Apamin increases excitability of CA1 hippocampal pyramidal neurons

## Abstract The experience of chronic stress induces a reversible regression of hippocampal CA3 apical neuron dendrites. Although such postsynaptic membrane reduction will obviously diminish the possibility of synaptic input, the consequences for the functional membrane properties of these cells ar

## Abstract The primary function of neurons is to integrate synaptic inputs and to transmit the results to other cells. It was shown previously that separate excitatory inputs to hippocampal pyramidal neurons are summated nonlinearly. In the hippocampus, responses of pyramidal neurons are influence

Anatomical substrates were investigated for local circuit hyperexcitability that occurs in the CA3 subfield of the rat hippocampus during postnatal week 2. A transient excess of excitatory local circuit connectivity was hypothesized to underlie this hyperexcitability. To test this hypothesis, recurr

## Abstract The heterogeneous expression of voltage‐gated channels in dendrites suggests that neurons perform local microdomain computations at different regions. It has been shown that A‐type K^+^ channels have a nonuniform distribution along the primary apical dendrite in CA1 pyramidal neurons, i

## Abstract We have found, based on the electrophysiological properties, two subtypes of CA1 pyramidal neurons in the CA1 region of the normal hippocampus, late postsynaptic potential (L‐PSP) neurons and non‐L‐PSP neurons. In addition, our previous study has shown that the electrophysiological prop

Ca2 + is an important regulator of neurite elongation and growth cone movements but the mechanism@) mediating these Ca2+-dependent effects is unclear. Since cytoskeletal proteins are rapidly degraded by Ca2+-dependent proteinases (calpains) in vitro and in vivo, we investigated whether Ca2+-induced