Involvement of EP3 subtype of prostaglandin E receptors in PGE2-induced enhancement of the bradykinin response of nociceptors

Regulation of PGE2 Pathway During Cerebral Ischemia Reperfusion Injury in Rat

Stroke is an acute central nervous system disease with high morbidity and mortality rate. Cerebral ischemia reperfusion (I/R) injury is easily induced during the development or treatment of stroke and subsequently leads to more serious brain damage. Prostaglandin E2 (PGE2) is one of the most important inflammatory mediators in the brain and contributes to both physiological and pathophysiological functions. It may be upregulated and subsequently plays a key role in cerebral ischemia reperfusion injury. The synthesis and degradation of PGE2 is an extremely complex process, with multiple key stages and molecules. However, there are few comprehensive and systematic studies conducted to investigate the synthesis and degradation of PGE2 during cerebral I/R injury, which is what we want to demonstrate. In this study, qRT-PCR and immunoblotting demonstrated that the key enzymes in PGE2 synthesis, including COX-1, COX-2, mPGES-1 and mPGES-2, were upregulated during cerebral I/R injury, but 15-PGDH, the main PGE2 degradation enzyme, was downregulated. In addition, two of PGE2 receptors, EP3 and EP4, were also increased. Meanwhile, immunohistochemistry demonstrated the localization of these molecules in ischemic areas, including cortex, striatum and hippocampus, and reflected their expression patterns in different regions. Combining the results of PCR, Western blotting and immunohistochemistry, we can determine where the increase or decrease of these molecules occurs. Overall, these results further indicate a possible pathway that mediates enhanced production of PGE2, and thus that may impact production of inflammatory cytokines including IL-1β and TNF-α during cerebral I/R injury.

Genetic deletion of the prostaglandin E2 E prostanoid receptor subtype 3 improves anatomical and functional outcomes after intracerebral hemorrhage

Intracerebral hemorrhage (ICH) is a stroke subtype associated with high mortality and morbidity. Following ICH, excitotoxicity and inflammation significantly contribute to secondary brain injury and poor outcomes. Prostaglandin E2 (PGE2 ) levels rise locally with insult to the nervous system, and PGE2 is known to modulate these processes mainly through its E prostanoid (EP) receptors, EP1-4. EP receptor subtype 3 (EP3) is the most abundant EP receptor in the brain and we have previously shown that signaling through the PGE2 -EP3 axis exacerbates excitotoxicity and ischemic stroke outcomes. This study aimed to investigate the contribution of this pathway in modulating anatomical outcomes and functional recovery following ICH. Genetic deletion of EP3 resulted in 48.2 ± 7.3% less ICH-induced brain injury (P < 0.005) and improved functional recovery (P < 0.05), as identified by neurological deficit scoring. To start investigating the mechanisms involved in neuroprotection with impaired PGE2 -EP3 signaling, histological staining was performed to evaluate blood and ferric iron accumulation, neuroinflammation, blood-brain barrier dysfunction, and peripheral neutrophil infiltration. After ICH, EP3 knockout mice demonstrated 49.5 ± 8.8% and 42.8 ± 13.1% less blood (P < 0.01) and ferric iron (P < 0.05), respectively. Furthermore, EP3 knockout mice had significantly reduced astrogliosis, microglial activation, blood-brain barrier breakdown, and neutrophil infiltration. Collectively, these results suggest an injurious role for the PGE2 -EP3 signaling axis in modulating brain injury, inflammation, and neurological functional recovery after ICH. Modulation of the PGE2 -EP3 signaling axis may represent a putative therapeutic avenue for the treatment of ICH.

Sensory and signaling mechanisms of bradykinin, eicosanoids, platelet-activating factor, and nitric oxide in peripheral nociceptors

Peripheral mediators can contribute to the development and maintenance of inflammatory and neuropathic pain and its concomitants (hyperalgesia and allodynia) via two mechanisms. Activation or excitation by these substances of nociceptive nerve endings or fibers implicates generation of action potentials which then travel to the central nervous system and may induce pain sensation. Sensitization of nociceptors refers to their increased responsiveness to either thermal, mechanical, or chemical stimuli that may be translated to corresponding hyperalgesias. This review aims to give an account of the excitatory and sensitizing actions of inflammatory mediators including bradykinin, prostaglandins, thromboxanes, leukotrienes, platelet-activating factor, and nitric oxide on nociceptive primary afferent neurons. Manifestations, receptor molecules, and intracellular signaling mechanisms of the effects of these mediators are discussed in detail. With regard to signaling, most data reported have been obtained from transfected nonneuronal cells and somata of cultured sensory neurons as these structures are more accessible to direct study of sensory and signal transduction. The peripheral processes of sensory neurons, where painful stimuli actually affect the nociceptors in vivo, show marked differences with respect to biophysics, ultrastructure, and equipment with receptors and ion channels compared with cellular models. Therefore, an effort was made to highlight signaling mechanisms for which supporting data from molecular, cellular, and behavioral models are consistent with findings that reflect properties of peripheral nociceptive nerve endings. Identified molecular elements of these signaling pathways may serve as validated targets for development of novel types of analgesic drugs.

Molecular characterization of prostaglandin F receptor (FP) and E receptor subtype 3 (EP3) in chickens

Prostaglandin E and F regulate diverse physiological functions including gastrointestinal motility, fever induction and reproduction. This multitude of biological effects is mediated via their four E receptor subtypes (EP(1), EP(2), EP(3) and EP(4)) and F receptor (FP), respectively. Majority of these studies was performed in mammalian species, while investigations on their roles were impeded by inadequate information on their receptors in avian species. In present study, full-length cDNAs of chicken EP(3) (cEP(3)) and two isoforms of FP - cFPa and cFPb - were cloned from adult hen ovary. The putative cEP(3) and cFPa share high amino acid sequence identity with their respective orthologs, while the predicted cFPb is a novel middle-truncated splice variant which lacks 107 amino acids between transmembrane domains 4 and 6. RT-PCR showed that cEP(3), cFPa and cFPb are widely expressed in adult tissues examined, including ovary and oviduct. Using a pGL3-CRE luciferase reporter system, cEP(3)-expressing DF1 cells inhibited forskolin-induced luciferase activity (EC(50): <1.9 pM) upon PGE(2) treatment, suggesting that cEP(3) may functionally couple to Gi protein. Upon PGF(2α) addition, cFPa was shown to potentially couple to intracellular Ca(2+)-signaling pathway by pGL3-NFAT-RE reporter assay (EC(50): 2.9 nM), while cFPb showed no response. Using a pGL4-SRE reporter system, both cEP(3) and cFPa exhibited potential MAPK activation by PGE(2) and PGF(2α) at EC(50) 0.34 and 13 nM, respectively. Molecular characterization of these receptors paved the road to the better understanding of PGE(2) and PGF(2α) roles in avian physiology and comparative endocrinology studies.

