Corticothalamic Inhibition in the Thalamic Reticular Nucleus

doi:10.1152/jn.00624.2003

Corticothalamic Inhibition in the Thalamic Reticular Nucleus

Liming Zhang and Edward G. Jones

Center for Neuroscience, University of California, Davis, California 95616

Submitted 1 July 2003; accepted in final form 20 October 2003

Mutual inhibition between the GABAergic cells of the thalamicreticular nucleus (RTN) is important in regulating oscillationsin the thalamocortical network, promoting those in the spindlerange of frequencies over those at lower frequencies. Excitatoryinputs to the RTN from the cerebral cortex are numerically largeand particularly powerful in inducing spindles. However, theextent to which corticothalamic influences can engage the inhibitorynetwork of the RTN has not been fully explored. Focal electricalstimulation of layer VI in the barrel cortex of the mouse thalamocorticalslice in vitro resulted in prominent di- or polysynaptic inhibitorypostsynaptic currents (IPSCs) in RTN cells under the experimentalconditions used. The majority of cortically induced responsesconsisted of mixed PSCs in which the inhibitory component predominatedor of large IPSCs alone, implying inhibition of neighboringcells by other, cortically excited RTN cells. Within the mixedPSCs, fixed and variable latency components could commonly beidentified. IPSCs could be blocked by application of ionotropicglutamate receptor antagonists or of GABA_A receptor antagonists,also indicating their dependence on corticothalamic excitationtriggering disynaptic or polysynaptic inhibition. SpontaneousGABA_A receptor-dependent IPSCs were routinely observed in theRTN and, taken together with the results of cortical stimulation,indicate the existence of a substantial network of intrareticularinhibitory connections that can be effectively recruited bythe corticothalamic system. These results suggest activationof cortical excitatory inputs triggers the propagation of inhibitorycurrents within the RTN and support the view that activationof the RTN from the somatosensory cortex, although focused bythe topography of the corticothalamic projection, is capableof disynaptically engaging the whole inhibitory network of theRTN, by local and probably by reentrant GABA_A receptor–basedsynapses, thus spreading the corticothalamic influence throughoutthe RTN.

Address for reprint requests and other correspondence: E. G. Jones, Center for Neuroscience, 1616 Newton Court, Davis, CA 95616 (E-mail: egjones{at}ucdavis.edu).

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