Your search keyword '"Ejoh LL"' showing total 5 results

1. Mimicking opioid analgesia in cortical pain circuits.

Author

James JG, McCall NM, Hsu AI, Oswell CS, Salimando GJ, Mahmood M, Wooldridge LM, Wachira M, Jo A, Sandoval Ortega RA, Wojick JA, Beattie K, Farinas SA, Chehimi SN, Rodrigues A, Ejoh LL, Kimmey BA, Lo E, Azouz G, Vasquez JJ, Banghart MR, Creasy KT, Beier KT, Ramakrishnan C, Crist RC, Reiner BC, Deisseroth K, Yttri EA, and Corder G

Abstract

The anterior cingulate cortex plays a pivotal role in the cognitive and affective aspects of pain perception. Both endogenous and exogenous opioid signaling within the cingulate mitigate cortical nociception, reducing pain unpleasantness. However, the specific functional and molecular identities of cells mediating opioid analgesia in the cingulate remain elusive. Given the complexity of pain as a sensory and emotional experience, and the richness of ethological pain-related behaviors, we developed a standardized, deep-learning platform for deconstructing the behavior dynamics associated with the affective component of pain in mice-LUPE (Light aUtomated Pain Evaluator). LUPE removes human bias in behavior quantification and accelerated analysis from weeks to hours, which we leveraged to discover that morphine altered attentional and motivational pain behaviors akin to affective analgesia in humans. Through activity-dependent genetics and single-nuclei RNA sequencing, we identified specific ensembles of nociceptive cingulate neuron-types expressing mu-opioid receptors. Tuning receptor expression in these cells bidirectionally modulated morphine analgesia. Moreover, we employed a synthetic opioid receptor promoter-driven approach for cell-type specific optical and chemical genetic viral therapies to mimic morphine's pain-relieving effects in the cingulate, without reinforcement. This approach offers a novel strategy for precision pain management by targeting a key nociceptive cortical circuit with on-demand, non-addictive, and effective analgesia., Competing Interests: Competing interests. G.C, K.D., C.R. and G.J.S. are inventors on a provisional patent application through the University of Pennsylvania and Stanford University regarding the custom sequences used to develop, and the applications of mMORp and hMORp constructs (patent application number: 63/383,462 462 ‘Human and Murine Oprm1 Promotes and Uses Thereof’).

Published

2024

2. A nociceptive amygdala-striatal pathway for chronic pain aversion.

Author

Wojick JA, Paranjapye A, Chiu JK, Mahmood M, Oswell C, Kimmey BA, Wooldridge LM, McCall NM, Han A, Ejoh LL, Chehimi SN, Crist RC, Reiner BC, Korb E, and Corder G

Abstract

The basolateral amygdala (BLA) is essential for assigning positive or negative valence to sensory stimuli. Noxious stimuli that cause pain are encoded by an ensemble of noci ceptive BLA projection neurons (BLA noci ensemble). However, the role of the BLA noci ensemble in mediating behavior changes and the molecular signatures and downstream targets distinguishing this ensemble remain poorly understood. Here, we show that the same BLA noci ensemble neurons are required for both acute and chronic neuropathic pain behavior. Using single nucleus RNA-sequencing, we characterized the effect of acute and chronic pain on the BLA and identified enrichment for genes with known functions in axonal and synaptic organization and pain perception. We thus examined the brain-wide targets of the BLA noci ensemble and uncovered a previously undescribed noci ceptive hotspot of the nucleus accumbens shell (NAcSh) that mirrors the stability and specificity of the BLA noci ensemble and is recruited in chronic pain. Notably, BLA noci ensemble axons transmit acute and neuropathic noci ceptive information to the NAcSh, highlighting this noci ceptive amygdala-striatal circuit as a unique pathway for affective-motivational responses across pain states., Competing Interests: B.C.R. receives research funding from Novo Nordisk and Boehringer Ingelheim that was not used in support of these studies. The other authors declare no competing interests.

Published

2024

3. Touch neurons underlying dopaminergic pleasurable touch and sexual receptivity.

Author

Elias LJ, Succi IK, Schaffler MD, Foster W, Gradwell MA, Bohic M, Fushiki A, Upadhyay A, Ejoh LL, Schwark R, Frazer R, Bistis B, Burke JE, Saltz V, Boyce JE, Jhumka A, Costa RM, Abraira VE, and Abdus-Saboor I

Subjects

Mice, Male, Female, Animals, Nucleus Accumbens metabolism, Sensory Receptor Cells metabolism, Skin metabolism, Reward, Dopaminergic Neurons metabolism, Optogenetics, Receptors, G-Protein-Coupled metabolism, Touch, Dopamine metabolism

Abstract

Pleasurable touch is paramount during social behavior, including sexual encounters. However, the identity and precise role of sensory neurons that transduce sexual touch remain unknown. A population of sensory neurons labeled by developmental expression of the G protein-coupled receptor Mrgprb4 detects mechanical stimulation in mice. Here, we study the social relevance of Mrgprb4-lineage neurons and reveal that these neurons are required for sexual receptivity and sufficient to induce dopamine release in the brain. Even in social isolation, optogenetic stimulation of Mrgprb4-lineage neurons through the back skin is sufficient to induce a conditioned place preference and a striking dorsiflexion resembling the lordotic copulatory posture. In the absence of Mrgprb4-lineage neurons, female mice no longer find male mounts rewarding: sexual receptivity is supplanted by aggression and a coincident decline in dopamine release in the nucleus accumbens. Together, these findings establish that Mrgprb4-lineage neurons initiate a skin-to-brain circuit encoding the rewarding quality of social touch., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2023

4. Optogenetic inhibition of the colon epithelium reduces hypersensitivity in a mouse model of inflammatory bowel disease.