The pharmacological effect of BGC20-1531, a novel prostanoid EP4 receptor antagonist, in the prostaglandin E2 human model of headache

Using a human Prostaglandin E(2) (PGE(2)) model of headache, we examined whether a novel potent and selective EP(4) receptor antagonist, BGC20-1531, may prevent headache and dilatation of the middle cerebral (MCA) and superficial temporal artery (STA). In a three-way cross-over trial, eight healthy volunteers were randomly allocated to receive 200 and 400 mg BGC20-1531 and placebo, followed by a 25-min infusion of PGE(2). We recorded headache intensity on a verbal rating scale, MCA blood flow velocity and STA diameter. There was no difference in headache response or prevention of the dilation of the MCA or the STA (P > 0.05) with either dose of BGC20-1531 relative to placebo, although putative therapeutic exposures were not reached in all volunteers. In conclusion, these data suggest that the other EP receptors may be involved in PGE(2) induced headache and dilatation in normal subjects.

Intracisternal administration of COX inhibitors attenuates mechanical allodynia following compression of the trigeminal ganglion in rats

The purpose of the present study was to investigate the role of central cyclooxygenase (COX) pathways in the modulation of mechanical allodynia following compression of the left trigeminal ganglion. Experiments were carried out on male Sprague-Dawley rats mounted onto a stereotaxic frame under anesthesia. For compression, a 4% agar solution (10 microl) was injected into the trigeminal ganglion. In the control group, rats were sham operated without agar injections. Ipsilateral and contralateral air-puff thresholds significantly decreased following trigeminal ganglion compression. Mechanical allodynia was established within 3 days and lasted beyond postoperative day 30, returning to preoperative levels at approximately 55 days following compression. Intracisternal administration of indomethacin, a non-selective COX inhibitor, SC-560, a selective COX-1 inhibitor, or NS-398, a selective COX-2 inhibitor, significantly inhibited mechanical allodynia. The individual anti-allodynic effects of the three COX inhibitors persisted for 6 h and returned to pretreatment values within 24 h. Based on these results, the blockade of central COX pathways may comprise a potential new therapeutic tool for the treatment of trigeminal ganglion compression-induced nociception.

Dual modulation of urinary bladder activity and urine flow by prostanoid EP3 receptors in the conscious rat

BACKGROUND AND PURPOSE

Cyclooxygenase inhibitors function to reduce levels of prostaglandin E(2) (PGE(2)) and are broadly efficacious in models of bladder overactivity. We therefore investigated a regulation of urinary bladder function in conscious rats by modulation of the EP(3) receptor for PGE(2).

EXPERIMENTAL APPROACH

The activity of the EP(3) receptor agonist GR63799X, and EP(3) receptor antagonists, CM9 and DG041, at recombinant EP(3) receptors was evaluated in vitro. In vivo, intraduodenal dosing during conscious, continuous-filling cystometry of spontaneously hypertensive rats was utilized to determine the urodynamic effect of EP(3) receptor modulation.

KEY RESULTS

GR63799X dose-dependently (0.001-1 mg x kg(-1)) reduced bladder capacity, as indicated by a reduction in both the micturition interval and volume of urine per void. In contrast, CM9 (10 and 30 mg x kg(-1)) and DG041 (30 mg x kg(-1)) enhanced bladder capacity, as indicated by significantly longer micturition intervals and larger void volumes. CM9 and DG041 inhibited the responses to GR63799X supporting the in vivo activity of these pharmacological agents at the EP(3) receptor. In addition to its effect on bladder capacity, GR63799X increased endogenous urine production. Intra-arterial infusion of saline mimicked the enhancement of urine flow observed with GR63799X, and the response was inhibited by CM9.

CONCLUSIONS AND IMPLICATIONS

These data support the EP(3) receptor as a modulator of urinary bladder activity in the conscious rat, and in addition, indicate a role for EP(3) receptor activity in regulating urine flow.

Excitation and sensitization of nociceptors by bradykinin: what do we know?

Bradykinin is an endogenous nonapeptide known to induce pain and hyperalgesia to heat and mechanical stimulation. Correspondingly, it excites nociceptors in various tissues and sensitizes them to heat, whereas sensitizing effect on the mechanical response of nociceptors is not well established. Protein kinase C and TRPV1 contribute to the sensitizing mechanism of bradykinin to heat. In addition, TRPA1 and other ion channels appear to contribute to excitation caused by bradykinin. Finally, prostaglandins sensitize bradykinin-induced excitation in normal tissues by restoring desensitized responses due to the inhibition of protein kinase A.

Modulation of bladder function by prostaglandin EP3 receptors in the central nervous system

Prostaglandin EP3 receptors in the central nervous system (CNS) may exert an excitatory effect on urinary bladder function via modulation of bladder afferent pathways. We have studied this action, using two EP3 antagonists, (2 E)-3-{1-[(2,4-dichlorophenyl)methyl]-5-fluoro-3-methyl-1 H-indol-7-yl}- N-[(4,5-dichloro-2-thienyl)sulfonyl]-2-propenamide (DG041) and (2 E)- N-{[5-bromo-2-(methyloxy)phenyl] sulfonyl}-3-[2-(2-naphthalenylmethyl)phenyl]-2-propenamide (CM9). DG041 and CM9 were proven to be selective EP3 antagonists with radioligand binding and functional fluorescent imaging plate reader (FLIPR) assays. Their effects on volume-induced rhythmic bladder contraction and the visceromotor reflex (VMR) response to urinary bladder distension (UBD) were evaluated in female rats after intrathecal or intracerebroventricular administration. Both DG041 and CM9 showed a high affinity for EP3 receptors at subnanomolar concentrations without significant selectivity for any splice variants. At the human EP3C receptor, both inhibited calcium influx produced by the nonselective agonist PGE2. After intrathecal or intracerebroventricular administration both CM9 and DG041 dose-dependently reduced the frequency, but not the amplitude, of the bladder rhythmic contraction. With intrathecal administration DG041 and CM9 produced a long-lasting and robust inhibition on the VMR response to UBD, whereas with intracerebroventricular injection both compounds elicited only a transient reduction of the VMR response to bladder distension. These data support the concept that EP3 receptors are involved in bladder micturition at supraspinal and spinal centers and in bladder nociception at the spinal cord. A centrally acting EP3 receptor antagonist may be useful in the control of detrusor overactivity and/or pain associated with bladder disorders.

