Complex Synaptic Current Waveforms Evoked in Hippocampal Pyramidal Neurons by Extracellular Stimulation of Dentate Gyrus

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Complex Synaptic Current Waveforms Evoked in Hippocampal Pyramidal Neurons by Extracellular Stimulation of Dentate Gyrus

Zixiu Xiang¹ and Thomas H. Brown¹^,²

¹ Department of Psychology and ² Department of Cellular and Molecular Physiology, Yale University, New Haven, Connecticut 06520

Xiang, Zixiu and Thomas H. Brown. Complex synaptic current waveforms evoked in hippocampal pyramidal neurons by extracellularstimulation of dentate gyrus. J. Neurophysiol. 79: 2475-2484,1998. Excitatory postsynaptic currents (EPSCs) evoked in hippocampalCA3 pyramidal neurons by extracellular stimulation of the dentategyrus typically exhibit complex waveforms. They commonly haveinflections or notches on the rising phase; the decay phase mayexhibit notches or other obvious departures from a simple monoexponentialdecline; they often display considerable variability in the latencyfrom stimulation to the peak current; and the rise times tendto be long. One hypothesis is that these complex EPSC waveformsmight result from excitation via other CA3 pyramidal cells thatwere recruited antidromically or trans-synaptically by the stimulusdue to the complex anatomy of this region. An alternative hypothesisis that EPSC complexity does not emerge from the functional anatomybut rather reflects an unusual physiological property, intrinsicto excitation-secretion coupling in mossy-fiber (mf) synapticterminals, that causes asynchronous quantal release. We evaluatedcertain predictions of our anatomic hypothesis by adding a pharmacologicalagent to the normal bathing medium that should suppress di- orpolysynaptic responses. For this purpose we used baclofen (3 µM),a selective agonist for the $gamma$ -aminobutyric acid B receptor. Theidea was that baclophen should discriminate against polysynapticversus monosynaptic inputs by hyperpolarizing the cells, bringingthem further from spike threshold and possibly also through inhibitorypresynaptic actions. Whole cell recordings were done from visuallypreselected CA3 pyramidal neurons and EPSCs were evoked by finebipolar electrodes positioned into the granule cell layer of thedentate. To the extent that the EPSC complexity reflects di- orpolysynaptic responses, we predicted baclofen to reduce the numberof notches on the rising and decay phases, reduce the variancein latency to peak of the EPSCs, decrease the amplitudes and risetimes of the individual and averaged EPSCs, and increase the apparentfailures in evoked EPSCs. All of these predictions were confirmed,in support of the hypothesis that these complex EPSC waveformscommonly reflect di- or polysynaptic responses. We also documenteda distinctly different, intermittent, form of EPSC complexity,which also is predicted and easily explained by our anatomic hypothesis.In particular, the results were in accord with the suggestionthat stimulation of the dentate gyrus might antidromically stimulateaxon collaterals of CA3 neurons that make recurrent synapses ontothe recorded cell. We conclude that the overall pattern of resultsis consistent with expectations based on the functional anatomy.The explanation does not demand a special type of intrinsic asynchronousmechanism for excitation-secretion coupling in the mf synapses.

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