostasis physiology, Neuronal Plasticity physiology, Receptors, AMPA metabolism, Tyrosine metabolism

Abstract

Hebbian plasticity, comprised of long-term potentiation (LTP) and depression (LTD), allows neurons to encode and respond to specific stimuli; while homeostatic synaptic scaling is a counterbalancing mechanism that enables the maintenance of stable neural circuits. Both types of synaptic plasticity involve the control of postsynaptic α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor (AMPAR) abundance, which is modulated by AMPAR phosphorylation. To address the necessity of GluA2 phospho-Y876 in synaptic plasticity, we generated phospho-deficient GluA2 Y876F knock-in mice. We show that, while GluA2 phospho-Y876 is not necessary for Hebbian plasticity, it is essential for both in vivo and in vitro homeostatic upscaling. Bidirectional changes in GluA2 phospho-Y876 were observed during homeostatic scaling, with a decrease during downscaling and an increase during upscaling. GluA2 phospho-Y876 is necessary for synaptic accumulation of glutamate receptor interacting protein 1 (GRIP1), a crucial scaffold protein that delivers AMPARs to synapses, during upscaling. Furthermore, increased phosphorylation at GluA2 Y876 increases GluA2 binding to GRIP1. These results demonstrate that AMPAR trafficking during homeostatic upscaling can be gated by a single phosphorylation site on the GluA2 subunit., Competing Interests: The authors declare no competing interest.

Published

2020

32. Molecular mechanisms of homeostatic plasticity in central pattern generator networks.

Author

Northcutt AJ and Schulz DJ

Subjects

Animals, Central Pattern Generators metabolism, Ion Channels metabolism, Central Pattern Generators physiology, Homeostasis physiology, Ion Channels physiology, Neuronal Plasticity physiology, Signal Transduction physiology

Abstract

Central pattern generator (CPG) networks rely on a balance of intrinsic and network properties to produce reliable, repeatable activity patterns. This balance is maintained by homeostatic plasticity where alterations in neuronal properties dynamically maintain appropriate neural output in the face of changing environmental conditions and perturbations. However, it remains unclear just how these neurons and networks can both monitor their ongoing activity and use this information to elicit homeostatic physiological responses to ensure robustness of output over time. Evidence exists that CPG networks use a mixed strategy of activity-dependent, activity-independent, modulator-dependent, and synaptically regulated homeostatic plasticity to achieve this critical stability. In this review, we focus on some of the current understanding of the molecular pathways and mechanisms responsible for this homeostatic plasticity in the context of central pattern generator function, with a special emphasis on some of the smaller invertebrate networks that have allowed for extensive cellular-level analyses that have brought recent insights to these questions., (© 2019 Wiley Periodicals, Inc.)

Published

2020

33. Homeostatic control of Drosophila neuromuscular junction function.

Author

Frank CA, James TD, and Müller M

Subjects

Animals, Drosophila, Homeostasis physiology, Neuromuscular Junction physiology, Neuronal Plasticity physiology, Synaptic Transmission physiology

Abstract

The ability to adapt to changing internal and external conditions is a key feature of biological systems. Homeostasis refers to a regulatory process that stabilizes dynamic systems to counteract perturbations. In the nervous system, homeostatic mechanisms control neuronal excitability, neurotransmitter release, neurotransmitter receptors, and neural circuit function. The neuromuscular junction (NMJ) of Drosophila melanogaster has provided a wealth of molecular information about how synapses implement homeostatic forms of synaptic plasticity, with a focus on the transsynaptic, homeostatic modulation of neurotransmitter release. This review examines some of the recent findings from the Drosophila NMJ and highlights questions the field will ponder in coming years., (© 2019 The Authors. Synapse published by Wiley Periodicals, Inc.)

Published

2020

34. Cortical Circuit Dynamics Are Homeostatically Tuned to Criticality In Vivo.

Author

Ma Z, Turrigiano GG, Wessel R, and Hengen KB

Subjects

Animals, Neural Inhibition physiology, Rats, Homeostasis physiology, Models, Neurological, Nerve Net physiology, Neuronal Plasticity physiology, Visual Cortex physiology

Abstract

Homeostatic mechanisms stabilize neuronal activity in vivo, but whether this process gives rise to balanced network dynamics is unknown. Here, we continuously monitored the statistics of network spiking in visual cortical circuits in freely behaving rats for 9 days. Under control conditions in light and dark, networks were robustly organized around criticality, a regime that maximizes information capacity and transmission. When input was perturbed by visual deprivation, network criticality was severely disrupted and subsequently restored to criticality over 48 h. Unexpectedly, the recovery of excitatory dynamics preceded homeostatic plasticity of firing rates by >30 h. We utilized model investigations to manipulate firing rate homeostasis in a cell-type-specific manner at the onset of visual deprivation. Our results suggest that criticality in excitatory networks is established by inhibitory plasticity and architecture. These data establish that criticality is consistent with a homeostatic set point for visual cortical dynamics and suggest a key role for homeostatic regulation of inhibition., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

