Chemical carcinogenesis studies in mouse epidermal cell cultures

Studies of tumor induction on mouse skin have provided insight into the basis biology of chemical carcinogenesis, but molecular mechanisms have been more difficult to elucidate. Mouse epidermal cell cultures have proven to be a valuable model for performing mechanistic studies. Previous data have indicated that such cultures proliferate and differentiate in a manner highly analogous to epidermis in vivo. In addition, carcinogen metabolism, DNA repair, and responses to tumor promoters are quite similar in mouse skin in vivo and in vitro. Recent data have extended these observations toward defining the biological characteristics of initiated cells and elucidating the mechanism of action of promoters and antipromoters. When mouse epidermis is cultured under conditions of low extracellular Ca++, proliferation is enhanced and terminal differentiation is inhibited. Addition of Ca++ induces terminal differentiation. If cells are treated with carcinogens under low Ca++ conditions and subsequently switched to standard Ca++, cell colonies which do not terminally differentiate evolve. Such colonies continue to synthesize keratin, are subculturable, and may represent preneoplastic cells. In other experiments, epidermal cells derived from mouse skin treated with carcinogens in vivo also demonstrate prolonged in vitro survival and subculturability while controls have a limited lifespan. Such studies suggest that biological alterations can be detected in epidermal cells exposed to carcinogens well before and the phenotypic expression of neoplasia. Exposure of epidermal cells to phorbol-ester tumor promoters induces ornithine decarboxylase (ODC). This induction is enhanced by corticosteroids and markedly inhibited by retinoids. Ultraviolet light also induces ODC in epidermal cells, but kinetic studies suggest that the early pathway of induction (afferent to the nucleus) is different from that of phorbol esters. The later pathways (efferent from the nucleus-i.e., transcription and translation) appear to be similar. Retinoids have only a minor suppressive effect on ODC induction by UV while corticosteroids enhance UV induction to the same extent as seen with phorbol esters These results suggest that the site of retinoids is in the afferent pathway while steroids act on the efferent pathway.

Inhibition of epidermal terminal differentiation and tumour promotion by retinoids

Retinoids are physiological regulators of growth and differentiation for a number of epithelial tissues. In several of these, retinoids also act as pharmacological anticarcinogens. Retinoids are most effective as anticarcinogens in the post-initiation portion of carcinogenesis. In mouse skin, retinoids are inhibitors of phorbol ester-mediated tumour promotion and can cause regression of pre-existing benign tumours. Studies in vivo and in vitro have indicated that phorbol ester-mediated skin tumour promotion results from selective clonal expansion of initiated cells. We have proposed that the biological basis for selection resides in the induction of terminal differentiation in subpopulations of keratinocytes while other keratinocytes, including initiated cells, are stimulated to proliferate. Terminal differentiation is accelerated by phorbol esters through the induction of epidermal transglutaminase and consequent cornification. Retinoids inhibit terminal differentiation of keratinocytes. Retinoids also induce transglutaminase in epidermis, but they inhibit cornification. Recent results suggest a biochemical basis for this paradox. The phorbol ester-induced transglutaminase is primarily particulate but the retinoid-induced enzyme is cytosolic. The induced enzymes differ in kinetic parameters, thermal stability and in elution from ion-exchange columns. Induction of the retinoid enzyme is associated with suppression of the induction of transglutaminase by phorbol esters. The retinoid-induced epidermal transglutaminase could interfere with normal or promoter-induced differentiation by inappropriately cross-linking precursor proteins before their assembly at the cell periphery. This could explain one aspect of the inhibitory action of retinoids on tumour promotion.

Mouse Sprr2 genes: a clustered family of genes showing differential expression in epithelial tissues

Small proline-rich (SPR) proteins are structural components of the cornified cell envelope of stratified squamous epithelia. They are subdivided into three families, i.e., SPR1, SPR2, and SPR3, of which the SPR2 family is the most complex. To understand the significance of this complexity, we have isolated 11 mouse Sprr2 genes, constructed a provisional physical map of the Sprr2 locus on mouse Chromosome 3, and examined the expression patterns of the Sprr2 genes in mouse epithelial tissues. The 11 Sprr2 sequences are highly conserved with a central domain containing a variable number of repeats. In situ hybridization showed the Sprr2 expression to be confined to epithelia. RT-PCR using primers specific for each of the 11 Sprr2 members demonstrated varying degrees of expression among the individual Sprr2 members in different tissues. The correlation between the physical location of the genes in the Sprr2 locus and their expression patterns suggests multiple levels of controlled expression.

Differential expression and cell envelope incorporation of small proline-rich protein 1 in different cornified epithelia

In the final stages of terminal differentiation in the epidermis and other squamous epithelia, a approximately 15 nm thick protein layer called the cornified cell envelope (CE) assembles on the keratinocytes' inner surface. Its constituent proteins are covalently crosslinked by the action of transglutaminases. Recent studies have indicated that the expression of CE precursor proteins may vary in different tissues. To investigate such variations further, we have studied the CEs of two different keratinizing epithelia of mouse: epidermis and forestomach, with particular focus on their contents of loricrin and the small proline-rich proteins (SPRs). To this end, we have applied electron microscopic immunocytochemistry and estimated the CE protein compositions by mathematical modeling of their amino acid compositions. Ultrastructurally, forestomach resembles the epidermis in having well defined cornified and granular layers. Minor but significant differences are: in forestomach, striated material resembling lamellar granules is intercalated between the cornified squames; and in forestomach granular layer cells, loricrin-containing L-granules are more abundant, and filaggrin-containing F-granules less abundant than in epidermis. In forestomach, dense labeling with anti-SPR1 antibody was observed at the margin of cornified layer cells; and in the granular layer, diffuse but positive labeling of both cytoplasm and nucleus. In contrast, epidermis was uniformly negative. Isolated forestomach CEs (but not epidermal CEs), labeled positively on the cytoplasmic side, consistent with the presence of covalently crosslinked SPR1. Our compositional analysis predicts the content of loricrin in forestomach CEs to be very high (approximately 65%), as in the epidermis, and accompanied by approximately 18% content of total SPRs. Of these, a substantial proportion should be SPR1, according to our immunolabeling data. In contrast, epidermal CEs are calculated to have a much lower amount of SPRs or SPR-like proteins (approximately 8%), with a negligible content of SPR1. Thus both kinds of CEs have loricrin as their major constituent but differ in their respective complements of SPRs, which are thought to inter-connect loricrin molecules in the final phase of CE assembly. Applying a basic concept of materials science, it may be that the observed differences in their SPR contents reflect differences in the mechanical and chemical properties required for the function of the respective CEs.

