Price, Theodore J.
Permanent URI for this collectionhttps://hdl.handle.net/10735.1/4097
Theodore Price is an Associate Professor of Neuroscience. He is alos the head of the Pain Neurobiology Research Group. "Our laboratory is interested in the fundamental principles underlying pain plasticity. Our goal is to develop novel therapeutics based on these discoveries with the potential to either prevent the development of or permanently reverse chronic pain states. We focus on two major areas: 1) plasticity in peripheral nociceptive neurons following injury and, 2) plasticity in central nervous system circuits that results from persistent stimulation of peripheral nociceptors. We utilize molecular, biochemical, genetic, behavioral and electrophysiological techniques combined with an overarching interest in pharmacology and drug discovery to tackle this problem."
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Browsing Price, Theodore J. by Author "0000-0002-3768-6996 (Campbell, ZT)"
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Item Activation of the Integrated Stress Response in Nociceptors Drives Methylglyoxal-Induced Pain(Lippincott Williams & Wilkins, 2019-01) Barragan-Iglesias, Paulino; Kuhn, Jasper; Vidal-Cantu, Guadalupe C.; Belen Salinas-Abarca, Ana; Granados-Soto, Vinicio; Dussor, Gregory; Campbell, Zachary T.; Price, Theodore J.; 0000-0002-3768-6996 (Campbell, ZT); 0000-0002-6971-6221 (Price, TJ); Dussor, Gregory; Campbell, Zachary T.; Price, Theodore J.Methylglyoxal (MGO) is a reactive glycolytic metabolite associated with painful diabetic neuropathy at plasma concentrations between 500 nM and 5 μM. The mechanisms through which MGO causes neuropathic pain at these pathological concentrations are not known. Because MGO has been linked to diabetic neuropathic pain, which is prevalent and poorly treated, insight into this unsolved biomedical problem could lead to much needed therapeutics. Our experiments provide compelling evidence that ~ 1-μM concentrations of MGO activate the integrated stress response (ISR) in IB4-positive nociceptors in the dorsal root ganglion (DRG) of mice in vivo and in vitro. Blocking the integrated stress response with a specific inhibitor (ISRIB) strongly attenuates and reverses MGO-evoked pain. Moreover, ISRIB reduces neuropathic pain induced by diabetes in both mice and rats. Our work elucidates the mechanism of action of MGO in the production of pain at pathophysiologically relevant concentrations and suggests a new pharmacological avenue for the treatment of diabetic and other types of MGO-driven neuropathic pain.Item Emerging Neurotechnology for Antinoceptive Mechanisms and Therapeutics Discovery(Elsevier Advanced Technology, 2018-11-13) Black, Bryan J.; Atmaramani, Rahul; Plagens, Sarah; Campbell, Zachary T.; Dussor, Gregory; Price, Theodore J.; Pancrazio, Joseph J.; 0000-0002-3768-6996 (Campbell, ZT); 0000-0002-6971-6221 (Price, TJ); 0000-0001-8276-3690 (Pancrazio, JJ); Black, Bryan J.; Atmaramani, Rahul; Plagens, Sarah; Campbell, Zachary T.; Dussor, Gregory; Price, Theodore J.; Pancrazio, Joseph J.The tolerance, abuse, and potential exacerbation associated with classical chronic pain medications such as opioids creates a need for alternative therapeutics. Phenotypic screening provides a complementary approach to traditional target-based drug discovery. Profiling cellular phenotypes enables quantification of physiologically relevant traits central to a disease pathology without prior identification of a specific drug target. For complex disorders such as chronic pain, which likely involves many molecular targets, this approach may identify novel treatments. Sensory neurons, termed nociceptors, are derived from dorsal root ganglia (DRG) and can undergo changes in membrane excitability during chronic pain. In this review, we describe phenotypic screening paradigms that make use of nociceptor electrophysiology. The purpose of this paper is to review the bioelectrical behavior of DRG neurons, signaling complexity in sensory neurons, various sensory neuron models, assays for bioelectrical behavior, and emerging efforts to leverage microfabrication and microfluidics for assay development. We discuss limitations and advantages of these various approaches and offer perspectives on opportunities for future development.Item Nociceptor Translational Profiling Reveals the Ragulator-Rag GTPase Complex as a Critical Generator of Neuropathic Pain(Soc Neuroscience, 2019-01-16) Megat, Salim; Ray, Pradipta R.; Moy, Jamie K.; Lou, Tzu-Fang; Barragan-Iglesias, Paulino; Li, Yan; Pradhan, Grishma; Wanghzou, Andi; Ahmad, Ayesha; Burton, Michael D.; North, Robert Y.; Dougherty, Patrick M.; Khoutorsky, Arkady; Sonenberg, Nahum; Webster, Nevin R.; Dussor, Gregory; Campbell, Zachary T.; Price, Theodore J.; 0000-0003-4281-3985 (Pradhan, G); 0000-0002-0628-824X (Burton, MD); 0000-0002-3768-6996 (Campbell, ZT); 0000-0002-6971-6221 (Price, TJ); Megat, Salim; Ray, Pradipta R.; Moy, Jamie K.; Lou, Tzu-Fang; Barragan-Iglesias, Paulino; Pradhan, Grishma; Wanghzou, Andi; Ahmad, Ayesha; Burton, Michael D.; Dussor, Gregory; Campbell, Zachary T.; Price, Theodore J.Nociceptors, sensory neurons in the DRG that detect damaging or potentially damaging stimuli, are key drivers of neuropathic pain. Injury to these neurons causes activation of translation regulation signaling, including the mechanistic target of rapamycin complex 1 (mTORC1) and mitogen-activated protein kinase interacting kinase(MNK) eukaryotic initiation factor (eIF) 4E pathways. This is a mechanism driving changes in excitability of nociceptors that is critical for the generation of chronic pain states; however, the mRNAs that are translated to lead to this plasticity have not been elucidated. To address this gap in knowledge, we used translating ribosome affinity purification in male and female mice to comprehensively characterize mRNA translation in Scn10a-positive nociceptors in chemotherapy-induced neuropathic pain (CIPN) caused by paclitaxel treatment. This unbiased method creates a new resource for the field, confirms many findings in the CIPN literature and also find extensive evidence for new target mechanisms that may cause CIPN. We provide evidence that an underlying mechanism of CIPN is sustained mTORC1 activation driven by MNK1-eIF4E signaling. RagA, aGTPase controlling mTORC1 activity, is identified as a novel target of MNK1-eIF4E signaling. This demonstrates a novel translation regulation signaling circuit wherein MNK1-eIF4E activity drives mTORC1 via control of RagA translation. CIPN and RagA translation are strongly attenuated by genetic ablation of eIF4E phosphorylation, MNK1 elimination or treatment with the MNK inhibitor eFT508. We identify a novel translational circuit for the genesis of neuropathic pain caused by chemotherapy with important implications for therapeutics.