Hans Smola

Overexpression of activin A in the skin of transgenic mice reveals new activities of activin in epidermal morphogenesis, dermal fibrosis and wound repair

Recently we demonstrated a strong induction of activin expression after skin injury, suggesting a function of this transforming growth factor‐β family member in wound repair. To test this possibility, we generated transgenic mice that overexpress the activin βA chain in the epidermis under the control of a keratin 14 promoter. The transgenic mice were significantly smaller than control littermates, and they had smaller ears and shorter tails. In their skin, the fatty tissue was replaced by connective tissue and a severe thickening of the epidermis was found. The spinous cell layer was significantly increased, and the epidermal architecture was highly disorganized. These histological abnormalities seem to result from increased proliferation of the basal keratinocytes and abnormalities in the program of keratinocyte differentiation. After skin injury, a significant enhancement of granulation tissue formation was detected in the activin‐overexpressing mice, possibly as a result of premature induction of fibronectin and tenascin‐C expression. These data reveal novel activities of activin in the regulation of keratinocyte proliferation and differentiation as well as in dermal fibrosis and cutaneous wound repair.

Paracrine regulation of keratinocyte proliferation and differentiation

The histoarchitecture and function of the epidermis depend on a well-controlled balance between keratinocyte proliferation and differentiation. This balance is perturbed after skin injury, and imbalance is a characteristic feature of major human skin diseases such as psoriasis and epidermal cancers. Recent studies have highlighted the importance of fibroblast-derived soluble factors for the regulation of keratinocyte proliferation and differentiation. Therefore, identification of these paracrine-acting factors and the elucidation of their mechanisms of action are necessary for understanding epidermal homeostasis, repair and disease, and these approaches will offer new potential targets for drug therapy. Here, we review exciting recent findings on the identification, regulation and function of paracrine-acting cytokines in the skin. In particular, we describe the role of fibroblast-derived mitogens as regulators of keratinocyte proliferation and differentiation, and we summarize the regulation of these factors by keratinocyte-derived interleukin 1 that involves the transcription factors c-Jun and JunB.

Myofibroblast Differentiation Is Induced in Keratinocyte-Fibroblast Co-Cultures and Is Antagonistically Regulated by Endogenous Transforming Growth Factor-β and Interleukin-1

In wound healing epidermal-dermal interactions are known to regulate keratinocyte proliferation and differentiation. To find out how fibroblasts respond to epithelial stimuli, we characterized fibroblasts in monolayer co-culture with keratinocytes. On co-culture numerous extracellular matrix- and smooth muscle cell-associated gene transcripts were up-regulated in fibroblasts, suggesting a differentiation into myofibroblasts. Increased alpha-smooth muscle actin (alpha-SMA) protein expression in co-cultured fibroblasts started at approximately day 4, was serum-independent, but required endogenous transforming growth factor (TGF)-beta. In co-cultures, TGF-beta neutralizing monoclonal antibody strongly reduced alpha-SMA induction. Endogenous TGF-beta production and activation were increased at 24 and 48 hours, requiring, like alpha-SMA induction, close keratinocyte-fibroblast proximity. As myofibroblast differentiation only started after 4 days, we analyzed the presence of endogenous inhibitors at early time points. Blocking keratinocyte-derived interleukin (IL)-1 using IL-1 receptor antagonist, alpha-SMA expression in co-cultures was potentiated. Conversely, adding exogenous IL-1alpha completely suppressed endogenous alpha-SMA induction. In co-cultured fibroblasts strong nuclear factor-kappaB binding activity was observed from 2 hours, decreasing at 2 and 4 days, suggesting an early, IL-1-mediated inhibition of TGF-beta signaling in co-cultured fibroblasts. This biphasic differentiation event is regulated by the balance of endogenous TGF-beta and IL-1 activity and is reminiscent of myofibroblast differentiation at early and later stages of wound healing.

Dissecting the roles of endothelin,TGF-β and GM-CSF on myofibroblast differentiation by keratinocytes

