Cardiovascular effects of proenkephalin products in the rat

Douglas, Helen

January 1989

1. The biology and chemistry of the endogenous opioid peptide precursors and the distribution, release and metabolism of the products of proenkephalin are summarised, together with a review of the in vitro and in vivo cardiovascular effects of endogenous opioid peptides. 2. The four major products of proenkephalin, [Met] enkephalin, [Leu] enkephalin, [Met] enkephalyl-arg[6]-phe[7] and [Met] enkephalyl-arg[6]- gly[7] -leu[8] , were studied for their direct effects on isolated rat atria and perfused mesentery in vitro and for their indirect effects on responses of the tissues to exogenous noradrenaline. The effects of the proenkephalin products upon atrial responses to noradrenergic and cholinergic nerve stimulation were also investigated. [Met] Enkephalin, [Leu] enkephalin, [Met] enkephalyl-arg6-phe7 and [Met] enkephalyl-arg[6]-gly[7]-leu[8] (10[-9]-10[-6]M) had no direct effects upon isolated atria or the perfused mesentery and did not produce any modulatory effects upon responses to exogenous noradrenaline or on atrial responses to noradrenergic and cholinergic nerve stimulation. 3. The cardiovascular responses to proenkephalin products were investigated in the urethane-anaesthetised rat. Blood pressure and integrated heart rate were measured using a pressure transducer connected to a carotid artery cannula. Intravenous administration of proenkephalin products (30-300?g/kg) produced a dose-related decrease in mean arterial pressure and heart rate. This was of a similar magnitude for the four opioid peptides. The response was abolished by naloxone (1 mg/kg) demonstrating that it was opioid-receptor mediated, and was qualitatively similar to that produced by the p-opioid receptor selective agonist DAGO. The involvement of u -receptors in the response is further supported by the lack of effect of the ?-receptor selective agonist DPDPE and k-receptor selective agonist U-50, 488H. This militates against an involvement of ?- and k-receptors in the cardiovascular response to proenkephalin products. 4. An "atypical response" to [Met] enkephalyl-arg[6]-phe[7] was exhibited in 25% of preparations studied. This consisted of an initial bradycardia and decrease in mean arterial pressure followed by a tachycardia and increase in mean arterial pressure. The tachycardia and pressor response were mimicked by the dipeptide arg-phe and antagonised by propranolol and phentolamine respectively. Both components of the response were abolished by hexamethonium which suggests that the response may have been due to the stimulation of sympathetic ganglia. The "atypical response" was produced in litter mates and may reflect genetically controlled differential capabilities to enzymatically degrade the heptapeptide and generate the pharmacologically active dipeptide. 5. The cardiovascular responses to proenkephalin products were potentiated following pre-treatment with captopril, the angiotensin converting enzyme inhibitor, or bestatin, the aminopeptidase inhibitor, although to a lesser extent. The effects of captopril on the duration of the responses, especially to the heptapeptide and octapeptide, were most marked indicating that the activity of a captopril-sensitive enzyme may be responsible for the relatively short duration of the observed responses. 6. Pharmacological manipulations, such as the use of atropine and the quaternary opioid antagonist N-methyl levallorphan, and surgical procedures, including bilateral vagotomy and pithing, were employed to examine the mechanisms involved in the cardiovascular response to proenkephalin products. Through these techniques it was demonstrated that the response was vagally dependent, mediated by peripheral opioid receptors and dependent on the central nervous sytem functioning. The cardiovascular response to proenkephalin products therefore arises from the stimulation of peripheral opioid receptors. This is then transmitted to the central nervous system by the vagus nerve and results in the production of a centrally mediated decrease in mean arterial pressure and an atropine-sensitive bradycardia. 6a. Non-opioid effects of N-methyl levallorphan (initial nicotinic agonist activity followed by ganglion blocking effects) were observed at doses only two-fold higher than those required to block cardiovascular responses to Met enkephalin. The narrow selectivity of this compound makes it inappropriate for opioid antagonist studies where nicotinic receptors may be involved. 7. Manipulations of the hypothalamus-pituitary-adrenal axis, through adrenalectomy and suppression of pituitary function by dexamethasone administration, had significant effects upon the cardiovascular responses to proenkephalin products. This indicates that the activity of the hypothalamus-pituitary-adrenal axis and/or changes in the levels of circulating opioids has a considerable influence on the magnitude of the evoked response. 8. The respiratory effects of proenkephalin products and cardiovascular responses in artificially ventilated rats were studied. The results confirmed that the cardiovascular responses to proenkephalin products in the urethane-anaesthetised rat were not secondary to respiratory effects.

