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Previous Article | Next Article
Volume 17, Number 9, Issue of May 1, 1997 pp. 3285-3292
Copyright ©1997 Society for NeuroscienceSEROTONERGIC Pontomedullary Neurons Are Not Activated by Antinociceptive Stimulation in the Periaqueductal Gray
Keming Gao, Yoo-Hang Hugh Kim, and Peggy Mason Department of Pharmacological and Physiological Sciences and the Committee on Neurobiology, University of Chicago, Chicago, Illinois 60637
ABSTRACT
The antinociceptive and cardiovascular effects of midbrain periaqueductal gray (PAG) stimulation are mediated through a relay in the pontomedullary raphe magnus (RM) and adjacent nucleus reticularis magnocellularis (NRMC). To test whether the neurons important in mediating PAG-evoked effects are SEROTONERGIC, the responses of pontomedullary SEROTONERGIC-LIKE cells to PAG stimulation were tested. SEROTONERGIC-LIKE neurons (n = 21) were recorded extracellularly in halothane-anesthetized Sprague Dawley rats. Serotonergic-like neurons were distinguished by their slow and steady background discharge. Two neurons that were physiologically characterized as SEROTONERGIC-LIKE were intracellularly labeled and processed for serotonin immunoreactivity; both cells tested contained immunoreactive serotonin. Train stimulation of sites within the midbrain PAG, at intensities of
Key words: raphe magnus; serotonin; monoamine; pain modulation; autonomic modulation; antinociception50 µA, suppressed the tail withdrawal from noxious heat and evoked changes in blood pressure and heart rate. No SEROTONERGIC-LIKE cells were activated by single-pulse or short-train (two to five pulses) stimulation of the PAG at antinociceptive intensities. In most cases, SEROTONERGIC-LIKE cells were unaffected by long-train stimulation (5-6 sec) of the PAG, which produced antinociception and cardiovascular changes. In contrast, >50% of the cells in two nonserotonergic-like cell classes were activated at short latency by such PAG stimulation. In conclusion, monosynaptic excitation of SEROTONERGIC cells in RM/NRMC is unlikely to be necessary for the nociceptive and autonomic modulatory effects of PAG stimulation.
INTRODUCTION
The antinociceptive effects of periaqueductal gray (PAG) stimulation are mediated at least in part by the activation of neurons in the raphe magnus (RM) and surrounding pontomedullary reticular nuclei, including nucleus reticularis magnocellularis (NRMC) (Behbehani and Fields, 1979
; Sandkuhler and Gebhart, 1984
In addition to having nociceptive modulatory effects, PAG stimulation also evokes changes in autonomic function, including cardiovascular tone. Stimulation within the ventrolateral PAG evokes hypotension and bradycardia and facilitates the vagal-mediated baroreflex, effects that are blocked by lesions of RM and NRMC (Inui et al., 1994
Stimulation of the dorsal PAG evokes an increase in blood pressure and heart rate (Lovick, 1991
If SEROTONERGIC cells mediate the nociceptive and/or cardiovascular modulatory effects of PAG stimulation, then PAG stimulation would be expected to activate RM and NRMC SEROTONERGIC cells. Although previous work has demonstrated that long-train (10 sec) stimulation of the PAG excites RM/NRMC ON and OFF cells (Vanegas et al., 1984
MATERIALS AND METHODS
Experimental protocol. Male Sprague Dawley rats (Sasco, Madison, WI, or Harlan, Indianapolis, IN) were used. Rats were pretreated with atropine sulfate (40 µg in 0.1 ml, s.c.) 10 min before anesthetic induction with halothane. A Y-tube was inserted into the trachea, and anesthesia was maintained with 2% halothane in oxygen during surgery. A posterior craniotomy was made overlying the cerebellum, and the exposed dura was cut. Electrodes were inserted bilaterally into the thorax to record the electrocardiogram and into the paraspinous muscles to record the electromyographic activity during tail withdrawal. In some animals, an arterial catheter was inserted into the femoral artery to record blood pressure. Core body temperature was maintained at 36-38°C. After surgical preparation, the halothane concentration was reduced to 1%, and the animal was allowed to equilibrate at this concentration for 30 min before recording.
