Heidemarie Rossiter

Loss of Vascular Endothelial Growth Factor A Activity in Murine Epidermal Keratinocytes Delays Wound Healing and Inhibits Tumor Formation

The angiogenic cytokine vascular endothelial growth factor (VEGF)-A plays a central role in both wound healing and tumor growth. In the skin, epidermal keratinocytes are a major source of this growth factor. To study the contribution of keratinocyte-derived VEGF-A to these angiogenesis-dependent processes, we generated mice in which this cytokine was inactivated specifically in keratin 5-expressing tissues. The mutant mice were macroscopically normal, and the skin capillary system was well established, demonstrating that keratinocyte-derived VEGF-A is not essential for angiogenesis in the skin during embryonic development. However, healing of full-thickness wounds in adult animals was appreciably delayed compared with controls, with retarded crust shedding and the appearance of a blood vessel-free zone underneath the newly formed epidermis. When 9,12-dimethyl 1,2-benzanthracene was applied as both tumor initiator and promoter, a total of 143 papillomas developed in 20 of 23 (87%) of control mice. In contrast, only three papillomas arose in 2 of 17 (12%) of the mutant mice, whereas the rest merely displayed epidermal thickening and parakeratosis. Mutant mice also developed only 2 squamous cell carcinomas, whereas 11 carcinomas were found in seven of the control animals. These data demonstrate that whereas keratinocyte-derived VEGF-A is dispensable for skin vascularization under physiological conditions, it plays an important albeit nonessential role during epidermal wound healing and is crucial for the development of 9,12-dimethyl 1,2-benzanthracene-induced epithelial skin tumors.

Autophagy Is Induced by UVA and Promotes Removal of Oxidized Phospholipids and Protein Aggregates in Epidermal Keratinocytes

The skin is exposed to environmental insults such as UV light that cause oxidative damage to macromolecules. A centerpiece in the defense against oxidative stress is the Nrf2 (nuclear factor (erythroid-derived-2)-like 2)-mediated transcriptional upregulation of antioxidant and detoxifying enzymes and the removal of oxidatively damaged material. Autophagy has an important role in the intracellular degradation of damaged proteins and entire organelles, but its role in the epidermis has remained elusive. Here, we show that both UVA and UVA-oxidized phospholipids induced autophagy in epidermal keratinocytes. Oxidative stressors induced massive accumulation of high-molecular-weight protein aggregates containing the autophagy adaptor protein p62/SQSTM1 in autophagy-deficient (autophagy-related 7 (ATG7) negative) keratinocytes. Strikingly, even in the absence of exogenous stress, the expression of Nrf2-dependent genes was elevated in autophagy-deficient keratinocytes. Furthermore, we show that autophagy-deficient cells contained significantly elevated levels of reactive oxidized phospholipids. Thus, our data demonstrate that autophagy is crucial for both the degradation of proteins and lipids modified by environmental UV stress and for limiting Nrf2 activity in keratinocytes. Lipids that promote inflammation and tissue damage because of their reactivity and signaling functions are commonly observed in aged and diseased skin, and thus targeting autophagy may be a promising strategy to counteract the damage promoted by excessive lipid oxidation.

Epidermal Vascular Endothelial Growth Factor Production Is Required for Permeability Barrier Homeostasis, Dermal Angiogenesis, and the Development of Epidermal Hyperplasia : Implications for the Pathogenesis of Psoriasis

Primary abnormalities in permeability barrier function appear to underlie atopic dermatitis and epidermal trauma; a concomitant barrier dysfunction could also drive other inflammatory dermatoses, including psoriasis. Central to this outside-inside view of disease pathogenesis is the epidermal generation of cytokines/growth factors, which in turn signal downstream epidermal repair mechanisms. Yet, this cascade, if sustained, signals downstream epidermal hyperplasia and inflammation. We found here that acute barrier disruption rapidly stimulates mRNA and protein expression of epidermal vascular endothelial growth factor-A (VEGF-A) in normal hairless mice, a specific response to permeability barrier requirements because up-regulation is blocked by application of a vapor-impermeable membrane. Moreover, epidermal vegf(-/-) mice display abnormal permeability barrier homeostasis, attributable to decreased VEGF signaling of epidermal lamellar body production; a paucity of dermal capillaries with reduced vascular permeability; and neither angiogenesis nor epidermal hyperplasia in response to repeated tape stripping (a model of psoriasiform hyperplasia). These results support a central role for epidermal VEGF in the maintenance of epidermal permeability barrier homeostasis and a link between epidermal VEGF production and both dermal angiogenesis and the development of epidermal hyperplasia. Because psoriasis is commonly induced by external trauma [isomorphic (Koebner) phenomenon] and is associated with a prominent permeability barrier abnormality, excess VEGF production, prominent angiogenesis, and epidermal hyperplasia, these results could provide a potential outside-inside mechanistic basis for the development of psoriasis.

