Antagonism of the mu-delta opioid receptor heterodimer enhances opioid antinociception by activating Src and calcium/calmodulin-dependent protein kinase II signaling

Attila Keresztes; Keith Olson; Paul Nguyen; Marissa A. Lopez-Pier; Ryan Hecksel; Natalie K. Barker; Zekun Liu; Victor J Hruby; John Konhilas; Paul R. Langlais; John M. Streicher

doi:https://doi.org/10.1097/j.pain.0000000000002320

Antagonism of the mu-delta opioid receptor heterodimer enhances opioid antinociception by activating Src and calcium/calmodulin-dependent protein kinase II signaling

Attila Keresztes, Keith Olson, Paul Nguyen, Marissa A. Lopez-Pier, Ryan Hecksel, Natalie K. Barker, Zekun Liu, Victor J Hruby, John Konhilas, Paul R. Langlais, John M. Streicher

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

The opioid receptors are important regulators of pain, reward, and addiction. Limited evidence suggests the mu and delta opioid receptors form a heterodimer (MDOR), which may act as a negative feedback brake on opioid-induced analgesia. However, evidence for the MDOR in vivo is indirect and limited, and there are few selective tools available. We recently published the first MDOR-selective antagonist, D24M, allowing us to test the role of the MDOR in mice. We thus cotreated CD-1 mice with D24M and opioids in tail flick, paw incision, and chemotherapy-induced peripheral neuropathy pain models. D24M treatment enhanced oxymorphone antinociception in all models by 54.7% to 628%. This enhancement could not be replicated with the mu and delta selective antagonists CTAP, naltrindole, and naloxonazine, and D24M had a mild transient effect in the rotarod test, suggesting this increase is selective to the MDOR. However, D24M had no effect on morphine or buprenorphine, suggesting that only specific opioids interact with the MDOR. To find a mechanism, we performed phosphoproteomic analysis on brainstems of mice. We found that the kinases Src and CaMKII were repressed by oxymorphone, which was restored by D24M. We were able to confirm the role of Src and CaMKII in D24M-enhanced antinociception using small molecule inhibitors (KN93 and Src-I1). Together, these results provide direct in vivo evidence that the MDOR acts as an opioid negative feedback brake, which occurs through the repression of Src and CaMKII signal transduction. These results further suggest that MDOR antagonism could be a means to improve clinical opioid therapy.

Original language	English (US)
Pages (from-to)	146-158
Number of pages	13
Journal	Pain
Volume	163
Issue number	1
DOIs	https://doi.org/10.1097/j.pain.0000000000002320
State	Published - Jan 1 2022

Keywords

CaMKII
Heterodimer
Opioid
Pain
Phosphoproteomics
Signal transduction
Src

ASJC Scopus subject areas

Neurology
Clinical Neurology
Anesthesiology and Pain Medicine

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https://doi.org/10.1097/j.pain.0000000000002320

Cite this

Keresztes, A., Olson, K., Nguyen, P., Lopez-Pier, M. A., Hecksel, R., Barker, N. K., Liu, Z., Hruby, V. J., Konhilas, J., Langlais, P. R., & Streicher, J. M. (2022). Antagonism of the mu-delta opioid receptor heterodimer enhances opioid antinociception by activating Src and calcium/calmodulin-dependent protein kinase II signaling. Pain, 163(1), 146-158. https://doi.org/10.1097/j.pain.0000000000002320

Keresztes, A, Olson, K, Nguyen, P, Lopez-Pier, MA, Hecksel, R, Barker, NK, Liu, Z, Hruby, VJ, Konhilas, J , Langlais, PR & Streicher, JM 2022, 'Antagonism of the mu-delta opioid receptor heterodimer enhances opioid antinociception by activating Src and calcium/calmodulin-dependent protein kinase II signaling', Pain, vol. 163, no. 1, pp. 146-158. https://doi.org/10.1097/j.pain.0000000000002320

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title = "Antagonism of the mu-delta opioid receptor heterodimer enhances opioid antinociception by activating Src and calcium/calmodulin-dependent protein kinase II signaling",

abstract = "The opioid receptors are important regulators of pain, reward, and addiction. Limited evidence suggests the mu and delta opioid receptors form a heterodimer (MDOR), which may act as a negative feedback brake on opioid-induced analgesia. However, evidence for the MDOR in vivo is indirect and limited, and there are few selective tools available. We recently published the first MDOR-selective antagonist, D24M, allowing us to test the role of the MDOR in mice. We thus cotreated CD-1 mice with D24M and opioids in tail flick, paw incision, and chemotherapy-induced peripheral neuropathy pain models. D24M treatment enhanced oxymorphone antinociception in all models by 54.7% to 628%. This enhancement could not be replicated with the mu and delta selective antagonists CTAP, naltrindole, and naloxonazine, and D24M had a mild transient effect in the rotarod test, suggesting this increase is selective to the MDOR. However, D24M had no effect on morphine or buprenorphine, suggesting that only specific opioids interact with the MDOR. To find a mechanism, we performed phosphoproteomic analysis on brainstems of mice. We found that the kinases Src and CaMKII were repressed by oxymorphone, which was restored by D24M. We were able to confirm the role of Src and CaMKII in D24M-enhanced antinociception using small molecule inhibitors (KN93 and Src-I1). Together, these results provide direct in vivo evidence that the MDOR acts as an opioid negative feedback brake, which occurs through the repression of Src and CaMKII signal transduction. These results further suggest that MDOR antagonism could be a means to improve clinical opioid therapy.",

