[A multivariate model for predicting induction response and prognosis in core binding factor acute myeloid leukemia].

Objective: To evaluate the efficacy and prognostic factors in core binding factor (CBF) acute myeloid leukemia (AML) under current therapy modalities, therefore optimizing the treatment strategies. Methods: Standard cytological and immune methods including next generation sequencing (NGS) were used for risk stratification. Complete remission (CR) rate, disease-free survival (DFS) and overall survival (OS) were assessed by multivariate Logistic and Cox regression models in a total of 206 adults (aged 16-65 years) with CBF-AML, including 152 AML patients with t(8;21) and 54 with inv(16). Results: The CR rate of inv(16) patients after first course was 54/54(100%), significantly higher than that of t(8;21) patients [127/147(86.4%), P=0.005]. The fusion transcript level and KIT mutation were independent factors related to CR rate in t(8;21) patients (P=0.044 and 0.027; respectively). DFS and OS in inv(16) patients tended to be more superior than that in t(8;21) patients (P=0.066 for DFS; P=0.306 for OS; respectively). Multivariate Cox identified negative expression of CD(19) and female gender the independent predictors of inferior DFS in t(8;21) patients (P=0.000 for CD(19); P=0.006 for sex; respectively). Analysis of combining CD(19) with gender indicated that females/CD(1)(9-)subpopulation had significantly poor DFS than did males/CD(19)(+) ones (Bonferroni-P<0.000 01). The number of mutations in each patient, FLT3-ITD and additional karyotype abnormalities did not affect CR rate and DFS (all P>0.05). Conclusions: Patients with inv(16) have better induction response than those with t(8;21). High level of fusion transcripts and positive KIT mutation are associated with low CR rate in t(8;21) patients. Negative CD(19) expression and female gender are independent predictors of inferior DFS in t(8;21) patients.

The expression of osteopontin and its association with Clara cell 10 kDa protein in allergic rhinitis.

BACKGROUND: Osteopontin (OPN) is a multifunctional protein that has recently been linked to allergic diseases. Clara cell 10 kDa protein (CC10) is another protein linked to allergy, and has been suggested to have an inhibitory role in inflammatory airway diseases. At this time, it is not known whether OPN is involved in allergic rhinitis (AR) or if there is any association between CC10 and OPN in AR. OBJECTIVE: To study the expression of OPN and its potential association with CC10 in AR. METHODS: The expression of CC10 and OPN in nasal mucosa of AR patients was investigated. AR animal models were established by using wild-type and CC10-knockout mice. In some experiments, human recombinant CC10 protein was given to AR mice during either sensitization or challenge. The phenotypic changes were examined by histology and real-time RT-PCR. The direct effect of CC10 on the OPN expression in spleen mononuclear cells and on the OPN-induced inflammatory cytokine expression in BEAS-2B cells was measured through in vitro cell culture. RESULTS: OPN expression was up-regulated, with a concomitant down-regulation of CC10, in AR patients, showing a significant negative correlation between their expression. Compared with control mice sensitized with PBS, the OPN expression was significantly increased in AR mice; such an increase was more prominent in CC10-knockout mice, compared with wild-type. Administration of CC10 during both sensitization and challenge could markedly ameliorate Th2-skewed inflammation and OPN expression in nasal mucosa. CC10 administration at the sensitization phase could also reduce spleen OPN expression. The in vitro study showed that CC10 directly down-regulated the OPN expression in spleen mononuclear cells stimulated with OVA and suppressed the OPN-induced expression of Th2 cytokines and pro-inflammatory cytokines in BEAS-2B cells. CONCLUSION: In the context of allergic airway responses, CC10 can inhibit OPN expression and suppress the Th2-promoting function of OPN, resulting in CC10's inhibitory biological effects.

Spinal N-methyl-D-aspartate receptors and nociception-evoked release of primary afferent substance P.