Sequence and expression patterns of mouse SPR1: Correlation of expression with epithelial function

A final event in the terminal differentiation of stratified squamous epithelia is the formation of a cornified cell envelope, which is a complex of several proteins cross-linked together by transglutaminases. One set of proteins is the family of small proline rich (SPR) proteins. In human foreskin epidermal cell envelopes, SPRs serve as cross-bridging proteins among the more abundant loricrin. In order to study further their evolution and expression, we have isolated and sequenced cDNAs encoding two mouse SPR1 proteins, SPR1a and SPR1b Comparative sequence analysis showed the preservation of the overall structure of mammalian SPR1 proteins with highly conserved termini and a central peptide domain repeated 13 (SPE1a) or seven (SPR1b) times. Tissues obtained from mouse fetal, newborn, and adult skin were tested by Northern blot analyses, in situ hybridization and immunohistochemistry using an antibody raised to a synthetic peptide corresponding to the C terminus of the SPR1a protein. Skin expression was first detected in fetal periderm in anagen hair follicles of newborn and older mice, and in the thickened epidermis of the lip and footpad, but no signal was detected in interfollicular trunk epidermis. High levels of SPR1a expression were found in epithelia from the forestomach and penis, and in benign squamous papillomas. Other epithelia expressing SPR1a include the tongue, esophagus, and vagina. Whenever detected, SPR1a positive staining was present in the spinous and granular layers. In the forestomach and papillomas, the periphery of cells in the cornified layer was also stained. Our results suggest that SPR1a participates widely in the construction of cell envelopes in cornifying epithelia characterized by either increased thickness or a requirement for extreme flexibility. Based on its likely function as a cross-bridging protein in cell envelopes, we conclude that the mechanical attributes of cell envelopes may be determined in part by the SPR1 content, in accordance with the specific function of the epithelium.

Immortalized rat whisker dermal papilla cells cooperate with mouse immature hair follicle buds to activate type IV procollagenases in collagen matrix coculture: correlation with ability to promote hair follicle development in nude mouse grafts

An in vivo nude mouse graft model and an in vitro collagen matrix culture system were used to study interactions of immature hair follicle buds from newborn mice with clonally derived AdE1A-12S-immortalized rat whisker dermal papilla cell lines. Of the 19 available dermal papilla cell lines, four consistently supported good hair follicle development and hair growth in grafts. Seven cell lines were clearly negative in this assay, and the remaining eight cell lines yielded poor to moderate hair growth. As a correlate to in vivo extracellular matrix remodeling accompanying hair follicle development, type IV collagenase activity in the medium from cocultures of dermal papilla cells and hair follicle buds was analyzed by gelatin zymography. Hair follicle buds cultured alone secrete primarily the 92-kDa type IV procollagenase. Cocultivation of hair follicle buds with eight of the dermal papilla cell lines resulted in activation of this proenzyme and activation of the 72-kDa and 92-kDa type IV procollagenases produced by the dermal papilla cells. Seven of these eight dermal papilla cell lines support hair growth in the graft system. In the absence of dermal papilla cells, several growth factors induced activation of the 92-kDa procollagenase secreted by hair follicle buds cultured in serum-free medium: epidermal growth factor, transforming growth factor alpha, acidic fibroblast growth factor, and keratinocyte growth factor. The current working hypothesis is that a) hair follicle epithelial cells interact with dermal papilla cells in coculture by mutual induction of growth factors and cytokines that stimulate the release and activation of matrix remodeling proteases; and b) the ability of dermal papilla cells to interact with hair follicle epithelial cells in this way may be crucial for controlled dermal matrix remodelling during HF development.

Targeted disruption of mouse EGF receptor: effect of genetic background on mutant phenotype

Gene targeting was used to create a null allele at the epidermal growth factor receptor locus (Egfr). The phenotype was dependent on genetic background. EGFR deficiency on a CF-1 background resulted in peri-implantation death due to degeneration of the inner cell mass. On a 129/Sv background, homozygous mutants died at mid-gestation due to placental defects; on a CD-1 background, the mutants lived for up to 3 weeks and showed abnormalities in skin, kidney, brain, liver, and gastrointestinal tract. The multiple abnormalities associated with EGFR deficiency indicate that the receptor is involved in a wide range of cellular activities.

Retinol and beta-carotene concentrations in skin, papillomas and carcinomas, liver, and serum of mice fed retinoic acid or beta-carotene to suppress skin tumor formation

Using 7,12-dimethylbenz[a]anthracene as the initiator and 12-O-tetradecanoyl-13-acetate as the tumor promoter on the dorsal skin of Sencar mice, we previously showed that pharmacological dietary all-trans-retinoic acid and beta-carotene inhibit the conversion of papillomas to carcinomas in a two-stage system of chemical carcinogenesis. The purpose of this study was to determine the influence of dietary retinoic acid and beta-carotene on retinoid and beta-carotene concentrations in skin and other tissues. We were unable to measure tissue retinoic acid because of the relatively limited amount of tissue available for analysis and the fast rate of metabolism. Different dietary levels of retinoic acid or beta-carotene did not influence total retinol of skin, papilloma, and carcinoma tissues, which all showed a concentration of approximately 1 +/- 0.5 microgram/g wet wt. Equally refractory to dietary retinoic acid or beta-carotene was serum retinol concentration. In contrast, dietary retinoic acid protected loss of liver retinol and retinyl palmitate, and beta-carotene caused an increase in beta-carotene and retinyl palmitate in liver but did not affect serum and liver retinol. We further investigated metabolic and functional aspects of retinoic acid in cultured mouse epidermal keratinocytes (LC-8 cells) and found that these cells actively metabolized [10,11-14C]retinoic acid to polar compounds. Isomers of retinoic acid were a minor product in the presence of cells and the major product when incubated in serum-containing medium in the absence of cells. From the functional point of view, exposure of LC-8 cells to 3 x 10(-6) M all-trans-retinoic acid (RA) caused a 75-fold induction in tissue transglutaminase and an approximately 9-fold induction in 10(-6) M RA at three days of culture. We conclude that retinoic acid spares endogenous retinol and that beta-carotene greatly enhances liver retinyl palmitate levels. Moreover we show that although mouse epidermal cells metabolize retinoic acid at a very high rate, they respond functionally by induction of tissue transglutaminase activity. Because this enzyme has been suggested to be involved in programmed cell death, we are presently investigating the possibility that it may be involved in the inhibition of carcinogenesis in mice fed pharmacological doses of RA.