Six stainless steel microelectrodes tip-plated with platinum were used to stimulate three regions of the PAG [anterior (A), 0.3-3.3 mm from interaural zero; lateral (L), 0-2.0 mm; ventral (V), 5.0-7.0 mm from cerebral surface] bilaterally. The array of six monopolar stimulating electrodes was inserted at an angle of 30° rostral to the frontal plane. To ensure correct placement of the stimulation electrodes, suppression of the tail flick (TF) reflex evoked by noxious heat was confirmed using train stimulation of the PAG (
A recording microelectrode was inserted into the region of the RM/NRMC [posterior (P), 1.5 to
or with 2% Neurobiotin in the above solution and used with a tip resistance of 40-70 M
All cells were characterized as SEROTONERGIC-LIKE or nonserotonergic-like using a previously described algorithm that makes use of quantitative differences between the two populations of cells in the rate and variability of the interspike intervals recorded during background conditions (Mason, 1997 was calculated, where
is the mean interspike interval (in milliseconds), and s is the SD of the intervals (in milliseconds). Cells were classified as SEROTONERGIC-LIKE if the function value was <0 and as nonserotonergic-like if the function value was >0 (Mason, 1997
After characterization, cells were tested for their responses to PAG stimulation at all six sites in the electrode array at a current of 50-500 µA with single shocks or short trains (300-500 Hz) of two to six pulses. Selected cells were then tested during long trains (5-6 sec) of PAG stimulation that were effective in suppressing the TF withdrawal or in producing a cardiovascular change. To determine whether a cell responded to tail heat or long-train PAG stimulation or both, the cell discharge rate before, during, and after the stimulus was calculated for 6 sec bins. In the absence of stimulation, the variation in the number of spikes per 6 sec bin was always 40%.
After the recording session, the final recording site and the stimulating sites were lesioned with 20 nA negative direct current for 4 min. The animals were perfused with saline and 500 ml of fixative. Coronal serial sections (40-50 µm) were cut on a freezing microtome. Pontomedullary sections containing SEROTONERGIC-LIKE cells were stained for serotonin immunoreactivity as described previously (Mason, 1997
In two cases, cells were intracellularly labeled with Neurobiotin, which was subsequently visualized with a Texas Red fluorophore. These cells were then processed for serotonin immunofluorescence using a Bodipy fluorophore, as described previously (Mason, 1997
Unless stated otherwise, all statistics are expressed as mean ± SEM.
RESULTS
The histologically verified sites of PAG stimulation were located bilaterally in the caudal (0.3-0.7 mm rostral to interaural zero), middle (1.7-2.3 mm), and rostral (2.7-3.3 mm) thirds of the ventral PAG. Most stimulation sites in the caudal and middle thirds of the PAG were concentrated in the ventral half of PAG, whereas those of the rostral third of PAG were located throughout the dorsoventral range within PAG (Fig. 1A). In each experiment, train stimulation (4-6 sec, 300 Hz, 200 µsec,
Fig. 1. Stimulation and recording sites. A, PAG stimulation sites. The most caudal section is shown on the left and the most rostral on the right. B, Pontomedullary recording sites for SEROTONERGIC (asterisks) and SEROTONERGIC-LIKE (filled circles) cells. The rostrocaudal location of each section is shown on the bottom right. n. VII, Facial nucleus; NRMC, nucleus reticularis magnocellularis pars
, nucleus reticularis magnocellularis pars
[View Larger Version of this Image (31K GIF file)]
A total of 21 SEROTONERGIC-LIKE cells from 18 animals were recorded and analyzed. Histological sites for the recorded and analyzed cells were found to be in RM and NRMC 
Fig. 2. Photomicrographs of two SEROTONERGIC cells. A1, B1, The intracellular label of each cell is visualized with Texas Red. A2, B2, The same field is seen after processing for serotonin immunoreactivity visualized with Bodipy.
[View Larger Version of this Image (121K GIF file)]
SEROTONERGIC-LIKE cells had background discharge rates of 0.4-2.9 Hz (mean 1.4 ± 0.2 Hz) (Fig. 3). The mean coefficient of variation of the interspike interval was 0.52 ± 0.03, with a range of 0.18-0.80. SEROTONERGIC-LIKE cells were unaffected (n = 13) or slightly excited (n = 8) by noxious tail heat and unaffected (n = 14) or slightly excited (n = 7) by noxious pinch. 