Dorsal horn N-methyl-D-aspartate (NMDA) receptors contribute significantly to spinal nociceptive processing through an effect postsynaptic to non-primary glutamatergic axons, and perhaps presynaptic to the primary afferent terminals. The present study sought to examine the regulatory effects of NMDA receptors on primary afferent release of substance P (SP), as measured by neurokinin 1 receptor (NK1r) internalization in the spinal dorsal horn of rats. The effects of intrathecal NMDA alone or in combination with D-serine (a glycine site agonist) were initially examined on basal levels of NK1r internalization. NMDA alone or when co-administered with D-serine failed to induce NK1r internalization, whereas activation of spinal TRPV1 receptors by capsaicin resulted in a notable NK1r internalization. To determine whether NMDA receptor activation could potentiate NK1r internalization or pain behavior induced by a peripheral noxious stimulus, intrathecal NMDA was given prior to an intraplantar injection of formalin. NMDA did not alter the formalin-induced NK1r internalization nor did it enhance the formalin paw flinching behavior. To further characterize the effects of presynaptic NMDA receptors, the NMDA antagonists DL-2-amino-5-phosphonopentanoic acid (AP-5) and MK-801 were intrathecally administered to assess their regulatory effects on formalin-induced NK1r internalization and pain behavior. AP-5 had no effect on formalin-induced NK1r internalization, whereas MK-801 produced only a modest reduction. Both antagonists, however, reduced the formalin paw flinching behavior. In subsequent in vitro experiments, perfusion of NMDA in spinal cord slice preparations did not evoke basal release of SP or calcitonin gene-related peptide (CGRP). Likewise, perfusion of NMDA did not enhance capsaicin-evoked release of the two peptides. These results suggest that presynaptic NMDA receptors in the spinal cord play little if any role on the primary afferent release of SP.

Inhibition of spinal cytosolic phospholipase A(2) expression by an antisense oligonucleotide attenuates tissue injury-induced hyperalgesia.

Activation of the spinal phospholipase A(2) (PLA(2)) -cyclooxygenase (COX) -prostaglandin signaling pathway is widely implicated in nociceptive processing. Although the role of spinal COX isoforms in pain signal transmission has been extensively characterized, our knowledge of PLA(2) enzymes in this cascade is limited. Among all PLA(2) groups, cytosolic calcium-dependent PLA(2) group IVA (cPLA(2)IVA) appears to be the predominant PLA(2) enzyme in the spinal cord. In the present study we sought to (i) characterize anatomical and cellular distribution and localization of cPLA(2)IVA in dorsal horn of rat spinal cord, (ii) verify efficacy and selectivity of intrathecal (IT) delivery of an antisense oligonucleotide (AS) targeting rat cPLA(2)IVA mRNA on spinal expression of this enzyme, and (iii) examine the effect of down-regulation of spinal cPLA(2)IVA on peripheral tissue injury-induced pain behavior. Here we demonstrate that cPLA(2)IVA is constitutively expressed in rat spinal cord, predominantly in dorsal horn neurons and oligodendrocytes but not in astrocytes or microglia. Intrathecal injection of AS significantly down-regulated both protein and gene expression of cPLA(2)IVA in rat spinal cord, while control missense oligonucleotide (MS) had no effect. Immunocytochemistry confirmed that the reduction occurred in neurons and oligodendrocytes. cPLA(2)IVA AS did not alter expression of several other PLA(2) isoforms, such as secretory PLA(2) (groups IIA and V) and calcium-independent PLA(2) (group VI), indicating that the AS was specific for cPLA(2)IVA. This selective knockdown of spinal cPLA(2)IVA did not change acute nociception (i.e. paw withdrawal thresholds to acute thermal stimuli and intradermal formalin-induced first phase flinching), however, it significantly attenuated formalin-induced hyperalgesia (i.e. second phase flinching behavior), which reflects spinal sensitization. Thus the present findings suggest that cPLA(2)IVA may specifically participate in spinal nociceptive processing.

Spinal distribution and metabolism of 2'-O-(2-methoxyethyl)-modified oligonucleotides after intrathecal administration in rats.