An excitatory role for peripheral EP3 receptors in bladder afferent function

The excitatory roles of EP3 receptors at the peripheral afferent nerve innervating the rat urinary bladder have been evaluated by using the selective EP3 antagonist (2 E)-3-{1-[(2,4-dichlorophenyl)methyl]-5-fluoro-3-methyl-1 H-indol-7-yl}- N-[(4,5-dichloro-2-thienyl)sulfonyl]-2-propenamide (DG-041). The bladder rhythmic contraction model and a bladder pain model measuring the visceromotor reflex (VMR) to urinary bladder distension (UBD) have been used to evaluate DG-041 in female rats. In addition, male rats [spontaneously hypertensive rat (SHR), Wistar-Kyoto (WKY), and Sprague-Dawley (SD)] were anesthetized with pentobarbital sodium, and primary afferent fibers in the L6 dorsal root were isolated for recording the inhibitory response to UBD following intravenous injection of DG-041. Intravenous injection of DG-041 (10 mg/kg), a peripherally restricted EP3 receptor antagonist, significantly reduced the frequency of bladder rhythmic contraction and inhibited the VMR response to bladder distension. The magnitude of reduction of the VMR response was not different in the different strains of rats (SD, SHR, and WKY). Furthermore, quantitative characterization of the mechanosensitive properties of bladder afferent nerves in SHR, WKY, and SD rats did not show the SHR to be supersensitive to bladder distension. DG-041 selectively attenuated responses of mechanosensitive afferent nerves to UBD, with strong suppression on the slow-conducting, high-threshold afferent fibers, with equivalent activity in the three strains. We conclude that sensitization of afferent nerve activity was not one of the mechanisms of bladder hypersensitivity in SHR. EP3 receptors are involved in the regulation of bladder micturition and bladder nociception at the peripheral level.

Prostaglandin E2 (PGE2) inhibits glutamatergic synaptic transmission in dorsolateral periaqueductal gray (dl-PAG)

The purpose of this study was to determine the role of prostaglandin E(2) (PGE(2)) in modulating neuronal activity of the dorsolateral periaqueductal gray (dl-PAG) through excitatory and inhibitory synaptic inputs. First, whole cell voltage-clamp recording was performed to obtain excitatory and inhibitory postsynaptic currents (EPSCs and IPSCs) of the dl-PAG neurons. Our results show that PGE(2) significantly decreased the frequency of miniature EPSCs and amplitude of evoked EPSCs. The effects were mimicked by sulprostone, an agonist to PGE(2) EP(3) receptors. In contrast, PGE(2) had no distinct effect on IPSCs. In addition, spontaneous action potential of the dl-PAG neurons was recorded using whole cell current-clamp methods. PGE(2) significantly attenuated the discharge rate of the dl-PAG neurons. The decreased firing activity was abolished in the presence of glutamate NMDA and non-NMDA receptor antagonists. The results from the current study provide the first evidence indicating that PGE(2) inhibits the neuronal activity of the dl-PAG via selective attenuation of glutamatergic synaptic inputs, likely due to the activation of presynaptic EP(3) receptors.

Intraplantar PGE2 causes nociceptive behaviour and mechanical allodynia: the role of prostanoid E receptors and protein kinases

BACKGROUND AND PURPOSE

Receptor subtypes involved in PGE(2)-induced nociception are still controversial. The present study investigated the prostanoid E receptor (EP) subtypes and the protein kinase (PK) pathways involved in the nociception induced by PGE(2) injection in the mouse paw.

EXPERIMENTAL APPROACH

Paw-licking and mechanical allodynia were measured in vivo and protein kinase activation ex vivo by Western blots of extracts of paw skin.

KEY RESULTS

Intraplantar (i.pl.) injection of PGE(2) into the mouse paw caused nociceptive behaviour of short duration with mean ED(50) of 1.43 nmol. PGE(2) produced a longer-lasting mechanical allodynia, with an ED(50) of 0.05 nmol. Intraplantar injection of antagonists at EP(3) or EP(4), but not at EP(1) or EP(2) receptors inhibited PGE(2)-induced paw-licking. Paw-licking caused by PGE(2) was blocked by an inhibitor of PKA but only partially decreased by inhibition of the extracellular-regulated kinase (ERK). Selective inhibitors of PKC, c-Jun N-terminal kinase (JNK) or p38, all failed to affect PGE(2)-induced paw-licking. An EP(3) antagonist inhibited PGE(2)-induced mechanical allodynia. However, inhibitors of PKA, PKC or ERK, but not p38 or JNK, also partially inhibited PGE(2)-induced mechanical allodynia. Western blot analyses confirmed that i.pl. injection of PGE(2) activated PKA, PKCalpha, and mitogen activated kinases (MAPKs) in the paw. Co-treatment with EP(3) or EP(4) receptor antagonists reduced PGE(2)-induced PKA and ERK, but not PKCalpha activation.

CONCLUSIONS AND IMPLICATIONS

The present results indicate that the nociceptive behaviour and mechanical allodynia caused by i.pl. PGE(2) are mediated through activation of distinct EP receptors and PK-dependent mechanisms.

Central cyclooxygenase inhibitors reduced IL-1β-induced hyperalgesia in temporomandibular joint of freely moving rats

Microinjection of formalin (5%, 50 microl) into a temporomandibular joint (TMJ) causes noxious behavioral responses in freely moving rats. In the present study, we investigated the role of central cyclooxygenase (COX) pathways in IL-1beta-induced hyperalgesia with formalin-induced TMJ pain model. Intra-articular injection of 100 pg or 1 ng of IL-1beta significantly facilitated formalin-induced behavior by 130 or 174% in the number of scratches. Intracisternal administration of 100 pg or 1 ng of IL-1beta also significantly increased formalin-induced behavior by 166 or 82% in the number of scratches. IL-1beta-induced hyperalgesia was blocked by pretreatment with IL-1 receptor antagonist. Intracisternal pretreatment with SC-560, a selective COX-1 inhibitor, or NS-398, a selective COX-2 inhibitor, abolished intra-articular administration of IL-1beta-induced hyperalgesic response. Intracisternal pretreatment with NS-398, a selective COX-2 inhibitor, abolished the intracisternal administration of IL-1beta-induced hyperalgesic response, while pretreatment with SC-560, a selective COX-1 inhibitor, did not change IL-1beta-induced hyperalgesic responses. On the other hand, pretreatment with acetaminophen, a tentative COX-3 inhibitor, also abolished both intra-articular and intracisternal administration of IL-1beta-induced hyperalgesic responses. These results indicate that central COX-2 plays important role in the central administration of IL-1beta-induced hyperalgesia and that central COX-1/2 pathways mediate peripheral administration of IL-1beta-induced hyperalgesia in the TMJ. Central COX-3 inhibitor seems to play an important role in the nociceptive process associated with both peripheral and central administration of IL-1beta-induced hyperalgesia in TMJ. It is concluded that central acting of COX-3 inhibitors may be of therapeutic value in the treatment of inflammatory pain in TMJ.

