Halting angiogenesis suppresses carcinoma cell invasion.

The importance of angiogenesis in malignant tumor growth has been interpreted mainly in terms of oxygen and nutrient supply. Here we demonstrate its fundamental role for tumor invasion of malignant human keratinocytes in surface transplants on nude mice. Distinct patterns of angiogenesis and vascular endothelial growth factor receptor-2 (VEGFR-2) expression allowed us to distinguish between benign and malignant cells. Functional inactivation of VEGF-R2 by a blocking antibody disrupted ongoing angiogenesis and prevented invasion of malignant cells, without reducing tumor cell proliferation. The reversion of a malignant into a benign phenotype by halting angiogenesis demonstrates a significant function of vascular endothelium for tumor invasion.

Absence of host plasminogen activator inhibitor 1 prevents cancer invasion and vascularization.

Acquisition of invasive/metastatic potential through protease expression is an essential event in tumor progression. High levels of components of the plasminogen activation system, including urokinase, but paradoxically also its inhibitor, plasminogen activator inhibitor 1 (PAI1), have been correlated with a poor prognosis for some cancers. We report here that deficient PAI1 expression in host mice prevented local invasion and tumor vascularization of transplanted malignant keratinocytes. When this PAI1 deficiency was circumvented by intravenous injection of a replication-defective adenoviral vector expressing human PAI1, invasion and associated angiogenesis were restored. This experimental evidence demonstrates that host-produced PAI is essential for cancer cell invasion and angiogenesis.

"Trans-differentiation" from epidermal to mesenchymal/myogenic phenotype is associated with a drastic change in cell-cell and cell-matrix adhesion molecules.

Cells of the human keratinocyte line HaCaT were shifted to a mesenchymal/myogenic phenotype (DTHMZ cells) by MyoD1 transfection, 5-aza-2' deoxycytidine treatment, and selection for reduced adhesion on plastic. Since this correlated with loss of stratification (inability to form a multilayered tissue), we determined the status of cell-cell and cell-matrix adhesion molecules involved in epidermal morphogenesis. Expression of desmosomal proteins (plakoglobin, desmoglein, desmoplakin) and uvomorulin was no longer detectable at the mRNA and protein level in the DTHMZ cells while both HaCaT cells and malignant variants (transfected with c-Ha-ras oncogene) expressed uvomorulin in vitro and in transplants in vivo, the latter even in invasively growing tumor nodules. Furthermore, HaCaT cells stained positive for the integrin subunits beta 1, alpha 2, alpha 3, and alpha 5, typical for cultured keratinocytes. In contrast, the putative fibronectin receptor alpha 5 beta 1, common also in fibroblasts, was the only integrin showing strong staining in DTHMZ cells. The integrin subunits alpha v and a6, clearly expressed at the mRNA level, weakly stained HaCaT cultures and led to a dotlike fluorescence in DTHMZ cells, possibly representing focal adhesion plaques. The respective integrin status correlated well with the growth behavior on different matrices. While HaCaT cells readily attached and proliferated on collagen (type I), fibronectin-coated, and laminin-coated collagen gels, DTHMZ cells formed monolayers only on fibronectin-coated collagen. This was, however, not sufficient to allow stratification in vivo. Altogether, the status of adhesion molecules in DTHMZ cells more likely reflects that seen in mesenchymal cells as compared to the pattern of keratinocytes displayed by HaCaT cells. Moreover, since the DTHMZ cells were clearly HaCaT descendants, the results support our hypothesis of a "trans-differentiation" process from an epidermal (HaCaT) to a mesenchymal/myogenic phenotype (DTHMZ).

Mutual induction of growth factor gene expression by epidermal-dermal cell interaction.