Intrathecal (IT) delivery of antisense oligodeoxynucleotides (ASO) has been used to study the function of specific gene products in spinal nociception. However, a lack of systematic studies on the spinal distribution and kinetics of IT ASO is a major hurdle to the utilization of this technique. In the present study, we injected rats IT with 2'-O-(2-methoxyethyl) modified phosphorothioate ASO (2'-O-MOE ASO) and examined anatomical and cellular location of the ASO in the spinal cord and dorsal root ganglia (DRG) by immunocytochemistry. At 0.5 h after a single IT injection, immunostaining for ISIS 13920 (a 2'-O-MOE ASO targeting h-ras) localized superficially in the lumbar spinal cord, while at 24 h the immunostaining was distributed throughout the spinal cord and was predominantly intracellular. Double staining with cell type specific antibodies indicated that the ASO was taken up by both glia and neurons. ASO immunoreactivity was also observed in DRG after IT ISIS 13920. Capillary gel electrophoresis analysis showed that ISIS 22703, a 2'-O-MOE ASO targeting the alpha isozyme of protein kinase C (PKC), remained intact in spinal cord tissue and cerebrospinal fluid up to 24 h after the injection and no metabolites were detected. In contrast, after IT ISIS 11300, an unmodified phosphorothioate ASO with the same sequence as ISIS 22703, no full-length compound was detectable at 24 h, and metabolites were seen as early as 0.5 h. IT treatment with ISIS 22703 at doses that effectively down-regulated PKCalpha mRNA in spinal cord did not affect the mRNA expression in DRG. In summary, 2'-O-MOE ASO displayed high stability in spinal tissue after IT delivery, efficiently distributed to spinal cord, and internalized into both neuronal and non-neuronal cells. ASO are able to reach DRG after IT delivery; however, higher doses may be required to reduce target gene in DRG as compared with spinal cord.

Spinal phospholipase A2 in inflammatory hyperalgesia: role of the small, secretory phospholipase A2.

Current work emphasizes that peripheral tissue injury and inflammation results in a heightened sensitivity to subsequent noxious input (hyperalgesia) that is mediated in large part by the spinal synthesis and release of eicosanoids, in particular prostaglandins. Secreted phospholipase A(2)s (sPLA(2)s) form a class of structurally related enzymes that release arachidonic acid from cell membranes that is further processed to produce eicosanoids. We hypothesized that spinal sPLA(2)s may contribute to inflammation-induced hyperalgesia. Spinal cord tissue and cerebrospinal fluid were collected from rats for assessment of sPLA(2) protein expression and sPLA(2) activity. A basal sPLA(2) protein expression and activity was detected in spinal cord homogenate (87+/-17 pmol/min/mg), though no activity could be detected in cisternal cerebrospinal fluid, of naive rats. The sPLA(2) activity did not change in spinal cord tissue or cerebrospinal fluid assessed over 8 h after injection of carrageenan into the hind paw. However, the sPLA(2) activity observed in spinal cord homogenates was suppressed by addition of LY311727, a selective sPLA(2) inhibitor. To determine the role of this spinal sPLA(2) in hyperalgesia, we assessed the effects of lumbar intrathecal (IT) administration of LY311727 in rats with chronic IT catheters in three experimental models of hyperalgesia. IT LY311727 (3-30 microg) dose-dependently prevented intraplantar carrageenan-induced thermal hyperalgesia and formalin-induced flinching, at doses that had no effect on motor function. IT LY311727 also suppressed thermal hyperalgesia induced by IT injection of substance P (30 nmol). Using in vivo spinal microdialysis, we found that IT injection of LY311727 attenuated prostaglandin E(2) release into spinal dialysate otherwise evoked by the IT injection of substance P. Taken together, this work points to a role for constitutive sPLA(2)s in spinal nociceptive processing.

Mechanisms of antinociception of spinal galanin: how does galanin inhibit spinal sensitization?

Galanin by a spinal action has been shown to have an antihyperalgesic action. Thus, in rats with lumbar intrathecal (IT) catheters, the thermal hyperalgesia evoked by carrageenan paw injection was blocked by IT delivery of galanin(1-29) (Gal(1-29)) and galanin(2-11) (Gal(2-11)) with the rank order of activity being Gal(1-29)>Gal(2-11). We sought to determine whether this spinal action reflects an effect upon afferent transmitter release, e.g., substance P (SP), and/or on secondary neurons, e.g., signaling postsynaptic to neurokinin 1 (NK1) receptor activation. To address the question on afferent release, we investigated the effect of IT administration of galanin on tissue injury-induced spinal NK1 internalization (an indicator of SP release). Noxious stimulation (paw compression) produced an increase in NK1 internalization in dorsal horn lamina I. IT pretreatment of rats with Gal(1-29) and Gal(2-11) significantly attenuated the evoked NK1 internalization, with the rank order of activity being Gal(1-29)>Gal(2-11)>saline. To address the question of postsynaptic action, we examined the effects of IT galanin upon IT SP-induced thermal hyperalgesia and spinal PGE2 release. Application of SP (30 nmol) directly to spinal cord led to a decrease in thermal thresholds and a profound increase in PGE(2) concentration in spinal dialysates. Both phenomena were reversed by Gal(1-29) and Gal(2-11) (10nmol, IT). These findings suggest that the antihyperalgesic effect of spinal galanin is due to its action on sites both presynaptic (inhibition of SP release) and postsynaptic (blockade of SP-evoked hyperalgesia and PGE2 production) to the primary afferents.

