Abstract
Serotonin [5-hydroxytryptamine (5-HT)] released from mast cells or platelets in peripheral tissues is one of the important inflammatory mediators in pain and hyperalgesia. The involvement of 5-HT in pain is complex because it could inhibit or facilitate nociceptive transmission, reflecting the presence of multiple 5-HT subtype receptors on peripheral and central nociceptors. The present study aimed to investigate the involvement of 5-HT2B in 5-HT-induced pain and whether the subtype exists in dorsal root ganglion (DRG) neurons. Injecting the 5-HT or 5-HT2 agonist in hindpaws of mice induced significant hyperalgesia to mechanical stimuli, which was inhibited by the 5-HT2B/2C antagonist but not by 5-HT1A, 5-HT2A, or 5-HT3A antagonists. Therefore, 5-HT2B or 5-HT2C may be involved in 5-HT-induced mechanical hyperalgesia. The 5-HT2B/2C antagonist also blocked 5-HT-induced transient [Ca2+] signaling in DRG neurons. All subtypes of 5-HT receptors except 5-HT2C and 5-HT6 are present in DRGs. In situ hybridization also demonstrated 5-HT2B mainly expressed in small- to medium-diameter DRG neurons that respond to pain. Likely, 5-HT2B mediates 5-HT-induced mechanical hyperalgesia in mice.
Introduction
Tissue injury, infection, or tumor growth, often accompanied by inflammation, produces various chemical mediators, such as prostaglandin E2, bradykinin, serotonin [5-hydroxytryptamine (5-HT)], and protons, that sensitize pain-transducing neurons (nociceptors) to elicit pain and hyperalgesia (Dray, 1995; Kress and Reeh, 1996; Reeh and Steen, 1996). 5-HT released from platelets, mast cells, and endothelial cells into the inflamed site is proinflammatory and pronociceptive, exciting nociceptive afferents and inducing hyperalgesia (Kessler et al., 1992; Sufka et al., 1992; Taiwo and Levine, 1992; Ernberg et al., 2000; Schmelz et al., 2003; Sommer, 2004). Seven subgroups of serotonin receptors (5-HT1–7) have been identified, and some subtypes have more than one receptor (e.g., 5-HT1 has 5-HT1A, 5-HT1B, 5-HT1D, 5-HT1E, 5-HT1F, and 5-HT2 has 5-HT2A, 5-HT2B, and 5-HT2C) (Hoyer et al., 2002). The presence of multiple 5-HT receptors on afferent nociceptors reflects distinct mechanisms of 5-HT-induced pain or hyperalgesia through different receptors.
Ionotropic 5-HT3 is responsible for inflammatory pain (Eschalier et al., 1989; Giordano and Rogers, 1989; Zeitz et al., 2002; Kayser et al., 2007). Lack of the 5-HT3 gene in mice or blocking by the 5-HT3 antagonist granisetron elicits normal acute pain responses but reduced responses to persistent pain (Zeitz et al., 2002; Kayser et al., 2007). Giordano and Dyche (1989) showed that 5-HT3 contributes to chemical but not thermal and mechanical nociceptive pain. Taiwo and Levine (1992) reported that only the 5-HT1A agonist, but not 5-HT2 or 5-HT3A agonists, mimics the 5-HT effect to induce hyperalgesia and that 5-HT1A antagonists block mechanical hyperalgesia induced by 5-HT. Nevertheless, Kayser et al. (2007) suggested that mice lacking 5-HT1A exhibit increased sensitivity to heat-evoked nociceptive pain but not mechanical pain. The other study of formalin testing suggested that 5-HT1A mediates antinociception (Granados-Soto et al., 2010). In the study by Tokunaga et al. (1998), only the 5-HT2A agonist, but not 5-HT1A and 5-HT3A agonists, mimics 5-HT-induced thermal hyperalgesia, which is blocked by the 5-HT2A antagonist, ketanserin. 5-HT2A also potentiates the effects of other inflammatory mediators (Abbott et al., 1996, 1997). Sufka et al. (1992) suggested that all of the 5-HT1A, 5-HT2A, and 5-HT3 subtypes also participate in 5-HT-induced pain. In addition, 5-HT4 enhances the inflammatory pain signal (Doak and Sawynok, 1997). 5-HT7 inhibits capsaicin-induced mechanical sensitivity (Brenchat et al., 2009).
Many contrary results of 5-HT-receptor mediation in hyperalgesia remain to be resolved. At present, the role played in nociception by 5-HT2B has not been thoroughly investigated, mainly because the presence of 5-HT2B in DRGs is controversial. A previous study by Wu et al. (2001) found no 5-HT2B or 5-HT2C mRNA present in rat DRGs, but Nicholson et al. (2003) found 5-HT2B but not 5-HT2C present. In the present study, we investigated the involvement of 5-HT2B in 5-HT-induced hyperalgesia and found 5-HT2B present in DRG neurons and that the 5-HT2B/2C antagonist 3,5-dihydro-5-methyl-N-3-pyridinylbenzo[1,2-b:4,5-b′]dipyrrole-1(2H)-carboxamide hydrochloride (SB206553) inhibited 5-HT-induced mechanical hyperalgesia but not thermal hyperalgesia. SB206553 also inhibited 5-HT-induced transient [Ca2+] signaling in DRG neurons. Given that 5-HT2B but not 5-HT2C was present in nociceptors, the 5-HT2B receptor is the one most likely involved in 5-HT-induced mechanical hyperalgesia.