Epithelial-mesenchymal interactions control epidermal growth and differentiation, but little is known about the mechanisms of this interaction. We have examined the effects of human dermal microvascular endothelial cells (DMEC) and fibroblasts on keratinocytes in conventional (feeder layer) and organotypic cocultures (lifted collagen gels) and demonstrated the induction of paracrine growth factor gene expression. Clonal keratinocyte growth was similarly stimulated in cocultures with irradiated DMEC and fibroblasts as feeder cells. This effect is most probably caused by induction of growth factor expression in cocultured dermal cells. Keratinocytes stimulated mRNA levels for KGF and IL-6 in both mesenchymal cell types and GM-CSF in fibroblasts. The feeder effect could not be replaced by conditioned media or addition of isolated growth factors. In organotypic cocultures with keratinocytes growing on collagen gels (repopulated with dermal cells), a virtually normal epidermis was formed within 7 to 10 d. Keratinocyte proliferation was drastically stimulated by dermal cells (histone 3 mRNA expression and BrdU labeling) which continued to proliferate as well in the gel. Expression of all typical differentiation markers was provoked in the reconstituted epithelium, though with different localization as compared to normal epidermis. Keratins K1 and K10 appeared coexpressed but delayed, reflecting conditions in epidermal hyperplasia. Keratin localization and proliferation were normalized under in vivo conditions, i.e., in surface transplants on nude mice. From these data it is concluded that epidermal homeostasis is in part controlled by complex reciprocally induced paracrine acting factors in concert with cell-cell interactions and extracellular matrix influences.

Normal keratinization in a spontaneously immortalized aneuploid human keratinocyte cell line.

In contrast to mouse epidermal cells, human skin keratinocytes are rather resistant to transformation in vitro. Immortalization has been achieved by SV40 but has resulted in cell lines with altered differentiation. We have established a spontaneously transformed human epithelial cell line from adult skin, which maintains full epidermal differentiation capacity. This HaCaT cell line is obviously immortal (greater than 140 passages), has a transformed phenotype in vitro (clonogenic on plastic and in agar) but remains nontumorigenic. Despite the altered and unlimited growth potential, HaCaT cells, similar to normal keratinocytes, reform an orderly structured and differentiated epidermal tissue when transplanted onto nude mice. Differentiation-specific keratins (Nos. 1 and 10) and other markers (involucrin and filaggrin) are expressed and regularly located. Thus, HaCaT is the first permanent epithelial cell line from adult human skin that exhibits normal differentiation and provides a promising tool for studying regulation of keratinization in human cells. On karyotyping this line is aneuploid (initially hypodiploid) with unique stable marker chromosomes indicating monoclonal origin. The identity of the HaCaT line with the tissue of origin was proven by DNA fingerprinting using hypervariable minisatellite probes. This is the first demonstration that the DNA fingerprint pattern is unaffected by long-term cultivation, transformation, and multiple chromosomal alterations, thereby offering a unique possibility for unequivocal identification of human cell lines. The characteristics of the HaCaT cell line clearly document that spontaneous transformation of human adult keratinocytes can occur in vitro and is associated with sequential chromosomal alterations, though not obligatorily linked to major defects in differentiation.

Progressive stages of "transdifferentiation" from epidermal to mesenchymal phenotype induced by MyoD1 transfection, 5-aza-2'-deoxycytidine treatment, and selection for reduced cell attachment in the human keratinocyte line HaCaT.

The ability of the myogenic determination gene (MyoD1) to convert differentiating human keratinocytes (HaCaT cell-line) to the myogenic pathway and the effect of MyoD1 on the epidermal phenotype was studied in culture and in surface transplants on nude mice. MyoD1 transfection induced the synthesis of myosin, desmin, and vimentin without substantially altering the epidermal differentiation properties (morphology, keratin profile) in vitro nor epidermal morphogenesis (formation of a complex stratified squamous epithelium) in surface transplants, demonstrating the stability of the keratinocyte phenotype. 5-Aza-CdR treatment of these MyoD1-transfected cells had little effect on the cultured cells but a morphologically unstructured epithelium was formed with no indications of typical cell layers including cornification. Since prevention of epidermal strata in transplants was not accompanied by blocked epidermal differentiation markers (keratins K1 and K10, involucrin, and filaggrin), the dissociation of morphogenesis and expression of these markers argues for independently controlled processes. A subpopulation of less adhesive cells, isolated from the 5-aza-CdR treated MyoD1-transfectants, had lost most epithelial characteristics in culture (epidermal keratins, desmosomal proteins, and surface-glycoprotein Gp90) and had shifted to a mesenchymal/myogenic phenotype (fibroblastic morphology, transactivation of Myf3 and myogenin, expression of myosin, desmin, vimentin, and Gp130). Moreover, the cells had lost the ability to stratify and remained as a monolayer of flat elongated cells in transplants. These subsequent changes from a fully differentiated keratinocyte to a mesenchymal/myogenic phenotype strongly argue for a complex "transdifferentiation" process which occurred in the original monoclonal human epidermal HaCaT cells.