Increased hyperalgesia after tissue injury and faster recovery of allodynia after nerve injury in the GalR1 knockout mice.

Evidence suggests that galanin and its receptors including GalR1 are involved in the modulation of nociception. To understand the contributions of this galanin receptor subtype to the analgesic effect of galanin, we systematically examined the nociception phenotype of the GalR1 knockout (KO) mice. (1) Baseline thresholds: Thermal escape latencies and tactile thresholds of the hind paws were not different between the GalR1 KO and wild type (WT) mice. (2) Thermal injury evoked hyperalgesia: Thermal injury (52 degrees C, 45 s) to one hind paw resulted in a reduction in the thermal escape latency as compared to the uninjured paw. The right/left difference score was significantly greater in the KO (5.9 +/- 0.8 s) than for the WT (2.8 +/- 0.7 s) indicating a greater hyperalgesia. (3) Formalin-induced flinching: Formalin paw injection (2.5%/20 microl) produced a two-phase flinching in both GalR1 KO and WT groups, that was detected by an automated flinching sensor device. Phase II flinching of KO (1510 +/- 90) was slightly greater than that observed for WT (1290 +/- 126), but the difference is not statistically significant. (4) Nerve injury evoked allodynia: Tactile thresholds were assessed prior to and at intervals up to 21 days after left L5 spinal nerve ligation and transection. In both GalR1 KO and WT mice, nerve injury caused thresholds to fall to 0.2-0.3g though 11 days. On days 14-21, GalR1 KO animals showed a significant recovery as compared to WT. In summary, GalR1 KO mice showed no difference from WT with respect to acute nociception, but showed a modest tendency towards increased hyperalgesia after tissue injury and inflammation. These results are consistent with a regulatory effect of galanin at GalR1 receptors on nociceptive processing.

Spinal release of tumour necrosis factor activates c-Jun N-terminal kinase and mediates inflammation-induced hypersensitivity.

BACKGROUND: Mounting evidence points to individual contributions of tumour necrosis factor-alpha (TNF) and the c-Jun N-terminal kinase (JNK) pathway to the induction and maintenance of various pain states. Here we explore the role of spinal TNF and JNK in carrageenan-induced hypersensitivity. As links between TNF and JNK have been demonstrated in vitro, we investigated if TNF regulates spinal JNK activity in vivo. METHODS: TNF levels in lumbar cerebrospinal fluid (CSF) were measured by enzyme-linked immunosorbent assay, spinal TNF gene expression by real-time polymerase chain reaction and TNF protein expression, JNK and c-Jun phosphorylation by western blotting. The role of spinal TNF and JNK in inflammation-induced mechanical and thermal hypersensitivity was assessed by injecting the TNF inhibitor etanercept and the JNK inhibitors SP600125 and JIP-1 intrathecally (i.t.). TNF-mediated regulation of JNK activity was examined by assessing the effect of i.t. etanercept on inflammation-induced spinal JNK activity. RESULTS: TNF levels were increased in CSF and spinal cord following carrageenan-induced inflammation. While JNK phosphorylation followed the same temporal pattern as TNF, c-jun was only activated at later time points. Intrathecal injection of TNF and JNK inhibitors attenuated carrageenan-induced mechanical and thermal hypersensitivity. TNF stimulation induced JNK phosphorylation in cultured spinal astrocytes and blocking the spinal actions of TNF in vivo by i.t. injection of etanercept reduced inflammation-induced spinal JNK activity. CONCLUSIONS: Here we show that spinal JNK activity is dependent on TNF and that both TNF and the JNK signalling pathways modulate pain-like behaviour induced by peripheral inflammation.

