Palmitoleic acid isomer (C16:1delta6) in human skin sebum is effective against gram-positive bacteria.

The percent lipid composition of pooled human sebum analyzed by thin-layer chromatography was: ceramides (13%), fatty acid (47%), cholesterol (7%), cholesterol esters (2%), squalene (11%), triglycerides (3%), and wax esters (17%). Total sebum lipids (2- 4 mg/ml), sonicated into bacterial culture medium, caused 4- to 5-fold log reduction in growth of gram-positive bacteria, Staphylococcus aureus, Streptococcus salivarius and the anaerobe Fusobacterium nucleatum, but was ineffective against most gram-negative bacteria. Fractionation of the sebum lipids showed that both saturated and unsaturated fatty acids contained the bulk of the antimicrobial activity. Lauric acid (C12:0) was the most active saturated fatty acid. The unsaturated fatty acid, palmitoleic acid (C16:1delta6, cPA) was both the most predominant monoene and the most active antimicrobial fatty acid. Purified cPA (>99%) yielded typical minimal inhibitory concentration (MIC) values of 10-20 microg/ml against gram-positive bacteria. Organically synthesized cPA isomer gave MIC values comparable to the natural material. Both natural and synthetic cPA were found to be the most active sebum lipid fraction in blocking the adherence of a pathogenic strain of Candida albicans to porcine stratum corneum. Ethanol in combination with cPA exerts a synergistic bactericidal activity against gram-negative pathogenic bacteria, including Pseudomonas aeruginosa, Propionibacterium acnes, Escherichia coli, and several methacillin-resistant strains of S. aureus. Palmitoleic acid may be useful in topical formulations for treatment of secondary gram-positive bacterial infections, as a gram-positive bacteria antimicrobial in wound dressings, and as a natural gram-positive antimicrobial preservative in skin and hair care products.

Inhibition of irritation and contact hypersensitivity by phenoxyacetic acid methyl ester in mice.

New anti-irritant treatments are required to prevent irritation and sensitization reactions to consumer medicines and dermatological drugs. We report here that phenoxyacetic acid methyl ester (PAME) is an effective agent to prevent and treat irritant and allergic contact dermatitis. Balb/c mice skin-treated with 1% PAME do not lose weight relative to vehicle-treated mice, nor is it irritating to mouse skin. Topical PAME prevents skin irritation to a wide variety of irritants including: arachidonic acid, capsaicin, sodium lauryl sulfate (SLS), disodium laureth sulfosuccinate and tetradecanoylphorbol-13-acetate. Histological studies showed that 1% PAME greatly diminished dermal neutrophilic infiltration and dermal capillary vessel dilation, and prevented epidermal hyperproliferation and hyperkeratosis that accompanies detergent (SLS)-induced skin irritation. Topical PAME inhibited ear swelling following ear challenge during the elicitation phase of contact hypersensitivity in mice sensitized with 1-chloro-2, 4-dinitrochlorobenzene (DNCB), oxazolone and the hair coloring dye rho-phenylenediamine (PPD). Finally, topical administration of 1% PAME prior to PPD or DNCB sensitization prevented the induction phase of contact hypersensitivity. These results indicate that PAME represents a potential new category of potent topical anti-inflammatory agents.

cis-urocanic acid induces mast cell degranulation and release of preformed TNF-alpha: A possible mechanism linking UVB and cis-urocanic acid to immunosuppression of contact hypersensitivity.

The search for effective inhibitors of transdermal drug-induced contact sensitization was directed to dermal mast-cell-degranulating agents (MCDA). Human skin organ cultures were employed to test whether cis-urocanic acid (C-UA) and other potential MCDAs cause mast cell degranulation. These were then tested for their ability to inhibit the induction phase of the contact hypersensitivity reaction (CHR). C-UA at 1 microg/ml significantly depleted mast cell chymase, whereas trans-urocanic acid (T-UA) was relatively ineffective. C-UA, but not T-UA, induced local effects of liberated mast cell TNF-alpha, as detected by E-selectin expression on the microvascular dermal endothelium. C-UA significantly reduced (>70%) the ear swelling response in Balb/c mice, when applied 24 h prior to application of a sensitizing amount of dinitrochlorobenzene (DNCB), and induced a prolonged (>3 weeks) state of immune tolerance (>40%). Similar effects on local immunosuppression of CHR were observed with topical chloroquine and capsaicin, while cromolyn, a mast cell membrane stabilizer, was unable to inhibit DNCB-induced CHR. It is suggested that MCDAs may interfere with downstream events associated with accessory cell function.

