Epidermal organization and differentiation of HaCaT keratinocytes in organotypic coculture with human dermal fibroblasts.

The immortal human keratinocyte line HaCaT is frequently used as a paradigm for skin keratinocytes in vitro because of its highly preserved differentiation capacity. HaCaT cells form a nearly regular epidermal architecture when transplanted onto subcutaneous tissue of athymic mice. In order to analyze further their differentiation capacity in vitro, HaCaT cells were studied in organotypic cocultures on top of collagen gels containing human dermal fibroblasts. Within 1 wk HaCaT cells formed a still dysplastic epithelium, the thickness of which correlated with the number of fibroblasts in the collagen gel. With further culture time of up to 3 wk a remarkably well structured and differentiated squamous epithelium developed. After 1 wk, keratins 10 and 16, involucrin, and transglutaminase I were expressed in suprabasal layers, whereas filaggrin, keratin 2e, and loricrin appeared after 2-3 wk. Within this time, a nearly complete basement membrane had formed including hemidesmosomes and anchoring fibrils. Epithelial cell proliferation became restricted to the basal layer after 2 and 3 wk. Using the TdT-mediated dUTP nick end labeling assay, fragmentation of DNA was detectable in nuclei of the parakeratotic stratum corneum. Ultrastructurally, many features of keratinization accumulated after 2 and 3 wk, though an orthokeratotic keratinization was not achieved, in contrast to HaCaT transplants. This differentiation deficiency - as compared with normal keratinocytes -- might be due to a lack of paracrine factors important for keratinocyte differentiation or to a reduced sensitivity of these cells. Nevertheless, this high degree of differentiation under organotypic conditions qualifies this cell line as an appropriate model for elucidation of the molecular mechanisms regulating keratinocyte growth and differentiation and for use in pharmacotoxicology.

Epidermal differentiation and basement membrane formation by HaCaT cells in surface transplants.

The immortal human keratinocyte line HaCaT has been employed in many studies as paradigm for epidermal keratinocytes. In order to demonstrate its potential to form stable epidermal structures in response to connective tissue, this was challenged in surface transplants on nude mice, where normal keratinocytes rebuild a typical epidermis within two weeks. During the initial regeneration phase (day 1-4) multilayered but poorly organized epithelia formed with proliferating cells in all layers in analogy to normal keratinocytes. Similarly, with tissue consolidation (around day 7) proliferation was reduced and restricted to cells in basal position marked by keratin K14 and beta1-integrin immunostaining. The strong suprabasal reaction for K1 and K10, the appearance of the late markers K2e, filaggrin and loricrin as well as the polarized distribution of alpha2beta1 and alpha3beta1 indicated advancing tissue normalization (day 14). Keratinization further improved at around three weeks switching from the initial parakeratotic to the regular orthokeratotic type which was prominent at six weeks. Accordingly, most ultrastructural features typical for epidermis or normal keratinocyte grafts were detectable including a complete basement membrane (BM) with regular attachment structures. Matrix- and BM-components appeared sequentially with marked linear deposition of laminin-5 (day 4) followed by accumulation of collagen-IV and 'classical' BM-laminin between one and two weeks. With the general codistribution of integrin alpha6beta4 and BM-molecules (day 14) collagen-VII lining of BM became prominent, while epithelium and host connective tissue were still separated by the collagen matrix. In accordance with the delayed orthokeratinization, wound-matrix molecules (fibronectin, tenascin) persisted longer than in normal keratinocyte transplants. Finally, grafts of long-term passaged (no. 310) cells demonstrated a remarkable stability in the expression of epidermal markers. Thus, the immortalized HaCaT cells reveal a generally high competence to realize an epidermal phenotype in a natural environment and appear therefore qualified for in vitro studies on structural and regulatory aspects of keratinocyte physiology and pathology.

Critical period-dependent reduction of the permissiveness of cat visual cortex tissue for neuronal adhesion and neurite growth.

During postnatal development, the visual cortex undergoes an experience-dependent refinement of its circuitry. This process includes synapse formation, as well as synapse elimination. Both mechanisms appear to be restricted to a limited 'critical period' which lasts for approximately 2 months in cats. We tested whether the termination of the critical period for cortical malleability is paralleled by changes in the growth permissiveness of the tissue. These changes may inhibit progressive reorganization of functional circuitries mediated by axon growth. Embryonic cortical neurons were cultured on unfixed cryostat sections of the visual cortex obtained from cats aged 2-50 weeks. After 2-3 days in vitro the distribution of viable cells and the percentage of neurite-bearing cells were determined and analysed with respect to the developmental age and subdivisions of the underlying tissue substrate. It was shown that cell adhesion and neurite formation are correlated with the developmental age of the substrate tissue and the time period of myelination. While embryonic neurons adhered and survived on grey and white matter tissue from 2- and 4-week-old kittens, there was a significant reduction in cell adhesion on the myelinated white matter regions of the tissue sections of older animals. Quantitative analyses showed that neurite formation by cultured neurons also became successively impaired on grey and white matter areas of tissue substrates, corresponding to the time course of the critical period for cortical malleability. On grey matter tissue this effect was most pronounced between the second and sixth postnatal weeks. The effects were not antagonized by coating the substrate sections with the growth-promoting molecule laminin. It is therefore proposed that neurite growth-inhibiting factors, most probably associated with central nervous system myelin, are gradually expressed postnatally and may contribute to the termination of the critical period in the visual cortex of cats.

Bactenecin, a leukocytic antimicrobial peptide, is cytotoxic to neuronal and glial cells.

Small antimicrobial peptides are abundantly produced by leukocytes. These peptides are active against a broad range of pathogens, notably bacteria, fungi, and enveloped viruses, but hardly anything is known about their physiological and pathophysiological relevance. We observed that bactenecin, a dodecapeptide, is strongly cytotoxic to rat embryonic neurons, fetal rat astrocytes and human glioblastoma cells. This neurotoxicity is unique to bactenecin, as a panel of antibacterial peptides from vertebrates and invertebrates, like defensins, corticostatin, indolicidin, cecropin P1, tachyplesin I, the magainins, or apidaecins did not impair neuronal viability.