The EGF/TGFα Receptor in Skin

In responsive cells, all known effects of epidermal growth factor (EGF), transforming growth factor a (TGFα), and related proteins are mediated through binding to a specific membrane receptor. The EGF/TGFα receptor is a single- chain glycoprotein (1186 amino acids) containing three functional domains: 1) an extracellular, glycosylated portion that binds EGF; 2) a small transmembrane portion; and 3) a cytoplasmic portion that has the intrinsic tyrosine kinase activity and multiple sites that can be phosphorylated. When EGF binds to the receptor its intrinsic tyrosine kinase is activated, resulting in increased phosphorylation of intracellular tyrosine residues both on the receptor (autophosphorylation sites) and on exogenous proteins involved in regulating cellular functions. Site-specific mutagenesis has established that the tyrosine-kinase activity of the receptor is essential for nearly all of the effects of EGF including its ability to elevate cellular calcium levels and to induce DNA synthesis. The binding of EGF and the kinase activity of the receptor are both regulated by the phosphorylation of the receptor on specific threonine/serine sites catalyzed by other protein kinases. Specific lipids such as sphingosine also can regulate kinase activity. Tyrosine-specific phosphoprotein phosphatases and perhaps proteases must be important in terminating the cellular response to EGF. In human skin, the response to EGF/TGFα is determined by the location and number of receptors and is modulated by processes affecting the binding affinity, internalization, and tyrosine-kinase activity of the receptor. Specific patterns of EGF binding and of immunoreactive receptors characterize normal growth and differentiation and these are altered during the abnormal growth and differentiation associated with diseases such as psoriasis, viral infections, neoplasms, and paraneoplastic syndromes. It is not clear if the altered patterns reflect the consequence of the disease or are the cause of the disease. As a cause, the EGF receptor may have undetected point mutations that result in internalization and degradation defects, aberrant phosphorylation, and dephosphorylation or abnormal glycosylation

Visualization of Epidermal Growth Factor Receptors in Human Epidermis

The localization of epidermal growth factor (EGF) receptors in normal human epidermis was examined with two independent experimental methods. The distribution of EGF receptor sites was studied using light microscopic autoradiography with [125I]EGF and direct immunocytochemical techniques with EGF receptor antibodies and protein A-colloidal gold complexes. Direct visualization by autoradiography indicated that the concentration of EGF receptors was greatest in the lower epidermal layers. Ultrastructural morphometric analysis of protein A-gold complexes showed that EGF receptors were primarily associated with the plasma membranes although intranuclear and cytoplasmic localization was also evident. This postembedment immunolocalization method also confirmed the relative differences in the number of EGF receptors found in individual epidermal layers (basalis > spinosum > granulosum corneum layers). This inverse relationship between numbers of EGF receptors and the degree of epidermal differentiation and/or keratinization may suggest a physiologic role for EGF in these processes in human epidermis

Proteolytic Cleavage and Activation of pro-Macrophage-Stimulating Protein and Upregulation of its Receptor in Tissue Injury

Macrophage stimulating protein (MSP) exists in blood as inactive pro-MSP. Cleavage yields active MSP, the ligand for a membrane receptor (RON) that is expressed on keratinocytes as well as macrophages. Because both cells have roles in tissue injury, we looked for active MSP and expressed RON in wounds. Concentration of pro-MSP + MSP in wound exudates was in the range for optimal activity. Western blot showed that MSP comprised about half the total, in contrast to less than 10% of the total in blood plasma. The presence of MSP was attributed to an exudate pro-MSP convertase that had an inhibitor profile consistent with a trypsin-like serine protease. Exudate evoked morphologic changes in macrophages in vitro like that of MSP. Removal of this activity by an anti-MSP column shows that exudate stimulation of macrophages is due to MSP. RON was infrequently detected in normal skin. RON protein was markedly upregulated in burn wound epidermis and accessory structures, in proliferating cells or differentiated cells, or both. RON was also detected on macrophages and capillaries. Tissue injury leads to cleavage of pro-MSP to MSP, which has potential to act on keratinocytes, macrophages, and capillaries, all components of the wound healing response

Upregulation of 8-Lipoxygenase in the Dermatitis of IκB-α-Deficient Mice

Neonatal mice deficient in IκB-α, an inhibitor of the ubiquitous transcription factor NF-κB, develop severe and widespread dermatitis shortly after birth. In humans, inflammatory skin disorders such as psoriasis are associated with accumulation in the skin of the unusual arachidonic acid metabolite 12R-hydroxyeicosatetraenoic acid (12R-HETE), a product of the enzyme 12R-lipoxygenase. To examine the etiology of the murine IκB-α-deficient skin phenotype, we investigated the expression of lipoxygenases and the metabolism of exogenous arachidonic acid in the skin. In the IκB-α-deficient animals, the major lipoxygenase metabolite was 8S-HETE, formed together with a minor amount of 12S-HETE; 12R-HETE synthesis was undetectable. Skin from the wild-type littermates formed 12S-HETE as the almost exclusive lipoxygenase metabolite. Upregulation of 8S-lipoxygenase (8-LOX) in IκB-α-deficient mice was confirmed at the transcriptional and translational level using ribonuclease protection assay and western analysis. In immunohistochemical studies, increased expression of 8-LOX was detected in the stratum granulosum of the epidermis. In the stratum granulosum, 8-LOX may be involved in the terminal differentiation of keratinocytes. Although mouse 8S-lipoxygenase and human 12R-lipoxygenase are not ortholog genes, we speculate that in mouse and humans the two different enzymes may fulfill equivalent functions in the progression of inflammatory dermatoses

