Julia Weise

The matricellular protein periostin contributes to proper collagen function and is downregulated during skin aging

BACKGROUND Periostin is a secreted 90kDa matricellular protein, which is predominantly expressed in collagen-rich tissues. Collagen is the most abundant protein in mammals and has great tensile strength. Recent investigations have shown that periostin influences collagen fibrillogenesis and biomechanical properties of murine connective tissues. OBJECTIVE We investigated the function of periostin concerning collagen homeostasis during intrinsic and extrinsic skin aging. For this purpose, human skin samples of young and old donors as well as samples of photoaged and sun-protected skin areas were analyzed for periostin expression. Using in vitro models, we determined the cell types responsible for periostin expression and performed functional analyses with periostin knockdown cells. METHODS TaqMan Real-Time PCR, UV irradiation, knockdown experiments, immunostaining, electron microscopy, collagen degradation assay, collagen crosslink analysis. RESULTS Periostin expression is highest in the papillary dermis and downregulated during skin aging. Fibroblasts and non-follicular skin derived precursors were identified as main source for periostin expression in human skin. Periostin knockdown in fibroblasts has no effect on collagen expression, but results in an increased fibril diameter and aberrant collagen structure. This leads to an increased susceptibility of collagen toward proteases, whereas recombinant periostin protects collagen fibrils from degradation. CONCLUSION Our data show that periostin plays an important role for proper collagen assembly and homeostasis. During skin aging periostin expression decreases and contributes to the phenotype of aged skin.

UV-mediated downregulation of the endocytic collagen receptor, Endo180, contributes to accumulation of extracellular collagen fragments in photoaged skin

BACKGROUND Collagen is the most abundant protein in human skin and is responsible for its resilience. In particular during photoaging, collagen homeostasis is out of balance leading to a continuous loss of intact collagen and to the observed signs of aged skin such as diminished tensile strength and wrinkle development. The process of collagen turnover is very slow and the relevance of cellular uptake of damaged collagen, most likely mediated via Endo180 or integrin α2β1, still remains a matter of investigation. OBJECTIVE We investigated the role of different collagen receptors on dermal fibroblasts for collagen internalization and their impact on collagen homeostasis during photoaging. METHODS TaqMan Real-Time PCR, flow cytometry, UV irradiation, knockdown experiments and immunostaining. RESULTS We show that Endo180 and integrin α2 are regulated in photoaged skin and after acute UV stress in vivo and in vitro. Knockdown experiments revealed that Endo180 is essential for cellular uptake of collagen fragments by dermal fibroblasts, whereas integrin α2 is important for initial binding of collagen. UV irradiation decreases collagen endocytosis. This correlates with reduced Endo180 expression and pericellular accumulation of collagen fragments during photoaging. CONCLUSION Our findings correlate for the first time impaired collagen uptake via Endo180 with the pericellular accumulation of collagen fragments during photoaging. We assume an altered pericellular niche of fibroblasts in photoaged skin that has an impact on collagen homeostasis.

A tissue-engineered human dermal construct utilizing fibroblasts and transforming growth factor β1 to promote elastogenesis

Numerous studies have shown that extracellular matrix (ECM)-based scaffolds are suitable for dermal constructs for the differentiation of various cell types in vitro and for constructive tissue remodeling after implantation in vivo. However, a shortcoming of these ECM materials is its limited elastogenesis. Elastic fibers constitute an essential component of mammalian connective tissue and the presence of elastic fibers is crucial for the proper function of the cardiovascular, pulmonary, and intestinal systems. Since it is still largely unknown how cells coordinate the molecular events of elastic-fiber assembly, understanding the ability to regenerate elastic fibers in tissues remains a significant challenge. For this reason, human neonatal dermal fibroblasts (HDFneo) were analyzed for their potential to serve as a cell culture model for elastic fiber assembly. Using optical technologies such as multiphoton laser-scanning microscopy (MPSLM) we demonstrate that HDFneo stimulated with transforming growth factor β1 (TGF-β1) are able to produce a distinct and complex elastic fiber system in vitro. As shown by the desmosine and isodesmosine content, crosslinked elastic fibers were formed within the 3D ECM-based scaffold. This tissue-engineered dermal construct may prove to be an effective template for the development of medicinal approaches in regenerative soft skin tissue reconstruction through TGF-β1 induction.

Damage at the root of cell renewal—UV sensitivity of human epidermal stem cells

BACKGROUND The epidermis harbors adult stem cells that reside in the basal layer and ensure the continuous maintenance of tissue homeostasis. Various studies imply that stem cells generally possess specific defense mechanisms against several forms of exogenous stress factors. As sun exposition is the most prevalent impact on human skin, this feature would be of particular importance in terms of sensitivity to UV-induced DNA damage. OBJECTIVE To investigate whether human epidermal stem cells are susceptible to UV-induced DNA damage and subsequent functional impairment. METHODS A method to isolate human epidermal stem cells from suction blister epidermis was established and validated. Volunteers were treated with solar-simulated irradiation on test areas of the forearm and stem cells were isolated from suction blister material of this region. DNA damage was analyzed by staining for cyclobutane thymidine dimers. The functional consequences of UV-induced damages were assessed by colony forming efficiency assays and gene expression analyses. RESULTS Compared to an unirradiated control, stem cells isolated from areas that were exposed to solar-simulated radiation showed significantly more DNA lesions. Although the number of stem cells was not reduced by this treatment, a functional impairment of stem cells could be shown by reduced colony forming efficiency and altered gene expression of stem cell markers. CONCLUSIONS Despite their essential role in skin maintenance, epidermal stem cells are sensitive to physiological doses of UV irradiation in vivo.