Project description:Opioid use is associated with worse outcome in HIV-infected patients. The exacerbated disease progression by opioids is mainly driven by increased epithelial damage and less regenerative response. The present study investigates how opioids potentiate HIV disease progression by impairing intestinal epithelial self-repair. Abnormal intestinal morphology and reduced epithelial proliferation were observed in HIV-infected humanized mice, which were exposed to opioids. For this study, we had 4 groups of BLT humanized mice- (A) Untreated, (B) Morphine treated, (C) HIV infected and (D) HIV infected + Morphine treated. HIV infection was done for 4 weeks and Morphine treatment was done for 7 days. Morphine treatment was done via subcutaneous implantation of slow-release morphine pellet in individual mouse in the appropriate groups. In other groups, a matching Placebo pellet was implanted.

Project description:Opioid analgesics are frequently prescribed in the United States and worldwide. However, serious side effects such as addiction, immunosuppression and gastrointestinal symptoms limit long term use. In the current study using a chronic morphine-murine model a longitudinal approach was undertaken to investigate the role of morphine modulation of gut microbiome as a mechanism contributing to the negative consequences associated with opioids use. The results revealed a significant shift in the gut microbiome and metabolome within 24 hours following morphine treatment when compared to placebo. Morphine induced gut microbial dysbiosis exhibited distinct characteristic signatures profiles including significant increase in communities associated with pathogenic function, decrease in communities associated with stress tolerance. Collectively, these results reveal opioids-induced distinct alteration of gut microbiome, may contribute to opioids-induced pathogenesis. Therapeutics directed at these targets may prolong the efficacy long term opioid use with fewer side effects.

Project description:Opioids are powerful analgesics but carry many contingencies that can lead to opioid-use disorder. Significant energy has been invested in understanding the molecular actions of the opioid alkaloids, particularly their relationship with the opioid receptors at the cell surface. However, there is growing awareness of the opioid-receptor-independent and intracellular actions of opioids that may contribute to their overall pharmacology. The investigation of these interactions is stymied by a lack of relevant opioid chemical tools to probe intracellular actions of the opioids. To investigate the intracellular interactions of the opioids, we designed and developed two opioid probes: photo-click morphine (PCM-2) as a photo-affinity probe for morphine and dialkynyl-acetyl morphine (DAAM) as a metabolic acetate reporter for heroin. Application of these probes to SH-SY5Y, HEK293T, and U2OS cells revealed that PCM-2 and DAAM primarily localize to the lysosome by confocal microscopy and chemical proteomics studies. Interaction site identification by mass spectrometry revealed the mitochondria phosphate carrier protein, solute carrier family 25 member 3, SLC25A3, and histone H2B as acetylation targets of DAAM. This study provides the first chemical probes for the study of the intracellular targets of opioid alkaloids.

Project description:Morphine and other opioids continue to be commonly utilized as clinical analgesics, despite their numerous adverse side effects, including respiratory depression, addiction, and tolerance. The modulation of µ-opioid receptor (MOR) signaling and subsequent behavioral output is one viable approach to improve opioid therapy. Heat shock protein 90 (Hsp90) is a molecular chaperone protein that has recently been implicated in downstream MOR signaling within the brain in mice. Here we identify a context-dependent impact on MOR signaling in which the inhibition of Hsp90 within the spinal cord promotes morphine induced anti-nociception. We show that intrathecal and not systemic administration of the Hsp90 inhibitors 17-AAG or KU-32 amplifies morphine-induced anti-nociception in both thermal and mechanical pain models. Further, we demonstrate that the inhibition of Hsp90 allows for ERK phosphorylation after opioid treatment. ERK activation was localized within the dorsal horns of the spinal cord, which are heavily populated with primary afferents responsible for nociception. The behavioral effects observed with Hsp90 inhibitors were abolished upon intrathecal U0126 (ERK inhibitor) and cycloheximide (translation inhibitor) treatment, suggesting that downstream ERK phosphorylation and rapid protein translation are responsible for the observed amplification of anti-nociception. Quantitative proteomic analysis identified upregulated RSK with spinal cord Hsp90 inhibition, which we further found was necessary for the observed enhancement of anti-nociception. Taken together, we have uncovered a novel downstream MOR ERK/RSK cascade, localized to the spinal cord and repressed by Hsp90, whose modulation may allow for enhanced efficacy and decreased side effects during opioid therapy.

Project description:A subpopulation of pericytes expressing the Glast-CreERT2 transgene (Type A pericytes) has recently been identified as the main source of stromal scar tissue that forms after SCI. Identification of molecules associated with pericyte-derived scarring may offer new therapeutic targets to facilitate axon regeneration following central nervous system (CNS) injury. We conducted genome-wide RNA sequencing of (i) uninjured spinal cord segments and (ii) lesion sites presenting full or attenuated pericyte-derived scarring 14 days after SCI.