The tumorigenic and angiogenic effects of MGSA/GRO proteins in melanoma

Continuous expression of the MGSA/GROα, β, or γ chemokine bestows tumorâ forming capacity to the immortalized murine melanocyte cell line, melanâ a. The mechanism for this transformation is unclear, although both autocrine and paracrine processes are possible because melanâ a cells as well as endothelial cells express a low level of the receptor for this ligand. To further define the role of MGSA/GRO proteins in melanocyte transformation, two types of experiments were designed to neutralize the biological effects of MGSA/GRO in the transfected melanâ a clones: (1) the effect of neutralizing antiserum to MGSA/GRO proteins on melanâ a tumor growth was assessed; (2) the tumorâ forming capacity of melanâ a clones expressing ELR motifâ mutated forms of MGSA/GRO with compromised receptor affinity was compared to the tumorâ forming capacity of clones expressing wildâ type MGSA/GRO. These experiments revealed that SCID mice inoculated with MGSA/GROαâ or γâ expressing melanâ a cells and subsequently treated with antiserum to the respective chemokine exhibited decreased tumor growth. This reduction in tumor growth was accompanied by declining angiogenic activity in MGSA/GROγâ expressing tumors. Moreover, athymic nude mice injected with melanâ a cells expressing ELRâ mutant forms of MGSA/GROα exhibited markedly impaired tumorâ forming capacity compared with those mice injected with melanâ a clones expressing wildâ type MGSA/GRO. These data suggest that continuous expression of MGSA/GRO proteins may facilitate tumor growth by stimulating the growth of microvessels into the tumor (paracrine) and by affecting melanocyte growth (autocrine). J. Leukoc. Biol. 67: 53â 62; 2000.Peer Reviewedhttps://deepblue.lib.umich.edu/bitstream/2027.42/142059/1/jlb0053.pd

Overview of the Role for Calreticulin in the Enhancement of Wound Healing through Multiple Biological Effects

Calreticulin (CRT), an intracellular chaperone protein crucial for the proper folding and transport of proteins through the endoplasmic reticulum, has more recent acclaim as a critical regulator of extracellular functions, particularly in mediating cellular migration and as a requirement for phagocytosis of apoptotic cells. Consistent with these functions, we show that the topical application of CRT has profound effects on the process of wound healing by causing a dose-dependent increase in epithelial migration and granulation tissue formation in both murine and porcine normal and impaired animal models of skin injury. These effects of CRT are substantiated, in vitro, as we show that CRT strongly induces cell migration/wound closure of human keratinocytes and fibroblasts, using a wound/scratch plate assay, and stimulates cellular proliferation of human keratinocytes, fibroblasts, and vascular endothelial cells, providing mechanistic insight into how CRT functions in repair. Similarly, in both animal models, the histology of the wounds show marked proliferation of basal keratinocytes and dermal fibroblasts, dense cellularity of the dermis with notably increased numbers of macrophages and well-organized collagen fibril deposition. Thus, CRT profoundly affects the wound healing process by recruiting cells essential for repair into the wound, stimulating cell growth, and increasing extracellular matrix production

Epidermal and Dermal Effects of Epidermal Growth Factor During Wound Repair

Epidermal growth factor (EGF), a well-characterized peptide that stimulates in vitro cell proliferation, has now been shown to enhance in vivo resurfacing of porcine wounds. Topical formulations containing either recombinant EGF or placebo were applied daily to partial-thickness wounds along the dorsal surface of pigs. Following full-thickness removal of these wounds, tissues were sectioned and stained, and histologic sections were subjected to computerized morphometric analysis. A significant acceleration of epithelialization across the wound surface was noted following daily EGF treatments. EGF delivered in a variety of topical formulations also produced a marked increase in the cellularity and thickness in the neodermis. A dose-responsive increase in the thickness of the granulation tissue was also observed. In conclusion, topical application of EGF stimulates epithelialization of partial-thickness wounds and produces a positive impact on the underlying dermis during the early phases of wound repair

Skin and adnexa.

The skin is the largest organ of the body based on surface area, although the muscles and bones have more mass. One of its primary functions is as a barrier against desiccation and the hostilities of microbial invaders from the outside world. Chapter 24, In: Treuting PM, Dintzis SM, Montine KS, eds. Comparative Anatomy and Histology, 2nd ed. 2018:511-542