The plasminogen activator inhibitor PAI-1 controls in vivo tumor vascularization by interaction with proteases, not vitronectin. Implications for antiangiogenic strategies.

The plasminogen (Plg)/plasminogen activator (PA) system plays a key role in cancer progression, presumably via mediating extracellular matrix degradation and tumor cell migration. Consequently, urokinase-type PA (uPA)/plasmin antagonists are currently being developed for suppression of tumor growth and angiogenesis. Paradoxically, however, high levels of PA inhibitor 1 (PAI-1) are predictive of a poor prognosis for survival of patients with cancer. We demonstrated previously that PAI-1 promoted tumor angiogenesis, but by an unresolved mechanism. We anticipated that PAI-1 facilitated endothelial cell migration via its known interaction with vitronectin (VN) and integrins. However, using adenoviral gene transfer of PAI-1 mutants, we observed that PAI-1 promoted tumor angiogenesis, not by interacting with VN, but rather by inhibiting proteolytic activity, suggesting that excessive plasmin proteolysis prevents assembly of tumor vessels. Single deficiency of uPA, tissue-type PA (tPA), uPA receptor, or VN, as well as combined deficiencies of uPA and tPA did not impair tumor angiogenesis, whereas lack of Plg reduced it. Overall, these data indicate that plasmin proteolysis, even though essential, must be tightly controlled during tumor angiogenesis, probably to allow vessel stabilization and maturation. These data provide insights into the clinical paradox whereby PAI-1 promotes tumor progression and warrant against the uncontrolled use of uPA/plasmin antagonists as tumor angiogenesis inhibitors.

Phenotypic and genotypic characteristics of a cell line from a squamous cell carcinoma of human skin.

A human cell line (SCL-1) from a poorly differentiating cutaneous squamous cell carcinoma (SCC) ws studied through 20 passages during 2 years. Cells maintained their original morphology with low degree of keratinization, as indicated by light and electron microscopy. The keratin peptide pattern resembled the type in SCC tumors, and the corresponding filaments were detected by immunofluorescence at all passage levels. Cells did not grow in soft agar but formed tumor-like nodules in an "organotypic" culture assay (on lifted collagen gels) and grew invasively after transplantation to immunosuppressed inbred C3H mice. After injection into BALB/c nu/nu mice, tumors of SCC morphology were formed. The hypodiploid tumor stem-line was maintained for about 10 passages, when a shift to hyperploidy started, as determined by chromosome and DNA flow microfluorometric analyses. Two stable marker chromosomes (in 100 and 70% of the metaphases, respectively), involving chromosomes 7 and 9, strongly indicated a monoclonal origin of this cell line.

Environmental modulation of the expression of differentiation and malignancy in six human squamous cell carcinoma cell lines.

Cell lines from six human squamous cell carcinomas exhibiting different degrees of differentiation and malignancy were studied under in vitro and in vivo growth conditions. The stability of phenotypic traits of these carcinoma cells and their sensitivity to environmental influences were analyzed to further elucidate the interdependency of differentiation and malignancy expressed under experimental conditions. In conventional (submerged) cultures the cell lines exhibited unique growth patterns with an individual but generally poor expression of differentiation (stratification). In a new organotypical culture assay where the cells grew on lifted collagen gels at the air-medium interface, three-dimensional structures were formed exhibiting organizational features and degrees of differentiation similar to those of the respective tumors. Both in tumors formed after s.c. injection of cells and in transplants (performed with silicone chambers on the dorsal muscle fascia) in nude mice, an enhancement of the individually distinct pattern of differentiation was observed. While anchorage independent growth was an unreliable marker for malignancy, all six lines were tumorigenic after s.c. injection into nude mice. However, the tumor yield (20 to 100%) and latency period (2 to 12 weeks) varied considerably. In contrast all lines exhibited (within 1 to 2 weeks) invasive growth in 100% of animals after transplantation onto the dorsal muscle fascia. All tumors (squamous carcinomas) and invading cells were identified as epithelial and as human by specific antibodies. The two new test systems, the organotypical culture assay in vitro and the transplantation assay in vivo, proved to be reliable and sensitive models also for human squamous carcinoma cells to analyze their differentiative and malignant potential. In comparing the individually maintained degrees of differentiation and malignancy in the different test systems, it was apparent that, opposite to the prevailing opinion, cell lines with the highest differentiation potential were at least as malignant as were the least differentiated ones.

