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The Journal of Neuroscience, September 1, 1999, 19(17):7648-7652
Lateral Hypothalamic Serotonin Inhibits Nucleus Accumbens Dopamine: Implications for Sexual Satiety
Daniel S. Lorrain, Jon V. Riolo, Leslie Matuszewich, and Elaine M. Hull Department of Psychology, State University of New York at Buffalo, Buffalo, New York 14260
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Dopamine (DA) is released in several brain areas, including the nucleus accumbens (NAcc), before and during copulation in male rats. DA agonists administered into this area facilitate, and DA antagonists inhibit, numerous motivated behaviors, including male sexual behavior. Serotonin (5-HT) is generally inhibitory to male sexual behavior. We reported previously that 5-HT is released in the anterior lateral hypothalamic area (LHAA) and that a selective serotonin reuptake inhibitor microinjected into that area delayed and slowed copulation. Our present results, using high temporal resolution microdialysis, (1) confirm previous electrochemical evidence that extracellular levels of DA increase in the NAcc during copulation and decrease during the postejaculatory interval (PEI) and (2) reveal that LHAA 5-HT can inhibit both basal and female-elicited DA release in the NAcc. These findings suggest that the neural circuit promoting sexual quiescence during the PEI includes serotonergic input to the LHAA, which in turn inhibits DA release in the NAcc. These findings may also provide insights concerning the inhibitory control of other motivated behaviors activated by the NAcc and may have relevance for understanding the sexual side effects common to antidepressant medications.
Key words: serotonin; lateral hypothalamic area; dopamine; nucleus accumbens; copulation; postejaculatory interval; microdialysis; male rats
INTRODUCTION
Male sexual behavior in humans, nonhuman primates, and rodents is influenced by dopamine (DA) and serotonin (5-HT) neurotransmission (Bitran and Hull, 1987
; Gorzalka et al., 1990
In the presence of sexually relevant stimuli, extracellular DA increases in the nucleus accumbens (NAcc) (Mas et al., 1990
Serotonin generally inhibits copulation. Sexual behavior is impaired by many 5-HT agonists and agents that increase 5-HT availability and is facilitated by serotonergic lesions and many receptor antagonists (Bitran and Hull, 1987
5-HT projections originating in the raphe may suppress forebrain catecholaminergic systems (Yamamoto and Ueki, 1978
MATERIALS AND METHODS
Subjects. Nineteen sexually experienced male rats were housed individually in plastic cages and maintained on a reverse light/dark cycle with lights off at 11:00 A.M. and on at 10:00 P.M. Food and water were available ad libitum. For experiment 1, 7 subjects received a unilateral guide cannula aimed at the shell region of the NAcc [anteroposterior, +3.0; mediolateral, +1.0; and dorsoventral,
5.2 (Pellegrino et al., 1979
Microdialysis. Concentric microdialysis probes were constructed in the lab. Briefly, a 27 ga thin-wall stainless steel tube was fitted with a dialysis membrane [12,000 kDa cutoff; 210 µm outer diameter (o.d.); 1 mm active-dialyzing surface; Spectra Por, Houston, TX] at one end and a 3 cm piece of polyethylene 20 tubing at the other end to serve as the inlet for the perfusion medium. A 20 cm piece of silica capillary tubing [125 µm o.d.; 50 µm inner diameter (i.d.); Polymicro Technologies, Phoenix, AZ], threaded down into the dialysis tube, served as the outlet. For experiment 1, the dialysate flow rate was 1 µl/min; samples were collected every 3 min into microcentrifuge tubes (250 µl), placed on dry ice, and injected within 1 hr onto a capillary column for analysis of DA concentration by HPLC with electrochemical detection (HPLC-EC). For experiment 2, the dialysate flow rate was 0.5 µl/min, and samples were collected every 10 min. For both experiments, the dialysis perfusion medium was a modified Ringer's solution consisting of 138 mM NaCl, 2.7 mM KCl, and 1.2 mM CaCl2, pH 7.0. Flow was controlled by a Harvard syringe infusion pump (model 22; Cambridge, MA). On the morning of each microdialysis session, subjects were briefly anesthetized with ether to allow for insertion of the microdialysis probe(s). Flow of dialysate began immediately, and a 5 hr stabilization period was allowed before sample collection began. All microdialysis data are presented as percentage of baseline [which was established by taking the average of three consecutive prefemale (experiment 1) or predrug (experiment 2) samples].
