Morphine Efficacy, Tolerance, and Hypersensitivity Are Altered After Modulation of SUR1 Subtype KATP Channel Activity in Mice

Cole Fisher; Kayla Johnson; Travis Okerman; Taylor Jurgenson; Austin Nickell; Erin Salo; Madelyn Moore; Alexis Doucette; James Bjork; Amanda H. Klein

doi:10.3389/fnins.2019.01122

Morphine Efficacy, Tolerance, and Hypersensitivity Are Altered After Modulation of SUR1 Subtype K_ATP Channel Activity in Mice

Cole Fisher, Kayla Johnson, Travis Okerman, Taylor Jurgenson, Austin Nickell, Erin Salo, Madelyn Moore, Alexis Doucette, James Bjork, Amanda H. Klein

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

16 Scopus citations

Abstract

ATP-sensitive potassium (K_ATP) channels are found in the nervous system and are downstream targets of opioid receptors. K_ATP channel activity can effect morphine efficacy and may beneficial for relieving chronic pain in the peripheral and central nervous system. Unfortunately, the K_ATP channels exists as a heterooctomers, and the exact subtypes responsible for the contribution to chronic pain and opioid signaling in either dorsal root ganglia (DRG) or the spinal cord are yet unknown. Chronic opioid exposure (15 mg/kg morphine, s.c., twice daily) over 5 days produces significant downregulation of Kir6.2 and SUR1 in the spinal cord and DRG of mice. In vitro studies also conclude potassium flux after K_ATP channel agonist stimulation is decreased in neuroblastoma cells treated with morphine for several days. Mice lacking the K_ATP channel SUR1 subunit have reduced opioid efficacy in mechanical paw withdrawal behavioral responses compared to wild-type and heterozygous littermates (5 and 15 mg/kg, s.c., morphine). Using either short hairpin RNA (shRNA) or SUR1 cre-lox strategies, downregulation of SUR1 subtype K_ATP channels in the spinal cord and DRG of mice potentiated the development of morphine tolerance and withdrawal. Opioid tolerance was attenuated with intraplantar injection of SUR1 agonists, such as diazoxide and NN-414 (100 μM, 10 μL) compared to vehicle treated animals. These studies are an important first step in determining the role of K_ATP channel subunits in antinociception, opioid signaling, and the development of opioid tolerance, and shed light on the potential translational ability of K_ATP channel targeting pharmaceuticals and their possible future clinical utilization. These data suggest that increasing neuronal K_ATP channel activity in the peripheral nervous system may be a viable option to alleviate opioid tolerance and withdrawal.

Original language	English (US)
Article number	1122
Journal	Frontiers in Neuroscience
Volume	13
DOIs	https://doi.org/10.3389/fnins.2019.01122
State	Published - Oct 22 2019

Bibliographical note

Funding Information:
Funding provided by the NIH to AK (K01 DA042902), the University of Minnesota Integrated Biosciences Graduate Program to TO, and the University of Minnesota Duluth Undergraduate Research Opportunity Program award to TJ and AN.

Funding Information:
The authors thank Joseph Bryan at the Pacific Northwest Diabetes Institute, Seattle, WA, United States for the SUR1 global knock out mice and SUR1 flox mice. Brian Turnquist provided assistance regarding CAP recordings and Dapsys implementation (Bethel University, St. Paul, MN, United States). Robert Meyer (Labortechnik Franken, R?thenbach, Germany) provided the adapter box for the CAP recordings. Sophie Socha (University of Minnesota) also provided technical assistance. Funding. Funding provided by the NIH to AK (K01 DA042902), the University of Minnesota Integrated Biosciences Graduate Program to TO, and the University of Minnesota Duluth Undergraduate Research Opportunity Program award to TJ and AN.

Publisher Copyright:
© Copyright © 2019 Fisher, Johnson, Okerman, Jurgenson, Nickell, Salo, Moore, Doucette, Bjork and Klein.

