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NPAS4 recruits CCK basket cell synapses and enhances cannabinoid-sensitive inhibition in the mouse hippocampus.
Experience-dependent expression of immediate-early gene transcription factors (IEG-TFs) can transiently change the transcriptome of active neurons and initiate persistent changes in cellular function. However, the impact of IEG-TFs on circuit connectivity and function is poorly understood. We investigate the specificity with which the IEG-TF NPAS4 governs experience-dependent changes in inhibitory synaptic input onto CA1 pyramidal neurons (PNs). We show that novel sensory experience selectively enhances somatic inhibition mediated by cholecystokinin-expressing basket cells (CCKBCs) in an NPAS4-dependent manner. NPAS4 specifically increases the number of synapses made onto PNs by individual CCKBCs without altering synaptic properties. Additionally, we find that sensory experience-driven NPAS4 expression enhances depolarization-induced suppression of inhibition (DSI), a short-term form of cannabinoid-mediated plasticity expressed at CCKBC synapses. Our results indicate that CCKBC inputs are a major target of the NPAS4-dependent transcriptional program in PNs and that NPAS4 is an important regulator of plasticity mediated by endogenous cannabinoids
Making Waves in the Brain: What Are Oscillations, and Why Modulating Them Makes Sense for Brain Injury.
Traumatic brain injury (TBI) can result in persistent cognitive, behavioral and emotional deficits. However, the vast majority of patients are not chronically hospitalized; rather they have to manage their disabilities once they are discharged to home. Promoting recovery to pre-injury level is important from a patient care as well as a societal perspective. Electrical neuromodulation is one approach that has shown promise in alleviating symptoms associated with neurological disorders such as in Parkinson's disease (PD) and epilepsy. Consistent with this perspective, both animal and clinical studies have revealed that TBI alters physiological oscillatory rhythms. More recently several studies demonstrated that low frequency stimulation improves cognitive outcome in models of TBI. Specifically, stimulation of the septohippocampal circuit in the theta frequency entrained oscillations and improved spatial learning following TBI. In order to evaluate the potential of electrical deep brain stimulation for clinical translation we review the basic neurophysiology of oscillations, their role in cognition and how they are changed post-TBI. Furthermore, we highlight several factors for future pre-clinical and clinical studies to consider, with the hope that it will promote a hypothesis driven approach to subsequent experimental designs and ultimately successful translation to improve outcome in patients with TBI
Signalling properties at single synapses and within the interneuronal network in the CA1 region of the rodent hippocampus
Understanding how the complexity of connections among the neurons in the brain is
established and modified in an experience- and activity-dependent way is a challenging
task of Neuroscience. Although in the last decades many progresses have been made in
characterising the basic mechanisms of synaptic transmission, a full comprehension of
how information is transferred and processed by neurons has not been fully achieved.
In the present study, theoretical tools and patch clamp experiments were used to further
investigate synaptic transmission, focusing on quantal transmission at single synapses
and on different types of signalling at the level of a particular interneuronal network in
the CA1 area of the rodent hippocampus.
The simultaneous release of more than one vesicle from an individual presynaptic active
zone is a typical mechanism that can affect the strength and reliability of synaptic
transmission. At many central synapses, however, release caused by a single presynaptic
action potential is limited to one vesicle (univesicular release). The likelihood of
multivesicular release at a particular synapse has been tied to release probability (Pr), and
whether it can occur at Schaffer collateral\u2013CA1 synapses, at which Pr ranges widely, is
controversial. In contrast with previous findings, proofs of multivesicular release at this
synapse have been recently obtained at late developmental stages; however, in the case of
newborn hippocampus, it is still difficult to find strong evidence in one direction or
another.
In order to address this point, in the first part of this study a simple and general stochastic
model of synaptic release has been developed and analytically solved. The model
solution gives analytical mathematical expressions relating basic quantal parameters with
average values of quantities that can be measured experimentally. Comparison of these
quantities with the experimental measures allows to determine the most probable values
of the quantal parameters and to discriminate the univesicular from the multivesicular
mode of glutamate release. The model has been validated with data previously collected
at glutamatergic CA3-CA1 synapses in the hippocampus from newborn (P1-P5 old) rats.
