Parvalbumin-positive (PV+) GABAergic interneurons in hippocampal microcircuits are thought to play a key role in several higher network functions, such as feedforward and feedback inhibition, network oscillations, and pattern separation. Fast lateral inhibition mediated by GABAergic interneurons may implement a winner-takes-all mechanism in the hippocampal input layer. However, it is not clear whether the functional connectivity rules of granule cells (GCs) and interneurons in the dentate gyrus are consistent with such a mechanism. Using simultaneous patch-clamp recordings from up to seven GCs and up to four PV+ interneurons in the dentate gyrus, we find that connectivity is structured in space, synapse-specific, and enriched in specific disynaptic motifs. In contrast to the neocortex, lateral inhibition in the dentate gyrus (in which a GC inhibits neighboring GCs via a PV+ interneuron) is ~ 10-times more abundant than recurrent inhibition (in which a GC inhibits itself). Thus, unique connectivity rules may enable the dentate gyrus to perform specific higher-order computations.
Summary Post-tetanic potentiation (PTP) is an attractive candidate mechanism for hippocampus-dependent short-term memory. Although PTP has a uniquely large magnitude at hippocampal mossy fiber-CA3 pyramidal neuron synapses, it is unclear whether it can be induced by natural activity and whether its lifetime is sufficient to support short-term memory. We combined in vivo recordings from granule cells (GCs), in vitro paired recordings from mossy fiber terminals and postsynaptic CA3 neurons, and “flash and freeze” electron microscopy. PTP was induced at single synapses and showed a low induction threshold adapted to sparse GC activity in vivo . PTP was mainly generated by enlargement of the readily releasable pool of synaptic vesicles, allowing multiplicative interaction with other plasticity forms. PTP was associated with an increase in the docked vesicle pool, suggesting formation of structural “pool engrams.” Absence of presynaptic activity extended the lifetime of the potentiation, enabling prolonged information storage in the hippocampal network.
Amyloid precursor protein (APP) is critically involved in the pathophysiology of Alzheimer’s disease, but its physiological functions remain elusive. Importantly, APP knockout (APP-KO) mice exhibit cognitive deficits, suggesting that APP plays a role at the neuronal network level. To investigate this possibility, we recorded local field potentials (LFPs) from the posterior parietal cortex, dorsal hippocampus and lateral prefrontal cortex of freely moving APP-KO mice. Spectral analyses showed that network oscillations within the theta- and gamma-frequency bands were not different between APP-KO and wild-type mice. Surprisingly, however, while gamma amplitude coupled to theta phase in all recorded regions of wild-type animals, in APP-KO mice theta-gamma coupling was strongly diminished in recordings from the parietal cortex and hippocampus, but not in LFPs recorded from the prefrontal cortex. Thus, lack of APP reduces oscillatory coupling in LFP recordings from specific brain regions, despite not affecting the amplitude of the oscillations. Together, our findings reveal reduced cross-frequency coupling as a functional marker of APP deficiency at the network level.
APP, APLP1, and APLP2 form a family of mammalian membrane proteins with unknown function. APP, however, plays a key role in the molecular pathology of Alzheimer's disease (AD), indicating that it is somehow involved in synaptic transmission, synaptic plasticity, memory formation, and maintenance of neurons. At present, most of our knowledge about the function of APP comes from consequences of AD-related mutations. The native role of APP, and even more of APLP1/2, remains largely unknown. New genetic knockout and knockin models involving several members of the APP/APLP family may yield better insight into the synaptic and systemic functions of these proteins. Here, we summarize recent results from such transgenic animals with special emphasis on synaptic plasticity and coherent patterns of memory-related network activity in the hippocampus. Data from APP knockout mice suggest that this protein is needed for the expression of long-term potentiation (LTP) in aged, but not in juvenile mice. The missing function can be rescued by expressing part of the protein, as well as by blocking inhibition. Double knockout mice lacking APP and APLP2 die shortly after birth indicating that different members of the APP/APLP family can mutually compensate for genetic ablation of single proteins. Recent techniques allow for analysis of tissue with combined defects, e.g., by expressing only part of APP in APLP2 knockout mice or by growing stem cells with multiple deletions on normal slice cultures. Data from these experiments confirm that APP and APLP2 do indeed play an important role in synaptic plasticity. Much less is known about the role of APP/APLP at the network level. Coherent patterns of activity like hippocampal network oscillations are believed to support formation and consolidation of memory. Analysis of such activity patterns in tissue from mice with altered expression of APP/APLP has just started and may shed further light on the importance of these proteins for cognitive functions.
Highlights d >50% of hippocampal GCs are active, but activity level varies over a wide range d 5% of GCs are place cells, but 50% receive spatially tuned synaptic input d Mixed input of GCs constrains models of grid-place code conversion d GC firing is controlled by intrinsic excitability
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