Keywords

K channels
SUR1
analgesia
antinociception
opioid
tolerance
withdrawal

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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title = "Morphine Efficacy, Tolerance, and Hypersensitivity Are Altered After Modulation of SUR1 Subtype KATP Channel Activity in Mice",

abstract = "ATP-sensitive potassium (KATP) channels are found in the nervous system and are downstream targets of opioid receptors. KATP channel activity can effect morphine efficacy and may beneficial for relieving chronic pain in the peripheral and central nervous system. Unfortunately, the KATP channels exists as a heterooctomers, and the exact subtypes responsible for the contribution to chronic pain and opioid signaling in either dorsal root ganglia (DRG) or the spinal cord are yet unknown. Chronic opioid exposure (15 mg/kg morphine, s.c., twice daily) over 5 days produces significant downregulation of Kir6.2 and SUR1 in the spinal cord and DRG of mice. In vitro studies also conclude potassium flux after KATP channel agonist stimulation is decreased in neuroblastoma cells treated with morphine for several days. Mice lacking the KATP channel SUR1 subunit have reduced opioid efficacy in mechanical paw withdrawal behavioral responses compared to wild-type and heterozygous littermates (5 and 15 mg/kg, s.c., morphine). Using either short hairpin RNA (shRNA) or SUR1 cre-lox strategies, downregulation of SUR1 subtype KATP channels in the spinal cord and DRG of mice potentiated the development of morphine tolerance and withdrawal. Opioid tolerance was attenuated with intraplantar injection of SUR1 agonists, such as diazoxide and NN-414 (100 μM, 10 μL) compared to vehicle treated animals. These studies are an important first step in determining the role of KATP channel subunits in antinociception, opioid signaling, and the development of opioid tolerance, and shed light on the potential translational ability of KATP channel targeting pharmaceuticals and their possible future clinical utilization. These data suggest that increasing neuronal KATP channel activity in the peripheral nervous system may be a viable option to alleviate opioid tolerance and withdrawal.",

keywords = "K channels, SUR1, analgesia, antinociception, opioid, tolerance, withdrawal",

author = "Cole Fisher and Kayla Johnson and Travis Okerman and Taylor Jurgenson and Austin Nickell and Erin Salo and Madelyn Moore and Alexis Doucette and James Bjork and Klein, {Amanda H.}",

note = "Funding Information: Funding provided by the NIH to AK (K01 DA042902), the University of Minnesota Integrated Biosciences Graduate Program to TO, and the University of Minnesota Duluth Undergraduate Research Opportunity Program award to TJ and AN. Funding Information: The authors thank Joseph Bryan at the Pacific Northwest Diabetes Institute, Seattle, WA, United States for the SUR1 global knock out mice and SUR1 flox mice. Brian Turnquist provided assistance regarding CAP recordings and Dapsys implementation (Bethel University, St. Paul, MN, United States). Robert Meyer (Labortechnik Franken, R?thenbach, Germany) provided the adapter box for the CAP recordings. Sophie Socha (University of Minnesota) also provided technical assistance. Funding. Funding provided by the NIH to AK (K01 DA042902), the University of Minnesota Integrated Biosciences Graduate Program to TO, and the University of Minnesota Duluth Undergraduate Research Opportunity Program award to TJ and AN. Publisher Copyright: {\textcopyright} Copyright {\textcopyright} 2019 Fisher, Johnson, Okerman, Jurgenson, Nickell, Salo, Moore, Doucette, Bjork and Klein.",

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AU - Okerman, Travis

AU - Jurgenson, Taylor

AU - Nickell, Austin

AU - Salo, Erin

AU - Moore, Madelyn

AU - Doucette, Alexis

AU - Bjork, James

AU - Klein, Amanda H.