Fig. 3. Graph of the background discharge characteristics of recorded cells. The coefficient of variation (CV) of the interspike interval is plotted against the mean interspike interval for a 5 min period of background discharge. A line representing the discriminant function [y(
[View Larger Version of this Image (25K GIF file)]
Single- and double-pulse stimulation of the PAG, at intensities of up to 500 µA, did not alter the discharge rate of any SEROTONERGIC-LIKE cell tested (n = 21) (Fig. 4A). Short-train (three to six pulses) stimulation of PAG, at intensities of 50-150 µA, was ineffective in altering the discharge of any SEROTONERGIC-LIKE cell. Short-train stimulation, at a stimulation intensity of 500 µA, of 24 PAG sites was tested on four SEROTONERGIC-LIKE cells. At such currents, two cells were excited by stimulation of only four PAG sites (Fig. 4B-D). The latency from the first PAG shock to peak excitation of these two RM/NRMC SEROTONERGIC-LIKE cells was 18-23 msec. The latency to the recorded response was highly variable, making it unlikely that this represents a monosynaptic connection. Furthermore, the calculated conduction velocities for a monosynaptic connection, assuming a synaptic delay of 0.5 msec, for each of the four PAG site-RM/NRMC cell pairs would be 0.3-0.4 m/sec. 
Fig. 4. Responses of a SEROTONERGIC cell to PAG stimulation. A, A raster plot of a SEROTONERGIC-LIKE cell that does not respond to single-pulse stimulation of any PAG site tested. The top of the figure represents background activity, and the bars on the left demarcate periods of PAG stimulation (1 pulse, 200 µsec pulse, 500 µA; trials repeated at 1 Hz). B, A raster plot of a SEROTONERGIC cell that responds to short-train stimulation of two of six PAG sites tested. The top of the figure represents background activity, and the bars on the left demarcate periods of PAG stimulation (1-3 pulses, 300 Hz, 200 µsec pulses, 500 µA; trials repeated at 1 Hz). C, Extracellular recordings from the SEROTONERGIC cell shown in B in response to rostral left PAG stimulation. Ten traces are overlaid. D, Extracellular recordings from the SEROTONERGIC cell shown in B and C in response to caudal left PAG stimulation. Ten traces are overlaid.
[View Larger Version of this Image (31K GIF file)]
During PAG-evoked suppression of the TF (50 uA, 300 Hz, 6 sec), the discharge of most SEROTONERGIC-LIKE cells did not change (Fig. 5). In two cases, there were small increases in discharge associated with the PAG train stimulation (Fig. 5F). These increases always had a latency of several seconds. During PAG-evoked changes in blood pressure, the discharge of SEROTONERGIC-LIKE cells did not change (Fig. 5B,D,F). 
Fig. 5. An example of a SEROTONERGIC cell during PAG suppression of the noxious-evoked TF. The bottom trace illustrates the instantaneous discharge rate (the reciprocal of the interspike interval; left axis) of the unit. It is important to note that in graphs of instantaneous rate, a point at 10 Hz reflects an action potential that occurred 100 msec after the preceding action potential; it does not reflect the occurrence of 10 action potentials within a bin. Adjacent points are joined by lines, and the graph is filled to the zero line. The middle trace represents the systemic blood pressure, and the top trace shows the instantaneous heart rate. The bar below the trace indicates where the heat stimulus was applied, and the arrow shows the time of the animal's withdrawal. A, Instantaneous discharge rate during a control trial of noxious tail heat. B, Discharge during suppression of the noxious heat-evoked TF by stimulation in the rostral right PAG (300 Hz, 200 µsec, 50 µA; dashed line under graph). C, Discharge during a control trial of noxious tail heat obtained 3 min after the suppression test shown in B. D, Discharge during suppression of the noxious heat (solid bar under graph)-evoked TF by stimulation in the rostral left PAG (300 Hz, 200 µsec, 50 µA; dashed line under graph). E, Discharge during a control trial of noxious tail heat obtained 3 min after the suppression test shown in D. F, Discharge during suppression of the noxious heat (solid bar under graph)-evoked TF by stimulation in the caudal left PAG (300 Hz, 200 µsec, 50 µA; dashed line under graph). G, Discharge during a recovery trial of noxious tail heat (solid bar under graph) obtained 3 min after the suppression test shown in F. The scale bar on the left of each trace represents the instantaneous discharge frequency; the scale bar on the right of each trace represents 0-100 for the blood pressure and 0-400 for the heart rate. H, This serotonergic cell was intracellularly labeled. The somatodendritic arbor is illustrated. The arrow points at the soma.