35. Intrinsic temporal tuning of neurons in the optic tectum is shaped by multisensory experience.

Author

Busch SE and Khakhalin AS

Subjects

Animals, Electrophysiological Phenomena, Larva physiology, Nerve Net cytology, Nerve Net growth & development, Patch-Clamp Techniques, Superior Colliculi cytology, Superior Colliculi growth & development, Xenopus physiology, Homeostasis physiology, Nerve Net physiology, Neuronal Plasticity physiology, Sensation physiology, Superior Colliculi physiology

Abstract

For a biological neural network to be functional, its neurons need to be connected with synapses of appropriate strength, and each neuron needs to appropriately respond to its synaptic inputs. This second aspect of network tuning is maintained by intrinsic plasticity; yet it is often considered secondary to changes in connectivity and mostly limited to adjustments of overall excitability of each neuron. Here we argue that even nonoscillatory neurons can be tuned to inputs of different temporal dynamics and that they can routinely adjust this tuning to match the statistics of their synaptic activation. Using the dynamic clamp technique, we show that, in the tectum of Xenopus tadpole, neurons become selective for faster inputs when animals are exposed to fast visual stimuli but remain responsive to longer inputs in animals exposed to slower, looming, or multisensory stimulation. We also report a homeostatic cotuning between synaptic and intrinsic temporal properties of individual tectal cells. These results expand our understanding of intrinsic plasticity in the brain and suggest that there may exist an additional dimension of network tuning that has been so far overlooked. NEW & NOTEWORTHY We use dynamic clamp to show that individual neurons in the tectum of Xenopus tadpoles are selectively tuned to either shorter (more synchronous) or longer (less synchronous) synaptic inputs. We also demonstrate that this intrinsic temporal tuning is strongly shaped by sensory experiences. This new phenomenon, which is likely to be mediated by changes in sodium channel inactivation, is bound to have important consequences for signal processing and the development of local recurrent connections.

Published

2019

36. Competing mechanisms of plasticity impair compensatory responses to repetitive apnoea.

Author

Fields DP, Braegelmann KM, Meza AL, Mickelson CR, Gumnit MG, and Baker TL

Subjects

Animals, Homeostasis, Hypoxia metabolism, Male, Oxygen metabolism, Phrenic Nerve metabolism, Phrenic Nerve physiopathology, Rats, Rats, Sprague-Dawley, Receptors, N-Methyl-D-Aspartate metabolism, Sleep Apnea Syndromes metabolism, Hypoxia physiopathology, Neuronal Plasticity, Sleep Apnea Syndromes physiopathology

Abstract

Key Points: Intermittent reductions in respiratory neural activity, a characteristic of many ventilatory disorders, leads to inadequate ventilation and arterial hypoxia. Both intermittent reductions in respiratory neural activity and intermittent hypoxia trigger compensatory enhancements in inspiratory output when experienced separately, forms of plasticity called inactivity-induced inspiratory motor facilitation (iMF) and long-term facilitation (LTF), respectively. Reductions in respiratory neural activity that lead to moderate, but not mild, arterial hypoxia occludes plasticity expression, indicating that concurrent induction of iMF and LTF impairs plasticity through cross-talk inhibition of their respective signalling pathways. Moderate hypoxia undermines iMF by enhancing NR2B-containing NMDA receptor signalling, which can be rescued by exogenous retinoic acid, a molecule necessary for iMF. These data suggest that in ventilatory disorders characterized by reduced inspiratory motor output, such as sleep apnoea, endogenous mechanisms of compensatory plasticity may be impaired, and that exogenously activating respiratory plasticity may be a novel strategy to improve breathing., Abstract: Many forms of sleep apnoea are characterized by recurrent reductions in respiratory neural activity, which leads to inadequate ventilation and arterial hypoxia. Both recurrent reductions in respiratory neural activity and hypoxia activate mechanisms of compensatory plasticity that augment inspiratory output and lower the threshold for apnoea, inactivity-induced inspiratory motor facilitation (iMF) and long-term facilitation (LTF), respectively. However, despite frequent concurrence of reduced respiratory neural activity and hypoxia, mechanisms that induce and regulate iMF and LTF have only been studied separately. Here, we demonstrate that recurrent reductions in respiratory neural activity ('neural apnoea') accompanied by cessations in ventilation that result in moderate (but not mild) hypoxaemia do not elicit increased inspiratory output, suggesting that concurrent induction of iMF and LTF occludes plasticity. A key role for NMDA receptor activation in impairing plasticity following concurrent neural apnoea and hypoxia is indicated since recurrent hypoxic neural apnoeas triggered increased phrenic inspiratory output in rats in which spinal NR2B-containing NMDA receptors were inhibited. Spinal application of retinoic acid, a key molecule necessary for iMF, bypasses NMDA receptor-mediated constraints, thereby rescuing plasticity following hypoxic neural apnoeas. These studies raise the intriguing possibility that endogenous mechanisms of compensatory plasticity may be impaired in some individuals with sleep apnoea, and that exogenously activating pathways giving rise to respiratory plasticity may be a novel pharmacological strategy to improve breathing., (© 2019 The Authors. The Journal of Physiology © 2019 The Physiological Society.)