N1 - Funding Information: Funding provided by the NIH to AK (K01 DA042902), the University of Minnesota Integrated Biosciences Graduate Program to TO, and the University of Minnesota Duluth Undergraduate Research Opportunity Program award to TJ and AN. Funding Information: The authors thank Joseph Bryan at the Pacific Northwest Diabetes Institute, Seattle, WA, United States for the SUR1 global knock out mice and SUR1 flox mice. Brian Turnquist provided assistance regarding CAP recordings and Dapsys implementation (Bethel University, St. Paul, MN, United States). Robert Meyer (Labortechnik Franken, R?thenbach, Germany) provided the adapter box for the CAP recordings. Sophie Socha (University of Minnesota) also provided technical assistance. Funding. Funding provided by the NIH to AK (K01 DA042902), the University of Minnesota Integrated Biosciences Graduate Program to TO, and the University of Minnesota Duluth Undergraduate Research Opportunity Program award to TJ and AN. Publisher Copyright: © Copyright © 2019 Fisher, Johnson, Okerman, Jurgenson, Nickell, Salo, Moore, Doucette, Bjork and Klein.

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N2 - ATP-sensitive potassium (KATP) channels are found in the nervous system and are downstream targets of opioid receptors. KATP channel activity can effect morphine efficacy and may beneficial for relieving chronic pain in the peripheral and central nervous system. Unfortunately, the KATP channels exists as a heterooctomers, and the exact subtypes responsible for the contribution to chronic pain and opioid signaling in either dorsal root ganglia (DRG) or the spinal cord are yet unknown. Chronic opioid exposure (15 mg/kg morphine, s.c., twice daily) over 5 days produces significant downregulation of Kir6.2 and SUR1 in the spinal cord and DRG of mice. In vitro studies also conclude potassium flux after KATP channel agonist stimulation is decreased in neuroblastoma cells treated with morphine for several days. Mice lacking the KATP channel SUR1 subunit have reduced opioid efficacy in mechanical paw withdrawal behavioral responses compared to wild-type and heterozygous littermates (5 and 15 mg/kg, s.c., morphine). Using either short hairpin RNA (shRNA) or SUR1 cre-lox strategies, downregulation of SUR1 subtype KATP channels in the spinal cord and DRG of mice potentiated the development of morphine tolerance and withdrawal. Opioid tolerance was attenuated with intraplantar injection of SUR1 agonists, such as diazoxide and NN-414 (100 μM, 10 μL) compared to vehicle treated animals. These studies are an important first step in determining the role of KATP channel subunits in antinociception, opioid signaling, and the development of opioid tolerance, and shed light on the potential translational ability of KATP channel targeting pharmaceuticals and their possible future clinical utilization. These data suggest that increasing neuronal KATP channel activity in the peripheral nervous system may be a viable option to alleviate opioid tolerance and withdrawal.

AB - ATP-sensitive potassium (KATP) channels are found in the nervous system and are downstream targets of opioid receptors. KATP channel activity can effect morphine efficacy and may beneficial for relieving chronic pain in the peripheral and central nervous system. Unfortunately, the KATP channels exists as a heterooctomers, and the exact subtypes responsible for the contribution to chronic pain and opioid signaling in either dorsal root ganglia (DRG) or the spinal cord are yet unknown. Chronic opioid exposure (15 mg/kg morphine, s.c., twice daily) over 5 days produces significant downregulation of Kir6.2 and SUR1 in the spinal cord and DRG of mice. In vitro studies also conclude potassium flux after KATP channel agonist stimulation is decreased in neuroblastoma cells treated with morphine for several days. Mice lacking the KATP channel SUR1 subunit have reduced opioid efficacy in mechanical paw withdrawal behavioral responses compared to wild-type and heterozygous littermates (5 and 15 mg/kg, s.c., morphine). Using either short hairpin RNA (shRNA) or SUR1 cre-lox strategies, downregulation of SUR1 subtype KATP channels in the spinal cord and DRG of mice potentiated the development of morphine tolerance and withdrawal. Opioid tolerance was attenuated with intraplantar injection of SUR1 agonists, such as diazoxide and NN-414 (100 μM, 10 μL) compared to vehicle treated animals. These studies are an important first step in determining the role of KATP channel subunits in antinociception, opioid signaling, and the development of opioid tolerance, and shed light on the potential translational ability of KATP channel targeting pharmaceuticals and their possible future clinical utilization. These data suggest that increasing neuronal KATP channel activity in the peripheral nervous system may be a viable option to alleviate opioid tolerance and withdrawal.

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