Inflammation increases MMP levels via PGE2 in human vascular wall and plasma of obese women.

BACKGROUND AND OBJECTIVES: Matrix metalloproteinases (MMPs) are involved in several inflammatory processes including obesity-related vascular diseases and graft failure of coronary artery (CA) bypass grafts [internal mammary artery (IMA), saphenous vein (SV)]. In these inflammatory conditions, the release of prostaglandin E2 (PGE2) is increased via the activity of inducible microsomal PGE synthase-1 (mPGES-1). Our aim was to investigate whether MMPs and their endogenous inhibitor (TIMPs) may be regulated by PGE2 under inflammatory conditions in human vasculature and perivascular adipose tissue (PVAT), as well as in plasma of obese patients. METHODS: MMP-1,-2 and TIMP-1,-2 densities were measured in human plasma (n = 68) as well as in supernatants of human vascular wall (IMA n = 16, SV n = 14, CA n = 13) and their PVAT. The effects of inflammation and mPGES-1 inhibitor (Compound III, 10 µM) on MMPs regulation were evaluated. The correlations between PGE2 and several parameters were calculated in plasma from patients with or without obesity. RESULTS: The vascular wall and PVAT from SV exhibited the greatest MMP-1,-2 release. An increase of MMP-1,-2 and/or a decrease of TIMP-1 quantities have been detected under inflammation only in vascular wall not in PVAT. These changes under inflammation were completely reversed by inhibition of mPGES-1. In obesity, C-reactive protein (CRP), biomarker of inflammation, and PGE2 levels were increased. PGE2 contents were positively correlated with some anthropometric parameters and plasmatic CRP in both genders, while the correlation with the plasmatic MMP-1 density was significant only in women. CONCLUSIONS: The greater MMP activity observed in SV may contribute to the increased prevalence of graft failure. Under inflammation, the greater mPGES-1 and PGE2 levels lead to enhanced MMP activity in human vascular walls. The positive association between PGE2 and MMP-1 or CRP has been observed in plasma of women. We suggest that mPGES-1 inhibitors could prevent graft failure and obesity-related vascular remodeling mostly in women.

Potassium channels modulate the action but not the synthesis of hydrogen sulfide in rat corpus cavernosum.

AIM: Hydrogen sulfide (H2S) is a newly-introduced gasotransmitter in penile tissues. However, its exact mechanism of action in mediating penile erection is not fully elucidated. The major aim of this study was to examine the role of different K+ channels in mediating the responses to H2S in the corpus cavernosum. MAIN METHODS: Tension studies using isolated rat corpus cavernosum strips were conducted. Endogenous H2S production was measured using polarographic technique. Results are expressed as mean±SEM. KEY FINDINGS: l-Cysteine (10-2M) stimulated rat corpus cavernosum to produce H2S. Blockade of CSE by BCA (10-3M) reduced the concentration of H2S produced from rat corpus cavernosum significantly. Addition of TEA (10-2M) or 4-AP (10-3M) didn't have a significant effect on the concentration of H2S produced. l-Cysteine (10-6-10-2M) elicited a concentration-dependent relaxation response which was significantly reduced by blockade of CSE using BCA (10-3M). TEA (10-2M), 4-AP (10-3M) and TEA (10-4M) attenuated l-cysteine-induced relaxation significantly. At 10-4M, l-cysteine resulted in percentage relaxation of 1.55±0.63, 10.94±1.93 and 1.93±0.80 in presence of TEA (10-2M), 4-AP (10-3M) and TEA (10-4M) respectively compared to 23.78±2.71 as control. Both glibenclamide (10-5M) and BaCl2 (3×10-5M) failed to reduce these relaxations significantly. SIGNIFICANCE: H2S-induced relaxation of rat corpus cavernosum may be mediated - at least in part - through BKca and KV channels not by KATP and Kir channels. It also seems that K+-channels do not contribute to the synthesis of H2S.

Prostanoids in the pathophysiology of human coronary artery.

