Synaptic Communication among Hippocampal Interneurons: Properties of Spontaneous IPSCs in Morphologically Identified Cells

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111

Inhibitory interneurons are considered to be the controlling units of neural networks, despite their sparse number and unique morphological characteristics compared with excitatory pyramidal cells. Although pyramidal cell dendrites have been shown to display local regenerative events-dendritic spikes (dSpikes)-evoked by artificially patterned stimulation of synaptic inputs, no such studies exist for interneurons or for spontaneous events. In addition, imaging techniques have yet to attain the required spatial and temporal resolution for the detection of spontaneously occurring events that trigger dSpikes. Here we describe a highresolution 3D two-photon laser scanning method (Roller Coaster Scanning) capable of imaging long dendritic segments resolving individual spines and inputs with a temporal resolution of a few milliseconds. By using this technique, we found that local, NMDA receptor-dependent dSpikes can be observed in hippocampal CA1 stratum radiatum interneurons during spontaneous network activities in vitro. These NMDA spikes appear when approximately 10 spatially clustered inputs arrive synchronously and trigger supralinear integration in dynamic interaction zones. In contrast to the one-to-one relationship between computational subunits and dendritic branches described in pyramidal cells, here we show that interneurons have relatively small (∼14 μm) sliding interaction zones. Our data suggest a unique principle as to how interneurons integrate synaptic information by local dSpikes.3D scanning | hippocampus | uncaging | signal integration | modeling I nterneurons are critically important for synaptic plasticity and synchronization of oscillatory activities and have been suggested to provide temporal control for principal cells (1). Although the output of interneurons is more thoroughly studied, there is only sparse evidence on how the inputs on their dendrites act when activated in concert under in vitro conditions. In contrast, there are a number of phenomena explored concerning signal integration on principal cells that have not been described on interneurons. Spatial clustering of synchronized synaptic inputs can lead to nonlinear integration and regenerative events in dendrites of principal neurons, increasing their computational power (2-8). On the contrary, interneurons were previously suggested to have more linear or sublinear integration propertiesfeatures that might imply a passive involvement in neuronal operations (9). Dendritic integration in principal cells is mediated by multiple layers of logical integrators (2, 6, 10), the first layer being the apical Ca 2+ and axonal Na + integration zone, generating relatively more global propagating spikes. At the same time, both tuft and basal thin dendritic branches are able to generate NMDA spikes, providing an integration method for distant inputs to overcome strong dendritic filtering (11) and drive the output of the cell (10). On the contrary, we are aware of no studies to date that have shown that local regenerative spikes (evoked or spontaneou...

Section: Resultsmentioning

confidence: 99%

Roller Coaster Scanning reveals spontaneous triggering of dendritic spikes in CA1 interneurons

Katona

Kaszás

Túri

et al. 2011

Self Cite

111

“…Experimental evidence in support of this connection awaits unambiguous identification of the GABA A,slow population (see below). Circumstantially, fast spontaneous IPSCs are seen in interneurons throughout the hippocampus (26), but only at low rates in SL-M interneurons (27), which may correspond to the GABA A,slow cells. In our model, connections from GABA A,slow to GABA A,fast cells are crucial for supporting either the generation or resynchronization of the theta-gamma rhythm.…”

Section: Discussionmentioning

confidence: 95%

“…This discrepancy may be caused by the difficulty in distinguishing between fast and slow inputs under current clamp, or by the possibility that the presynaptic cells from the dual-cell recordings may not be the same ones activated by an extracellular stimulus in SL-M. It should also be noted that GABA A,slow spontaneous IPSCs have not been reported in recordings from interneurons (26). Their absence in published data may reflect a rarity of spontaneous activity in GABA A,slow interneurons, as implied by the rarity (but documented presence) of spontaneous GABA A,slow IPSCs in recordings from pyramidal cells (18).…”

Section: Discussionmentioning

confidence: 99%

“…2), parameters must be tuned to give strong interconnections among cells of the same kinetic class; appropriate levels of drive to each population to give firing rates (under conditions of inhibition) that are compatible with the speed of decay of GABA A,fast or GABA A,slow inhibition, and tuning of the connections from GABA A,slow to GABA A,fast cells to create a pause of the appropriate duration in activity of GABA A,fast cells. In models including connections from GABA A,fast to GABA A,slow cells, as is likely the case in the biological network (21,26), parameters must be tuned even more carefully, with strong connections between cells of a given class, weaker connections between classes, and precise values of drive. Slight mistuning leads to a population rhythm that is dominated by one population or the other (e.g., Fig.…”

Section: Previous Experimentsmentioning

confidence: 99%

See 1 more Smart Citation

Networks of interneurons with fast and slow γ-aminobutyric acid type A (GABA _A ) kinetics provide substrate for mixed gamma-theta rhythm