Published

2019

37. Synergistic Transcriptional Changes in AMPA and GABA A Receptor Genes Support Compensatory Plasticity Following Unilateral Hearing Loss.

Author

Balaram P, Hackett TA, and Polley DB

Subjects

Animals, Auditory Cortex drug effects, Auditory Cortex metabolism, Auditory Pathways drug effects, Auditory Pathways physiology, Hearing Loss, Unilateral genetics, Hyperacusis drug therapy, Hyperacusis metabolism, Inferior Colliculi drug effects, Inferior Colliculi physiology, Mice, Inbred C57BL, Mice, Transgenic, Neurons metabolism, Hearing Loss, Unilateral physiopathology, Neuronal Plasticity physiology, Receptors, AMPA metabolism, Receptors, GABA-A metabolism, Synaptic Transmission physiology

Abstract

Debilitating perceptual disorders including tinnitus, hyperacusis, phantom limb pain and visual release hallucinations may reflect aberrant patterns of neural activity in central sensory pathways following a loss of peripheral sensory input. Here, we explore short- and long-term changes in gene expression that may contribute to hyperexcitability following a sudden, profound loss of auditory input from one ear. We used fluorescence in situ hybridization to quantify mRNA levels for genes encoding AMPA and GABA A receptor subunits (Gria2 and Gabra1, respectively) in single neurons from the inferior colliculus (IC) and auditory cortex (ACtx). Thirty days after unilateral hearing loss, Gria2 levels were significantly increased while Gabra1 levels were significantly decreased. Transcriptional rebalancing was more pronounced in ACtx than IC and bore no obvious relationship to the degree of hearing loss. By contrast to the opposing, synergistic shifts in Gria2 and Gabra1 observed 30 days after hearing loss, we found that transcription levels for both genes were equivalently reduced after 5 days of hearing loss, producing no net change in the excitatory/inhibitory transcriptional balance. Opposing transcriptional shifts in AMPA and GABA receptor genes that emerge several weeks after a peripheral insult could promote both sensitization and disinhibition to support a homeostatic recovery of neural activity following auditory deprivation. Imprecise transcriptional changes could also drive the system toward perceptual hypersensitivity, degraded temporal processing and the irrepressible perception of non-existent environmental stimuli, a trio of perceptual impairments that often accompany chronic sensory deprivation., (Copyright © 2018 IBRO. Published by Elsevier Ltd. All rights reserved.)

Published

2019

38. Endogenous Tagging Reveals Differential Regulation of Ca 2+ Channels at Single Active Zones during Presynaptic Homeostatic Potentiation and Depression.

Author

Gratz SJ, Goel P, Bruckner JJ, Hernandez RX, Khateeb K, Macleod GT, Dickman D, and O'Connor-Giles KM

Subjects

Animals, Drosophila physiology, Homeostasis, Male, Calcium Channels physiology, Drosophila Proteins physiology, Neuronal Plasticity, Presynaptic Terminals physiology, Synaptic Potentials

