Neuro-Signals
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The development of the prototype synthetic delta-opioid receptor antagonist peptides TIPP [(H-Tyr-Tic-Phe- Phe-OH); Tic: tetrahydroisoquinoline-3-carboxylic acid] and TIPPpsi (H-Tyr-psiTic-Phe-Phe-OH) by Schiller and coworkers was followed by extensive structure-activity relationship studies, leading to the emergence of numerous analogs that are of pharmacological interest. Eight novel diastereomeric compounds in this peptide family were designed, prepared, and tested biologically to gain structure-activity relationship information. The new multisubstituted tetrapeptide analogs contain both a 2',6'-dimethyltyrosine residue at the N-terminus and beta-methyl-cyclohexylalanine at the third position as replacements for the original first tyrosine and the third phenylalanine, respectively. ⋯ The potency and delta- versus mu-opioid receptor selectivity were evaluated by in vitro radioreceptor-binding assays, while the intrinsic G-protein-activating efficacy of these analogs was tested in [35S]GTPgammaS-binding assays using rat brain membranes or Chinese hamster ovary cells stably expressing mu- or delta-opioid receptors. The analogs showed delta-antagonist selectivity with differences regarding their isomeric forms, and these analogs containing a C-terminal carboxamide group displayed a mixed mu-agonist/delta-antagonist profile, thus they are expected to be safer analgesics with a low propensity to produce tolerance and physical dependence. These results constitute further examples of the influence of beta-methyl substitution and C-terminal amidation on potency, selectivity, and signal transduction properties of TIPP-related peptides as well as they represent valuable pharmacological tools for opioid research.
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The condition of pain after spinal cord injury (SCI) affects the life quality of nearly 70% of individuals with SCI. Clinical studies over the past decade have provided important insights into the complexities of the clinical and psychosocial characteristics of this debilitating consequence of SCI. The use of experimental models developed to study at-level or below-level pain has provided an appreciation for the mechanism(s) responsible for the onset and progression of these conditions. Important to the studies related to SCI pain has been the focus on the molecular, biochemical, anatomical, and functional consequences of SCI that have identified potential therapeutic targets for the design of novel treatment strategies.
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Opiates are the primary treatment for pain management in cancer patients reporting moderate to severe pain, and are being increasingly used for non-cancer chronic pain. However, prolonged administration of opiates is associated with significant problems including the development of antinociceptive tolerance, wherein higher doses of the drug are required over time to elicit the same amount of analgesia. High doses of opiates result in serious side effects such as constipation, nausea, vomiting, dizziness, somnolence, and impairment of mental alertness. ⋯ Importantly, the descending pain modulatory pathway from the brainstem rostral ventromedial medulla (RVM) via the dorsolateral funiculus (DLF) is critical for maintaining the changes observed in the spinal cord, abnormal pain states and antinociceptive tolerance, because animals with lesion of the DLF did not show enhanced evoked neuropeptide release, or develop abnormal pain or antinociceptive tolerance upon sustained exposure to opiates. Microinjection of either lidocaine or a CCK antagonist into the RVM blocked both thermal and touch hypersensitivity as well as antinociceptive tolerance. Thus, prolonged opioid exposure enhances a descending pain facilitatory pathway from the RVM that is mediated at least in part by CCK activity and is essential for the maintenance of antinociceptive tolerance.
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Comparative Study
An integrated study of heart pain and behavior in freely moving rats (using fos as a marker for neuronal activation).
The awareness in specific brain centers of angina pectoris most often results from ischemic episodes in the heart. These ischemic episodes induce the release of a collage of chemicals that activate chemosensitive and mechanoreceptive receptors in the heart, which in turn excite receptors of the sympathetic afferent pathways. Ascending pain signals from these fibers result in the activation of the brain centers which are involved in the perception and integration of cardiac pain. ⋯ This finding suggests that these two chemicals use two different pathways, and provides extra evidence for the role of the vagus nerve in the transmission of cardiac nociception. Different cerebral areas showed an increase in the c-fos activity following pericardial application of pain-inducing chemicals. The role of these cerebral areas in the integration of cardiac pain is discussed in relation to the identified pathways which transmit cardiac pain.
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Cyclin-dependent kinase 5 (Cdk5) displays kinase activity predominantly in post-mitotic neurons and its physiological roles are unrelated to cell cycle progression. Cdk5 is activated by its binding to a neuron-specific activator, p35 or p39. The protein amount of p35 or p39 is a primary determinant of the Cdk5 activity in neurons, with the amount of p35 or p39 being determined by its synthesis and degradation. ⋯ Phosphorylation is age dependent, as p35 is phosphorylated in foetal brains, but unphosphorylated in adult brains. Therefore, foetal phosphorylated p35 is turned over rapidly, whereas adult unphosphorylated p35 has a long life and is easily cleaved to p25 when calpain is activated. p39 is also a short-lived protein and cleaved to the N-terminal truncation form of p29 by calpain. How the metabolism of p39 is regulated, however, is a future problem to be investigated.