Analysis of responses to hAmylin, hCGRP, and hADM in isolated resistance arteries from the mesenteric vascular bed of the rat

Responses to human calcitonin gene-related peptide (hCGRP) and human adrenomedullin (hADM) hAmylin were investigated in isolated mesenteric resistance arteries from the rat. The results of the present investigation show that hCGRP, hAmylin, and hADM induce dose-related vasodilator responses in isolated resistance arteries from the rat mesenteric vascular bed. Vasodilator responses to hCGRP and hAmylin were not altered after denuding the vascular endothelium, after administration of the nitric oxide synthase inhibitor L-NA, or after administration of the soluble guanylate cyclase inhibitor ODQ, suggesting that vasodilator responses to hCGRP and hAmylin are not mediated by the release of nitric oxide from the vascular endothelium and the subsequent increase in cGMP. Vasodilator responses to hCGRP, hAmylin, and hADM were not altered by the vascular selective K+(ATP) channel antagonist U-37883A. The role of the CGRP1 receptor was investigated and responses to hCGRP and hAmylin, but not hADM, were significantly reduced following administration of hCGRP-(8-37). Moreover, vasodilator responses to hCGRP and hAmylin, but not hADM, were significantly reduced by hAmylin-(8-37), suggesting that an hAmylin-(8-37)-sensitive receptor mediates responses to hCGRP and hAmylin in the rat mesenteric artery. These data suggest that hCGRP and hAmylin have direct vasodilator effects in the isolated mesenteric resistance artery that are mediated by hAmylin-(8-37)- and hCGRP-(8-37)-sensitive receptors.     

Adrenomedullin 2 (AM2)/intermedin is a more potent activator of hypothalamic oxytocin-secreting neurons than AM possibly through an unidentified receptor in rats

Central administration of either adrenomedullin 2 (AM2) or adrenomedullin (AM) activates hypothalamic oxytocin (OXT)-secreting neurons in rats. We compared AM2 with AM, given intracerebroventricularly (icv), across multiple measures: (1) plasma OXT levels in conscious rats; (2) blood pressure, heart rate and circulating catecholamine levels in urethane-anesthetized rats; and (3) the expression of the c-fos gene in the supraoptic (SON) and the paraventricular nuclei (PVN). We also tested the effects of the AM receptor antagonist, AM(22-52) and calcitonin gene-related peptide (CGRP) antagonist, CGRP(8-37) on these measures. Plasma OXT levels at 10 min after icv injection of AM (1 nmol/rat) were increased (compared with vehicle), but OXT levels after AM2 (1 nmol/rat) were nearly double the levels seen after AM injection. OXT levels remained elevated at 30 min. Pretreatment with AM(22-52) (27 nmol/rat) and CGRP(8-37) (3 nmol/rat), nearly abolished the increase in plasma OXT level after AM injection, but partially blocked OXT level changes due to AM2. Increases in blood pressure, heart rate and circulating catecholamines were all greater in response to central AM2 than to AM at the same dose. In situ hybridization histochemistry showed that both AM2 and AM induced expression of the c-fos gene in the SON and the PVN, but AM(22-52)+CGRP(8-37) could only nearly abolish the effects of centrally administered AM. These results suggest that the more potent central effects of AM2 and only partial blockade by AM/CGRP receptor antagonists may result from its action on an additional, as yet unidentified, specific receptor in the central nervous system.     

Specific N-terminal CGRP fragments mitigate chronic hypoxic pulmonary hypertension in rats

Chronic hypoxic pulmonary hypertension (HPH) is characterized by elevated pulmonary arterial pressure (P(PA)), right ventricular hypertrophy (RVH), pulmonary vascular remodeling, pulmonary edema and polycythemia. Currently, there is no safe and effective treatment for HPH. Calcitonin gene-related peptide (CGRP) is the most potent peptide vasodilator discovered thus far. We previously demonstrated that exogenous CGRP reversed HPH in rats. However, the CGRP1 receptor antagonist CGRP(8-37) and smaller inhibitory C-terminal CGRP fragments that can be formed by enzymatic cleavage in vivo may compromise the beneficial effects of endogenous or exogenous CGRP. We here examine the agonistic efficacy of N-terminal rat alpha-CGRP peptides containing the disulfide bridge (Cys(2)-Cys(7)) with amidated C-terminal in prevention of HPH. Chronic infusion of CGRP(1-8), CGRP(1-13), or CGRP(1-14) at 7 nmol/h/rat via the right jugular vein during 14 days of hypobaric hypoxia (10% inspired O(2)) significantly decreased the P(PA), RVH and pulmonary arterial medial thickness in comparison with controls, suggesting that these CGRP sequences can mitigate chronic HPH in rats. Systemic pressure was unchanged by infused peptides indicating no carry-over effect. In conclusion, N-terminal CGRP fragments (CGRP(1-8), CGRP(1-13) and CGRP(1-14)) may have a protective role in hypoxic pulmonary hypertension.     