Coronary artery disease is one of the leading causes of death in wordwide. There is growing evidence that prostanoids are involved in the physiology and pathophysiology of the human coronary artery by controlling vascular tone, remodelling of the vascular wall or angiogenesis. In this review, the production of prostanoids and the expression of prostanoid receptors in human coronary artery in health or disease are described. In addition, the interactions between sex hormones and prostanoids, their participations in the development of coronary artery diseases have been addressed. Globally, most of the studies performed in human coronary artery preparations have shown that prostacyclin (PGI2) has beneficial effects by inducing vasodilatation and promoting angiogenesis while reverse effects are confirmed by thromboxane A2 (TxA2). More studies are needed to determine the roles of the other prostanoids (PGE2, PGD2 and PGF2α) in vascular functions of the human coronary artery. Finally, in addition to the in vitro data about the human coronary artery, myocardial infarction induced by cyclooxygenase-2 (COX-2) inhibitor and the protective effects of aspirin after coronary artery bypass surgery suggest that prostanoids are key mediators in coronary homeostasis.

The role of prostaglandin E2 in human vascular inflammation.

Prostaglandins (PG) are the product of a cascade of enzymes such as cyclooxygenases and PG synthases. Among PG, PGE2 is produced by 3 isoforms of PGE synthase (PGES) and through activation of its cognate receptors (EP1-4), this PG is involved in the pathophysiology of vascular diseases. Some anti-inflammatory drugs (e.g. glucocorticoids, nonsteroidal anti-inflammatory drugs) interfere with its metabolism or effects. Vascular cells can initiate many of the responses associated with inflammation. In human vascular tissue, PGE2 is involved in many physiological processes, such as increasing vascular permeability, cell proliferation, cell migration and control of vascular smooth muscle tone. PGE2 has been shown to contribute to the pathogenesis of atherosclerosis, abdominal aortic aneurysm but also in physiologic/adaptive processes such as angiogenesis. Understanding the roles of PGE2 and its cognate receptors in vascular diseases could help to identify diagnostic and prognostic biomarkers. In addition, from these recent studies new promising therapeutic approaches like mPGES-1 inhibition and/or EP4-antagonism should be investigated.

PGE(2) receptor (EP(4)) agonists: potent dilators of human bronchi and future asthma therapy?

BACKGROUND: Asthma and chronic obstructive pulmonary disease are characterized by inappropriate constriction of the airway smooth muscle. In this context, the physiological response of the human airways to selective relaxant agonists like PGE(2) is highly relevant. The aim of this study was thus to characterize the PGE(2) receptor subtypes (EP(2) or EP(4)) involved in the relaxation of human bronchial preparations. METHODS: Human bronchial preparations cut as rings were mounted in organ baths for isometric recording of tension and a pharmacological study was performed using selective EP(2) or EP(4) ligands. RESULTS: In the presence of a thromboxane TP receptor antagonist and indomethacin, PGE(2) induced the relaxation of human bronchi (E(max) = 86 ± 04% of papaverine response; pEC(50) value = 7.06 ± 0.13; n = 6). This bronchodilation was significantly blocked by a selective EP(4) receptor antagonist (GW627368X, 1 and 10 µmol/L) with a pK(B) value of 6.38 ± 0.19 (n = 5). In addition, the selective EP(4) receptor agonists (ONO-AE1-329; L-902688), but not the selective EP(2) receptor agonist (ONO-AE1-259), induced potent relaxation of bronchial preparations pre-contracted with histamine or anti-IgE. CONCLUSION: PGE(2) and EP(4) agonists induced potent relaxations of human bronchial preparations via EP(4) receptor. These observations suggest that EP(4) receptor agonists could constitute therapeutic agents to treat the increased airway resistance in asthma.

Differential reactivity of human mammary artery and saphenous vein to prostaglandin E(2) : implication for cardiovascular grafts.

BACKGROUND AND PURPOSE: Human internal mammary arteries (IMA) and saphenous veins (SV) are frequently used for coronary artery bypass graft surgery. Intra- and postoperatively, the bypass grafts are exposed to inflammatory conditions, under which there is a striking increase in the synthesis of prostaglandin E(2) (PGE(2) ). In this context, the physiological response of these vascular grafts to PGE(2) is highly relevant. The aim of this study was thus to characterize the PGE(2) receptor subtypes (EP(1) , EP(2) , EP(3) or EP(4) ) involved in modulation of the vascular tone in these two vessels. EXPERIMENTAL APPROACH: Rings of IMA and SV were prepared from 48 patients. The rings were mounted in organ baths for isometric recording of tension, and a pharmacological study was performed, together with associated reverse transcriptase PCR and immunohistochemistry experiments. KEY RESULTS: PGE(2) induced contractions of IMA (E(max) = 1.43 ± 0.20 g; pEC(50) = 7.50 ± 0.10); contractions were also observed with the EP(3) receptor agonists, sulprostone, 17-phenyl-PGE(2) , misoprostol or ONO-AE-248. In contrast, PGE(2) induced relaxation of the precontracted SV (E(max) =-0.22 ± 0.02 g; pEC(50) = 7.14 ± 0.09), as did the EP(4) receptor agonist, ONO-AE1-329. These results were confirmed by the use of selective EP receptor antagonists (GW627368X, L-826266, ONO-8713, SC-51322) and by molecular biology and immunostaining. CONCLUSIONS AND IMPLICATIONS: PGE(2) induced potent and opposite effects on the human vascular segments used for grafting, namely vasoconstriction of the IMA and vasodilatation of the SV via EP(3) and EP(4) receptors respectively. These observations suggest that EP(3) and EP(4) receptors could constitute therapeutic targets to increase vascular graft patency.