Tumor necrosis factor alpha and interleukin-1beta stimulate the expression of cyclooxygenase II but do not alter prostaglandin E2 receptor mRNA levels in cultured dorsal root ganglia cells

Tumor necrosis factor alpha (TNFalpha) and interleukin 1beta (IL-1beta) are pro-inflammatory cytokines capable of altering the sensitivity of sensory neurons. Because sensitization elicited by IL-1beta and TNFalpha is blocked by inhibition of the inducible enzyme, cyclooxygenase-II (COX-2), we examined whether these cytokines could increase COX-2 expression in dorsal root ganglion (DRG) cultures. Treatment of cell cultures with either IL-1beta or TNFalpha increases immunoreactive COX-2, as measured by immunoblotting, in a time- and concentration-dependent manner. A 24-h pretreatment with 10 ng/ml IL-1beta or 50 ng/ml TNFalpha augmented COX-2 expression 50- and 8-fold over basal levels, respectively. Immunohistochemistry established the presence of COX-2-like immunoreactivity in both neuronal and non-neuronal cells in culture. The addition of IL-1 receptor antagonist blocked the induction of COX-2 expression by IL-1beta, but did not alter TNFalpha-stimulated increases in COX-2, indicating that the mechanism of TNFalpha is not limited to increasing the expression of IL-1beta. The basal and TNFalpha-induced expression of COX-2 was not dependent on the presence of NGF in the growth media. IL-1beta and TNFalpha treatment for 24 h enhanced prostaglandin E2 (PGE2) production 2-4-fold, which was blocked by pretreatment with the COX-2 inhibitor, NS-398. Exposing cultures to PGE2, IL-1beta, or TNFalpha for 24 h did not alter PGE2 receptor (EP) mRNA levels. These results indicate that TNFalpha and IL-1beta induce the functional expression of COX-2 but not EP receptors in DRG cells in culture and suggest that cytokine-induced sensitization of sensory neurons is secondary to prostaglandin production and not alterations in EP receptors.

Central cyclooxygenase-2 participates in interleukin-1β-induced hyperalgesia in the orofacial formalin test of freely moving rats

The present study was performed to investigate effects of central cyclooxygenase (COX) on interleukin (IL)-1beta-induced hyperalgesia in the orofacial area. Experiments were carried out on 72 male Sprague-Dawley rats weighing 220-280 g. Surgical procedures were performed under pentobarbital sodium. We examined noxious behavioral scratching responses induced by 50 microl of 5% formalin injected subcutaneously into the vibrissa pad without any restraints. The orofacial formalin responses exhibited two distinct phases with early responses (0-10 min) and continuous prolonged responses (11-45 min). Intracisternal injection of 100 pg IL-1beta significantly increased noxious behavioral responses. Pretreatment with indomethacin, a non-selective COX inhibitor, or NS-398, a selective COX-2 inhibitor, blocked IL-1beta-induced hyperalgesic responses. However, pretreatment with SC-560, a selective COX-1 inhibitor, did not change hyperalgesic response to IL-1beta. These data suggest that central IL-1beta modulates the transmission of nociceptive information in the orofacial area and that central COX-2 plays an important role in IL-1beta-induced hyperalgesia.

PGE(2) selectively blocks inhibitory glycinergic neurotransmission onto rat superficial dorsal horn neurons

Despite the crucial role that prostaglandins (PGs) have in the sensitization of the central nervous system to pain, their cellular and molecular targets leading to increased pain perception have remained elusive. Here we investigated the effects of PGE(2) on fast synaptic transmission onto neurons in the rat spinal cord dorsal horn, the first site of synaptic integration in the pain pathway. We identified the inhibitory (strychnine-sensitive) glycine receptor as a specific target of PGE(2). PGE(2), but not PGF(2 alpha), PGD(2) or PGI(2), reduced inhibitory glycinergic synaptic transmission in low nanomolar concentrations, whereas GABAA, AMPA and NMDA receptor-mediated transmission remained unaffected. Inhibition of glycine receptors occurred via a postsynaptic mechanism involving the activation of EP2 receptors, cholera-toxin-sensitive G-proteins and cAMP-dependent protein kinase. Via this mechanism, PGE(2) may facilitate the transmission of nociceptive input through the spinal cord dorsal horn to higher brain areas where pain becomes conscious.

Prostaglandin EP3 receptor protein in serotonin and catecholamine cell groups: a double immunofluorescence study in the rat brain

Prostaglandin E(2) exerts diverse physiological actions in the central nervous system with unknown mechanisms. We have reported the immunohistochemical localization of the EP3 receptor, one of the prostaglandin E receptor subtypes, in various brain regions including many monoaminergic nuclei. In the present study, a double immunofluorescence technique with an antibody to EP3 receptor and antibodies to markers for monoamine neurons was employed to examine the expression of the receptor in serotonin and catecholamine neurons, and to reveal the distribution of the receptor-expressing monoamine neurons in the rat brain. Almost all serotonergic cells in the medulla oblongata (B1-B4) exhibited EP3 receptor-like immunoreactivity, whereas mesencephalic and pontine serotonergic cell groups (B5-B9) contained relatively small populations of EP3 receptor-immunoreactive cells. In the catecholaminergic cell groups, many of the noradrenergic A7 cells in the subcoeruleus nucleus showed immunoreactivity for the receptor. The locus coeruleus exhibited EP3 receptor-like immunoreactivity densely in the neuropil and occasionally in neuronal cell bodies, all of which were immunopositive for dopamine beta-hydroxylase, as observed by confocal laser microscopy. Many of the other noradrenergic and adrenergic cell groups contained small populations of EP3 receptor-like immunoreactive cells. In contrast, no EP3 receptor-like immunoreactivity was detected in the noradrenergic A2 and A4, the adrenergic C2, and all the dopaminergic cell groups. The expression of EP3 receptor by most of the serotonergic, noradrenergic and adrenergic cell groups suggests that prostaglandin E(2) modulates many physiological processes mediated by widely distributed monoaminergic projections through activation of the EP3 receptor on the monoaminergic neurons; for instance, it may modulate nociceptive and autonomic processes by affecting the descending serotonergic pathway from the raphe magnus nucleus to the spinal cord.