Materials and Methods
Cloning of 5-HT2B receptor.
Mouse 5-HT2B was cloned into pBSII by PCR. The reaction mixture (50 μl) included 0.2 mm dNTP, 1.5 mm MgCl2, 1 U of Taq polymerase, 1× PCR buffer (all Invitrogen), and 500 nm each of primers. A specific primer set for each gene was designed by use of the primer design software Primer3 (http://biotools.umassmed.edu/bioapps/primer3_www.cgi). The primer set for 5-HT2B gene (1677 bp) was as follows (5′–3′, forward/reverse): actgactagttcaccttggctgtgagtgtc/tatctcgaggaagctggacagccttggta. The PCR condition was 1 cycle of 5 min at 95°C, 36 cycles of 45 s at 95°C, 1.5 min at 60°C, 3 min at 72°C, and 1 cycle of 3 min at 72°C. The clone was sequenced and the sequences were matched with the accession number (NM_008311) of the NCBI database. The sequenced clone was further subcloned into pIRES-GFP for expression analysis. 5-HT1A, 5-HT2A, and 5-HT3A clones were from the Guthrie cDNA Resource Center (Sayre, PA).
Animals.
Male CD-1/ICR mice (8–18 weeks of age) were bred and cared for in accordance with the Guide for the Care and Use of Laboratory Animals. Animal experimental procedures were approved by the local animal use committee (Institutional Animal Care and Use Committee, National Central University, Taiwan).
Animal tissue and RNA preparation.
Tissues from 8- to 12-week-old wild-type mice (CD-1/ICR strain) were removed by use of a fine forceps and immediately frozen in dry ice or in freezing solution for RNA preparation or in situ hybridization, respectively. Total RNA from tissues was extracted by use of Trizol reagent (Invitrogen) according to the manufacturer's instructions. RNA was then treated with DNaseI (Roche) at 1.4 U/μg RNA at 37°C for 5 min to remove contamination of genomic DNA for cDNA synthesis. DRG and trigeminal ganglion (TRG) RNA extraction involved the RNeasy kit (QIAGEN).
Reverse transcription-PCR and quantitative PCR.
One to 5 μg of total RNA from different mouse tissues was reverse transcribed by use of Superscript II RT (Invitrogen), with oligo-dT (Invitrogen) used as a primer. Derived cDNA was used as a template for PCR experiments. The reaction mixture (10 μl) included 0.2 mm dNTP, 1.5 mm MgCl2, 0.5 U of Taq polymerase, 1× PCR buffer, and 100 nm each of primers. The primer sets for 5-HT receptor genes and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) gene were designed by use of Primer3 and are listed in Table 1. The PCR conditions were 95°C for 5 min, followed by 40 cycles of 15 s at 95°C, and 1 min at 60°C. PCR product detection was performed in a 4% agarose gel. The internal control was GAPDH measured from the same samples.
For quantitative PCR of 5-HT receptor genes in DRGs, the reaction mixture (25 μl) included 6 μl of 2× master mix (containing SYBR Green I and AmpliTaq Gold DNA polymerase; Applied Biosystems), 100 nm each of primers and cDNA. Each assay was run in quadruplicate for each preparation. The DRG pool had at least 10 ganglia. The cycling conditions were 95°C for 10 min, 40 cycles of 95°C for 15 s, and 60°C for 1 min. PCRs and product detection involved the ABI Prism 7300 detection system. The amplified product was detected by measurement of SYBR Green I, which was added to the initial experiment mixtures. The threshold cycle (Ct) values obtained in experiments indicate the fractional cycle numbers at which the amount of amplified target reached a fixed threshold. The Ct values of both the target and internal reference (GAPDH) were measured from the same samples, and the expression of the target gene relative to that of GAPDH was calculated by the comparative Ct method to obtain the ΔCt. All data are presented as mean ± SEM.
In situ hybridization and immunohistochemistry.