White

Banks²,

Pearce³

2000

200

154

During active exploration, hippocampal neurons exhibit nested rhythmic activity at theta (Ϸ8 Hz) and gamma (Ϸ40 Hz) frequencies. Gamma rhythms may be generated locally by interactions within a class of interneurons mediating fast GABAA (GABAA,fast) inhibitory postsynaptic currents (IPSCs), whereas theta rhythms traditionally are thought to be imposed extrinsically. However, the hippocampus contains slow biophysical mechanisms that may contribute to the theta rhythm, either as a resonance activated by extrinsic input or as a purely local phenomenon. For example, region CA1 of the hippocampus contains a slower class of GABAA (GABAA,slow) synapses, believed to be generated by a distinct group of interneurons. Recent evidence indicates that these GABAA,slow interneurons project to the GABAA,fast interneurons that contribute to hippocampal gamma rhythms. Here, we use biophysically based simulations to explore the possible ramifications of interneuronal circuits containing separate classes of GABAA,fast and GABAA,slow interneurons. Simulated interneuronal networks with fast and slow synaptic kinetics can generate mixed theta-gamma rhythmicity under restricted conditions, including strong connections among each population, weaker connections between the two populations, and homogeneity of cellular properties and drive. Under a broader range of conditions, including heterogeneity, the networks can amplify and resynchronize phasic responses to weak phase-dispersed external drive at theta frequencies to either GABAA,slow or GABAA,fast cells. GABAA,slow synapses are necessary for this process of amplification and resynchronization.A prevalent feature of activity in the brain is the presence of distinct patterns of synchronous oscillatory activity that are linked tightly to the behavioral state of the animal. A particularly prominent rhythmic pattern is that of synchronous firing in the gamma (Ϸ40 Hz) and theta (Ϸ8 Hz) bands, seen under conditions of active exploration in the rat hippocampal formation, a set of structures necessary for declarative memory. A recent flurry of experimental, computational, and theoretical work (1-6) has made the convincing argument that the gamma rhythm is generated intrinsically by networks of inhibitory interneurons in the hippocampus. The theta rhythm, on the other hand, is commonly believed to be imposed on the hippocampus by phasic input from the medial septum͞diagonal band of Broca and entorhinal cortex (7-12).

“…The decay time of the I inhibitory postsynaptic potentials (IPSPs) are chosen to be 10 ms (24). The IPSPs originating from the O cells onto pyramidal cells was taken to be 20 ms (25). The decay time of the excitatory postsynaptic potentials onto O and I cells was taken to be 4 ms.…”

Section: Methodsmentioning

confidence: 99%

Orthogonal arrangement of rhythm-generating microcircuits in the hippocampus

Gloveli

Dugladze

Rotstein

et al. 2005

224

212

As a structure involved in learning and memory, the hippocampus functions as a network. The functional differentiation along the longitudinal axis of the hippocampus is poorly demarcated in comparison with the transverse axis. Using patch clamp recordings in conjunction with post hoc anatomy, we have examined the pattern of connectivity and the functional differentiation along the long axis of the hippocampus. Here, we provide anatomical and physiological evidence that the prominent rhythmic network activities of the hippocampus, the behavior-specific gamma and theta oscillations, are seen predominantly along the transverse and longitudinal axes respectively. This orthogonal relationship is the result of the axonal field trajectories and the consequential interaction of the principal cells and major interneuron subtypes involved in generating each rhythm. Thus, the axonal arborization patterns of hippocampal inhibitory cells may represent a structural framework for the spatiotemporal distribution of activity observed within the hippocampus.interneurons ͉ oscillations ͉ patch clamp T he hippocampus is required for the encoding of new information and for retrieving information shortly after acquisition (1). Spatial information is coded at theta frequencies (2) by clusters of neurons segmentally distributed along the longitudinal axis of the hippocampus (3). Gamma oscillations are also generated by the hippocampus nested within these theta rhythms and are thought to be involved in transient neuronal assembly formation (4), information transmission, and storage (5).As previous observation has shown, the hippocampus is made up of multiple lamellae organized in parallel across the long axis, in which each lamella contains a functionally independent transverse circuit (6). The well defined connections between subregions along the transverse axis facilitates the investigation of crucial neurobiological processes such as network oscillatory activity in the in vitro preparation. Although the functionally segregated subregions of the long axis of the hippocampal formation may cooperate with each other during memory formation (for review, see ref. 7), morphological evidence about their interconnectivity is sparse. Although CA3 neurons connect to other CA3 neurons (8, 9), and excitation of interneurons occurs along the longitudinal axis (10), the involvement of hippocampal interneurons in the functional circuit along the longitudinal axis of hippocampus is still unclear.Interneurons serve a wide variety of functions in the brain, amongst them generating and maintaining local or large scale coherent activity (for review, see ref. 11). They also have a particularly pivotal role in driving inhibition-based rhythms, such as gamma and theta frequency network oscillations (12-16). Theta rhythms are seen as a major operational mode of the hippocampus (for review, see ref. 17), and clusters of neurons that encode information required to perform spatial and nonspatial short-term memory tasks during theta rhythms are distributed in di...