It is now well accepted that endogenous morphine is present in animals, both in invertebrates and vertebrates. It is a key signaling molecule that plays an important role in downregulating physiological responses, such as those in the immune system, including immune elements in the CNS. It has been demonstrated that a specific mu-opiate-receptor subtype, mu3, mediates these downregulatory effects through release of NO. This article examines morphine as an endogenous signaling molecule, in terms of its role in neural and immune regulation.
Systemic administration of morphine induced a hyperalgesic response in the hot plate test, at an extremely low dose (1-10 lg/kg). We have examined in vivo whether morphine, at an extremely low dose, induces acute central hypernociception following activation of the opioid receptor-mediated PLC/PKC inositol-lipid signaling pathway. The PLC inhibitor U73122 and the PKC blocker, calphostin C, dose dependently prevented the thermal hypernociception induced by morphine. This effect was also prevented by pretreatment with aODN against PLCb 3 at 2 nmol/mouse and PKCc at 2-3 nmol/mouse. Low dose morphine hyperalgesia was dose dependently reversed by selective NMDA antagonist MK801 and ketamine. This study demonstrates the presence of a nociceptive PLCb 3 /PKCc/NMDA pathway stimulated by low concentrations of morphine, through lOR 1 receptor, in mouse brain. This signaling pathway appears to play an opposing role in morphine analgesia. When mice were treated with a morphine analgesic dose (7 mg/kg), the downregulation of PLCb 3 or PKCc at the same aODN doses used for the prevention of the hyperalgesic effect induced, respectively, a 46% and 67% potentiation in analgesic response. Experimental and clinical studies suggest that opioid may activate pronociceptive systems, leading to pain hypersensitivity and short-term tolerance, a phenomenon encountered in postoperative pain management by acute opioid administration. The clinical management of pain by morphine may be revisited in light of the identification of the signaling molecules of the hyperalgesic pathway. Ó
Brain slices obtained from young rats were incubated with different radioactive precursors, in the presence and absence of L-cycloserine (an inhibitor of the synthesis of sphingosine) in order to explore the possibility that transport of proteolipids--and specifically of the major myelin proteolipid PLP--to the myelin membrane could be coupled to the transport of cerebrosides or sulfatides. At a concentration of 0.15 mM L-cycloserine, the incorporation of [3H] glycine into total proteins, proteolipid apoproteins (APL), PLP, and myelin basic proteins (MBP) of the total homogenate was unaffected by the presence of the inhibitor, whereas the incorporation of [3H] serine into glycosphingolipids decreased markedly. Under similar incubation conditions, the entry of labeled APL and of PLP into the myelin membranes in the presence of L-cycloserine decreased markedly (50%) in comparison to controls. Entry of MBP was not affected by the inhibitor. These results indicate that when synthesis of glycosphingolipids is inhibited by L-cycloserine, thus decreasing the availability of cerebrosides and sulfatides, the translocation of PLP to myelin is disrupted, suggesting that its transport through the oligodendroglial cell could be coupled to the transport of glycosphingolipids and, most probably, of sulfatides.
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