Targeting SERCA2 in organotypic epidermis reveals MEK inhibition as a therapeutic strategy for Darier disease
Shivam A. Zaver, Mrinal K. Sarkar, Shaun Egolf, Jonathan Zou, Afua Tiwaa, Brian C. Capell, Johann E. Gudjonsson, Cory L. Simpson
Shivam A. Zaver, Mrinal K. Sarkar, Shaun Egolf, Jonathan Zou, Afua Tiwaa, Brian C. Capell, Johann E. Gudjonsson, Cory L. Simpson
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Research Article Dermatology

Targeting SERCA2 in organotypic epidermis reveals MEK inhibition as a therapeutic strategy for Darier disease

Abstract

Mutation of the ATP2A2 gene encoding sarco-endoplasmic reticulum calcium ATPase 2 (SERCA2) was linked to Darier disease more than 2 decades ago; however, there remain no targeted therapies for this disorder causing recurrent skin blistering and infections. Since Atp2a2-knockout mice do not phenocopy its pathology, we established a human tissue model of Darier disease to elucidate its pathogenesis and identify potential therapies. Leveraging CRISPR/Cas9, we generated human keratinocytes lacking SERCA2, which replicated features of Darier disease, including weakened intercellular adhesion and defective differentiation in organotypic epidermis. To identify pathogenic drivers downstream of SERCA2 depletion, we performed RNA sequencing and proteomics analysis. SERCA2-deficient keratinocytes lacked desmosomal and cytoskeletal proteins required for epidermal integrity and exhibited excess MAPK signaling, which modulates keratinocyte adhesion and differentiation. Immunostaining patient biopsies substantiated these findings, with lesions showing keratin deficiency, cadherin mislocalization, and ERK hyperphosphorylation. Dampening ERK activity with MEK inhibitors rescued adhesive protein expression and restored keratinocyte sheet integrity despite SERCA2 depletion or chemical inhibition. In sum, coupling multiomic analysis with human organotypic epidermis as a preclinical model, we found that SERCA2 haploinsufficiency disrupts critical adhesive components in keratinocytes via ERK signaling and identified MEK inhibition as a treatment strategy for Darier disease.

Authors

Shivam A. Zaver, Mrinal K. Sarkar, Shaun Egolf, Jonathan Zou, Afua Tiwaa, Brian C. Capell, Johann E. Gudjonsson, Cory L. Simpson

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Figure 1

Loss of SERCA2 in human keratinocytes impairs cytosolic calcium handling and reduces intercellular adhesive strength.

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Loss of SERCA2 in human keratinocytes impairs cytosolic calcium handling...
(A) Immunoblot of SERCA2 in lysates from ATP2A2 wild-type (WT, +/+), heterozygous (HET, +/-), and homozygous knockout (KO, -/-) cells. hTERT-immortalized human epidermal keratinocytes (THEKs) were differentiated in E-medium for 72 hours before lysate harvesting; data represent 3 independent experiments; and β-actin is a loading control. (B) Immunofluorescence of SERCA2 (green) in WT, HET, and KO THEKs; images are representative of 14 independent high-powered fields (hpf) per genotype; Hoechst (blue) stains nuclei; scale bar = 10 μm. (C) Mechanical dissociation of monolayers from control (+/+), HET (+/-), and KO (-/-) cells grown in 1.3 mM CaCl2 for 72 hours prior to using dispase to release intact monolayers; representative images of fragmented monolayers transferred into 6-well cell culture plates after mechanical stress are shown. (D) Graphs display mean ± SD of the number of epithelial fragments with data plotted for N = 3 biological replicates; P values from 1-way ANOVA with Dunnett’s adjustment for multiple comparisons. (E) Change (Δ) in intensity of GCaMP in control (+/+), HET (+/-), and KO (-/-) THEKs from baseline at t = 0 seconds with addition of 1 mM CaCl2 at t = 60 seconds (arrow); data plotted as mean ± SEM from N = 3 independent experiments per genotype. (F) Representative fluorescence images of GCaMP in WT, HET, and KO cells in low CaCl2 (left) or high CaCl2 (right); scale bar = 10 μm.