Diabetes and mitochondrial encephalomyopathy with lactic acidosis and stroke-like episodes (MELAS): radiolabeled polymerase chain reaction is necessary for accurate detection of low percentages of mutation.

A 6-yr-old boy presented with muscle weakness, lactic acidemia, and insulin-dependent diabetes mellitus (IDDM). Using PCR and restriction enzyme analysis, he was found to have the classical A3248G mitochondrial DNA (mtDNA) mutation frequently associated with mitochondrial encephalomyopathy with lactic acidosis and stroke-like episodes (MELAS). The mutation was confirmed by sequencing muscle mtDNA. The mutation in mtDNA from muscle, lymphoblasts, and blood was clearly demonstrable by standard methods using ethidium bromide staining. His mother also had IDDM, but no A3243G mutation could be detected in her blood or transformed lymphoblasts using the same PCR technique. When PCR was carried out in the presence of [32P]deoxycytidine triphosphate, subsequent autoradiography detected the presence of the mutation at low levels in mtDNA from the mother's lymphoblasts and blood. Study of the mother's muscle showed a mitochondrial myopathy, despite the fact that she was asymptomatic. We emphasize that the increased sensitivity of radiolabeled PCR may be necessary to detect small percentages of heteroplasmic A3243G mtDNA mutation in blood from diabetic subjects. Otherwise the incidence of mtDNA mutations in both IDDM and non-insulin dependent diabetes may be underestimated.

Antinociception induced by civamide, an orally active capsaicin analogue.

The antinociceptive effects of a novel capsaicin analogue, civamide (cis-8-methyl-N-vanillyl-6-nonenamide), given orally to adult rats were examined. In the formalin test, civamide significantly suppressed the flinch response, particularly phase 2, in a dose-dependent fashion (20-200 mg/kg). This inhibitory effect started 1 h after application, and was maintained for 4-7 days. A competitive capsaicin antagonist, capsazepine (15 mg/kg, s.c.), reversed the antinociceptive action of civamide (200 mg/kg) on the formalin test when it was given either 5 min or 55 min after oral civamide delivery. In contrast, capsazepine delivered 2 days after civamide had no effect upon the depressed formalin response. Civamide produced a significant increase in the response latency on the thermal paw withdrawal test, which persisted for 2-3 days. Civamide produced a modest, but statistically significant, reversal of low tactile thresholds otherwise observed in the Chung neuropathic rats. Morbidity (approximately 10%) was observed which was secondary to bronchial constriction occurring with gastric reflux. Civamide at the doses given did not produce motor dysfunction. Neither calcitonin gene-related peptide (CGRP) nor substance P (SP) concentrations in dorsal or ventral spinal cord were altered by civamide (200 mg/kg) up to 5 days, whereas CGRP, but not SP, in dorsal root ganglia (DRG) and sciatic nerves was modestly reduced at 1 day after the delivery. These data suggest that an orally bioavailable capsaicin analogue, civamide, possessed analgesic activity with respect to several noxious stimuli, including inflammation-induced hyperalgesia, noxious thermal stimulation and nerve injury-induced tactile allodynia. The rapid onset and lack of change in the peptide levels in dorsal spinal cord suggests that the analgesic action of civamide is primarily a result of desensitization at the afferent terminals. The antinociception of civamide is probably mediated by at least two mechanisms: (i) an acute receptor occupancy dependent effect; and (ii) a persistent and receptor independent effect which is initiated by the acute exposure to the drug.

Multiple mechanisms for the effects of capsaicin, bradykinin and nicotine on CGRP release from tracheal afferent nerves: role of prostaglandins, sympathetic nerves and mast cells.

