Your search keyword '"Emrick, Joshua J."' showing total 2 results

1. A Cell-Penetrating Scorpion Toxin Enables Mode-Specific Modulation of TRPA1 and Pain

Author

Lin King, John V, Emrick, Joshua J, Kelly, Mark JS, Herzig, Volker, King, Glenn F, Medzihradszky, Katalin F, and Julius, David

Subjects

Biomedical and Clinical Sciences, Neurosciences, Pain Research, Chronic Pain, 1.1 Normal biological development and functioning, Animals, HEK293 Cells, Humans, Mice, Inbred C57BL, Rats, Sprague-Dawley, Scorpion Venoms, Scorpions, TRPA1 Cation Channel, TRP channels, TRPA1, cell-penetrating peptides, chemo-nociception, ion channel biophysics, neurogenic Inflammation, pain, peptide toxins, scorpion toxins, sensory physiology, Biological Sciences, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences

Abstract

TRPA1 is a chemosensory ion channel that functions as a sentinel for structurally diverse electrophilic irritants. Channel activation occurs through an unusual mechanism involving covalent modification of cysteine residues clustered within an amino-terminal cytoplasmic domain. Here, we describe a peptidergic scorpion toxin (WaTx) that activates TRPA1 by penetrating the plasma membrane to access the same intracellular site modified by reactive electrophiles. WaTx stabilizes TRPA1 in a biophysically distinct active state characterized by prolonged channel openings and low Ca2+ permeability. Consequently, WaTx elicits acute pain and pain hypersensitivity but fails to trigger efferent release of neuropeptides and neurogenic inflammation typically produced by noxious electrophiles. These findings provide a striking example of convergent evolution whereby chemically disparate animal- and plant-derived irritants target the same key allosteric regulatory site to differentially modulate channel activity. WaTx is a unique pharmacological probe for dissecting TRPA1 function and its contribution to acute and persistent pain.

Published

2019

2. Tissue-specific contributions of Tmem79 to atopic dermatitis and mast cell-mediated histaminergic itch

Author

Emrick, Joshua J, Mathur, Anubhav, Wei, Jessica, Gracheva, Elena O, Gronert, Karsten, Rosenblum, Michael D, and Julius, David

Subjects

Biochemistry and Cell Biology, Biomedical and Clinical Sciences, Biological Sciences, Neurosciences, Eczema / Atopic Dermatitis, 2.1 Biological and endogenous factors, Skin, Animals, Dermatitis, Atopic, Gene Deletion, HEK293 Cells, Humans, Keratinocytes, Membrane Proteins, Mice, Oxidative Stress, Pruritus, Sensory Receptor Cells, Signal Transduction, itch, atopic dermatitis, oxidative stress, Tmem79, prostaglandin E2

Abstract

Atopic dermatitis (AD) is the most common skin disease in children. It is characterized by relapsing inflammation, skin-barrier defects, and intractable itch. However, the pathophysiology of itch in AD remains enigmatic. Here, we examine the contribution of Tmem79, an orphan transmembrane protein linked to AD in both mice and humans. We show that Tmem79 is expressed by both keratinocytes and sensory neurons, but that loss of keratinocytic Tmem79 is sufficient to elicit robust scratching. Tmem79-/- mice demonstrate an accumulation of dermal mast cells, which are diminished following chronic treatment with cyclooxygenase inhibitors and an EP3 receptor antagonist. In Tmem79-/- mice, mast cell degranulation produces histaminergic itch in a histamine receptor 1/histamine receptor 4 (H4R/H1R)-dependent manner that may involve activation of TRPV1- afferents. TMEM79 has limited sequence homology to a family of microsomal glutathione transferases and confers protection from cellular accumulation of damaging reactive species, and may thus play a role in regulating oxidative stress. In any case, mechanistic insights from this model suggest that therapeutics targeting PGE2 and/or H1R/H4R histaminergic signaling pathways may represent useful avenues to treat Tmem79-associated AD itch. Our findings suggest that individuals with mutations in Tmem79 develop AD due to the loss of protection from oxidative stress.

Published

2018