Prostaglandin receptor subtypes, EP3C and EP4, mediate the prostaglandin E2-induced cAMP production and sensitization of sensory neurons

Although a number of prostaglandin E(2) (PGE(2)) receptor subtypes have been cloned, limited studies have been performed to elucidate subtypes that subserve specific actions of this eicosanoid, in part because of a paucity of selective receptor antagonists. Using reverse transcription-polymerase chain reaction (PCR) and antisense oligonucleotides, we examined which prostaglandin E(2) receptor (EP receptor) subtypes are expressed in sensory neurons and which mediate the PGE(2)-induced increase in cAMP production and augmentation of peptide release. Reverse transcription-PCR of cDNA isolated from rat sensory neurons grown in culture revealed PCR products for the EP1, EP2, EP3C, and EP4 receptor subtypes but not the EP3A or EP3B. Preexposing neuronal cultures for 48 h to antisense oligonucleotides of EP3C and EP4 mRNA diminished expression of the respective receptors by approximately 80%, abolished the PGE(2)-stimulated production of cAMP, and blocked the ability of PGE(2) to augment release of immunoreactive substance P and calcitonin gene-related peptide. Pretreating with individual antisense against the EP2, EP3C, or EP4 receptors or combinations of missense oligonucleotides had no effect on PGE(2)-induced activity. Treatment with antisense to EP3C and EP4 receptor subtypes did not alter the ability of forskolin to increase cAMP or enhance peptide release. These results demonstrate that sensory neurons are capable of expressing multiple EP receptor subtypes but that only the EP3C and EP4 receptors mediate PGE(2)-induced sensitization of sensory neurons.

Direct activation of rat spinal dorsal horn neurons by prostaglandin E2

Whole-cell patch-clamp and intracellular recording techniques have been used to study the action of prostaglandin E2 (PGE2) on neurons in adult rat transverse spinal cord slices. Bath-applied PGE2 (1-20 microm) induced an inward current or membrane depolarization in the majority of deep dorsal horn neurons (laminas III-VI; 83 of 139 cells), but only in a minority of lamina II neurons (6 of 53 cells). PGE2 alone never elicited spontaneous action potentials; however, it did convert subthreshold EPSPs to suprathreshold, leading to action potential generation. PGE2-induced inward currents were unaffected by perfusion with either a Ca(2+)-free/high Mg(2+) (5 mm) solution or tetrodotoxin (1 microm), indicating a direct postsynaptic action. Both 17-phenyl trinor prostaglandin E2 (an EP1 agonist) and sulprostone (an EP3 agonist) had little effect on membrane current, whereas butaprost methyl ester (an EP2 agonist) mimicked the effect of PGE2. Depolarizing responses to PGE2 were associated with a decrease in input resistance, and the amplitude of inward current was decreased as the holding potential was depolarized. PGE2-induced inward currents were reduced by substitution of extracellular Na(+) with N-methyl-d-glucamine and inhibited by flufenamic acid (50-200 microm), which is compatible with activation of a nonselective cation channel. These results suggest that PGE2, acting via an EP2-like receptor, directly depolarizes spinal neurons. Moreover, these findings imply an involvement of spinal cord-generated prostanoids in modulating sensory processing through an alteration in dorsal horn neuronal excitability.

Interactions of inflammatory mediators stimulating release of calcitonin gene-related peptide, substance P and prostaglandin E(2) from isolated rat skin

Inflammatory mediators acting directly on nociceptive primary afferents induce neuropeptide release. In this study we investigated interactions between bradykinin, serotonin, histamine, prostaglandin and acid pH in stimulating the release of substance P (SP), calcitonin gene-related peptide (CGRP) and prostaglandin E(2) (PGE(2)) from isolated flaps of rat back skin using enzyme immunoassays. Stimulation with bradykinin (10(-5) M) augmented the release of SP, CGRP and PGE(2) significantly. Serotonin, histamine and PGE(2) individually tested (10(-5) M) had no effect on neuropeptide release but they facilitated the bradykinin-evoked neuropeptide release. When bradykinin was combined with both serotonin and histamine, neither additional PGE(2) nor acid pH showed any further effect, suggesting that the facilitation had reached a maximum. Exposure of the skin to acid pH (6.1 or 5.2) significantly increased CGRP release. SP release was only slightly enhanced and PGE(2) release, in contrast, was suppressed by low pH stimulation, probably due to pH-dependent inhibition of phospholipase A(2). Treatment of the rats with flurbiprofen (25 mg/kg i.p.) one hour before dissection reduced PGE(2) to detection level and inhibited the CGRP secretion evoked by the combination of bradykinin, serotonin and histamine (all 10(-6) M). As this suppression could not be overcome by substitution of PGE(2) (10(-6) M), it is likely that exogenously applied PGE(2) differs in effect from endogenous, intracellularly synthesized prostaglandins that are accompanied by active intermediates and byproducts.