Abstract

Neurons communicate through Ca 2+ -dependent neurotransmitter release at presynaptic active zones (AZs). Neurotransmitter release properties play a key role in defining information flow in circuits and are tuned during multiple forms of plasticity. Despite their central role in determining neurotransmitter release properties, little is known about how Ca 2+ channel levels are modulated to calibrate synaptic function. We used CRISPR to tag the Drosophila Ca V 2 Ca 2+ channel Cacophony (Cac) and, in males in which all Cac channels are tagged, investigated the regulation of endogenous Ca 2+ channels during homeostatic plasticity. We found that heterogeneously distributed Cac is highly predictive of neurotransmitter release probability at individual AZs and differentially regulated during opposing forms of presynaptic homeostatic plasticity. Specifically, AZ Cac levels are increased during chronic and acute presynaptic homeostatic potentiation (PHP), and live imaging during acute expression of PHP reveals proportional Ca 2+ channel accumulation across heterogeneous AZs. In contrast, endogenous Cac levels do not change during presynaptic homeostatic depression (PHD), implying that the reported reduction in Ca 2+ influx during PHD is achieved through functional adaptions to pre-existing Ca 2+ channels. Thus, distinct mechanisms bidirectionally modulate presynaptic Ca 2+ levels to maintain stable synaptic strength in response to diverse challenges, with Ca 2+ channel abundance providing a rapidly tunable substrate for potentiating neurotransmitter release over both acute and chronic timescales. SIGNIFICANCE STATEMENT Presynaptic Ca 2+ dynamics play an important role in establishing neurotransmitter release properties. Presynaptic Ca 2+ influx is modulated during multiple forms of homeostatic plasticity at Drosophila neuromuscular junctions to stabilize synaptic communication. However, it remains unclear how this dynamic regulation is achieved. We used CRISPR gene editing to endogenously tag the sole Drosophila Ca 2+ channel responsible for synchronized neurotransmitter release, and found that channel abundance is regulated during homeostatic potentiation, but not homeostatic depression. Through live imaging experiments during the adaptation to acute homeostatic challenge, we visualize the accumulation of endogenous Ca 2+ channels at individual active zones within 10 min. We propose that differential regulation of Ca 2+ channels confers broad capacity for tuning neurotransmitter release properties to maintain neural communication., (Copyright © 2019 Gratz et al.)

Published

2019

39. Homeostatic Intrinsic Plasticity Is Functionally Altered in Fmr1 KO Cortical Neurons.

Author

Bülow P, Murphy TJ, Bassell GJ, and Wenner P

Subjects

Animals, Cerebral Cortex cytology, Fragile X Syndrome genetics, Homeostasis, Male, Membrane Potentials, Mice, Mice, Inbred C57BL, Neurons physiology, Cerebral Cortex physiopathology, Fragile X Mental Retardation Protein genetics, Fragile X Syndrome physiopathology, Neuronal Plasticity

Abstract

Cortical hyperexcitability is a hallmark of fragile X syndrome (FXS). In the Fmr1 knockout (KO) mouse model of FXS, cortical hyperexcitability is linked to sensory hypersensitivity and seizure susceptibility. It remains unclear why homeostatic mechanisms fail to prevent such activity. Homeostatic intrinsic plasticity (HIP) adjusts membrane excitability through regulation of ion channels to maintain activity levels following activity perturbation. Despite the critical role of HIP in the maturation of excitability, it has not been examined in FXS. Here, we demonstrate that HIP does not operate normally in a disease model, FXS. HIP was either lost or exaggerated in two distinct neuronal populations from Fmr1 KO cortical cultures. In addition, we have identified a mechanism for homeostatic intrinsic plasticity. Compromising HIP function during development could leave cortical neurons in the FXS nervous system vulnerable to hyperexcitability., (Copyright © 2019 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2019

40. Scaling Synapses in the Presence of HIV.

Author

Green MV, Raybuck JD, Zhang X, Wu MM, and Thayer SA

Subjects

Animals, HIV Infections metabolism, HIV Infections pathology, Humans, tat Gene Products, Human Immunodeficiency Virus metabolism, HIV metabolism, Neuronal Plasticity physiology, Synapses metabolism, Synapses virology

Abstract

A defining feature of HIV-associated neurocognitive disorder (HAND) is the loss of excitatory synaptic connections. Synaptic changes that occur during exposure to HIV appear to result, in part, from a homeostatic scaling response. Here we discuss the mechanisms of these changes from the perspective that they might be part of a coping mechanism that reduces synapses to prevent excitotoxicity. In transgenic animals expressing the HIV proteins Tat or gp120, the loss of synaptic markers precedes changes in neuronal number. In vitro studies have shown that HIV-induced synapse loss and cell death are mediated by distinct mechanisms. Both in vitro and animal studies suggest that HIV-induced synaptic scaling engages new mechanisms that suppress network connectivity and that these processes might be amenable to therapeutic intervention. Indeed, pharmacological reversal of synapse loss induced by HIV Tat restores cognitive function. In summary, studies indicate that there are temporal, mechanistic and pharmacological features of HIV-induced synapse loss that are consistent with homeostatic plasticity. The increasingly well delineated signaling mechanisms that regulate synaptic scaling may reveal pharmacological targets suitable for normalizing synaptic function in chronic neuroinflammatory states such as HAND.

Published

2019

41. Retinoic Acid Receptor RARα-Dependent Synaptic Signaling Mediates Homeostatic Synaptic Plasticity at the Inhibitory Synapses of Mouse Visual Cortex.