Overexpression of Bcl-2 Protects from Ultraviolet B-Induced Apoptosis but Promotes Hair Follicle Regression and Chemotherapy-Induced Alopecia

Hair follicle (HF) growth and regression is an exquisitely regulated process of cell proliferation followed by massive cell death and is accompanied by cyclical expression of the apoptosis regulatory gene pair, Bcl-2 and Bax. To further investigate the role of Bcl-2 expression in the control of hair growth and keratinocyte apoptosis, we have used transgenic mice that overexpress human Bcl-2 in basal epidermis and in the outer root sheath under the control of the human keratin-14 promoter (K14/Bcl-2). When irradiated with ultraviolet B (UVB) light, K14/Bcl-2 mice developed about 5-10-fold fewer sunburn cells (ie, apoptotic keratinocytes) in the basal layer of the epidermis, compared to wild-type mice, whereas cultures of primary keratinocytes from transgenic mice were completely resistant to UVB-induced histone formation, at doses that readily induced histone release from wild-type cells. K14/Bcl-2 mice show no alteration of neonatal hair follicle morphogenesis or of the onset of the first wave of HF regression (catagen). However, compared to wild-type controls, K14/Bcl-2 mice subsequently displayed a significant acceleration of spontaneous catagen progression. During chemotherapy-induced alopecia, follicular dystrophy was promoted in K14/Bcl-2 mice. Thus, although K14-driven overexpression of Bcl-2 protected murine epidermal keratinocytes from UVB-induced apoptosis, it surprisingly promoted catagen- and chemotherapy-associated keratinocyte apoptosis.

Epidermal keratinocytes form a functional skin barrier in the absence of Atg7 dependent autophagy

BACKGROUND Cornification of keratinocytes involves the degradation of intracellular constituents which has led to the hypothesis that autophagy plays a role in this process. Mice, in which essential autophagy-related genes such as Atg7 are deleted systemically, die after birth and have not been characterized for potential epidermal defects. OBJECTIVE This study tested whether autophagy is essential for epidermal barrier formation and function. METHODS Atg7 was inactivated in epidermal keratinocytes by the Cre-loxP system under the control of the keratin K14 promoter (Atg7Δepi mice). Autophagic activity was detected using the GFP-microtubule-associated protein light chain 3 (GFP-LC3) reporter construct and Western blot analysis of LC3. Epidermal morphology was examined by histological and ultrastructural analyses, and barrier functions were assessed by dye diffusion and water loss assays. RESULTS Suprabasal epidermal cells of normal mice contained GFP-LC3-labeled autophagosomes and epidermal lysates of these mice showed an excess of lipidated over non-lipidated LC3. These features of active autophagy were efficiently suppressed in Atg7Δepi epidermis. Atg7Δepi mice survived the perinatal period and were apparently healthy. Histologically, their epidermis was inconspicuous and ultrastructural analysis revealed no significant defect in cornification. There was however, an increase in the thickness of corneocytes in the back skin of mutant mice. Nevertheless, resistance to dye penetration into the skin and transepidermal water loss were normal in Atg7Δepi mice. CONCLUSION This study demonstrates that autophagy is constitutively active in the epidermis but not essential for the barrier function of the skin.

Essential role of the keratinocyte-specific endonuclease DNase1L2 in the removal of nuclear DNA from hair and nails

Degradation of nuclear DNA is a hallmark of programmed cell death. Epidermal keratinocytes die in the course of cornification to function as the dead building blocks of the cornified layer of the epidermis, nails, and hair. Here, we investigated the mechanism and physiological function of DNA degradation during cornification in vivo. Targeted deletion of the keratinocyte-specific endonuclease DNase1-like 2 (DNase1L2) in the mouse resulted in the aberrant retention of DNA in hair and nails, as well as in epithelia of the tongue and the esophagus. In contrast to our previous studies in human keratinocytes, ablation of DNase1L2 did not compromise the cornified layer of the epidermis. Quantitative PCRs showed that the amount of nuclear DNA was dramatically increased in both hair and nails, and that mitochondrial DNA was increased in the nails of DNase1L2-deficient mice. The presence of nuclear DNA disturbed the normal arrangement of structural proteins in hair corneocytes and caused a significant decrease in the resistance of hair to mechanical stress. These data identify DNase1L2 as an essential and specific regulator of programmed cell death in skin appendages, and demonstrate that the breakdown of nuclear DNA is crucial for establishing the full mechanical stability of hair.

