Understanding the phenotypic similarities between IFAP and Olmsted syndrome from a molecular perspective: the interaction of MBTPS2 and TRPV3.

Ichthyosis Follicularis, Atrichia, and Photophobia (IFAP) is a severe rare genetic disorder caused by mutations in the gene encoding the Membrane-Bound Transcription Factor Peptidase, Site 2 (MBTPS2). Olmsted syndrome is another rare genetic disease with overlapping clinical features caused by mutations in the gene encoding the Transient Receptor Potential Cation Channel, subfamily V (TRPV3). Mutations in MBTPS2 have been recently reported in Olmsted syndrome, underscoring the overlap and the confusion in separating Olmsted from IFAP syndrome. We studied a Lebanese family with IFAP syndrome both, clinically and molecularly, and investigated whether there is a cross relation between TRPV3 and MBTPS2. We identified a recurrent mutation designated p.F475S in MBTPS2 in the affected individuals. This mutation was not found in 100 control individuals from the same population. We determined that TRPV3 regulatory region is a target for MBTPS2. In addition, there was an increased cell death in the cells transfected with the mutant versus the wild-type MBTPS2. In conclusion, we identified a direct regulatory effect of MBTPS2 on TRPV3 which can partially contribute to the overlapping clinical features of IFAP and Olmsted syndromes under a common signaling pathway.

Identification of several mutations in ATP2C1 in Lebanese families: insight into the pathogenesis of Hailey-Hailey disease.

BACKGROUND: Hailey-Hailey disease (HHD) is an inherited blistering dermatosis characterized by recurrent erosions and erythematous plaques that generally manifest in intertriginous areas. Genetically, HHD is an autosomal dominant disease, resulting from heterozygous mutations in ATP2C1, which encodes a Ca2+/Mn2+ATPase. In this study, we aimed at identifying and analyzing mutations in five patients from unrelated families diagnosed with HHD and study the underlying molecular pathogenesis. OBJECTIVES: To genetically study Lebanese families with HHD, and the underlying molecular pathogenesis of the disease. METHODS: We performed DNA sequencing for the coding sequence and exon-intron boundaries of ATP2C1. Heat shock experiments were done on several cell types. This was followed by real-time and western blotting for ATP2C1, caspase 3, and PARP proteins to examine any possible role of apoptosis in HHD. This was followed by TUNEL staining to confirm the western blotting results. We then performed heat shock experiments on neonatal rat primary cardiomyocytes. RESULTS: Four mutations were detected, three of which were novel and one recurrent mutation in two families. In order for HHD to manifest, it requires both the genetic alteration and the environmental stress, therefore we performed heat shock experiments on fibroblasts (HH and normal) and HaCaT cells, mimicking the environmental factor seen in HHD. It was found that stress stimuli, represented here as temperature stress, leads to an increase in the mRNA and protein levels of ATP2C1 in heat-shocked cells as compared to non-heat shocked ones. However, the increase in ATP2C1 and heat shock protein hsp90 is significantly lower in HH fibroblasts in comparison to normal fibroblasts and HaCaT cells. We did not find a role for apoptosis in the pathogenesis of HHD. A similar approach (heat shock experiments) done on rat cardiomyocytes, led to a significant variation in ATP2C1 transcript and protein levels. CONCLUSION: This is the first genetic report of HHD from Lebanon in which we identified three novel mutations in ATP2C1 and shed light on the molecular mechanisms and pathogenesis of HHD by linking stress signals like heat shock to the observed phenotypes. This link was also found in cultured cardiomyocytes suggesting thus a yet uncharacterized cardiac phenotype in HHD patients masked by its in-expressivity in normal health conditions.