L-Name modulates responses to adrenomedullin in the hindquarters vascular bed of the rat

Responses to synthetic human adrenomedullin (ADM), a novel hypotensive peptide recently discovered in human pheochromocytoma cells, and calcitonin gene-related peptide (CGRP), a structurally related peptide, were investigated in the hintquarters vascular bed of the rat. Under conditions of controlled hintquarters blood flow, intraarterial injections of ADM (0.01–0.3 nmol) and of CGRP (0.03–0.3 nmol) caused dose-related decreases in hindquarters perfusion pressure and decreases in systemic arterial pressure. Following administration of the nitric oxide synthase inhibitor, N^ω-nitro-L-arginine methyl ester (L-NAME), hindquarters vasodilator and systemic depressor responses to ADM were significantly decreased, whereas L-NAME did not significantly decrease the vasodilator response to CGRP in either the hindquarters or systemic vascular beds. Following administration of the cyclooxygenase inhibitor, meclofenamate, vasodilator responses to ADM and to CGRP were not significantly decreased. When the relative vasodilator activity of the two peptides was compared on a nmol basis, responses to ADM were similar to responses with CGRP in the hindquarters vascular bed, whereas ADM was 30–100 fold less potent than CGRP in decreasing systemic arterial pressure. The present data demonstrate that ADM has significant vasodilator activity in the hindquarters vascular bed of the rat, that hindquarters vasodilator and systemic vasodepressor responses to ADM, but not to CGRP, are dependent upon the release of nitric oxide from the endothelium.     

Adrenomedullin (ADM), acting through ADM(22-52)-sensitive receptors, is involved in the endotoxin-induced hypotension in rats

The possible involvement of adrenomedullin (ADM) in the endotoxin-induced hypotension has been investigated in the rat. Lipopolysaccharide (LPS, 500 micrograms/kg intraperitoneum) caused a severe decrease in the blood pressure (BP), reaching maximum 2-3 h after the injection and subsiding after 12 h. The putative ADM-receptor antagonist ADM(22-52) (3 nmol/kg) counteracted LPS-induced BP lowering at 1 and 2 h, and reversed it at 3 and 6 h. CGRP(8-37), a selective antagonist of the CGRP1 receptors, was ineffective. Both ADM(22-52) and CGRP(8-37) did not evoke significant changes in the basal BP. Our findings provide strong support to the view ADM overproduction plays a major role in the LPS-induced decrease in BP, and suggest a potentially important therapeutic effect of the blockade of ADM(22-52)-sensitive receptors during endotoxic shock.     

Digestive motor effects and vascular actions of CGRP in dog are expressed by different receptor subtypes

Calcitonin gene-related peptide (CGRP) is a 37 AA peptide localized in blood vessels and nerves of the GI tract. Activation of CGRP receptors (subtypes 1 or 2) usually induces vasodilation and/or muscle relaxation, but its effects in dog and on gastroduodenal motility are still unclear. This study looked for the effect of CGRP and the antagonist CGRP8-37, specific for CGRP type 1 receptor, 1) on GI motility (interdigestive and postprandial), and 2) on hemodynamy, in conscious dogs. During the interdigestive period, the infusion of CGRP1-37 (200 pmol/kg/h) or CGRP8-37 (2000 pmol/kg/h) did not modify the duration of the migrating motor complex nor the release nor the motor action of plasma motilin. The gastric emptying of a solid meal (15 g meat/kg) was reduced by the administration of CGRP1-37 (AUC: 2196 +/- 288.6 versus 3618 +/- 288.4 with saline or T12: 78 +/- 7.3 versus 50 +/- 4.3 min; P < 0.01) and this effect was reversed by the antagonist CGRP8-37. CGRP1-37 significantly (P < 0. 01) diminished arterial pressures (118 +/- 1.6/64 +/- 1.4 vs. 125 +/- 1.4/75 +/- 1.2 mmHg with saline) and accelerated the basal cardiac rhythm (110 +/- 1.4 versus 83 +/- 1.6 beats/min). However, CGRP8-37 failed to block the cardiovascular effects of CGRP1-37. In dog, CGRP could influence digestive motility by slowing the gastric emptying of a meal through an action on CGRP-1 receptors. Hemodynamic effects of CGRP were not blocked by CGRP8-37 and seem therefore mediated by CGRP-2 receptor subtype.     