In vivo regulation of murine hair growth: insights from grafting defined cell populations onto nude mice

The nude mouse graft model for testing the hair-forming ability of selected cell populations has considerable potential for providing insights into factors that are important for hair follicle development and proper hair formation. We have developed a minimal component system consisting of immature hair follicle buds from newborn pigmented C57BL/6 mice and adenovirus E1A-immortalized rat vibrissa dermal papilla cells. Hair follicle buds contribute to formation of hairless skin when grafted alone or with Swiss 3T3 cells, but produce densely haired skin when grafted with a fresh dermal cell preparation. The fresh dermal cell preparation represents the single cell fraction after hair follicles have been removed from a collagenase digest of newborn mouse dermis. It provides dermal papilla cells, fibroblasts, and possibly other important growth factor-producing cell types. Rat vibrissa dermal papilla cells supported dense hair growth at early passage in culture but progressively lost this potential during repeated passage in culture. Of 19 E1A-immortalized, clonally derived rat vibrissa dermal papilla cell lines, the four most positive clones supported hair growth to the extent of approximately 200 to 300 hairs per 1-2 cm2 graft area. The remaining clones were moderately positive (five clones), weakly positive (three clones), or negative (seven clones). Swiss 3T3 cells prevented contraction of the graft area but did not appear to affect the number of hairs in the graft site produced by dermal papilla cells plus hair follicle buds alone. The relatively low hair density (estimated 1-5% of normal) resulting from grafts of hair follicle buds with the most positive of the immortalized dermal papilla cell clones compared to fresh dermal cells suggests that optimal reconstitution of hair growth requires some function of dermal papilla cells partially lost during the immortalization process and possibly the contribution of other cell types present in the fresh dermal cell preparation, which is not supplied by the Swiss 3T3 cells. The current graft system, comprising hair follicle buds and immortalized dermal papilla cell clones, provides an assay for positive or negative influences on hair growth exerted by added selected cell types, growth factors, or other substances. Characterization of the phenotype of the dermal papilla cell lines, which differ in their ability to support hair growth when grafted with hair follicle buds, may provide insight into specific dermal papilla cell properties important for their function in this system.

Regulation of hair follicle development: an in vitro model for hair follicle invasion of dermis and associated connective tissue remodeling

During embryonic development presumptive hair follicle cells of epithelial and mesenchymal origin are determined in defined body locations. This is followed by rapid proliferation of epithelial cells and associated penetration into the dermis in response to as yet undetermined signals. A collagen matrix culture system, which maintains the three-dimensional relationships of hair follicle cells to each other, was developed to study the regulation of the enlargement of immature hair follicles and the accompanying remodeling of the dermis. In studies with a heterogeneous dermis-derived preparation of murine hair follicles, ranging in size from the earliest down-growing budding cell mass to hair-forming follicles, we had previously shown that cell proliferation was stimulated by cholera toxin and epidermal growth factor, but only the epidermal growth factor-stimulated proliferation was accompanied by digestion of the collagen matrix due to release of collagenolytic enzymes. Further studies revealed that transforming growth factor-alpha also stimulated hair follicle cell proliferation and collagenase release. However, although transforming growth factor-beta inhibited the transforming growth factor-alpha-stimulated proliferation, it enhanced the release and activation of collagenases and other gelatin-degrading enzymes detectable by gelatin zymography. Stimulation of collagenolytic activity depended on the three-dimensional hair follicle structure and did not occur in monolayer cultures of hair follicle cells. Comparison of hair follicle buds with more developed dermis-derived hair follicles, plated at the same cell density (based on DNA content), suggested that a greater fraction of cells in the bud-stage follicle responded to the growth factors by release of collagenases. Possibly only the cells in the advancing portion of growing hair follicles that are closest to the dermal papilla cell cluster produce the collagenases in response to growth factors. To examine the participation of dermal papilla cells in collagenase release and activation, several immortalized rat whisker dermal papilla cell lines were co-cultured with mouse hair follicle buds. Co-culture resulted in a marked enlargement of follicles as well as activation of the 92-kDa type IV collagenase, produced by hair follicle buds, that correlated with ability of the dermal papilla cells to stimulate hair formation in grafts of hair follicle buds on nude mice. Dermal papilla cells cultured alone produced the 72-kDa type IV collagenase, which was also activated during co-culture with hair follicle buds. Thus, two activities, both relevant for hair follicle development, namely, cell proliferation and release and activation of collagenases, have been stimulated in immature hair follicle buds by either growth-factor supplementation or interaction with dermal papilla cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Reconstitution of hair follicle development in vivo: determination of follicle formation, hair growth, and hair quality by dermal cells

Combinations of cultured and uncultured epidermal and dermal cell preparations from newborn and perinatal mice were grafted onto the backs of athymic nude mouse hosts to elucidate the cellular requirements for skin appendage formation. All epidermal populations studied, including a total epidermal keratinocyte preparation from trypsin-split skin, developing hair follicle buds isolated from epidermis, and preformed hair follicles isolated from dermis, make haired skin when grafted with fresh dermal cells. Only pre-formed hair follicles produce haired skin on grafts without an additional dermal component. Hair follicle buds grafted alone or with cultured dermal cells will reconstitute skin but without appendage formation. Thus, cells or factors present in fresh, but not cultured, dermal cells are essential for supporting hair growth from budding follicles, whereas more developed (pre-formed) follicles appear to contain all the necessary components for hair formation. Dissociation of isolated hair follicles by trypsin/ethylenediaminetetraacetic acid prior to grafting is permissive for hair growth, suggesting that follicle cells can be re-induced or reassociate in vivo. Dermal papilla cells, microdissected from rat vibrissal follicles and cultured for up to 14 passages, stimulate hair growth from follicle buds and influence the quality of hair growth from pre-formed hair follicles. Thus, dermal papilla cells maintain inductive capacity in culture and contribute to the reconstituted skin. This reconstitution model should be useful for identifying cell populations within the hair follicle compartment necessary for hair growth and for examining the effects of specific gene products on hair follicle growth and development in vivo.

