Krankheitsspezifische Hautmodelle

A variety of skin equivalent systems have been developed recently mainly for burn therapy but also for studies of the cell and molecular biology of dermatologic and immunologic disorders and for cosmetic and pharmaceutical research. Since European regulation forbids the use of animals to prove product safety in cosmetic products, several commercially available three-dimensional skin models were developed by the cosmetic and chemical industry and validated according to OECD and ECVAM regulations. Three-dimensional skin models consist of two compartments: one serves as a dermal equivalent, usually consisting of fibroblasts in type I collagen, onto which a terminally differentiating epidermis is placed. Up-to-date models are missing that mimic monogenic skin disorders or signs of disease in the skin caused by a systemic autoimmune disorder. We recently developed a three-dimensional skin model for congenital ichthyosis as an example for a keratinization disorder. The system is being validated and will be fundamental for studies of disturbed epidermal differentiation and pharmaceutical intervention.     

Disorders of the cutaneous basement membrane zone—The paradigm of epidermolysis bullosa

The cutaneous basement membrane zone (BMZ) is a highly specialized functional complex that provides the skin with structural adhesion and resistance to shearing forces. Its regulatory functions include control of epithelial–mesenchymal interactions under physiological and pathological conditions. Mutations in genes encoding components of the BMZ are associated with inherited skin disorders of the epidermolysis bullosa (EB) group, characterized by skin fragility, mechanically induced blisters and erosions of the skin and mucous membranes. Although most disease-associated genes are known, the genetic basis of new EB subtypes linked to mutations in genes for focal adhesion proteins was uncovered only recently. The molecular mechanisms leading to blistering, abnormal wound healing, predisposition to skin cancer, and other complications in EB have been elucidated using animal models and disease proteomics. The rapid progress in understanding the molecular basis of EB has enabled the development of strategies for biologically valid causal therapies.     

Ehlers–Danlos syndrome: A showcase of conditions that lead to understanding matrix biology

The Ehlers–Danlos syndromes (EDS) are genetically and clinically diverse disorders in which affected individuals share a number of physical characteristics, including joint hypermobility, skin extensibility, and tissue friability. Clinical investigations opened the door to identifying the biochemical and molecular etiologies of this diverse but overlapping group of disorders. In this article, we provide an overview of how these disorders inform our understanding of matrix biology, including the role of collagens (types I, III and V), proteoglycans and other proteins.     

Ectopic mineralization disorders of the extracellular matrix of connective tissue: Molecular genetics and pathomechanisms of aberrant calcification

Ectopic mineralization of connective tissues is a complex process leading to deposition of calcium phosphate complexes in the extracellular matrix, particularly affecting the skin and the arterial blood vessels and common in age-associated disorders. A number of initiating and contributing metabolic and environmental factors are linked to aberrant mineralization in these diseases, making the identification of precise pathomechanistic pathways exceedingly difficult. However, there has been significant recent progress in understanding the ectopic mineralization processes through study of heritable single-gene disorders, which have allowed identification of discrete pathways and contributing factors leading to aberrant connective tissue mineralization. These studies have provided support for the concept of an intricate mineralization/anti-mineralization network present in peripheral connective tissues, providing a perspective to development of pharmacologic approaches to limit the phenotypic consequences of ectopic mineralization. This overview summarizes the current knowledge of ectopic heritable mineralization disorders, with accompanying animal models, focusing on pseudoxanthoma elasticum and generalized arterial calcification of infancy, two autosomal recessive diseases manifesting with extensive connective tissue mineralization in the skin and the cardiovascular system.     

Transgenic animal models of tauopathies

Tauopathies are a group of neurodegenerative disorders that include Alzheimer's disease, frontotemporal dementia with parkinsonism linked to chromosome 17 (FTDP-17) and other related diseases with prominent tau pathology. Research advances in the last several decades have characterized and defined tau neuropathologies of both neuron and glia in these diverse disorders and this has stimulated development of animal models of tauopathies. Indeed, animal models ranging from invertebrate species such as C. elegan to Drosophila melanogaster and mammalian transgenic mouse models of tauopathies have been generated and reported. This review summarizes the salient features of many of the known models of tauopathies.     