Author

Zhong LR, Chen X, Park E, Südhof TC, and Chen L

Subjects

Animals, Female, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Mice, Transgenic, Neural Inhibition physiology, Receptors, Retinoic Acid genetics, Homeostasis physiology, Neuronal Plasticity physiology, Receptors, Retinoic Acid deficiency, Synapses physiology, Visual Cortex pathology

Abstract

Homeostatic synaptic plasticity is a synaptic mechanism through which the nervous system adjusts synaptic excitation and inhibition to maintain network stability. Retinoic acid (RA) and its receptor RARα have been established as critical mediators of homeostatic synaptic plasticity. In vitro studies reveal that RA signaling enhances excitatory synaptic strength and decreases inhibitory synaptic strength. However, it is unclear whether RA-mediated homeostatic synaptic plasticity occurs in vivo , and if so, whether it operates at specific types of synapses. Here, we examine the impact of RA/RARα signaling in the monocular zone of primary visual cortex (V1m) in mice of either sex. Exogenous RA treatment in acute cortical slices resulted in a reduction in mIPSCs of layer 2/3 pyramidal neurons, an effect mimicked by visual deprivation induced by binocular enucleation in postcritical period animals. Postnatal deletion of RARα blocked RA's effect on mIPSCs. Cell type-specific deletion of RARα revealed that RA acted specifically on parvalbumin (PV)-expressing interneurons. RARα deletion in PV + interneurons blocked visual deprivation-induced changes in mIPSCs, demonstrating the critical involvement of RA signaling in PV + interneurons in vivo Moreover, visual deprivation- or RA-induced downregulation of synaptic inhibition was absent in the visual cortical circuit of constitutive and PV-specific Fmr1 KO mice, strongly suggesting a functional interaction between fragile X mental retardation protein and RA signaling pathways. Together, our results demonstrate that RA/RARα signaling acts as a key component for homeostatic regulation of synaptic transmission at the inhibitory synapses of the visual cortex. SIGNIFICANCE STATEMENT In vitro studies established that retinoic acid (RA) and its receptor RARα play key roles in homeostatic synaptic plasticity, a mechanism by which synaptic excitation/inhibition balance and network stability are maintained. However, whether synaptic RA signaling operates in vivo Thus, dysfunction of RA-dependent homeostatic plasticity may contribute to cortical circuit abnormalities in fragile X syndrome.in vivo Thus, dysfunction of RA-dependent homeostatic plasticity may contribute to cortical circuit abnormalities in fragile X syndrome., (Copyright © 2018 the authors 0270-6474/18/3810454-13$15.00/0.)

Published

2018

42. Molecular Interface of Neuronal Innate Immunity, Synaptic Vesicle Stabilization, and Presynaptic Homeostatic Plasticity.

Author

Harris N, Fetter RD, Brasier DJ, Tong A, and Davis GW

Subjects

Animals, Animals, Genetically Modified, Drosophila Proteins immunology, Drosophila melanogaster, Female, I-kappa B Kinase immunology, MAP Kinase Kinase Kinases immunology, Male, Signal Transduction, Transcription Factors immunology, Homeostasis, Immunity, Innate, Neuronal Plasticity immunology, Neurons immunology, Presynaptic Terminals immunology, Synaptic Vesicles immunology

Abstract

We define a homeostatic function for innate immune signaling within neurons. A genetic analysis of the innate immune signaling genes IMD, IKKβ, Tak1, and Relish demonstrates that each is essential for presynaptic homeostatic plasticity (PHP). Subsequent analyses define how the rapid induction of PHP (occurring in seconds) can be coordinated with the life-long maintenance of PHP, a time course that is conserved from invertebrates to mammals. We define a novel bifurcation of presynaptic innate immune signaling. Tak1 (Map3K) acts locally and is selective for rapid PHP induction. IMD, IKKβ, and Relish are essential for long-term PHP maintenance. We then define how Tak1 controls vesicle release. Tak1 stabilizes the docked vesicle state, which is essential for the homeostatic expansion of the readily releasable vesicle pool. This represents a mechanism for the control of vesicle release, and an interface of innate immune signaling with the vesicle fusion apparatus and homeostatic plasticity., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2018

43. Response to short-term deprivation of the human adult visual cortex measured with 7T BOLD.

Author

Binda P, Kurzawski JW, Lunghi C, Biagi L, Tosetti M, and Morrone MC

Subjects

Adult, Animals, Dominance, Ocular physiology, Female, Humans, Male, Vision, Binocular physiology, Visual Cortex physiology, Eye growth & development, Neuronal Plasticity physiology, Sensory Deprivation physiology, Visual Cortex growth & development

