Palmitoylation of Desmoglein 2 Is a Regulator of Assembly Dynamics and Protein Turnover.

Desmosomes are prominent adhesive junctions present between many epithelial cells as well as cardiomyocytes. The mechanisms controlling desmosome assembly and remodeling in epithelial and cardiac tissue are poorly understood. We recently identified protein palmitoylation as a mechanism regulating desmosome dynamics. In this study, we have focused on the palmitoylation of the desmosomal cadherin desmoglein-2 (Dsg2) and characterized the role that palmitoylation of Dsg2 plays in its localization and stability in cultured cells. We identified two cysteine residues in the juxtamembrane (intracellular anchor) domain of Dsg2 that, when mutated, eliminate its palmitoylation. These cysteine residues are conserved in all four desmoglein family members. Although mutant Dsg2 localizes to endogenous desmosomes, there is a significant delay in its incorporation into junctions, and the mutant is also present in a cytoplasmic pool. Triton X-100 solubility assays demonstrate that mutant Dsg2 is more soluble than wild-type protein. Interestingly, trafficking of the mutant Dsg2 to the cell surface was delayed, and a pool of the non-palmitoylated Dsg2 co-localized with lysosomal markers. Taken together, these data suggest that palmitoylation of Dsg2 regulates protein transport to the plasma membrane. Modulation of the palmitoylation status of desmosomal cadherins can affect desmosome dynamics

c-Src/Cav1-dependent activation of the EGFR by Dsg2.

The desmosomal cadherin, desmoglein 2 (Dsg2), is deregulated in a variety of human cancers including those of the skin. When ectopically expressed in the epidermis of transgenic mice, Dsg2 activates multiple mitogenic signaling pathways and increases susceptibility to tumorigenesis. However, the molecular mechanism responsible for Dsg2-mediated cellular signaling is poorly understood. Here we show overexpression as well as co-localization of Dsg2 and EGFR in cutaneous SCCs in vivo. Using HaCaT keratinocytes, knockdown of Dsg2 decreases EGFR expression and abrogates the activation of EGFR, c-Src and Stat3, but not Erk1/2 or Akt, in response to EGF ligand stimulation. To determine whether Dsg2 mediates signaling through lipid microdomains, sucrose density fractionation illustrated that Dsg2 is recruited to and displaces Cav1, EGFR and c-Src from light density lipid raft fractions. STED imaging confirmed that the presence of Dsg2 disperses Cav1 from the cell-cell borders. Perturbation of lipid rafts with the cholesterol-chelating agent MβCD also shifts Cav1, c-Src and EGFR out of the rafts and activates signaling pathways. Functionally, overexpression of Dsg2 in human SCC A431 cells enhances EGFR activation and increases cell proliferation and migration through a c-Src and EGFR dependent manner. In summary, our data suggest that Dsg2 stimulates cell growth and migration by positively regulating EGFR level and signaling through a c-Src and Cav1-dependent mechanism using lipid rafts as signal modulatory platforms

Enhancement of cutaneous wound healing by Dsg2 augmentation of uPAR secretion

In addition to playing a role in adhesion, desmoglein 2 (Dsg2) is an important regulator of growth and survival signaling pathways, cell proliferation, migration and invasion, and oncogenesis. While low-level Dsg2 expression is observed in basal keratinocytes and is downregulated in non-healing venous ulcers, overexpression has been observed in both melanomas and non-melanoma malignancies. Here, we show that transgenic mice overexpressing Dsg2 in basal keratinocytes primed the activation of mitogenic pathways, but did not induce dramatic epidermal changes or susceptibility to chemical-induced tumor development. Interestingly, acceleration of full-thickness wound closure and increased wound-adjacent keratinocyte proliferation was observed in these mice. As epidermal cytokines and their receptors play critical roles in wound healing, Dsg2-induced secretome alterations were assessed with an antibody profiler array and revealed increased release and proteolytic processing of the urokinase-type plasminogen activator receptor (uPAR). Dsg2 induced uPAR expression in the skin of transgenic compared to wild-type mice. Wound healing further enhanced uPAR in both epidermis and dermis with concomitant increase in the pro-healing laminin-332, a major component of the basement membrane zone, in transgenic mice. This study demonstrates that Dsg2 induces epidermal activation of various signaling cascades and accelerates cutaneous wound healing, in part, through uPAR-related signaling cascades

Intrinsic Networks Regulating Tissue Repair: Comparative Studies of Oral and Skin Wound Healing.

Wound repair is a systematic biological program characterized by four overlapping phases: hemostasis, inflammation, proliferation, and remodeling. Notwithstanding differences between species and distinct anatomical sites, the fundamental phases in the wound healing process are conserved among mammalian species. Oral wound healing is defined as an ideal wound healing model because it resolves rapidly and without scar formation. Understanding the regulation and contribution of the different molecular events that drive rapid wound healing in oral mucosa compared with those of the skin will help us define how these lesions heal more efficiently and may provide new therapeutic strategies that can be translated to the clinical settings for patients with chronic nonhealing wounds. Although all epithelial tissues have remarkable ability for tissue repair, the efficiency of such repair differs between epithelia (oral mucosa vs. cutaneous). This prompts the long-standing, fundamental biological and clinically relevant questions as to why and how does the oral mucosa achieve its enhanced wound healing capacity. In this review, we focus on (1) distinct innate wound healing capabilities of the oral mucosa, (2) lessons learned from comparative transcriptomic studies of oral mucosa versus skin, and (3) translation of findings to therapeutics for enhanced wound healing

Feasibility study for clinical application of caspase-3 inhibitors in Pemphigus vulgaris.

The potentially severe side effects of systemic corticosteroids and immunosuppressants used in Pemphigus vulgaris (PV) call for novel therapeutic approaches. In this context, pharmacological inhibition of major pathogenic signalling effectors represents a promising alternative. However, we have also shown that overinhibition of effectors required for epidermal homeostasis can exacerbate PV pathophysiology implicating transepidermal keratinocyte fragility. A feedforward target validation therefore preferentially includes studies on knockout mouse models. We previously reported on successful amelioration of PV blisters following inhibition of non-apoptotic, low-level caspase-3. Here, we use conditional, keratinocyte-specific caspase-3-deficient mice (casp3EKO ) to demonstrate (i) absence of keratinocyte fragility upon injection of the potent Dsg3-specific antibody AK23 and (ii) amelioration of blistering on the background of known signalling effectors. Our results provide the experimental proof of concept justifying translation of the caspase-3 inhibitor approach into PV clinical trials

Dsg2 increases exosome release and enhances EGFR/c-Src content: A mechanism for intercellular mitogenic effect

Abstract: Exosomes are nanoscale membrane-derived vesicles that are secreted by cancer cells and play a critical role in modulating the tumor microenvironment and disease pathogenesis. Dsg2, a desmosomal cadherin often overexpressed in skin malignancies including squamous cell carcinoma (SCC), can activate EGFR/c-Src signaling and promote oncogenesis. We sought to address the potential role of Dsg2 in exosome biogenesis and intercellular signaling in SCC. Here, purified exosomes from SCC cells and head/neck SCC patient sera were enriched with a processed 65 kDa membrane-associated C-terminal fragment of Dsg2. Cells overexpressing Dsg2 had increased exosome release and protein content and produced particles enriched with EGFR/c-Src, enhancing proliferation in recipient fibroblasts, compared to parental cell exosomes. This study suggests a mechanism by which SCC cells can promote intercellular signaling and modulate the tumor microenvironment through enhanced Dsg2 levels.https://jdc.jefferson.edu/dcbposters/1000/thumbnail.jp