The results strongly support a multivesicular type of release process requiring a variable
pool of immediately releasable vesicles. Moreover, computing quantities that are
functions of the model parameters, the mean amplitude of the synaptic response to the release of a single vesicle (Q) was estimated to be 5-10 pA, in very good agreement with
experimental findings. In addition, a multivesicular type of release was supported by
various experimental evidences: a high variability of the amplitude of successes, with a
coefficient of variation ranging from 0.12 to 0.73; an average potency ratio a2/a1 between
the second and first response to a pair of stimuli bigger than 1; and changes in the
potency of the synaptic response to the first stimulus when the release probability was
modified by increasing or decreasing the extracellular calcium concentration. This work
indicates that at glutamatergic CA3-CA1 synapses of the neonatal rat hippocampus a
single action potential may induce the release of more than one vesicle from the same
release site.
In a more systemic approach to the analysis of communication between neurons, it is
interesting to investigate more complex, network interactions. GABAergic interneurons
constitute a heterogeneous group of cells which exert a powerful control on network
excitability and are responsible for the oscillatory behaviour crucial for information
processing in the brain. They have been differently classified according to their
morphological, neurochemical and physiological characteristics.
In the second part of this study, whole cell patch clamp recordings were used to further
characterize, in transgenic mice expressing EGFP in a subpopulation of GABAergic
interneurons containing somatostatin (GIN mice), the functional properties of EGFPpositive
cells in stratum oriens of the CA1 region of the hippocampus, in slice cultures
obtained from P8 old animals. These cells showed passive and active membrane
properties similar to those found in stratum oriens interneurons projecting to stratum
lacunosum-moleculare. Moreover, they exhibited different firing patterns which were
maintained upon membrane depolarization: irregular (48%), regular (30%) and clustered
(22%). Paired recordings from EGFP-positive cells often revealed electrical coupling
(47% of the cases), which was abolished by carbenoxolone (200 mM). On average, the
coupling coefficient was 0.21 \ub1 0.07. When electrical coupling was particularly strong it
acted as a powerful low-pass filter, thus contributing to alter the output of individual
cells. The dynamic interaction between cells with various firing patterns may differently
control GABAergic signalling, leading, as suggested by simulation data, to a wide range
of interneuronal communication. In additional paired recordings of a presynaptic EGFP positive interneuron and a postsynaptic principal cell, trains of action potentials in
interneurons rarely evoked GABAergic postsynaptic currents (3/45 pairs) with small
amplitude and slow kinetics, and that at 20 Hz exhibited short-term depression. In
contrast, excitatory connections between principal cells and EGFP-positive interneurons
were found more often (17/55 pairs) and exhibited a frequency and use-dependent
facilitation, particularly in the gamma band. In conclusion, it appears that EGFP-positive
interneurons in stratum oriens of GIN mice constitute a heterogeneous population of cells
interconnected via electrical synapses, exhibiting particular features in their chemical and
electrical synaptic signalling. Moreover, the dynamic interaction between these
interneurons may differentially affect target cells and neuronal communication within the
hippocampal network
Synaptic plasticity and cognitive function are disrupted in the absence of Lrp4.
Lrp4, the muscle receptor for neuronal Agrin, is expressed in the hippocampus and areas involved in cognition. The function of Lrp4 in the brain, however, is unknown, as Lrp4-/- mice fail to form neuromuscular synapses and die at birth. Lrp4-/- mice, rescued for Lrp4 expression selectively in muscle, survive into adulthood and showed profound deficits in cognitive tasks that assess learning and memory. To learn whether synapses form and function aberrantly, we used electrophysiological and anatomical methods to study hippocampal CA3-CA1 synapses. In the absence of Lrp4, the organization of the hippocampus appeared normal, but the frequency of spontaneous release events and spine density on primary apical dendrites were reduced. CA3 input was unable to adequately depolarize CA1 neurons to induce long-term potentiation. Our studies demonstrate a role for Lrp4 in hippocampal function and suggest that patients with mutations in Lrp4 or auto-antibodies to Lrp4 should be evaluated for neurological deficits
Disinhibition Mediates a Form of Hippocampal Long-Term Potentiation in Area CA1
