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Mechanosensory and ATP release deficits following keratin14-cre-mediated TRPA1 deletion despite absence of TRPA1 in murine Keratinocytes

PLoS ONE (2016) 11(3)
DOI: 10.1371/journal.pone.0151602
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Abstract

Keratinocytes are the first cells that come into direct contact with external tactile stimuli; however, their role in touch transduction in vivo is not clear. The ion channel Transient Receptor Potential Ankyrin 1 (TRPA1) is essential for some mechanically-gated currents in sensory neurons, amplifies mechanical responses after inflammation, and has been reported to be expressed in human and mouse skin. Other reports have not detected Trpa1 mRNA transcripts in human or mouse epidermis. Therefore, we set out to determine whether selective deletion of Trpa1 from keratinocytes would impact mechanosensation. We generated K14Cre-Trpa1fl/fl mice lacking TRPA1 in K14-expressing cells, including keratinocytes. Surprisingly, Trpa1 transcripts were very poorly detected in epidermis of these mice or in controls, and detection was minimal enough to preclude observation of Trpa1 mRNA knockdown in the K14Cre-Trpa1fl/fl mice. Unexpectedly, these K14Cre-Trpa1fl/fl mice nonetheless exhibited a pronounced deficit in mechanosensitivity at the behavioral and primary afferent levels, and decreased mechanically-evoked ATP release from skin. Overall, while these data suggest that the intended targeted deletion of Trpa1 from keratin 14-expressing cells of the epidermis induces functional deficits in mechanotransduction and ATP release, these deficits are in fact likely due to factors other than reduction of Trpa1 expression in adult mouse keratinocytes because they express very little, if any, Trpa1.

