Inherited Mouse Mutations as Models of Human Adnexal, Cornification, and Papulosquamous Dermatoses

Phenotyping mice with skin, hair, or nail abnormalities: A systematic approach and methodologies from simple to complex

The skin and adnexa can be difficult to interpret because they change dramatically with the hair cycle throughout life. However, a variety of methods are commonly available to collect skin and perform assays that can be useful for figuring out morphological and molecular changes. This overview provides information on basic approaches to evaluate skin and its molecular phenotype, with references for more detail, and interpretation of results on the skin and adnexa in the mouse. These approaches range from mouse genetic nomenclature, setting up a cutaneous phenotyping study, skin grafts, hair follicle reconstitution, wax stripping, electron microscopy, and Köbner reaction to very specific approaches such as lipid and protein analyses on a large scale.

Proteomic and Metabolomic Changes in Psoriasis Preclinical and Clinical Aspects

Skin diseases such as psoriasis (Ps) and psoriatic arthritis (PsA) are immune-mediated inflammatory diseases. Overlap of autoinflammatory and autoimmune conditions hinders diagnoses and identifying personalized patient treatments due to different psoriasis subtypes and the lack of verified biomarkers. Recently, proteomics and metabolomics have been intensively investigated in a broad range of skin diseases with the main purpose of identifying proteins and small molecules involved in the pathogenesis and development of the disease. This review discusses proteomics and metabolomics strategies and their utility in research and clinical practice in psoriasis and psoriasis arthritis. We summarize the studies, from in vivo models conducted on animals through academic research to clinical trials, and highlight their contribution to the discovery of biomarkers and targets for biological drugs.

Animal models of psoriasis-highlights and drawbacks

Research into the pathophysiology of psoriasis remains challenging, because this disease does not occur naturally in laboratory animals. However, specific aspects of its complex immune-pathology can be illuminated through transgenic, knockout, xenotransplantation, immunological reconstitution, drug-induced, or spontaneous mutation models in rodents. Although some of these approaches have already been pursued for more than 5 decades and even more models have been described in recent times, they have surprisingly not yet been systematically validated. As a consequence, researchers regularly examine specific aspects that only partially reflect the complex overall picture of the human disease. Nonetheless, animal models are of great utility to investigate inflammatory mediators, the communication between cells of the innate and the adaptive immune systems, the role of resident cells as well as new therapies. Of note, various manipulations in experimental animals resulted in rather similar phenotypes. These were called "psoriasiform", "psoriasis-like" or even "psoriasis" usually on the basis of some similarities with the human disorder. Xenotransplantation of human skin onto immunocompromised animals can overcome this limitation only in part. In this review, we elucidate approaches for the generation of animal models of psoriasis and assess their strengths and limitations with a certain focus on more recently developed models.

Adenoviral gene transfer of a single-chain IL-23 induces psoriatic arthritis-like symptoms in NOD mice

Previously, we demonstrated that intratumoral delivery of adenoviral vector encoding single-chain (sc)IL-23 (Ad.scIL-23) was able to induce systemic antitumor immunity. Here, we examined the role of IL-23 in diabetes in nonobese diabetic mice. Intravenous delivery of Ad.scIL-23 did not accelerate the onset of hyperglycemia but instead resulted in the development of psoriatic arthritis. Ad.scIL-23-treated mice developed erythema, scales, and thickening of the skin, as well as intervertebral disc degeneration and extensive synovial hypertrophy and loss of articular cartilage in the knees. Immunological analysis revealed activation of conventional T helper type 17 cells and IL-17-producing γδ T cells along with a significant depletion and suppression of T cells in the pancreatic lymph nodes. Furthermore, treatment with anti-IL-17 antibody reduced joint and skin psoriatic arthritis pathologies. Thus, these Ad.scIL-23-treated mice represent a physiologically relevant model of psoriatic arthritis for understanding disease progression and for testing therapeutic approaches.-Flores, R. R., Carbo, L., Kim, E., Van Meter, M., De Padilla, C. M. L., Zhao, J., Colangelo, D., Yousefzadeh, M. J., Angelini, L. A., Zhang, L., Pola, E., Vo, N., Evans, C. H., Gambotto, A., Niedernhofer, L. J., Robbins, P. D. Adenoviral gene transfer of a single-chain IL-23 induces psoriatic arthritis-like symptoms in NOD mice.

