Federico Casares

Presence of the μ3 Opiate Receptor in Endothelial Cells COUPLING TO NITRIC OXIDE PRODUCTION AND VASODILATION

Initial confinement of opiate receptors to the nervous system has recently been broadened to several other cell types. Based on the well established hypotensive effect of morphine, we hypothesized that endothelial cells may represent a target for this opiate substance. Endothelial cells (human arterial and rat microvascular) contain a high affinity, saturable opiate binding site presumed to mediate the morphine effects that is stereoselectively and characteristically antagonized by naloxone. This opiate alkaloid-specific binding site is insensitive to opioid peptides. It is, therefore, considered to be the same subtype of opiate receptor (designated μ3) used in the mediation of morphine in other cell types exhibiting the same binding profile. Experiments with endothelial cultures and the aortic ring of rats cultured in vitro demonstrate that morphine exerts direct modulatory control over the activities of endothelial cells, which leads to vasodilation. It induces the production of nitric oxide, a process that is sensitive to naloxone antagonism and nitric oxide synthase inhibition. In contrast with that of opiates, the administration of opioid peptides does not induce nitric oxide production by endothelial cells. In conclusion, the data presented above reveal a novel site of morphine action, endothelial cells, where a μ3 receptor is coupled to nitric oxide release and vasodilation.

Presence of morphine and morphine-6-glucuronide in the marine mollusk Mytilus edulis ganglia determined by GC/MS and Q-TOF-MS : Starvation increases opiate alkaloid levels

Morphine and morphine-6-glucuronide, a morphine metabolite, have been identified and quantified in Mytilus edulis pedal ganglia at a level of 2.67+/-0.44 and 0.98+/-0.14 ng/ganglia, respectively by high performance liquid chromatography coupled to electrochemical detection. These opiate alkaloids were further identified by both gas-chromatography mass spectrometry and nanoflow electrospray ionization double quadrupole orthogonal acceleration Time of Flight mass spectrometry. In animals that were starved, the morphine level rose to 6.38+/-0.88 ng/ganglion and the morphine 6-glucoronide rose to a level of 23.0+/-3.2 ng/ganglion after 30 days. These studies demonstrate that opiate alkaloids are present as naturally occurring signal molecules whose levels respond to stress, i.e., starvation. Opiate alkaloids were not found in the animals incubation media or food, demonstrating their synthesis occurred in the respective tissue. These new method of opiate alkaloid detection, conclusively proves that morphine and morphine-6-glucuronide are present in animal tissues.

Ascaris suum, an Intestinal Parasite, Produces Morphine

The parasitic worm Ascaris suum contains the opiate alkaloid morphine as determined by HPLC coupled to electrochemical detection and by gas chromatography/mass spectrometry. The level of this material is 1168 ± 278 ng/g worm wet weight. Furthermore, Ascaris maintained for 5 days contained a significant amount of morphine, as did their medium, demonstrating their ability to synthesize the opiate alkaloid. To determine whether the morphine was active, we exposed human monocytes to the material, and they immediately released nitric oxide in a naloxone-reversible manner. The anatomic distribution of morphine immunoreactivity reveals that the material is in the subcuticle layers and in the animals’ nerve chords. Furthermore, as determined by RT-PCR, Ascaris does not express the transcript of the neuronal μ receptor. Failure to demonstrate the expression of this opioid receptor, as well as the morphine-like tissue localization in Ascaris, suggests that the endogenous morphine is intended for secretion into the microenvironment.

Endogenous morphine levels increase in molluscan neural and immune tissues after physical trauma.

The aim of this study was to demonstrate by biochemical and immunocytochemical methods the presence of endogenous morphine in nervous and immune tissues of the freshwater snail, Planorbarius corneus. High performance liquid chromatography (HPLC) coupled to electrochemical detection performed on tissues from control snails, revealed that the CNS contains 6.20+/-2.0 pmol/g of the alkaloid, the foot tissue contains a much lower level, 0.30+/-0.03 pmol/g, whilst morphine is not detected in the hemolymph and hepatopancreas. In specimens that were traumatized, we detected a significant rise of the CNS morphine level 24 h later (43.7+/-5.2 pmol/g) and an initial decrease after 48 h (19.3+/-4.6 pmol/g). At the same times, we found the appearance of the opiate in the hemolymph (0.38+/-0.04 pmol/ml and 0.12+/-0.03 pmol/ml) but not in the hepatopancreas. Using indirect immunocytochemistry, a morphine-like molecule was localized to a number of neurons and a type of glial cell in the CNS, to some immunocytes in the hemolymph and to amoebocytes in the foot, as well as to fibers in the aorta wall. Simultaneously to the rise of morphine biochemical level following trauma, morphine-like immunoreactivity (MIR) increased in both intensity and the number of structures responding positively, i.e., neurons and fiber terminals. In another mollusc, the mussel Mytilus galloprovincialis, the same pattern of enhanced MIR was found after trauma. Taken together, the data suggest the presence of a morphinergic signaling in invertebrate neural and immune processes resembling those of classical messenger systems and an involvement in trauma response.

The presence of morphine in ganglionic tissues of Modiolus deminissus: a highly sensitive method of quantitation for morphine and its derivatives

Morphine and morphine-6-glucuronide, a morphine metabolite, have been identified and quantified in Modiolus deminissus pedal ganglia at a level of 2.41 and 0.95 ng/ganglia, respectively. These opiate alkaloids are normally found at low concentrations in invertebrate and vertebrate tissues, including neural. Given this problem, we also describe a new opiate extraction protocol as well as a high-performance liquid chromatography purification procedure that can separate and quantify morphine and its derivatives at sub-nanogram concentrations. Furthermore, both morphine and morphine-6-glucuronide were identified in this mollusks pedal ganglia by mass spectrometry analysis.

Identification of morphine in the adrenal medullary chromaffin PC-12 cell line

Morphine was identified in the adrenal medulla chromaffin PC-12 cell line by reversed-phase HPLC, following liquid and solid extraction. The morphine corresponding HPLC fractions (1.746+/-0.615 ng of morphine/million cells) were further analyzed by gas chromatography-mass spectrometry and found to be identical to synthetic morphine. Furthermore, using primers derived from the human neuronal mu 1 opiate receptor, we used RT-PCR to detect expression of mu transcripts from this cell line. The transcript was absent. The study conclusively proves morphine, but not a mu opiate receptor, is constitutively expressed in the adrenal medulla chromaffin PC-12 cell line.

Morphine stimulates nitric oxide release in human mitochondria

The expression of morphine by plants, invertebrate, and vertebrate cells and organ systems, strongly indicates a high level of evolutionary conservation of morphine and related morphinan alkaloids as required for life. The prototype catecholamine, dopamine, serves as an essential chemical intermediate in morphine biosynthesis, both in plants and animals. We surmise that, before the emergence of specialized plant and animal cells/organ systems, primordial multi-potential cell types required selective mechanisms to limit their responsiveness to environmental cues. Accordingly, cellular systems that emerged with the potential for recruitment of the free radical gas nitric oxide (NO) as a multi-faceted autocrine/paracrine signaling molecule, were provided with extremely positive evolutionary advantages. Endogenous morphinergic signaling, in concert with NO-coupled signaling systems, has evolved as an autocrine/paracrine regulator of metabolic homeostasis, energy metabolism, mitochondrial respiration and energy production. Basic physiological processes involving morphinergic/NO-coupled regulation of mitochondrial function, with special emphasis on the cardiovascular system, are critical to all organismic survival. Key to this concept may be the phenomenon of mitochondrial enslavement in eukaryotic evolution via endogenous morphine.