Several different ion channel modulators abrogate contact hypersensitivity in mice.

A major obstacle in transdermal delivery of drugs is the development of adverse skin sensitization reactions. We tested the concept that ion channel modulators as a class of agents suppress contact hypersensitivity in a mouse model. Mice were sensitized to several contact sensitizing chemicals including dinitrochlorobenzene (DNCB) and a sensitizing drug, nadolol. We report our successful use of several ion channel modulators in suppressing contact hypersensitivity, including amiloride, ethacrynic acid (ECA), nifedipine and verapamil. For this purpose, Balb/c female mice were sensitized with DNCB, and abrogation of induction of contact hypersensitivity reaction (CHR) was examined by topical pretreatment of the target-sensitized skin with amiloride, nifedipine and pairwise combinations of these agents with ECA, a potassium ion channel blocker. Abrogation of induction of CHR was observed in all cases. In addition, suppression of contact hypersensitivity was observed in nadolol-sensitized mice pretreated with either verapamil or nifedipine. The results indicate that ion channel inhibitors are broadly effective inhibitors of allergic contact dermatitis and may be useful for facilitating the transdermal delivery of therapeutic drugs that have sensitization potential.

Inhibition of irritation and contact hypersensitivity by ethacrynic acid.

The immunosuppressive effect of topical ethacrynic acid (ECA) was tested on both the induction and elicitation phases of contact sensitization in a mouse model. ECA (0.5% in vehicle) reduced the sensitization response by >50% when the sensitizer was either dinitrochlorobenzene (DNCB), oxazalone (OX) or para-phenylenediamine (PPD), and was applied 1 day later to the ECA-pretreated skin site. The immunosuppressive effect of combining ECA with either hydrocortisone or with cis-urocanic acid was also tested. An additive suppressive effect was observed with ECA in both combinations. The effect of ECA (1% in vehicle) on blocking the elicitation phase was also examined in a mouse ear edema assay. ECA was highly effective in preventing the challenge response in mice previously sensitized to either DNCB, OX or PPD. ECA (1% in vehicle) was also tested for its ability to inhibit contact irritation. ECA (1% in vehicle) was highly effective in preventing ear edema due to topically applied skin irritants including arachidonic acid, capsaicin, lactic acid, phorbol myristate acetate, trans-retinoic acid, and sodium lauryl sulfate. ECA may be useful for both prophylaxis and therapeutic treatment of diverse skin conditions including contact dermatitis, eczema, and other related allergic skin disorders.

Retinyl ethers as cancer chemopreventive agents. Suppression of mammary cancer.

It had been demonstrated previously that retinyl methyl ether (RME) can suppress carcinogen-induced mammary cancers in vivo. It had also been shown that RME is demethylated enzymatically to retinol and produces the toxic effects of retinol; however, a rationale was developed for further investigations of retinyl ethers and was the basis for the synthesis and biological evaluations of new retinyl ethers for the chemoprevention of mammary cancer, reported herein. Two of the new retinyl ethers, retinyl 3-methyl-2-butenyl ether (RMBE) and retinyl 2-propynyl ether (RPE), were evaluated for the suppression of mammary cancers in vivo. RMBE, RPE, RME, the 2,3,6-trimethyl-4-methoxyphenyl analogue of RME, and retinyl acetate (a positive control) were incorporated individually into the feed of rats that had been injected with N-methyl-N-nitrosourea to induce mammary cancers. Ninety-day tests of these compounds for suppression of mammary cancer showed that RPE has significant cancer chemopreventive activity, comparable to that of retinyl acetate in simultaneous tests. RMBE demonstrated borderline activity. Both RPE and RMBE were less toxic than retinyl acetate or RME and, in contrast to the other retinoids, did not cause accumulation of large amounts of retinyl palmitate in the liver. Further investigations of RPE showed that it accumulated in mammary tissue after a single oral dose was administered to female rats, reached maximum concentrations within 24 h, and was still present at 75-80% of maximum concentrations after 72 h. In ethanol at 25 degrees C, RPE slowly underwent intramolecular cyclization; small amounts of the cyclized product also appeared in mammary tissue of rats dosed with RPE. During the mammary cancer bioassay, however, RPE was essentially stable in the feed. Some of the new retinyl ethers, as well as RME, bind to cellular retinol-binding protein.

