Leopold Eckhart

Human caspase 12 has acquired deleterious mutations

Caspase 12 has been cloned from rodent cells, in which it mediated apoptosis in response to endoplasmic reticulum stress. Based on experiments with murine cells it was suggested that this caspase plays a central role in the pathogenesis of Alzheimers disease. By alignment of the murine caspase 12 cDNA with the human genome sequence we localized the human caspase 12 gene at a single locus within the caspase 1/ICE gene cluster on chromosome 11q22.3. RT-PCR and molecular cloning revealed that nine alternatively spliced transcripts of this gene are expressed. A frame shift mutation and a premature stop codon which is present in all splice variants preclude the expression of a full length protein. An additional loss-of-function mutation within the SHG box, a critical site in caspases, prohibits any proteins, if they are produced, from acting catalytically. Based on our data we conclude that functional caspase 12 is lost in humans and that it can therefore not play a role in Alzheimers disease.

miR-17, miR-19b, miR-20a, and miR-106a are down-regulated in human aging.

Aging is a multifactorial process where deterioration of body functions is driven by stochastic damage while counteracted by distinct genetically encoded repair systems. To better understand the genetic component of aging, many studies have addressed the gene and protein expression profiles of various aging model systems engaging different organisms from yeast to human. The recently identified small non‐coding miRNAs are potent post‐transcriptional regulators that can modify the expression of up to several hundred target genes per single miRNA, similar to transcription factors. Increasing evidence shows that miRNAs contribute to the regulation of most if not all important physiological processes, including aging. However, so far the contribution of miRNAs to age‐related and senescence‐related changes in gene expression remains elusive. To address this question, we have selected four replicative cell aging models including endothelial cells, replicated CD8+ T cells, renal proximal tubular epithelial cells, and skin fibroblasts. Further included were three organismal aging models including foreskin, mesenchymal stem cells, and CD8+ T cell populations from old and young donors. Using locked nucleic acid‐based miRNA microarrays, we identified four commonly regulated miRNAs, miR‐17 down‐regulated in all seven; miR‐19b and miR‐20a, down‐regulated in six models; and miR‐106a down‐regulated in five models. Decrease in these miRNAs correlated with increased transcript levels of some established target genes, especially the cdk inhibitor p21/CDKN1A. These results establish miRNAs as novel markers of cell aging in humans.

Knockdown of Filaggrin Impairs Diffusion Barrier Function and Increases UV Sensitivity in a Human Skin Model

Loss-of-function mutations in the filaggrin gene are associated with ichthyosis vulgaris and atopic dermatitis. To investigate the impact of filaggrin deficiency on the skin barrier, filaggrin expression was knocked down by small interfering RNA (siRNA) technology in an organotypic skin model in vitro. Three different siRNAs each efficiently suppressed the expression of profilaggrin and the formation of mature filaggrin. Electron microscopy revealed that keratohyalin granules were reduced in number and size and lamellar body formation was disturbed. Expression of keratinocyte differentiation markers and the composition of lipids appeared normal in filaggrin-deficient models. The absence of filaggrin did not render keratins 1, 2, and 10 more susceptible to extraction by urea, arguing against a defect in aggregation. Despite grossly normal stratum corneum morphology, filaggrin-deficient skin models showed a disturbed diffusion barrier function in a dye penetration assay. Moreover, lack of filaggrin led to a reduction in the concentration of urocanic acid, and sensitized the organotypic skin to UVB-induced apoptosis. This study thus demonstrates that knockdown of filaggrin expression in an organotypic skin model reproduces epidermal alterations caused by filaggrin mutations in vivo. In addition, our results challenge the role of filaggrin in intermediate filament aggregation and establish a link between filaggrin and endogenous UVB protection.