In situ hybridization was performed as previously described (Huang et al., 2007). Briefly, lumbar 4 DRG tissues were frozen and sectioned in 12-μm-thick slices by use of a cryostat (Leica Microsystems 3510S). After fixation and acetylation, sections were preincubated with hybridization buffer (50% formamide, 4× SSC, 2× Denhardt's solution, and 50 μg/ml tRNA) for 2 h at room temperature. The digoxigenin-UTP (dig) (Roche)-labeled cRNA probes were generated by in vitro transcription with T7 and T3 polymerases (Roche) from nucleotide sequences of 5-HT2B (1455∼1888; 433 bp; NM_008311) and hybridized to sections overnight at 65°C. Then slides underwent high-stringency washing cycles with SSC buffers, followed by detection with an alkaline phosphatase-conjugated anti-dig antibody (Roche). Development of signals involved use of a mixture of nitroblue tetrazolium chloride (0.45%) and 5-bromo-4-chloro-3′-indolyphosphate p-toluidine salt (0.35%) (Sigma-Aldrich). The specificity of hybridization signals was confirmed by a control study of sense cRNA probes.
After detection of hybridization signals, sections were costained with various combinations of primary antibodies, followed by suitable secondary antibodies. All antibodies were diluted in 1× PBS containing 1% BSA. All antibody incubations were performed at 4°C overnight. Primary antibodies were against N52 (1:500; Sigma-Aldrich) or peripherin (PERI) (1:500; Millipore Bioscience Research Reagents). Secondary antibodies were goat anti-mouse IgG conjugated to TRITC (tetramethylrhodamine isothiocyanate) (1:250; Sigma-Aldrich) or goat anti-rabbit IgG conjugated to FITC (1:250; Sigma-Aldrich). Some experiments involved direct staining with IB4-FITC conjugates (12.5 μg/ml; Sigma-Aldrich).
The specimens were examined by use of a 20× objective with a fluorescence microscope (Zeiss; Axiovert 200). The digitized images were captured by MetaMorph software. In general, >1000 neurons from eight sections were counted, and 95% confidence intervals for proportions were estimated. Experiments were repeated three times and one mouse was used for each group each time.
Agents.
The following agents were used: 5-HT (Sigma-Aldrich), α-methyl 5-HT (α-m5-HT) (Sigma-Aldrich), 1-methyl-N-[(3-endo)-9-methyl-9-azabicyclo[3.3.1]non-3-yl]-1H-indazole-3-carboxamide hydrochloride (granisetron hydrochloride) (Tocris Bioscience), 3-[2-[4-(4-fluorobenzoyl)-1-piperidinyl]ethyl]-2,4[1H,3H]-quinazolinedione tartrate (ketanserin tartrate) (Tocris Bioscience), SB206553 hydrochloride (Tocris Bioscience), (S)-N-tert-butyl-3-(4-(2-methoxyphenyl)-piperazin-1-yl)-2-phenylpropanamide dihydrochloride [(S)-WAY100135 dihydrochloride] (Tocris Bioscience), 1-[6-[[(17b)-3-methoxyestra-1,3,5(10)-trien-17-yl]amino]hexyl]-1H-pyrrole-2,5-dione (phospholipase C inhibitor) (U73122) (Sigma-Aldrich), 1-[6-[((17β)-3-methoxyestra-1,3,5[10]-trien-17-yl)amino]hexyl]-2,5-pyrrolidinedione (U73343) (U73122 analog) (Sigma-Aldrich), and pertussis toxin (PTX) (Sigma-Aldrich). For animal experiments, all compounds were diluted into saline before injection. For cell experiments, all compounds were diluted in the HEPES/MES buffer.
Behavioral tests.
Right hindpaws of male CD-1/ICR mice (8–18 weeks of age) were injected with 25 μl of agonists, antagonists, or saline using 30 gauge by 1/2 inch needle (BD Biosciences), and then animal behavioral tests were performed. To assess mechanical nociceptive response, animals were tested for withdrawal thresholds to mechanical stimuli (von Frey filaments; Touch-Test; North Coast Medical) applied to the plantar aspect of the hindpaw. Mice (n = 6∼8 per group) were placed on a wire mesh platform in transparent Plexiglas chambers (10 × 8 × 10 cm/chamber), allowed to habituate for 2 h each day, and trained for 2 d before the test. At certain times after mice were injected with agonists or antagonists, we applied a series of von Frey fibers (0.6, 1.0, 1.4, 2.0, 4 g) in ascending order beginning with the finest fiber through the wire mesh onto the plantar surface of both hindpaws of mice. A withdrawal response was considered valid only if the hindpaw was removed completely from the platform. If the paw withdrawal response was ambiguous, the application of fibers was repeated. For each paw, a von Frey fiber was applied five times at 5 s intervals. The paw withdrawal threshold (PWT) was when paw withdrawal was observed in more than three of five applications.
Animals were also tested for thermal nociceptive response to radiant heat applied to the plantar surface of the paw (Hargreaves et al., 1988). Mice (n = 6∼8 per group) were allowed to habituate for at least 2 h in transparent Plexiglas chambers (10 × 8 × 10 cm/chamber) on a glass floor before testing. At certain times after mice were injected with agonists or antagonists, we stimulated the plantar surface of mouse hindpaws with a light bulb (40% intensity, 305 mW/cm2). The latency to withdrawal of the paw from radiant heat was measured. Measurements from three trials at 1 min intervals in each paw were averaged. We obtained mean basal withdrawal latencies of ∼15∼17 s in uninjected mice.