HPLC. Detection of DA was accomplished using capillary HPLC-EC. Each sample was loaded manually into a VALCO self-actuating injector valve, delivering 500 nl to a C18 reverse-phase capillary column (0.3 mm i.d. × 5.0 cm; 3 µm spheres; LC Packings, San Francisco, CA). The mobile phase consisted of 30 mM citric acid, 50 mM sodium acetate, 0.027 mM Na2EDTA, and 0.25 mM octyl sodium sulfate, with 2.5% acetonitrile and 0.2% tetrahydrofuran (v/v), pH 3.6, and was delivered using a Gilson, Inc. (Middleton, WI) model 307 pump operating at 0.5 ml/min and equipped with an Acurate flow splitter (LC Packings). The flow splitter provided 6 µl/min of pulsation-free mobile phase to the analytical column. Dopamine oxidation was detected via an Antec DECADE controller (Leiden, The Netherlands) using a micro flow cell (11 nl volume) with a glassy carbon working electrode maintained at a potential of +0.7 V relative to a Ag/AgCl reference electrode. The system was calibrated daily with a freshly prepared DA standard at a concentration of 1 pg/µl (0.5 pg on the column).
Procedures. In experiment 1, after the 5 hr stabilization period and after collection of baseline dialysate samples, an estrous female was introduced into the male's testing arena, and copulation began. The male was allowed to copulate for up to three ejaculations. During this time, samples were collected in 3 min bins and labeled as those collected during copulation (COP) and those collected during sexual quiescence after an ejaculation (PEI). Three groups of samples (based on the male's behavior during collection) were thus established for subsequent HPLC analysis of DA content: baseline (BL), COP, and PEI.
In experiment 2, after the 5 hr stabilization period and after collection of baseline samples via the microdialysis probe located in the NAcc, flow was initiated in the probe located in the ipsilateral LHAA, which delivered either 5-HT [1 mg/ml (5.6 mM); Sigma, St. Louis, MO] or vehicle (Ringer's solution). Dialysate samples continued to be collected from the NAcc in 10 min bins during 40 min of LHAA perfusion. To test for 5-HT suppression of copulation-elicited NAcc DA release, we placed an estrous female into the male's testing arena during collection of the final sample, concurrent with LHAA 5-HT perfusion (i.e., time, 30-40 min after baseline). All males displayed some sexual behaviors; however, their performance was not scored.
Histology. After the microdialysis session, animals were deeply anesthetized with sodium pentobarbital, and cresyl violet dye was perfused through their microdialysis probe(s). Subjects were then decapitated, and their brains were removed for histological verification of probe placement. Only those animals with blue dye in the region of the NAcc (experiment 1) and LHAA (experiment 2) were used for statistical analysis.
Data analysis. For experiment 1, as noted above, dialysate collected from the NAcc was grouped into three behavioral categories: BL, COP, and PEI (expressed as percentages). A one-way ANOVA was conducted on the mean DA percentages for these three groups. Because the test for normality failed (p < 0.001), a Kruskal-Wallis one-way ANOVA on ranks was performed, followed by post hoc comparisons using the Dunn's method. For experiment 2, a two-way repeated measures ANOVA was used, with perfusate (5-HT vs vehicle) as the between factor and time (6 or 10 min dialysis bins) as the within factor, to test the effects of 5-HT perfusion into the LHAA on NAcc DA levels. Post hoc Scheffé comparisons were made according to Kirk (1968)
RESULTS
Experiment 1: DA release in the NAcc during copulation and after ejaculation
DA release in the NAcc followed a predictable pattern reflective of an activational role for this neurotransmitter in copulation. A typical pattern for an individual animal can be seen in Figure 1A; DA release was high during copulation but decreased after each ejaculation (i.e., during the PEI). The ANOVA on ranks for the grouped data revealed a significant difference in mean dialysate DA levels across behavioral categories [H(2) = 14.794; p < 0.001; Figure 1B]. Post hoc comparisons showed that DA was significantly higher in samples collected during copulation, compared with those collected during either BL or the PEI (p < 0.05).
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Figure 1. In vivo microdialysis of DA release from the NAcc of male rats during sexual behavior sessions. A, Representative example of temporal changes in a single rat. B, Mean change in DA release (±SEM) for a group of six rats. Samples were collected at 3 min intervals during three ejaculatory series and are designated precopulatory BL (filled circles), COP (open circles), or PEI (hatched circles). Dopamine content was significantly greater in samples collected during copulation, compared with samples collected under BL and PEI conditions (**p < 0.05).
Experiment 2: effects of 5-HT in the LHAA on DA in the NAcc
Reverse dialysis of 5-HT into the LHAA decreased the basal release of NAcc DA and also prevented the enhanced release normally seen during copulation (Fig. 2). The ANOVA conducted on these data detected a significant effect of groups [F(1,10) = 46.324; p < 0.001] and time [F(5,50) = 11.232; p < 0.001] and a group × time interaction [F(5,50) = 22.876; p < 0.001]. Post hoc comparisons revealed that DA was significantly lower in each of the four dialysate samples collected during 5-HT perfusion, compared with baseline values (p < 0.05). Animals receiving vehicle into the LHAA showed a significant increase in NAcc DA relative to baseline (p < 0.05) during copulation; however, no such increase was observed in the animals receiving 5-HT into the LHAA.