Leukoregulin and gamma-interferon inhibit human papillomavirus type 16 gene transcription in human papillomavirus-immortalized human cervical cells

The human papillomavirus (HPV) transforming genes E6 and E7 are retained and expressed in the majority of cervical cancers implying an important role for these proteins in maintenance of the malignant phenotype. Leukoregulin (LR) and recombinant gamma-interferon (r-IFN-gamma), lymphokines secreted by immune cells present in regressing HPV infections, inhibited transcription of E6/E7 RNAs in several human cervical epithelial cell lines immortalized by recombinant HPV-16, -18, and -33 DNAs. r-IFN alpha was not effective. Reduction in E6/E7 RNA expression was accompanied by inhibition of cell proliferation coincident with an increase in epidermal transglutaminase activity, a marker of squamous differentiation. LR and r-IFN gamma enhanced transcription of class 1 cell surface histocompatibility antigens (HLA) and r-IFN gamma additionally induced HLA class 2 expression. HPV-immortalized cells developed partial resistance to the growth inhibitory effects of lymphokines after malignant transformation or extended propagation in culture. This is the first demonstration that LR and r-IFN gamma selectively inhibit transcription of HPV-transforming genes and suggests a molecular mechanism by which these lymphokines participate in regression of premalignant cells.

Characterization of human loricrin. Structure and function of a new class of epidermal cell envelope proteins

We have isolated and characterized a full-length cDNA clone encoding human loricrin. Curiously, this protein displays major differences from the recently described mouse loricrin (Mehrel, T., Hohl, D., Nakazawa, H., Rothnagel, J.A., Longley, M.A., Bundman, D., Cheng, C.K., Lichti, U., Bisher, M.E., Steven, A. C., Steinert, P.M., Yuspa, S.H., and Roop, D.R. (1990) Cell 61, 1103-1112). Although both proteins are glycine-serine-cysteine-rich, the sequences have not been conserved. However, analysis of the sequences reveals a common motif of quasi-peptide repeats of an aliphatic or aromatic amino acid residue followed by several glycine and/or serine and cysteine residues. These sequences are interspersed and flanked by short glutamine- or glutamine/lysine-rich peptides. Thus loricrins consist of a family of cell envelope proteins of highly variable sequences that nevertheless retain common structural elements. We show that unlike all other putative protein components of the cell envelope, loricrins are highly insoluble, due at least in part to cross-linking by disulfide bonds. Furthermore, we have isolated four peptides from purified human cell envelopes that contain recognizable loricrin sequences and which are cross-linked by the N epsilon-(gamma-glutamyl)lysine isodipeptide bond. The presence of such bonds thus affords an explanation for the extraordinary insolubility of loricrin by cross-linking to the cell envelope and can also explain the low steady-state levels of monomeric loricrin in cytoskeletal extracts of epidermis. This study represents the first report of this isodipeptide cross-link in a protein component of the cornified cell envelope. We propose a model for the structure of loricrin in which (i) the unusual glycine-serine-rich sequences adopt a flexible loop conformation, indexed on the recurrent aliphatic residues; (ii) inter- or intramolecular isodipeptide and disulfide cross-links induce or stabilize folding of loricrin so as to form a more compact rosette-like structure; and (iii) the presence of the flexible glycine-rich loops necessarily will impact a flexible character to the cell envelope and entire epithelium.

Transcription of the human loricrin gene in vitro is induced by calcium and cell density and suppressed by retinoic acid

We have previously shown that loricrin is a major component of the cornified cell envelope (CE) expressed late in epidermal differentiation in the granular layers of normal skin. Normal human keratinocytes were cultured under various conditions and loricrin mRNA levels were assessed at various time points. Only Ca++ concentrations above 0.1 mM Ca++ were permissive for the expression of lori-crin mRNA. Maximal mRNA levels were found at 0.35 mM Ca++ and a critical cell density appeared to be required for optimal accumulation of loricrin transcripts. Retinoic acid (RA) at 10(-7) to 10(-9) M completely blocked Ca+(+)-induced loricrin mRNA synthesis when applied simultaneously. Furthermore, addition of RA to cultures already exposed to higher Ca++ levels resulted in the complete loss of loricrin mRNA within 48-72 h. So far, no other components of the CE have been shown to be suppressed by RA. However, similar patterns of expression were reported for filaggrin, a matrix protein also expressed late in epidermal differentiation. Therefore, we compared the mRNA levels of loricrin and filaggrin and found them to change in parallel in response to the various culture conditions. These results suggest that Ca++, cell density, and RA are crucial regulators of loricrin expression in vitro and that the transcriptional control of loricrin and filaggrin expression in the epidermis are closely coordinated.

Identification of a major keratinocyte cell envelope protein, loricrin

During epidermal cell cornification, the deposition of a layer of covalently cross-linked protein on the cytoplasmic face of the plasma membrane forms the cell envelope. We have isolated and characterized cDNA clones encoding a major differentiation product of mouse epidermal cells, which has an amino acid composition similar to that of purified cell envelopes. Transcripts of this gene are restricted to the granular layer and are as abundant as the differentiation-specific keratins, K1 and K10. An antiserum against a C-terminal peptide localizes this protein in discrete granules in the stratum granulosum and subsequently at the periphery of stratum corneum cells. Immunofluorescence and immunoelectron microscopy detect this epitope only on the inner surface of purified cell envelopes. Taken together, these results suggest that it is a major component of cell envelopes. On the basis of its presumed function, this protein is named loricrin.

Modulation of tissue and epidermal transglutaminases in mouse epidermal cells after treatment with 12-O-tetradecanoylphorbol-13-acetate and/or retinoic acid in vivo and in culture

Retinoic acid (RA) induces tissue transglutaminase (TGASE) and inhibits terminal differentiation induced either by calcium ion or by the tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) in primary mouse epidermal cells in culture. The relevance of these effects on cultured cells to the antipromoting action of RA was investigated in female BALB/c and CD-1 mice in vivo. Tissue TGASE was distinguished from epidermal TGASE on the basis of different thermolability at pH 9 or elution from the anion exchanger Mono Q. After topical application of 3 to 5 micrograms (10 to 17 nmol) of RA to the shaved back skin, the specific activity of tissue TGASE increased up to 30-fold primarily in the basal cell fraction of Percoll-separated epidermal cells. Enzyme activity returned to basal levels by 7 days. Treatment with TPA (10 micrograms or 17 nmol/mouse) induced an increase in epidermal TGASE which reached a maximum at 12 h after application, primarily in suprabasal cells. RA applied 1 h before TPA caused no reduction of TPA-induced epidermal TGASE, but the increase in tissue TGASE due to RA was markedly inhibited by TPA. The effects of TPA and RA on TGASE activities in primary epidermal cells in culture were similar to those in vivo except that RA reduced the induction of epidermal TGASE by TPA. In culture the induction of epidermal TGASE by TPA was independent of Ca2+ concentration in the medium above 0.03 mM, but cornified envelope formation was markedly enhanced by Ca2+ above the level required for maintaining a basal cell population (0.03 to 0.05 mM). The TPA-induced formation of cornified envelope in the presence of elevated Ca2+ was completely inhibited by RA if cells were pretreated with RA for 24 h. Our results are consistent with RA causing a reprogramming of epidermal cells that alters their response to differentiation stimuli.