Cell culture and transfection.
HEK293T cells were seeded on 24 mm poly-d-lysine-coated coverslips and grown in DMEM (Invitrogen) containing 10% fetal bovine serum (FBS). Cells were then transfected with 5-HT1A, 5-HT2A, 5-HT2B, 5-HT3A, or pIRES-GFP vector only. Intracellular Ca2+ imaging was performed at 19∼48 h after transfection.
One day primary DRG cultures were cultured as previously described (Chen et al., 2009). Briefly, mice were preinjected with or without SB206553, and then injected with 5-HT. After 30 min, mouse lumbar 4–6 DRGs were collected in prewarmed serum-free DMEM. DRGs were first treated with 0.125% collagenase IA (Sigma-Aldrich) at 37°C for 1.5 h, and then with 0.25% trypsin (Invitrogen) at 37°C for 15 min. After trypsin digestion, cells were washed once with DMEM containing 10% FBS, and then once with serum-free medium. DRGs were resuspended in 2 ml of serum-free DMEM and then dissociated into single cells by mechanical titration eight times through flame-polished Pasteur pipettes of decreasing tip diameter. Cell suspension was slowly dropped into 10 ml of serum-free DMEM. After 3∼5 min, the cell suspension on the top (∼10 ml) was collected and centrifuged at 1224 × g for 5 min. The cell pellet was suspended and mixed in 400 μl of DMEM containing 10% FBS and seeded on 100 μg/ml poly-l-lysine-coated 24 mm coverslips. After incubation at 37°C for 2 h, cells were supplemented with 1.5 ml of DMEM containing 10% FBS and maintained at 37°C for 16 h before intracellular Ca2+ imaging.
Intracellular calcium imaging.
Intracellular calcium imaging was performed as previously described (Chen et al., 2009). Briefly, transfected cells grown on coverslips were preincubated at 37°C with 2.5 μm fura-2 acetoxymethyl ester (fura-2 AM) (Invitrogen) for 40 min in HEPES/MES buffer (125 mm NaCl, 1 mm KCl, 5 mm CaCl2, 1 mm MgCl2, 8 mm glucose, 10 mm HEPES, and 15 mm MES, pH 7.4). Coverslips were assembled into culture wells and supplemented with 500 μl of the HEPES/MES buffer. Cells were stimulated with 500 μl of HEPES/MES buffer containing twofold concentrations of agonists or antagonists, followed by intracellular calcium recording with a Zeiss inverted microscope equipped with a xenon lamp. Cell images were taken with use of a Zeiss Plan-Apo 63× oil-immersion objective lens. Green fluorescent protein (GFP)-positive cells within a field were identified by use of a FITC filter with excitation wavelength of 480 nm and emission wavelength of 535 nm. In the same field, fura-2 AM fluorescence was measured by 10 Hz alternating wavelength time scanning, with excitation wavelength of 340 and 380 nm and emission wavelength of 510 nm. The fluorescence ratio at two excitation wavelengths (340/380 nm, Ca2+-bound fura-2 AM/free fura-2 AM) was recorded and analyzed.
Statistical analysis.
All data are presented as mean ± SEM. Paired Student's t test was used for comparison. A value of p < 0.05 was considered statistically significant.
Results
5-HT2B is present in nociceptors
A previous study by Wu et al. (2001) suggested that 5-HT2B and 5-HT2C mRNA were not present in rat DRGs, but Nicholson et al. (2003) reported that 5-HT2B but not 5-HT2C was present in rat DRGs. To understand whether 5-HT2B is present in nociceptors, we first examined the tissue distribution of 5-HT2B. As shown in Figure 1A, 5-HT2B was expressed in all tissues tested. The expression of 5-HT receptor subtypes in DRGs was also examined. Total RNA from DRGs was extracted and 5-HT receptor distribution was analyzed by quantitative PCR. Among subtypes of 5-HT receptors tested (Fig. 1B), 5-HT6 was undetectable and 5-HT2C had only a trace amount (ΔCt = 20.75 ± 0.29). The highest expressed receptor was 5-HT3A (ΔCt = 5.59 ± 0.04). Receptors with the medium levels were 5-HT1B, 5-HT1D, 5-HT2A, and 5-HT4, whereas 5-HT1A, 5-HT1F, 5-HT2B, 5-HT5, and 5-HT7 had lower expression levels (Fig. 1B). Localization of 5-HT2B in nociceptors was further examined by in situ hybridization. Of the total lumbar 4 DRG neurons, 41% expressed 5-HT2B (Fig. 2). In those 5-HT2B-expressed neurons, ∼82% were present in PERI-labeled neurons (a marker of small- and medium-diameter neurons) (Fig. 2C,D,G). Of 5-HT2B and PERI-positive populations, 75% were IB4-positive (Fig. 2E,F,H). Accordingly, 5-HT2B was predominantly expressed in nonpeptidergic nociceptors.