Regulation of in vivo whole blood aggregation in rats by calcitonin gene related peptide

The purpose of these experiments was to determine whether calcitonin gene related peptide (CGRP) mediates physiological control of platelet function in vivo. Rat blood pressure was continuously monitored via a femoral arterial cannula, and whole blood aggregation was assessed periodically ex vivo with an impedance aggregometer before and following a 1.4 nmol/kg bolus dose of CGRP8-37, a specific receptor antagonist of CGRP. Mean arterial blood pressure was not significantly affected by CGRP8-37 over a 30-min period (p>0.05). However, whole blood aggregation increased by 38.4+/-18.0% (p<0.01) and 32.0+/-11.2% (p<0.05), at 5 and 15 min post CGRP8-37, respectively, when compared with control. Whole blood aggregation was not significantly different from control at 30 min (p>0.05), suggesting a relatively short duration of action for in vivo CGRP8-37. These data suggest that CGRP contributes to the maintenance of hemostasis, and that this function may be more important than the better known vasodilatatory effects of this neuropeptide.     

Adrenomedullin inhibits neurotransmission of calcitonin gene-related peptide (CGRP)-containing vasodilator nerves in rat mesenteric resistance arteries.

We have reported that the rat mesenteric resistance artery has innervation of calcitonin gene-related peptide (CGRP)-containing vasodilator nerves (CGRPergic nerves). We also demonstrated that adrenomedullin (AM) causes mesenteric vasodilation through activation of CGRP receptors. The present study was designed to examine the effect of AM on neurotransmission of CGRPergic nerves in rat mesenteric arteries. In preconstricted preparations without endothelium, periarterial nerve stimulation (PNS, 1 and 2 Hz) induced a frequency-dependent vasodilation. A bolus injection of CGRP (10 pmol) into the perfusate also caused a vasodilation. AM (0.1 to 10 nM) concentration-dependently caused 40% to 60% inhibition of the PNS-induced vasodilation, but AM did not attenuate vasodilation induced by exogenous CGRP injection. The inhibitory effect of AM (10 nM) on PNS-induced vasodilation was further potentiated by CGRP [8-37] (CGRP receptor antagonist, 50 nM), which attenuated the vasodilator response to the CGRP injection. Combined perfusion of AM [22-52] (AM receptor antagonist, 10 to 100 nM) resulted in further inhibition of PNS-induced neurogenic vasodilation without affecting the vasodilator response to the CGRP injection. CGRP [8-37] but not AM [22-52] antagonized vasodilation induced by AM perfusion. These findings suggest that AM presynaptically inhibits neurotransmission of CGRPergic nerves, probably decreasing CGRP release, via receptors different from CGRP receptors.     

Intermedin 1-53 in central nervous system elevates arterial blood pressure in rats

