SYNCHRONIZATION OF NEURONAL-ACTIVITY IN HIPPOCAMPUS BY INDIVIDUAL GABAERGIC INTERNEURONS

被引：1176

作者：

COBB, SR ^{[1
]}

BUHL, EH ^{[1
]}

HALASY, K ^{[1
]}

PAULSEN, O ^{[1
]}

SOMOGYI, P ^{[1
]}

机构：

[1] ATTILA JOZSEF UNIV, DEPT ZOOL & CELL BIOL, H-6722 SZEGED, HUNGARY

来源：

NATURE | 1995年 / 378卷 / 6552期

基金：

英国惠康基金;

关键词：

D O I：

10.1038/378075a0

中图分类号：

O [数理科学和化学]; P [天文学、地球科学]; Q [生物科学]; N [自然科学总论];

学科分类号：

07 ; 0710 ; 09 ;

摘要：

SYNCHRONIZATION Of neuronal activity is fundamental in the operation of cortical networks(1). With respect to an ongoing synchronized oscillation, the precise timing of action potentials is an attractive candidate mechanism for information coding(2-5) Networks of inhibitory interneurons have been proposed to have a role in entraining cortical, synchronized 40-Hz activity(6,7). Here we demonstrate that individual GABAergic interneurons(8) can effectively phase spontaneous firing and subthreshold oscillations in hippocampal pyramidal cells at theta frequencies (4-7 Hz). The efficiency of this entrainment is due to interaction of GABA(A)-receptor-mediated hyperpolarizing synaptic events with intrinsic oscillatory mechanisms tuned to this frequency range in pyramidal cells. Moreover, this GABAergic mechanism is sufficient to synchronize the firing of pyramidal cells. Thus, owing to the divergence of each GABAergic interneuron(9,10), more than a thousand pyramidal cells may share a common temporal reference established by an individual interneuron.

引用

页码：75 / 78

页数：4

共 27 条

[1] SUBTHRESHOLD NA+-DEPENDENT THETA-LIKE RHYTHMICITY IN STELLATE CELLS OF ENTORHINAL CORTEX LAYER-II [J].

ALONSO, A ;

LLINAS, RR .

NATURE, 1989, 342 (6246) :175-177

[2] INHIBITORY PHASING OF NEURONAL DISCHARGE [J].

ANDERSEN, P ;

ECCLES, J .

NATURE, 1962, 196 (4855) :645-&

[3] RECURRENT INHIBITION IN HIPPOCAMPUS WITH IDENTIFICATION OF INHIBITORY CELL AND ITS SYNAPSES [J].

ANDERSEN, P ;

ECCLES, JC ;

LOYNING, Y .

NATURE, 1963, 198 (488) :540-&

[4] DIVERSE SOURCES OF HIPPOCAMPAL UNITARY INHIBITORY POSTSYNAPTIC POTENTIALS AND THE NUMBER OF SYNAPTIC RELEASE SITES [J].

BUHL, EH ;

HALASY, K ;

SOMOGYI, P .

NATURE, 1994, 368 (6474) :823-828

[5] MEMBRANE-POTENTIAL AND IMPEDANCE CHANGES IN HIPPOCAMPAL PYRAMIDAL CELLS DURING THETA RHYTHM [J].

FOX, SE .

EXPERIMENTAL BRAIN RESEARCH, 1989, 77 (02) :283-294

[6] GABA-CONTAINING NEURONS IN THE SEPTUM CONTROL INHIBITORY INTERNEURONS IN THE HIPPOCAMPUS [J].

FREUND, TF ;

ANTAL, M .

NATURE, 1988, 336 (6195) :170-173

[7] ELECTRICAL CHANGES IN MEMBRANE IN JUNCTIONAL TRANSMISSION [J].

GINSBORG, BL .

BIOCHIMICA ET BIOPHYSICA ACTA, 1973, 300 (03) :289-317

[8] HIPPOCAMPAL PYRAMIDAL CELLS EXCITE INHIBITORY NEURONS THROUGH A SINGLE RELEASE SITE [J].

GULYAS, AI ;

MILES, R ;

SIK, A ;

TOTH, K ;

TAMAMAKI, N ;

FREUND, TF .

NATURE, 1993, 366 (6456) :683-687

[9] PATTERN-RECOGNITION COMPUTATION USING ACTION-POTENTIAL TIMING FOR STIMULUS REPRESENTATION [J].

HOPFIELD, JJ .

NATURE, 1995, 376 (6535) :33-36

[10] ELECTROPHYSIOLOGY OF HIPPOCAMPAL NEURONS .2. AFTER-POTENTIALS AND REPETITIVE FIRING [J].

KANDEL, ER ;

SPENCER, WA .

JOURNAL OF NEUROPHYSIOLOGY, 1961, 24 (03) :243-&

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