Photosensitivity skin disorders in childhood

Photosensitivity in childhood is caused by a diverse group of diseases. A specific sensitivity of a child's skin to ultraviolet light is often the first manifestation or a clinical symptom of photodermatosis. It might indicate a serious underlying systemic disease such as lupus erythematosus or dermatomyositis, or a rare group of genetic skin disorders like Xeroderma pigmentosum, Cockayne syndrome, Trichothyodystrophy, Bloom syndrome, Rothmund-Thomson and Kindler syndrome as well as metabolic disorders and cutaneous porphyria. Photosensitivity secondary to topical or systemic agents may also cause photosensitivity in children. Early recognition and prompt diagnosis may prevent complications associated with unprotected exposure to sunlight and avoid actinic injuries that can lead to malignant skin changes.     

Models for human porphyrias: Have animals in the wild been overlooked?

Humans accumulate porphyrins in the body mostly during the course of porphyrias, diseases caused by defects in the enzymes of the heme biosynthesis pathway and that produce acute attacks, skin lesions and liver cancer. In contrast, some wild mammals and birds are adapted to accumulate porphyrins without injurious consequences. Here we propose viewing such physiological adaptations as potential solutions to human porphyrias, and suggest certain wild animals as models. Given the enzymatic activity and/or the patterns of porphyrin excretion and accumulation, the fox squirrel, the great bustard and the Eurasian eagle owl may constitute overlooked models for different porphyrias. The Harderian gland of rodents, where large amounts of porphyrins are synthesized, presents an underexplored potential for understanding the carcinogenic/toxic effect of porphyrin accumulation. Investigating how these animals avoid porphyrin pathogenicity may complement the use of laboratory models for porphyrias and provide new insights into the treatment of these disorders.     

Microfluidic skin chip with vasculature for recapitulating the immune response of the skin tissue

There is a considerable need for cell-based in vitro skin models for studying dermatological diseases and testing cosmetic products, but current in vitro skin models lack physiological relevance compared to human skin tissue. For example, many dermatological disorders involve complex immune responses, but current skin models are not capable of recapitulating the phenomena. Previously, we reported development of a microfluidic skin chip with a vessel structure and vascular endothelial cells. In this study, we cocultured dermal fibroblasts and keratinocytes with vascular endothelial cells, human umbilical vascular endothelial cells. We verified the formation of a vascular endothelium in the presence of the dermis and epidermis layers by examining the expression of tissue-specific markers. As the vascular endothelium plays a critical role in the migration of leukocytes to inflammation sites, we incorporated leukocytes in the circulating media and attempted to mimic the migration of neutrophils in response to external stimuli. Increased secretion of cytokines and migration of neutrophils was observed when the skin chip was exposed to ultraviolet irradiation, showing that the microfluidic skin chip may be useful for studying the immune response of the human tissue.     

Neurons and mechanisms of neuronal death in neurodegenerative diseases: a brief review.

BACKGROUND AND PURPOSE: Degenerative diseases of the central nervous system are a heterogenous group of slowly progressive disorders. A common feature of this group, which includes Alzheimer's disease, Parkinson's disease, and amyotrophic lateral sclerosis, is gradual loss of specific populations of neurons. METHODS: A series of reports about neurodegenerative diseases and their relevant animal models, as well as a brief overview of the normal neuron and mechanisms of neuronal degeneration and death, is presented. CONCLUSION: Study of the aforementioned animal models, spontaneously occurring and experimentally induced, have provided important insights into the pathogenesis of these disorders and the development of effective therapeutic strategies.     

Gene therapy: prospects for glycolipid storage diseases

Lysosomal storage diseases comprise a group of about 40 disorders, which in most cases are due to the deficiency of a lysosomal enzyme. Since lysosomal enzymes are involved in the degradation of various compounds, the diseases can be further subdivided according to which pathway is affected. Thus, enzyme deficiencies in the degradation pathway of glycosaminoglycans cause mucopolysaccharidosis, and deficiencies affecting glycopeptides cause glycoproteinosis. In glycolipid storage diseases enzymes are deficient that are involved in the degradation of sphingolipids. Mouse models are available for most of these diseases, and some of these mouse models have been used to study the applicability of in vivo gene therapy. We review the rationale for gene therapy in lysosomal disorders and present data, in particular, about trials in an animal model of metachromatic leukodystrophy. The data of these trials are compared with those obtained with animal models of other lysosomal diseases.     