Vasorelaxation induced by prostaglandin E2 in human pulmonary vein: role of the EP4 receptor subtype.

BACKGROUND AND PURPOSE: PGE2 has been shown to induce relaxations in precontracted human pulmonary venous preparations, while in pulmonary arteries this response was not observed. We investigated and characterized the prostanoid receptors which are activated by PGE2 in the human pulmonary veins. EXPERIMENTAL APPROACH: Human pulmonary arteries and veins were cut as rings and set up in organ baths in presence of a TP antagonist. A pharmacological study was performed using selective EP1-4 ligands. The cellular localization of the EP4 receptors by immunohistochemistry and their corresponding transcripts were also investigated in these vessels. KEY RESULTS: PGE2 and the EP4 agonists (L-902688, ONO-AE1-329) induced potent vasodilatation of the human pulmonary vein, pEC50 values: <7.22+/-0.20, 8.06+/-0.12 and 7.80+/-0.09, respectively. These relaxations were inhibited by the EP(4) antagonist GW627368X and not modified in presence of the DP antagonist L-877499. Higher concentrations (>or=1 microM) of the EP2 agonist ONO-AE1-259 induced relaxations of the veins. The EP4 agonists had no effect on the precontracted arteries. Finally, the EP(1) antagonists ONO-8713 and SC-51322 potentiated the relaxation of the veins induced by PGE2. EP4 and EP1 receptors were detected by immunohistochemistry in the veins but not in the arteries. EP4 mRNA accumulation was also greater in the veins when compared with the arterial preparations. CONCLUSIONS AND IMPLICATIONS: Of the 4 EP receptor subtypes, smooth muscle cells in the human pulmonary vein express the EP4 and EP1 receptor subtypes. The relaxations induced by PGE2 in this vessel result from the activation of the EP4 receptor.

A new mRNA splice variant coding for the human EP3-I receptor isoform.

The cellular localization of prostaglandin E2 receptors (EP) and their corresponding transcripts were investigated in human gastric and vascular tissues. A strong staining of the EP3 receptor on the gastric glands, mucous cells, media of the mammary and pulmonary arteries was observed by immunohistochemistry. We identified a new mRNA splice variant of the EP3 gene in human gastric fundic mucosa, mammary artery and pulmonary vessels. This EP3-Ic transcript contains exons 1, 2, 3, 5 and 6 of the EP3 gene and should be translated in the EP3-I isoform. In addition, the EP3-Ib, EP3-II, EP3-III, EP3-IV and EP3-e mRNAs were detected in these tissues.

Modulation of vascular tone and reactivity by nitric oxide in porcine pulmonary arteries and veins.

Isolated porcine pulmonary vessels were studied in order to evaluate the role of nitric oxide in arteries and veins. Leukotriene C4 and noradrenaline contracted porcine pulmonary arteries but induced only negligible contractions of porcine pulmonary veins. After treatment with the nitric oxide synthase inhibitor N(omega)-nitro-L-arginine (L-NOARG), significant contractions to leukotriene C4 and noradrenaline were uncovered in pulmonary veins. In arterial preparations, L-NOARG caused a less marked potentiation of noradrenaline-induced contractions and did not alter leukotriene C4-induced contractions. Endothelium-dependent relaxations to acetylcholine were greater in veins compared with arteries whereas the endothelium-independent relaxations to the nitric oxide donor sodium nitroprusside (SNP) and the cyclic nucleotide analogue 8-bromo-cGMP were similar in the two preparations. Taken together these data suggest that the apparent insensitivity of porcine pulmonary veins to leukotriene C4 and noradrenaline was because of release of nitric oxide. The effect of nitric oxide synthase inhibition was less pronounced in porcine pulmonary arteries, suggesting a preferential functional role of nitric oxide in porcine pulmonary veins, originating in a greater production of nitric oxide by veins as opposed to arteries.

