Abstract
Dopamine (DA) is released from somatodendritic sites of neurons in the substantia nigra pars compacta (SNc) and ventral tegmental area (VTA), where it has neuromodulatory effects. The aim of this study was to evaluate the role of D2 autoreceptor inhibition in the regulation of this somatodendritic release in each region. Fast cyclic voltammetry at carbon fiber microelectrodes was used to measure electrically evoked DA release in vitro. Furthermore, we compared D2 regulation of somatodendritic release with the more familiar axon terminal release in caudate putamen (CPu) and nucleus accumbens (NAc). Evoked DA release was TTX-sensitive at all sites. There was significant D2 autoinhibition of DA release in SNc; however, this mechanism was two- to threefold less powerful, as compared with axon terminal release in CPu. In contrast to SNc, somatodendritic release in VTA was not under significant D2 receptor control, whereas release in the respective axon terminal region (NAc) was controlled strongly by autoinhibition. Thus, these data indicate that, first, autoinhibition via D2receptors consistently plays a less significant role in the control of somatodendritic than axon terminal DA release, and, second, even at the level of somatodendrites themselves, D2 autoinhibition displays marked regional variation. In the light of previous data indicating that DA uptake processes are also less active in somatodendritic than in terminal regions, these results are interpreted as indicating that DA transmission is regulated differently in somatodendritic zones, as compared with axon terminals, and thus may have different functional consequences.
- somatodendritic release
- dopamine
- substantia nigra
- ventral tegmental area
- striatum
- D2 receptor
- autoreceptor
Dopamine (DA) is stored and released from somatodendritic regions of the dopaminergic neurons of the substantia nigra pars compacta (SNc) (A9) and ventral tegmental area (VTA) (A10) (Björklund and Lindvall, 1975; Geffen et al., 1976; Nieoullon et al., 1977). Neuromodulatory actions of somatodendritic DA include autoreceptor inhibition of impulse propagation (Groves et al., 1975;Aghajanian and Bunney, 1977; Lacey et al., 1987, 1990; Mercuri et al., 1989) and heteroreceptor regulation of nondopamine transmission from systems innervating these regions (Gale et al., 1977; Reubi et al., 1978; Waszczak and Walters, 1983, 1984, 1986; Lantin Le Boulch et al., 1991; Aceves et al., 1992; Cameron and Williams, 1993). However, somatodendritic signaling may differ from axon terminal transmission in several respects (see Rice et al., 1997). For example, postsynaptic specializations apposed to dopaminergic dendrites are sparse (Wilson et al., 1977; Reubi and Sandri, 1979; Cuello, 1982; Groves and Linder, 1983), and extrasynaptic plasmalemmal receptors for DA are abundant in the SN and VTA (Sesack et al., 1994; Yung et al., 1995). Furthermore, release is regulated less strictly by DA reuptake in somatodendritic than in striatal axon terminal regions (Cragg et al., 1997). Taken together, these findings suggest that somatodendritic DA signaling relies on extrasynaptic diffusion or “volume transmission” (Fuxe and Agnati, 1991; Nicholson and Rice, 1991). Thus, the time course and sphere of action of somatodendritic DA may differ significantly from a large part of the neurotransmission at axon terminal synapses.