Suppression of Autophagy Dysregulates the Antioxidant Response and Causes Premature Senescence of Melanocytes

Autophagy is the central cellular mechanism for delivering organelles and cytoplasm to lysosomes for degradation and recycling of their molecular components. To determine the contribution of autophagy to melanocyte (MC) biology, we inactivated the essential autophagy gene Atg7 specifically in MCs using the Cre-loxP system. This gene deletion efficiently suppressed a key step in autophagy, lipidation of microtubule-associated protein 1 light chain 3 beta (LC3), in MCs and induced slight hypopigmentation of the epidermis in mice. The melanin content of hair was decreased by 10-15% in mice with autophagy-deficient MC as compared with control animals. When cultured in vitro, MCs from mutant and control mice produced equal amounts of melanin per cell. However, Atg7-deficient MCs entered into premature growth arrest and accumulated reactive oxygen species (ROS) damage, ubiquitinated proteins, and the multi-functional adapter protein SQSTM1/p62. Moreover, nuclear factor erythroid 2-related factor 2 (Nrf2)-dependent expression of NAD(P)H dehydrogenase, quinone 1, and glutathione S-transferase Mu 1 was increased, indicating a contribution of autophagy to redox homeostasis in MCs. In summary, the results of our study suggest that Atg7-dependent autophagy is dispensable for melanogenesis but necessary for achieving the full proliferative capacity of MCs.

Targeted deletion of Atg5 reveals differential roles of autophagy in keratin K5-expressing epithelia

Autophagy contributes to the homeostasis of many tissues, yet its role in epithelia is incompletely understood. A recent report proposed that Atg5-dependent autophagy in thymic epithelial cells is essential for their function in the negative selection of self-reactive T-cells and, thus, for the suppression of tissue inflammation. Here we crossed mice carrying floxed alleles of the Atg5 gene with mice expressing the Cre recombinase under the control of the keratin K5 promoter to suppress autophagy in all K5-positive epithelia. The efficiency of autophagy abrogation was confirmed by immunoanalyses of LC3, which was converted to the autophagy-associated LC3-II form in normal but not Atg5-deficient cells, and of p62, which accumulated in Atg5-deficient cells. Mice carrying the epithelium-specific deletion of Atg5 showed normal weight gain, absence of tissue inflammation, and a normal morphology of the thymic epithelium. By contrast, autophagy-deficient epithelial cells of the preputial gland showed aberrant eosinophilic staining in histology and premature degradation of nuclear DNA during terminal differentiation. Taken together, the results of this study suggest that autophagy is dispensable for the suppression of autoimmunity by thymic epithelial cells but essential for normal differentiation of the preputial gland in mice.

Holocrine secretion of sebum is a unique DNase2-dependent mode of programmed cell death.

Sebaceous glands produce sebum via holocrine secretion, a largely uncharacterized mode of programmed cell death that contributes to the homeostasis and barrier function of the skin. To determine the mechanism of DNA degradation during sebocyte cell death, we have inactivated candidate DNA-degrading enzymes by targeted gene deletions in mice. DNase1 and DNase1-like 2 were dispensable for nuclear DNA degradation in sebocytes. By contrast, epithelial cell-specific deletion of lysosomal DNase2 blocked DNA degradation in these cells. DNA breakdown during sebocyte differentiation coincided with the loss of LAMP1 and was accelerated by the abrogation of autophagy, the central cellular program of lysosome-dependent catabolism. Suppression of DNA degradation by the deletion of DNase2 resulted in aberrantly increased concentrations of residual DNA and decreased amounts of the DNA metabolite uric acid in secreted sebum. These results define holocrine secretion as a DNase2-mediated form of programmed cell death and suggest that autophagy-dependent metabolism, DNA degradation, and the molecular composition of sebum are mechanistically linked.

Autophagy deficient melanocytes display a senescence associated secretory phenotype that includes oxidized lipid mediators

Autophagy is a recycling program which allows cells to adapt to metabolic needs and to stress. Defects in autophagy can affect metabolism, aging, proteostasis and inflammation. Autophagy pathway genes, including autophagy related 7 (Atg7), have been associated with the regulation of skin pigmentation, and autophagy defects disturb the biogenesis and transport of melanosomes in melanocytes as well as transfer and processing of melanin into keratinocytes. We have previously shown that mice whose melanocytes or keratinocytes lack Atg7 (and thus autophagy) as a result of specific gene knockout still retained functioning melanosome synthesis and transfer, and displayed only moderate reduction of pigmentation. In cell culture the Atg7 deficient melanocytes were prone to premature senescence and dysregulation of nuclear factor (erythroid-derived 2)-like 2 (Nrf2) signaling. To elucidate the biochemical basis of this phenotype, we performed a study on global gene expression, protein secretion and phospholipid composition in Atg7 deficient versus Atg7 expressing melanocytes. In cell culture Atg7 deficient melanocytes showed a pro-inflammatory gene expression signature and secreted higher levels of C-X-C motif chemokine ligand -1,-2,-10 and -12 (Cxcl1, Cxcl2, Cxcl10, Cxcl12), which are implicated in the pathogenesis of pigmentary disorders and expressed higher amounts of matrix metalloproteinases -3 and -13 (Mmp3, Mmp13). The analysis of membrane phospholipid composition identified an increase in the arachidonic- to linoleic acid ratio in the autophagy deficient cells, as well as an increase in oxidized phospholipid species that act as danger associated molecular patterns (DAMPs). The secretion of inflammation related factors suggests that autophagy deficient melanocytes display a senescence associated secretory phenotype (SASP), and we propose oxidized lipid mediators as novel components of this SASP.