The hippocampus plays a central role in memory formation in the mammalian brain. Its ability to encode information is thought to depend on the plasticity of synaptic connections between neurons. In the pyramidal neurons constituting the primary hippocampal output to the cortex, located in area CA1, firing of presynaptic CA3 pyramidal neurons produces monosynaptic excitatory postsynaptic potentials (EPSPs) followed rapidly by feedforward (disynaptic) inhibitory postsynaptic potentials (IPSPs). Long-term potentiation (LTP) of the monosynaptic glutamatergic inputs has become the leading model of synaptic plasticity, in part due to its dependence on NMDA receptors (NMDARs), required for spatial and temporal learning in intact animals. Using whole-cell recording in hippocampal slices from adult rats, we find that the efficacy of synaptic transmission from CA3 to CA1 can be enhanced without the induction of classic LTP at the glutamatergic inputs. Taking care not to directly stimulate inhibitory fibers, we show that the induction of GABAergic plasticity at feedforward inhibitory inputs results in the reduced shunting of excitatory currents, producing a long-term increase in the amplitude of Schaffer collateral-mediated postsynaptic potentials. Like classic LTP, disinhibition-mediated LTP requires NMDAR activation, suggesting a role in types of learning and memory attributed primarily to the former and raising the possibility of a previously unrecognized target for therapeutic intervention in disorders linked to memory deficits, as well as a potentially overlooked site of LTP expression in other areas of the brain
The role of excitation and inhibition in learning and memory formation
The neurons in the mammalian brain can be classified into two broad categories: excitatory and inhibitory neurons. The former has been historically associated to information processing whereas the latter has been linked to network homeostasis. More recently, inhibitory neurons have been related to several computational roles such as the gating of signal propagation, mediation of network competition, or learning. However, the ways by which excitation and inhibition can regulate learning have not been exhaustively explored. Here we explore several model systems to investigate the role of excitation and inhibition in learning and memory formation. Additionally, we investigate the effect that third factors such as neuromodulators and network state exert over this process. Firstly, we explore the effect of neuromodulators onto excitatory neurons and excitatory plasticity. Next, we investigate the plasticity rules governing excitatory connections while the neural network oscillates in a sleep-like cycle, shifting between Up and Down states. We observe that this plasticity rule depends on the state of the network. To study the role of inhibitory neurons in learning, we then investigate the mechanisms underlying place field emergence and consolidation. Our simulations suggest that dendrite-targeting interneurons play an important role in both promoting the emergence of new place fields and in ensuring place field stabilization. Soma-targeting interneurons, on the other hand, are suggested to be related to quick, context-specific changes in the assignment of place and silent cells. We next investigate the mechanisms underlying the plasticity of synaptic connections from specific types of interneurons. Our experiments suggest that different types of interneurons undergo different synaptic plasticity rules. Using a computational model, we implement these plasticity rules in a simplified network. Our simulations indicate that the interaction between the different forms of plasticity account for the development of stable place fields across multiple environments. Moreover, these plasticity rules seems to be gated by the postsynaptic membrane voltage. Inspired by these findings, we propose a voltage-based inhibitory synaptic plasticity rule. As a consequence of this rule, the network activity is kept controlled by the imposition of a maximum pyramidal cell firing rate. Remarkably, this rule does not constrain the postsynaptic firing rate to a narrow range. Overall, through multiple stages of interactions between experiments and computational simulations, we investigate the effect of excitation and inhibition in learning. We propose mechanistic explanations for experimental data, and suggest possible functional implications of experimental findings. Finally, we proposed a voltage-based inhibitory synaptic plasticity model as a mechanism for flexible network homeostasis.Open Acces
Cell- and input-specific expression of the α5-GABAAR in the CA1 area of the mouse hippocampus
Dans l'hippocampe, les processus de mémoire et d'apprentissage dépendent fortement de l'inhibition GABAergique, qui est fournis par une population hétérogène d'interneurones (INs) via l'activation de sous-types spécifiques de récepteurs GABA. La sous-unité alpha5-GABAAR (α5-GABAAR) est fortement exprimée dans l'hippocampe de la souris, du singe et du cerveau humain. Il a été rapporté que, dans les cellules pyramidales CA1, cette sous-unité est principalement localisée sur les sites extrasynaptiques, où elle est responsable de la génération de la conductance inhibitrice tonique. Si la sous-unité α5-GABAAR peut être ciblée sur des types spécifiques de synapses dans des types cellulaires distincts reste inconnue. En utilisant l'immunohistochimie dans des coupes d'hippocampe de souris, nous avons étudié l'expression spécifique de la sous-unité α5-GABAAR dans les cellules et les synapses de l’oriens/alveus de le région CA1. Nos résultats démontrent que la sous-unité α5-GABAAR est principalement exprimée dans les