Paul Hoover

Mitochondrial reactive oxygen species promote epidermal differentiation and hair follicle development

Skin development requires reactive oxygen species generated by mitochondria in keratinocytes. Building a Barrier Mitochondria are an important source of reactive oxygen species (ROS), which participate in diverse signaling pathways. To test the role of mitochondrially produced ROS in epidermal development, Hamanaka et al. generated mice with keratinocytes lacking mitochondrial transcription factor A (TFAM), which is required for transcription of genes encoded by mitochondrial DNA, including those that proteins required for ROS generation. The epidermis of these mice was abnormally thick, lacked hair, and showed defects in differentiation and barrier function, which likely contributed to perinatal death. Keratinocytes from these mice did not produce mitochondrial ROS and showed impaired Notch signaling, which is involved in epidermal differentiation, and β-catenin signaling, which is required for growth of hair follicles. Thus, signaling pathways involved in skin development rely on the production of ROS generated by mitochondria. Proper regulation of keratinocyte differentiation within the epidermis and follicular epithelium is essential for maintenance of epidermal barrier function and hair growth. The signaling intermediates that regulate the morphological and genetic changes associated with epidermal and follicular differentiation remain poorly understood. We tested the hypothesis that reactive oxygen species (ROS) generated by mitochondria are an important regulator of epidermal differentiation by generating mice with a keratinocyte-specific deficiency in mitochondrial transcription factor A (TFAM), which is required for the transcription of mitochondrial genes encoding electron transport chain subunits. Ablation of TFAM in keratinocytes impaired epidermal differentiation and hair follicle growth and resulted in death 2 weeks after birth. TFAM-deficient keratinocytes failed to generate mitochondria-derived ROS, a deficiency that prevented the transmission of Notch and β-catenin signals essential for epidermal differentiation and hair follicle development, respectively. In vitro keratinocyte differentiation was inhibited in the presence of antioxidants, and the decreased differentiation marker abundance in TFAM-deficient keratinocytes was partly rescued by application of exogenous hydrogen peroxide. These findings indicate that mitochondria-generated ROS are critical mediators of cellular differentiation and tissue morphogenesis.

FibronectinEDA Promotes Chronic Cutaneous Fibrosis Through Toll-Like Receptor Signaling

FibronectinEDA is an endogenous TLR4 ligand in scleroderma. Scleroderma Takes Its Toll Scleroderma is a disease where the immune system attacks the connective tissues of the body, with notable hardening of the skin and fibrosis in multiple organs. However, what causes scleroderma—and the associated persistent fibrosis activation—remains unknown. Bhattacharyya et al. now report that the fibronectin extra domain A (FnEDA)—an endogenous damage-induced TLR4 ligand—may contribute to cutaneous fibrosis. The authors found that FnEDA is elevated in lesions and circulation both of patients with scleroderma and of a mouse model of fibrosis. FnEDA was up-regulated by TGF-β in healthy fibroblasts. In vitro, FnEDA increased mechanical stiffness of human skin equivalents. Indeed, the profibrotic responses induced by FnEDA were dependent on TLR4 signaling and could be blocked by genetic, RNA interference, and pharmacologic TLR4 inhibition. These data suggest that a damage-induced TLR4 signaling may contribute to fibrogenesis in scleroderma. Scleroderma is a progressive autoimmune disease affecting multiple organs. Fibrosis, the hallmark of scleroderma, represents transformation of self-limited wound healing into a deregulated self-sustaining process. The factors responsible for maintaining persistent fibroblast activation in scleroderma and other conditions with chronic fibrosis are not well understood. Toll-like receptor 4 (TLR4) and its damage-associated endogenous ligands are implicated in immune and fibrotic responses. We now show that fibronectin extra domain A (FnEDA) is an endogenous TLR4 ligand markedly elevated in the circulation and lesional skin biopsies from patients with scleroderma, as well as in mice with experimentally induced cutaneous fibrosis. Synthesis of FnEDA was preferentially stimulated by transforming growth factor–β in normal fibroblasts and was constitutively up-regulated in scleroderma fibroblasts. Exogenous FnEDA was a potent stimulus for collagen production, myofibroblast differentiation, and wound healing in vitro and increased the mechanical stiffness of human organotypic skin equivalents. Each of these profibrotic FnEDA responses was abrogated by genetic, RNA interference, or pharmacological disruption of TLR4 signaling. Moreover, either genetic loss of FnEDA or TLR4 blockade using a small molecule mitigated experimentally induced cutaneous fibrosis in mice. These observations implicate the FnEDA-TLR4 axis in cutaneous fibrosis and suggest a paradigm in which aberrant FnEDA accumulation in the fibrotic milieu drives sustained fibroblast activation via TLR4. This model explains how a damage-associated endogenous TLR4 ligand might contribute to converting self-limited tissue repair responses into intractable fibrogenesis in chronic conditions such as scleroderma. Disrupting sustained TLR4 signaling therefore represents a potential strategy for the treatment of fibrosis in scleroderma.