Factors that regulate the extracellular concentration of DA ([DA]o) will be pivotal in determining the degree of neuromodulation offered by DA. Defining these factors in SNc and VTA will be a vital step in understanding fundamental features of somatodendritic signaling in these key regions. There are two mechanisms that are central in the control of axon terminal DA neurotransmission in striatum in addition to DA synthesis and the initial response to depolarization: DA uptake via the DA transporter (DAT) (Bull et al., 1990; Cass et al., 1992; Kawagoe et al., 1992;Nicholson, 1995; Giros et al., 1996) and inhibition of release via presynaptic D2-like autoreceptors (Palij et al., 1990; Bull and Sheehan, 1991; Limberger et al., 1991; Trout and Kruk, 1992; Garris et al., 1994). In contrast, DA uptake in somatodendritic regions is markedly less avid (Nissbrandt et al., 1991; Simon and Ghetti, 1993;Cragg et al., 1997). Furthermore, it is unclear whether autoreceptor inhibition is a factor in the regulation of somatodendritic DA release (Nissbrandt et al., 1985; Kalivas and Duffy, 1991; Nissbrandt and Hjorth, 1992) and how any such mechanism might function in the SNc versus VTA. Such comparison of regional function might be crucial for understanding both the physiology and pathophysiology of midbrain dopaminergic neurons, given the regional susceptibility of these cell groups to neurodegeneration, e.g., in Parkinson’s disease (Gibb and Lees, 1991). With the use of fast cyclic voltammetry and carbon fiber microelectrodes, it is possible to measure DA release from adjacent somatodendritic regions (Cragg et al., 1997; Rice et al., 1997). Thus, in this study we compare directly the function of autoreceptor control of evoked DA release between somatodendrites and terminals and between the somatodendritic regions SNc and VTA.
MATERIALS AND METHODS
Brain slice preparation. Brain slices were prepared as described previously (Cragg et al., 1997; Rice et al., 1997) from male albino guinea pigs (250–450 gm). A block of midbrain or rostral neostriatum was isolated over ice, and slices 400 μm thick were cut on a Vibratome (Lancer Series 1000) in ice-cold artificial cerebrospinal fluid (HEPES-ACSF), which contained (in mm): NaCl 120, NaHCO3 20, glucose 10, HEPES acid 6.7, KCl 5, HEPES salt 3.3, CaCl2 2, and MgSO4 2, saturated with 95%/O2/5% CO2. Slices were maintained in HEPES-ACSF for at least 1 hr before transferral to a recording chamber. The coordinates of midbrain slice taken correspond approximately to A8.0–A8.7 mm anterior (A) to the interaural line, according to the atlas of Smits et al. (1990). All slices were equilibrated with the superfusion medium at 32°C for an additional 30 min before experimentation. The superfusion solution contained (in mm): NaCl 124, NaHCO3 26, glucose 10, CaCl2 2.4, KCl 3.7, MgSO4 1.3, and KH2PO4 1.3, gassed with 95% O2/5% CO2. Flow rate was 1.3 ml/min.
Carbon fiber microelectrodes and fast cyclic voltammetry (FCV).Carbon fiber microelectrodes for FCV were spark-etched to a tip length of 30–50 μm and beveled to a tip diameter of 2–4 μm (MPB Electrodes, London, UK). Electrode calibrations were performed in the recording chamber postexperiment, with 1–5 μm DA in Ringer’s solution at 32°C. Calibration solutions were made immediately before use from stock solutions in 0.1 mHClO4. The detection limit for [DA]o in situ was 30–40 nm.
Voltammetric measurements were made with a Millar Voltammeter (P.D. Systems, West Moseley, UK) as described previously (Cragg et al., 1997;Rice et al., 1997); the applied waveform was a dual-triangle wave scanning from −0.7 to +1.3 V and back versus Ag/AgCl (see also Figs.3, 5). Scan rate was 800 V/sec, and the sampling frequency was 4 Hz. All current records illustrated are faradaic currents obtained by electronic subtraction of the background current. Background-subtracted voltammograms were monitored on a Gould 1602 storage oscilloscope and recorded on digital audiotape for analysis with Strathclyde Electrophysiology software. In caudate putamen (CPu),y–t traces of [DA]o versus time were obtained by sampling the current at the DA oxidation peak (+530 mV vs Ag/AgCl). In striatum in general, changes in [DA]o can be resolved more readily against time than in midbrain, owing to the greater ratio of signals to background shifts than in midbrain; during stimulation, DA voltammograms are accompanied in part, but followed in large part, by some distortion because of pH- and Ca2+-dependent changes in background current (Rice and Nicholson, 1989, 1995; Jones et al., 1994; Rice et al., 1994).