Prostanoid EP(1)- and TP-receptors involved in the contraction of human pulmonary veins.

1. To characterize the prostanoid receptors (TP, FP, EP(1) and/or EP(3)) involved in the vasoconstriction of human pulmonary veins, isolated venous preparations were challenged with different prostanoid-receptor agonists in the absence or presence of selective antagonists. 2. The stable thromboxane A(2) mimetic, U46619, was a potent constrictor agonist on human pulmonary veins (pEC(50)=8.60+/-0.11 and E(max)=4.61+/-0.46 g; n=15). The affinity values for two selective TP-antagonists (BAY u3405 and GR32191B) versus U46619 were BAY u3405: pA(2)=8.94+/-0.23 (n=3) and GR32191B: apparent pK(B)=8.25+/-0.34 (n=3), respectively. These results are consistent with the involvement of TP-receptor in the U46619 induced contractions. 3. The two EP(1)-/EP(3)- agonists (17-phenyl-PGE(2) and sulprostone) induced contraction of human pumonary veins (pEC(50)=8.56+/-0.18; E(max)=0.56+/-0.24 g; n=5 and pEC(50)=7.65+/-0.13; E(max)=1.10+/-0.12 g; n=14, respectively). The potency ranking for these agonists: 17-phenyl-PGE(2) > sulprostone suggests the involvement of an EP(1)-receptor rather than EP(3). In addition, the contractions induced by sulprostone, 17-phenyl-PGE(2) and the IP-/EP(1)- agonist (iloprost) were blocked by the DP-/EP(1)-/EP(2)-receptor antagonist (AH6809) as well as by the EP(1) antagonist (SC19220). 4. PGF(2alpha) induced small contractions which were blocked by AH6809 while fluprostenol was ineffective. These results indicate that FP-receptors are not implicated in the contraction of human pulmonary veins. 5. These data suggest that the contractions induced by prostanoids involved TP- and EP(1)-receptors in human pulmonary venous smooth muscle.

The muscarinic receptor subtypes in human blood vessels.

Acetylcholine (ACh) may induce the relaxation and the contraction of human blood vessels. These effects involve the activation of muscarinic receptors located on endothelial or smooth muscle cells. In humans and animals, five subtypes of muscarinic receptors (M1-M5) have been identified. In the particular case of human blood vessels, the M3 subtype seems to be prevalent on endothelial cells as well as on smooth muscle cells. However, the M1 subtype may be specific for the pulmonary vascular endothelium. In contrast, the M4 subtype has not been described in human vessels. These conclusions are, however, based on a limited number of studies and further work is needed in this area of research. Although muscarinic receptors may not be the only receptors involved in hypertension, the development of specific agonists for M1 receptors may be useful to counteract any elevation of blood pressure in the pulmonary circulation.

Antagonist resistant contractions of the porcine pulmonary artery by cysteinyl-leukotrienes.

The contractile response to cysteinyl-leukotrienes was studied in isolated porcine pulmonary arterial rings. In endothelium-denuded preparations, the concentration-response curves for leukotriene C(4) and leukotriene D(4) were identical, whereas leukotriene E(4) did not contract these tissues. The response to leukotriene C(4) was not blocked by either CysLT(1)/CysLT(2) receptor antagonism or by pre-treatment with leukotriene E(4). In preparations with an intact endothelium, leukotriene C(4) was somewhat more potent than leukotriene D(4) and the concentration-response curves were only slightly depressed in the presence of either ICI 204,219 (4-(5-cyclopentyloxycarbonylamino-1-methylindol-3-ylmethy l)-3-methoxy -N-o-tolylsulfonylbenzamide, 1 microM) or BAY u9773 (6(R)-(4'-carboxyphenylthio)-5(S)-hydroxy-7(E),9(E), 11(Z)14(Z)-eicosatetrenoic acid, 3 microM). Indomethacin (1.7 microM) significantly reduced the response to leukotriene C(4) whereas the response to leukotriene D(4) was unchanged. These findings suggest that a CysLT receptor subtype resistant to current antagonists mediated the major part of the contractions to leukotriene C(4) and leukotriene D(4) in intact preparations, and was the sole receptor associated with contractions of endothelium-denuded preparations.