Intermedin (IMD) is a novel member of the calcitonin/calcitonin gene-related peptide (CGRP) family identified from human and other vertebrate tissues. Preprointermedin can generate various mature peptides by proteolytic cleavage. Amino acid sequence analysis showed cleavage sites located between two basic amino acids at Arg93-Arg94 resulting in the production of prepro-IMD(95-147), namely IMD(1-53). The present study was designed to determine the effects of the IMD(1-53) fragment in the central nervous system (CNS) on mean arterial blood pressure and heart rate in normal rats and its possible mechanism. Rats were given doses of adrenomedullin (ADM) or IMD(1-53), intracerebroventricularly or intravenously, respectively, with continuous blood pressure and heart rate monitoring for 45min. Analysis with CGRP receptor antagonist CGRP(8-37), ADM receptor antagonist ADM(22-52), and anti-prepro-IMD antibody showed that 0.1, 0.5, and 1.0 nmol/kg IMD(1-53), caused a dose-dependent elevation in blood pressure, which was more prominent than the increase with equivalent IMD(1-47) or ADM. As well, IMD(1-53) caused a persistent increase in heart rate. The CNS action of IMD(1-53) could be blocked by ADM(22-52), CGRP(8-37), or prepro-IMD antibody. In contrast to the CNS action, intravenous administration of IMD(1-53) induced a depressor effect. These results suggest that IMD(1-53) is an important regulatory factor in mean arterial blood pressure and heart rate through its central and peripheral bioaction.     

Amylin increases cyclic AMP formation in L6 myocytes through calcitonin gene-related peptide receptors.

The cellular function of amylin is investigated in L6 myocytes, a rat skeletal muscle cell line. Both rat amylin and human amylin-amide acutely cause a dose-dependent increase in cyclic AMP formation in L6 myocytes. 100 nM amylin stimulates intracellular cyclic AMP concentrations 12-fold, whereas human amylin-amide at this concentration causes only a 2-fold increase. Up to 10 mM human amylin has no effect on cyclic AMP levels. Rat calcitonin gene-related peptide (CGRP) is more potent than amylin, causing a 60-fold increase over basal at 1 nM, with an EC50 value of 0.2 nM. The CGRP receptor antagonist, human CGRP8-37 (hCGRP8-37), completely blocks the stimulatory effect of both rat amylin and human amylin-amide on cyclic AMP production. [125I]CGRP binds specifically to a membrane fraction prepared from L6 [125I]CGRP with a Ki of 0.9 nM, while rat amylin also displaces [125I]CGRP with a Ki of 91 nM. Specific binding of [125I]CGRP to plasma membranes of rat liver and brain is also displaced by rat amylin with Ki values of 35 nM and 37 nM, respectively. In contrast, specific binding of [125I]amylin to numerous cells and tissues, under similar conditions, can not be demonstrated. These results suggest that the cellular effects and physiological actions of amylin may be mediated through receptors for CGRP.     

Close arterial infusion of calcitonin gene-related peptide into the rat stomach inhibits aspirin- and ethanol-induced hemorrhagic damage

Afferent neuron-mediated gastric mucosal protection has been suggested to result from the local release of vasodilator peptides such as calcitonin gene-related peptide (CGRP) from afferent nerve endings within the stomach. The present study, therefore, examined whether rat alpha-CGRP, administered via different routes, is able to protect against mucosal injury induced by gastric perfusion with 25% ethanol or acidified aspirin (25 mM, pH 1.5) in urethane-anesthetized rats. Close arterial infusion of CGRP (15 pmol/min) to the stomach, via a catheter placed in the abdominal aorta proximal to the celiac artery, significantly reduced gross mucosal damage caused by ethanol and aspirin whereas mean arterial blood pressure (BP) was not altered. Intravenous infusion of CGRP (50 pmol/min) did not affect aspirin-induced mucosal injury but significantly enhanced ethanol-induced lesion formation. Intravenous CGRP (50 pmol/min) also lowered BP and increased the gastric clearance of [14C]aminopyrine, an indirect measure of gastric mucosal blood flow while basal gastric output of acid and bicarbonate was not altered. Intragastric administration of CGRP (260 nM) significantly inhibited aspirin-induced mucosal damage but did not influence damage in response to ethanol. BP, gastric clearance of [14C]aminopyrine, and gastric output of acid and bicarbonate remained unaltered by intragastric CGRP. These data indicate that only close arterial administration of CGRP to the rat stomach, at doses devoid of a systemic hypotensive effect, is able to protect against both ethanol- and aspirin-induced mucosal damage. As this route of administration closely resembles local release of the peptide in the stomach, CGRP may be considered as a candidate mediator of afferent nerve-induced gastric mucosal protection.     

Turn structures in CGRP C-terminal analogues promote stable arrangements of key residue side chains.

