Plasticity in an Electrosensory System. III. Contrasting Properties of Spatially Segregated Dendritic Inputs

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Plasticity in an Electrosensory System. III. Contrasting Properties of Spatially Segregated Dendritic Inputs

J. Bastian

Department of Zoology, University of Oklahoma, Norman, Oklahoma 73019

Bastian, J. Plasticity in an electrosensory system. III. Contrasting properties of spatially segregated dendritic inputs.J. Neurophysiol. 79: 1839-1857, 1998. Efferent neurons of thefirst-order electrosensory processing center of the brain, theelectrosensory lateral line lobe (ELL), receive electroreceptorafferent input as well as feedback inputs descending from highercenters. These ELL efferents, pyramidal cells, adaptively filterpredictable patterns of sensory input while preserving sensitivityto novel stimuli. The filter mechanism involves integration ofcentrally generated predictive inputs with the afferent inputsbeing canceled. The predictive inputs, referred to as "negativeimage" inputs, terminate on pyramidal cell apical dendrites andgenerate responses that are opposite those resulting from thepredictable afference, hence integration of these signals resultsin attenuation of pyramidal cell responses. The system also showsa robust form of plasticity; the pyramidal cells learn, with atime course of a few minutes, to cancel new patterns of repetitiveinputs. This is accomplished by adjusting the strength of excitatoryand inhibitory apical dendritic inputs according to an anti-Hebbianlearning rule. This study focuses on the properties of two separatepathways that convey descending information to pyramidal cellapical dendrites. One pathway terminates proximally, nearer tothe pyramidal cell body, whereas the other terminates distally.Recordings of ELL evoked potentials, extracellular pyramidal cellspike responses, and intracellularly recorded synaptic potentialsshow that the pyramidal cells respond oppositely to moderate-frequency(> ~8 Hz) single pulse stimulation or repeated (1/s) tetanic activationof these two pathways. Repetitive activation of the proximallyterminating pathway results in highly facilitating responses dueto potentiation of pyramidal cell excitatory postsynaptic potentials(EPSPs). These same stimuli applied to the distally terminatingpathway result in a reduction of pyramidal cell responses dueto depression of EPSPs and potentiation of inhibitatory postsynapticpotentials (IPSPs). Anti-Hebbian plasticity was demonstrated bypairing tetanic stimulation of either pathway with changes inthe postsynaptic cell's membrane potential. After stabilizationof the response potentiation due to tetanic stimulation of theproximally terminating pathway, paired postsynaptic hyperpolarizationresulted in further increases in spike responses and additionalpotentiation of pyramidal cell EPSPs. Paired postsynaptic depolarizationreduced subsequent responses to the tetanus, depressed EPSP amplitudes,and, in many cases, potentiated IPSPs. The same pattern of plasticitywas observed when postsynaptic hyper- or depolarization was pairedwith tetanic stimulation of the distally terminating pathway exceptthat the plasticity was superimposed on the depressed pyramidalcell responses resulting from stimulating this pathway alone.Modulation of a postsynaptic form of synaptic depression is proposedto account for the anti-Hebbian plasticity associated with bothpathways.

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				A.-M. M. Oswald, J. E. Lewis, and L. Maler Dynamically Interacting Processes Underlie Synaptic Plasticity in a Feedback Pathway J Neurophysiol, May 1, 2002; 87(5): 2450 - 2463. [Abstract] [Full Text] [PDF]

				J. Bastian and J. Nguyenkim Dendritic Modulation of Burst-Like Firing in Sensory Neurons J Neurophysiol, January 1, 2001; 85(1): 10 - 22. [Abstract] [Full Text] [PDF]

				P. D. Roberts Modeling Inhibitory Plasticity in the Electrosensory System of Mormyrid Electric Fish J Neurophysiol, October 1, 2000; 84(4): 2035 - 2047. [Abstract] [Full Text] [PDF]

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