Author

Najjar SA, Ejoh LL, Loeza-Alcocer E, Edwards BS, Smith-Edwards KM, Epouhe AY, Gold MS, Davis BM, and Albers KM

Subjects

Animals, Colon, Epithelium, Intestinal Mucosa, Mice, Inflammatory Bowel Diseases complications, Optogenetics

Abstract

Abstract: Visceral pain is a prevalent symptom of inflammatory bowel disease that can be difficult to treat. Pain and hypersensitivity are mediated by extrinsic primary afferent neurons (ExPANs) that innervate the colon. Recent studies indicate that the colon epithelium contributes to initiating ExPAN firing and nociceptive responses. Based on these findings, we hypothesized that the epithelium contributes to inflammation-induced hypersensitivity. A key prediction of this hypothesis is that inhibition of the epithelium would attenuate nociceptive signaling and inflammatory hypersensitivity. To test this hypothesis, the inhibitory yellow light-activated protein archaerhodopsin was targeted to the intestinal epithelium (villin-Arch) or the ExPANs (TRPV1-Arch) that innervate the colon. Visceral sensitivity was assessed by measuring the visceromotor response (VMR) to colorectal distension (CRD), with and without yellow light illumination of the colon lumen. Inhibition of the colon epithelium in healthy villin-Arch mice significantly diminished the CRD-induced VMR. Direct inhibition of ExPANs during CRD using TRPV1-Arch mice showed that ExPAN and epithelial inhibition were similarly effective in reducing the VMR to CRD. We then investigated the effect of epithelial and ExPAN inhibition in the dextran sulfate sodium model of inflammatory bowel disease. Inhibition of the colon epithelium significantly decreased dextran sulfate sodium-induced hypersensitivity and was comparable with the inhibition of ExPANs. Together, these results reveal the potential of targeting the colon epithelium for the treatment of pain., (Copyright © 2020 International Association for the Study of Pain.)

Published

2021

5. Sympathetic Input to Multiple Cell Types in Mouse and Human Colon Produces Region-Specific Responses.

Author

Smith-Edwards KM, Edwards BS, Wright CM, Schneider S, Meerschaert KA, Ejoh LL, Najjar SA, Howard MJ, Albers KM, Heuckeroth RO, and Davis BM

Subjects

Animals, Colon cytology, Colon drug effects, Colon physiology, Female, Ganglia, Sympathetic drug effects, Gastrointestinal Motility drug effects, Guanethidine pharmacology, Humans, Intestinal Mucosa cytology, Intestinal Mucosa drug effects, Intestinal Mucosa innervation, Intestinal Mucosa physiology, Male, Mice, Models, Animal, Myenteric Plexus cytology, Myenteric Plexus drug effects, Neurons drug effects, Neurons physiology, Optogenetics, Prazosin pharmacology, RNA-Seq, Single-Cell Analysis, Yohimbine pharmacology, Colon innervation, Ganglia, Sympathetic physiology, Gastrointestinal Motility physiology, Myenteric Plexus physiology

Abstract

Background & Aims: The colon is innervated by intrinsic and extrinsic neurons that coordinate functions necessary for digestive health. Sympathetic input suppresses colon motility by acting on intrinsic myenteric neurons, but the extent of sympathetic-induced changes on large-scale network activity in myenteric circuits has not been determined. Compounding the complexity of sympathetic function, there is evidence that sympathetic transmitters can regulate activity in non-neuronal cells (such as enteric glia and innate immune cells)., Methods: We performed anatomical tracing, immunohistochemistry, optogenetic (GCaMP calcium imaging, channelrhodopsin), and colon motility studies in mice and single-cell RNA sequencing in human colon to investigate how sympathetic postganglionic neurons modulate colon function., Results: Individual neurons in each sympathetic prevertebral ganglion innervated the proximal or distal colon, with processes closely opposed to multiple cell types. Calcium imaging in semi-intact mouse colon preparations revealed changes in spontaneous and evoked neural activity, as well as activation of non-neuronal cells, induced by sympathetic nerve stimulation. The overall pattern of response to sympathetic stimulation was unique to the proximal or distal colon. Region-specific changes in cellular activity correlated with motility patterns produced by electrical and optogenetic stimulation of sympathetic pathways. Pharmacology experiments (mouse) and RNA sequencing (human) indicated that appropriate receptors were expressed on different cell types to account for the responses to sympathetic stimulation. Regional differences in expression of α-1 adrenoceptors in human colon emphasize the translational relevance of our mouse findings., Conclusions: Sympathetic neurons differentially regulate activity of neurons and non-neuronal cells in proximal and distal colon to promote distinct changes in motility patterns, likely reflecting the distinct roles played by these 2 regions., (Copyright © 2021 AGA Institute. Published by Elsevier Inc. All rights reserved.)

Published

2021