The 37-amino acid calcitonin gene-related peptide (CGRP) is a potent endogenous vasodilator thought to be implicated in the genesis of migraine attack. CGRP antagonists may thus have therapeutic value for the treatment of migraine. The CGRP C-terminally derived peptide [D(31),P(34),F(35)]CGRP(27-37)-NH(2) was recently identified as a high-affinity hCGRP(1) receptor selective antagonist. Reasonable CGRP(1) affinity has also been demonstrated for several related analogues, including [D(31),A(34),F(35)]CGRP(27-37)-NH(2). In the study presented here, conformational and structural features in CGRP(27-37)-NH(2) analogues that are important for hCGRP(1) receptor binding were explored. Structure-activity studies carried out on [D(31),P(34),F(35)]CGRP(27-37)-NH(2) resulted in [D(31),P(34),F(35)]CGRP(30-37)-NH(2), the shortest reported CGRP C-terminal peptide analogue exhibiting reasonable hCGRP(1) receptor affinity (K(i) = 29.6 nM). Further removal of T(30) from the peptide's N-terminus greatly reduced receptor affinity from the nanomolar to micromolar range. Additional residues deemed critical for hCGRP(1) receptor binding were identified from an alanine scan of [A(34),F(35)]CGRP(28-37)-NH(2) and included V(32) and F(37). Replacement of the C-terminal amide in this same peptide with a carboxyl, furthermore, resulted in a greater than 50-fold reduction in hCGRP(1) affinity, thus suggesting a direct role for the amide moiety in receptor binding. The conformational properties of two classes of CGRP(27-37)-NH(2) peptides, [D(31),X(34),F(35)]CGRP(27-37)-NH(2) (X is A or P), were examined by NMR spectroscopy and molecular modeling. A beta-turn centered on P(29) was a notable feature consistently observed among active peptides in both series. This turn led to exposure of the critical T(30) residue to the surrounding environment. Peptides in the A(34) series were additionally characterized by a stable C-terminal helical turn that resulted in the three important residues (T(30), V(32), and F(37)) adopting consistent interspatial positions with respect to one another. Peptides in the P(34) series were comparatively more flexible at the C-terminus, although a large proportion of the [D(31),P(34),F(35)]CGRP(27-37)-NH(2) calculated conformers contained a gamma-turn centered on P(34). These results collectively suggest that turn structures at both the C-terminus and N-terminus of CGRP(27-37)-NH(2) analogues may help to appropriately orient critical residues (T(30), V(32), and F(37)) for hCGRP(1) receptor binding.     

Amylin or CGRP (8-37) fragments reverse amylin-induced inhibition of 14C-glycogen accumulation

The peptides amylin and calcitonin-gene related peptide (CGRP) have been shown to have similar effects on glycogen metabolism in vivo and in vitro. However, it is not clear whether they act via separate receptors. Peptide fragments based on the amino acid sequence of amylin or CGRP were evaluated for their ability to inhibit the action of the peptides in vitro. Insulin-stimulated glycogen turnover, as measured by 14C-glycogen accumulation, was inhibited about 70% by amylin (10nM) and 85% by CGRP (10nM). In the absence of exogenous peptide, peptide fragments based on the 8-37 and 10-37 amino acid sequences of rat amylin (10 uM) had no affect on 14C-glycogen accumulation. In the presence of amylin (10nM), the 8-37 and 10-37 fragments blocked amylin-induced inhibition of 14C-glycogen accumulation 100% and 11.4%, respectively. The 8-37 and 10-37 amylin fragments blocked CGRP inhibition of 14C-glycogen accumulation by 23.2% or 28.6%, respectively. The CGRP 8-37 fragment was equally effective as the amylin 8-37 reversing the effects of amylin than at reversing the effects of CGRP. These results demonstrate that amylin (8-37) completely antagonizes the effects of amylin with limited ability to block CGRP. Removing the eighth and ninth amino acids reduced the effectiveness of the inhibitor by about 90%.     

