MicroRNAs: novel regulators in skin inflammation

Compelling evidence indicates that microRNAs (miRNAs), short, non-protein coding RNAs, are critical for the development and survival of multicellular organisms. Recently, miRNAs were implicated in the pathogenesis of psoriasis and atopic eczema (AE), the two most common chronic inflammatory disorders in skin. In particular, miR-203, the first skin-specific miRNA, showing an intriguing expression profile being confined to skin epithelium, is specifically overexpressed in psoriasis. MiR-146a, another miRNA showing specific upregulation in psoriasis, is involved in the regulation of innate immune responses and the tumour necrosis factor (TNF)-alpha pathway. Interestingly, miR-125b, another miRNA involved in the TNF-alpha pathway, is also deregulated in psoriasis and AE. As skin inflammation may serve as a model for chronic inflammatory disorders, it is likely that miRNAs involved in skin inflammation will eventually emerge in other inflammatory or autoimmune disorders, and some of these may become disease markers and therapeutic targets. In this review we present an overview of what is currently known about the roles of miRNAs in chronic inflammatory skin disorders.     

Schwann cells as underestimated,major players in human skin physiology and pathology

Schwann cells (SCs) have long been recognized for their ability to support repair and promote axon regeneration following injury to the peripheral nervous system. In response to nerve injury, they rapidly dedifferentiate into a precursor-like state, secrete an array of inflammatory mediators and growth factors, proliferate, undergo epithelial-to-mesenchymal-like transformation to facilitate migration, phagocytose cellular debris and remodel the extracellular environment to promote regeneration of axons through the site of injury. However, even though a cutaneous role for SCs is becoming increasingly recognized, we argue in this Viewpoint essay that the likely complex functions of SCs in skin physiology and pathology beyond skin sensation and nerve repair deserve more attention and systemic research than they have received so far. For example, SCs promote wound healing, disseminate infection in leprosy, support the growth of neurofibromas/schwannomas and facilitate/accelerate the growth and invasion of melanoma. Despite representing a major dermal cell population, comparatively little is still known about the role of SCs in other dermatoses. To quintessentially illustrate the opportunities that promise to arise from a new skin research focus on SCs, we focus on two dermatoses that are not traditionally associated with SCs, that is, psoriasis and atopic dermatitis (AD), since both show distinct SC changes along with continuous nerve fibre degeneration and regeneration, and an impact of denervation on skin lesions. Specifically, we critically discuss the hypothesis that repeated activation of the SC repair programme occurs in and contributes to psoriasis and AD and delineate experimental approaches how to probe this clinically relevant hypothesis.     

Patterns in naevoid skin disease: development,disease and modelling

Please cite this paper as: Patterns in naevoid skin disease: development, disease and modelling. Experimental Dermatology 2010; 19: 240–245. Abstract: The aetiology of pattern‐formation in human naevoid skin disease remains unknown. However, it is likely that the majority of previously proposed mechanisms – those that simply rely on passive clonal trafficking in embryogenesis – are incomplete. A more comprehensive explanation for pattern‐formation in naevi invokes the principle of self‐organization. We define two types of patterning: anatomical and functional. Anatomical patterning is where the abnormal clone is limited to regions of pathologic skin, while functional patterning is where the abnormal clone and pathologic skin are spatially uncorrelated. From a theoretical perspective self‐organized naevoid patterns may be either secondary to local interactions between normal and aberrant genotypes or due to the interaction between aberrant genotypes and the presence of normal embryonic patterning cues. The latter possibility suggests the critical observation and analysis of patterns in naevoid skin disease may lead to unique insights into key aspects of early human embryogenesis.     