keywords = "CaMKII, Heterodimer, Opioid, Pain, Phosphoproteomics, Signal transduction, Src",

author = "Attila Keresztes and Keith Olson and Paul Nguyen and Lopez-Pier, {Marissa A.} and Ryan Hecksel and Barker, {Natalie K.} and Zekun Liu and Hruby, {Victor J} and John Konhilas and Langlais, {Paul R.} and Streicher, {John M.}",

note = "Funding Information: The authors thank Drs Tally Largent-Milnes and Todd Vanderah of the University of Arizona, Co-Directors of the Department of Pharmacology Rodent Behavioral Core, for the use of their rotarod device. This study was funded by R21DA044509 and UG3DA047717 to J. M. Streicher. The mass spectrometry proteomics data have been deposited to the ProteomeXchange Consortium through the PRIDE8,37 partner repository with the data set identifier PXD022106 and 10.6019/PXD022106. Reviewer account access is by username: reviewer_pxd022106@ ebi.ac.uk and password: WKO6g8yH. Author contributions: A. Keresztes collaborated on experimental and project design, performed most experiments, analyzed most of the data, and cowrote the article. K. Olson conceived, designed, and synthesized the key reagent D24M and collaborated on project design. P. Nguyen performed some behavioral experiments and analyzed the data. M. A. Lopez-Pier performed extensive statistical analysis of the phosphoproteomic data. R. Hecksel contributed to analysis of the proteomic data. N. K. Barker performed the proteomic experiment. Z. Liu contributed to synthesis of the key reagent D24M. V. Hruby supervised K. Olson and Z. Liu in the design and synthesis of D24M. J. Konhilas supervised M. A. Lopez-Pier in the statistical analysis of the proteomic data. P. R. Langlais supervised M. A. Lopez-Pier, R. Hecksel, and N. K. Barker in the design, performance, and analysis of the proteomic experiment and contributed to organization and analysis of the data. J. M. Streicher conceived the initial idea for the project; collaborated on project and experimental design; analyzed some data; supervised A. Keresztes, K. Olson, and P. Nguyen in the performance of their experiments; and cowrote the article. All authors had editorial input into the article. Funding Information: The authors thank Drs Tally Largent-Milnes and Todd Vanderah of the University of Arizona, Co-Directors of the Department of Pharmacology Rodent Behavioral Core, for the use of their rotarod device. This study was funded by R21DA044509 and UG3DA047717 to J. M. Streicher. The mass spectrometry proteomics data have been deposited to the ProteomeXchange Consortium through the PRIDE partner repository with the data set identifier PXD022106 and 10.6019/PXD022106. Reviewer account access is by username: reviewer_pxd022106@ebi.ac.uk and password: WKO6g8yH. Publisher Copyright: {\textcopyright} 2021 International Association for the Study of Pain",

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doi = "https://doi.org/10.1097/j.pain.0000000000002320",

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T1 - Antagonism of the mu-delta opioid receptor heterodimer enhances opioid antinociception by activating Src and calcium/calmodulin-dependent protein kinase II signaling

AU - Keresztes, Attila

AU - Olson, Keith

AU - Nguyen, Paul

AU - Lopez-Pier, Marissa A.

AU - Hecksel, Ryan

AU - Barker, Natalie K.

AU - Liu, Zekun

AU - Hruby, Victor J

AU - Konhilas, John

AU - Langlais, Paul R.

AU - Streicher, John M.