Hairless-knockout piglets generated using the clustered regularly interspaced short palindromic repeat/CRISPR-associated-9 exhibit abnormalities in the skin and thymus

The nuclear receptor corepressor Hairless (HR) interacts with nuclear receptors and controls expression of specific target genes involved in hair morphogenesis and hair follicle cycling. Patients with HR gene mutations exhibit atrichia, and in rare cases, immunodeficiency. Pigs with HR gene mutations may provide a useful model for developing therapeutic strategies because pigs are highly similar to humans in terms of anatomy, genetics, and physiology. The present study aimed to knockout the HR gene in pigs using the clustered regularly interspaced short palindromic repeat (CRISPR)/CRISPR-associated-9 (Cas9) system and to investigate the molecular and structural alterations in the skin and thymus. We introduced a biallelic mutation into the HR gene in porcine fetal fibroblasts and generated nine piglets via somatic cell nuclear transfer. These piglets exhibited a lack of hair on the eyelids, abnormalities in the thymus and peripheral blood, and altered expression of several signaling factors regulated by HR. Our results indicate that introduction of the biallelic mutation successfully knocked out the HR gene, resulting in several molecular and structural changes in the skin and thymus. These pigs will provide a useful model for studying human hair disorders associated with HR gene mutations and the underlying molecular mechanisms.

Murine models of psoriasis and their usefulness for drug discovery

INTRODUCTION

Psoriasis is an autoimmune skin disease characterized by red plaques with silver or white multilayered scales with a thickened acanthotic epidermis. Using mouse models of cutaneous inflammation, IL-23/Th17 was identified to have a potential key role in psoriasis. New treatments to slow this inflammatory skin disorder are urgently needed. To aid their discovery, a psoriasis animal model mimicking human psoriasis is urgently needed for their early preclinical evaluation. Areas covered: The authors review animal models of psoriasis and analyze the features and molecular mechanisms involved in these mouse models. The application of various mouse models of psoriasis for drug discovery and development has also been reviewed and the possible molecular targets in psoriasis for future anti-psoriatic drug design is discussed. Expert opinion: So far, it has been difficult to create an animal model that exactly simulates a human disease or condition. The xenotransplantation model is regarded as the closest to incorporating the complete genetic, phenotypic, and immunopathogenic processes of psoriasis. However, the imiquimod (IMQ)-induced model is the most prevalent among psoriatic mouse models due to its ease of use, convenience, and low cost. Further efforts to develop psoriasis-like skin models in mice are needed for the study and treatment of this complex disease.

Skin Diseases in Laboratory Mice: Approaches to Drug Target Identification and Efficacy Screening

A large variety of mouse models for human skin, hair, and nail diseases are readily available from investigators and vendors worldwide. Mouse skin is a simple organ to observe lesions and their response to therapy, but identifying and monitoring the progress of treatments of mouse skin diseases can still be challenging. This chapter provides an overview on how to use the laboratory mouse as a preclinical tool to evaluate efficacy of new compounds or test potential new uses for compounds approved for use for treating an unrelated disease. Basic approaches to handling mice, applying compounds, and quantifying effects of the treatment are presented.

Reactive oxygen species in psoriasis and psoriasis arthritis: relevance to human disease

Psoriasis (Ps) is a chronic, immune-mediated, skin inflammatory disease affecting up to 3% of the population worldwide. Different environmental triggers initiate this complex multifactorial syndrome. Many individuals affected by Ps (6-26%) develop inflammatory disease in other organs, often in the joints as in psoriasis arthritis (PsA). Animal models that reflect the typical Ps syndrome, including both skin and joint pathology as in Ps and PsA, are valuable tools for dissecting disease pathways leading to clinical manifestations. In this context, we developed a new acute Ps and PsA-like disease model that appears after exposure to Saccharomyces cerevisiae mannan in certain mouse strains. The disease was found to be triggered by mannan-activated macrophages, leading to the activation of a pathogenic interleukin-17 pathway involving innate lymphocytes. Interestingly, the production of reactive oxygen species protected the mice from the triggering of this pathway and ameliorated Ps and PsA development.

Animal models of skin disease for drug discovery

INTRODUCTION

Discovery of novel drugs, treatments, and testing of consumer products in the field of dermatology is a multi-billion dollar business. Due to the distressing nature of many dermatological diseases, and the enormous consumer demand for products to reverse the effects of skin photodamage, aging, and hair loss, this is a very active field.

AREAS COVERED

In this paper, we will cover the use of animal models that have been reported to recapitulate to a greater or lesser extent the features of human dermatological disease. There has been a remarkable increase in the number and variety of transgenic mouse models in recent years, and the basic strategy for constructing them is outlined.