Figures

  • Fig 1. Trpa1mRNA is poorly detected in mouse epidermal keratinocytes. (A) Following Cre-mediated recombination of genomic Trpa1 DNA, an excision product is amplified in the epidermis of K14Cre-Trpa1fl/fl mice (left), but not in the control (K14Cre-Trpa1+/+) mice. Mutant mice (K14Cre-Trpa1fl/fl) mice were either from an independently maintained colony (mutant-colony), or generated as littermates from heterozygous breeders (mutant—littermate). No excision product was observed in the DRGs of either control or mutant mice. Positive control band was obtained from DRG tissue from an AdvillinCreTrpa1fl/fl mouse (right). For panels B-F, mRNAwas isolated from DRG and epidermis from control mice. (B) Amplification plot showingGapdh and Trpa1
  • Fig 2. No Trpa1 knockdown is observed in epidermis of mutant (K14Cre-Trpa1fl/fl) mice compared to controls (K14Cre-Trpa1+/+). (A) Gene-specific primers to improve reverse transcription of Trpa1 were used prior to targeted amplification of Trpa1. This sensitive method detected a very small amount of Trpa1 transcripts within hindpaw epidermis, and the amplification was equivalent between control and mutant samples. (B-D) Quantitative digital-droplet PCR was performed on samples isolated from epidermis of control and mutant mice. (B) TRPV3 was efficiently detected in all samples tested. No template control (NTC) bars denote ddPCR performed with no cDNA added. (C) ddPCR for exons 23–24 of Trpa1 (within the loxp-flanked region) detected ample transcripts within the DRG samples. On average, less than one positive event per entire reaction volume was detected in both control and mutant samples. A control sample of DRG tissue from an AdvillinCre-Trpa1fl/fl mouse shows that Cre-mediated recombination in a different tissue (sensory neurons) reduces Trpa1mRNA detection (DRGAdv). (D) ddPCR for exons 12–13 detected on average less than one positive event per epidermal sample.N.d. denotes transcript not detected. **** P<0.0001, compared to every other bar.
  • Fig 3. Mutant mice (K14Cre-Trpa1fl/fl) exhibit decreased behavioral sensitivity to noxious and gentle mechanical stimuli. (A) Paw withdrawal responses revealed markedly elevated thresholds in mutant mice. (B) Mutant mice had significantly fewer responses to repeated application of a 3.31 mN von Frey filament. (C) Mutant mice responded less frequently to repeated applications of a spinal needle. (D). Mutant mice responded less frequently to repeated, punctate application of a 0.7 mN von Frey filament to the plantar hindpaw. (E) Mutant mice exhibited decreased responses to gentle stroking puffed-out cotton swab applied to the hindpaw. * P<0.05; *** P<0.001, **** P<0.0001. Data reported as mean ± s.e.m.
  • Fig 4. Mutant mice have normal behavioral thermal sensitivity. (A) Mutant and control mice did not differ in latency to respond to a heat lamp directed at the plantar hindpaw. (B-C) Mutant and control mice exhibited similar paw lift response latency to a cold plate at either 0°C (B) or 10°C (C). Data reported as mean ± s.e.m.N.s. denotes not significant.
  • Fig 5. Mutant mice exhibited decreased mechanically-evoked action potential firing.Glabrous skin-sural nerve preparations were dissected from mutant and control mice. (A) Examples of responses of single C fiber nociceptors to 40 and 100 mN stimuli, shown for both a control fiber (top) and a mutant fiber (bottom). (B) Average action potential firing rate of mutant fibers compared to control was significantly reduced in C fibers innervating glabrous skin. (C) Sample RA-Aβ fiber responses from control (top) and mutant (bottom) glabrous skin recordings at forces of 40 and 100 mN. (D) Mutant RA-Aβ fibers fired
  • Fig 6. Mutant mice exhibit minimal inflammatory allodynia and hyperalgesia two days after CFA injection. (A) Following injection of CFA into the hindpaw, control mice exhibited a marked increase in mechanical sensitivity following CFA injection into the hindpaw as indicated by the reduction in paw withdrawal threshold. In contrast, no changes in threshold were observed in mutant mice treated with CFA. After inflammation, there remained a striking
  • Fig 7. Cre recombinase activity was visualized in epidermal tissues ofK14Cre-tdTomato reporter mice. (A-B) tdTomato reporter fluorescence was observed in the epidermis of both glabrous and hairy skin sections, as expected. In glabrous skin, reporter fluorescence was also observed in sebaceous glands (arrowhead). Bottom row presents the lack of fluorescence in the tdTomatoLSL mice in the absence of the K14Cre allele. (C) No tdTomato reporter fluorescence was detected in the DRG of either control or mutant animals, suggesting no ectopic Cre recombinase activity was present in these sensory neurons. (D) Importantly, in the absence of the K14Cre allele, the Trpa1fl/fl mice did not show any mechanical sensory deficit compared to wildtype C57BL/6 mice. (E) Mutant animals from the same litters as controls exhibited significant elevated mechanical thresholds (littermate mutants vs. littermate controls). Furthermore, although there was a trend for the mutant animals from the independent colony to have an even greater mechanosensitivity deficit, their mechanical thresholds were not statistically different from those of littermate mutant animals (p = 0.0503). Analysis was performed via Kruskall-Wallis and a Dunn’s post hoc test. *** P< 0.001, **** P< 0.0001.
  • Fig 8. Decreasedmechanically- and chemically-evoked ATP release in mutant glabrous skin. (A) Example traces of ATP release transient measured from control (top) and mutant (bottom) glabrous skin in response to a 10s, 20 mNmechanical stimulation (applied when indicated by arrows). (B) Peak ATP measurements were markedly decreased from the mutant skin compared to control skin. ATP responses from both control and mutant skin were greatly reduced when performed using a calcium-free extracellular solution. (C) Sample ATP release traces in response to application of 1 mM cinnamaldehyde (CINN; indicated by green bars). (D) Chemically-induced ATP release was greatly reduced in glabrous skin of mutant animals. (E) Examples of ATP recordings from control and mutant glabrous skin excised frommice treated with either PBS or CFA. (F) Maximal ATP release was not significantly different between PBS and CFA-treated animals of either genotype; a single animal treated with CFA did show a substantially elevated peak ATP response. * P<0.05. Data reported as mean ± s.e.m.

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CITATION STYLE

APA

Zappia, K. J., Garrison, S. R., Palygin, O., Weyer, A. D., Barabas, M. E., Lawlor, M. W., … Stucky, C. L. (2016). Mechanosensory and ATP release deficits following keratin14-cre-mediated TRPA1 deletion despite absence of TRPA1 in murine Keratinocytes. PLoS ONE, 11(3). https://doi.org/10.1371/journal.pone.0151602

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