Prostacyclin modulation of contractions of the human pulmonary artery by cysteinyl-leukotrienes.

The contractile response to cysteinyl-leukotrienes was studied in isolated human pulmonary arterial rings. Concentration-response curves for leukotriene C(4) were significantly potentiated by the cyclooxygenase inhibitor indomethacin (1.7 microM) and after endothelial denudation. Measurements of 6-keto prostaglandin F(1alpha) showed that cysteinyl-leukotrienes stimulated the release of prostacyclin. A single concentration (1 microM) of either leukotriene C(4) or leukotriene D(4) resulted in both contraction and relaxation. Indomethacin abolished the relaxant phase and enhanced the amplitude of the contraction, supporting that cysteinyl-leukotriene-induced contractions of the human pulmonary artery may be functionally antagonised by the release of prostacyclin. The contractions induced by leukotriene C(4) were resistant to the two cysteinyl-leukotriene receptor antagonists MK 571 ((3-(-2(7-chloro-2-quinolinyl)ethenyl)phenyl)((3-(dimethylamino-3-oxo propyl)thio)methyl)thio propanoic acid, 1 microM) and BAY u9773 (6(R)-(4'-carboxyphenylthio)-5(S)-hydroxy-7(E),9(E), 11(Z)14(Z)-eicosatetrenoic acid, 3 microM), both in the absence and presence of indomethacin. These findings suggest a functional cysteinyl-leukotriene receptor in the human pulmonary artery with antagonist properties not previously described in human tissue.

Evidence for a M(1) muscarinic receptor on the endothelium of human pulmonary veins.

1. To characterize the muscarinic receptors on human pulmonary veins associated with the acetylcholine (ACh)-induced relaxation, isolated venous and arterial preparations were pre-contracted with noradrenaline (10 microM) and were subsequently challenged with ACh in the absence or presence of selective muscarinic antagonists. 2. ACh relaxed venous preparations derived from human lung with a pD(2) value of 5.82+/-0.09 (n=16). In venous preparations where the endothelium had been removed, the ACh relaxations were abolished (n=4). ACh relaxed arterial preparations with a pD(2) value of 7. 06+/-0.14 (n=5). 3. Atropine (1 microM), the non selective antagonist for muscarinic receptors, inhibited ACh-induced relaxations in human pulmonary veins. The affinity value (pK(B) value) for atropine was: 8.64+/-0.10 (n=5). The selective muscarinic antagonists (darifenacin (M(3)), himbacine (M(2),M(4)), methoctramine (M(2)) and pFHHSiD (M(1),M(3))) also inhibited ACh-induced relaxations in venous preparations. The pK(B) values obtained for these antagonists were not those predicted for the involvement of M(2 - 5) receptors in the ACh-induced relaxation in human pulmonary veins. 4. The pK(B) value for darifenacin (1 microM) was significantly greater in human pulmonary arterial (8.63+/-0.14) than in venous (7.41+/-0.20) preparations derived from three lung samples. 5. In human pulmonary veins, the pK(B) values for pirenzepine (0.5 and 1 microM), a selective antagonist for M(1) receptors, were: 7.89+/-0.24 (n=7) and 8.18+/-0.22 (n=5), respectively. In the venous preparations, the pK(B) values derived from the functional studies with all the different muscarinic antagonists used were correlated (r=0.89; P=0.04; slope=0.78) with the affinity values (pK(i) values) previously published for human cloned m1 receptors in CHO cells. 6. These results suggest that the relaxations induced by ACh are due to the activation of M(1) receptors on endothelial cells in isolated human pulmonary veins.

Functional studies of leukotriene receptors in vascular tissues.