Comparative effect of Phoneutria nigriventer spider venom and capsaicin on the rat paw oedema

Capsaicin, the pungent component of hot peppers, and the venom of the spider Phoneutria nigriventer are able to activate sensory nerves resulting in cutaneous neurogenic plasma extravasation. This study was undertaken to compare the ability of these substances to evoke oedema in the rat hind-paw and mechanisms underlying this effect. Subplantar injection of either Phoneutria nigriventer venom (PNV; 1-100 microg/paw) or capsaicin (10-200 microg/paw) caused a significant paw oedema that was potentiated by CGRP (10 pmol/paw). In rats treated neonatally with capsaicin to deplete neuropeptides, the paw oedema induced by either PNV (100 microg/paw) or capsaicin (100 microg/paw) was partially reduced (P<0.05). The tachykinin NK1 receptor antagonist SR140333 (0.2 micromol/kg; i.v.) prevented the paw oedema induced by the tachykinin NK1 receptor agonist GR73632 (30 pmol/paw) and partially reduced paw oedema induced by PNV or capsaicin. Treatment of rats with compound 48/80 (5 mg/kg; s.c. 3 days) or with both H1 receptor antagonist (mepyramine; 1 nmol/paw) and 5-HT receptor antagonist (methysergide; 1 nmol/paw) significantly inhibited PNV- or capsaicin-induced paw oedema. The combined treatment with mepyramine and methysergide and SR140333 further reduced PNV- and capsaicin-induced paw oedema. The bradykinin B2 receptor antagonist Hoe 140 affected neither PNV- nor capsaicin-induced responses. Our results suggest that PNV and capsaicin each induce paw oedema that is partially mediated by activation of sensory fibers culminating in the release of substance P as well as by activation of mast cells which in turn release amines such as histamine and 5-HT.     

Comparison of responses to rat and human adrenomedullin in the hindlimb vascular bed of the cat

Responses to rat (r) adrenomedullin (ADM) and human (h) ADM were compared in the hindlimb vascular bed of the cat under conditions of controlled blood flow. Intra-arterial injections of rADM and hADM in doses of 0.03–1 nmol caused dose-related decreases in hindlimb perfusion pressure. In terms of relative vasodilator activity, rADM was similar to hADM. The time course of the vasodilator response and the recovery half times (T_1/2) for the vasodilator response to rADM and hADM were not significantly different. Decreases in hindlimb perfusion pressure in response to rADM and hADM were not altered by the calcitonin gene-related peptide receptor antagonist, rCGRP(8–37), at the same time, vasodilator responses to calcitonin gene-related peptide (CGRP) were significantly reduced. The T_1/2 of the vasodilator response to rADM and hADM were significantly greater after administration of the cAMP-selective, type IV phosphodiesterase inhibitor, rolipram. These data demonstrate that decreases in hindlimb perfusion pressure in response to rADM and hADM are similar and that vasodilator responses to rADM are not dependent on the activation of CGRP receptors in the hindlimb vascular bed of the cat. These data further suggest that decreases in hindlimb perfusion pressure in response to rADM are mediated by smooth muscle increases in cAMP levels.     

Comparative effects of adrenomedullin,an adrenomedullin analog,and CGRP in the pulmonary vascular bed of the cat and rat

Responses to synthetic human adrenomedullin (ADM), a novel hypotensive peptide initially isolated from human pheochromocytoma cells, an ADM analog (ADM_15–52), and a structurally related peptide, calcitonin gene-related peptide (CGRP), were compared in the pulmonary vascular bed of the cat and rat under constant flow conditions. When tone was increased with U46619, intraarterial injections of ADM (0.03–0.3 nmol), ADM_15–52 (0.03–0.3 nmol), and of CGRP (0.03–0.3 nmol) caused dose-related decreases in pulmonary arterial perfusion pressure. When the relative vasodilator activity of the peptides was compared on a nmol basis, ADM was approximately 10-fold more potent in the cat than in the rat, whereas vasodilator responses to CGRP were very similar in both species. CGRP was slightly more potent than ADM in the rat, whereas ADM was slightly more potent than CGRP in the cat. ADM and ADM_15–52 had similar pulmonary vasodiltor activity in the cat, whereas the full sequence peptide was slightly more potent than ADM_15–52 in the rat. The present data demonstrate that ADM has significant vasodilator activity in the pulmonary vascular beds of the cat and of the rat, and that the relative potency of the vasodilator effects of ADM and ADM_15–52 are different in the two species.     