DNA excision repair in ultraviolet-irradiated normal and malignantly transformed mouse epidermal cell cultures.

Pyrimidine dimer production and excision was studied in ultraviolet light (UV)-irradiated primary cultures of epidermal cells derived from perinatal mouse skin and in an in vitro malignantly transformed epidermal cell line. Dimer production increased linearly with UV dose level for both cell types. However, at any given UV dose level, there were 20% fewer thymine-containing dimers induced in the primary cultures compared to the transformed cell line. The reduced dimer yield in the primary cultures was attributed to the multilayer (three cell layers) of these cultures. The primary cultures were found to exicse no more than 10% of the original dimers in a 24-hr period, while the malignantly transformed cells excised 34%. Nonsemiconservative DNA repair synthesis was also studied as a function of dimer yields in the first 3 hr after irradiation. When the levels of repair replication in both cell types were compared at equal yields of UV-induced dimers, the malignantly transformed cells exhibited a higher level of repair than did the primary epidermal cells. There was no difference in the kinetics of repair replication between the two cell types at a UV dose level of 10 J/sq m over the first 6 hr after irradiation.

Normal keratinocytes suppress early stages of neoplastic progression in stratified epithelium.

The importance of interactions between potentially neoplastic cells and their normal neighbors on malignant progression of precancerous lesions is not well understood. In this study, we have established novel human tissue models that simulate intraepithelial neoplasia in stratified epithelia to investigate the fate and phenotype of neoplastic keratinocyte clones in normal cell context during clonal expansion and early malignant progression. This was accomplished by mixing genetically marked keratinocytes with malignant potential (II-4) with normal keratinocytes at ratios of 1:1, 4:1, 12:1, and 64:1 (normal:II-4) to visualize nests of marked, dysplastic cells in organotypic cultures and in cultures transplanted to nude mice. Four weeks after transplantation of 4:1 mixtures, grafts were normal and demonstrated no beta-galactosidase (beta-gal)-positive cells, suggesting that cells with malignant potential were eliminated from the tissue at this mixing ratio. However, grafted 1:1 mixtures demonstrated persistence of expanded foci of dysplastic cells (4 weeks) and invasion (8 weeks). This demonstrated that the capacity of a keratinocyte clone with neoplastic potential to persist and invade is directly related to the threshold number of such keratinocytes present in the tissue. To explain the failure of II-4 to persist in vivo, the intraepithelial dynamics between the two populations were studied before grafting. Double-stain immunofluorescence for bromodeoxyuridine/beta-gal and filaggrin/beta-gal of mixtures grown in organotypic cultures for 7 days demonstrated that when increasing numbers of normal cells were added (12:1), II-4 ceased to proliferate and expressed filaggrin. This suggests a novel mechanism of tumor suppression wherein contact with normal cells induces cell cycle withdrawal and terminal differentiation of potentially malignant cells. These findings support the view that normal tissue architecture acts as a dominant suppressor of early neoplastic progression in stratified epithelium.

Epidermal morphogenesis and keratin expression in c-Ha-ras-transfected tumorigenic clones of the human HaCaT cell line.

Several tumorigenic (benign and malignant) clones have been raised from the human epidermal cell line HaCaT after transfection with the c-Ha-ras oncogene (val 12) (P. Boukamp et al., Cancer Res., 50: 2840-2847, 1990). In culture, these HaCaT-ras clones expressed epidermal differentiation markers, such as keratins K1 and 10, at high density or upon depletion of retinoic acid. Accordingly, as HaCaT cells, the clones formed well-differentiated stratified epithelia synthesizing K1 and 10 in surface transplants, while simple and internal epithelial keratins seen in culture were suppressed (as upon retinoic acid depletion in vitro). In transplants of HaCaT cells, in contrast to those of normal keratinocytes, K1 appeared prematurely already in basal cells, while K10 localized rather normally in the suprabasal position. Keratins 1 and 10 were also synthesized in transplants of HaCaT-ras clones (again K1 preceding K10), but both generally shifted toward upper layers. This was particularly evident in thicker transplants of malignant clones. Staining for both keratins persisted "suprabasally" in invasive tissue masses, and this corresponded to their marked expression in solid carcinomas (after s.c. injection), seen by immunofluorescence and two-dimensional gel electrophoresis. Thus, notwithstanding some variations, differentiation potential was not significantly reduced in these clones disregarding levels of ras oncogene expression and malignant properties.

c-Ha-ras oncogene expression in immortalized human keratinocytes (HaCaT) alters growth potential in vivo but lacks correlation with malignancy.