Electrical stimulation. Bipolar stimulating electrodes were prepared from Teflon-coated platinum wire as previously described (Cragg et al., 1997; Rice et al., 1997) but with a smaller diameter: bare diameter 50 μm, coated diameter 75 μm, tip separation 50 μm, and a total array size of ∼200 μm. The tips of the bipolar electrode were positioned for surface stimulation as previously described (Cragg et al., 1997; Rice et al., 1997). The two forms of stimulation used were a train of pulses (0.1 msec pulses, 18 V) at either 10 Hz (see Rice et al., 1997) for 3–4 sec or a “pseudo-one pulse” train (Singer, 1988) at 100 Hz for 0.1 sec. Stimulus pulses were blanked electronically during voltammetric scanning to prevent interference with the FCV signal. The voltammetric microelectrode was inserted 50–100 μm into the tissue directly between the stimulating electrodes.
Drugs and solutions. All drugs and chemicals were obtained from Sigma (Poole, Dorset, UK) except (−)-quinpirole (RBI, St Albans, Herts, UK). Fresh 10,000× stock solutions of drugs were made daily in deionized H2O. All solutions were applied by superfusion.
Experimental design and data analysis. Experiments were conducted as described previously (Cragg et al., 1997; Rice et al., 1997): several adjacent recording sites, each separated by ∼200 μm, were sampled within a given slice. Control recordings were made in one hemisphere and compared with the experimental condition recordings from paired sites in the contralateral hemisphere. SNc (A9) is defined as lateral to the accessory optic tract and VTA (A10) as medial. All slices were stained for tyrosine hydroxylase immunoreactivity (TH-ir), as described previously (Hajós and Greenfield, 1993), to confirm correct anatomical placement. All data are expressed as mean ± SEM; n = number of observations. For the figures, each mean percentage of control (“mean % of control”) is the mean from a treatment population represented as a percentage of the mean of the paired control population. Comparisons for differences in means were assessed by paired Student’s t tests or Wilcoxon signed ranks test (TTX).
Important considerations for an appropriate stimulation protocol.Autoreceptor activity in vitro is highly sensitive to the duration of the electrical stimulation applied (Singer, 1988): first, different stimulation durations (and intensities) will elicit varying [DA]o and therefore a varying concentration-dependent autoreceptor tone; second, there is a threshold time period for autoreceptor activation after transmitter release (Singer, 1988; O’Connor and Kruk, 1991, 1992; Trout and Kruk, 1992;Palij and Stamford, 1993; Wieczorek and Kruk, 1994). For example, a threshold time for activation of D2 receptors in the rat limbic forebrain requires a minimum exposure to DA of 500–1000 msec for an antagonist response to be detectable (Trout and Kruk, 1992). Hence, appropriate stimulus parameters must be selected when determining the role of autoreceptors in the control of transmitter release by application of exogenous agonists or antagonists. Similarly, a technique with appropriate time resolutions, such as FCV, is necessary.
The effects of competitive autoreceptor antagonists can be observed only in the presence of sufficient activation of the autoreceptor population by released DA against which an antagonist can compete. Thus, a stimulation train is required that will exceed any activation threshold time and thus ensure sufficient time- and concentration-dependent receptor activation by endogenous DA. The multisecond stimulation trains (at 10 Hz) that are appropriate for eliciting somatodendritic DA release (Cragg et al., 1997; Rice et al., 1997) are suitable for this experiment. On the other hand, the effect of an exogenous autoreceptor agonist requires that activation of the autoreceptor population by the endogenous agonist, DA, is submaximal. Thus, the effect of an exogenous agonist on transmitter release is best examined with minimal endogenous tone at the autoreceptor, i.e., after single-pulse stimulation (Singer, 1988). A single-pulse stimulation results in less endogenous tone at the D2 autoreceptor, as compared with multiple second trains, by two possible mechanisms: first, resultant evoked [DA]ois less, and/or, second, the stimulation time is shorter than the threshold time for activation of the DA autoreceptor by endogenous DA. However, a train of pulses is necessary to obtain measurable amounts of [DA]o from somatodendritic regions in this system (Rice et al., 1997). Short high-frequency trains, or “pseudo-one pulse” stimulations (≤ 100 msec; see also Palij and Stamford, 1993), offer a compromise to a single pulse whereby high transmitter efflux is evoked but in a period of time too short to activate the DA autoreceptor (Mayer et al., 1988; Singer, 1988).