The antagonist of 5-HT2B/2C, SB206553, inhibits 5-HT2B-mediated 5-HT and α-methyl 5-HT signaling in vitro
To understand whether the antagonist of 5-HT2B/2C, SB206553, inhibits 5-HT2B-mediated signaling, we first examined 5-HT2B-mediated 5-HT signaling in vitro. HEK293T cells overexpressing 5-HT2B were stimulated with different concentrations of 5-HT, and intracellular calcium was measured with a calcium imaging technique. After the addition of 5-HT to the cells, 5-HT2B-expressing but not vector-expressing cells showed a rapid increase in intracellular calcium level (Fig. 3A,B). Effective concentrations of 5-HT caused an increase in calcium level that peaked ∼15 s after drug addition. Intracellular calcium levels reached the EC50 with 0.001 μm and peaked at 0.01 μm 5-HT (Fig. 3C). SB206553 (5-HT2B/2C antagonist) at 1 μm eliminated the increase in 5-HT-induced calcium level in 5-HT2B-expressing cells (Fig. 3D), thus confirming that 5-HT-induced calcium level increase is mediated by 5-HT2B. 5-HT2B-expressing cells were treated with U73122 (a phospholipase C inhibitor), which caused a marked inhibition of the 5-HT-induced [Ca2+] increase in level. U73343 (an inactive analog of U73122) or PTX (Gi protein inhibitor) was ineffective in inhibiting the Ca2+ response (Fig. 3D), which suggests that 5-HT2B-mediated signaling is mainly through activation of Gq protein.
To understand whether SB206553 acts only on 5-HT2B and 5-HT2C, SB206553 was tested in 5-HT1A-, 5-HT2A-, 5-HT2B-, 5-HT2C-, or 5-HT3A-expressing cells. As shown in Figure 4A, SB206553 (1 μm) inhibited 5-HT2B- or 5-HT2C-mediated 5-HT signaling but not 5-HT1A-, 5-HT2A-, or 5-HT3A-mediated 5-HT signaling. We also examined whether signaling induced by the selective 5-HT2 agonist α-m5-HT could be inhibited by SB206553. Indeed, α-m5-HT specifically activated 5-HT2A, 5-HT2B, and 5-HT2C, but not 5-HT1A or 5-HT3 (Fig. 4B). Interestingly, 1 μm SB206553 completely inhibited α-m5-HT-induced [Ca2+] signaling in 5-HT2B-expressing cells (Fig. 4B). However, α-m5-HT-induced [Ca2+] signaling in 5-HT2C-expressing cells could not be inhibited by 1 μm SB206553. A high concentration (10 μm) of SB206553 was required (data not shown). Selective antagonists for 5-HT1A (WAY100135), 5-HT2A (ketanserin), or 5-HT3A (granisetron) were also tested for specificity. Selective antagonists blocked the mediated signaling of each subtype, but 5-HT2B-mediated signaling was not inhibited by any antagonists for 5-HT1A, 5-HT2A, or 5-HT3A (Fig. 4C).
The antagonist of 5-HT2B/2C, SB206553, inhibits 5-HT-induced mechanical hyperalgesia but not thermal hyperalgesia
Local administration of 5-HT (10 μm) into mice hindpaws caused pain-related behaviors. Before injection (0 min), the PWT for mechanical stimuli was 3.50 ± 0.42 g on the injected paw (ipsilateral side) and 3.83 ± 0.29 g on the uninjected paw (contralateral side). The greatest magnitude of pain-related behaviors occurred within 15 min after the injection (PWT = 1.13 ± 0.08 g on the ipsilateral paw and 3.33 ± 0.42 g on the contralateral paw) (Fig. 5A). The hyperalgesia induced by mechanical stimuli was gradually decreased and returned to baseline within 4 h. Non-noxious mechanical stimulation did not induce hyperalgesia in saline-injected mice (data not shown). When mice were preinjected with SB206553 (10 μm), an antagonist of 5-HT2B/2C, before 5-HT injection, the hyperalgesia to mechanical stimuli was completely inhibited within 15 min after injection (3.00 ± 0.44 g on the ipsilateral paw and 3.67 ± 0.33 g on contralateral paw) (Fig. 5B) and the inhibition lasted at least 4 h.
The paw withdrawal latency (PWL) to heat stimuli was also examined on 5-HT-injected mice. The latency of paw withdrawal was 17.75 ± 1.55 s for the contralateral paw and 15.45 ± 1.64 s for the ipsilateral paw before injection. At 15 min after 5-HT injection, the latency was decreased to 6.80 ± 0.73 s for the ipsilateral paw and remained at 12.51 ± 1.07 s for the contralateral paw (Fig. 6A). The decreased PWL to heat stimulation gradually returned to baseline after 4 h (10.20 ± 1.30 s on the ipsilateral paw and 12.04 ± 1.09 s on the contralateral paw). Unlike with mechanical hyperalgesia, with thermal hyperalgesia, SB206553 preinjection before 5-HT injection did not block the hyperalgesia (6.27 ± 0.72 s on the ipsilateral paw and 10.04 ± 1.98 s on contralateral paw in 15 min) (Fig. 6B).