Cell death by cornification

Epidermal keratinocytes undergo a unique form of terminal differentiation and programmed cell death known as cornification. Cornification leads to the formation of the outermost skin barrier, i.e. the cornified layer, as well as to the formation of hair and nails. Different genes are expressed in coordinated waves to provide the structural and regulatory components of cornification. Differentiation-associated keratin intermediate filaments form a complex scaffold accumulating in the cytoplasm and, upon removal of cell organelles, fill the entire cell interior mainly to provide mechanical strength. In addition, a defined set of proteins is cross-linked by transglutamination in the cell periphery to form the so-called cornified envelope. Extracellular modifications include degradation of the tight linkages between corneocytes by excreted proteases, which allows corneocyte shedding by desquamation, and stacking and modification of the excreted lipids that fill the intercellular spaces between corneocytes to provide a water-repellant barrier. In hard skin appendages such as hair and nails these tight intercorneocyte connections remain permanent. Various lines of evidence exist for a role of organelle disintegration, proteases, nucleases, and transglutaminases contributing to the actual cell death event. However, many mechanistic aspects of kearatinocyte death during cornification remain elusive. Importantly, it has recently become clear that keratinocytes activate anti-apoptotic and anti-necroptotic pathways to prevent premature cell death during terminal differentiation. This review gives an overview of the current concept of cornification as a mode of programmed cell death and the anti-cell death mechanisms in the epidermis that secure epidermal homeostasis. This article is part of a Special Section entitled: Cell Death Pathways.

Histamine suppresses epidermal keratinocyte differentiation and impairs skin barrier function in a human skin model

Defects in keratinocyte differentiation and skin barrier are important features of inflammatory skin diseases like atopic dermatitis. Mast cells and their main mediator histamine are abundant in inflamed skin and thus may contribute to disease pathogenesis.

Increased Sensitivity of Histidinemic Mice to UVB Radiation Suggests a Crucial Role of Endogenous Urocanic Acid in Photoprotection

Urocanic acid (UCA) is produced by the enzyme histidase and accumulates in the stratum corneum of the epidermis. In this study, we investigated the photoprotective role of endogenous UCA in the murine skin using histidinemic mice, in which the gene encoding histidase is mutated. Histidase was detected by immunohistochemistry in the stratum granulosum and stratum corneum of the normal murine skin but not in the histidinemic skin. The UCA content of the stratum corneum and the UVB absorption capacity of aqueous extracts from the stratum corneum were significantly reduced in histidinemic mice as compared with wild-type mice. When the shaved back skin of adult mice was irradiated with 250 mJ cm(-2) UVB, histidinemic mice accumulated significantly more DNA damage in the form of cyclobutane pyrimidine dimers than did wild-type mice. Furthermore, UVB irradiation induced significantly higher levels of markers of apoptosis in the epidermis of histidinemic mice. Topical application of UCA reversed the UVB-photosensitive phenotype of histidinemic mice and increased UVB photoprotection of wild-type mice. Taken together, these results provide strong evidence for an important contribution of endogenous UCA to the protection of the epidermis against the damaging effects of UVB radiation.

Retinoic Acid Increases the Expression of p53 and Proapoptotic Caspases and Sensitizes Keratinocytes to Apoptosis A Possible Explanation for Tumor Preventive Action of Retinoids

Retinoids influence growth and differentiation of keratinocytes (KCs) and are widely used for the management of skin diseases and for prevention of nonmelanoma skin cancer (NMSC) in predisposed patients. Here we investigated the effect of all-trans-retinoic acid (ATRA) on KC apoptosis. When KCs were cultured in confluent monolayers for several days, they acquired resistance against UVB-induced apoptosis. In contrast, when the cells were treated with 1 μmol/L ATRA for 6 days and subsequently irradiated with different doses of UVB, they underwent massive apoptosis as assessed by morphology, expression of activated caspase-3, and DNA fragmentation. The same effect was observed when doxorubicin was used instead of UVB. Analysis by real-time PCR and Western blot revealed that ATRA treatment strongly increased the mRNA and protein expression of p53 and caspase-3, -6, -7, and -9, which are key regulators of apoptosis. UVB irradiation of ATRA-treated cells but not of control cells led to the accumulation of p53 protein and of its target gene Noxa. Inhibition of p53 and caspases with α-pifithrin and z-Val-Ala-Asp-fluoromethyl ketone, respectively, blocked UVB- and doxorubicin-induced apoptosis in ATRA-treated KCs. Analogous to the observed ATRA effects in monolayer cultures, in vitro-generated organotypic skin cultures reacted with up-regulation of p53 and proapoptotic caspases and displayed increased sensitivity to UVB-induced apoptosis. The ability of retinoic acid to regulate the expression of proapoptotic genes and to sensitize KCs to apoptosis may play a role in their prevention of NMSC in transplant patients and patients with DNA-repair deficiencies.