FCV at a carbon fiber microelectrode has the appropriate time and space resolutions and sensitivity to resolve DA release at a subsecond sampling rate in response to subsecond stimuli. As a result, the technique is suited ideally to monitoring the role of autoreceptor control of DA release in vitro, which requires subsecond control of stimuli duration and transmitter measurements.
RESULTS
Identification of DA release
DA was detected with FCV at a carbon fiber microelectrode after electrical stimulation in SNc, VTA, CPu, or nucleus accumbens (NAc), as described previously (Bull et al., 1990; Palij et al., 1990; Limberger et al., 1991; Trout and Kruk, 1992; Iravani et al., 1996; Cragg et al., 1997; Rice et al., 1997), with either multisecond stimulation trains (30–40 pulses at 10 Hz) or a pseudo-one pulse stimulation (10 pulses at 100 Hz). The identification of extracellular signals evoked by 10 Hz stimulation as DA and not other monoamines or metabolites was confirmed previously (Cragg et al., 1997; Rice et al., 1997) on the basis of anatomical, electrochemical (see also Figs. 3, 5), and pharmacological criteria. Signals evoked in the same regions in the current study by 100 Hz pseudo-one pulse stimuli were also identified as DA: DA signals were obtained only in TH-ir regions and had identical oxidation (approximately +530 mV) and reduction (approximately −200 mV) peak potentials to exogenously applied DA and DA signals obtained previously (see also Figs. 3, 5). No unstimulated levels of DA were detectable.
TTX sensitivity of evoked DA release
Evoked DA release was sensitive to inhibition by TTX (1 μm) in all midbrain and axon terminal regions. Somatodendritic DA release in both SNc and VTA (40 pulses, 10 Hz) was reduced significantly to 6 ± 4% of control release in paired sites from 0.21 ± 0.02 μm (control) to 0.01 ± 0.01 μm (TTX) (p < 0.001,n = 16). Similarly, evoked DA release across CPu and NAc (30 pulses, 10 Hz) was abolished from 0.73 ± 0.04 μm (control) to undetectable levels (TTX) (p < 0.01, n = 9).
DA release evoked by 10 Hz stimulation trains
The mean peak [DA]o evoked by a multisecond 10 Hz stimulation train in somatodendritic regions was (in μm± SEM): 0.26 ± 0.03, n = 26 (SNc) and 0.44 ± 0.05, n = 26 (VTA) (Fig. 1). The mean evoked [DA]o released from DA axon terminal regions during a comparable 10 Hz stimulation train as used previously (Cragg et al., 1997) was (in μm ± SEM): 1.01 ± 0.11,n = 38 (CPu) and 0.75 ± 0.06, n = 14 (NAc) (Fig. 1). Thus, with the current stimulation paradigm, the ratios of evoked [DA]o in terminal versus somatodendritic regions were approximately fourfold in A9 (CPu vs SNc) and ∼1.7-fold in A10 (NAc vs VTA). These ratios are independent of the duration (<5 sec) of the stimulus train in striatal regions, because peak [DA]o in both CPu and NAc is attained within the first second of 10 Hz stimulation (see Fig. 3b).