Induced pluripotent stem cells reprogramming overcomes technical limitations for highly pigmented adult melanocyte amplification and integration in 3D skin model

Understanding pigmentation regulations taking into account the original skin color type is important to address pigmentary disorders. Biological models including adult melanocytes from different phenotypes allow to perform fine-tuned explorative studies and support discovery of treatments adapted to populations' skin color. However, technical challenges arise when trying to not only isolate but also amplify melanocytes from highly pigmented adult skin. To bypass the initial isolation and growth of cutaneous melanocytes, we harvested and expanded fibroblasts from light and dark skin donors and reprogrammed them into iPSC, which were then differentiated into melanocytes. The resulting melanocyte populations displayed high purity, genomic stability, and strong proliferative capacity, the latter being a critical parameter for dark skin cells. The iPSC-derived melanocyte strains expressed lineage-specific markers and could be successfully integrated into reconstructed skin equivalent models, revealing pigmentation status according to the native phenotype. In both monolayer cultures and 3D skin models, the induced melanocytes demonstrated responsiveness to promelanogenic stimuli. The data demonstrate that the iPSC-derived melanocytes with high proliferative capacity maintain their pigmentation genotype and phenotypic properties up to a proper integration into 3D skin equivalents, even for highly pigmented cells.     

Emerging role of immune cell network in autoimmune skin disorders: An update on pemphigus,vitiligo and psoriasis

Autoimmune skin diseases are a group of disorders that arise due to a deregulated immune system resulting in skin tissue destruction. In the majority of these conditions, either autoreactive immune cells or the autoantibodies are generated against self-antigens of the skin. Although the etiology of these diseases remains elusive, biochemical, genetic, and environmental factors such as infectious agents, toxins damage the skin tissue leading to self-antigen generation, autoantibody attack and finally results in autoimmunity of skin. Immune dysregulation, which involves predominantly T helper 1/17 (Th1/Th17) polarization and the inability of regulatory T cells to regress immune response, is implicated in autoimmune skin diseases.The emerging roles of immune cells, cytokines, and chemokines in the pathogenesis of common autoimmune skin diseases like pemphigus, vitiligo, and psoriasis are discussed in this review. The main focus is on the interplay between immune cell network including the innate and adaptive immune system, regulatory cells, immune checkpoints and recently identified tissue-resident memory cells (TRMs) in disease pathogenesis and relapse. We also attempt to highlight on the immune mechanisms common to these diseases which can be targeted for designing novel therapeutics.     

Molecular basis of inherited skin-blistering disorders, and therapeutic implications

Epidermolysis bullosa (EB) and associated skin-fragility syndromes are a group of inherited skin diseases characterised by trauma-induced blistering of the skin and mucous membranes. Mutations in at least 14 distinct genes encoding molecular components of the epidermis or the dermal-epidermal junction (DEJ) can cause blistering skin diseases that differ by clinical presentation and severity of the symptoms. Despite great advances in discerning the genetic basis of this group of diseases, the molecular pathways leading to symptoms are not yet fully understood. Unravelling these pathways by molecular analysis of the structure and in vitro assessment of functional properties of the human proteins involved, combined with genetic models in lower organisms, should pave the way for specific cures for inherited skin fragility.     