Endogenous calcitonin gene-related peptide protects human alveolar epithelial cells through protein kinase Cepsilon and heat shock protein

The intracellular mechanisms of ischemic preconditioning (PC) in preventing lung dysfunction following transplantation, shock, and trauma remain poorly understood. Previously, we have shown that alveolar epithelial cells secrete calcitonin gene-related peptide (CGRP) under inflammatory stress. Using a hypoxia/reoxygenation (H/R) and PC model, we found that CGRP was also secreted from human type II alveolar epithelial cells (A549) after PC. The locally released CGRP interacted with its receptor on the membrane of A549 cells and elicited downstream signals mediating the PC effect, because hCGRP(8-37), a specific CGRP receptor antagonist, attenuated the protective effect of PC. Pre-inhibition of CGRP protein synthesis by small interfering RNA exacerbated (but overexpression of the CGRP gene ameliorated) H/R-induced cell death, which supports the autocrine effect of CGRP on A549 cells. Exogenous bioactive CGRP mimicked the beneficial effect of PC and up-regulated the expression of heat shock protein 70 (HSP70), which might act as the end effector to maintain cell viability. These effects were sensitive to hCGRP(8-37), calphostin C (a protein kinase C (PKC) inhibitor), and 5-hydroxydecanoic acid (a mitochondrial K(+)(ATP) channel blocker) but were insensitive to protein kinase A blockers. Moreover, CGRP induced the membrane translocation of PKCepsilon. PKCV1-2 (a cell-permeable inhibitory peptide of PKCepsilon) effectively abolished CGRP-induced HSP70 expression and cell protection. Therefore, PC induces CGRP secretion from human alveolar epithelial cells, and the locally released CGRP acts back on these cells, protecting them from H/R injury. The post-receptor signaling of CGRP is through PKCepsilon-dependent expression of HSP70.     

C-terminal peptides of calcitonin gene-related peptide act as agonists at the cholecystokinin receptor

We have previously described that [Tyr⁰]CGRP(28–37) acts as a receptor antagonist of rat CGRP in guinea pig pancreatic acini. We therefore examined other C-terminal peptides of CGRP for such activity. CGRP-acetyl(28–37) acetate did act as a rat CGRP antagonist. However, C-terminal CGRP peptides of 4 to 8 amino acid residues did not antagonize the actions of rat CGRP but stimulated amylase secretion. In pancreatic acini, a maximally effective concentration of rat CGRP (100 nM) caused a 2.1-fold increase in amylase secretion. When the C-terminal peptides of CGRP were tested in at 100 μM, CGRP(34–37) caused a 1.8-fold increase in amylase secretion, CGRP(33–37) a 2.8-fold increase, CGRP(32–37) a 9.2-fold increase, CGRP(31–37) a 4.1-fold increase, and CGRP(30–37) a 5.1-fold increase. Further studies with the most effective peptide, CGRP(32–37), demonstrated that it did not cause release of lactate dehydrogenase, and thus did not cause amylase release by cell damage. Unlike rat CGRP, CGRP(32–37) did not increase cellular cyclic AMP, but did stimulate outflux of ⁴⁵Ca. CGRP(32–37)-stimulated amylase release was not inhibited by the substance P receptor antagonist, spantide, by the bombesin receptor antagonist, [D-Phe⁶]bombesin(6–13) propylamide, or by the muscarinic receptor antagonist, atropine, but was inhibited by the CCK receptor antagonist L364,718. C-terminal peptides of CGRP inhibited binding of ¹²⁵I-BH-CCK-8, with the relative potencies of the peptides being the same as their relative potencies for stimulating amylase secretion. The present data demonstrate that C-terminal peptides of CGRP, although they have only 2 amino acid residues in common with CCK(26–33), act exclusively at CCK receptors on pancreatic acini to stimulate amylase secretion.     