Abstract

Sensory deprivation during the post-natal 'critical period' leads to structural reorganization of the developing visual cortex. In adulthood, the visual cortex retains some flexibility and adapts to sensory deprivation. Here we show that short-term (2 hr) monocular deprivation in adult humans boosts the BOLD response to the deprived eye, changing ocular dominance of V1 vertices, consistent with homeostatic plasticity. The boost is strongest in V1, present in V2, V3 and V4 but absent in V3a and hMT+. Assessment of spatial frequency tuning in V1 by a population Receptive-Field technique shows that deprivation primarily boosts high spatial frequencies, consistent with a primary involvement of the parvocellular pathway. Crucially, the V1 deprivation effect correlates across participants with the perceptual increase of the deprived eye dominance assessed with binocular rivalry, suggesting a common origin. Our results demonstrate that visual cortex, particularly the ventral pathway, retains a high potential for homeostatic plasticity in the human adult., Competing Interests: PB, JK, CL, LB, MT, MM No competing interests declared, (© 2018, Binda et al.)

Published

2018

44. Molecular mechanisms that stabilize short term synaptic plasticity during presynaptic homeostatic plasticity.

Author

Ortega JM, Genç Ö, and Davis GW

Subjects

Animals, Drosophila Proteins metabolism, Drosophila melanogaster, Nerve Tissue Proteins metabolism, Synaptic Vesicles metabolism, Syntaxin 1 metabolism, rab3 GTP-Binding Proteins metabolism, Neuronal Plasticity, Neurotransmitter Agents metabolism, Presynaptic Terminals metabolism

Abstract

Presynaptic homeostatic plasticity (PHP) compensates for impaired postsynaptic neurotransmitter receptor function through a rapid, persistent adjustment of neurotransmitter release, an effect that can exceed 200%. An unexplained property of PHP is the preservation of short-term plasticity (STP), thereby stabilizing activity-dependent synaptic information transfer. We demonstrate that the dramatic potentiation of presynaptic release during PHP is achieved while simultaneously maintaining a constant ratio of primed to super-primed synaptic vesicles, thereby preserving STP. Mechanistically, genetic, biochemical and electrophysiological evidence argue that a constant ratio of primed to super-primed synaptic vesicles is achieved by the concerted action of three proteins: Unc18, Syntaxin1A and RIM. Our data support a model based on the regulated availability of Unc18 at the presynaptic active zone, a process that is restrained by Syntaxin1A and facilitated by RIM. As such, regulated vesicle priming/super-priming enables PHP to stabilize both synaptic gain and the activity-dependent transfer of information at a synapse., Competing Interests: JO, ÖG No competing interests declared, GD Reviewing editor, eLife, (© 2018, Ortega et al.)

Published

2018

45. The AMPA Receptor Code of Synaptic Plasticity.

Author

Diering GH and Huganir RL

Subjects

Animals, Humans, Synapses physiology, Brain physiology, Neuronal Plasticity physiology, Receptors, AMPA physiology

Abstract

Changes in the properties and postsynaptic abundance of AMPA-type glutamate receptors (AMPARs) are major mechanisms underlying various forms of synaptic plasticity, including long-term potentiation (LTP), long-term depression (LTD), and homeostatic scaling. The function and the trafficking of AMPARs to and from synapses is modulated by specific AMPAR GluA1-GluA4 subunits, subunit-specific protein interactors, auxiliary subunits, and posttranslational modifications. Layers of regulation are added to AMPAR tetramers through these different interactions and modifications, increasing the computational power of synapses. Here we review the reliance of synaptic plasticity on AMPAR variants and propose "the AMPAR code" as a conceptual framework. The AMPAR code suggests that AMPAR variants will be predictive of the types and extent of synaptic plasticity that can occur and that a hierarchy exists such that certain AMPARs will be disproportionally recruited to synapses during LTP/homeostatic scaling up, or removed during LTD/homeostatic scaling down., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2018

46. Functional Recovery of a Locomotor Network after Injury: Plasticity beyond the Central Nervous System.

Author

Puhl JG, Bigelow AW, Rue MCP, and Mesce KA

Subjects

Animals, Ganglia, Invertebrate drug effects, Ganglia, Invertebrate injuries, Hirudo medicinalis, Recovery of Function drug effects, Central Pattern Generators physiology, Dopamine pharmacology, Ganglia, Invertebrate physiology, Locomotion physiology, Motor Neurons physiology, Neuronal Plasticity physiology, Proprioception physiology, Recovery of Function physiology