Application of capsaicin (CAP), bradykinin (BK) or nicotine (NIC) to intraluminally perfused rat tracheas induced an increase in calcitonin gene-related peptide (CGRP) levels in the perfusates. Depletion of sensory afferent CGRP with systemic CAP pretreatment resulted in a significant reduction of CGRP release evoked by CAP, BK or NIC. Chemical destruction of sympathetic nerve fibres by systemic pretreatment with 6-hydroxydopamine reduced CGRP release evoked by NIC, but did not alter the release produced by CAP or BK. Elimination of the tracheal mast cell population by pretreatment with compound 48/80 did not alter the effects of CAP, BK or NIC. CGRP release evoked by BK and NIC, but not CAP, was diminished by indomethacin, suggesting that cyclooxygenase products mediate the actions of BK and NIC. Prostaglandins, PGE1, PGE2, PGF2 alpha and PGI2, displayed stimulatory effects on CGRP release in the trachea. There are evidently multiple mechanisms mediating CGRP release from sensory terminals in rat trachea. It appears that CAP exerts a direct action on sensory nerves, while the effects of BK and NIC are mediated by PG synthesis. Sympathetic activation may be involved in NIC, but not BK, induced PG-mediated CGRP release.

Intrathecal substance P-induced thermal hyperalgesia and spinal release of prostaglandin E2 and amino acids.

Substance P is an important neuromediator in spinal synaptic transmission, particularly in processing nociceptive afferent information. The effects of substance P are mediated by activation of the neurokinin 1 receptor. Evidence has suggested that excitatory amino acids such as glutamate, and prostaglandins including prostaglandin E2 are involved in the enhanced spinal excitability and hyperalgesia produced by spinal substance P. In the present study, we have demonstrated that intrathecal injection of substance P (20 nmol) in rats chronically implanted with intrathecal dialysis catheters induced a decrease in thermal paw withdrawal latency (before: 10.4+/-0.3 s; after 7.6+/-0.6 s), which was accompanied by an increase in prostaglandin E2 (362+/-37% of baseline), glutamate (267+/-84%) and taurine (279+/-57%), but not glycine, glutamine, serine or asparagine. Intrathecal injection of artificial cerebrospinal fluid had no effect upon the behavior or release. Substance P-induced thermal hyperalgesia and prostaglandin E2 release were significantly attenuated by a selective neurokinin 1 receptor antagonist RP67580, but not by an enantiomer RP68651. However, substance P-induced release of glutamate and taurine was not reduced by treatment with RP67580. SR140333, another neurokinin 1 receptor antagonist, displayed the same effects as RP67580 (i.e. block of thermal hyperalgesia and prostaglandin E2 release, but not release of amino acids). These results provide direct evidence suggesting that the spinal substance P-induced thermal hyperalgesia is mediated by an increase in spinal prostaglandin E2 via activation of the neurokinin 1 receptor. These findings define an important linkage between small afferents, sensory neurotransmitter release and spinal prostanoids in the cascade of spinally-mediated hyperalgesia. The evoked release of glutamate is apparently not a result of activation of neurokinin 1 receptors. Accordingly, consistent with other pharmacological data, acute spinal glutamate release does not contribute to the hyperalgesia induced by activation of spinal neurokinin 1 receptors.

Capsaicin induced release of multiple tachykinins (substance P, neurokinin A and eledoisin-like material) from guinea-pig spinal cord and ureter.

The release of tachykinins from isolated slice preparations of the guinea-pig spinal cord and ureter was studied in vitro. Capsaicin (10 microM) caused release of substance P, neurokinin A and an eledoisin-like component from both the spinal cord and ureter. The release of tachykinins induced by capsaicin or potassium (60 mM) was calcium dependent. No detectable release of neurokinin B or neuropeptide K, an N-terminally extended form of neurokinin A, was induced by capsaicin. No detectable release of tachykinins could be demonstrated after exposure to agents which are known to activate C-fibre afferents, such as histamine, bradykinin, serotonin, prostaglandins E1, E2 or acetylcholine. Protein extravasation in the ureter, as determined by the Evans Blue extravasation technique was used as a functional correlate to the tachykinin release. Protein extravasation was induced in vivo by local intraluminal injections of capsaicin at several hundred-fold lower concentrations than those required to induce a detectable release of tachykinins in vitro. The difference may, however, partly depend on the experimental conditions and the detection limit of the tachykinin assay used. The protein extravasation response to capsaicin was absent after systemic capsaicin pretreatment, which causes a marked depletion of tachykinins in the ureter. In conclusion, capsaicin evokes release of several tachykinins from both central and peripheral endings of primary afferent neurons. The peptides released from sensory nerves in the periphery may induce effects such as protein extravasation and smooth muscle contraction.