Calcitonin gene-related peptide: a sensory and motor neurotransmitter in the feline lower esophageal sphincter

The effect of calcitonin gene-related peptide (CGRP) on the feline lower esophageal sphincter (LES) was determined and correlated with its anatomic distribution as determined by immunohistochemistry. Intraluminal pressures of the esophagus and LES were recorded in anesthetized cats. In separate cats, gastroesophageal junctions were removed after locating the LES manometrically and stained for CGRP-like immunoreactivity (LI) and substance P-LI (SP-LI) by indirect immunohistochemistry. CGRP-LI in the LES was most prominent in large nerve fascicles between the circular and longitudinal muscle layers and only rarely seen in nerve fibers within the circular muscle. The myenteric plexus contained numerous CGRP-LI nerve fibers but cell bodies were not seen. Many CGRP-LI nerve fibers in the myenteric plexus and occasional varicose nerves in the circular muscle demonstrated colocalization with SP-LI. Colocalization of CGRP-LI with SP-LI was also seen in the perivascular nerves of the submucosal and intramural blood vessels and in varicose fibers in the lamina propria of the gastric fundic mucosa. In the esophagus, CGRP-LI nerves extended through the muscularis mucosa and penetrated the squamous epithelium to the lumen. CGRP, given intra-arterially caused a dose-dependent fall in basal LES pressure, with a threshold dose of 10(-8) g/kg (2.63 pmol/kg). At the maximal effective dose, 5 x 10(-6) g/kg (1.31 x 10(3) pmol/kg), CGRP produced 61.0 +/- 6.0% decrease in basal LES pressure. At this dose, mean systemic blood pressure fell by 40.9 +/- 7.8%. The LES relaxation induced by a submaximal dose of CGRP (10(-6) g/kg, 262.7 pmol/kg), 50.3 +/- 3.2% relaxation was partially inhibited by tetrodotoxin (26.9 +/- 10.8% relaxation, P less than 0.025). The inhibitory effect of CGRP was not affected by cervical vagotomy, hexamethonium, atropine, propranolol, or naloxone. The LES contractile response to the D90 of SP (5 x 10(-8) g/kg, 37.1 pmol/kg) was not altered by CGRP 10(-8) or 10(-6) g/kg and the CGRP relaxation effect was not altered by the threshold dose of substance P (5 X 10(-9) g/kg, 3.71 pmol/kg). CONCLUSIONS: (1) CGRP-LI is present at the feline LES and is primarily seen in large nerve fascicles which pass from the intermuscular plane and through the circular muscle layer to the submucosa and in mucosal nerves. (2) CGRP colocalizes with SP-LI in some varicose nerve fibers of the circular muscle of the esophagus, LES and fundus, in perivascular nerves of the submucosal and intramucosal blood vessels, and in nerves of the lamina propria of the gastric fundus. (3) The luminal penetration of CGRP-LI nerves in the squamous mucosa of the esophagus suggests a sensory func     

Calcitonin gene-related peptide-evoked sustained tachycardia in calcitonin receptor-like receptor transgenic mice is mediated by sympathetic activity

Calcitonin gene-related peptide (CGRP) and adrenomedullin (AM) are potent vasodilators and exert positive chronotropic and inotropic effects on the heart. Receptors for CGRP and AM are calcitonin receptor-like receptor (CLR)/receptor-activity-modifying protein (RAMP) 1 and CLR/RAMP2 heterodimers, respectively. The present study was designed to delineate distinct cardiovascular effects of CGRP and AM. Thus a V5-tagged rat CLR was expressed in transgenic mice in the vascular musculature, a recognized target of CGRP. Interestingly, basal arterial pressure and heart rate were indistinguishable in transgenic mice and in control littermates. Moreover, intravenous injection of 2 nmol/kg CGRP, unlike 2 nmol/kg AM, decreased arterial pressure equally by 18 +/- 5 mmHg in transgenic and control animals. But the concomitant increase in heart rate evoked by CGRP was 3.7 times higher in transgenic mice than in control animals. The effects of CGRP in transgenic and control mice, different from a decrease in arterial pressure in response to 20 nmol/kg AM, were suppressed by 2 micromol/kg of the CGRP antagonist CGRP(8-37). Propranolol, in contrast to hexamethonium, blocked the CGRP-evoked increase in heart rate in both transgenic and control animals. This was consistent with the immunohistochemical localization of the V5-tagged CLR in the superior cervical ganglion of transgenic mice. In conclusion, hypotension evoked by CGRP in transgenic and control mice was comparable and CGRP was more potent than AM. Unexpectedly, the CLR/RAMP CGRP receptor overexpressed in postganglionic sympathetic neurons of transgenic mice enhanced the positive chronotropic action of systemic CGRP.