DA release evoked by pseudo-one pulse stimulation
When a shorter train of stimulation, a pseudo-one pulse stimulus (Singer, 1988), was used (100 msec train of 10 pulses at 100 Hz), the concentrations of [DA]o released in each region were (in μm ± SEM): 0.18 ± 0.02, n = 16 (SNc); 0.36 ± 0.04, n = 14 (VTA); 1.40 ± 0.19, n = 29 (CPu); and 1.42 ± 0.14,n = 24 (NAc) (Fig. 1). Compared with evoked [DA]o during the multisecond stimulus trains at 10 Hz, [DA]o in somatodendritic regions was reduced by 1.5-fold in SNc (p < 0.05) and by 1.2-fold in VTA, whereas [DA]o in terminal regions was enhanced by 1.4-fold in CPu (p < 0.05) and by 1.9-fold in NAc (p < 0.01). Therefore, with a pseudo-one pulse stimulus train, the ratios of evoked [DA]o in terminal versus somatodendritic regions were approximately doubled to eightfold in A9 (CPu vs SNc) and fourfold in A10 (NAc vs VTA).
D2 receptor control of DA release evoked by 10 Hz trains
In the presence of a supramaximal concentration (see Lacey et al., 1987) of the D2-antagonist sulpiride (1 μm), there was a significant increase in mean peak evoked [DA]o in SNc to 131 ± 13% of paired controls from 0.34 ± 0.04 μm to 0.44 ± 0.05 μm (p < 0.05, n = 13) (Figs. 2a, 3a). In contrast, evoked [DA]o in the adjacent VTA was not affected significantly by sulpiride application at 106 ± 11% of paired controls, representing 0.57 ± 0.05 μm in control and 0.61 ± 0.06 μm with sulpiride (Fig.2a, n = 16).
Evoked DA release in nerve terminal regions in both CPu and NAc was increased markedly by sulpiride. Maximum evoked [DA]o in CPu was increased significantly to 242 ± 23% of paired controls from 1.74 ± 0.13 μm to 4.22 ± 0.39 μm (p < 0.001, n= 14) (Figs. 2a, 3b). In NAc, evoked [DA]o was increased significantly to 265 ± 19% of paired controls from 0.72 ± 0.10 μm to 1.92 ± 0.14 μm (p < 0.01,n = 3) (Fig. 2a). The degree of modulation of evoked [DA]o by sulpiride in terminal regions (CPu) was significantly greater than in somatodendritic regions (SNc) (p < 0.001; Student’s t test). In addition, the action of sulpiride demonstrated a time dependency: in CPu, [DA]o increasingly was enhanced with increasing time of stimulus and was enhanced significantly compared with control only after at least 750 msec stimulation (Fig.3b).
In somatodendritic regions the D2 receptor agonist quinpirole (1 μm) had no inhibitory effect on evoked [DA]o (40 pulses, 10 Hz) that might be comparable to the action of sulpiride. Evoked [DA]o from SNc in quinpirole was 104 ± 15% of paired controls, representing no significant change from 0.19 ± 0.03 μm in control versus 0.20 ± 0.03 μm in quinpirole (n = 13) (Figs. 2b, 3a). Similarly evoked [DA]o from VTA was unaffected by quinpirole at 91 ± 16% of control: 0.24 ± 0.03 μm versus 0.22 ± 0.04 μm (n = 10) (Fig.2b).
Conversely, in DA terminal regions, there was a significant decrease in evoked [DA]o (30 pulses, 10 Hz) during quinpirole administration in both CPu and NAc. Maximum evoked [DA]oin CPu was reduced significantly to 31 ± 2% of paired controls from 0.58 ± 0.04 μm to 0.18 ± 0.01 μm (p < 0.001, n= 25) (Figs. 2b, 3b). In NAc, evoked [DA]o was reduced significantly to 56 ± 4% of paired controls from 0.76 ± 0.08 μm to 0.42 ± 0.03 μm (p < 0.01,n = 11) (Fig. 2b). Whereas the action of sulpiride was increasingly prominent after 750 msec of stimulation, the effect of quinpirole was, in contrast, most pronounced in the initial phase of DA release, before 750 msec of stimulation (Fig.3b).