Fibronectin Expression Determines Skin Cell Motile Behavior

Mouse keratinocytes migrate significantly slower than their human counterparts in vitro on uncoated surfaces. We tested the hypothesis that this is a consequence of differences in the extracellular matrix (ECM) that cells deposit. In support of this, human keratinocyte motility was dramatically reduced when plated onto the ECM of mouse skin cells whereas the latter cells migrated faster when plated onto human keratinocyte ECM. The ECM of mouse and human keratinocytes contained similar levels of the α3 laminin subunit of laminin-332. However, mouse skin cells expressed significantly more fibronectin (FN) than human cells. To assess whether FN is a motility regulator, we utilized siRNA to reduce expression of FN in mouse keratinocytes. The treated mouse keratinocytes moved significantly more rapidly than wild-type mouse skin cells. Moreover, the FN depleted mouse cell ECM supported increased migration of both mouse and human keratinocytes. Furthermore, the motility of human keratinocytes was slowed when plated onto FN-coated substrates or human keratinocyte ECM supplemented with FN in a dose dependent manner. Consistent with these findings, the ECM of α3 integrin-null keratinocytes, which also migrated faster than wild-type cells, was FN deficient. Our results provide evidence that FN is a brake to skin cell migration supported by laminin-332-rich matrices.

Alteration of the EphA2/Ephrin-A signaling axis in psoriatic epidermis.

EphA2 is a receptor tyrosine kinase (RTK) that triggers keratinocyte differentiation upon activation and subsequently down-regulation by ephrin-A1 ligand. The objective for this study was to determine if the EphA2/ephrin-A1 signaling axis was altered in psoriasis, an inflammatory skin condition where keratinocyte differentiation is abnormal. Microarray analysis of skin biopsies from psoriasis patients revealed increased mRNA transcripts for several members of this RTK family in plaques, including the EphA1, EphA2 and EphA4 subtypes prominently expressed by keratinocytes. Of these, EphA2 showed the greatest up-regulation, a finding that was confirmed by quantitative RT-PCR, IHC analysis and ELISA. In contrast, psoriatic lesions exhibited reduced ephrin-A ligand immunoreactivity. Exposure of primary keratinocytes induced to differentiated in high calcium or a 3-dimensiosnal raft culture of human epidermis to a combination of growth factors and cytokines elevated in psoriasis increased EphA2 mRNA and protein expression while inducing S100A7 and disrupting differentiation. Pharmacological delivery of a soluble ephrin-A1 peptidomimetic ligand led to a reduction in EphA2 expression and ameliorated proliferation and differentiation in raft cultures exposed to EGF and IL-1α. These findings suggest that ephrin-A1-mediated down-regulation of EphA2 supports keratinocyte differentiation in the context of cytokine perturbation.

In Vitro Model of the Epidermis

Much of our understanding of the biological processes that underlie cellular functions in humans, such as cell-cell communication, intracellular signaling, and transcriptional and posttranscriptional control of gene expression, has been acquired from studying cells in a two-dimensional (2D) tissue culture environment. However, it has become increasingly evident that the 2D environment does not support certain cell functions. The need for more physiologically relevant models prompted the development of three-dimensional (3D) cultures of epithelial, endothelial, and neuronal tissues (Shamir & Ewald, 2014). These models afford investigators with powerful tools to study the contribution of spatial organization, often in the context of relevant extracellular matrix and stromal components, to cellular and tissue homeostasis in normal and disease states.

In Vitro Model of the Epidermis: Connecting Protein Function to 3D Structure.

Much of our understanding of the biological processes that underlie cellular functions in humans, such as cell-cell communication, intracellular signaling, and transcriptional and posttranscriptional control of gene expression, has been acquired from studying cells in a two-dimensional (2D) tissue culture environment. However, it has become increasingly evident that the 2D environment does not support certain cell functions. The need for more physiologically relevant models prompted the development of three-dimensional (3D) cultures of epithelial, endothelial, and neuronal tissues (Shamir & Ewald, 2014). These models afford investigators with powerful tools to study the contribution of spatial organization, often in the context of relevant extracellular matrix and stromal components, to cellular and tissue homeostasis in normal and disease states.