Animal Studies

Chronic abdominal pain is a common symptom of inflammatory bowel diseases (IBD). Peripheral and central mechanisms contribute to the transition from acute to chronic pain during active disease and clinical remission. Lower mechanical threshold and hyperexcitability of visceral afferents induce gliosis in central pain circuits, leading to persistent visceral hypersensitivity (VHS). In the spinal cord, microglia, the immune sentinels of the central nervous system, undergo activation in multiple models of VHS. Here we investigated the mechanisms of microglia activation to identify centrally acting analgesics for chronic IBD pain.

Whereas human spinal cord injury (SCI) is more common in men, the prevalence is growing in women. However, little is known about the effect of biological sex on brain dysfunction and injury mechanisms. To model the highest per capita rate of injury (ages between 16 and 30 years old) in humans, in the present study, young adult or a young/middle-aged male and female C57BL/6 mice were subjected to moderate contusion SCI. When mice were injured at 10-12-week-old, transcriptomic analysis of inflammation-related genes and flow cytometry revealed a more aggressive neuroinflammatory profile in male than females following 3 d SCI, ostensibly driven by sex-specific changes myeloid cell function rather than cell number. Female mice were generally more active at baseline, as evidenced by greater distance traveled in the open field. After SCI, female mice had more favorable locomotor function than male animals. At 13 weeks post-injury, male mice showed poor performance in cognitive and depressive-like behavioral tests, while injured female mice showed fewer deficits in these tasks. However, when injured at 6 months old followed by 8 months post-injury, male mice had considerably less inflammatory activation compared with female animals despite having similar or worse outcomes in affective, cognitive, and motor tasks. Collectively, these findings indicate that sex differences in functional outcome after SCI are associated with the age at onset of injury, as well as disrupted neuroinflammation not only at the site of injury but also in remote brain regions. Thus, biological sex should be considered when designing new therapeutic agents.

In this study, we investigated the effects of fosphenytoin (fPHT) a water-soluble prodrug of phenytoin, on the pain responses of a mouse herpes zoster (HZ) pain model. Transdermal herpes simplex virus type 1 (HSV-1) inoculation induced mechanical allodynia and hyperalgesia of the hind paw and spontaneous pain-like behaviors, such as licking the affected skin. Intravenous injection of fPHT (15 and 30 mg/kg) alleviated HSV-1-induced provoked pain (allodynia and hyperalgesia). The suppressive effects of fPHT on provoked pain were weaker than those of diclofenac and pregabalin which were used as positive controls. fPHT, diclofenac, and pregabalin significantly suppressed HSV-1-induced spontaneous pain-like behaviors. Among them, high-dose fPHT (30 mg/kg) showed the strongest suppression. Intravenous fPHT may become a viable option for an acute HZ pain, especially for spontaneous pain.

Chronic pain is a prevalent medical problem, and its molecular basis remains poorly understood. Here, we demonstrate the significance of the transmembrane protein (Tmem) 160 for nerve injury-induced neuropathic pain. An extensive behavioral assessment suggests a pain modality- and entity-specific phenotype in male Tmem160 global knockout (KO) mice: delayed establishment of tactile hypersensitivity and alterations in self-grooming after nerve injury. In contrast, Tmem160 seems to be dispensable for other nerve injury-induced pain modalities, such as non-evoked and movement-evoked pain, and for other pain entities. Mechanistically, we show that global KO males exhibit dampened neuroimmune signaling and diminished TRPA1-mediated activity in cultured dorsal root ganglia. Neither these changes nor altered pain-related behaviors are observed in global KO female and male peripheral sensory neuron-specific KO mice. Our findings reveal Tmem160 as a sexually dimorphic factor contributing to the establishment, but not maintenance, of discrete nerve injury-induced pain behaviors in male mice.

While opioids produce both analgesia and side-effects by action at mu-opioid receptors (MOR), at spinal and supraspinal sites, potency of different opioids to produce these effects vary. While it has been suggested that these differences might be due to bias for signaling via β-arrestin versus G protein alpha (Gα), recent studies suggest that G protein biased MOR agonists still produce clinically important side-effects. Since bias also exists in the role of Gα subunits, we evaluated the role of Gα subunits in analgesia, hyperalgesia, and hyperalgesic priming produced by fentanyl and morphine, in male rats. We found that intrathecal treatment with oligodeoxynucleotides antisense (AS-ODN) for Gα2, Gα3 and Gα markedly attenuated hyperalgesia induced by sub-analgesic dose (sub-AD) fentanyl, while AS-ODN for Gα1, as well as Gα2 and Gα3, but not Gα, prevented hyperalgesia induced by sub-AD morphine. AS-ODN for Gα1 and Gα2 unexpectedly analgesia induced by analgesic dose (AD) fentanyl, while Gα1 AS-ODN markedly AD morphine analgesia. Hyperalgesic priming, assessed by prolongation of prostaglandin E (PGE)-induced hyperalgesia, was not produced by systemic sub-AD and AD fentanyl in Gα3 and Gα AS-ODN-treated rats, respectively. In contrast, none of the Gα AS-ODNs tested affected priming induced by systemic sub-AD and AD morphine. We conclude that signaling by different Gα subunits is necessary for the analgesia and side-effects of two of the most clinically used opioid analgesics. Design of opioid analgesics that demonstrate selectivity for individual Gα may produce a more limited range of side-effects and enhanced analgesia. Biased mu-opioid receptor (MOR) agonists that preferentially signal through G proteins α-subunits over β-arrestins have been developed, as an approach to mitigate opioid side-effects. However, we recently demonstrated that biased MOR agonists also produce hyperalgesia and priming. We show that oligodeoxynucleotide antisense (AS-ODN) to different Gα subunits play a role in hyperalgesia and analgesia induced by sub-analgesic and analgesic dose (respectively), of fentanyl and morphine, as well as in priming. Our findings have the potential to advance our understanding of the mechanisms involved in adverse effects of opioid analgesics that could assist in the development of novel analgesics, preferentially targeting specific G protein α-subunits.

Non-steroidal anti-inflammatory drugs (NSAIDs) are the commonly used therapeutic interventions of inflammation and pain that competitively inhibit the cyclooxygenase (COX) enzymes. Several side effects like gastrointestinal and renal toxicities are associated with the use of these drugs. The therapeutic anti-inflammatory benefits of NSAIDs are produced by the inhibition of COX-2 enzymes, while undesirable side effects arise from the inhibition of COX-1 enzymes.

Bacterial products can act on neurons to alter signaling and function. In the present study, we found that dorsal root ganglion (DRG) sensory neurons are enriched for ANTXR2, the high-affinity receptor for anthrax toxins. Anthrax toxins are composed of protective antigen (PA), which binds to ANTXR2, and the protein cargoes edema factor (EF) and lethal factor (LF). Intrathecal administration of edema toxin (ET (PA + EF)) targeted DRG neurons and induced analgesia in mice. ET inhibited mechanical and thermal sensation, and pain caused by formalin, carrageenan or nerve injury. Analgesia depended on ANTXR2 expressed by Na1.8 or Advillin neurons. ET modulated protein kinase A signaling in mouse sensory and human induced pluripotent stem cell-derived sensory neurons, and attenuated spinal cord neurotransmission. We further engineered anthrax toxins to introduce exogenous protein cargoes, including botulinum toxin, into DRG neurons to silence pain. Our study highlights interactions between a bacterial toxin and nociceptors, which may lead to the development of new pain therapeutics.