Optical detection of dendritic spike initiation in hippocampal CA1 pyramidal neurons.

Previous studies have shown that spikes can be generated in the dendrites of CA1 pyramidal neurons. Some have suggested that, in response to synaptic inputs, spikes are initiated near the soma and propagate back into the dendrites, but some recent studies have shown that intense synaptic inputs initiate spikes in the dendrite. Here, we report the optical detection of spike propagation along the apical dendrites of hippocampal pyramidal neurons. Rat hippocampal slices were stained with the fluorescent voltage-sensitive dye, JPW1114, and optical signals monitored using a 16 x 16 photodiode array system at a frame rate of 4 kHz. A stimulating electrode was placed at the boundary between the stratum (str.) lacnosum-moleculare and the str. radiatum to stimulate the Schaffer collateral, and fast and slow signal components were detected in the dendritic and somatic regions. By comparing the optical signals with whole-cell recordings, we confirmed that the fast component was due to a population of dendritic spikes in pyramidal neurons. The fast component appeared in dendritic locations near the input sites in response to synaptic activation, and signal onset at the soma was delayed by a few milliseconds compared with that at the input sites. Local perfusion of a Na(+) channel blocker near the soma eliminated the fast component at the soma, but had no effect on the fast component at the input sites. Our results indicate that dendritic spikes can be initiated in dendrites near the input site and propagate orthodromically toward the proximal dendrites and the soma.

Optical monitoring of synaptic summation along the dendrites of CA1 pyramidal neurons.

The primary function of neurons is to integrate synaptic inputs and to transmit the results to other cells. Recent studies with somatic whole-cell recordings have shown that separate excitatory inputs to hippocampal or cortical pyramidal neurons are summated non-linearly. In the present study, we examined how postsynaptic potentials (PSPs) are summated along the dendrites employing fast optical voltage imaging techniques. Rat hippocampal slices were stained with a fluorescent voltage-sensitive dye (JPW1114) and optical signals were monitored with a 16 x 16 photodiode array system. Two independent input pathways were stimulated individually or in pairs through glass electrodes such that different locations of the dendrites received separate synaptic inputs. We found that (1) the summation of PSPs was sub-linear along the entirety of dendrites, (2) the blockade of GABA(A) receptors suppressed sub-linearity and (3) further blockade of GABA(B) receptors suppressed sub-linearity of the summation of separate inputs on apical dendrites. Our study demonstrates that pyramidal neurons integrate PSPs linearly along the entirety of dendrites; moreover, GABAergic inputs are responsible for maintaining sub-linear summation in CA1 pyramidal neurons.

GABAergic control of synaptic summation in hippocampal CA1 pyramidal neurons.

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 influenced by GABAergic inputs in feed-forward or feedback manner, and also by oscillatory network activities. It is likely that these GABAergic inputs regulate the way synaptic inputs are summated. To examine the roles of GABAergic inputs on synaptic summation, we made whole-cell recordings from the cell bodies of CA1 pyramidal neurons in rat hippocampal slices while stimulating two independent input pathways with short interstimulus intervals, and examined the manner by which postsynaptic potentials were summated. We found that: 1) the summation of the perforant pathway and the Schaffer collateral pathway inputs was sublinear when the interval between two inputs was shorter than 30 ms, 2) the blockade of GABA(A) receptors partially suppressed the sublinearity, and 3) further blockade of GABA(B) receptors removed the sublinearity totally. We also found that 4) the summation was superlinear under the concomitant blockade of GABA(A) and GABA(B) receptors when the two inputs arrived with no delay. Thus our study demonstrates that GABAergic inputs are responsible for keeping the summation of two separate inputs on CA1 pyramidal neurons sublinear.