EXPERT OPINION

Inflammatory and autoimmune skin diseases are all represented by a range of mouse models both transgenic and normal. Skin cancer is mainly studied in mice and fish. Wound healing is studied in a wider range of animal species, and skin infections such as acne and leprosy also have been studied in animal models. Moving to the more consumer-oriented area of dermatology, there are models for studying the harmful effect of sunlight on the skin, and testing of sunscreens, and several different animal models of hair loss or alopecia.

Sleep loss and cytokines levels in an experimental model of psoriasis

Up to 80% of people develop a cutaneous condition closely connected to their exposure to stressful life events. Psoriasis is a chronic recurrent inflammatory skin disorder with multifactorial etiology, including genetic background, environmental factors, and immune system disturbances with a strong cytokine component. Moreover, psoriasis is variably associated with sleep disturbance and sleep deprivation. This study evaluated the influence of sleep loss in the context of an animal model of psoriasis by measuring cytokine and stress-related hormone levels. Male adult Balb/C mice with or without psoriasis were subjected to 48 h of selective paradoxical sleep deprivation (PSD). Sleep deprivation potentiated the activities of kallikrein-5 and kallikrein-7 in the skin of psoriatic groups. Also, mice with psoriasis had significant increases in specific pro-inflammatory cytokines (IL-1β, IL-6 and IL-12) and decreases in the anti-inflammatory cytokine (IL-10) after PSD, which were normalized after 48 h of sleep rebound. Linear regression showed that IL-2, IL-6 and IL-12 levels predicted 66% of corticosterone levels, which were selectively increased in psoriasis mice subject to PSD. Kallikrein-5 was also correlated with pro-inflammatory cytokines, explaining 58% of IL-6 and IL-12 variability. These data suggest that sleep deprivation plays an important role in the exacerbation of psoriasis through modulation of the immune system in the epidermal barrier. Thus, sleep loss should be considered a risk factor for the development of psoriasis.

Chronic Proliferative Dermatitis in Mice: NFκB Activation Autoinflammatory Disease

Autoinflammatory diseases are a heterogeneous group of congenital diseases characterized by the presence of recurrent inflammation, in the absence of infectious agents, detectable autoantibodies or antigen-specific autoreactive T-cells. SHARPIN deficient mice presents multiorgan chronic inflammation without known autoantibodies or autoreactive T-cells, designated Sharpin(cpdm). Histological studies demonstrated epidermal hyperproliferation, Th-2 inflammation, and keratinocyte apoptosis in this mutant. The mutant mice have decreased behavioral mobility, slower growth, and loss of body weight. Epidermal thickness and mitotic epidermal cells increase along with disease development. K5/K14 expression is distributed through all layers of epidermis, along with K6 expression in interfollicular epidermis, suggesting epidermal hyperproliferation. K1/K10 is only detectable in outer layers of spinosum epidermis, reflecting accelerated keratinocyte migration. Alpha smooth muscle actin is overexpressed in skin blood vessels, which may release the elevated white blood cells to dermis. CD3(+)CD45(+) cells and granulocytes, especially eosinophils and mast cells, aggregate in the mutant skin. TUNEL assay, together with Annexin-V/propidium iodide FACS analysis, confirmed the increase of apoptotic keratinocytes in skin. These data validate and provide new lines of evidence of the proliferation-inflammation-apoptosis triad in Sharpin(cpdm) mice, an NFκB activation autoinflammatory disease.

Skin diseases in laboratory mice: approaches to drug target identification and efficacy screening

A large variety of mouse models for human skin and adnexa diseases are readily available from investigators and vendors worldwide. While the skin is an obvious organ to observe lesions and their response to therapy, actually treating and monitoring progress in mice can be challenging. This chapter provides an overview on how to use the laboratory mouse as a preclinical tool to evaluate efficacy of a new compound or test potential new uses for a compound approved for use for treating an unrelated disease. Basic approaches to handling mice, applying compounds, and quantifying effects of the treatment are presented.

