Tonic Endovanilloid Facilitation of Glutamate Release in Brainstem Descending Antinociceptive Pathways

Animals.

Male Wistar rats (250–300 g) were housed 3 per cage under controlled illumination (12:12 h light/dark cycle; light on 06.00 h) and environmental conditions (ambient temperature 20−22°C, humidity 55–60%) for at least 1 week before the start of the experiments. Rat chow and tap water were available ad libitum. The experimental procedures were approved by the Animal Ethics Committee of the Second University of Naples. Animal care was in compliance with Italian (D.L. 116/92) and EEC (O.J. of E.C. L358/1 18/12/86) regulations on the protection of laboratory animals. All efforts were made to minimize animal suffering and to reduce the number of animals used.

Surgical preparation for intra-PAG microinjections.

To perform direct intra-VL PAG administrations of drugs or respective vehicle, 10% dimethylsulfoxide in artificial CSF (ACSF, composition in mm: KCl 2.5; NaCl 125; MgCl₂ 1.18; CaCl₂ 1.26), rats were anesthetized with pentobarbital (60 mg/kg, i.p.) and a 31-gauge, 12 mm-long stainless steel guide cannula was stereotaxically lowered until its tip was 1.5 mm above the ventrolateral PAG by applying coordinates from the atlas of Paxinos and Watson (1986) (AP: −7.8 mm and L: 0.5 mm from bregma, V: 4.3 mm below the dura). Ventrolateral PAG (VL-PAG) was considered in this study, because previous studies have shown the presence of excitatory output neurons projecting to OFF neurons in the RVM in that area (Sandkulher and Gebhart, 1984; Moreau and Fields, 1986). The cannula was anchored with dental cement to a stainless steel screw in the skull. We used a David Kopf stereotaxic apparatus (David Kopf Instruments, Tujunga, CA, USA) with the animal positioned on a homeothermic temperature control blanket (Harvard Apparatus Limited, Edenbridge, Kent). Direct intra-VL PAG administration of drugs, or respective vehicle, was conducted with a stainless steel cannula connected by a polyethylene tube to a SGE 1 μl syringe, inserted through the guide cannula and extended 1.5 mm beyond the tip of the guide cannula to reach the VL-PAG. Volumes of 200 nl drug solutions, or vehicle, were injected into the VL PAG over a period of 60 s and the injection cannula gently removed 2 min later. At the end of the experiment, a volume of 200 nl of neutral red (0.1%) was also injected in the VL-PAG 30–40 min before killing the rat. Rats were then perfused intracardially with 20 ml of PBS followed by 200 ml of 10% Formalin solution in PBS. The brains were removed and immersed in a saturated Formalin solution for 2 d. The injection site was ascertained by using 2 consecutive sections (40 μm), one stained with cresyl violet to identify nuclei and the other unstained to determine dye spreading. Only those rats whose microinjected site was located within the VL-PAG were used for data computation (see Fig. 3).

RVM microdialysis.

In vivo microdialysis experiments were performed in awake and freely moving rats. In brief, rats already implanted with guide cannula (as described above) and still anesthetized with pentobarbital (60 mg/kg, i.p.) were stereotaxically implanted with concentric microdialysis probes, which were constructed as previously described (Biggs et al., 1992), into the RVM using coordinates: AP: −11.5 mm and L: +0.3 mm from bregma, V: 10.5 mm below the dura (Paxinos and Watson, 1986). After a postoperative recovery period of ∼18 h dialysis was commenced by perfusing ACSF at a rate of 0.8 μl/min using a Harvard Apparatus infusion pump (model 22). On the day of the experiment each animal was placed in a Plexiglas cage and allowed to move freely. After an initial 60 min equilibration period, 12 consecutive 15 min dialysate samples were collected. On completion of each experiment, rats were anesthetized with pentobarbital and their brains perfused-fixed via the left cardiac ventricle with heparinized paraformaldehyde saline (4%). Brains were removed after fixation, and coronal sections cut to verify probe placements (see Fig. 3). Dialysates were analyzed for amino acid content using an HPLC method. The system comprised two Gilson pumps (model 303), a C18 reverse-phase column, a Gilson refrigerated autoinjector (model 231) and a Gilson fluorimetric detector (model 121). Dialysates were precolumn derivatized with o-pthaldialdehyde (OPA) (10 μl of dialysate + 10 μl of OPA) and amino acid conjugates resolved using a gradient separation. The detection limit of GABA and glutamate in 10 μl samples was ∼0.5–1 and 2–3 pmol, respectively. The mobile phase consisted of two components: (A) 50 mm sodium dihydrogen orthophosphate, pH 5.5, with 20% methanol and (B) 100% methanol. Gradient composition was determined with an Apple microcomputer installed with Gilson gradient management software. The mobile phase flow rate was maintained at 1.0 ml/min. Data was collected using a Dell Corporation PC system 310 interfaced to the detector via a Drew data collection unit.

