The transduction of cutaneous stimuli has been previously thought to be solely a function of sensory fibers. It is now recognized that production of growth factors and neuroactivators (e.g., NGF, ATP, ACh, glutamate) by epidermal keratinocytes can have a profound effect on this process. To unravel these complex interactions and advance our understanding of the mechanisms regulating neural-keratinocyte communication, we developed optogenetic mouse models in which light activated channelrhodopsin (ChR2) is targeted to cutaneous sensory neurons. Light stimulation of the skin of these mice was found to elicit a robust nocifensive behavioral response. Electrophysiological analysis of this activation using a skin-nerve-ganglia and spinal cord ex vivo preparation showed preferential activation of C-fiber nociceptors. Thus, blue-laser light penetrates the epidermis and activates ChR2 at levels that depolarize peripheral nerve terminals. Interestingly, light activation of some neurons did not elicit response properties identical to those obtained using direct mechanical or thermal stimulation of the skin. We hypothesized this lack of a full response reflected a missing stimulus from the skin. We therefore isolated mice in which ChR2 was targeted exclusively to K14 keratin expressing keratinocytes. Remarkably, light stimulation of keratinocytes expressing ChR2 evoked changes in behavioral and electrophysiologic response properties of cutaneous sensory neurons. We also found that different subtypes of cutaneous afferents are activated at different levels suggesting heterogeneity in skin-neural communication. Using these new genetic models we propose three specific aims to advance these findings:
Aim 1 experiments will examine how light-induced release of neuroactivators (e.g., ATP) from ChR2- expressing keratinocytes activates subtypes of primary sensory afferents.
Aim 2 will determine how light activation of ChR2 or halorhodopsin expressed by subtypes of sensory afferents or keratinocytes affects afferent response properties. We will also determine how this activation compares to mechanical and/or thermal stimulation of the skin.
Aim 3 experiments will determine the contribution of changes in keratinocytes and sensory neurons to thermal and mechanical hyperalgesia in a model of inflammatory pain. These studies will determine if hyperalgesia is caused by changes in primary afferents, skin keratinocytes or both. The ability to control activation of either keratinocytes or sensory afferents will provide new insights into how the skin and sensory nervous system communicate under normal and inflamed conditions.

Public Health Relevance

The proposed studies will provide important new insights into how epithelial cells of the skin communicate with sensory nerve fibers that transmit touch, temperature and pain. These studies should also provide new knowledge about how keratinocyte activity modulates neuronal response properties under normal and inflamed conditions.

Agency
National Institute of Health (NIH)
Institute
National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS)
Type
Research Project (R01)
Project #
1R01AR069951-01
Application #
9095715
Study Section
Somatosensory and Chemosensory Systems Study Section (SCS)
Program Officer
Tseng, Hung H
Project Start
2016-04-01
Project End
2021-03-31
Budget Start
2016-04-01
Budget End
2017-03-31
Support Year
1
Fiscal Year
2016
Total Cost
Indirect Cost
Name
University of Pittsburgh
Department
Neurology
Type
Schools of Medicine
DUNS #
004514360
City
Pittsburgh
State
PA
Country
United States
Zip Code
15213
Ritter-Jones, Marsha; Najjar, Sarah; Albers, Kathryn M (2016) Keratinocytes as modulators of sensory afferent firing. Pain 157:786-7