Mouse models of psoriasis

Psoriasis is a T-cell-mediated chronic inflammatory skin disease believed to be of autoimmune nature that can be triggered or worsened by streptococcal throat infections. In addition to conventional chronic inflammatory changes, psoriasis is characterized by complex and striking alterations in epidermal growth and differentiation. Psoriasis is generally not observed in animals other than man, and this lack of a suitable animal model has greatly hindered research into the pathogenesis of psoriasis. Multiple transgenic, knockout, and reconstituted models of psoriasis have been developed over the past two decades. Despite their limitations, these models have demonstrated that keratinocyte hyperplasia, vascular hyperplasia, and cell-mediated immunity in the skin are closely interrelated. Xenograft models, in which involved and uninvolved psoriatic skin are transplanted onto immunodeficient mice, are the only models that come close to incorporating the complete genetic, immunologic, and phenotypic changes of the disease. They have shown conclusively that psoriasis is a T-cell-mediated disease, and have been used to elucidate novel pathogenic pathways. In this review, we describe various animal models, detail the immunologic and intracellular pathways that mediate these phenotypes and assess the utility of these models to better understand this disease.

Heavy water labeling of keratin as a non-invasive biomarker of skin turnover in vivo in rodents and humans

Measurement of skin turnover has been problematic in humans. Heavy water (2H2O) labeling has recently been developed as a safe, simple method to study in vivo kinetics of many biosynthetic processes, including DNA and protein synthesis. Here, we apply this approach to the measurement of 2H incorporation into skin keratin and show close agreement between keratin and keratinocyte turnover data in the epidermis of rodents. Elevated turnover rates of both keratin and keratinocytes were observed in the epidermis of the flaky skin mouse, although topical treatments effective in human psoriasis had no effect on either turnover rate in these mice. In humans, keratin turnover was monitored non-invasively by serial tape stripping during and after 2H2O labeling. Kinetic data were consistent with previous estimates of epidermal turnover, with a lag time of 18 days before label appeared at the skin surface and a transit time of 4-5 weeks. Variability in skin keratin turnover rates was present among healthy individuals. In summary, 2H2O labeling of skin keratin represents a non-invasive approach for assessing skin turnover dynamics in pre-clinical models and in human subjects.

Involvement of a tissue-specific autoantibody in skin disorders of murine systemic lupus erythematosus and autoinflammatory diseases

Human systemic lupus erythematosus (SLE) and its murine model, MRL lpr/lpr mice, are well known to develop a wide range of symptoms, such as glomerulonephritis, dermatitis, and arthritis, as an immune-complex disease. However, the deposition of circulating immune complex does not fully explain the tissue specificity of disease. Tissue-specific autoantigens may also be involved in tissue inflammation. In this study, desmoglein 3 (Dsg3), a major component of epidermal desmosomes, was identified as a skin-specific autoantigen. Several murine models of skin inflammation were found to develop autoantibodies to Dsg3 tightly correlated with disease aggravation, especially in MRL lpr/lpr mice. Furthermore, SLE-prone skin disease-free FcgammaRIIb-deficient mice developed skin inflammation upon immunization with Dsg3. Taken together with histological studies, we concluded that skin-specific Dsg3 serves as an autoantigen in chronic skin inflammatory diseases accompanied by mast cell degranulation, including both murine SLE and other autoinflammatory diseases.

The Tetratricopeptide repeat domain 7 gene is mutated in flaky skin mice: a model for psoriasis, autoimmunity, and anemia

The flaky skin (fsn) mutation in mice causes pleiotropic abnormalities including psoriasiform dermatitis, anemia, hyper-IgE, and anti-dsDNA autoantibodies resembling those detected in systemic lupus erythematosus. The fsn mutation was mapped to an interval of 3.9 kb on chromosome 17 between D17Mit130 and D17Mit162. Resequencing of known and predicted exons and regulatory sequences from this region in fsn/fsn and wild-type mice indicated that the mutation is due to the insertion of an endogenous retrovirus (early transposon class) into intron 14 of the Tetratricopeptide repeat (TPR) domain 7 (Ttc7) gene. The insertion leads to reduced levels of wild-type Ttc7 transcripts in fsn mice and the insertion of an additional exon derived from the retrovirus into the majority of Ttc7 mRNAs. This disrupts one of the TPRs within TTC7 and may affect its interaction with an as-yet unidentified protein partner. The Ttc7 is expressed in multiple types of tissue including skin, kidney, spleen, and thymus, but is most abundant in germinal center B cells and hematopoietic stem cells, suggesting an important role in the development of immune system cells. Its role in immunologic and hematologic disorders should be further investigated.