Two types of transglutaminase in the PC12 pheochromocytoma cell line. Stimulation by sodium butyrate

Transglutaminases are a class of enzymes capable of covalently cross-linking both intracellular and extracellular proteins. The activity of tissue transglutaminase is known to decrease precipitously following neoplastic transformation, and it has been hypothesized that transglutaminase may be involved in growth regulation. We have found that the differentiation promoter sodium butyrate is able to cause a marked increase in transglutaminase activity in PC12 pheochromocytoma cells in a time- and dose-dependent manner. This increased transglutaminase activity is associated with growth arrest, as well as with striking morphological changes including increased cell adhesion. The transglutaminase induced by sodium butyrate appears to be tissue transglutaminase, based on its cytosolic localization, thermal lability at basic pH, and elution profile on anion-exchange chromatography. Untreated PC12 cells contain only small amounts of transglutaminase which resembles epidermal transglutaminase, an enzyme previously described only in skin. In contrast to sodium butyrate, nerve growth factor did not stimulate tissue transglutaminase in PC12 cells, although it, too, caused growth arrest. It is hypothesized that transglutaminase may be involved in certain morphological changes accompanying cellular differentiation and neoplastic transformation, rather than in growth regulation per se.

Effect of retinoic acid on cornified envelope formation: difference between spontaneous envelope formation in vivo or in vitro and expression of envelope competence

A large number of cross-linked envelopes form spontaneously when cell lines derived from chemically induced mouse skin papillomas are cultured in medium containing 1.2 mM calcium. This phenomenon is associated with high activity of the cross-linking enzyme, epidermal transglutaminase (TGase). The influence of retinoic acid (RA) on envelope formation was studied in detail in a papilloma cell line, PE. Retinoic acid (3 microM) completely blocked cornified envelope (CE) production but reduced TGase activity only 50%. A rabbit antiserum was produced against sonicated CEs isolated from newborn mouse skin. On Western blots of epidermal extracts, diffuse staining was observed for particulate proteins of suprabasal, but not basal, cells and similar immunoreactive material was absent from the cytosolic fraction of both cell layers. The antibody also recognized particulate proteins from PE cells induced to differentiate by calcium, but not from cells grown in the presence of high calcium and RA. The antiserum appears to recognize partially cross-linked CE precursor proteins judging by the diffuse staining, the molecular weight range of the proteins stained, and their origin in the particulate cellular fraction. Cross-linked envelopes could be induced in RA-treated PE cells by permeabilization with 0.75 M NaCl or 50 micrograms/ml A23187. However, this treatment failed to cause the appearance of proteins recognized by the antiserum. Preincubation of the antiserum with purified fragments of CEs from newborn mouse epidermis, but not with cross-linked envelopes from permeabilized, RA-treated PE cells, removed immunoreactivity. These results indicate that the cross-linked envelopes formed in RA-treated cells after permeabilization lack a set of proteins contained in CEs from stratum corneum and may even be composed of different proteins. Retinoic acid appears to prevent CE formation in part by inhibiting activation of epidermal TGase but in addition by influencing the synthesis of precursor proteins.

Response of carcinogen-altered mouse epidermal cells to phorbol ester tumor promoters and calcium

Primary cultures of mouse epidermal cells are induced to terminally differentiate when extracellular calcium levels are increased to more than 0.1 mM. After carcinogen treatment, cellular foci can be selected that resist this calcium signal to terminally differentiate. Calcium causes these foci to stratify; however, in contrast to normal epidermis, DNA-synthesizing cells in these foci are found in the suprabasal cell layers as well as in basal cells. Cell lines derived from these foci may be considered to be putative initiated cells. Three of these cell lines, designated 308, D, and F, have been characterized for their response to calcium and phorbol ester tumor promoters. The formation of cornified cells and the activity of epidermal transglutaminase were utilized as markers of epidermal differentiation. Neither calcium nor the tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) increased transglutaminase activity or cornification of any of the 3 lines. Proliferation was estimated by the [3H]thymidine labeling index, by incorporation of [3H]thymidine into DNA, and by a clonal growth assay. Unlike primary normal cultures, raising the calcium level of the medium did not markedly reduce the rate of proliferation of any of the 3 cell lines. In 2 of the lines, line 308 and line D, proliferation increased in response to TPA exposure. In line F, [3H]thymidine incorporation in confluent cultures was inhibited by TPA, while in cells plated at clonal densities, TPA was cytotoxic at doses of 5 ng/ml or higher. If these calcium-resistant epidermal cell lines correspond to initiated cells, their lack of sensitivity to the induction of terminal differentiation by TPA could account for their growth relative to normal cells. Those lines that also respond to stimulation of proliferation by TPA to a greater extent than normal cells would have a further growth advantage.

Cultivation and characterization of cells derived from mouse skin papillomas induced by an initiation-promotion protocol

Methods to culture cells from papillomas induced by an initiation-promotion protocol in SENCAR mice were developed, and the resultant cell lines have been characterized. Using Eagle's medium with 0.05 mM Ca2+ conditioned by dermal fibroblasts and supplemented with 1 ng/ml epidermal growth factor (EGF) in culture dishes coated with collagen and fibronectin, six cell lines (PA, PB, PC, PD, PE and PF) were established from separate pools of papillomas. When tested for tumorigenicity in nude mice by injection of a cell suspension or implantation of cells growing on a plastic liner, two of the lines (PC and PF) produced no tumors at any passage. In contrast, cells of the lines PA and PE produced highly differentiated squamous cell carcinomas from the earliest passage tested. The results with PB and PD were variable on tumorigenicity testing with some passages positive and others negative. When tested for responsiveness to Ca2+ (greater than 0.1 mM) as a differentiation stimulus, all lines responded. In the higher Ca2+ medium there was a 50-95% decrease in colony-forming efficiency, a slight decrease in [3H]thymidine incorporation (except for PA) and an increase in the number of cornified cells (except for early passage PF). Epidermal transglutaminase activity, a marker for terminal differentiation, was increased in the presence of medium with Ca2+ greater than 0.1 mM. However, unlike normal cells, only a fraction of the cells from each of the papilloma-derived cell lines terminally differentiated in response to Ca2+ while the remaining cells continued to proliferate, although at a slower rate. Responsiveness to phorbol ester tumor promoters was also examined in papilloma cell lines. 12-O-Tetradecanoylphorbol-13-acetate (TPA) treatment increased colony forming efficiency, DNA synthesis and colony size in all lines in medium with either 0.05 mM Ca2+ or 1.2 mM Ca2+. TPA treatment also increased ornithine decarboxylase activity in all lines, even at the higher Ca2+ concentration, although normal keratinocytes respond only when grown in medium with low Ca2+. TPA treatment caused only a slight increase in the number of cornified cells and no increase in epidermal transglutaminase activity in papilloma cells while it causes 10-fold or greater increases in these differentiation markers in normal keratinocytes. Thus papilloma cells appear to differ from normal keratinocytes in their ability to maintain a proliferating population under conditions favoring terminal differentiation, their consistent proliferative response to phorbol esters under these same conditions, and their reduced sensitivity to phorbol ester-induced terminal differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)

