Pain affects more Americans than does diabetes, heart disease and cancer combined. Opioids are a key drug class for pain treatment; however, there are significant drawbacks (e.g. CNS adverse effects, social and legal issues) that limit their use for effective management of pain. Consequently, development of novel approaches for improved pain control is a critically important research objective. To eliminate adverse CNS-derived effects, attention has turned to targeting peripherally located opioid receptors expressed on the pain-sensing neurons themselves. Importantly, the regulatory mechanisms of opioid receptor systems in peripheral sensory neurons are unique, and results obtained from studies in other systems (CNS, heterologous expression systems, etc.) do not always translate to peripheral sensory neurons. Thus, to understand opioid receptor function in peripheral sensory neurons, experiments must be done with peripheral sensory neurons. The goal of this project is to study the regulation of kappa opioid receptor (KOR) signaling systems in peripheral sensory neurons, using primary cultures of adult rat sensory neurons and a behavioral model of nociception.
Our specific aims are 1) To delineate the role of ERK in regulation of KOR function in peripheral sensory neurons; 2) To delineate the role of JNK in regulation of KOR function in peripheral sensory neurons; and 3) To delineate the role of acute desensitization in regulating KOR agonist efficacy in peripheral sensory neurons. Our overall goal is to increase the reliability and therapeutic efficacy of peripherally-restricted kappa opioid analgesic drugs. By understanding the cellular mechanisms that are involved in regulating the responsiveness of kappa opioid receptor systems on peripheral sensory neurons, improved approaches to treat pain can be developed that have improved therapeutic efficacy and are devoid of debilitating CNS-mediated adverse effects. The combination of rigorous mechanistic studies using primary sensory neurons in culture with the translational value of behavioral studies provides a powerful approach to understanding the regulation of kappa opioid receptor agonist efficacy in a physiologically relevant system and may lead to new approaches for improved pharmacotherapy for pain.
Pain affects millions of people in the United States and is poorly managed. Peripheral kappa opioid receptors may provide a novel and improved target for treatment of pain that is devoid of debilitating, dose-limiting, CNS-mediated adverse effects. In this application, we propose to identify cellular mechanisms which regulate kappa opioid receptor-mediated analgesia in peripheral sensory neurons with the ultimate goal of producing effective relief of pain.