Anti-CD11a ameliorates disease in the human psoriatic skin-SCID mouse transplant model: comparison of antibody to CD11a with Cyclosporin A and clobetasol propionate

The present study assesses the applicability of human skin-SCID (severe combined immunodeficiency) mouse chimeras in testing antipsoriatic therapeutics. Three agents were examined: (1) a monoclonal antibody to the alpha subunit of leukocyte function associated antigen-1 integrin (CD11a); (2) Cyclosporin A; and (3) clobetasol propionate (Temovate), a potent topical corticosteroid used clinically in the treatment of psoriasis. Skin transplanted to SCID mice from normal human volunteers or from psoriatic lesional skin was allowed to heal for 3 to 5 weeks before application of test reagents. During this period, psoriatic skin, which was 3.8-fold thicker than the corresponding normal skin before transplantation, maintained its phenotype (ie, increased epidermal thickness, rete ridges with blunted ends, and intralesional presence of T lymphocytes). Transplanted normal human skin, however, underwent a hyperplastic response during this period, resulting in a 2.4-fold increase in epidermal thickness. After the healing period, animals transplanted with normal or psoriatic skin were treated for 14 days by daily intraperitoneal injection of either Cyclosporin A or a monoclonal antibody to human CD11a, or by topical application of clobetasol propionate. At the end of the treatment period, the mice were killed and the tissue evaluated morphometrically for changes in epidermal thickness and immunohistologically for the presence of T lymphocytes. Both Cyclosporin A and anti-CD11a reduced the epidermal thickness of transplanted psoriatic skin, whereas neither reagent significantly reduced the thickness of transplanted normal skin. T lymphocytes were detected in the skin from treated animals; there did not seem to be any reduction in the number of T lymphocytes. Clobetasol propionate reduced the epidermal thickness of both normal and psoriatic skin. These data indicate that, in this model, therapies directed against pathophysiologic mechanisms that contribute to psoriasis can be distinguished from treatments that block epidermal hyperplasia occurring as a consequence of xenografting. Our observations provide evidence for the activity of anti-CD11a in an animal model of human psoriasis.

Severe combined immunodeficiency mouse-human skin chimeras: a unique animal model for the study of psoriasis and cutaneous inflammation

Elucidation of the molecular and cellular mechanisms responsible for the pathogenesis of psoriasis had been significantly handicapped due to lack of an ideal animal model. To overcome this hurdle several investigators have developed a number of animal models for psoriasis. Recent establishment of the SCID-human skin chimeras with transplanted psoriasis plaques has opened new vistas to study the molecular complexities involved in psoriasis. This model also offers a unique opportunity to investigate various key biological events such as cell proliferation, angiogenesis, homing in of T cells in target tissues, neurogenic inflammation and cytokine/chemokine cascades involved in an inflammatory reaction. The SCID mouse model will be of immense help to target the cellular and molecular events associated with these pathogenic processes and develop novel drugs for psoriasis and other inflammatory diseases. In this article we have reviewed the prospects and the limitations of the SCID mouse model of psoriasis.

Pathogenic function of IL-1 beta in psoriasiform skin lesions of flaky skin (fsn/fsn) mice

IL-1 acts on many cells as an inflammatory mediator. Its two forms, IL-1 alpha and IL-1 beta, are regulated differentially within hyperproliferative inflammatory skin conditions, such as psoriasis. While IL-1 alpha is down-regulated within psoriatic lesions, the levels of IL-1 beta are increased. However, some investigators have described an inactive form of IL-1 beta in psoriasis, while others have detected increased IL-1 beta activity within these lesions. Thus, its in vivo role remains unclear. We have assessed expression and function of IL-1 beta within psoriasiform skin lesions of the spontaneous mouse mutation flaky skin (fsn/fsn ). It was found that IL-1 beta was increased by 357% within psoriasiform lesions of fsn/fsn mice compared with their wild-type or heterozygous (+/?) littermates (P < 0.00001). When the IL-1 beta function was inhibited by i.p. injection with a neutralizing MoAb, no effects were seen in +/? mice. In contrast, psoriasiform features in fsn/fsn mice were alleviated dramatically, as demonstrated by a 40% decrease of the epidermal thickness and a diminished number of intra-epidermal microabscesses. In addition, infiltrating epidermal CD4(+) and CD8(+) T cells were decreased by 68% and 81%, respectively (P < 0.05), and epidermal Langerhans cells also were reduced by 36% (P < 0.005). In contrast, mast cells were not affected, suggesting differential responses of various cutaneous cell types. Our results demonstrate an important in vivo role of IL-1 beta for the generation of hyperproliferative inflammatory skin lesions in the fsn/fsn model.