Fortschritt in der Pathogenese des Marfan-Syndroms und verwandter Krankheiten

Heritable connective tissue disorders comprise a heterogeneous group of disorders that result from genetic defects affecting normal extracellular matrix assembly. Many of these diseases are associated with a significant cardiovascular risk leading to morbidity and mortality in childhood or young adulthood. Prime examples that represent important genetic models for cardiovascular pathology are the Marfan syndrome and related disorders. In these conditions, progressive dilatation of the aortic root leads to aortic dissection, often associated with precocious death. Over the last decade tremendous progress in clinical and molecular research has changed the prevailing concept of these syndromes as structural disorders of the connective tissue into diseases manifesting perturbed cytokine signaling with widespread developmental abnormalities. These insights opened new and unexpected targets for causally directed drug treatments for these aneurysm syndromes, and by extent, also for the more common non-syndromic forms of aneurysm formation, a major cause of morbidity and mortality in the Western world.     

Topical Gene Electrotransfer to the Epidermis of Hairless Guinea Pig by Non-Invasive Multielectrode Array

Topical gene delivery to the epidermis has the potential to be an effective therapy for skin disorders, cutaneous cancers, vaccinations and systemic metabolic diseases. Previously, we reported on a non-invasive multielectrode array (MEA) that efficiently delivered plasmid DNA and enhanced expression to the skin of several animal models by in vivo gene electrotransfer. Here, we characterized plasmid DNA delivery with the MEA in a hairless guinea pig model, which has a similar histology and structure to human skin. Significant elevation of gene expression up to 4 logs was achieved with intradermal DNA administration followed by topical non-invasive skin gene electrotransfer. This delivery produced gene expression in the skin of hairless guinea pig up to 12 to 15 days. Gene expression was observed exclusively in the epidermis. Skin gene electrotransfer with the MEA resulted in only minimal and mild skin changes. A low level of human Factor IX was detected in the plasma of hairless guinea pig after gene electrotransfer with the MEA, although a significant increase of Factor IX was obtained in the skin of animals. These results suggest gene electrotransfer with the MEA can be a safe, efficient, non-invasive skin delivery method for skin disorders, vaccinations and potential systemic diseases where low levels of gene products are sufficient.     

Skin‐resident memory T cells as a potential new therapeutic target in vitiligo and melanoma

Tissue‐resident memory T (T_RM) cells are abundant in the memory T cell pool and remain resident in peripheral tissues, such as the skin, where they act as alarm sensors or cytotoxic killers. T_RM cells persist long after the pathogen is eliminated and can respond rapidly upon reinfection with the same antigen. When aberrantly activated, skin‐located T_RM cells have a profound role in various skin disorders, including vitiligo and melanoma. Autoreactive T_RM cells are present in human lesional vitiligo skin and mouse models of vitiligo, which suggests that targeting these cells could be effective as a durable treatment strategy for vitiligo. Furthermore, emerging evidence indicates that induction of melanoma‐reactive T_RM cells is needed to achieve effective protection against tumor growth. This review highlights seminal reports about skin‐resident T cells, focusing mainly on their role in the context of vitiligo and melanoma, as well as their potential as therapeutic targets in both diseases.     

Dermatologic problems in amputees.

Improvements in surgical techniques and prosthetic devices and the establishment of prosthetic clinics have altered the outlook for the amputee. A cooperative effect on the part of professionals looking after amputee patients, as carried out in these clinics, offers the best means of recognition and treatment of difficulties as they arise. Until the "bionic man" becomes a reality, amputees will continue to have skin problems. In describing a number of illustrative cases, we have attempted to: (a) renew interest in these problems; (b) demonstrate the value of the group approach; and (c) encourage the participation of interested dermatologists in the prosthetic clinic team to facilitate earlier recognition and treatment of troublesome skin disorders in the amputee.     

Revertant mosaicism in skin: natural gene therapy

Revertant mosaicism is a naturally occurring phenomenon involving spontaneous correction of a pathogenic mutation in a somatic cell. Recent studies suggest that it is not a rare event and that it could be clinically relevant to phenotypic expression and patient treatment. Indeed, revertant cell therapy represents a potential 'natural gene therapy' because in vivo reversion obviates the need for further genetic correction. Revertant mosaicism has been observed in several inherited conditions, including epidermolysis bullosa, a heterogeneous group of blistering skin disorders. These diseases provide a useful model for studying revertant mosaicism because of the visual and accessible nature of skin. This overview highlights the latest developments in revertant mosaicism and the translational implications germane to heritable skin disorders.