Immunohistochemical localization of prostaglandin EP3 receptor in the rat nervous system

The prostaglandin EP3 receptor (EP3R) subtype is believed to mediate large portions of diverse physiologic actions of prostaglandin E2 in the nervous system. However, the distribution of EP3R protein has not yet been unveiled in the peripheral or central nervous systems. The authors raised a polyclonal antibody against an amino-terminal portion of rat EP3R that recognized specifically the receptor protein. In this study, immunoblotting analysis with this antibody showed several immunoreactive bands with different molecular weights in rat brain extracts and in membrane fractions of recombinant EP3R-expressing culture cells, and treatment with N-glycosidase shifted those immunoreactive bands to an apparently single band with a lower molecular weight, suggesting that EP3R proteins are modified posttranslationally with carbohydrate moieties of various sizes. The authors performed immunohistochemical investigation of EP3R in the rat brain, spinal cord, and peripheral ganglia by using the antibody. EP3R-like immunoreactivity was observed in many and discrete regions of the rostrocaudal axis of the nervous system. The signals were particularly strong in the anterior, intralaminar, and midline thalamic nuclear groups; the median preoptic nucleus; the medial mammillary nucleus; the superior colliculus; the periaqueductal gray; the lateral parabrachial nucleus; the nucleus of the solitary tract; and laminae I and II of the medullary and spinal dorsal horns. Sensory ganglia, such as the trigeminal, dorsal root, and nodose ganglia, contained many immunopositive neurons. Neuronal cells in the locus coeruleus and raphe nuclei exhibited EP3R-like immunoreactivity. This suggests that EP3R plays regulatory roles in the noradrenergic and serotonergic monoamine systems. Autonomic preganglionic nuclei, such as the dorsal motor nucleus of the vagus nerve, the spinal intermediolateral nucleus, and the sacral parasympathetic nucleus, also contained neuronal cell bodies with the immunoreactivity, implying modulatory functions of EP3R in the central autonomic nervous system. The characteristic distribution of EP3R provides valuable information on the mechanisms for various physiologic actions of prostaglandin E2 in the central and peripheral nervous systems.

Hyperalgesia due to nerve injury: role of prostaglandins

The hypothesis that prostaglandins contribute to hyperalgesia resulting from nerve injury was tested in rats in which the sciatic nerve was partially transected on one side. Subcutaneous injection of indomethacin (a classic inhibitor of cyclo-oxygenase) into the affected hindpaw relieved mechanical hyperalgesia for up to 10 days after injection. Subcutaneous injection of meloxicam or SC-58125 (selective inhibitors of cyclo-oxygenase-2) into the affected hindpaw also relieved mechanical hyperalgesia, but with a shorter time-course. Subcutaneous injection of SC-19220 (an EP1 prostaglandin receptor blocker) into the affected hindpaw produced significant relief of mechanical and thermal hyperalgesia. Comparable injections into the contralateral paw or abdomen had no effect on mechanical or thermal hyperalgesia, suggesting that the effects we observed were local rather than systemic. We conclude that prostaglandins, probably prostaglandin E1 or E2, contribute to the peripheral mechanisms underlying hyperalgesia following nerve injury. These data provide further evidence that inflammatory mediators contribute to neuropathic pain, and may warrant further study of peripherally administered non-steroidal anti-inflammatory drugs as a possible treatment for such pain in patients.

Mechanical sensitization of cutaneous C-fiber nociceptors by prostaglandin E2 in the rat

While it is generally assumed that nociceptor sensitization underlies peripheral hyperalgesia, there is disagreement regarding the ability of inflammatory mediators to sensitize nociceptors to mechanical stimuli. In this in vivo electrophysiological study, mechanical threshold and response to sustained threshold and sustained suprathreshold mechanical stimuli were measured before and after intradermal administration of prostaglandin E2 (PGE2) into the receptive field of cutaneous C-fiber nociceptors in the rat. PGE2 produced a decrease in mechanical threshold and an increase in response to sustained threshold but not sustained suprathreshold mechanical stimulation. These data suggest that while inflammatory mediators produce a decrease in mechanical threshold and/or an increase in number of action potentials to sustained threshold stimuli, they do not increase the maximal response to mechanical stimuli in C-fiber nociceptors.

NOS inhibitor antagonism of PGE2-induced mechanical sensitization of cutaneous C-fiber nociceptors in the rat

Prostaglandins, metabolites of arachidonic acid, released during tissue injury and inflammation sensitize primary afferent nociceptors. While it has been suggested that this effect on nociceptors is mediated mainly via the cAMP second messenger system, recent evidence suggests that nitric oxide (NO) is also involved in peripheral pain mechanisms. To test the hypothesis that NO contributes to the sensitization of nociceptors to mechanical stimuli induced by hyperalgesic prostaglandins, we compared von Frey hair mechanical threshold as well as the response evoked by 10-s sustained threshold mechanical stimulation before and after injection of prostaglandin E2 (PGE2) alone, and NOS inhibitor NG-methyl-L-arginine (L-NMA) or its inactive stereoisomer NG-methyl-D-arginine (D-NMA) plus PGE2, adjacent to the receptive field of C-fiber nociceptors. The reduction of mechanical threshold and increase in number of action potentials to sustained mechanical stimulation induced by intradermal application of PGE2 was blocked by L-NMA, but not D-NMA. It is suggested that NO contributes to nociceptor sensitization induced by hyperalgesic prostaglandins.

Mast cell degranulation induces delayed rectal allodynia in rats: role of histamine and 5-HT

Visceral hypersensitivity is a common feature of functional bowel disorders, where an increased number of mast cells have often been described. Thus, we investigated the effect of an experimental mast cell degranulation induced by BrX-537A on somatic (tail heating) and visceral (rectal distension) sensitivity in rats and the involvement of histamine and/or serotonin on this last response. After BrX-537A administration, the latency of tail withdrawal reflex was shortened within the 2- to 8-hr period. Moreover, BrX-537A reduced the distension volume threshold from 0.8 ml to 0.4 ml inducing allodynia, from 6 to 12 hr after its administration. This effect was suppressed by doxantrazole (mast cell stabilizing agent) and WAY 100635 (5-HT1A receptor antagonist), and reproduced by 5-HTP (5-HT precursor) and 8-OH-DPAT (5-HT1A receptor agonist). However, neither granisetron (5-HT3 receptor antagonist) nor H1, H2, or H3 histamine receptor antagonists modified the BrX-537A-induced allodynia. Consequently, mast cell degranulation initiates a delayed somatic and visceral allodynia, with the participation of serotonin, through 5-HT1A receptor activation, on the visceral response.