Molecular genetics of the hair follicle: the state of the art

For those who are interested in the biology of skin and its derivatives, these are interesting times indeed. In a mere 5 years, the field has been revolutionized by the application of molecular genetics to human congenital skin disorders. Where dermatology first was limited to observation and empirics, there are now DNA-diagnostics, rational drug design, and perhaps even gene therapy available soon. In particular, the study of rare human syndromes involving abnormalities of hair growth and structure has yielded new insights into the regulation of cell growth and differentiation in the hair follicle. As this structure shows a cyclic pattern of differentiation, it may give new information concerning the regulation of cell differentiation in general. This review covers the recent developments in this fast-moving field. First, we will give a short introduction to (structural) hair biology. Next, we will try to fit these data into the framework of what is already known and attempt to present a unified model for hair follicle growth and differentiation.

Animal models of psoriasis - what can we learn from them?

Research into the pathogenesis of psoriasis has been hampered by the lack of an animal disease resembling this common human skin disorder. Over the past few years, however, various rodent models that mirror aspects of the psoriatic phenotype and pathogenesis have become available. Here, the most prominent models are compared with human psoriasis and potential uses for psoriasis research are reviewed. Asebia (ab), flaky skin (fsn), and chronic proliferative dermatitis (cpd) are spontaneous mouse mutations with psoriasiform skin alterations of unclear pathogenesis. Transgenic mice with cutaneous overexpression of cytokines, such as interferon-gamma, interleukin-1alpha, keratinocyte growth factor, transforming growth factor-alpha, interferon-6, vascular endothelial growth factor, or bone morphogenic protein-6, are valuable tools for studying in vivo effects of individual cytokines in the pathogenesis of psoriasiform features. Psoriasiform lesions also were seen in beta2-integrin hypomorphic mice backcrossed to the PL/J strain and in beta1-integrin transgenic mice. A T cell-based immunopathogenesis of psoriasiform features was shown in a form of graft-versus-host disease in scid/scid mice reconstituted with CD4+/CD45RB(hi) T lymphocytes as well as in HLA-B27/hbeta2m transgenic rats, demonstrating that dysregulated T cells can induce psoriasiform skin alterations without a primary epithelial abnormality. Finally, xenotransplantation models using human skin grafted on to immunodeficient mice are attractive, as different cell types and some environmental factors leading to psoriasiform features may be studied in human tissue. Overall, although there is no animal model imitating psoriasis completely, many aspects of this common human skin disorder are mirrored in the currently available models and psoriatic plaques can be created in xenotransplantation models.

Molecular and functional aspects of the hairless (hr) gene in laboratory rodents and humans

For many years, hairless and rhino mouse mutants have provided a useful and extensively exploited model for studying different aspects of skin physiology, including skin aging, pharmacokinetic evaluation of drug activity and cutaneous absorption, skin carcinogenesis, and skin toxicology. Interestingly, however, hairless and rhino mice have rarely been studied for their primary cellular defect - hairlessness - and thus, the hairless gene itself and its physiological functions have been largely overlooked for decades. The recent identification of the human homolog of the hairless gene on human Chromosome 8p12 confirmed the clinical significance of the phenomenon of "hairlessness" in humans, which was predicted on the basis of similarities between hairless mice and a congenital hair disorder characterized by atrichia with papules. Mutations in the hairless gene of mice provide instructive models for further studies of hr gene function, and may facilitate insights into the pathophysiology of different human disorders associated with the disruption of hr gene activity. We provide an overview of current data on the structure and expression patterns of the hr gene, and of mutations at the hairless locus in mice and humans, including the genetic basis of different alleles, the pathology of hairlessness, reproductive and immunological defects, and susceptibility to dioxin toxicity. On the basis of our current understanding of hairlessness, we speculate on the putative functions of the hr gene product in skin physiology, and particularly, in hair follicle biology.

Murine psoriasis-like disorder induced by naive CD4+ T cells

Psoriasis is a complex disorder involving alterations of many cell types. Although evidence suggests a T-cell pathogenesis for psoriasis, a primary role of T cells has not been directly demonstrated. Here, we show that reconstitution of scid/scid mice with minor histocompatibility mismatched naive CD4+ T lymphocytes resulted in skin alterations that strikingly resembled human psoriasis clinically, histopathologically and in cytokine expression. This skin disorder was diminished when memory T cells were coinjected. Thus, a subset of dysregulated CD4+ T cells can cause tissue alterations seen in psoriasis without the presence of CD8+ cells or a primary epithelial abnormality.

