ERK hyperactivation in epidermal keratinocytes impairs intercellular adhesion and drives Grover disease pathology
Cory L. Simpson, Afua Tiwaa, Shivam A. Zaver, Christopher J. Johnson, Emily Y. Chu, Paul W. Harms, Johann E. Gudjonsson
Cory L. Simpson, Afua Tiwaa, Shivam A. Zaver, Christopher J. Johnson, Emily Y. Chu, Paul W. Harms, Johann E. Gudjonsson
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Research Article Cell biology Dermatology

ERK hyperactivation in epidermal keratinocytes impairs intercellular adhesion and drives Grover disease pathology

Abstract

Grover disease is an acquired epidermal blistering disorder in which keratinocytes lose intercellular connections. While its pathologic features are well defined, its etiology remains unclear, and there is no FDA-approved therapy. Interestingly, Grover disease was a common adverse event in clinical trials for cancer using B-RAF inhibitors, but it remained unknown how B-RAF blockade compromised skin integrity. Here, we identified ERK hyperactivation as a key driver of Grover disease pathology. We leveraged a fluorescent biosensor to confirm that the B-RAF inhibitors dabrafenib and vemurafenib paradoxically activated ERK in human keratinocytes and organotypic epidermis, disrupting cell-cell junctions and weakening epithelial integrity. Consistent with clinical data showing that concomitant MEK blockade prevents Grover disease in patients receiving B-RAF inhibitors, we found that MEK inhibition suppressed ERK and rescued cohesion of B-RAF–inhibited keratinocytes. Validating these results, we demonstrated ERK hyperactivation in patient biopsies from vemurafenib-induced Grover disease and from spontaneous Grover disease, revealing a common etiology for both. Finally, in line with our recent identification of ERK hyperactivation in Darier disease, a genetic disorder with identical pathology to Grover disease, our studies uncovered that the pathogenic mechanisms of these diseases converge on ERK signaling and support MEK inhibition as a therapeutic strategy.

Authors

Cory L. Simpson, Afua Tiwaa, Shivam A. Zaver, Christopher J. Johnson, Emily Y. Chu, Paul W. Harms, Johann E. Gudjonsson

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Figure 2

B-RAF inhibition disrupts desmosomal protein localization in epidermal keratinocytes.

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B-RAF inhibition disrupts desmosomal protein localization in epidermal k...
(A) Immunoblot of classical cadherins (Pan-Cad), desmosomal cadherins (DSG1, DSG2, DSG3), and plakoglobin (PG) in lysates from NHEKs treated with dabrafenib (Dab) or Vemurafenib (Vem) ± Trametinib (Tram) for 24 hours; β-actin is a loading control. (B) Confocal immunofluorescence images of DSG3 (magenta) and PG (green) in NHEKs treated with the indicated compounds for 24 hours; Scale bar: 50 μm. (C) Line scans were performed in a blinded manner across the entire field of 6 confocal microscopy images (individually colored pink, orange, yellow, green, blue, or purple) for each drug condition; graphs depict PG fluorescence intensity of each pixel across the entire field of view with the largest peaks occurring as the line scan crosses properly formed cell-cell junctions. (D) Bar graph displays the mean ± SD of the net intensity of PG with individual data points representing the average intensity across n = 6 independent line scans from 3 biological replicates; mean intensity for DMSO was normalized to 1; P values are from 1-way ANOVA using the Bonferroni adjustment for multiple comparisons.