The antagonist of 5-HT2B/2C, SB206553, inhibits 5-HT2 agonist-induced mechanical hyperalgesia
As shown in Figure 5, 5-HT-induced mechanical hyperalgesia was inhibited by the antagonist of 5-HT2B/2C. To further confirm that the effect is attributable to 5-HT2B/2C function, we used the 5-HT2 agonist α-m5-HT to induce mechanical hyperalgesia. After being injected with α-m5-HT (5 μm), mice showed hyperalgsia to mechanical stimuli within 15 min. The PWT was 1.40 ± 0.00 and 3.33 ± 0.42 g for the ipsilateral and contralateral paws, respectively (Fig. 7A). Hyperalgesia induced by α-m5-HT disappeared within 90 min. The response was shorter than that induced by 5-HT. Preinjection with SB206553 (10 μm) before α-m5-HT injection completely inhibited the mechanical hyperalgesia within 15 min (PWT = 3.33 ± 0.42 and 3.67 ± 0.33 g for the ipsilateral and contralateral paws, respectively) (Fig. 7B), and the inhibition lasted until α-m5-HT-induced hyperalgesia disappeared.
The antagonist of 5-HT2A, ketanserin, does not inhibit 5-HT or α-m5-HT-induced mechanical hyperalgesia
To understand whether 5-HT2A is involved in 5-HT-induced mechanical hyperalgesia, the selective antagonist of 5-HT2A, ketanserin, was used to inhibit 5-HT2A function. When mice were preinjected with ketanserin (10 μm) before 5-HT injection, the hyperalgesia to mechanical stimuli was not inhibited but was slightly enhanced in the first 30 min after injection (PWT = 0.73 ± 0.08 g on the ipsilateral paw of ket-5HT-injected mice and 1.13 ± 0.08 g on ipsilateral paw of 5-HT-injected mice) (Fig. 8A). Nevertheless, the hyperalgesia in ket-5HT-injected mice returned to baseline within 60–90 min, faster than in 5-HT-injected mice (within 4 h). Similar results were obtained with α-m5-HT injection instead of 5-HT. Ket-α-m5-HT-injected mice, like ket-5-HT-injected mice, also displayed slightly enhanced mechanical hyperalgesia within first 30 min, and hyperalgesia disappeared in 60–90 min (Fig. 8B).
Selective antagonists for 5-HT1A or 5-HT3A do not inhibit 5-HT-induced mechanical hyperalgesia
Sufka et al. (1992) found that all 5-HT1, 5-HT2, 5-HT3 subtype receptors were involved in 5-HT-induced pain. Taiwo and Levine (1992) reported that 5-HT1A antagonists blocked mechanical hyperalgesia induced by 5-HT. To understand whether 5-HT1 and 5-HT3 are involved in 5-HT-induced mechanical hyperalgesia, we tested selective antagonists for 5-HT1 or 5-HT3. As shown in Figure 8C, the 5-HT1 antagonist WAY100135 did not inhibit but, rather, slightly enhanced 5-HT-induced mechanical hyperalgesia in the first 30 min after injection, and hyperalgesia gradually disappeared in 90–120 min. Similarly, the 5-HT3 antagonist granistetron enhanced 5-HT-induced mechanical hyperalgesia in the first 30 min, but hyperalgesia disappeared in 60–90 min (Fig. 8D).
The antagonist of 5-HT2B/2C, SB206553, inhibited 5-HT-induced signaling in DRG neurons
To examine the effect of SB206553 on DRG neurons, we collected lumbar 4–6 DRG neurons from 5-HT-injected and SB-5-HT-injected mice at 30 min after injection and analyzed 5-HT-induced signaling. In DRGs from the contralateral side of 5-HT-injected mice, 3.4% of DRG neurons responded to 1 μm 5-HT stimuli and elicited an increase in [Ca2+] level with two different patterns (Fig. 9A,B) in 10- to 35-μm-diameter neurons. Pattern 1 was a rapid [Ca2+] level increase after 5-HT stimulation; and pattern 2 was a rapid [Ca2+] level increase followed by a sustained and delayed return. The number of 5-HT-responding neurons in DRGs from the ipsilateral side of 5-HT-injected mice was twofold higher than those from the contralateral side (8.5 vs 3.4%). Only pattern 1 showed an increased [Ca2+] response (increased peak value 4.5-fold) (Fig. 9C,E). The peak value of pattern 2 did not change (Fig. 9D). In contrast, DRG neurons from SB-5-HT-injected mice showed few responding cells (2.9% 5-HT responding neurons on the ipsilateral side). Patterns 1 disappeared on the ipsilateral side of SB206553 injection but was unchanged on the contralateral side (Fig. 9E). A transient [Ca2+] response in pattern 2 also disappeared on the ipsilateral side, but sustained [Ca2+] response remained. It seems that transient [Ca2+] response is completely eliminated after SB206553 injection. Accordingly, the results provide the evidence that 5-HT injection increased 5-HT receptors for the 5-HT response in peripheral neurons, and SB206553 inhibited peripheral 5-HT2B/2C action, thus reducing the 5-HT response.