Maintenance of donor phenotype after full-thickness skin transplantation from mice with chronic proliferative dermatitis (cpdm/cpdm) to C57BL/Ka and nude mice and vice versa

Chronic proliferative dermatitis is a spontaneous mutation in C57BL/Ka mice (cpdm/cpdm) and is characterized by epithelial hyperproliferation, infiltration by eosinophils and macrophages, and vascular dilatation. To elucidate whether these pathologic features are the result of a local (skin) process or a consequence of a systemic disorder, transplantations were performed of full-thickness grafts of affected skin from cpdm/cpdm mice and normal skin from control (C57BL/Ka) mice on the back of cpdm/cpdm, C57BL/Ka and athymic nude mice. After 3 months, the grafts maintained the histologic phenotype of the donor animal. Intercellular adhesion molecule-1 continued to be expressed by basal keratinocytes of the cpdm/cpdm grafts after transplantation. In contrast, the basal keratinocytes of the C57BL/Ka grafts onto cpdm/cpdm mice remained negative for intercellular adhesion molecule-1 3 months after transplantation. An increased number of proliferating keratinocytes was present in the cpdm/cpdm skin-graft transplanted to nudes or to C57BL/Ka mice based on short-term bromodeoxyuridine labeling. The bromodeoxyuridine incorporation in the keratinocytes of the control C57BL/Ka skin grafts transplanted to cpdm/cpdm, nude, or C57BL/Ka mice was the same as in the keratinocytes of normal C57BL/Ka mice. This study demonstrates that the pathologic features found in the cpdm/cpdm mice are the result of a disorder in the epidermis or dermis and not due to a systemic defect.

Cutaneous ultrastructural features of the flaky skin (fsn) mouse mutation

An autosomal recessive genetic disease with clinical and histopathological skin features resembling human psoriasis vulgaris occurs naturally in flaky skin mice (fsn/fsn). Affected mice are normal at birth, except for a hypochromic anemia. Subsequently, they develop hyperkeratotic plaques and acanthosis with elongation of rete ridges. Scanning electron microscopic examination revealed a greatly thickened epidermis, a sparsity of hairs and scale accumulations on the epidermal surface. Hair shafts had conspicuous pits, striations, and exophytic protrusions. Nails were bent at a 90 degrees angle with surface irregularities and accumulations of scale at the nail base. Transmission electron microscopic examination showed increased epidermal thickness, mitochondrial aberrations, and intraepidermal invasion by neutrophils. Keratohyalin abnormalities were detected using immunocytochemical staining for profilaggrin. At the dermal-epidermal junction, numerous macrophages and mast cells were seen in close proximity to focal dissolutions of the basement membrane. A high density of collagen fibers and cellular infiltrates were evident in the papillary dermis. This constellation of ultrastructural aberrations is typically found in psoriasis vulgaris and supports the theory that the flaky skin mouse mutation is a naturally occurring analog to one variety of human psoriasis vulgaris.

Ultrastructure of epidermis of mice with chronic proliferative dermatitis

C57BL/Ka mice with chronic proliferative dermatitis (cpdm/cpdm) develop chronic persistent skin lesions characterized by epidermal hyperplasia, infiltration by granulocytes and macrophages, and vascular dilatation. Similar lesions are present in other orthokeratotic epithelia in affected mice, in particular the esophagus and forestomach. Here, we report on further characterization of epidermal hyperplasia and the granulocytes. Keratinocytes of lesional skin, but not of normal skin, show round and electron-dense mitochondrial inclusions that are present in all layers of the epidermis. Similar inclusions are also present in the esophagus and forestomach of affected mice. There appears to be a direct relation between the presence of intramitochondrial inclusions and epidermal hyperplasia in the mouse. Furthermore, the presence of keratinocyte-derived apoptotic bodies in the epidermis, esophagus, and forestomach was frequently observed in the lesions, which is consistent with previous light microscopic observations of single cell death of keratinocytes. The granulocytes present in the skin, esophagus, and forestomach were mainly eosinophils. There were widespread gaps observed in the lamina densa in the epidermis that were mostly directly associated with dermal or epidermal eosinophils. This type of gap is also observed in psoriasiform diseases in humans. This electron microscopic study demonstrated that this mouse model should be useful to screen potential therapeutic strategies for psoriasiform and other inflammatory skin disorders.