The paradoxical effects of cysteinyl-leukotrienes, namely contraction and relaxation, are now well documented in a number of vascular preparations from various species. The vascular smooth muscle contractions are associated with activation of a single receptor subtype and in some vascular smooth muscles with activation of two receptor subtypes. However, the receptors implicated in the contraction of vessels such as pig pulmonary arteries and veins, dog inferior vena cava, and dog splenic and mesenteric veins remain to be established. There are sufficient data concerning some vascular tissues to suggest that relaxations induced by cysteinyl-leukotrienes are via the stimulation of specific receptors present on the endothelium. The endothelium in human pulmonary arteries has one receptor (CysLT2) and activation induced the release of NO. However, in isolated human pulmonary veins two receptors are present, CysLT1 and CysLT2 (Figure 1). Activation of the former induced the release of a contractile factor whereas activation of the CysLT2 receptor released NO. In guinea pig pulmonary artery and guinea pig thoracic aorta, one receptor has been demonstrated since the relaxations are blocked by ICI-198615. These data suggest the presence of a CysLT1 receptor. Activation of this receptor leads to the release of a relaxant factor, namely, nitric oxide. In contrast, in human pulmonary arteries and veins activation of a receptor that is resistant to ICI-198615 is associated with NO release. These results suggest that there may be species differences even when analogous vascular preparations are examined. While the cysteinyl-leukotrienes are known to relax vascular smooth muscle in a variety of preparations from different species, there are presently two pathways known to be involved in this response. One involves the metabolites of arachidonic acid via the cyclooxygenase enzymatic pathway and the other implicates products of the L-arginine enzymatic pathway. Although both pathways may be present and active in the endothelium of the vascular preparations only one of these enzymatic pathways may be dominant and responsible for the relaxations observed. Ortiz and coworkers have demonstrated that in pulmonary veins the dominant pathway for cysteinyl-leukotriene relaxations is the NO pathway. There are some reports from animal studies that support a dominant role for NO in pulmonary veins. In contrast, Allen and co-workers demonstrated that the LTC4-induced relaxations in isolated human saphenous veins were not modified by treatment of tissues with an NO inhibitor but were significantly enhanced after treatment with indomethacin. These authors suggested that a contracting factor derived from the arachidonic acid pathway was released in preparations challenged with LTC4. In addition, these investigators demonstrated that the NO inhibitor had no effect on the LTC4 relaxations. Together, these results suggest that cysteinyl-leukotriene effects in human pulmonary veins are dominated by the NO pathway whereas in human systemic veins these mediator effects are modified by metabolites of the cyclooxygenase pathway. Unfortunately, most studies involving the actions of cysteinyl-leukotrienes on vessels have been performed in the presence of indomethacin, making interpretation of the relative contribution of the cyclooxygenase and NO pathways difficult. In any event, the cysteinyl-leukotrienes may have a prominent role in the activation of these pathways and the receptors involved have not been clearly established.

Prostanoid receptors involved in the relaxation of human bronchial preparations.

1. Iloprost and cicaprost (IP-receptor agonists) induced relaxations in the histamine- (50 microM) contracted human bronchial preparations (pD2 values, 6.63+/-0.12 and 6.86+/-0.08; Emax values, 90+/-04 and 65+/-08% of the papaverine response for iloprost (n=6) and cicaprost (n=3), respectively). 2. Prostaglandin E2 (PGE2) and misoprostol (EP-receptor agonist) relaxed the histamine-contracted human bronchial preparations (pD2 values, 7.13+/-0.07 and 6.33+/-0.28; Emax values, 67+/-04 and 57+/-08% of the papaverine response for PGE2 (n=14) and misoprostol (n=4), respectively). In addition, both relaxations were inhibited by AH6809 (DP/EP1/EP2-receptor antagonist; 3 microM; n=5-6). 3. The PGE2-induced relaxations of human bronchial preparations were not modified by treatment with AH23848B (TP/EP4-receptor antagonist; 30 microM; n=4). 4. The contracted human bronchial preparations were significantly relaxed by prostaglandin D2 (PGD2) or by BW245C a DP-receptor agonist. However, these responses did not exceed 40% of the relaxation induced by papaverine. In addition, the relaxations induced by PGD2 were significantly inhibited by treatment with a DP-receptor antagonist BWA868C (0.1 microM; n=3). 5. These data suggest that the relaxation of human isolated bronchial preparations induced by prostanoids involved IP-, EP2- and to a lesser extent DP-receptors but not EP4-receptor.

Prostanoid receptors involved in the relaxation of human pulmonary vessels.