Spontaneously immortalized human skin keratinocytes (HaCaT) were transfected with the c-Ha-ras (EJ) oncogene via a plasmid construct which also contained the selectable neomycin gene. Clones were selected on the basis of G418 resistance. Those clones that had stable integrants of Ha-ras fell into 3 classes with respect to tumorigenicity. Class I clones were nontumorigenic, i.e., formed nodules which rapidly regressed. This phenotype is identical to that seen with parental HaCaT cells. Class II clones formed slowly growing, highly differentiated cystic or papillomatous-type benign tumors, and class III clones formed highly differentiated, locally invasive squamous cell carcinomas. The clones of all three classes exhibited similar morphology and growth potential in culture and retained the ability to reconstitute an epidermis-like stratified epithelium in transplantation experiments. Only the malignant clones showed locally invasive growth. Both the benign and the malignant clones exhibited higher levels of ras integration and variable levels of mutated p21 protein product. Thus, expression of the cellular Ha-ras oncogene in these human epithelial cells significantly altered growth regulation, resulting in varying degrees of growth potential in vivo, ranging from benign to malignant tumors. However, no direct correlation was seen between high levels of p21 expression and malignant growth.

Preservation of morphological, functional, and karyotypic traits during long-term culture and in vivo passage of two human skin squamous cell carcinomas.

Two cell lines (SCL-I and SCL-II) derived from squamous cell carcinomas of human skin were investigated during 4 years in culture. Both lines were tumorigenic in nude mice, and cells could be recultivated from xenografts. Growth in agar remained poor, but both cell lines developed abnormal stratified epithelial structures in organotypical cultures. The morphological and particularly ultrastructural characteristics remained typical in both cultures and xenografts. Keratinization slightly decreased, but nude mouse tumors differentiated as the original tumors, and this was reflected in keratin expression. Six major polypeptides (Mr 61,000, 57,000, 54,000, 51,000, 49,000, and 45,000) were similarly identified in both tumors and cell lines, also after animal passage, which was further substantiated by two-dimensional gel electrophoresis, but quantitative variations were found with different growth conditions. A distinct keratin cytoskeletal network was visualized in both lines by immunofluorescence, but only a few cells in SCL-II also expressed vimentin. Flow cytometry demonstrated 2c DNA stem lines for original tumors and derived lines. Early passages were hypodiploid by cytogenetic analysis of banded chromosomes. In SCL-I, a shift to tetraploidy occurred before passage 20 and remained stable throughout. In SCL-II, an incomplete shift to near tetraploidy and a stem line deviation were apparent, but later passages, nude mouse tumors, and cells recultured therefrom were hypodiploid (2c) again. Chromosome studies further revealed distinct stable marker chromosomes which showed additional structural aberrations with time in culture and after animal passage. Thus, phenotypically and genotypically, each squamous cell carcinoma and its derived cell line were distinct, and characteristics were preserved over long time periods in vitro and through in vivo passage.

12-O-tetradecanoylphorbol-13-acetate induces clonal expansion of potentially malignant keratinocytes in a tissue model of early neoplastic progression.