Thermal withdrawal latency during microdialysis.

Thermal nociception was evaluated by using Plantar Test Apparatus (Ugo Basile, Varese, Italy). On the day of the experiment each animal, which had been previously implanted with a microdialysis probe, was placed in a plastic cage (22 × 17 × 14 cm; length × width × height) with a glass floor. After a 60 min habituation period, the plantar surface of the hind paw was exposed to a beam of radiant heat through the glass floor within the time interval between dialysate sample collection. The radiant heat source consisted of an infrared bulb (Osram halogen-bellaphot bulb; 8 V, 50 W). A photoelectric cell detected light reflected from the paw and turned off the lamp when paw movement interrupted the reflected light. Paw withdrawal latency was automatically displayed to the nearest 0.1 s; the cutoff time was 20 s to prevent tissue damage. Vehicle or drugs were microinjected into the PAG after the collection of five basal microdialysis samples and the simultaneous recording of five basal thermal withdrawal latencies every 30 min. The results were expressed as percentage of the maximum possible effect using the following formula: Nociceptive responses were measured every 15 min for a period of 2 h.

RVM extracellular recordings and tail flick test.

After implantation of the guide cannula into the VL-PAG (described in: Surgical preparation for intra-PAG microinjections), a tungsten microelectrode was stereotaxically lowered through a small craniotomy into the RVM (AP: 11.5; L: + 0.3; V: 9.9–10.9) (Paxinos and Watson, 1986) to record the activity of Neutral, ON and OFF cells (see Fig. 3). These neurons were identified by the characteristic OFF cell pause and ON cell burst of activity just before tail flick responses (Fields et al., 1983). Anesthesia was maintained with a constant, continuous infusion of propofol (5–10 mg/kg/h, i.v.). Anesthesia was adjusted so that tail flicks were elicited with a constant latency of 4–5 s. A thermal stimulus was elicited by a radiant heat source of a tail flick unit (Ugo Basile, Varese, Italy) focused on the rat tail ∼3–5 cm from the tip. From 35°C, the temperature increased linearly to 53°C and was adjusted at the beginning of each experiment to elicit a constant tail flick latency. Tail flicks were elicited every 3–4 min for at least 15–20 min before microinjecting drugs, or respective vehicle, into the VL-PAG.

Extracellular single-unit recordings were made in the RVM with glass insulated tungsten filament electrodes (3–5 MΩ) (Frederick Haer Company, Bowdoinham, ME). The recorded signals were amplified and displayed on analog and digital storage oscilloscope to ensure that the unit under study was unambiguously discriminated throughout the experiment. Signals were also fed into a window discriminator, whose output was processed by an interface (CED 1401) (Cambridge Electronic Design, Cambridge, UK) connected to a Pentium III PC. Spike2 software (version 4; Cambridge Electronic Design) was used to create peristimulus rate histograms on-line and to store and analyze digital records of single-unit activity off-line. Configuration, shape, and height of the recorded action potentials were monitored and recorded continuously, using a window discriminator and Spike2 software for on-line and off-line analysis. Once an ON or OFF cell was identified from its background activity, we optimized spike size before all treatments. This study only included neurons whose spike configuration remained constant and could clearly be discriminated from activity in the background throughout the experiment, indicating that the activity from one neuron only and from that same neuron was measured. Only one neuron was recorded in each rat.

