Role of GABA Receptor Subtypes in Inhibition of Primate Spinothalamic Tract
Neurons : Difference Between Spinal and Periaqueductal Gray Inhibition.
LIN, QING, YUAN BO PENG AND WILLIAM D. WILLIS.
Department of Anatomy and Neurosciences and Marine Biomedical Institute,
The University of Texas Medical Branch, Galveston, TX 77555-1069, U.S.A.
APStracts 2:0261N, 1995.
SUMMARY AND CONCLUSIONS
1. _-Aminobutyric acid (GABA) is thought to inhibit both pre- and
postsynaptically the transfer of nociceptive signals from primary afferent
fibers to spinal dorsal horn sensory cells, including spinothalamic tract
(STT) neurons. The inhibition can be mediated by both GABA A and GABA B
receptors. We have now attempted to characterize the synaptic inhibition of
STT cells by spinal GABA A and GABA B receptors in anesthetized monkeys and to
analyse the roles of these two receptor subtypes in the inhibition of STT
cellular activity produced by stimulation in the periaqueductal gray (PAG). 2.
Iontophoretic release of GABA or muscimol (a selective GABA A receptor
agonist) onto STT cells elicited a profound and dose-related inhibition of the
responses of all cells tested to noxious cutaneous stimuli. Only 4 cells
(16.7%) were found to be inhibited when baclofen (a selective GABA B receptor
agonist) was applied iontophoretically. However, a strong and dose-dependent
inhibition of the responses to cutaneous mechanical and thermal stimuli was
obtained in all cells examined when baclofen was administered into the dorsal
horn through a microdialysis fiber. The inhibitory effects were mainly on
nociceptive inputs. 3. The inhibition of cellular activity by GABA A and GABA
B agonists could be selectively antagonized by specific antagonists applied
through a microdialysis fiber. 4. The excitatory responses evoked by pulsed
release of glutamic acid (GLUT) were also inhibited in a dose-related manner
by iontophoretic application of GABA and muscimol, but not by baclofen. A high
dose of baclofen administered by microdialysis resulted in only a small
decrease in GLUT-evoked excitatory responses. 5. Infusion of GABA A and GABA B
antagonists into the dorsal horn by microdialysis caused an increase in both
background activity and responses to cutaneous stimuli, suggesting that there
is a tonic GABAergic inhibition of STT cells. 6. The inhibition of responses
to mechanical and thermal stimulation of the cutaneous excitatory receptive
field resulting from stimulation in PAG was significantly antagonized in most
of the STT cells tested when the GABA A antagonist, bicuculline, was infused
into the spinal dorsal horn through a microdialysis fiber. In contrast, the
inhibition produced by PAG stimulation in most of the cells examined was not
significantly antagonized by GABA B antagonists, phaclofen or CGP35348,
administered into the spinal dorsal horn by microdialysis. 7. Our results
support the contention that GABAergic mechanisms in the spinal dorsal horn
normally exert a tonic modulation of nociceptive inputs through both GABA A
and GABA B receptors. The evidence provided here indicates that GABA A
receptors located on primate STT neurons contribute to a postsynaptic
inhibitory effect on the transmission of peripheral nociceptive inputs. A
possible presynaptic GABA A action was not investigated. Our finding of a GABA
B receptor-mediated inhibition is consistent with the view that both pre- and
postsynaptic GABA B receptors are involved in inhibitory modulation of spinal
nociceptive transmission. Finally, it is suggested from this study that
primate spinal GABA A , but not GABA B receptors, are involved in mediating
the descending inhibition induced by PAG stimulation.
Received 5 January 1995; accepted in final form 16 August 1995.
APS Manuscript Number J7-5.
Article publication pending J. Neurophysiol.
ISSN 1080-4757 Copyright 1995 The American Physiological Society.
Published in APStracts on 15 September 1995.