D2 receptor control of DA release evoked by a pseudo-one pulse stimulus
Sulpiride (1 μm) had no significant effect on [DA]o evoked by pseudo-one pulse stimulation (10 pulses, 100 Hz) in any region tested (Fig. 4a). Evoked [DA]o was not affected significantly in the somatodendritic regions, SNc (93 ± 5%; 0.17 ± 0.02 μm in control vs 0.16 ± 0.01 μm in sulpiride, n = 7) (Figs. 4a,5a) or VTA (82 ± 17%; 0.28 ± 0.06 μm in control versus 0.23 ± 0.05 μm in sulpiride, n = 5) (Fig.4a) or in the DA terminal regions, CPu (102 ± 8%; 0.65 ± 0.05 μm in control versus 0.65 ± 0.05 μm in sulpiride, n = 10) (Figs.4a, 5b) or NAc (104 ± 11%; 1.33 ± 0.15 μm vs 1.38 ± 0.15 μm,n = 8) (Fig. 4a).
In contrast, with the use of a pseudo-one pulse stimulation paradigm, 1 μm quinpirole subsequently caused a significant decrease in evoked somatodendritic [DA]o in SNc to 70 ± 10% of paired controls from 0.19 ± 0.02 μm to 0.13 ± 0.02 μm (p < 0.05,n = 8) (Figs. 4b, 5a). In contrast, evoked [DA]o in VTA remained unaffected by quinpirole at 98 ± 14% of paired controls, 0.43 ± 0.05 μm in control versus 0.42 ± 0.06 μmin quinpirole (n = 8) (Fig. 4b). The most significant changes in one-pulse-evoked [DA]o after quinpirole were seen in axon terminal regions (Fig. 4b). Quinpirole significantly reduced evoked [DA]o in CPu to 29 ± 2% of paired controls from 2.48 ± 0.44 μm to 0.71 ± 0.03 μm(p < 0.001, n = 12) (Figs.4b, 5b) and in NAc to 34 ± 3% of paired controls from 1.46 ± 0.13 μm to 0.50 ± 0.04 μm (p < 0.001, n= 23) (Fig. 4b).
DISCUSSION
Characteristics of evoked DA release
We previously have determined that electrically evoked somatodendritic release of DA from SNc is dependent on extracellular calcium and stimulation frequency, is TTX-insensitive (Rice et al., 1997), and, in contrast to some suggestions (Nirenberg et al., 1996), is not mediated by reversal of the DA uptake transporter (DAT) (Cragg et al., 1997). On the other hand, the DAT is active in the SNc in the reuptake of DA (Cragg et al., 1997). In those studies the TTX insensitivity, coupled with the Ca2+ dependence, suggested that release was stimulated by directly activating voltage-dependent Ca2+ channels, independent of the status of voltage-dependent Na+ channels. Previous studies have used TTX sensitivity to address the question of whether somatic Na+ channels, i.e., neuronal firing, are required for somatodendritic release. However, the finding that nonattenuating potentials in DA dendrites also are mediated by voltage-dependent Na+ channels (Häusser et al., 1995) indicates that experiments with TTX alone do not address that particular question. In the present study a release mechanism that was TTX-sensitive was recruited by reducing our stimulus current either directly, by reducing applied voltage, or indirectly, by increasing the resistance of the stimulating electrode–solution interface (reduced surface area). Thus, we are now able to study somatodendritic release elicited by a mechanism that is dependent on voltage-dependent Na+ channels.