[View Larger Version of this Image (23K GIF file)]
No SEROTONERGIC-LIKE cells were antidromically activated by PAG stimulation at any site.
Although the PAG stimulation was effective in evoking PAG suppression of the noxious-evoked TF, additional confirmation of the efficacy of PAG stimulation was examined by recording from nonserotonergic-like cells in RM and NRMC, which have previously been reported to respond to PAG stimulation (see introductory remarks). Nonserotonergic-like cells were recorded in the same animals as the SEROTONERGIC-LIKE cells discussed above. The background discharge of nonserotonergic-like cells was faster and/or more irregular than that of SEROTONERGIC-LIKE cells (Fig. 3). Nonserotonergic-like cells were characterized further as ON (n = 15), OFF (n = 10), and NEUTRAL (n = 47) cells, as described previously (Leung and Mason, 1995
DISCUSSION
Summary
The current study provides little evidence for a monosynaptic excitatory connection between PAG and RM/NRMC SEROTONERGIC cells. Short-train stimulation of sites located throughout the rostrocaudal extent of the midbrain PAG, at intensities that suppressed the noxious-evoked TF, failed to activate any of the 21 SEROTONERGIC-LIKE cells tested. Furthermore, PAG suppression of the TF occurred in the absence of SEROTONERGIC-LIKE cell activation. In the two cases in which PAG suppression evoked an increase in SEROTONERGIC-LIKE cell discharge, this activation was likely attributable to oligo- or polysynaptic rather than monosynaptic pathways (see below).
Two SEROTONERGIC-LIKE cells were excited at short latency by PAG train stimulation at an intensity of 500 µA. The latency of these excitations (18-23 msec) is evidence that if a monosynaptic excitatory connection exists between PAG and RM/NRMC SEROTONERGIC cells, the conduction velocity would have to be very slow,
The activation of two SEROTONERGIC-LIKE cells by train stimulation of the PAG, reported above, is likely attributable to current spread or activation of oligosynaptic pathways or both. Responses were evoked by short-train stimulation only at intensities of
All SEROTONERGIC-LIKE cells were characterized using a previously described algorithm developed from an analysis of more than 45 physiologically characterized, intracellularly labeled and immunocytochemically tested cells (Mason, 1997 Functional implications
The current findings suggest that the fast glutamatergic input that mediates the antinociceptive effects of PAG activation (see introductory remarks) is likely to act on RM/NRMC nonserotonergic cells. This is consistent with the previous observation that intracellularly labeled RM cells that receive a monosynaptic EPSP from PAG stimulation do not contain serotonin immunoreactivity in the cat (Mason et al., 1988
In light of the anatomical evidence that PAG cells project to serotonin-containing neurons in RM, the current finding that pontomedullary SEROTONERGIC-LIKE cells do not respond physiologically to PAG stimulation is puzzling. It is possible that PAG-derived synaptic input to SEROTONERGIC RM and NRMC cells is not of sufficient strength to change the discharge rate recorded extracellularly. It is also possible that PAG stimulation inhibits SEROTONERGIC cells; any inhibition lasting less than the mean interspike interval (i.e., 300-2000 msec) would be difficult to detect in the present study. Finally, SEROTONERGIC cells in RM and NRMC are a heterogeneous population with regard to physiology, morphology, and neurochemistry (Bowker et al., 1982
The lack of a strong physiological input from PAG to pontomedullary SEROTONERGIC-LIKE cells is also puzzling because of the large body of evidence that the antinociceptive and cardiovascular modulatory effects of PAG stimulation are mediated, at least in part, by the spinal release of serotonin. Pontomedullary SEROTONERGIC cells are the primary, if not the only, source of serotonin in the spinal cord (Dahlstrom and Fuxe, 1964
FOOTNOTES
Received Dec. 9, 1996; revised Jan. 22, 1997; accepted Feb. 11, 1997.
This research was supported by the Brain Research Foundation and National Institutes of Health Grant NS33984. We thank David O. Chen for technical assistance, Cynthia Leung for comments on this manuscript, and Drs. R. A. McCrea, J. M. Goldberg, and D. L. Hammond for helpful conversations.
Correspondence should be addressed to Peggy Mason, Department of Pharmacological and Physiological Sciences, University of Chicago, MC 0926, 947 East 58th Street, Chicago, IL 60637.
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