Full-thickness skin grafts from flaky skin mice to nude mice: maintenance of the psoriasiform phenotype

Flaky skin (fsn) is an autosomal recessive mouse mutation with papulosquamous disease features similar to human psoriasis. In fsn/fsn skin, one sees marked acanthosis and hyperkeratosis with focal parakeratosis, subcorneal pustules, dermal capillary dilation, and a marked diffuse dermal infiltration of mixed inflammatory cells, predominantly lymphocytes. To determine if these pathologic features are a characteristic of the skin or a chronic autoimmune attack, we placed full-thickness skin grafts from affected homozygous (fsn/fsn) and normal littermate control (+/?) mice on the dorsal skin of genetically athymic nude (nu/nu) mice. After 10 weeks of observation, the grafts maintained the histologic phenotype of the donor animal. In the fsn/fsn grafts, there was persistence of both epidermal proliferation and dermal inflammation, characteristics of the mutation. The fsn/fsn phenotype was also confirmed by immunohistochemical evaluation for specific mouse keratinocyte marker expression. Based on tritiated thymidine uptake, we found DNA synthesis rates elevated threefold or more in fsn/fsn epidermis compared to littermate control mouse skin. Elevated rates of DNA synthesis remained a feature of the fsn/fsn grafts but not that of littermate control skin grafts. This study demonstrates that the psoriasiform phenotype of this mouse mutation can persist independent of the host thymic-derived immune system.

Insertional mutation of the hairless locus on mouse chromosome 14

Crosses between heterozygous transgenic mice from line 5053 produced offspring with progressive irreversible hair loss beginning at day 19. With increasing age, the skin of these animals became thicker and plicated in appearance. Histological analysis revealed the complete absence of normal hair follicles and numerous intradermic cystic structures, which enlarged with time and became filled with keratinaceous material. Test crosses demonstrated that the affected animals are homozygous for the transgene insertion. The clinical and histological phenotype of the new mutant closely resembles that of the rhino allele at the hairless locus on Chromosome (Chr) 14. Complementation tests and linkage analysis indicate that the transgene has interrupted the hairless locus. It has been demonstrated previously that mutation at the hr locus is accompanied by a variety of immune deficiencies. Many of the older affected transgenic mice developed an impetigo-like skin eruption which responded to antibiotic ointment and which may reflect impaired immune function. The transgenic allele, hrTgN5053Mm, will be useful for identification of the transcription unit of the hairless locus.

A genetic linkage map of the mouse: current applications and future prospects

Technological advances have made possible the development of high-resolution genetic linkage maps for the mouse. These maps in turn offer exciting prospects for understanding mammalian genome evolution through comparative mapping, for developing mouse models of human disease, and for identifying the function of all genes in the organism.

Epidermal dendritic cell populations in the flaky skin mutant mouse

Flaky skin (gene symbol: fsn) is an autosomal recessive mouse mutation that causes pathologic changes in the skin yielding a papulosquamous disease resembling human psoriasis. Preliminary studies of epidermal sheets from foot pads of fsn/fsn mice stained for Ia+ Langerhans cells (LC) or Thy-1+ dendritic epidermal cells (Thy-1+ DEC) indicated a rise in LC numbers at the time of weaning, when the skin lesion becomes clinically evident. To further investigate this observation, epidermal sheets were obtained from the ear, dorsal skin, and foot pads from replicates of 6 female mice (both mutants and normal littermates) on weekly intervals from birth to 8 weeks of age. Dorsal skin epidermal thickness was quantitated by computer assisted image analysis and found to be significantly thickened from one week onward in the mutant mice. Using immunofluorescence microscopy, epidermal dendritic cell numbers were determined following staining with antibodies for the following markers: Ia, NLDC-145, and S-100 (for LC) or Thy 1.2 and asialo-GM1 (for Thy-1+ DEC). Use of all 5 markers to evaluate skin from 3 different locations yielded a subtle but significant increase in LC and Thy-1+ DEC in flaky skin mice. Of the three sites evaluated, the dorsal skin and ear epidermal sheets were most informative, which corresponded to the degree of pathological involvement. Mice doubly homozygous for fsn and for the severe combined immunodeficiency (scid) mutation developed the psoriasiform dermatitis. Bone marrow grafts from fsn/fsn homozygotes to homozygous scid/scid mice reproduce the skin lesion. These studies suggest that the psoriasiform dermatitis in the flaky skin mouse mutation is associated with abnormalities at the level of hematopoietic progenitor cells.

Forestomach papillomas in flaky skin and steel-Dickie mutant mice

Gastric papillomas were diagnosed in flaky skin (fsn/fsn) and steel-Dickie (Sl/Sld) mutant mice but not littermate controls. Both mutants suffer from severe anemia of differing causes. Immunohistochemical screening and Southern blot analyses failed to detect any evidence of a papillomavirus in the gastric lesions. Phenotypic expression of the fsn and Sld mutant genes may play an essential role in the spontaneous development of forestomach papillomas in these mouse mutants.