Myofibroblasts are specialized fibroblasts that contribute to wound healing by producing extracellular matrix and by contracting the granulation tissue. They appear in a phase of wound healing when the dermis strongly interacts with activated epidermal keratinocytes. Direct co-culture with keratinocytes upregulates TGFbeta activity and also induces fibroblast to differentiate into alpha-smooth muscle actin (alphaSMA)-positive myofibroblasts. TGF-beta activity alone cannot completely account for alphaSMA induction in these co-cultures, and here we analyze mechanical force generation, another potent inducer of myofibroblast differentiation in this model. Using deformable silicone substrates, we show that contractile activity of fibroblasts is already induced after 1-2-days of co-culture, when fibroblasts are generally alphaSMA negative. Endothelin-1 (ET-1), the most potent inducer of smooth muscle cell contraction, was up-regulated in co-cultures, while blocking ET-1 with the ET receptor inhibitor PD156252 inhibited contraction in these early co-cultures. In 4-5 days of co-culture, however, fibroblast contractile activity correlated with an increased expression of alphaSMA expression. Stimulation of fibroblast mono-cultures with ET-1 in a low serum medium did not induce alphaSMA expression; however, ET-1 did synergize with TGF-beta. Surprisingly, GM-CSF, another mediatorstimulating myofibroblast differentiation in granulation tissue, inhibited alphaSMA expression in fibroblasts, costimulated with TGF-beta and ET-1. GM-CSF activated NFkappaB, thus interfering with TGF-beta signaling. Blocking TGFbeta and ET-1 largely impaired alphaSMA induction in co-cultures at day 7 and, in combination, almost completely prevented alphaSMA induction. Our results dissect the roles of TGF-beta and ET-1 on mechanical force generation in keratinocyte-fibroblast co-cultures, and identify GM-CSF as an inducer of myofibroblasts acting indirectly.

Treatment of Chronic Wounds: State of the Art and Future Concepts

The morbidity and mortality from chronic wounds of varying etiology present a significant health care problem. Multiple local disturbances and systemic disease can impair wound healing. Recently, experiments with tissue cultures and animal models have revolutionized the understanding of wound healing and the pathophysiological processes involved. In cooperation with clinicians and industrial partners novel therapeutic concepts including the topical application of growth factors and cell therapies have been developed. Cytokines that have been tested in clinical studies include epidermal growth factor, platelet-derived growth factor and fibroblast growth factor. These studies showed that an important aspect of the growth factor wound healing paradigm is the effective delivery of these polypeptides to the wound site. Current drug delivery strategies suffer from the inherent loss of drug activity due to the combined effects of physical inhibition and biological degradation. A molecular genetic approach in which genetically modified cells synthesize and deliver the desired growth factor in a time-regulated manner is a powerful means to overcome the limitations associated with the topical application of recombinant growth factor proteins.

The inhibition of matrix metalloproteinase activity in chronic wounds by a polyacrylate superabsorber

Excessive matrix metalloproteinase (MMP) levels have been observed in wound fluid of impaired healing wounds. This is thought to interfere with granulation tissue formation as newly formed extracellular matrix and cytokines are degraded and the wound becomes deadlocked, unable to progress to the next healing stages. In the cleansing phase, associated with high MMP activity levels, hydroactive wound dressings containing polyacrylate superabsorber particles are particularly effective. We tested whether these particles can block MMP activity in wound fluid obtained from chronic venous leg ulcers. Polyacrylate superabsorber particles inhibited MMP activity by more than 87% in a fluorogenic peptide substrate assay. Further analysis revealed two underlying molecular mechanisms. First, experiments showed direct binding of MMPs to the particles. Secondly, polyacrylate superabsorber particles can bind Ca2+ and Zn2+ ions competing with MMPs for divalent ions required for enzymatic activity. Furthermore, we provide the first evidence in vivo that MMPs bind effectively to polyacrylate superabsorber particles within the hostile environment of chronic wounds. We conclude that polyacrylate superabsorber particles can rescue the highly proteolytic microenvironment of non-healing wounds from MMP activity so that more conductive conditions allow healing to proceed.

Defective Laminin 5 Processing in Cylindroma Cells

Cylindromas are benign skin tumors occurring as multiple nodules characteristically well circumscribed by an excess of basement membrane-like material. To determine the molecular defects leading to extracellular matrix accumulation, the ultrastructural, immunological, and biochemical properties of cylindroma tissue and isolated cells were analyzed. In cylindromas, hemidesmosomes are reduced in number, heterogeneous and immature compared to the normal dermal-epidermal junction. Expression of the alpha6beta4 integrin in tumor cells is weaker than in basal keratinocytes of the epidermis. Moreover, although in the epidermis alpha2beta1-integrin expression is restricted to the basal cell layer, it is found in all neoplastic cells within the nodules. Laminin 5 is present throughout the whole thickness of the basement membrane-like zone whereas laminin 10 is restricted to the interface adjacent to the tumor cells. Furthermore, laminin 5 is not properly processed and most of the alpha3A and gamma2 laminin chains remain as 165-kd and 155-kd polypeptides, respectively. Mature laminin 5 is thought to be necessary for correct hemidesmosome and basement membrane formation and its abnormal processing, as well as the low expression of alpha6beta4 integrins, could explain the lack of mature hemidesmosomes. Together, the results show that multiple molecular defects, including alteration of laminin 5 and its integrin receptors, contribute to structural aberrations of the basement membrane and associated structures in cylindromas.