MicroRNAs in skin wound healing

Wound healing is a fundamental physiological progress to keep the integrity of the skin. The transition from inflammation to proliferation is a critical step during skin wound repair process. Impairment of this transition has been known as a common dominator in the pathophysiology of chronic non-healing wounds. MicroRNAs (miRNAs) are short non-coding RNAs regulating gene expression. Emerging evidence has revealed that miRNAs play important roles in both normal skin wound healing and in the pathogenesis of chronic wounds. We focus on the miRNAs regulating the inflammation-proliferation transition during wound healing and propose that these miRNAs may be promising targets for development of more effective wound therapy.     

皮肤发育成形及创伤愈合与microRNA

microRNA是一类小分子非编码RNA,长度大约为21～25个核苷酸.其通过与靶mRNA的互补结合,造成mRNA降解、蛋白表达抑制,从而在多种种属、多种组织以及多种疾病中,发挥着转录后调控的作用.近年的研究表明,microRNA在皮肤发育成形中有着重要的调节作用,并且与许多皮肤疾病、肿瘤以及创伤修复存在着相关性.进一步研究microRNA与创伤愈合的关系,为皮肤创伤的治疗提供新的思路及新靶点.     

Nitric oxide and its implications in skin homeostasis and disease – a review

Abstract The recent identification of the nitric oxide synthase (NOS) pathway in various cell types in the skin has provided important insight into the molecular mechanisms underlying regulatory and homeostatic functions of the skin. Many studies also point to perturbations or defects in the signaling cascade of nitric oxide (NO) and reactive nitrogen intermediates as key players in skin disease pathogenesis. A critical role for NO is now established for a subset of human skin diseases, and new mechanism-based therapies may be available in the near future. This remarkable progress and the implications it may have for common forms of skin disease are reviewed here. Received: 22 June 1998 / Accepted: 31 August 1998     

Wnt signaling in skin homeostasis and pathology

The mammalian skin mediates the primary interphase between the body and the external environment and provides the first line of defense against pathogens, mechanical trauma, sunlight injuries, and chemical stress. Proper physical, biochemical, and immunological composition of the skin is necessary to maintain its barrier function. Therefore, the skin reflects a complex dynamic organ with high cellular turnover during normal tissue replacement and wound repair. Stem cell reservoirs ensure constant skin renewal. Wnt signaling controls stem cell maintenance and fate decisions in various tissues and also reflects a key pathway in controlling skin development and homeostasis. Disruption of Wnt signaling in the skin causes disorders such as alopecia, chronic inflammatory skin diseases or cancer. This review summarizes the role of Wnt signaling during skin development, homeostasis, and disease.     

Homeobox transcription factor DLX4 is not necessary for skin development and homeostasis

Dlx4 is a member of a family of homeobox genes with homology to Drosophila distal‐less (dll) gene. We show that Dlx4 expression pattern partially overlaps with its cis‐linked gene Dlx3 during mouse development as well as in neonatal and adult skin. In mice, Dlx4 is expressed in the branchial arches, embryonic limbs, digits, nose, hair follicle and in the basal and suprabasal layers of mouse interfollicular epidermis. We show that inactivation of Dlx4 in mice did not result in any overtly gross pathology. Skin development, homeostasis and response to TPA treatment were similar in mice with loss of Dlx4 compared to wild‐type counterparts.     

The role of ceramides in skin homeostasis and inflammatory skin diseases

Ceramides, members of sphingolipid family, are not only the building blocks of epidermal barrier structure, but also bioactive metabolites involved in epidermal self-renewal and immune regulation. Hence, abnormal ceramide expression profile is recognized to defect extracellular lipid organization, disturb epidermal self-renewal, exacerbate skin immune response and actively participate in progression of several inflammatory dermatoses, exemplifying by psoriasis and atopic dermatitis. Here, we discuss recent advances in understanding skin ceramides and their regulatory roles in skin homeostasis and pathogenic roles of altered ceramide metabolism in inflammatory skin diseases. These insights provide new opportunities for therapeutic intervention in inflammatory dermatoses.     