Biphasic modulation in the trigeminal nociceptive neuronal responses by the intracerebroventricular prostaglandin E2 may be mediated through different EP receptors subtypes in rats

To determine which prostaglandin E2 (PGE2) receptor subtypes are involved in the brain-derived PGE2-induced changes in nociception, we injected synthetic EP1, EP2 and EP3 receptor agonists (0.01 fmol to 10 nmol) into the lateral cerebroventricle (LCV) of urethane-anesthetized rats and observed the changes in the responses of the wide dynamic range (WDR) neurons in the trigeminal nucleus caudalis to noxious pinching of facial skin. The enhancement and suppression of the nociceptive responses of the WDR neurons were observed after the LCV injection of MB28767 (an EP3 receptor agonist) at a low dose range (1-100 fmol) and 17-phenyl-omega-trinor PGE2 (an EP1 receptor agonist) at high doses (1-10 nmol), respectively. Furthermore, the suppression of nociceptive neuronal responses after the LCV injection of PGE2 (1 nmol) was completely blocked by SC19220 (an EP1 receptor antagonist, 300 nmol). On the other hand, butaprost (an EP2 receptor agonist) at any doses tested (0.1 fmol to 1 nmol) had no effect on the nociceptive responses. The LCV injection of MB28767 (10 fmol) and 17-phenyl-omega-trinor PGE2 (1 nmol), which respectively enhanced and suppressed the nociceptive neuronal responses, did not affect the responses of the low threshold mechanoreceptive neurons to innocuous tactile stimuli. These results provide electrophysiological evidence that brain-derived PGE2 induces mechanical hyperalgesia and hypoalgesia through EP3 and EP1 receptors, respectively, in the rat.

Prostaglandin E receptor EP3 subtype induces neurite retraction via small GTPase Rho

Prostaglandin E receptor EP3 subtype is widely distributed in the nervous system and is specifically localized to neurons, suggesting that the EP3 receptor plays important roles in the nervous system. We established a PC12 cell line that stably expresses the EP3B receptor isoform isolated from bovine adrenal chromaffin cells and examined the effect of agonist stimulation on the neuronal morphology of the PC12 cells. In the differentiated cells, M&B28767, an EP3 agonist, caused neurite retraction in a pertussis toxin-insensitive manner. 12-O-Tetradecanoylphorbol-13-acetate (TPA) also induced neurite retraction. However, when protein kinase C was down-regulated by long term exposure to TPA, TPA failed to induce neurite retraction, while the EP3B receptor-mediated retraction occurred normally. Clostridium botulinum C3 exoenzyme completely inhibited both EP3 agonist- and TPA-induced neurite retraction when microinjected into the cells, indicating that the morphological effect of the EP3B receptor is dependent on Rho activity. Thus, the activation of the EP3B receptor induced neurite retraction through a protein kinase C-independent Rho-activation pathway.

Prostaglandin E2 increases the proportion of neonatal rat dorsal root ganglion neurons that respond to bradykinin

Prostaglandins sensitize some nociceptors to noxious mechanical, thermal and chemical stimuli; however, not all nociceptors are sensitized by prostaglandins. We used cultures of dorsal root ganglion neurons from neonatal rats to determine whether prostaglandins differentially alter the responsiveness of populations of neurons to the chemical stimulus bradykinin. Groups of dorsal root ganglion neurons were defined by size of the cell soma and by the presence of immunoreactivity for substance P. An increase in the concentration of free intracellular Ca2+ was used as an indicator of responsiveness to bradykinin. Pretreatment (5 min) with prostaglandin E2 (100 nM) increased the proportion of intermediate-size neurons (somal areas of 240-320 microns2) that responded to 30 nM bradykinin by two-fold but did not alter the proportion of small-size neurons (somal areas of 160-239 microns2) that responded. Pretreatment with prostaglandin E2 had no effect on the maximum increase in free intracellular Ca2+ evoked by 30 nM bradykinin in either population of neurons, defined by size. Although pretreatment with PGE2 did not increase the proportion of intermediate-size neurons that responded to a lower concentration of bradykinin (3 nM), it did increase the concentration of free intracellular Ca2+ evoked by 3 nM bradykinin. Both results were consistent with a leftward shift in the stimulus-response relationship for bradykinin following pretreatment with PGE2. Small- and intermediate-size neurons that responded to bradykinin also differed in their expression of immunoreactivity for substance P. Furthermore, intermediate-size neurons that expressed immunoreactivity for substance P were more likely to respond to bradykinin after treatment with prostaglandin E2. These results support the hypothesis that prostaglandin E2 sensitizes some normally unresponsive primary afferent neurons to chemical stimuli. One population of neurons which becomes responsive to bradykinin after treatment with prostaglandin E2 can be defined based on cell size, and furthermore, these neurons are likely to express substance P. During inflammation, recruitment of primary afferent neurons that are immunoreactive for substance P would enhance the participation of substance P in central mechanisms that contribute to hyperalgesia.

Stable analogues of cyclic AMP but not cyclic GMP sensitize unmyelinated primary afferents in rat skin to heat stimulation but not to inflammatory mediators, in vitro

The aim of this investigation was to evaluate the role played by cyclic nucleotides in the transduction of inflammatory pain and hyperalgesia. Unmyelinated afferents (n = 79) were exposed to stable analogues of cyclic AMP and cyclic GMP, to inflammatory mediators and to Methylene Blue, an inhibitor of guanylyl cyclase. Analogues of cyclic AMP at a concentration of 1 mM (n = 9) but not 10 microM (n = 16) sensitized nociceptor responses to noxious heat and enhanced interstimulus activity. In addition. mechanical thresholds were moderately, but significantly lowered after superfusion of the cyclic AMP analogue (1 mM). Addition of 10 microM cyclic AMP analogue to a mixture of excitatory inflammatory mediators (serotonin, histamine, bradykinin and prostaglandin E2, 10 microM each) did not further increase nociceptor activity (n = 15), in contrast to a previous report that cAMP sensitized bradykinin responses. Cyclic GMP analogues (10 microM, 1 mM) did not alter heat sensitivity or mechanical thresholds of polymodal C-fibres, nor did they enhance the ongoing activity that resulted from repeated heat stimulation. After inhibition of guanylyl cyclase with Methylene Blue, cyclic GMP analogues (1-10 microM) did not alter nociceptor responses evoked by application of the mixture of inflammatory mediators. The findings indicate that polymodal nociceptor sensitization and excitation is independent of cyclic GMP. Cyclic AMP can obviously contribute to the increased heat sensitivity of inflamed tissue, whereas cyclic GMP might be of importance in the recruitment of "silent" nociceptors.