Comparison of somatodendritic and terminal DA release
Evoked [DA]o was greater from axon terminal than from somatodendritic regions, as previously reported (Iravani et al., 1996; Cragg et al., 1997; Rice et al., 1997), and consistent with tissue DA content (Heeringa and Abercrombie, 1995). Moreover, within a given region, the ratios of peak [DA]o released in response to the two types of pulse trains were different in somatodendritic, as compared with terminal, regions. Whereas in both SNc and VTA a sustained 10 Hz train evoked greater[DA]o than the pseudo-one pulse, in CPu and NAc a sustained 10 Hz train evoked lower peak [DA]othan a pseudo-one pulse. Such a discrepancy arises from a complex interplay of many factors, including the ability to follow depolarization frequency and processes that constrain [DA]o during stimulation, such as storage, uptake, and autoinhibition of release. Thus, these data are indicative of a net prevailing difference in such processes at somatodendritic versus terminal levels. In fact, somatodendritic and axon terminal sites may differ in their primary DA storage site (Cuello and Kelly, 1977; Mercer et al., 1979; Wassef et al., 1981; Heeringa and Abercrombie, 1995) (see also Rice et al., 1997), whereas DA reuptake systems are more active in axon terminal regions (Cragg et al., 1997). Furthermore, as the current data show, there is, indeed, heterogeneity in the D2receptor control of release.
D2 receptor control of axon terminal DA release
Consistent with previous data (Palij et al., 1990; Bull and Sheehan, 1991; Limberger et al., 1991; Trout and Kruk, 1992; Garris et al., 1994), evoked DA release in CPu and NAc was regulated strongly by D2 autoreceptor inhibition, as indicated by the marked enhancement of [DA]o after D2 receptor antagonism by sulpiride and the reduction of [DA]o during D2 agonism by quinpirole. The time course of autoinhibition in CPu was consistent with a time delay for D2 receptor activation by DA in vitro. In particular, competitive D2 antagonism by sulpiride was seen only after at least 750 ± 250 msec of stimulation and not during only a pseudo-one pulse train; in contrast, a competitive agonist action of quinpirole was most prominent during the pseudo-one pulse and before 500–1000 msec of 10 Hz stimulation despite the greatest evoked [DA]o in this period. A comparable delay period has been reported previously for activation of D2 receptors in striatum after DA release (Trout and Kruk, 1992), for α2receptors in bed nucleus of stria terminalis after norepinephrine release (Palij and Stamford, 1993), and for 5-HT1Areceptors in dorsal raphe nucleus after 5-HT release (O’Connor and Kruk, 1991, 1992).
D2 receptor modulation of somatodendritic DA release in SNc
Somatodendritic DA release evoked in SNc was enhanced significantly by D2 receptor antagonism and reduced by D2 receptor agonism during appropriate stimuli. These data indicate directly, for the first time, that D2 receptors are operative as an autoinhibitory mechanism to regulate somatodendritic release. However, D2 autoinhibition of somatodendritic release differs from terminal release both quantitatively and qualitatively. First, the degree of modulation of [DA]o by D2 receptors was approximately twofold less in SNc than in CPu. Second, the action of D2agents on somatodendritic release was observed only during the stimulation protocol optimized for the treatment. Specifically, the agonist effects of quinpirole in SNc were apparent only when the occupancy of the D2 receptor by endogenous transmitter release was minimized with a pseudo-one pulse stimulus, whereas in CPu an agonist effect was detected even throughout the sustained stimulus. Together, these quantitative and qualitative differences in D2 regulation of somatodendritic and terminal DA release suggest that D2 autoinhibition in SNc is less effective than in CPu presumably because of fewer D2 receptors.
Less effective autoinhibition of release, in conjunction with less DA reuptake via the DAT (Nissbrandt et al., 1991; Simon and Ghetti, 1993;Cragg et al., 1997), will result in an altogether different regulation of [DA]o in somatodendritic and axon terminal regions. Such functional variation, together with the differing anatomical constraints in these regions, e.g., sparse postsynaptic specializations in dendritic zones (Wilson et al., 1977; Cuello, 1982; Groves and Linder, 1983) and extrasynaptic location of DA receptors in the SNc and VTA (Sesack et al., 1994; Yung et al., 1995), support the notion that the neuromodulatory actions of somatodendritic release of DA differ in time course and sphere of influence from those of more familiar axon terminal release (Groves and Linder, 1983; Elverfors and Nissbrandt, 1991) (see also Rice et al., 1997).