Activated Kras alters epidermal homeostasis of mouse skin, resulting in redundant skin and defective hair cycling

Germline mutations in the RAS-mitogen-activated protein kinase (RAS/MAPK) pathway are associated with genodermatoses, characterized by cutaneous, cardiac, and craniofacial defects, and cancer predisposition. Whereas activating mutations in HRAS are associated with the vast majority of patients with Costello syndrome, mutations in its paralog, KRAS, are rare. To better understand the disparity among RAS paralogs in human syndromes, we generated mice that activate a gain-of-function Kras allele (Lox-Stop-Lox (LSL)-Kras(G12D)) in ectodermal tissue using two different Cre transgenic lines. Using Msx2-Cre or ligand-inducible keratin 15 (K15)-CrePR, the embryonic effects of activated Kras were bypassed and the effects of Kras(G12D) expression from its endogenous promoter were determined. We found that Kras(G12D) induced redundant skin, papillomas, shortened nails, and hair loss. Redundant skin was associated with basal keratinocyte hyperplasia and an increase in body surface area. Paradoxically, Kras(G12D) also prevented hair cycle activation. We find that Kras(G12D) blocks proliferation in the bulge region of the hair follicle, when activated through Msx2-Cre but not through K15-CrePR. These studies reveal that KRAS, although infrequently involved in RAS/MAPK syndromes, is capable of inducing multiple cutaneous features that grossly resemble human RAS/MAPK syndromes.     

Epidermal homeostasis in long-term scaffold-enforced skin equivalents

Epidermal homeostasis is understood as the maintenance of epidermal tissue structure and function by a fine tuned regulatory mechanism balancing proliferation and cell loss by desquamation and apoptosis. The lack of appropriate experimental models has largely prevented a better understanding of the regulatory mechanisms controlling epidermal tissue homeostasis in human skin. Keratinocyte culture studies had revealed a strict dependency of regular epidermal differentiation on dermal interactions only accomplishable in three-dimensional skin models. As major drawbacks, conventional models, employing collagen hydrogels as dermal equivalents (DEs) exhibit a rather poor stability and limited lifespan. Here, we present an improved stabilized in vitro-model for long-term growth and differentiation of keratinocytes providing the basis for tissue homeostasis. Keratinocytes were grown on DEs reinforced by modified hyaluronic acid fibers (Hyalograft-3D) and colonized with skin fibroblasts, producing genuine dermis-type matrix. These skin equivalents (SEs) develop superior epidermal architecture with regular differentiation and ultrastructure. Critical aspects of differentiation, still unbalanced in early stages, are renormalized, most strikingly the coexpression of keratins K1/K10, downregulation of regeneration-associated keratins (K16), and restriction of K15 to the basal layer. The strict localization of integrins to basal cells underlining restored tissue polarity, the drop of keratinocyte growth rates towards physiological levels and the rapid formation of a mature basement membrane with abundant anchoring fibrils are altogether features fulfilling the criteria of tissue homeostasis. Therefore, these scaffold-based SEs not only allow for studying homeostasis control but also for the first time provide proper experimental conditions for establishing a stem cell niche in vitro.     

Effects and mechanisms of histatins as novel skin wound-healing agents

Wound healing is a complex and important physiological process that maintains the integrity of skin after various injuries. Abnormal wound healing, especially of chronic wounds, impairs normal physical function. Therefore, the search for effective and safe healing agents is one of the main concerns. Histatins are histidine-rich low molecular weight peptides that are expressed in the saliva of both humans and higher primates. Histatins have two main biological effects, cell stimulation and bacteria killing, with the former playing an important role in wound healing by promoting epithelial cell and fibroblast migration and angiogenesis and enhancing the re-epithelialization of the wounded area. Because of these biological effects, histatins have been shown to be promising agents of improved wound healing. Histatins are categorized into many subtypes, of which histatin 1 and its hydrolysates are the most effective in promoting wound healing. This review addresses the bioactivity of histatins in wound healing, such as their stimulatory effects on epithelial cells and fibroblasts, and elucidates the possible mechanisms by which histatin subtypes induce their biological effects.