Similar effects of phospholipase C and phorbol ester tumor promoters on primary mouse epidermal cells

Interaction of tumor promoting phorbol esters with specific high affinity receptors is probably essential for many of the biological responses elicited by these agents. Since diacylglycerols which can be produced enzymatically from phospholipids by phospholipase C are postulated to be the physiological ligands for the phorbol ester receptor, we have examined primary cultures of mouse epidermal basal cells exposed to phospholipase C (Clostridium perfringens) for several biological and biochemical responses characteristic of treatment with 12-O-tetradecanoyl-phorbol-13-acetate, the most potent phorbol ester tumor promoter. Formation of diacylglycerols by treatment with phospholipase C was demonstrated by the dose-dependent release of radioactive diacylglycerols in cells prelabeled with [3H]arachidonic acid. Treatment with phospholipase C at 0.05 units/ml for 30 min led to the morphological changes and to the reduction in epidermal growth factor binding (90%) associated with 12-O-tetradecanoylphorbol-13-acetate treatment. Continuous treatment at the same dose led to the induction of the enzymes ornithine decarboxylase and transglutaminase with a time course and extent similar to the inductions by 12-O-tetradecanoylphorbol-13-acetate. Treatment with phospholipase C at 0.1 enzyme unit/ml yielded substantial suppression of the binding affinity of phorbol-12,13-dibutyrate for its receptors without reduction in total number of binding sites, consistent with the production by phospholipase C of a competitive inhibitor of phorbol ester binding. Several diacylglycerols at concentrations of 250 microM and above effectively competed for phorbol-12,13-dibutyrate binding, reduced epidermal growth factor binding, and to a lesser extent induced ornithine decarboxylase and transglutaminase. These results support the hypothesis that diacylglycerols can act through the phorbol ester receptors and thus produce biological and biochemical responses similar to those of the phorbol esters.

Keratinocytes blocked in phorbol ester-responsive early stage of terminal differentiation by sarcoma viruses

It has been suggested that the initiation step in mouse skin carcinogenesis involves an alteration in epidermal-differentiation, as mouse basal keratinocytes exposed to initiators resist the arrest of cell growth that is normally associated with the induction of terminal differentiation by calcium ions. The growth of epidermal basal cells infected by Kirsten (Ki) or Harvey (Ha) sarcoma viruses is, however, arrested in response to calcium ions, although the cells do not progress through their entire maturation programme when a functioning ras gene of those viruses is expressed. If continuous proliferation in the differentiating cell layers is a requirement for tumour formation in skin, the response of sarcoma virus-infected cells seems inconsistent with the suggestion that an activated ras gene is sufficient to initiate skin carcinogenesis. We now show that sarcoma virus-infected keratinocytes, when induced to differentiate, are blocked at an early, reversible stage of maturation. Furthermore, the cells respond to phorbol ester tumour promoters by undergoing a phenotypic reversion to a less mature stage. These results suggest that activation of a ras gene can produce conditionally initiated cells, in which the full expression of tumorigenicity depends on exposure to tumour promoters.

Retinoic acid-induced transglutaminase in mouse epidermal cells is distinct from epidermal transglutaminase

Elevated transglutaminase activity and formation of cornified envelopes are markers of terminal differentiation in mouse epidermal cells. Epidermal transglutaminase catalyzes cornified envelope formation and in cultured cells is inducible by calcium ion or phorbol ester tumor promoters. Retinoic acid also induces transglutaminase activity but inhibits cross-linked envelope formation. This apparent paradox might be resolved by the observation that the retinoic acid-induced transglutaminase appears to be either a different enzyme or a markedly altered form of the epidermal enzyme. The retinoic acid-induced transglutaminase is soluble in aqueous buffers, is thermolabile at pH 9.0, 37 degrees C, and elutes from an anion exchange column at 0.4 M NaCl. In contrast, the epidermal enzyme is particulate and requires detergent for solubilization, is relatively thermostable, and elutes from the anion exchanger at 0.25 M NaCl. The retinoic acid-induced enzyme is probably identical with the "tissue" transglutaminase present in liver and in other cells. It is proposed that the transglutaminase induced by retinoic acid may play a role in the inhibition by retinoids of calcium and tumor promoter-induced differentiation.

Regulation of epidermal transglutaminase activity and terminal differentiation by retinoids and phorbol esters

A number of characteristics of phorbol ester-mediated mouse skin tumor promotion indicate that cell selection is the underlying biological process. Studies in vivo and in cultured mouse epidermal cells suggest that selection is based on heterogeneous responses of subpopulations of basal cells which can be induced to proliferate or differentiate in response to promoter exposure. Retinoids are effective inhibitors of tumor promotion in mouse skin but do not influence the proliferative response to phorbol esters. Since both retinoids and phorbol esters modify epidermal differentiation, the antipromoter action of retinoids could be related to differentiation responses. Retinoic acid induces transglutaminase activity in cultured mouse epidermal basal cells grown in less than 0.1 mM Ca2+. While this enzyme is associated with terminal differentiation in skin, retinoic acid paradoxically blocks the terminal differentiation of cultured cells. In contrast, phorbol esters and extracellular calcium greater than 0.1 mM induce both transglutaminase activity and terminal differentiation. Enzyme kinetic analyses indicate that the transglutaminases induced by all three inducers are the same enzyme. The increase in activity of transglutaminase by all three inducers requires RNA and protein synthesis. However, the time course of increase and decay of each activity differs for each inducer. A variety of biologically active retinoids induce transglutaminase activity, and their effectiveness correlates with their reported antipromoter activity. Exposures to both retinoic acid and the phorbol ester 12-O-tetradecanoylphorbol-13-acetate are antagonistic resulting in less than additive induction. Induction kinetics with both inducers are more like those of retinoic acid than those of the phorbol ester. Simultaneous exposure to retinoic acid and 12-O-tetradecanoylphorbol-13-acetate protects the epidermal cell population from induced terminal differentiation and cell loss which is observed in response to the promoter alone. These results suggest that the antipromoting action of retinoids could be mediated by modification of phorbol ester-accelerated terminal differentiation through an effect on transglutaminase and cornification. This action of retinoids would block a critical aspect of cell selection involving loss of cells and subsequent regenerative hyperplasia, although simple hyperplasia may still occur.