D2 receptor modulation of somatodendritic DA release in VTA
Surprisingly, in contrast to SNc (A9), evoked [DA]oin the adjacent somatodendritic region, the VTA (A10), was unaffected by both sulpiride and quinpirole, irrespective of the stimulus. These observations suggest that D2 autoinhibition plays no part in regulating evoked DA release in VTA. However, this finding does not hold for the A10 path per se: DA release in the terminal region (NAc) is controlled strongly by autoinhibition, as demonstrated by other researchers (Bull and Sheehan, 1991; Trout and Kruk, 1992; Garris et al., 1994), and confirmed here. Although these findings in VTA are consistent with those of Iravani et al. (1996), who similarly failed to detect any D2 autoinhibition of evoked DA release, release in that study was TTX-insensitive, i.e., evoked by a mechanism that was uncoupled from some ionic mechanisms of regulation of membrane potential and thus also likely to be uncoupled from any D2receptor-mediated hyperpolarization. However, in the current study we demonstrate a lack of autoreceptor control of evoked somatodendritic release in VTA within a paradigm of release that is TTX-sensitive and thus also coupled to local membrane potential.
It cannot be discounted that the observed regional heterogeneity in the D2 receptor control of somatodendritic DA release in some manner might be related to the fact that the VTA may contain more distal dendrites than the SNc; many distal dendrites arising from the SNc actually ramify the SN pars reticulata (Björklund and Lindvall, 1975; Fallon and Moore, 1978). On the other hand, the heterogeneity in D2 receptor control is strongly consistent with accumulating evidence of greater expression levels of D2 protein in SNc than in VTA (Bouthenet et al., 1987;Morelli et al., 1988; Sales et al., 1989; Mansour et al., 1990; Le Moine and Bloch, 1991; Hurd et al., 1994). In particular, stronger autoinhibition of release in SNc than in VTA may be attributable to differential D2 receptor expression levels in the two tiers of neurons that comprise the midbrain DA cell groups. Ventral tier neurons found only in ventral SNc (Fallon and Moore, 1978; Gerfen et al., 1985, 1987) have higher expression and protein levels of the D2 receptor than dorsal tier cells found in dorsal SNc and throughout VTA (Chiodo et al., 1984; Shimada et al., 1992; Blanchard et al., 1994; Hurd et al., 1994; Sanghera et al., 1994; Ciliax et al., 1995; Freed et al., 1995). Similarly, the greater activity of DA uptake process via the DAT in SNc than in VTA (Cragg et al., 1997) might be attributable to the greater expression levels of the DAT in ventral tier cells (Shimada et al., 1992; Blanchard et al., 1994; Hurd et al., 1994; Sanghera et al., 1994; Ciliax et al., 1995; Freed et al., 1995). In any event, reduced autoreceptor control and uptake via the DAT in VTA suggest that released DA may be under a less strict regulation in VTA than in the adjacent SNc. Such regional variation in somatodendritic transmission in VTA and SNc may be important in the differential susceptibility of these cell groups to the pathophysiologies of schizophrenia and Parkinson’s disease, respectively.
Conclusions
In summary, this study demonstrates directly, for the first time, functional D2 autoinhibition of somatodendritic DA release in the SNc. On the other hand, autoinhibitory processes are less important in the regulation of somatodendritic than axon terminal [DA]o. In conjunction with a lower activity of DA uptake systems (Cragg et al., 1997), these data suggest that somatodendritic DA transmission thus will differ significantly from axon terminal transmission in both time course and sphere of action. Furthermore, regional variation in D2 autoinhibition of release between somatodendritic regions indicates that these findings not only describe fundamental physiological features of somatodendritic signaling but also may be pivotal for an understanding of the mechanisms underlying the regional pathophysiology of midbrain DA cells.
Footnotes
S.J.C. was funded by an E. P. Abraham Junior Research Fellowship (St. Cross College, Oxford) and a Goodger Scholarship (Oxford Medical School).
Correspondence should be addressed to Dr. S. J. Cragg, University Department of Pharmacology, Oxford University, Mansfield Road, Oxford OX1 3QT, UK.