Project description:Opioids analgesics are frequently prescribed in the United States and worldwide. However, serious side effects such as addiction, immunosuppression and gastrointestinal symptoms limit their use. It has been recently demonstrated that morphine treatment results in significant disruption in gut barrier function leading to increased translocation of gut commensal bacteria. Further study indicated distinct alterations in the gut microbiome and metabolome following morphine treatment, contributing to the negative consequences associated with opioid use. However, it is unclear how opioids modulate gut homeostasis in the context of a hospital acquired bacterial infection. In the current study, a mouse model of C. rodentium infection was used to investigate the role of morphine in the modulation of gut homeostasis in the context of a hospital acquired bacterial infection. Citrobacter rodentium is a natural mouse pathogen that models intestinal infection by enteropathogenic Escherichia coli (EPEC) and enterohemorrhagic E. coli (EHEC) and causes attaching and effacing lesions and colonic hyperplasia. Morphine treatment resulted in 1) the promotion of C. rodentium systemic dissemination, 2) increase in virulence factors expression with C. rodentium colonization in intestinal contents, 3) altered gut microbiome, 4) damaged integrity of gut epithelial barrier function, 5) inhibition of C. rodentium-induced increase in goblet cells, and 6) dysregulated IL-17A immune response. This is the first study to demonstrate that morphine promotes pathogen dissemination in the context of intestinal C. rodentium infection, indicating morphine modulates virulence factor-mediated adhesion of pathogenic bacteria and induces disruption of mucosal host defense during C. rodentium intestinal infection in mice. This study demonstrates and further validates a positive correlation between opioid drug use/abuse and increased risk of infections, suggesting over-prescription of opioids may increase the risk in the emergence of pathogenic strains and should be used cautiously. Therapeutics directed at maintaining gut homeostasis during opioid use may reduce the comorbidities associated with opioid use for pain management.

Project description:In addition to their intrinsic rewarding properties. opioids can also evoke aversive reactions that protect against misuse. Cellular mechanisms that govern the interplay between opioid reward and aversion are poorly understood. We used whole-brain activity mapping to show that neurons in the dorsal peduncular nucleus (DPn) are highly responsive to the opioid oxycodone. Connectomic profiling revealed that DPn neurons innervate the parabrachial nucleus (PBn). Spatial and single-nuclei transcriptomics resolved a unique population of PBn-projecting pyramidal neurons restricted to the DPn that express μ-opioid receptors (μORs). Disrupting μOR signaling in these neurons switched oxycodone from rewarding to aversive and exacerbated the severity of opioid withdrawal. These findings identify DPn neurons as key substrates for the abuse liability of opioids.

Project description:The spinal cord neural stem cell potential is contained within the ependymal cells lining the central canal. Ependymal cells are, however, heterogeneous and we know little about what this reflects. To gain new insights into ependymal cell heterogeneity, we microdissected the ependymal cell layer from the thoracic spinal cord of 4 FOXJ1-EGFP transgenic mice (2.5-to-3-month old). After after dissociating the tissue into a cell suspension, we sorted single GFP-positive ependymal cells into lysis plates. cDNA synthesis was performed using Smart-seq2 technology.

Project description:In settings of heightened pain sensitivity, such as following peripheral nerve injury (PNI) or opioid-induced hyperalgesia (OIH), microglia take on an activated phenotype. Functional studies have suggested that microglia activated by PNI or chronic opioids then engage common mechanisms to facilitate pain. Here we conducted RNA sequencing of acutely isolated spinal cord microglia to comprehensively interrogate commonality between PNI and OIH. By combining our results with meta-analysis of published datasets, we identify transcriptional signatures of microglial reactivity that differ between PNI models over time, opioid exposure, or CNS pathology, despite similar histological outcomes. Collectively, these results reveal a discrepancy between histological markers of activation and transcriptional response, and provide a resource of pain-associated microglial transcriptomes that caution against a universal signature of microglia activation.

Project description:In settings of heightened pain sensitivity, such as following peripheral nerve injury (PNI) or opioid-induced hyperalgesia (OIH), microglia take on an activated phenotype. Functional studies have suggested that microglia activated by PNI or chronic opioids then engage common mechanisms to facilitate pain. Here we conducted RNA sequencing of acutely isolated spinal cord microglia to comprehensively interrogate commonality between PNI and OIH. By combining our results with meta-analysis of published datasets, we identify transcriptional signatures of microglial reactivity that differ between PNI models over time, opioid exposure, or CNS pathology, despite similar histological outcomes. Collectively, these results reveal a discrepancy between histological markers of activation and transcriptional response, and provide a resource of pain-associated microglial transcriptomes that caution against a universal signature of microglia activation.