Genetic evidence that a phorbol ester tumor promoter stimulates ornithine decarboxylase activity by a pathway that is independent of cyclic AMP-dependent protein kinases in CHO cells

Ornithine decarboxylase (ODC) inductions by cholera toxin and by the phorbol ester tumor promoter, TPA, were compared in wild-type Chinese hamster ovary (CHO) cells and in mutant cells having altered cyclic AMP-dependent protein kinase activity. The aim of these studies was to determine whether cyclic AMP-dependent protein kinase is involved in these inductions. The time course and the magnitude of ODC inductions by either 100 ng/ml cholera toxin or 100 ng/ml TPA were similar in wild-type cells with a maximum at 3-4 hours after treatment and a return to unstimulated levels by 8 hours. Induction of ODC by cholera toxin was suppressed more than 80% in the four protein kinase mutants studied (10215, 10248, 10260, and 10265), strongly implicating a cyclic AMP-dependent kinase step in the mechanism of induction. Similar results were found with the cyclic AMP analog 8-Br-cyclic AMP and the phosphodiesterase inhibitor, methyl-isobutylxanthine. The induction of ODC by TPA, on the other hand, was only partially inhibited (approximately 50%) in three of four mutants. Lower ODC activity in two mutants stimulated by cholera toxin or TPA whose kinetics were studied in more detail could not be ascribed to a reduced affinity (Km) of ornithine for the enzyme, but appeared to be due to reduced catalytic activity (Vmax) in the extracts. These results suggest that the induction of ODC by TPA proceeds by a mechanism which is only partially dependent on an intact cyclic AMP-dependent protein kinase activity.

Divergent responses in epidermal basal cells exposed to the tumor promoter 12-O-tetradecanoylphorbol-13-acetate

Mouse epidermal basal cells can be selectively cultivated in medium with 0.02 to 0.09 mM Ca2+ and can be induced to differentiate by medium containing 1.2 mM Ca2+. Basal cell cultures were studied to determine if all cells in this population responded identically to the skin tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA). Studies on the induction of the enzyme epidermal transglutaminase by TPA demonstrated a 2- to 4-fold increase in activity within 12 hr of exposure. This activity increase paralleled morphological differentiation in approximately 50% of the basal cell population, and differentiating cells sloughed from the culture dish within 24 to 48 hr as transglutaminase activity returned to basal levels. The cells which remained were resistant to induced differentiation by 1.2 mM Ca2+ medium, in that they failed to demonstrate increased transglutaminase activity or decreased thymidine incorporation, both characteristics of control basal cells induced to differentiate by 1.2 mM Ca2+. Cells remaining after a single exposure to TPA did not respond to a second exposure with an induction of transglutaminase if the interval between exposures was 4 days. TPA-pretreated cells did not undergo a transient decrease in thymidine incorporation (characteristic of control cells) when exposed to TPA a second time but instead were directly stimulated to proliferate by the phorbol ester, indicating that such cells were not refractory to the promoter. When the treatment-free interval after TPA was extended from 4 to 10 days, transglutaminase inducibility was restored in basal cells to either TPA or 1.2 mM Ca2+ as inducers. These results indicate that heterogeneity exits within the epidermal cell population and that exposure to phorbol esters induces differentiation in some cells, while stimulating proliferation in others. Such heterogeneous responses would cause a selective redistribution of the epidermal cell population and could lead to clonal expansion of initiated cells.

The tumor promoter 12-O-tetradecanoylphorbol-13-acetate induces ornithine decarboxylase in proliferating basal cells but not in differentiating cells from mouse epidermis

The cultivation of mouse epidermal cells in medium of reduced calcium concentration (0.02--0.1 mM) selects for basal cell growth. Elevation of medium calcium levels above 0.1 mM results in rapid and well defined differentiative changes. This model was utilized to determine which cell type in mouse epidermis responds to the phorbol ester tumor promoter, 12-O-tetradecanoylphorbol-13-acetate (TPA), by an induction of the enzyme ornithine decarboxylase (ODC). Previous data had shown that TPA induces ODC in primary mouse epidermal cells only during the first 36 hr after plating in medium containing 1.44 mM Ca2+. In contrast, the induction in cells grown in low calcium medium was 2--10-fold greater, and inducibility persisted for at least 4 weeks. The greater inducibility of ODC in low calcium cells is not paralleled by increased thymidine incorporation after TPA treatment, probably because these cells are already proliferating at a maximum rate. When low calcium cells grown in 0.07 mM Ca2+ medium were switched to 1.2 mM Ca2+, there was a rapid loss of ODC inducibility. These results strongly suggest that the basal cells of the epidermis constitute the major target cells for the induction of ODC by TPA. The induction of ODC by ultraviolet light was not enhanced by growth of cells in low calcium medium, indicating that extracellular calcium concentration per se does not determine ODC inducibility. When epidermal cells grown in 1.2 mM or 0.07 mM Ca2+ medium were exposed to both UV light and TPA, there was a significant synergistic effect of combined treatment over the sum of each individual response, suggesting that factors in addition to differentiation determine the extent of ODC induction.