1. To characterize the prostanoid receptors on human pulmonary smooth muscle involved in vasodilatations, isolated arteries and veins were contracted with norepinephrine (10 microM) and vessels were subsequently challenged with different prostanoid-receptor agonists in the absence or presence of selective antagonists. 2. Prostaglandin D2 (PGD2) and the selective DP-receptor agonist, BW245C, induced relaxations in the contracted human pulmonary venous preparations. The pD2 values were: 6.88+/-0.11 (n=17) and 7.31+/-0.12 (n=5), respectively. The relaxant responses induced by PGD2 were reduced by the selective DP-receptor antagonist, BWA868C, and the estimated pA2 value was 7.84+/-0.16 (n=4). PGD2 and BW245C did not relax contracted human pulmonary arteries. 3. The selective IP-receptor agonists, iloprost and cicaprost, both induced relaxations in the contracted human vascular preparations. The pD2 values for iloprost were: 7.84+/-0.08 (n=6) and 8.25+/-0.06 (n=4) and for cicaprost: 8.06+/-0.12 (n=5) and 8.11+/-0.09 (n=5) in arteries and veins respectively. 4. Prostaglandin E2 (PGE2) and the EP2/EP3-receptor agonist, misoprostol, partially relaxed the contracted venous preparations and the pD2 values were: 8.10+/-0.15 (n=15) and 6.24+/-0.33 (n=3), respectively. These relaxations suggest the presence of an EP receptor in the human pulmonary veins. The contracted human pulmonary arteries did not relax when challenged with PGE2. 5. In human pulmonary venous preparations, the PGE2-induced relaxations were neither modified by treatment with TP/EP4-receptor antagonist, AH23848B (10 and 30 microM, n=6), nor by the DP/EP1/EP2-receptor antagonist, AH6809 (3 microM, n=6). 6. These data suggest that the relaxation induced by prostanoids involved DP-, IP-receptors and to a lesser extent an EP-receptor on human pulmonary venous smooth muscle. In contrast, only the IP-receptor is involved in the prostanoid induced relaxations on human pulmonary arterial smooth muscle.

Cholinergic control of human and animal pulmonary vascular tone.

The regulation of pulmonary vascular tone by acetylcholine (ACh) involves the activation of different subtypes of muscarinic receptors as well as the cholinesterase activities which are responsible for ACh degradation. Most of the studies on the cholinergic control of the pulmonary vascular tone have been performed in vessels derived from animals. The ability of ACh to induce pulmonary vasoconstriction is species dependent. In vessels derived from sheep lung, ACh induced contractions in veins but not in arteries whereas in human pulmonary vessels the reverse was observed. The subtype(s) of the muscarinic receptors involved in the pulmonary vasoconstrictions is also dependent on the species which are studied. M1 receptors are implicated in the rabbit pulmonary vasoconstrictions, M3 in humans, whereas M1 and M2 receptors are involved in the dog. The cholinesterases are implicated in the vasoconstriction produced by ACh in human and rabbit pulmonary arteries. However, in these studies while acetylcholinesterase (EC 3.1.1.7) and butyrylcholinesterase (EC 3.1.1.8) activities were detected in human vessels only acetylcholinesterase activity was found in rabbit vessels. The endothelium-dependent relaxation induced by ACh has been reported in isolated pulmonary vessels from different animals including man. However, the muscarinic receptors involved in the ACh-induced vasodilatation of rat and rabbit pulmonary artery are of the M3 subtype while those characterized in the human pulmonary artery are of the M3 and M1 subtypes. Together these results concerning the cholinergic control of the pulmonary vascular tone indicate that extrapolation of the data obtained in animal models to human vessels requires some caution. In addition, there is considerable evidence to demonstrate that ageing may modify cholinergic responses. However, little information is available concerning the pulmonary vascular bed during ageing.

Anaphylactic bronchoconstriction in BP2 mice: interactions between serotonin and acetylcholine.

1. Immunized BP2 mice developed an acute bronchoconstriction in vivo and airway muscle contraction in vitro in response to ovalbumin (OA) and these contractions were dose dependent. 2. Methysergide or atropine inhibited OA-induced bronchoconstriction in vivo and airway muscle contraction in vitro. 3. Neostigmine potentiated the OA-induced bronchoconstriction in vivo and airway muscle contraction in vitro of BP2 mice. This potentiation was markedly reduced by the administration of methysergide or atropine and when the two antagonists were administered together, the responses were completely inhibited. 4. Neostigmine also potentiated the serotonin (5-HT)- and acetylcholine (ACh)-induced bronchoconstriction and this potentiation was significantly reversed by atropine. 5. These results indicate that OA provokes a bronchoconstriction in immunized BP2 mice by stimulating the release of 5-HT, which in turn acts via the cholinergic mediator, ACh.