Shou-Wu Ma scite author profile

Dynorphin A is an endogenous opioid peptide that produces non-opioid receptor-mediated neural excitation. Here we demonstrate that dynorphin induces calcium influx via voltage-sensitive calcium channels in sensory neurons by activating bradykinin receptors. This action of dynorphin at bradykinin receptors is distinct from the primary signaling pathway activated by bradykinin and underlies the hyperalgesia produced by pharmacological administration of dynorphin by the spinal route in rats and mice. Blockade of spinal B1 or B2 receptor also reverses persistent neuropathic pain but only when there is sustained elevation of endogenous spinal dynorphin, which is required for maintenance of neuropathic pain. These data reveal a mechanism for endogenous dynorphin to promote pain through its agonist action at bradykinin receptors and suggest new avenues for therapeutic intervention.

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Design of novel peptide ligands which have opioid agonist activity and CCK antagonist activity for the treatment of pain

Hruby

Agnes

Davis

et al. 2003

Life Sciences

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Disease states such as neuropathic pain offer special challenges in drug design due to the system changes which accompany these diseases. In this manuscript we provide an example of a new approach to drug design in which we have modified a potent and selective peptide ligand for the CCK-2 receptor to a peptide which has potent agonist binding affinity and bioactivity at delta and mu opioid receptors, and simultaneous antagonist activity at CCK receptors. De novo design based on the concept of overlapping pharmacophores was a central hypothesis of this design, and led to compounds such as H-Tyr-DPhe-Gly-DTrp-NMeNle-Asp-Phe-NH 2 (i.e., RSA 601) which have the designed properties.

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Development of Novel Enkephalin Analogues that Have Enhanced Opioid Activities at Both μ and δ Opioid Receptors

et al. 2007

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Enkephalin analogues with a 4-anilidopiperidine scaffold have been designed and synthesized to achieve therapeutic benefit for the treatment of pain due to mixed mu and delta opioid agonist activities. Ligand 16, in which a Dmt-substituted enkephalin-like structure was linked to the N-phenyl-N-piperidin-4-yl propionamide moiety, showed very high binding affinities (0.4 nM) at mu and delta receptors with an increased hydrophobicity (aLogP = 2.96). This novel lead compound was found to have very potent agonist activities in MVD (1.8 nM) and GPI (8.5 nM) assays.

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‘Knock-down’ of spinal CB1 receptors produces abnormal pain and elevates spinal dynorphin content in mice

Doğrul¹,

Gardell²,

Ma³

et al. 2002

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Recent studies demonstrate the possible existence of tonic modulatory control of nociceptive input mediated by spinal cannabinoid receptors (CB1). Accordingly, it is predicted that a reduction in the spinal CB1 receptors may enhance sensitivity to sensory stimuli and a decrease in spinal antinociceptive potency to cannabinoid agonists. An antisense oligodeoxynucleotide (ODN) specific to the CB1 receptor was used to 'knock-down' CB1 receptors in the lumbar spinal cord and dorsal root ganglia by the local, repeated intrathecal (i.th.) administration of the ODN. This treatment resulted in a decrease in lumbar spinal CB1 receptor expression accompanied by a decrease in the response thresholds to both innocuous tactile and noxious thermal stimuli. The antinociceptive action of the CB1 agonist, WIN 55,212-2, by i.th. administration was also significantly attenuated after treatment with the antisense ODN. Similar treatment using a mismatch control ODN had no effect on receptor protein or on sensory thresholds. The effects of the antisense ODN treatment on sensory thresholds were fully reversed after discontinuation of the ODN injection. The antisense ODN treated rats also showed a significant increase in lumbar spinal dynorphin A. Acute i.th. injection of MK-801 or an antidynorphin antiserum blocked the antisense ODN-induced tactile and thermal hypersensitivity. These data support the possibility of endogenous inhibitory cannabinoid tone to limit spinal afferent input of thermal and tactile stimuli. Lifting of this inhibitory tone through a 'knock-down' of spinal CB1 receptors apparently lowers the thresholds for sensory input, as reflected by the actions of MK-801 to block tactile and thermal hypersensitivity. The increased spinal dynorphin may act to further promote afferent outflow and abnormal pain because sequestration of spinal dynorphin with antiserum also reverses the manifestations of abnormal pain following knock-down of CB1 receptors.

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Pharmacological characterization of the cloned kappa opioid receptor as a kappa1b subtype

Lai¹,

Ma²,

Zhu³

et al. 1994

NeuroReport

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Shou-Wu Ma

Dynorphin A activates bradykinin receptors to maintain neuropathic pain

Design of novel peptide ligands which have opioid agonist activity and CCK antagonist activity for the treatment of pain

Development of Novel Enkephalin Analogues that Have Enhanced Opioid Activities at Both μ and δ Opioid Receptors

‘Knock-down’ of spinal CB1 receptors produces abnormal pain and elevates spinal dynorphin content in mice

Pharmacological characterization of the cloned kappa opioid receptor as a kappa1b subtype

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