Discussion
In this study, we investigated the involvement of 5-HT2B in 5-HT-induced pain. The selective antagonist for 5-HT2B/2C, SB206553, but not antagonists for 5-HT1A, 5-HT2A, or 5-HT3A, completely inhibited 5-HT-induced mechanical hyperalgesia. SB206553 injection in mice also inhibited DRG neurons responding to 5-HT. Given that only a trace amount of 5-HT2C mRNA is detected in DRG tissues (Fig. 1), 5-HT2B seems to be the subtype mediating 5-HT-induced mechanical hyperalgesia.
The roles of 5-HT2B in 5-HT-induced pain were previously overlooked, mainly because the presence of 5-HT2B in rat DRGs is arguable. Wu et al. (2001), using reverse transcription (RT)-PCR, could not detect 5-HT2B mRNA in DRGs, whereas Nicholson et al. (2003), using in situ hybridization, reported 5-HT2B in rat DRGs. To clarify this issue, we used both techniques to examine the presence of 5-HT2B in mouse DRGs and found 5-HT2B mRNA in mouse DRGs, although the expression was at a medium level compared with that of other 5-HT subtype receptors. Consistent with previous results from Nicholson et al. (2003), we also found that 5-HT2B was distributed in small-, medium-, and large-diameter DRG neurons but mainly in the small-to-medium population (82% of total 5-HT2B-positive neurons). Nicholson et al. reported almost 100% rat DRG neurons expressing 5-HT2B, whereas we found 41% of mouse DRG neurons expressing 5-HT2B. Of 5-HT2B- and PERI-coexpressing neurons, most (75%) were in IB4-positive neurons. The distribution of 5-HT2B in DRGs suggests its possible involvement in pain.
Sufka et al. (1992) found all 5-HT1, 5-HT2, 5-HT3 subtype receptors involved in 5-HT-induced pain. However, Taiwo and Levine suggested that the 5-HT1 agonist but not 5-HT2 or 5-HT3 agonist induces 5-HT-induced hyperalgesia. Tokunaga et al. (1998) found that rats displayed thermal hyperalgesia on injection with the 5-HT2 agonist but not 5-HT1 or 5-HT3 agonist. In this study, we demonstrated that 5-HT-induced mechanical hyperalgesia can be completely inhibited by the 5-HT2B/2C antagonist, SB206553, but not by antagonists for 5-HT1A, 5-HT2A, or 5-HT3.
We found that the 5-HT3 antagonist, granisetron, did not inhibit mechanical hyperalgesia but shortened the hyperalgesia response. 5-HT3 is responsible for direct action in chemical stimuli but not in the mechanical or thermal response (Giordano and Dyche, 1989). Although Zeitz et al. (2002) showed that mice lacking 5-HT3 have a reduced visceral pain response after injection of 5-HT, mice injected with the 5-HT3 agonist did not display mechanical hyperalgesia (Taiwo and Levine, 1992) or thermal hyperalgesia (Tokunaga et al., 1998). Thus, our data are consistent with previous results that 5-HT3 is not involved in 5-HT-induced mechanical hyperalgesia. Our finding that the 5-HT3 antagonist shortened the mechanical hyperalgesia response and other findings that lack of or blocking the 5-HT3 with an antagonist also show reduced responses in the phase 2 of formalin-induced nociception (Kayser et al., 2007) suggest that 5-HT3 may have an influence on maintaining hyperalgesia but does not directly act on mechanical hyperalgesia.
5-HT1A has been found to be involved in 5-HT-induced mechanical hyperalgesia (Taiwo and Levine, 1992). In contrast, our findings suggested that the 5-HT1A antagonist cannot inhibit 5-HT-induced mechanical hyperalgesia but slightly enhanced hyperalgesia in the first 30 min. The difference between our results and those of Taiwo and Levine could be attributable to the antagonists and measurement methods used. Taiwo and Levine used spiperone, which has considerable affinities for 5-HT2 and dopamine (D2) receptors, so the inhibition could be attributable in part to action of these receptors. In our study, we used a more selective antagonist, WAY100135, which acts on 5-HT1A but not 5-HT2 or 5-HT3 in a cultured system. Other studies involving the same antagonist also did not find 5-HT1A involved in mechanical hyperalgesia (Parada et al., 2001; Kayser et al., 2007). The role of 5-HT1A in 5-HT-induced pain seems more complicated. Millan (1994) found that 5-HT1A agonists mediated antinociception under certain conditions. A formalin test study also suggested that 5-HT1A mediates antinociception (Granados-Soto et al., 2010). Mice lacking 5-HT1A exhibit increased sensitivity to heat-evoked nociceptive pain but not mechanical pain (Kayser et al., 2007). In our data, 5-HT1A seems to have few antinociceptive effects on 5-HT-induced mechanical hyperalgesia, because 5-HT1A only slightly enhanced mechanical hyperalgesia.