Immunohistochemistry.

Animals were deeply anesthetized with pentobarbital and perfused transcardially with saline followed by ice-cold 4% paraformaldehyde in 0.1M phosphate buffer (PB), pH 7.4. Brains were removed, postfixed for 2 h and then washed. Tissues to be cut at cryostat were cryoprotected overnight in PB containing 30% (w/v) sucrose at 4°C until they sank. Serial cryostat sections were cut at 14 μm and mounted onto gelatin-coated slides (Mezel, Germany). For double immunofluorescence serial sections were incubated for 1 h in 10% normal donkey serum (NDS, Jackson Immunoresearch Laboratories, West Grove, PA) in PB containing 0.3% Triton X-100 (block solution). Subsequently the sections were incubated for 2 d at 4°C in a humid chamber with the respective polyclonal antibodies (all diluted in block solution). All sections were processed for anti-TRPV1 receptor immunoreaction (1:250 guinea pig anti-TRPV1, Abcam, Cambridge, UK) coupled to one of the following: rabbit anti-vesicular glutamate transporter-1 (VGLUT1) (1:500, SySy, Germany), rabbit anti-vesicular GABA transporter (VGAT) (1:250, SySy, Germany), rabbit-anti metabotropic glutamate receptor 7 (mGluR7) (1:500, Chemicon International, Germany) or rabbit anti-μ-opioid receptor (MOR) (1:1000, Abcam, Cambridge, UK). After three washes in PB, double immunofluorescence was revealed by incubation for 2 h in the appropriate fluorochrome conjugated secondary antibody: Alexa Fluor488 anti guinea pig (for TRPV1); Alexa Fluor546 anti rabbit (for VGLUT1, VGAT, mGluR7 and MOR) diluted 1:250 in NDS block solution. Thereafter, sections were washed with PB and coverslipped with Aquatex mounting medium (Merck, Darmstadt, Germany).

Controls included (1) preabsorption of diluted antibodies with their respective immunizing peptides (if not commercially available control peptides were synthesized on custom request by Inbios, Italy), and (2) omission of either the primary antisera or the secondary antibodies. These control experiments did not show staining. The sections processed for immunofluorescence were studied with an epifluorescence microscope (Leica DM IRB); settings for excitation of fluorescein isothiocyanate (488 nm) and Texas Red (543 nm) were identical throughout the analysis. Images were acquired using the digital camera Leica DFC 320 connected to the microscope and the image analysis software Leica IM500, which allows both single and merged pictures acquisitions. Digital images were processed in Adobe Photoshop, with brightness and contrast being the only adjustments made.

Quantification of immunoreactivity.

Quantification of the mean percentage value of the number of neurons double-labeled for TRPV1/VGLU1 or TRPV1/VGAT or TRPV1/mGluR7 or TRPV1/MOR was performed by an observer blinded to the experimental protocols, on the total of VL-PAG and RVM neurons identified with respect to the corresponding adjacent section labeled with cresyl violet and whose nuclei, unstained or lightly stained, were in the focal plane. The level of section evaluated for immunohistochemistry study covered the entire extension of the VL-PAG or RVM regions, approximately for 1.0 mm rostrally from bregma AP:-8.0 mm, L:0.5 mm and AP:-12.0 mm, L:+0.3 mm respectively. For each regions we counted 9 section per animal (4 animals per group) for each double immunolabeling.

Experimental technique combination.

In vivo single-unit electrophysiological recording was coupled to tail flick latency monitoring in lightly anesthetized rats to identify ON, OFF, and NEUTRAL cells. Microdialysis was coupled to Hargreaves' method (Plantar Test) to correlate PAG amino acid release to behavioral pain responses in awake freely moving rats.