Flagellin is the principal inducer of the antimicrobial peptide S100A7c (psoriasin) in human epidermal keratinocytes exposed to Escherichia coli

Epidermal keratinocytes (KCs) express antimicrobial peptides as a part of the innate immune response. It has recently been shown that the culture supernatant of Escherichia coli induces the expression of S100A7c (psoriasin) in KCs and that S100A7c efficiently kills E. coli. Here we have investigated which of the microbial components triggers the up‐regulation of S100A7c expression. Exposure of human primary KCs to ligands of the human Toll‐like receptors (TLRs) revealed that only the TLR5 ligand flagellin strongly induced the expression of S100A7c mRNA and protein, whereas all other TLR ligands had no significant effect. In contrast to the supernatant from flagellated wild‐type (WT) E. coli, the supernatant of a flagellin‐deficient E. coli strain (ΔFliC) did not induce S100A7c expression. Small interfering RNA‐mediated knockdown of TLR5 expression suppressed the ability of KCs to up‐regulate S100A7c expression in response to both flagellin and WT E. coli supernatant. Taken together, our data demonstrate that bacterial flagellin is essential and sufficient for the induction of S100A7c expression in KCs by E. coli.—Abtin, A., Eckhart, L., Mildner, M., Gruber, F., Schröder, J‐M., Tschachler, E. Flagellin is the principal inducer of the antimicrobial peptide S100A7c (psoriasin) in human epidermal keratinocytes exposed to Escherichia coli. FASEB J. 22, 2168–2176 (2008)

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.

Identification of Novel Mammalian Caspases Reveals an Important Role of Gene Loss in Shaping the Human Caspase Repertoire

Proteases of the caspase family play central roles in apoptosis and inflammation. Recently, we have described a new gene encoding caspase-15 that has been inactivated independently in different mammalian lineages. To determine the dynamics of gene duplication and loss in the entire caspase gene family, we performed a comprehensive evolutionary analysis of mammalian caspases. By comparative genomics and reverse transcriptase-polymerase chain reaction analyses, we identified 3 novel mammalian caspase genes, which we tentatively named caspases-16 through -18. Caspase-16, which is most similar in sequence to caspase-14, has been conserved in marsupials and placental mammals, including humans. Caspase-17, which is most similar to caspase-3, has been conserved among fish, frog, chicken, lizard, and the platypus but is absent from marsupials and placental mammals. Caspase-18, which is most similar to caspase-8, has been conserved among chicken, platypus, and opossum but is absent from placental mammals. These gene distribution patterns suggest that, in the evolutionary lineage leading to humans, caspase-17 was lost after the split of protherian and therian mammals and caspase-18 was lost after the split of marsupials and placental mammals. In the canine genome, the number of caspases has been reduced by the fusion of the neighboring genes caspases-1 and -4, resulting in a single coding region. Further lineage-specific gene inactivations were found for caspase-10 in murine rodents and caspase-12 in humans, rabbit, and cow. Lineage-specific gene duplications were found for caspases-1, -3, and -12 in opossum and caspase-4 in primates. Other caspases were generally conserved in all mammalian species investigated. Using the positions of introns as stable characters during recent vertebrate evolution, we define 3 phylogenetic clades of caspase genes: caspases-1/-2/-4/-5/-9/-12/-14/-15/-16 (clade I), caspases-3/-6/-7/-17 (clade II), and caspases-8/-10/-18/CFLAR (clade III). We conclude that gene inactivations have occurred in each of the 3 caspase clades and that gene loss has been as critical as gene duplication in the evolution of the human repertoire of caspases.