Opioids are a mainstay of treatment for acute and chronic pain. Unfortunately, chronic opioid use is highly problematic in large part due to the loss of treatment effect over time and the need to escalate doses. Strong preliminary and published evidence suggests that pain signaling and opioid effects converge on BDNF expression in the dorsal horn of the spinal cord to accelerate tolerance, paradoxically enhance pain and worsen functional outcomes after acute injuries including surgery and when treating chronic disease. Epigenetic effects appear to play a prominent role. The main objective of these studies is to understand how spinal input through pain pathways and chronic opioid administration interact to heighten pain sensitivity, increase opioid requirements and worsen functional outcomes after injury. The goal of the first aim is to determine how opioid exposure and surgical trauma work individually and together to regulate spinal Bdnf expression, and to define the functional consequences of that expression. We hypothesize that surgical incision and chronic opioid administration in mice converge to cause the up- regulation of Bdnf in spinal cord neurons thus enhancing the severity of opioid maladaptations and pain. Pain-related signaling involving the activation of spinal NK1 receptors by the primary afferent neurotransmitter substance P (SP) and opioid effects involving -opioid receptors (-OR) will be examined specifically using knockout mice and selective pharmacological agents. Expression studies measuring Bdnf mRNA and protein will be integrated with immunohistochemical approaches carefully identifying the cellular source(s) of BDNF in our mouse model. Additional pharmacological studies will examine the functional roles of the high affinity TrkB and low affinity p75 receptors in mediating BDNF's effects in spinal cord tissue. We expect to observe that neuronal up-regulation of Bdnf and activation of TrkB receptors contribute to multiple indices of pain after incision, functional changes in gait, tolerance and OIH. The goal of the second aim is to determine the role of epigenetics in the regulation of spinal Bdnf expression after opioid exposure, surgical trauma and the combination of circumstances. We hypothesize that the pain-related neurotransmitter SP and morphine individually and together enhance the neuronal expression of Bdnf in spinal cord dorsal horn neurons in vivo via an epigenetic mechanism. Chromatin immunoprecipitation (ChIP) assays will be used to follow changes in the association of acetylated H3K9 and/or H4K12 histone protein with the Bdnf promoter. Immunohistochemical studies will identify the cell types within the dorsal horn of the spinal cord where histone acetylation and Bdnf up-regulation are occurring. Pharmacological studies will be used to demonstrate the functional role of alterations in histone acetylation with respect to Bdnf up-regulation and worsened opioid maladaptations and pain after incision. Additional mechanism-oriented studies will examine the role of the pCREB-CBP/p300 pathway in mediating the effects of SP and morphine on histone acetylation. We expect to find that the SP and morphine pathways converge on the phosphorylation of CREB thus activating CBP/p300-mediated histone acetylation at the H3K9 or H4K12 positions near the Bdnf promoter. The proposed studies pursue the novel hypothesis that epigenetic mechanisms are responsible for clinically important adverse interactions between pain and the chronic use of opioids. In doing so we expect to identify new approaches to the treatment of pain and methods to enhance the effectiveness of our most powerful but problematic class of pain relievers. The team assembled to pursue these aims possesses expertise in all required technical aspects of the project and has the scientific and clinical experience to place the anticipated results in thei proper perspective.

Public Health Relevance

Opioid medications including drugs such as morphine are our most powerful pain relievers. They are commonly prescribed to Veterans. Unfortunately, when patients with pain are given opioids the required dose tends to rise over time (tolerance) and patients paradoxically become sensitized to pain from new and existing injuries (hyperalgesia). Increasing doses of opioids can result in serious side effects overdose and death. These have emerged as major problems for the VA despite its commitment to improving pain control for its patients. The reasons why patients adapt to the use of these drugs and the interactions between opioid adaptations and pain are very poorly understood. We hypothesize that epigenetic mechanisms are largely responsible. This novel hypothesis is supported by molecular, cellular and behavioral evidence. By controlling the involved epigenetic mechanisms and targets we may make pain treatment safer and more effective for veterans and others suffering from chronic pain requiring ongoing opioid therapy.

Agency
National Institute of Health (NIH)
Institute
Veterans Affairs (VA)
Type
Non-HHS Research Projects (I01)
Project #
2I01BX000881-05A2
Application #
9021498
Study Section
Neurobiology A (NURA)
Project Start
2010-04-01
Project End
2020-03-31
Budget Start
2016-04-01
Budget End
2017-03-31
Support Year
5
Fiscal Year
2016
Total Cost
Indirect Cost
Name
Veterans Admin Palo Alto Health Care Sys
Department
Type
DUNS #
046017455
City
Palo Alto
State
CA
Country
United States
Zip Code
94304
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Donaldson, Robin; Sun, Yuan; Liang, De-Yong et al. (2016) The multiple PDZ domain protein Mpdz/MUPP1 regulates opioid tolerance and opioid-induced hyperalgesia. BMC Genomics 17:313
Nelson, E C; Agrawal, A; Heath, A C et al. (2016) Evidence of CNIH3 involvement in opioid dependence. Mol Psychiatry 21:608-14
Liang, De-Yong; Sun, Yuan; Shi, Xiao-You et al. (2014) Epigenetic regulation of spinal cord gene expression controls opioid-induced hyperalgesia. Mol Pain 10:59
Liang, De-Yong; Sun, Yuan; Clark, J David (2013) Dietary methyl content regulates opioid responses in mice. J Pain Res 6:281-7