Treatments.

Groups of 8–10 animals per treatment were used with each animal being used for one treatment only.

For the combined plantar test and RVM microdialysis experiments, rats received intra-VL PAG microinjections of vehicle, capsaicin (6 nmol/rat), I-RTX (0.1 and 0.5 nmol/rat) alone or I-RTX (0.1 nmol/rat) in combination with capsaicin (6 nmol/rat).

For in vivo extracellular recording and tail-flick test, rats received intra-VL-PAG microinjections of vehicle, capsaicin (3 and 6 nmol/rat), I-RTX (0.5 and 1 nmol/rat) alone or I-RTX (0.5 nmol/rat) in combination with capsaicin (6 nmol/rat).

An important issue regards how we chose the doses of capsaicin or I-RTX to be administered into the VL-PAG. The choice was based on our and others' previous in vivo studies in the rat (Palazzo et al., 2002; McGaraughty et al., 2003). Indeed, we performed extensive preliminary experiments with several doses of capsaicin, as well as of I-RTX, to find minimal doses able to change RVM cell activities or thermoceptive thresholds.

Drugs.

Capsaicin and I-RTX (5′-Iodo-resiniferatoxin) were purchased from Tocris Cookson Ltd, Bristol, UK.

Drugs were dissolved in 10% dimethylsulfoxide in ACSF with final pH = 7.2 for intra-VL PAG microinjections.

Statistics.

Single-unit extracellular recording (action potentials) was analyzed off-line from peristimulus rate histograms using Spike2 software (CED, version 4). The neuron responses, before and after intra-VL-PAG vehicle or drug microinjections, were measured and expressed as spikes/s (Hz). Baseline activities of neurons were measured between tail flicks. In particular, basal values were obtained by averaging the activities recorded 30–50 s before the application of 3–4 thermal stimulations (each stimulation trial was performed every 3–4 min). Data are presented as mean ± SE either of changes in time latencies (tail flick test) or changes in neuron responses (extracellular recordings). Statistical comparisons of values from different treated groups of rats were made using the two-way ANOVA for repeated measures followed by the Tukey–Kramer test for post hoc comparisons.

To analyze tail flick-related ON cell activities (before and after drug treatment), the ongoing activity (spikes/s) was determined 30–50 s before tail flick application, and then the peak of ON cell activity related to the tail flick (peak firing) was quantified. Tail flick-related ON cell firing was calculated as the number of spikes in the 2 s interval beginning 0.5 s before the tail flick. Comparisons between pretreatment and posttreatment ongoing activity and tail flick-related cell burst were performed by applying the nonparametric Wilcoxon matched-pairs signed rank test. Furthermore, we calculated the ON cell burst latency; that is, the interval between the onset of the applied noxious radiant heat and the beginning of the tail flick-related cell burst. Burst latency was analyzed using two-way ANOVA for repeated measures followed by the Tukey–Kramer test for post hoc comparisons.

We also performed analysis of tail flick related OFF cell activities before and after drug treatments. The ongoing activity (spikes/s, 40–50 s before radial heat application), the latency to onset of the OFF cell pause (the interval between the onset of thermal stimulus and the last spike), and the duration of the cell pause (the interval between the pause onset and the first spike after the tail flick) were determined. Comparisons between pretreatment and posttreatment ongoing activity and cell pause related to tail flick were performed by applying the nonparametric Wilcoxon matched-pairs signed rank test. The interval between the onset of applied noxious radiant heat and the beginning of the tail flick related cell pause (pause latency), was also calculated. The latency to the onset of the cell pause was analyzed with a two-way ANOVA for repeated measures with the Tukey–Kramer test for post hoc comparisons.

Microdialysis, tail flick or plantar test data are represented as means ± SEM, and statistical analysis of these data were performed by two-way ANOVA for repeated measures followed by the Student–Newman–Keuls multiple comparisons test to determine the statistical significance between different treated groups of rats. Differences were considered significant at p < 0.05.