Plasminogen Activator in Differentiating Mouse Keratinocytes

The activity of the serine protease plasminogen activator (PA) was measured in cell lysates from primary mouse keratinocyte cultures as well as from a number of established mouse keratinocyte lines. Enzyme activity was generally higher in the transformed lines than in the primary cultures; however, among the lines tested, those that expressed the highest degree of morphologic differentiation had the highest levels of cell-associated PA. In both the normal (primary) and transformed (established) keratinocyte cultures, PA activity increased when cultures reached confluence and morphologic evidence of differentiation was noted. The highest specific activity of the enzyme was found in cells shed from differentiating cultures, which consisted predominantly of detergent-resistant cornified envelopes. As the cultures differentiated and these cells were shed from the culture surface, the total cell-associated PA activity of the culture decreased accordingly. In both the normal and transformed keratinocyte cultures, peak PA activity occurred at a time when DNA synthesis was declining. These findings indicate that as keratinocytes differentiate, their intracellular levels of PA increase. The modulation of this endogenous keratinocyte enzyme may play an important, although as yet undefined, role in the normal maturation and terminal differentiation of these cells

Regeneration of Organized Epithelial Structure

The role of connective tissue in facilitating and directing the growth of epithelia during adult life is uncertain. The basic processes associated with maintenance of epithelial structure and previous work concerning the role of mesenchyme in this process in the embryo and adult are reviewed. A series of experiments examining the role of connective tissue in facilitating epithelial growth and development in vitro and after transplantation in vivo is described, These confirm the requirement for dermal elements if normal structure is to be reestablished and point to the requirement of dermal, as opposed to deep, connective tissues for facilitation of the growth of adult epithelia in vivo, The in vitro experiments suggest the presence of diffusible dermally produced factors that facilitate epithelial growth

Organotypic cocultures as skin equivalents: A complex and sophisticated in vitro system

To assess the role of genes required for skin organogenesis, tissue regeneration and homeostasis, we have established in vitro skin equivalents composed of primary cells or cell lines, respectively. In these organotypic cocultures keratinocytes generate a normal epidermis irrespective of the species and tissue origin of fibroblasts. The combination of cells derived from mouse and human tissues facilitates the identification of the origin of compounds involved in epidermal tissue reconstitution and thus the precise analysis of growth regulatory mechanisms

The specialized tomograph rotary table design in the T-Flex CAD system

Статья "Проектирование поворотного стола специализированного томографа в T-Fleх CAD" посвящена актуальной проблеме обеспечения правильного расположения объектов контроля в томографических комплексах. Представлен вариант конструкции поворотного стола, спроектированный в среде T-Fleх CAD.The article "Designing of the Rotary Table of the Specialized Tomograph in the T-Flex CAD system" is devoted to the urgent problem of the object correct arrangement control in a tomographic complex. The rotary table embodiment is designed with the T-Flex CAD system

Interleukin-1-Induced Growth Factor Expression in Postmitotic and Resting Fibroblasts.

Tissue homeostasis in skin is regulated by epithelial-mesenchymal interactions, mostly operating via diffusible factors. To study the underlying regulatory mechanisms, in vitro systems have been established to mimic the in vivo situation in skin. In co-cultures, keratinocytes grow either adjacent to irradiated fibroblasts on plastic or on top of collagen gels containing fibroblasts, thus forming 3-dimensional organotypic structures. Keratinocyte growth is supported in part by fibroblast-produced factors induced by keratinocyte mediators such as interleukin-1 (IL-1). To better understand this cellular interaction and its modulation by fibroblast proliferation and extracellular matrix (ECM), we examined the effect of IL-1 on growth factor expression in proliferating and growth-arrested x-irradiated human dermal fibroblasts on plastic and in resting cells embedded in collagen gels. By semiquantitative reverse transcriptase PCR, we demonstrated that IL-1α and IL-1β stimulated the expression of KGF, HGF, IL-1&alpaha;, IL-1β, IL-1RI, and IL-8 in fibroblasts regardless of their physiologic condition, whereas that of TGF-β remained unaffected. The constitutive mRNA levels were usually lower in irradiated postmitotic and ECM-embedded cells than in proliferating fibroblasts. Cells responded to stimulation with IL-1 under all three culture conditions, although to different degrees depending on the growth factor. As demonstrated for HGF, IL-8, and IL-1β, the IL-1α-induced mRNA expression was followed by production and secretion of protein in irradiated fibroblasts. Thus, our findings show that resting and growth-inhibited fibroblasts, reflecting more closely the situation in dermis, exhibit lower constitutive growth factor expression levels but characteristically respond to IL-1 stimulation

Keratinocyte Growth Regulation in Defined Organotypic Cultures Through IL-1-Induced Keratinocyte Growth Factor Expression in Resting Fibroblasts

Balanced keratinocyte proliferation and differentiation resulting in regular tissue organization strictly depend on dermal support. Organotypic cultures represent biologically relevant in vitro models to study the molecular mechanism of the underlying dermal–epidermal interactions. To mimic the state of resting fibroblasts in the dermis, postmitotic (irradiated) fibroblasts were incorporated in the collagen matrix, where they typically support epidermal proliferation and tissue organization. In coculture with keratinocytes, fibroblasts exhibit an enhanced expression of keratinocyte growth factor and the interleukin-1 receptor (type I), which further increase with culture time. In cocultured keratinocytes, keratinocyte growth factor receptor as well as RNA expression and protein release of interleukin-1α and interleukin-1β are upregulated. We hypothesized that the modulated cytokine expression represents a basic mechanism for keratinocyte growth regulation. The functional significance of this double paracrine pathway, i.e., induction of keratinocyte growth factor expression in fibroblasts by keratinocytes via release of interleukin-1, was confirmed by interfering with both signaling elements: (i) interleukin-1-neutralizing antibodies and interleukin-1 receptor antagonist significantly inhibited keratinocyte growth factor release, keratinocyte proliferation, and tissue formation comparable to the effect produced by keratinocyte-growth-factor-blocking antibodies; (ii) addition of keratinocyte growth factor to cocultures with inactivated interleukin-1 pathway completely reverted growth inhibition; (iii) in organotypic cocultures with subthreshold fibroblast numbers both interleukin-1 and keratinocyte growth factor restored the impaired epidermal morphogenesis. Thus, epidermal tissue regeneration in organotypic cocultures is mainly regulated by keratinocyte-derived interleukin-1 signaling, which induces keratinocyte growth factor expression in cocultured fibroblasts. This demonstrates a novel role for interleukin-1 in skin homeostasis substantiating data from wound healing studies in vivo