Alternative Proteolytic Processing of Hepatocyte Growth Factor during Wound Repair

Wound healing is a crucial regenerative process in all organisms. We examined expression, integrity, and function of the proteins in the hepatocyte growth factor (HGF)/c-Met signaling pathway in normally healing and non-healing human skin wounds. Whereas in normally healing wounds phosphorylation of c-Met was most prominent in keratinocytes and dermal cells, in non-healing wounds phosphorylation of c-Met was barely detectable, suggesting reduced c-Met activation. In wound exudates obtained from non-healing, but not from healing wounds, HGF protein was a target of substantial proteolytic processing that was different from the classical activation by known serine proteases. Western blot analysis and protease inhibitor studies revealed that HGF is a target of neutrophil elastase and plasma kallikrein during skin repair. Proteolytic processing of HGF by each of these proteases significantly attenuated keratinocyte proliferation, wound closure capacity in vitro, and c-Met signal transduction. Our findings reveal a novel pathway of HGF processing during skin repair. Conditions in which proteases are imbalanced and tend toward increased proteolytic activity, as in chronic non-healing wounds, might therefore compromise HGF activity due to the inactivation of the HGF protein and/or the generation of HGF fragments that ultimately mediate a dominant negative effect and limit c-Met activation.

CD40 induces resistance to TNF‐mediated apoptosis in a fibroblast cell line

CD40, a member of the TNF receptor family, has been characterized as an important T‐B cell interaction molecule. In B cells it co‐stimulates isotype switching, proliferation, adhesion and is involved in cell death regulation. In addition to B cells, CD40 expression was found on transformed cells and carcinomas. However, little is known about its functions in these cell types. Recent studies show that CD40 mediates the production of pro‐inflammatory cytokines in non‐hematopoietic cells, inhibits proliferation or induces cell death. In some cell types the apoptotic program triggered by CD40 is only executed when protein synthesis is blocked, suggesting the existence of constitutively expressed resistance proteins. Here we demonstrate that CD40, similar to the 55‐kDa TNF receptor (p55TNFR), has a dual role in the regulation of apoptosis in such cells. In the fibroblast cell line SV80 both CD40 and the p55TNFR trigger apoptosis when protein synthesis is blocked with cycloheximide (CHX). Simultaneous activation of both receptors results in markedly enhanced cell death. However, CD40 activation more than 4 h prior to a challenge with TNF/CHX paradoxically conferred resistance to TNF‐induced cell death. Protection correlated with NF‐κB induction and up‐regulation of the anti‐apoptotic zinc finger protein A20. Overexpression of A20 in turn rendered SV80 cells resistant to TNF cytotoxicity. In conclusion, our data provide evidence that CD40 may regulate cell death in non‐hematopoietic cells in a dual fashion: the decision upon apoptosis or survival of a CD40‐activated cell seems to depend on its ability to up‐regulate resistance factors.

Loss of IL-6 Receptor Expression in Cervical Carcinoma Cells Inhibits Autocrine IL-6 Stimulation: Abrogation of Constitutive Monocyte Chemoattractant Protein-1 Production

IL-6 is synthesized in human pampilloma virus (HPV)-transformed cervical carcinoma cell lines and is supposed to stimulate these cells in an autocrine manner. We studied IL-6 production and responsiveness in nonmalignant HPV-transformed keratinocytes and cervical carcinoma cells in detail. IL-6 was detected in cervical carcinomas in situ. Correspondingly, HPV-positive carcinoma cell lines expressed high IL-6 levels. However, these carcinoma cell lines showed low responsiveness to IL-6 as revealed by low constitutive STAT3 binding activity, which was not further enhanced by exogenous IL-6. In contrast, in vitro-transformed nonmalignant keratinocytes without endogenous IL-6 production strongly responded to exogenous IL-6 with activation of STAT3. STAT3 protein expression levels were comparable in both responsive and nonresponsive cell lines. Also, gp130, the upstream signal-transducing receptor subunit conveying IL-6 signals into the cell, was expressed in all tested cell lines. However, the IL-6 binding subunit gp80 was lost in the malignant cells. Addition of soluble gp80 was sufficient to restore IL-6 responsiveness in carcinoma cells as shown by enhanced activation of STAT3 binding activity. As a consequence of the restored IL-6 responsiveness, carcinoma cells strongly produced the chemokine monocyte chemoattractant protein-1 (MCP-1). Our data demonstrate that cervical carcinoma cells producing high amounts of IL-6 only weakly respond to IL-6 in an autocrine manner due to limited gp80 expression. While production of IL-6 might contribute to a local immunosuppressive effect, silencing an autocrine IL-6 response prevents constitutive production of the mononuclear cell-attracting chemokine MCP-1. Both mechanisms might help the tumor to escape the immune system.