Editorial: Novel Molecular Targets for the Treatment of Pain

Abstract

Editorial on the Research Topic Novel Molecular Targets for the Treatment of Pain The chronic pain and opioid epidemics are two interdependent public health crises that have challenged the United States, in particular, and the world in general for more than 20 years. Chronic pain affects more than 100 million people in the USA, is growing in incidence as the population ages, can severely impact patient quality of life, and has economic costs of more than $600 billion in the USA alone (Breivik et al., 2009; Gaskin and Richard, 2012). In response, opioid prescribing has risen rapidly for two decades, resulting in an opioid abuse and overdose crisis that claims more than 40,000 lives annually in the USA (Lozano et al., 2012; Warner et al., 2016). These twin crises highlight the vast medical and social need to develop new treatments for chronic pain that are non-opioid or mitigate the negative effects of opioid therapy. However, despite a rapid increase in our understanding of the basic science of the pain and opioid systems, this knowledge has not yet translated into new therapies (Woodcock et al., 2007; Olson et al., 2017). By identifying new targets and new approaches to treat pain, we may be able to design new therapies to efficaciously treat chronic pain without the drawbacks of current opioid therapies. This collection of novel basic science research articles titled “Novel Molecular Targets for the Treatment of Pain” is intended to stimulate research into these novel targets by the scientific community, which could then lead to the clinical development of new drugs. This collection naturally falls into several themes, the first of which is novel regulation of the mu opioid receptor (MOR), the primary target of clinical opioids like morphine (Matthes et al., 1996; Olson et al., 2019). Original research from the Briddon and Canals groups demonstrated novel molecular events for the MOR after stimulation by the high efficacy agonist DAMGO; understanding of exactly how the MOR desensitizes and internalizes could lead to new methods to manipulate this process to improve opioid therapy (Gondin et al.). Several review articles also highlighted new areas of research into MOR regulation. The Filizola group reviewed recent advances in modeling the MOR activation process using molecular dynamics simulation (Ribeiro and Filizola). The Traynor group reviewed the role of Regulator of G Protein Signaling (RGS) proteins in regulating MOR activation, including the use of novel inhibitors to produce opioid-sparing or enhancement of endogenous opioid activity (Senese et al.). Lastly, the Veldhuis group reviewed exciting recent advances in separating membrane from internalized receptor signaling, how internalized signaling contributes to pain states, and how these disparate signaling states can be targeted by location-biased drugs (Retamal et al.). The next major theme consisted of targeting other anti-nociceptive receptor systems to achieve pain relief without the side effects of MOR stimulation, particularly addiction, and respiratory depression. The Massotte group used elegant peripherally-restricted knockout of the delta opioid receptor (DOR) to demonstrate that the β2-adrenergic agonist formoterol produced efficacious anti-nociception in a neuropathic pain model via peripheral DOR (Ceredig et al.). This finding suggests that formoterol could be re-purposed from its current use as an adrenergic agonist as a novel non-opioid analgesic. The DOR has been a target of great interest for some time due to its ability to produce anti-nociception without addiction or respiratory depression, especially in inflammatory pain states. An overview of the DOR in pain and how it can be targeted in the future was written by the Gendron group, with a special emphasis on DOR intracellular trafficking, which strongly impacts receptor competency to relieve pain (Quirion et al.). The DOR has been implicated in other uses as well, such as the treatment of migraine pain (Charles and Pradhan, 2016). Another alternate receptor system of interest is the cannabinoid receptor type-1 (CB₁R). The CB₁R can also produce anti-nociception, and while it can have unwanted psychoactive side effects, these side effects do not rise to the severity of addiction and respiratory depression caused by opioids (Rabgay et al., 2020). The CB₁R is also the main target of the phytocannabinoid Δ9-tetrahydrocannabinol from the plant Cannabis sativa, and is thus of great interest considering the growth in recreational and medicinal marijuana (Morales et al., 2017). A study in this collection from the Laprairie group found that the non-steroidal anti-inflammatory drug indomethacin acts as a positive allosteric modulator of the CB₁R (Laprairie et al.). This finding establishes a new CB₁R drug scaffold for the creation of novel therapeutics. The third theme of our collection is inflammatory regulation, which can contribute to both pain and the side effects of opioid drugs (Okun et al., 2011; Pan et al., 2016). Original research from the Schmidt group showed that granulocyte-colony stimulating factor (G-CSF) induced the recruitment of Ly6G positive neutrophils to the site of oral cancer, which released endogenous opioids to prevent or block oral cancer pain (Scheff et al.). This suggests that G-CSF could be used as a novel therapeutic for oral cancers. Work from the Jang-Hern Lee group showed that interleukin-1β was released in the early stages of spinal cord neuropathic pain to repress P450c17 expression and slow the development of neuropathic pain (Choi et al.), suggesting that enhancing activity of this pathway could slow or prevent the development of neuropathy. Lastly, the Laumet group provided a comprehensive review of the role of T cells in pain, including in the transition to chronic pain and resolution of pain, suggesting...