Tumor promoters stimulate the selective expansion of initiated mouse keratinocytes in the two-stage model of skin carcinogenesis. However, it is not clear whether these promoters directly modulate the growth of initiated cells or rather permit clonal expansion of initiated cells by modifying the environment of adjacent normal cells. The goal of this study was to further understand the mechanism of action of tumor promotion during early neoplastic progression of human stratified epithelium. To accomplish this, we have established an organotypic culture model that mimics a preneoplastic tissue and contains mixtures of genetically marked (beta-galactosidase), low-grade malignant keratinocytes (HaCaT-ras II-4) and normal human keratinocytes (NHKs) to monitor the fate and phenotype of these cells after treatment with 12-O-tetradecanoylphorbol-13-acetate (TPA). In submerged culture, concentrations of 0.001-1 microg/ml TPA were shown to limit the growth of NHKs yet had no effect on growth of II-4 cells. TPA (0.001 microg/ml) was then added to organotypic cultures containing mixtures of NHK:II-4 cells at varying ratios to determine whether this agent could selectively stimulate clonal expansion of II-4 cells in a normal epidermal background. Immunofluorescence for beta-galactosidase demonstrated that TPA caused a significant increase in the percentage of beta-galactosidase-positive areas in 12:1 and 4:1 mixtures. This TPA-induced expansion of II-4 cells was associated with a marked decrease in proliferation of NHKs, suggesting that II-4 could selectively expand because of its growth advantage relative to NHKs. Clonal expansion of tumor cells was temporally linked to the decreased expression of filaggrin and keratin 1 expression in adjacent NHKs. These findings indicate that TPA may enable expansion of potentially malignant cells through the epigenetic modification of proliferation in NHKs and differentiation of NHK and II-4 cells.

Expression of epithelial antigens Exo-1 and EPM-1 in human epidermal keratinocyte maturation and benign and malignant neoplasia.

Exo-1, a polar neutral glycolipid, and EPM-1, a high molecular weight glycoprotein, are developmental antigens of human epithelial cells, initially described as components both on the cell surface and in secretions of gastrointestinal epithelial and respective tumors. In order to assess the biological significance of both antigens for epithelial cell differentiation and neoplastic transformation, their expression during human skin development and benign and malignant neoplasia was analyzed in fresh frozen tissue specimens of skin biopsies and of human epidermal keratinocytes growing in experimental model systems. Antigen expression was assessed immunohistochemically with specific monoclonal antibodies. During fetal development Exo-1 was temporarily expressed in intermediate cells but was absent in normal adult human skin. Exo-1 expression reemerged in neoplasias, both benign and malignant, but was restricted to spinous-like differentiated cells. Similarly, Exo-1 was not expressed in transplants of normal keratinocytes mimicking the normal epidermis but was clearly visible in differentiated areas of transplants of malignantly transformed keratinocytes. EPM-1 appeared first in basal epidermal cells in the second half of gestation and remained detectable in the stratum basale of adult skin. While squamous cell carcinomas continued to express EPM-1, it was not detectable in basal cell epitheliomas and in normal epidermis after invasion by neuroectodermal tumor cells. In experimental models, EPM-1 was present in the basal layers of normal human keratinocytes and of transformed keratinocytes with benign growth characteristics whenever a well stratified and keratinized epidermis-like epithelium had formed in transplants. In transformed keratinocytes with malignant growth behavior, EPM-1 was expressed irregularly, as in squamous cell carcinomas in situ. Thus, expression of Exo-1 is a marker for an early embryonic differentiation pathway of human keratinocytes and in adult tissue reveals abnormal differentiation associated with certain stages of hyperproliferation. EPM-1 expression is part of developmental programs and is influenced by microenvironmental interactions and alterations of tissue homeostasis.

Inhibition of collagenase-3 (MMP-13) expression in transformed human keratinocytes by interferon-gamma is associated with activation of extracellular signal-regulated kinase-1,2 and STAT1.

Collagenase-3 (MMP-13) is characterized by an exceptionally wide substrate specificity and restricted expression. MMP-13 is specifically expressed by transformed human keratinocytes in squamous cell carcinomas in vivo and its expression correlates with their invasion capacity. Here, we show, that interferon-gamma (IFN-gamma) markedly inhibits expression of MMP-13 by human cutaneous SCC cells (UT-SCC-7) and by ras-transformed human epidermal keratinocytes (A-5 cells) at the transcriptional level. In addition, IFN-gamma inhibits collagenase-1 (MMP-1) expression in these cells. IFN-gamma abolished the enhancement of MMP-13 and MMP-1 expression by transforming growth factor-beta (TGF-beta) and tumor necrosis factor-alpha (TNF-alpha), and inhibited invasion of A-5 cells through type I collagen. IFN-gamma also rapidly and transiently activates extracellular signal-regulated kinase 1,2 (ERK1,2) and blocking ERK1,2 pathway (Raf/MEK1,2/ERK1,2) by specific MEK1,2 inhibitor PD98059 partially (by 50%) prevents Ser-727 phosphorylation of STAT1 and suppression of MMP-13 expression by IFN-gamma. Furthermore, Ser-727 phosphorylation of STAT1 by ERK1,2, or independently of ERK1,2 activation is associated with marked reduction in MMP-13 expression. These observations identify a novel role for IFN-gamma as a potent inhibitor of collagenolytic activity and invasion of transformed squamous epithelial cells, and show that inhibition of MMP-13 expression by IFN-gamma involves activation of ERK1,2 and STAT1.