N1 - Funding Information: The authors thank Drs Tally Largent-Milnes and Todd Vanderah of the University of Arizona, Co-Directors of the Department of Pharmacology Rodent Behavioral Core, for the use of their rotarod device. This study was funded by R21DA044509 and UG3DA047717 to J. M. Streicher. The mass spectrometry proteomics data have been deposited to the ProteomeXchange Consortium through the PRIDE8,37 partner repository with the data set identifier PXD022106 and 10.6019/PXD022106. Reviewer account access is by username: reviewer_pxd022106@ ebi.ac.uk and password: WKO6g8yH. Author contributions: A. Keresztes collaborated on experimental and project design, performed most experiments, analyzed most of the data, and cowrote the article. K. Olson conceived, designed, and synthesized the key reagent D24M and collaborated on project design. P. Nguyen performed some behavioral experiments and analyzed the data. M. A. Lopez-Pier performed extensive statistical analysis of the phosphoproteomic data. R. Hecksel contributed to analysis of the proteomic data. N. K. Barker performed the proteomic experiment. Z. Liu contributed to synthesis of the key reagent D24M. V. Hruby supervised K. Olson and Z. Liu in the design and synthesis of D24M. J. Konhilas supervised M. A. Lopez-Pier in the statistical analysis of the proteomic data. P. R. Langlais supervised M. A. Lopez-Pier, R. Hecksel, and N. K. Barker in the design, performance, and analysis of the proteomic experiment and contributed to organization and analysis of the data. J. M. Streicher conceived the initial idea for the project; collaborated on project and experimental design; analyzed some data; supervised A. Keresztes, K. Olson, and P. Nguyen in the performance of their experiments; and cowrote the article. All authors had editorial input into the article. Funding Information: The authors thank Drs Tally Largent-Milnes and Todd Vanderah of the University of Arizona, Co-Directors of the Department of Pharmacology Rodent Behavioral Core, for the use of their rotarod device. This study was funded by R21DA044509 and UG3DA047717 to J. M. Streicher. The mass spectrometry proteomics data have been deposited to the ProteomeXchange Consortium through the PRIDE partner repository with the data set identifier PXD022106 and 10.6019/PXD022106. Reviewer account access is by username: reviewer_pxd022106@ebi.ac.uk and password: WKO6g8yH. Publisher Copyright: © 2021 International Association for the Study of Pain

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Y1 - 2022/1/1

N2 - The opioid receptors are important regulators of pain, reward, and addiction. Limited evidence suggests the mu and delta opioid receptors form a heterodimer (MDOR), which may act as a negative feedback brake on opioid-induced analgesia. However, evidence for the MDOR in vivo is indirect and limited, and there are few selective tools available. We recently published the first MDOR-selective antagonist, D24M, allowing us to test the role of the MDOR in mice. We thus cotreated CD-1 mice with D24M and opioids in tail flick, paw incision, and chemotherapy-induced peripheral neuropathy pain models. D24M treatment enhanced oxymorphone antinociception in all models by 54.7% to 628%. This enhancement could not be replicated with the mu and delta selective antagonists CTAP, naltrindole, and naloxonazine, and D24M had a mild transient effect in the rotarod test, suggesting this increase is selective to the MDOR. However, D24M had no effect on morphine or buprenorphine, suggesting that only specific opioids interact with the MDOR. To find a mechanism, we performed phosphoproteomic analysis on brainstems of mice. We found that the kinases Src and CaMKII were repressed by oxymorphone, which was restored by D24M. We were able to confirm the role of Src and CaMKII in D24M-enhanced antinociception using small molecule inhibitors (KN93 and Src-I1). Together, these results provide direct in vivo evidence that the MDOR acts as an opioid negative feedback brake, which occurs through the repression of Src and CaMKII signal transduction. These results further suggest that MDOR antagonism could be a means to improve clinical opioid therapy.

AB - The opioid receptors are important regulators of pain, reward, and addiction. Limited evidence suggests the mu and delta opioid receptors form a heterodimer (MDOR), which may act as a negative feedback brake on opioid-induced analgesia. However, evidence for the MDOR in vivo is indirect and limited, and there are few selective tools available. We recently published the first MDOR-selective antagonist, D24M, allowing us to test the role of the MDOR in mice. We thus cotreated CD-1 mice with D24M and opioids in tail flick, paw incision, and chemotherapy-induced peripheral neuropathy pain models. D24M treatment enhanced oxymorphone antinociception in all models by 54.7% to 628%. This enhancement could not be replicated with the mu and delta selective antagonists CTAP, naltrindole, and naloxonazine, and D24M had a mild transient effect in the rotarod test, suggesting this increase is selective to the MDOR. However, D24M had no effect on morphine or buprenorphine, suggesting that only specific opioids interact with the MDOR. To find a mechanism, we performed phosphoproteomic analysis on brainstems of mice. We found that the kinases Src and CaMKII were repressed by oxymorphone, which was restored by D24M. We were able to confirm the role of Src and CaMKII in D24M-enhanced antinociception using small molecule inhibitors (KN93 and Src-I1). Together, these results provide direct in vivo evidence that the MDOR acts as an opioid negative feedback brake, which occurs through the repression of Src and CaMKII signal transduction. These results further suggest that MDOR antagonism could be a means to improve clinical opioid therapy.

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Antagonism of the mu-delta opioid receptor heterodimer enhances opioid antinociception by activating Src and calcium/calmodulin-dependent protein kinase II signaling

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