Co-localization of tachykinins and calcitonin gene-related peptide in capsaicin-sensitive afferents in relation to motility effects on the human ureter in vitro.

Tachykinin- and calcitonin gene-related peptide (CGRP) immunoreactivities were localized by immunohistochemistry in the same nerves of the kidney, renal pelvis and ureter as well as in spinal ganglion cells of both the guinea-pig and man. The tachykinin and CGRP-immunoreactive nerves in the ureter were present within the smooth muscle layers, around blood vessels, close to and within the lining epithelium. The levels of neurokinin A-, substance P- and CGRP-like immunoreactivity per tissue weight, as determined by radioimmunoassay, were about 30-100-fold higher in the guinea-pig than in the human ureter, which was in good agreement with the relative density of immunoreactive nerve fibres, as seen by immunohistochemistry. Capsaicin treatment caused an almost total disappearance of both neurokinin A-, substance P- and CGRP-immunoreactive nerve fibres in the guinea-pig ureter and a 90% depletion of neurokinin A, substance P- and CGRP-like immunoreactivity, further supporting a sensory origin of these nerves. Reversed-phase high performance liquid chromatography of water extracts of the human ureter revealed the presence of neurokinin A- and eledoisin-like material using antiserum K12, which does not cross-react with substance P. Most of the CGRP-like immunoreactivity in human ureter extracts co-eluted with synthetic human CGRP. Capsaicin both caused inhibition of spontaneous motility of the human ureter in vitro and initiated contractions in some preparations. Neurokinin A and neuropeptide K potently initiated phasic contractions of the ureter, while substance P had only minor contractile effects. CGRP inhibited both spontaneous and neurokinin A-induced ureteric contractions. In conclusion, peptides with potent opposite motility effects are present in the same, presumably sensory nerves of the ureter in both the guinea-pig and man. It will be of importance to determine whether local release of neuropeptides can account for ureteric motility changes accompanying sensory nerve activation upon ureteral obstruction, by e.g. renal calculi.

Inhibition of spinal protein kinase Calpha expression by an antisense oligonucleotide attenuates morphine infusion-induced tolerance.

Protein kinase C isoforms including the alpha isozyme have been implicated in morphine tolerance. In the present study, we examined the effect of intrathecal delivery of an antisense oligonucleotide targeting rat protein kinase Calpha mRNA on the expression of spinal protein kinase Calpha isozyme and spinal morphine tolerance. Continuous intrathecal infusion of rats with morphine produced an increase in paw withdrawal threshold to thermal stimulation on day 1, which disappeared by day 5. On day 6, a bolus intrathecal injection of morphine (a probe dose) produced significantly less analgesia in morphine-infused rats than in saline-infused rats, suggesting tolerance. Intrathecal treatment with the protein kinase Calpha antisense concurrent with spinal morphine infusion not only maintained the analgesic effect of morphine during the 5-day infusion, it also significantly increased responsiveness to the probe morphine dose on day 6. In comparison, the missense used in the same treatment paradigm had no effect. The inhibitory effect of protein kinase Calpha antisense on spinal morphine tolerance was dose-dependent, and reversible. Intrathecal treatment with the antisense, but not the missense, in rats decreased expression of spinal protein kinase Calpha mRNA and protein, as revealed by real-time quantitative reverse transcription-polymerase chain reaction and western blots. Expression of the gamma isozyme was not affected by the oligonucleotides. The antisense also attenuated protein kinase C-mediated phosphorylation in spinal cord. These results demonstrate that selective reduction in the expression of the spinal protein kinase Calpha isozyme followed by a decrease of local protein kinase C-mediated phosphorylation will reverse spinal morphine infusion-induced tolerance. This finding is consistent with the view that tolerance produced by morphine infusion is dependent upon an increase in phosphorylation by protein kinase C, and also it emphasizes that the protein kinase Calpha isozyme and its activation in spinal cord may specifically participate in the phenomenon of opiate tolerance.

Neonatal capsaicin treatment abolishes formalin-induced spinal PGE2 release.