A previous study by Tokunaga et al. (1998) suggested that the 5-HT2 agonist, α-m5-HT, mimics the 5-HT-induced response. Similarly, we demonstrated that α-m5-HT can induce mechanical hyperalgesia, but hyperalgesia disappeared shortly, within 60–90 min. In cell experiments, α-m5-HT acted on 5-HT2A and on 5-HT2B and 5-HT2C, which suggests that α-m5-HT-induced mechanical hyperalgesia may act on 5-HT2A, 5-HT2B, or 5-HT2C. 5-HT2A and 5-HT2B/2C antagonists inhibited the α-m5-HT action in 5-HT2A-, 5-HT2B-, or 5-HT2C-expressing cells, respectively. However, α-m5-HT-induced mechanical hyperalgesia can be inhibited by only the 5-HT2B/2C antagonist, not the 5-HT2A antagonist. Similarly, the 5-HT2A antagonist did not inhibit 5-HT-induced mechanical hyperalgesia.
A previous study suggested that the 5-HT2A antagonist ketanserin inhibits 5-HT-induced thermal hyperalgesia but not mechanical hyperalgesia in rats (Tokunaga et al., 1998). In contrast, the 5-HT2B/2C antagonist, SB206553, inhibited 5-HT-induced mechanical hyperalgesia but not thermal hyperalgesia. 5-HT2 subtype receptors seem to be responsible for 5-HT-induced hyperalgesia: 5-HT2A for thermal hyperalgesia and 5-HT2B or 5-HT2C for mechanical hyperalgesia. Given that 5-HT2C has only trace amounts in DRGs and 5-HT-induced hyperalgesia occurred within 15 min, 5-HT2C is unlikely synthesized in such a short time. In addition, a high concentration of SB206553 was required to block α-m5-HT action on 5-HT2C-expressing cells, which suggests that 5-HT2B is more sensitive to SB206553. The study by Knight et al. (2004) had reported that 5-HT2A antagonist, ketanserin, is also a potent blocker of the 5-HT2C receptor. Ketanserin did not inhibit 5-HT-induced mechanical hyperalgesia. Accordingly, 5-HT2B seems to be the subtype involved in 5-HT-induced mechanical hyperalgesia.
In DRG neurons from 5-HT-injected mice, the number of 5-HT-responding neurons was increased in the ipsilateral side (from 3.4 to 8.5%), and the [Ca2+] response only increased in pattern 1. All responding cells were mainly located in 10∼35 μm, which is consistent with results from in situ hybridization that 5-HT2B was expressed predominantly in small- to medium-diameter neurons. After SB206553 injection, the number of 5-HT-responding cells was decreased to 2.9% on the ipsilateral side. SB206553 inhibited the [Ca2+] response in patterns 1 and partially in pattern 2, which suggests that patterns 1 and the transient [Ca2+] response in pattern 2 are mediated by the 5-HT2B or 5-HT2C receptor. Because 5-HT2C showed only trace amounts in DRG neurons, 5-HT2B could be the only receptor mediating 5-HT-induced transient [Ca2+] signaling. Given that 5-HT2B gene expression in DRGs did not have significant change after 5-HT injection (data not shown), the increased number of 5-HT-responding neurons could not be attributable to an increase in the number of 5-HT2B receptors. More likely, it is because 5-HT2B-mediated signaling is enhanced.
How 5-HT2B mediates 5-HT-induced mechanical hyperalgesia is unclear. Several lines of evidence have suggested that 5-HT increased tetrodotoxin-resistant (TTX-R) INa currents (Gold et al., 1996), Nav1.8 (one of TTX-R channels) is related to inflammatory hyperalgesia (Abrahamsen et al., 2008), and protein kinase C (PKC) can modulate TTX-R INa currents (Gold et al., 1998; Cang et al., 2009). Given that 5-HT2B activation leads to PKC activation, 5-HT2B-mediated mechanical hyperalgesia may be attributable to modulation of TTX-R INa currents through PKC. A recent study has also found that one isoform of PKC, PKCε, can mediate mechanical hyperalgesia by mitochondrial mechanisms (Joseph and Levine, 2010). Alternatively, 5-HT2B mediates mechanical hyperalgesia by activating a PKCε-dependent mitochondrial mechanism.
Footnotes
-
This work was supported by National Science Council (Taiwan) Grants NSC 95-2311-B-008-004 and NSC 99-2320-B-008-001-MY3. We thank the support of the Biophysics and Soft Matter at National Central University for calcium imaging.
- Correspondence should be addressed to Dr. Wei-Hsin Sun, Department of Life Sciences, National Central University, Jhongda Road 300, Jhongli 32054, Taiwan. weihsin{at}cc.ncu.edu.tw