615.1

Opioid cardiovascular effect

Cardiovascular effects of (13S)-9_, 13_- epoxylabda-6_(19), 15(14)diol dilactone, a diterpenoid isolated from the organic extract of leonotis leonurus leaves, in anaesthetized normotensive rats

Chibuzo, Obikeze Kenechukwu

January 2009

Philosophiae Doctor - PhD / Plants used in traditional medicines have served as sources of some of the drug compounds used in medicines today, and could still serve as leads for then development of new drugs to treat existing chronic diseases such as hypertension. This study was aimed at the isolation and identification of a cardio-active compound from L. leonurus, a plant commonly used in traditional medicines in South Africa for the treatment of hypertension and other cardiac problems. The possible mechanisms by which the isolated compound produced its effect on the cardiovascular system were explored using the anaesthetized normotensive rat model.Fractionation of the organic extracts of the leaves led to the isolation of a novel diterpene,(13S)-9 , 13 -epoxylabda-6 (19),15(14)diol dilactone (EDD) whose structure was elucidated using infra red (IR), nuclear magnetic resonance (NMR), mass spectroscopy(MS), and X-ray diffraction analysis. In anaesthetized normotensive male Wistar rats, EDD(0.5 mg/kg – 5.0 mg/kg; IV) produced slight non-significant decreases in systolic pressure(SP), diastolic pressure (DP), and mean arterial pressure (MAP) with the lower (0.5 mg/kg– 2.0 mg/kg) doses, while significant increases in SP, DP and MAP occurred with the higher (3.0 mg/kg – 5.0 mg/kg) doses. All doses of EDD administered also produced significant decreases in heart rate (HR).Prazosin and reserpine pre-treatment abolished the vasoconstrictive effect of EDD,suggesting an indirect vasoconstrictive effect for EDD via the release of catecholamines.Atenolol pre-treatment led to increases in the negative chronotropic effect of EDD, while the positive chronotropic effect of dobutamine was significantly decreased by EDD,suggesting the involvement of the 1 adrenoceptor in the negative chronotropic effect of EDD. In animals pre-treated with verapamil, a cardio-selective Ca2+ channel blocker, no significant changes in HR occurred with all EDD doses, but HR values were significantly lower than those obtained with EDD in non pre-treated animals.The results of this study indicate that (13S)-9 , 13 -epoxylabda-6 (19),15(14)diol dilactone, a novel dilactone diterpene isolated from the leaves of L. leonurus has an effect on the cardiovascular system. EDD exhibits a dual effect on the cardiovascular system by producing a vasoconstrictive effect accompanied by bradycardia. The vasoconstrictive effect of EDD is probably due to the release of catecholamines, while the negative chronotropic effect is probably due to 1 adrenoceptor antagonism. Further studies are however required to fully determine the mechanism by which EDD produces its cardiovascular effects.

Plants

Leonotis leonurus

Diterpenes

Anaesthetized normotensive rat

Cardiovascular effect

Negative chronotropic effect

Vasoconstriction

Blood pressure

Heart rate

The Cardiovascular Effects of alpha-Melanocyte-Stimulating Hormone in the Nucleus Tractus Solitarii of Spontaneously Hypertensive Rats

Weng, Wen-Tsan

09 August 2004

alpha-melanocyte stimulating hormone (alpha-MSH) is an important regulator of food intake, metabolic rate, and inflammation. Recently, alpha-MSH was shown to influence sympathetic activity and blood pressure regulation. In the present study, we investigated the cardiovascular effects of alpha-MSH in the nucleus tractus solitarii (NTS) of spontaneously hypertensive rats (SHR). Because nitric oxide (NO) is well-known to involve in central cardiovascular regulation, we elucidated the role of NO in the cardiovascular responses induced by alpha-MSH. In urethane-anesthetized SHR, unilateral microinjection of alpha-MSH (0.3-300 pmol) into the NTS produced dose-responsive depressor and bradycardic effects. The cardiovascular effects of alpha-MSH were abrogated by the antagonist of melanocortin receptor (MC3/4-R), SHU9119. Pretreatment with precursor of nitric oxide, L-arginine, enhanced the duration of alpha-MSH-mediated hypotensive effects, whereas prior application of L-NAME, a universal inhibitor of nitric oxide synthase (NOS), significantly attenuated the effects of alpha-MSH. Prior injection with inhibitor of inducible NOS, aminoguanidine, but not inhibitor of neuronal NOS, 7-nitroindazole, attenuated the hypotensive effect of alpha-MSH. In summary, these results indicated alpha-MSH induced depressor and bradycardic effects in the NTS of SHR. Besides, the hypotensive mechanism of alpha-MSH was mediated via MC4-R and involved with iNOS activation in the NTS of SHR.

spontaneously hypertensive rats (SHR)

nucleus tractus solitarii (NTS)

depressor and bradycardic effects

nitric oxide (NO)

melanocortin receptor

cardiovascular effect

alpha-melanocyte stimulating hormone