We investigated the effect of neonatal capsaicin treatment on formalin-evoked pain behavior and spinal levels of nociceptive neuromodulators using in vivo intrathecal microdialysis in conscious adult rats and age-matched controls. Capsaicin-treated rats displayed thermal hypoalgesia and a significant decrease in tissue content of calcitonin gene-related peptide. Paw swelling, flinching and release of spinal prostaglandin E2 induced by injection of formalin into the hindpaw were also reduced in capsaicin-treated rats compared with controls, whereas glutamate, aspartate and taurine release was unaffected. These data suggest that formalin-induced inflammation, pain behavior and spinal prostaglandin E2 release are mediated by mechanisms sensitive to neonatal capsaicin while the formalin-evoked release of amino acids in the spinal cord is not.

Characterization of muscarinic receptors involved in tracheal CGRP release.

Application of acetylcholine (ACh) to isolated rat trachea induces an increase in calcitonin gene-related peptide (CGRP) outflow in the perfusates. The elevation of CGRP release by ACh was absent in capsaicin-desensitized preparations, suggesting that the release of peptide is derived from capsaicin-sensitive afferent nerves. ACh-induced release was not altered by hexamethonium, but was significantly attenuated by atropine, indicating involvement of the muscarinic receptor. Effects of three selective muscarinic subtype antagonists, pirenzepine (M1), methoctramine (M2) and 4-DAMP (M3) on ACh-evoked release were examined. The ordering of antagonist potency was: 4-DAMP (ED50 = 14 nM) > pirenzepine (3.8 microM) > methoctramine (> 10 microM). The results suggest that the muscarinic receptor mediating tracheal CGRP release resembles the M3 receptor subtype.

Nicotine and acetylcholine induce release of calcitonin gene-related peptide from rat trachea.

In the present study, we observed that nicotine, the nicotinic analogue cytisine, and acetylcholine (ACh) evoked a concentration-dependent (5 x 10(-6)-5 x 10(-5) M) release of calcitonin gene-related peptide (CGRP) from the rat trachea. After a prolonged exposure to capsaicin, nicotine-induced CGRP release was absent, suggesting that the release of CGRP by nicotine is derived from capsaicin-sensitive afferent terminals. Nicotine- and cytisine-induced release displayed a significant degree of tachyphylaxis after sequential exposures. The release of CGRP evoked by capsaicin was also reduced after nicotine and cytisine desensitization. This indicates that similar mechanisms may mediate the tachyphylactic effect of capsaicin and nicotine. Hexamethonium and mecamylamine blocked the effect of nicotine but not that of ACh, whereas atropine significantly attenuated the release of CGRP outflow induced by ACh. Physostigmine and neostigmine did not alter resting release of CGRP from rat trachea, although exogenous (10(-5) M) ACh-induced CGRP release was enhanced in the presence of neostigmine, suggesting minimal tonic cholinergic activity in this model. We conclude that activation of nicotinic and muscarinic receptors in the rat trachea can induce local release of CGRP. These observations indicate that cholinergically induced airway responses may be mediated in part by activation of the peripheral terminals of primary afferent sensory neurons and subsequent release of local neuropeptides.

Release of calcitonin gene-related peptide and tachykinins from the rat trachea.

The release of calcitonin gene-related peptide (CGRP), neurokinin A (NKA) and substance P (SP) from intralumenally perfused rat trachea was examined in vitro. In accord with the relative tissue levels of the respective peptides, capsaicin (10(-8) to 10(-5) M) and K+ (120 mM) added to the perfusate resulted in a concentration-dependent increase in the levels of CGRP and NKA, and to a minor extent SP, in the perfusates. Sequential exposure of the trachea to capsaicin revealed a concentration-dependent tachyphylaxis of CGRP release. Thus, 40 min after the application with capsaicin 10(-5) M, a second exposure to capsaicin at the same concentration, or K+ 120 mM, did not evoke CGRP release. In contrast, prior stimulation with K+ 120 mM significantly enhanced the CGRP release induced by a second stimulation with K+ 120 mM or capsaicin 10(-5) M. Capsaicin- and K(+)-induced peptide release was diminished or abolished in the absence of Ca2+. HPLC analysis of CGRP in release materials revealed that there was a single peak which eluted in the same fraction as synthetic rat CGRP. These data demonstrate that CGRP, NKA and SP exist in releasable, capsaicin-sensitive pools in terminals which lie within the proximal lumen of the trachea.