Dynorphin - Analgesia

Analgesia

Dynorphin has been shown to be a modulator of pain response. Han and Xie found that injecting dynorphin into the subarachnoid space of the rat spinal cord produced dose-dependent analgesia that was measured by tail-flick latency. Analgesia was partially eliminated by opioid antagonist naloxone.

Han and Xie found dynorphin to be 6-10 times more potent than morphine on a per mole basis. In addition, morphine tolerance did not reduce dynorphin-induced analgesia. Ren et al. demonstrated some of the complexities related to dynorphin induced analgesia. The authors found that combining subanalgesic levels of morphine and dynorphin A_1-13, a version of dynorphin A containing only the first 13 amino acids of the peptide, in the rat spinal cord had additive effects. However, when dynorphin A_1-13 was injected into the intracerebroventriulcar (ICV) region of the brain, it had an antagonist effect on morphine-induced analgesia.

A study by Lai et al. found that dynorphin might actually stimulate pain. The group found that it acts on the bradykinin receptor as well as KOR. The N-terminal tyrosine of dynorphin A is necessary to activate opioid receptors such as KOR, but is unnecessary in binding to bradykinin receptors. Lai et al. studied the effects of dynorphin A_2-13 that did not contain the N-terminal tyrosine. Based on the results of dynorphin A_2-13, the authors proposed a mechanism in which dynorphin A activates bradykinin receptors and thus stimulates pain response.

According to this mechanism, dynorphin activates bradykinin receptors, which triggers the release of calcium ions into the cell through voltage-sensitive channels in the cell membrane. Blocking bradykinin receptors in the lumbar region of the spinal cord reversed persistent pain. A multiple pathway system might help explain the conflicting effects of dynorphin in the CNS.

Svensson et al. provided another possible mechanism by which dynorphin might cause pain in the spinal cord. The authors found that administration of truncated dynorphin A_2-17, which does not bind to opioid receptors, causes an increase in phosphorylated p38 mitogen-activated protein kinase (MAPK) in microglia in the dorsal horn of the spinal cord. Activated p38 has been previously linked to the NMDA-evoked prostaglandin release, which causes pain. Thus, dynorphin could also induce pain in the spinal cord through a non-opioid p38 pathway.

Other studies have identified a role for dynorphin and kappa opioid receptor stimulation in neuropathic pain. This same group also showed that the dynorphin-KOR system mediates astrocyte proliferation through the activation of p38 MAPK that was required for the effects of neuropathic pain on analgesic responses. Taken together, these reports suggest that dynorphin can elicit multiple effects on both Kappa opioid, and non-opioid pathways to modulate analgesic responses.