Initiator and promoter induced specific changes in epidermal function and biological potential

Mouse epidermal basal cells can be selectively cultivated in medium with a calcium concentration of 0.01--9.09 mM. Terminal differentiation and sloughing of mature keratinocytes occur when the calcium concentration is increased to 1.2--1.4 mM. When basal cell cultures are exposed to chemical initiators of carcinogenesis, colonies of cells that resist calcium-induced differentiation evolve. Likewise, basal cells derived from mouse skin initiated in vivo yield foci that resist terminal differentiation. This defect in the commitment to terminal differentiation appears to be an essential change in initiated cells in skin and is also characteristic of malignant epidermal cells. This model system has also provided a means to determine if basal cells are more responsive to phorbol esters than other cells in epidermis and to explore the possibility that heterogeneity of response exists within subpopulations of basal cells. The induction of the enzyme ornithine decarboxylase (ODC) was used as a marker for responsiveness to phorbol esters. ODC induction after exposure to 12-0-tetradecanoylphorbol-13-acetate (TPA) in basal cells is enhanced 20-fold over the response of a culture population containing both differentiating and basal cells. When basal cells are induced to differentiate by increased calcium, responsiveness to TPA is lost within several hours. In basal cell cultures, two ODC responses can be distinguished. After exposure to low concentrations of TPA or to weak promoters of the phorbol ester series, ODC activity is maximal at 3 hr. With higher concentrations of TPA, the ODC maximum is at 9 hr. These results are consistent with the presence of subpopulations of basal cells with differing sensitivities to TPA. Other studies that use the enzyme epidermal transglutaminase as a marker for differentiation support this conclusion. In basal cell culture TPA exposure rapidly increases transglutaminase activity and cornified envelope development, reflecting induced differentiation in some cells. As differentiated cells are sloughed from the dish, the remaining basal cells proliferate and become resistant to induced differentiation by 1.2 mM calcium. These data provide additional evidence of basal cell heterogeneity in which TPA induces one subpopulation to differentiate while another is stimulated to proliferate and resists a differentiation signal. Tumor promoters, by their ability to produce heterogeneous responses with regard to terminal differentiation and proliferation, would cause redistribution of subpopulations of epidermal cells in skin. Cells that resist signals for terminal differentiation, such as initiated cells, would be expected to increase in number during remodeling, Clonal expansion of the initiated population could result in a benign tumor with an altered program of differentiation. In skin, benign tumors are the principal product of 2-stage carcinogenesis. Subsequent progression to malignancy may involve an additional step, probably a genetic alteration, that is independent of the tumor promoter.

Differential retinoic acid inhibition of ornithine decarboxylase induction by 12-O-tetradecanoylphorbol-13-acetate and by germicidal ultraviolet light

Several retinoids including retinoic acid effectively inhibit phorbol ester-mediated tumor promotion and ornithine decarboxylase (ODC) induction in mouse epidermis. To understand better the possible cellular site of action of retinoids, the inhibitory action of retinoic acid on the induction of ODC was compared for two distinctly different inducers, namely, 12-O-tetradecanoylphorbol-13-acetate (TPA) and germicidal ultraviolet light (UV), in primary mouse epidermal cell cultures. It was found that the induction of ODC by TPA is almost completely prevented by 0.1 to 1 microM retinoic acid while the induction by UV is only moderately inhibited. Maximum inhibition is achieved by treating cells continuously with retinoic acid from 4 hr after plating, although pretreatment or simultaneous treatment relative to either inducer is almost as effective. When added after the inducer, retinoic acid loses its effectiveness as an inhibitor more rapidly for TPA induction than for UV induction of ODC. The differential inhibition of enzyme induction cannot be accounted for by selective retinoid inhibition of DNA, RNA, or protein synthesis either alone or in concert with TPA or UV. Other agents known to modulate the induction of ODC by TPA (fluocinolone acetonide, tosyl-L-lysylchloromethane, and local anesthetics) do not act differentially on UV induction. These agents possibly act at transcription or translation, both of which are required for ODC induction by TPA or UV. The preferential inhibition by retinoic acid of ODC induction by TPA is interpreted to result from specific interference at a unique and early site of interaction of TPA with the cell.

Local anesthetics inhibit induction of ornithine decarboxylase by the tumor promoter 12-O-tetradecanoylphorbol 13-acetate

The induction of ornithine decarboxylase (L-ornithine carboxy-lyase, EC 4.1.1.17) activity in mouse epidermal cells in vivo and in vitro occurs rapidly after exposure to the tumor promoter 12-O-tetradecanoylphorbol 13-acetate (TPA). This induction has characteristics of a cell surface receptor-mediated process. Local anesthetics modify a variety of cellular responses mediated by membrane receptors. When cultured mouse epidermal cells were exposed to the local anesthetics lidocaine, tetracaine, or procaine (0.1-1 mM), induction of the decarboxylase by TPA was inhibited by more than 90%. In vivo, lidocaine essentially abolishes the decarboxylase response of mouse epidermis when applied shortly after TPA. In contrast, local anesthetics have no effect on the enzyme's activity when added directly to the assay mixture and, in concert with TPA, have only a minimal effect on overall protein synthesis relative to controls. However, lidocaine has no effect on TPA-stimulated DNA synthesis in vitro (12-fold with or without lidocaine). Local anesthetics also markedly inhibit induction of the decarboxylase by ultraviolet light, which is probably not membrane mediated. Furthermore, in culture, lidocaine has only a small inhibitory effect on ornithine decarboxylase when given before TPA but is an effective inhibitor even when given up to 4-5 hr after the promoter, a time when decarboxylase activity has already increased. These findings suggest that local anesthetics, which are tertiary amines, do not act at the site of interaction of TPA and its putative receptor but may be acting specifically on polyamine biosynthesis. These drugs could be useful agents to determine the role of the polyamine pathway in tumor promotion.

Dissociation of tumor promoter-stimulated ornithine decarboxylase activity and DNA synthesis in mouse epidermis in vivo and in vitro by fluocinolone acetonide, a tumor-promotion inhibitor

12-O-Tetradecanoyl phorbol-13-acetate (TPA), a tumor promoter, stimulates DNA synthesis in mouse epidermal cells in vivo and in vitro. This response appears to be mediated through polyamine metabolism because ornithine decarboxylase (L-ornithine carboxy-lyase, EC 4.1.1.17)activity is markedly increased shortly after promoter exposure and this induction varies in magnitude according to dose and promoter potency of a series of phorbol esters. In vitro, exogenous putrescine (0.01-10 mM) results in a dose-related increase and prolongation of promoter-stimulated DNA DNA synthesis, a phenomenon noted in other systems of polyamine-mediated growth stimulation. The anti-inflammatory steroid fluocinolone acetonide (FA), an inhibitor of tumor promotion, prevents TPA stimulation of epidermal proliferation in vivo and in vitro. In vitro, FA most effectively prevents stimulation of DNA synthesis when applied is not required. Paradoxially, FA potentiates the increase in ornithine decarboxylase activity after TPA administeration both in vivo and in vitro. Furthermore, the inhibition of TPA-stimulated DNA synthesis by FA in vitro can be reversed by exogenous putrescine. These results suggestthat FA exerts its antipromotion effect by reducing the sensitivity of the cell to polyamines or by reducing intracellular polyamine levels.