Plasticity of Signaling by Spinal Estrogen Receptor α, κ-Opioid Receptor, and Metabotropic Glutamate Receptors over the Rat Reproductive Cycle Regulates Spinal Endomorphin 2 Antinociception: Relevance of Endogenous-Biased Agonism

Abstract: We previously showed that intrathecal application of endomorphin 2 [EM2; the highly specific endogenous μ-opioid receptor (MOR) ligand] induces antinociception that varies with stage of the rat estrous cycle: minimal during diestrus and prominent during proestrus. Earlier studies, however, did not identify proestrus-activated signaling strategies that enable spinal EM2 antinociception. We now report that in female rats, increased spinal dynorphin release and κ-opioid receptor (KOR) signaling, as well as the em… Show more

“…Our findings reveal that compromised spinal estrogenic and mGluR 1 activity, which unleashes antinociceptive responsiveness to i.t. EM2 in intact diestrous rats 46,47 reduced spinal opioid antiallodynia in spinal nerve ligated rats during diestrous. Conversely, compromised mGluR 1 signaling, which minimizes i.t.…”

“…This includes increased release of spinal dynorphin, activation of spinal kappa-opioid receptors (KOR), and a switch in the endogenous agonist of mGluR 1 from mERα in diestrus to glutamate in proestrus. 46 It is likely that signaling mechanisms regulating analgesic effectiveness of intrathecally applied EM2 also pertain to endogenous EM2 antinociception. An anatomical organization is present in spinal cord that enables endogenous interactions among presumed regulatory components of intrathecal (i.t.)…”

“…Additionally, spinal dynorphin-expressing neurons that coexpress mGluR 1 and ERα are apposed by terminals expressing vesicular glutamate transporters (glutamatergic terminals). 46 This cellular organization not only provides basis for cycling between ERα-activated and glutamate-activated mGluR 1 signaling over the estrous cycle, but also enables glutamate modulation of spinal dynorphin release, thereby coordinating glutamate activation of mGluR 1 with dynorphin release, both of which are prerequisites for spinal EM2 antinociception during proestrus. 46 The identification of signaling molecules that gate analgesic responsiveness to spinal EM2 suggests them to be potential targets for tapping into the spinal EM2 analgesic system for pain management.…”

“…46 This cellular organization not only provides basis for cycling between ERα-activated and glutamate-activated mGluR 1 signaling over the estrous cycle, but also enables glutamate modulation of spinal dynorphin release, thereby coordinating glutamate activation of mGluR 1 with dynorphin release, both of which are prerequisites for spinal EM2 antinociception during proestrus. 46 The identification of signaling molecules that gate analgesic responsiveness to spinal EM2 suggests them to be potential targets for tapping into the spinal EM2 analgesic system for pain management. However, under resting physiological conditions, in the absence of acute or chronic pain, endogenous opioid systems are quiescent, i.e., naloxone does not alter basal pain thresholds in laboratory animals 4,24 and humans.…”

“…treatments that unleash the analgesic properties of spinal EM2 during diestrus will also be antiallodynic, in the absence of exogenous opioids, in a spinal nerve ligation (SNL) chronic pain model during diestrus. We also tested the hypothesis that spinal treatments that impair spinal EM2 antinociception during proestrus 46 will exacerbate SNL-induced mechanical allodynia during this estrous cycle stage.…”

Pharmacological Modulation of Endogenous Opioid Activity to Attenuate Neuropathic Pain in Rats

“…Our findings reveal that compromised spinal estrogenic and mGluR 1 activity, which unleashes antinociceptive responsiveness to i.t. EM2 in intact diestrous rats 46,47 reduced spinal opioid antiallodynia in spinal nerve ligated rats during diestrous. Conversely, compromised mGluR 1 signaling, which minimizes i.t.…”

“…This includes increased release of spinal dynorphin, activation of spinal kappa-opioid receptors (KOR), and a switch in the endogenous agonist of mGluR 1 from mERα in diestrus to glutamate in proestrus. 46 It is likely that signaling mechanisms regulating analgesic effectiveness of intrathecally applied EM2 also pertain to endogenous EM2 antinociception. An anatomical organization is present in spinal cord that enables endogenous interactions among presumed regulatory components of intrathecal (i.t.)…”

“…Additionally, spinal dynorphin-expressing neurons that coexpress mGluR 1 and ERα are apposed by terminals expressing vesicular glutamate transporters (glutamatergic terminals). 46 This cellular organization not only provides basis for cycling between ERα-activated and glutamate-activated mGluR 1 signaling over the estrous cycle, but also enables glutamate modulation of spinal dynorphin release, thereby coordinating glutamate activation of mGluR 1 with dynorphin release, both of which are prerequisites for spinal EM2 antinociception during proestrus. 46 The identification of signaling molecules that gate analgesic responsiveness to spinal EM2 suggests them to be potential targets for tapping into the spinal EM2 analgesic system for pain management.…”

“…46 This cellular organization not only provides basis for cycling between ERα-activated and glutamate-activated mGluR 1 signaling over the estrous cycle, but also enables glutamate modulation of spinal dynorphin release, thereby coordinating glutamate activation of mGluR 1 with dynorphin release, both of which are prerequisites for spinal EM2 antinociception during proestrus. 46 The identification of signaling molecules that gate analgesic responsiveness to spinal EM2 suggests them to be potential targets for tapping into the spinal EM2 analgesic system for pain management. However, under resting physiological conditions, in the absence of acute or chronic pain, endogenous opioid systems are quiescent, i.e., naloxone does not alter basal pain thresholds in laboratory animals 4,24 and humans.…”

“…treatments that unleash the analgesic properties of spinal EM2 during diestrus will also be antiallodynic, in the absence of exogenous opioids, in a spinal nerve ligation (SNL) chronic pain model during diestrus. We also tested the hypothesis that spinal treatments that impair spinal EM2 antinociception during proestrus 46 will exacerbate SNL-induced mechanical allodynia during this estrous cycle stage.…”

Pharmacological Modulation of Endogenous Opioid Activity to Attenuate Neuropathic Pain in Rats

Estrogens as arbiters of sex-specific and reproductive cycle-dependent opioid analgesic mechanisms

Sex-based divergence of mechanisms underlying pain and pain inhibition