INs positifs à la somatostatine. De plus, la densité de sous-unité était plus élevée dans les dendrites proximales et diminuait avec la distance par rapport au soma, ce qui correspond à une diminution de la densité des synapses inhibitrices dépendant de la distance. De plus, l'α5-GABAAR ciblait les synapses formées par les entrées exprimant le peptide intestinal vasoactif (VIP+) et la calrétinine (CR+) et, dans une moindre mesure, celles produites par les projections exprimant de la parvalbumine (PV+). En résumé, nos résultats montrent que la sous-unité α5-GABAAR présente une expression spécifique à la cellule et à la synapse dans l'hippocampe CA1. Comme la sous-unité α5-GABAAR a été impliquée dans plusieurs maladies, comprenant la maladie d'Alzheimer et le syndrome de Down, les nouvelles connaissances sur la localisation de l'α5-GABAAR seront importantes pour le développement de la thérapie cellulaire spécifique.In the hippocampus, memory and learning processes are highly dependent on the GABAergic inhibition, which is provided by a heterogeneous population of interneurons (INs) via activation of specific sub-types of GABA receptors. The alpha5-GABAAR subunit (α5-GABAAR) is highly expressed in the hippocampus of the mouse, monkey and human brain. It has been reported that, in the CA1 pyramidal cells, this subunit is predominantly located at extrasynaptic sites, where it is responsible for generation of tonic inhibitory conductance. Whether the α5-GABAAR subunit can be targeted to specific types of synapses in distinct cell types remains unknown. Using immunohistochemistry and electophysiological approach in mouse hippocampal slices, we studied the cell- and synapse-specific expression of the α5-GABAAR subunit in the CA1 oriens/alveus INs. Our results demonstrate that the α5-GABAAR subunit is mainly expressed in the somatostatin-positive INs. In addition, the subunit density was higher in proximal dendrites and declined with distance from the soma, consistent with a distance-dependent decrease in the density of inhibitory synapses. Furthermore, the α5-GABAAR was targeted to synapses made by the vasoactive intestinal peptide (VIP+)- and calretinin (CR+)-expressing inputs and to a lesser extent to those made by the parvalbumin-positive (PV+) projections. In summary, our results show that the α5-GABAAR subunit exhibits a cell- and input-specific expression in the CA1 hippocampus. As the α5-GABAAR subunit has been implicated in several diseases, including Alzheimer’s disease and Down syndrome, the new insights into the α5-GABAAR localization will be important for the development of cell- and site-specific therapy
Hippocampal gabaergic inhibitory interneurons
This is the author accepted manuscript. The final version is available from American Physiological Society via the DOI in this record In the hippocampus GABAergic local circuit inhibitory interneurons represent only ~10–15% of the total neuronal population; however, their remarkable anatomical and physiological diversity allows them to regulate virtually all aspects of cellular and circuit function. Here we provide an overview of the current state of the field of interneuron research, focusing largely on the hippocampus. We discuss recent advances related to the various cell types, including their development and maturation, expression of subtype-specific voltage-and ligand-gated channels, and their roles in network oscillations. We also discuss recent technological advances and approaches that have permitted high-resolution, subtype-specific examination of their roles in numerous neural circuit disorders and the emerging therapeutic strategies to ameliorate such pathophysiological conditions. The ultimate goal of this review is not only to provide a touchstone for the current state of the field, but to help pave the way for future research by highlighting where gaps in our knowledge exist and how a complete appreciation of their roles will aid in future therapeutic strategies.National Institute of Child Health and Human Developmen
Hippocampal GABAergic inhibitory interneurons
In the hippocampus GABAergic local circuit inhibitory interneurons represent only ~10–15% of the total neuronal population; however, their remarkable anatomical and physiological diversity allows them to regulate virtually all aspects of cellular and circuit function. Here we provide an overview of the current state of the field of interneuron research, focusing largely on the hippocampus. We discuss recent advances related to the various cell types, including their development and maturation, expression of subtype-specific voltage- and ligand-gated channels, and their roles in network oscillations. We also discuss recent technological advances and approaches that have permitted high-resolution, subtype-specific examination of their roles in numerous neural circuit disorders and the emerging therapeutic strategies to ameliorate such pathophysiological conditions. The ultimate goal of this review is not only to provide a touchstone for the current state of the field, but to help pave the way for future research by highlighting where gaps in our knowledge exist and how a complete appreciation of their roles will aid in future therapeutic strategies
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