Step-wise progression in human skin carcinogenesis in vitro involves mutational inactivation of p53, rasH oncogene activation and additional chromosome loss.

Two mechanisms relevant for skin carcinogenesis in man are mutational inactivation of p53 and oncogenic activation of c-rasH gene. Previously, we transfected c-rasH oncogene into human skin keratinocytes (HaCaT) with u.v.-typic mutations in both p53 alleles, which produced benign and malignant tumorigenic clones, expressing similar amounts of mutant Ras protein. Here we show that neither the ras integration site nor the karyotypic changes affects the formation of the benign or malignant tumorigenic phenotype. From the original malignant HaCaT-ras clone we took single human chromosomes, carrying the c-rasH oncogene and transferred them by microcell mediated chromosome transfer into genetically different untransfected nontumorigenic HaCaT cells. This novel approach identified the genetic background of the recipient cell as a critical determinant for the resulting tumor phenotype. Exhibiting similar oncogene expression, microcell hybrids from early passage cells remained nontumorigenic or formed benign tumors, while those with more cytogenetic aberrations (later passages) and loss of > 1 copy of chromosome 15 became malignant. Since aberrations in chromosome 15 were also detected in three of five human skin carcinoma lines this study provides evidence that p53 and c-rasH mutations are early events of human skin carcinogenesis, while loss of gene(s) on chromosome 15 is a late event.

Molecular and cytogenetic analysis of immortalized human primary keratinocytes obtained after transfection with human papillomavirus type 16 DNA.

A proliferating population of human foreskin keratinocytes (presently in the sixtieth passage) has been obtained after transfection with human papillomavirus (HPV) type 16 DNA. In contrast, the control cultures did not survive beyond the sixth passage. Cytogenetic analysis of cells taken from the twelfth passage revealed a heteroploid male karyotype. In approximately 50% of the cells a common marker chromosome was found, suggesting a clonal origin for at least part of the population. This is further substantiated by Southern blot analysis of cellular DNA which revealed oligomeric HPV 16 genomes integrated at a single site within the host DNA. RNA transcribed from the early region of the HPV 16 genome was identified in the cytoplasm. The immortalizing effect of HPV 16 DNA on human keratinocytes could be reproduced in a second experiment. Such cell lines represent an unique system to study the interaction of HPV with its natural target cell in vitro.

Tumorigenic conversion of immortal human skin keratinocytes (HaCaT) by elevated temperature.

UV-radiation is a major risk factor for non-melanoma skin cancer causing specific mutations in the p53 tumor suppressor gene and other genetic aberrations. We here propose that elevated temperature, as found in sunburn areas, may contribute to skin carcinogenesis as well. Continuous exposure of immortal human HaCaT skin keratinocytes (possessing UV-type p53 mutations) to 40 degrees C reproducibly resulted in tumorigenic conversion and tumorigenicity was stably maintained after recultivation of the tumors. Growth at 40 degrees C was correlated with the appearance of PARP, an enzyme activated by DNA strand breaks and the level corresponded to that seen after 5 Gy gamma-radiation. Concomitantly, comparative genomic hybridization (CGH) analyis demonstrated that chromosomal gains and losses were present in cells maintained at 40 degrees C while largely absent at 37 degrees C. Besides individual chromosomal aberrations, all tumor-derived cells showed gain of chromosomal material on 11q with the smallest common region being 11q13.2 to q14.1. Cyclin D1, a candidate gene of that region was overexpressed in all tumor-derived cells but cyclinD1/cdk4/cdk6 kinase activity was not increased. Thus, these data demonstrate that long-term thermal stress is a potential carcinogenic factor in this relevant skin cancer model, mediating its effect through induction of genetic instability which results in selection of tumorigenic cells characterized by gain of 11q.