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Figure 2. Temporal change in DA concentration of the dialysate collected from the NAcc before and during 40 min of 5-HT perfusion into the LHAA of six male rats. Samples were collected at 10 min intervals. An estrous female was introduced to the male, and copulation was allowed during collection of the final sample during 5-HT perfusion. A significant decrease in DA occurred throughout the entire 5-HT perfusion period. This treatment blocked the increase in NAcc DA release seen in control animals [*p < 0.05, perfusion times vs time 0 (baseline)]. VEH, Vehicle.
DISCUSSION
These findings demonstrate a neurochemical link between the hypothalamic and mesolimbic systems of the brain that may promote sexual quiescence during the PEI. In experiment 1 we established that extracellular DA levels increase in the NAcc of male rats during copulation but then decrease after ejaculation, during the PEI. Similar results have been reported, based on in vivo chronoamperometric techniques (Phillips et al., 1991
Lateral hypothalamic 5-HT levels, which increase after ejaculation, may contribute to the sexual quiescence of the PEI. Administering 5-HT into the LHAA via reverse dialysis in experiment 2, like ejaculation, produced an immediate decrease in the extracellular levels of DA in the NAcc. Dopamine continued to decline steadily throughout 5-HT administration. This treatment also prevented the female-elicited DA increase that is normally associated with copulation.
We reported recently that extracellular 5-HT increased in the LHAA after ejaculation; microinjection of an SSRI into this region delayed the onset of sexual activity (similarly to the PEI) and also delayed ejaculation after copulation began but did not interfere with general locomotion (Lorrain et al., 1997
Inhibitory control over copulation during the PEI is an important factor in reproductive success. Too early resumption of copulation would dislodge the sperm plug that promotes sperm transport to the female's uterus (Adler and Zoloth, 1970
The LHAA may be well suited for modulating sexually relevant information from the hypothalamus to the rest of the brain. The lateral zone of the hypothalamus has been described as controlling arousal and motivated behavior (Benarroch, 1993
There are at least two potential pathways that may mediate LHAA 5-HT influences on NAcc DA release (Fig. 3). The LHA is included in a group of structures that comprise the subpallidal area, which has been shown to have reciprocal connections with the NAcc (Hakan et al., 1992
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Figure 3. Schematic representation of possible neural circuits involved in LHAA 5-HT inhibition of NAcc DA release. DA release may be influenced from 5-HT acting on direct projections from the LHAA to the NAcc (A) or indirect projection neurons reaching the VTA (B). Adapted from Paxinos and Watson (1982)
The NAcc terminal field is comprised of two main subregions, the shell and the core (for review, see Deutch et al., 1993
Although copulation did not elicit a DA response in the NAcc ipsilateral to the 5-HT reverse dialysis (experiment 2), all males were able to copulate, possibly because of normal DA activity in the unaffected contralateral hemisphere. Behavioral parameters were not recorded, so it is impossible to know whether 5-HT animals were different from controls. However, bilateral microinjections of an SSRI into the LHAA did delay and slow copulation in a previous experiment (Lorrain et al., 1997
These findings may have relevance for serotonergic control over other behaviors. Mesoaccumbens DA activity contributes to the activational impetus for many forms of motivated behavior (Koob, 1996
The present data may also provide insight into the effects of altered 5-HT activity on electrical self-stimulation of the brain and intravenous drug self-administration. These behaviors are under the control of mesoaccumbens DA activity (for review, see Di Chiara, 1995
In conclusion, extracellular DA in the NAcc increased during copulation but then decreased after ejaculation. Elevating LHAA 5-HT via reverse dialysis decreased extracellular DA during both basal conditions and copulation. These data, together with previous findings (Lorrain et al., 1997
FOOTNOTES Received April 9, 1999; accepted June 11, 1999.
This research was supported by National Institute of Mental Health Grant MH40826 to E.M.H.
Correspondence should be addressed to Dr. Elaine M. Hull, Department of Psychology, State University of New York at Buffalo, Buffalo, NY 14260.
Dr. Lorrain's present address: Department of Psychiatry, University of Chicago, MC 3077, 5841 South Maryland Avenue, Chicago, IL 60637.
Dr. Matuszewich's present address: Department of Psychiatry, Case Western Reserve University, 11100 Euclid Avenue, Cleveland, OH 44106-5000.
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