Abstract

Many animals depend on descending information from the brain for the initiation and proper execution of locomotion. Interestingly, after injury and the loss of such inputs, locomotor function can sometimes be regained without the regrowth of central connections. In the medicinal leech, Hirudo verbana , we have shown that crawling reemerges after removal of descending inputs. Here, we studied the mechanisms underlying this return of locomotion by asking if central pattern generators (CPGs) in crawl-recovered leeches are sufficient to produce crawl-specific intersegmental coordination. From recovered animals, we treated isolated chains of ganglia with dopamine to activate the crawl CPGs (one crawl CPG per ganglion) and observed fictive crawl-like bursting in the dorsal-longitudinal-excitor motoneuron (DE-3), an established crawl-monitor neuron. However, these preparations did not exhibit crawl-specific coordination across the CPGs. Although the crawl CPGs always generated bidirectional activation of adjacent CPGs, we never observed crawl-appropriate intersegmental phase delays. Because central circuits alone were unable to organize crawl-specific coordination, we tested the coordinating role of the peripheral nervous system. In transected leeches normally destined for recovery, we removed afferent information to the anterior-most (lead) ganglion located below the nerve-cord transection site. In these dually treated animals, overt crawling was greatly delayed or prevented. After filling the peripheral nerves with Neurobiotin tracer distal to the nerve-root lesion, we found a perfect correlation between regrowth of peripheral neuronal fibers and crawl recovery. Our study establishes that during recovery after injury, crawl-specific intersegmental coordination switches to a new dependence on afferent information.

Published

2018

47. REST-Dependent Presynaptic Homeostasis Induced by Chronic Neuronal Hyperactivity.

Author

Pecoraro-Bisogni F, Lignani G, Contestabile A, Castroflorio E, Pozzi D, Rocchi A, Prestigio C, Orlando M, Valente P, Massacesi M, Benfenati F, and Baldelli P

Subjects

Animals, Mice, Repressor Proteins genetics, Synaptic Vesicles metabolism, Hippocampus metabolism, Homeostasis physiology, Neuronal Plasticity physiology, Neurons metabolism, Presynaptic Terminals physiology, Repressor Proteins metabolism

Abstract

Homeostatic plasticity is a regulatory feedback response in which either synaptic strength or intrinsic excitability can be adjusted up or down to offset sustained changes in neuronal activity. Although a growing number of evidences constantly provide new insights into these two apparently distinct homeostatic processes, a unified molecular model remains unknown. We recently demonstrated that REST is a transcriptional repressor critical for the downscaling of intrinsic excitability in cultured hippocampal neurons subjected to prolonged elevation of electrical activity. Here, we report that, in the same experimental system, REST also participates in synaptic homeostasis by reducing the strength of excitatory synapses by specifically acting at the presynaptic level. Indeed, chronic hyperactivity triggers a REST-dependent decrease of the size of synaptic vesicle pools through the transcriptional and translational repression of specific presynaptic REST target genes. Together with our previous report, the data identify REST as a fundamental molecular player for neuronal homeostasis able to downscale simultaneously both intrinsic excitability and presynaptic efficiency in response to elevated neuronal activity. This experimental evidence adds new insights to the complex activity-dependent transcriptional regulation of the homeostatic plasticity processes mediated by REST.

Published

2018

48. Homeostatic plasticity in neural development.

Author

Tien NW and Kerschensteiner D

Subjects

Animals, Humans, Nerve Net physiology, Homeostasis physiology, Neuronal Plasticity physiology, Neurons physiology, Synapses physiology

Abstract

Throughout life, neural circuits change their connectivity, especially during development, when neurons frequently extend and retract dendrites and axons, and form and eliminate synapses. In spite of their changing connectivity, neural circuits maintain relatively constant activity levels. Neural circuits achieve functional stability by homeostatic plasticity, which equipoises intrinsic excitability and synaptic strength, balances network excitation and inhibition, and coordinates changes in circuit connectivity. Here, we review how diverse mechanisms of homeostatic plasticity stabilize activity in developing neural circuits.

Published

2018

49. The Arc of cognition: Signaling cascades regulating Arc and implications for cognitive function and disease.

Author

Epstein I and Finkbeiner S

Subjects

Active Transport, Cell Nucleus physiology, Cell Nucleus metabolism, Humans, Neurons metabolism, Protein Biosynthesis genetics, Signal Transduction physiology, Synapses metabolism, Cognition physiology, Cognition Disorders pathology, Cytoskeletal Proteins metabolism, Memory physiology, Nerve Tissue Proteins metabolism, Neuronal Plasticity physiology

