The Desmoglein‐1 Transmembrane Domain Drives Lipid Raft Association and Desmosome Assembly

Abstract

The epidermis is a barrier to the outside world, but mutations in genes encoding desmosomal proteins can inhibit this function, causing human diseases of skin fragility. Severe dermatitis, multiple allergies, and metabolic wasting (SAM) syndrome is a severe homozygous recessive disorder of skin fragility caused by mutations in the gene encoding desmoglein 1 (DSG1), a component of desmosomes. Desmosomes are junctional complexes that function in mechanical stress resistance across tissues. In these junctions, desmosomal cadherins such as DSG1 interact across extracellular spaces and with intracellular adaptor proteins to link cytoskeletal elements of adjacent cells. Both assembly and disassembly of desmosomes have been shown to rely on lipid raft membrane microdomains, highly ordered cholesterol and sphingolipid‐enriched regions of the plasma membrane important in signaling and trafficking. Our current model predicts that raft association promotes clustering of desmosomal proteins to drive assembly and mediate adhesion. However, the mechanisms of raft association and desmosome assembly are not fully understood. We created a DSG‐null A431 cell line to examine the relationship between DSG raft association and desmosomal adhesion. A431s are an immortal human epidermal carcinoma cell line commonly used in desmosomal studies that express a single DSG species, DSG2. The absence of DSG2 in these cells was confirmed by western blot and immunofluorescence. Further characterization of these DSG‐null A431 cells revealed mislocalized desmoplakin, a marker of mature desmosomes, and a lack of strong cell‐cell adhesion. Exogenous stable expression of GFP‐tagged wildtype DSG1 (DSG1WT‐GFP) rescued both desmosome formation and function, suggesting that these DSG‐null cells would be suitable for probing the relationship between DSG raft association and desmosome assembly and function. Recently, we discovered a novel, heterozygous mutation in the transmembrane domain (TMD)‐encoding region of DSG1 that causes a glycine to arginine substitution and SAM syndrome. DSG1SAM is a lipid raft targeting mutant suggesting an important role for the TMD in raft association. Stable expression of DSG1SAM‐GFP could not rescue desmosome formation or function in the DSG‐null cells, suggesting that a loss of raft association also impacts desmosome assembly and adhesive function. Intriguingly, a chimeric DSG1 protein containing the TMD from E‐cadherin (DSG1Ecad‐GFP), a non‐raft associating adhesive protein, only partly rescued desmosome formation and function. Furthermore, these results correlated with the predicted lipid raft affinity of each TMD, suggesting that desmosome assembly and function is dependent on raft association. We are currently analyzing a panel of GFP‐tagged DSG1TMD variants with differential raft targeting affinities and assessing their ability to support desmosome assembly and function. In conclusion, the TMD targets desmogleins to lipid rafts and modulates desmoglein adhesive function.Support or Funding InformationNIH R01AR050501, NIH R01AR048266