The central goal of this project is to define the mechanisms by which keratinocytes and sensory neurons communicate in vivo under naive conditions and after tissue injury, to convey mechanical information to the CNS. It is well known that sensory afferent fibers respond to external mechanical stimuli and convey this information to spinal cord circuits that project to brain regions. The peripheral terminals of cutaneous sensory neurons are largely assumed to be the sole site of transduction for evoked mechanical stimuli. However, cutaneous mechanical stimuli first impact keratinocytes which comprise 95% of the epidermis. Anatomically, keratinocytes are closely apposed to sensory nerve terminals and appear to make synapse-like contacts with them. Although isolated keratinocytes respond to mechanical stimuli, the in vivo roles of keratinocytes in detecting and conveying baseline mechanotransduction have not been investigated and are important for understanding normal cutaneous mechanotransduction. In the opposite direction, after tissue injury, peripheral sensory nerve terminals release neurotransmitters and neuropeptides that induce neurogenic inflammation by acting on multiple cell types including blood vessels and immune cells. Whether these neuronally-released molecules act on receptors on keratinocytes to contribute to the mechanical sensitization of primary afferent terminals in vivo during tissue injury has not been mechanistically investigated and is important because this process may contribute to sensitization during skin inflammation or disease. Our preliminary findings suggest that in non-injured skin, mechanical stimulation evokes local ATP release, and hydrolysis of cutaneous ATP elevates mechanical thresholds. Further, mechanically-evoked ATP release is increased after tissue injury, and P2X4 receptors are involved in the mechanical coding. From these data, we hypothesize that keratinocytes and cutaneous sensory neurons communicate with each other in a bidirectional manner. This proposal will explore the mechanisms of bidirectional signaling through two Specific Aims:
Aim 1 will test the hypothesis that the mechanical sensitivity of nave skin depends on ATP release from keratinocytes which signals through P2X4 receptors on sensory neurons.
Aim 2 will examine the hypothesis that the mechanical sensitization after tissue injury involves sensory neuron release of factors that act on keratinocyte NMDA or NK1 receptors, and amplify keratinocyte ATP release. These studies will illuminate basic touch transduction mechanisms, lay a foundation for understanding dysfunctional signaling processes during cutaneous inflammatory pain and disease, and potentially reveal targets for topical therapeutics that are easily applied and may limit CNS side effects.

Public Health Relevance

Skin covers nearly the entire body surface and the top layer of skin is comprised mostly of keratinocytes. In this proposal, we will investigate whether keratinocytes participate in conveying the mechanical signals of touch to sensory neurons, and whether keratinocytes respond after tissue injury to neuronally-released factors to amplify the sensitivity to touch.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
2R01NS040538-15A1
Application #
9125538
Study Section
Special Emphasis Panel (ZRG1)
Program Officer
Oshinsky, Michael L
Project Start
2000-07-01
Project End
2021-01-31
Budget Start
2016-02-15
Budget End
2017-01-31
Support Year
15
Fiscal Year
2016
Total Cost
Indirect Cost
Name
Medical College of Wisconsin
Department
Anatomy/Cell Biology
Type
Schools of Medicine
DUNS #
937639060
City
Milwaukee
State
WI
Country
United States
Zip Code
53226
Moehring, Francie; Halder, Priyabrata; Seal, Rebecca P et al. (2018) Uncovering the Cells and Circuits of Touch in Normal and Pathological Settings. Neuron 100:349-360
Cowie, Ashley M; Moehring, Francie; O'Hara, Crystal et al. (2018) Optogenetic Inhibition of CGRP? Sensory Neurons Reveals Their Distinct Roles in Neuropathic and Incisional Pain. J Neurosci 38:5807-5825
Sadler, Katelyn E; Zappia, Katherine J; O?Hara, Crystal L et al. (2018) Chemokine (c-c motif) receptor 2 mediates mechanical and cold hypersensitivity in sickle cell disease mice. Pain 159:1652-1663
Moehring, Francie; Cowie, Ashley M; Menzel, Anthony D et al. (2018) Keratinocytes mediate innocuous and noxious touch via ATP-P2X4 signaling. Elife 7:
Sadler, Katelyn E; Stucky, Cheryl L (2018) Neuronal transient receptor potential (TRP) channels and noxious sensory detection in sickle cell disease. Neurosci Lett 694:184-191
Moehring, Francie; Waas, Matthew; Keppel, Theodore R et al. (2018) Quantitative Top-Down Mass Spectrometry Identifies Proteoforms Differentially Released during Mechanical Stimulation of Mouse Skin. J Proteome Res 17:2635-2648
Miller, James J; Aoki, Kazuhiro; Moehring, Francie et al. (2018) Neuropathic pain in a Fabry disease rat model. JCI Insight 3:
Brandow, Amanda M; Hansen, Karla; Nugent, Melodee et al. (2018) Children and adolescents with sickle cell disease have worse cold and mechanical hypersensitivity during acute painful events. Pain :
Zappia, Katherine J; O'Hara, Crystal L; Moehring, Francie et al. (2017) Sensory Neuron-Specific Deletion of TRPA1 Results in Mechanical Cutaneous Sensory Deficits. eNeuro 4:
Xiang, Hongfei; Liu, Zhen; Wang, Fei et al. (2017) Primary sensory neuron-specific interference of TRPV1 signaling by AAV-encoded TRPV1 peptide aptamer attenuates neuropathic pain. Mol Pain 13:1744806917717040

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