Opposite effects of increased intracellular cyclic AMP on the heat and bradykinin responses of canine visceral polymodal receptors in vitro

To clarify the validity of the long standing hypothesis that effects of E series prostaglandin (PG)S are mediated by cyclic AMP (cAMP), we studied the effects of increases in intracellular cAMP on the heat and bradykinin responses of testicular polymodal receptors. Polymodal receptor activities were recorded in vitro from testis-spermatic nerve preparations excised from dogs anesthetized with pentobarbital (30 mg/kg, i.v.). Increases in intracellular cAMP induced by either forskolin (5 or 10 microM), an adenylyl cyclase activator, or a mixture of dibutyryl cAMP (20-100 microM), a membrane permeable cAMP analog, and 3-isobutyl-1-methyl xanthine (20-100 microM), an inhibitor of the cAMP degrading enzyme, significantly augmented the response to heat (42-48 degrees C). In contrast, these substances failed to facilitate the response to bradykinin (0.1 or 1 microM) and instead suppressed it. Dideoxyforskolin (10 microM), an inactive analog of forskolin, had no effects on both the heat and bradykinin responses. These results demonstrate that an increase in intracellular cAMP induces opposite effects on the heat and bradykinin responses. Possible involvement of intracellular cAMP in the facilitatory effects of PGE2 on both responses was discussed in connection with the PGE receptor subtypes involved in the sensitization of the bradykinin and heat responses.

Influence of bradykinin in gastrointestinal disorders and visceral pain induced by acute or chronic inflammation in rats

This work investigated the role of bradykinin in viscerosensitivity before and during inflammation in two models of visceral pain induced by rectal distension (RD) or "abdominal distension" (AD) in rats. RD induced both inhibition of colonic motility and an increase of abdominal spike bursts. Bradykinin receptor antagonist, Hoe 140 did not affect any of the RD-induced responses. After TNB-induced rectal inflammation, colonic inhibition and the number of abdominal contractions were enhanced. Hoe 140 selectively reduced the abdominal response to the highest distension volume, without affecting the colonic response. In AD group, acetic acid inhibited gastric emptying and increased the number of abdominal contractions, whereas the same volume of saline did not affect any of the responses. Before inflammation, Hoe 140 (1-5 mg/kg, intraperitoneally) did not affect per se abdominal and gastric emptying responses; in contrast, at 5 mg/kg, intraperitoneally, it reduced significantly (P < 0.05) both acetic acid-induced responses. We conclude that bradykinin is involved in viscerosensitivity changes related to abdominal and rectal distension in inflammatory conditions.

Is there more than one prostaglandin E receptor subtype mediating hyperalgesia in the rat hindpaw?

Five synthetic prostaglandin E analogs (11-deoxyPGE1, 17-phenyl-ol-trinor prostaglandin E2, enisoprost, MB28767 and misoprostol) have been evaluated for their ability to produce mechanical hyperalgesia in rats. The Randall-Selitto paw withdrawal model of mechanical hyperalgesia was used. Following intradermal injections (2.5 microliters) into the dorsal surface of the hindpaw, each prostaglandin E analog produced a dose-dependent (1-1000 ng) decrease in nociceptive threshold (i.e. hyperalgesia). Hyperalgesia produced by 17-phenyl-ol-trinor prostaglandin E2 and MB28767, was inhibited by the prostaglandin E1 antagonist SC19220 (7.5 ng), while the hyperalgesia produced by 11-deoxyprostaglandin E1, enisoprost and misoprostol was not inhibited by this antagonist. Hyperalgesia produced by all five analogs was significantly attenuated or completely blocked by inhibiting stimulatory guanine nucleotide-binding regulatory protein with guanosine 5'-O-(2-thiodiphosphate), adenylyl cyclase with 2'5'-dideoxyadenosine and protein kinase A with WIPTIDE. These results suggest the presence of more than one prostaglandin E-receptor subtype, which mediate hyperalgesia, predominantly via the cAMP second messenger system, in the hindpaw of the rat.

Distribution of the messenger RNA for the prostaglandin E receptor subtype EP3 in the mouse nervous system

Distribution of the messenger RNA for the prostaglandin E receptor subtype EP3 was investigated by in situ hybridization in the nervous system of the mouse. The hybridization signals for EP3 were widely distributed in the brain and sensory ganglia and specifically localized to neurons. In the dorsal root and trigeminal ganglia, about half of the neurons were labeled intensely. In the brain, intensely labeled neurons were found in Ammon's horn, the preoptic nuclei, lateral hypothalamic area, dorsomedial hypothalamic nucleus, lateral mammillary nucleus, entopeduncular nucleus, substantia nigra pars compacta, locus coeruleus and raphe nuclei. Moderately labeled neurons were seen in the mitral cell layer of the main olfactory bulb, layer V of the entorhinal and parasubicular cortices, layers V and VI of the cerebral neocortex, nuclei of the diagonal band, magnocellular preoptic nucleus, globus pallidus and lateral parabrachial nucleus. In the thalamus, moderately labeled neurons were distributed in the anterior, ventromedial, laterodorsal, paraventricular and central medial nuclei. Based on these distributions, we suggest that EP3 not only mediates prostaglandin E2 signals evoked by blood-borne cytokines in the areas poor in the blood-brain barrier, but also responds to those formed intrinsically within the brain to modulate various neuronal activities. Possible EP3 actions are discussed in relation to the reported neuronal activities of prostaglandin E2 in the brain.

Possible involvement of the EP2 receptor subtype in PGE2-induced enhancement of the heat response of nociceptors

Prostaglandin E2 augments bradykinin- and heat-induced discharges of polymodal receptors as studied in vitro preparations. Our previous study revealed the involvement of the EP3 receptor subtype in the PGE2 induced enhancement of the BK response [Brain Res. 632 (1993) 321-324]. The agonist for EP2 (butaprost; 10(-8) M) significantly augmented heat responses, but did not augment the BK responses at concentrations from 10(-8) to 10(-5) M; however, the agonist for EP3 (M&B28767) or EP1 (17-phenyl-trinor-PGE2) at 10(-7) M did not affect the heat responses. These findings indicate the involvement of the EP2 receptor subtype in the augmenting effect of PGE2 on heat responses.

Forskolin does not augment the bradykinin response of canine visceral polymodal receptors in vitro

In clarifying the possible involvement of cyclic AMP (cAMP) in prostaglandin (PG) E2-induced sensitization of the bradykinin response of canine testicular polymodal receptors, the effects of forskolin, an activator of adenylyl cyclase, were studied in the presence and absence of acetylsalicylic acid (ASA, 550 microM) which blocks PG production. Forskolin (10 microM) seldom induced discharges in polymodal receptors. An unexpected outcome of this study was that forskolin induced no facilitation of the bradykinin (0.1 microM) response, both in the absence and presence of ASA. A slight yet significant suppression of the bradykinin response was instead observed in the absence of ASA. These results suggest that intracellular cAMP may be related with PG E2-induced sensitization of the bradykinin response through its decrease.