Abstract

The activity-regulated cytoskeletal (Arc) gene is implicated in numerous synaptic plasticity paradigms, including long-term potentiation and depression and homeostatic plasticity, and is critical for consolidating memory. How Arc facilitates these forms of plasticity is not fully understood. Unlike other neuronal immediate-early genes, Arc encodes a protein that shuttles between the somatodendritic and nuclear compartments to regulate synaptic plasticity. Little attention has been paid to Arc's role in the nucleus. Here, we highlight the regulatory elements and signaling cascades required to induce Arc transcription and discuss the significance of Arc nuclear localization for synaptic plasticity and scaling. We integrate these findings into the context of cognitive function and disease and propose a model in which Arc mediates an effect on memory as a "chaser" of synaptic activity through homeostatic scaling., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2018

50. Control of Homeostatic Synaptic Plasticity by AKAP-Anchored Kinase and Phosphatase Regulation of Ca 2+ -Permeable AMPA Receptors.

Author

Sanderson JL, Scott JD, and Dell'Acqua ML

Subjects

Action Potentials genetics, Action Potentials physiology, Animals, Electrophysiological Phenomena physiology, Excitatory Postsynaptic Potentials genetics, Excitatory Postsynaptic Potentials physiology, Female, Gene Knock-In Techniques, Long-Term Potentiation genetics, Long-Term Potentiation physiology, Male, Mice, Neuronal Plasticity physiology, Primary Cell Culture, Receptors, N-Methyl-D-Aspartate genetics, Receptors, N-Methyl-D-Aspartate physiology, Recruitment, Neurophysiological genetics, Recruitment, Neurophysiological physiology, A Kinase Anchor Proteins genetics, A Kinase Anchor Proteins physiology, Homeostasis genetics, Homeostasis physiology, Neuronal Plasticity genetics, Phosphoric Monoester Hydrolases genetics, Phosphoric Monoester Hydrolases physiology, Receptors, AMPA genetics, Receptors, AMPA physiology, Synapses physiology

Abstract

Neuronal information processing requires multiple forms of synaptic plasticity mediated by NMDARs and AMPA-type glutamate receptors (AMPARs). These plasticity mechanisms include long-term potentiation (LTP) and long-term depression (LTD), which are Hebbian, homosynaptic mechanisms locally regulating synaptic strength of specific inputs, and homeostatic synaptic scaling, which is a heterosynaptic mechanism globally regulating synaptic strength across all inputs. In many cases, LTP and homeostatic scaling regulate AMPAR subunit composition to increase synaptic strength via incorporation of Ca 2+ -permeable receptors (CP-AMPAR) containing GluA1, but lacking GluA2, subunits. Previous work by our group and others demonstrated that anchoring of the kinase PKA and the phosphatase calcineurin (CaN) to A-kinase anchoring protein (AKAP) 150 play opposing roles in regulation of GluA1 Ser845 phosphorylation and CP-AMPAR synaptic incorporation during hippocampal LTP and LTD. Here, using both male and female knock-in mice that are deficient in PKA or CaN anchoring, we show that AKAP150-anchored PKA and CaN also play novel roles in controlling CP-AMPAR synaptic incorporation during homeostatic plasticity in hippocampal neurons. We found that genetic disruption of AKAP-PKA anchoring prevented increases in Ser845 phosphorylation and CP-AMPAR synaptic recruitment during rapid homeostatic synaptic scaling-up induced by combined blockade of action potential firing and NMDAR activity. In contrast, genetic disruption of AKAP-CaN anchoring resulted in basal increases in Ser845 phosphorylation and CP-AMPAR synaptic activity that blocked subsequent scaling-up by preventing additional CP-AMPAR recruitment. Thus, the balanced, opposing phospho-regulation provided by AKAP-anchored PKA and CaN is essential for control of both Hebbian and homeostatic plasticity mechanisms that require CP-AMPARs. SIGNIFICANCE STATEMENT Neuronal circuit function is shaped by multiple forms of activity-dependent plasticity that control excitatory synaptic strength, including LTP/LTD that adjusts strength of individual synapses and homeostatic plasticity that adjusts overall strength of all synapses. Mechanisms controlling LTP/LTD and homeostatic plasticity were originally thought to be distinct; however, recent studies suggest that CP-AMPAR phosphorylation regulation is important during both LTP/LTD and homeostatic plasticity. Here we show that CP-AMPAR regulation by the kinase PKA and phosphatase CaN coanchored to the scaffold protein AKAP150, a mechanism previously implicated in LTP/LTD, is also crucial for controlling synaptic strength during homeostatic plasticity. These novel findings significantly expand our understanding of homeostatic plasticity mechanisms and further emphasize how intertwined they are with LTP and LTD., (Copyright © 2018 the authors 0270-6474/18/382863-14$15.00/0.)

Published

2018