Sensitization of mice to topically applied drugs: albuterol, chlorpheniramine, clonidine and nadolol.

Allergic contact dermatitis from drugs is a significant obstacle to the development of transdermal drug delivery systems. Protocols for the sensitization of mice to drugs are needed to test methods for the prevention of allergic contact dermatitis. CBA/J female mice were sensitized to the drugs albuterol, chlorpheniramine, clonidine and nadolol by topical application. Sensitization was achieved by application of drug at 5% (w/v) to shaven dorsal skin for 5 days in a hydroxyethylcellulose vehicle. Contact sensitization was determined by measuring the ear swelling response to application of 1% drug in vehicle. Control mice treated by application of vehicle alone did not exhibit an ear swelling response to drug. Supplementation of the mice with vitamin A boosted the ear swelling response, as did application of drug to dorsal versus abdominal skin. Although plasma amounts of retinol were higher in vitamin A supplemented versus control mice, the rate of drug (albuterol and nadolol) permeation was not significantly different between vitamin A supplemented and control mice. Permeability of dorsal skin for nadolol was twice that of ventral skin, which may explain the differences in sensitization at these sites. This sensitization protocol should be useful in the development of hypoallergenic transdermal drug delivery systems.

A conformationally defined 6-s-trans-retinoic acid isomer: synthesis, chemopreventive activity, and toxicity.

A conformationally defined retinoic acid analog (1) which contains a dimethylene bridge to maintain the 6-s-trans orientation for two terminal double bonds in the polyene chain was synthesized. A Reformatsky reaction was utilized to extend the polyene chain of the starting enone, which provided exclusively the 9Z-configuration for the intermediate aldehyde. A Horners-Emmons condensation with this aldehyde then produced retinoic acid analogs with both 9Z- and 9Z,13Z-configurations. An I2-catalyzed isomerization of the intermediate 9Z-aldehyde yielded the all-E-aldehyde, which was olefinated as above to yield the (all-E)- and (13Z)-retinoic acid analogs of 1. Each configurational isomer of 1 was evaluated for its ability to inhibit the binding of retinoic acid to CRABP (chick skin) and to inhibit the chemical induction of ornithine decarboxylase in mouse skin. In each assay (all-E)-1 was the most active isomer, and this activity was comparable to or better than that for (all-E)-retinoic acid. (all-E)-1 and (13Z)-1 were both shown to be equally effective as (13Z)-retinoic acid in suppressing the proliferation of human sebaceous cells in vitro. (all-E)-1 was further evaluated for its ability to prevent the induction of mouse skin papillomas and to induce signs of vitamin A toxicity in mice. The cancer chemopreventive activity of (all-E)-1 was comparable to that of (all-E)-retinoic acid, and the toxicity was comparable to or slightly better than that of the natural vitamin.

Effects of growth factors, hormones, bacterial lipopolysaccharides, and lipotechoic acids on the clonal growth of normal ureteral epithelial cells in serum-free culture.

In vitro tissue culture techniques were employed to study the effects of bacterial endotoxins on the growth of normal epithelial cells from the human ureter (NHU). Primary cultures of NHU cells were initiated from explant outgrowth cultures of human ureteral tissue and cultured on collagen gel in F-12* medium containing 1% fetal calf serum (FCS). Optimal clonal growth of secondary cultures of NHU cells seeded at relatively low seeding cell densities, directly on plastic dishes, was achieved in F-12* medium containing bovine pituitary extract (0.5% BPE) and 0.05% BSA. Results indicated that insulin in the F-12* medium could be replaced by three orders of magnitude less IGF-1. Further clonal growth experiments demonstrated that PGE1 is growth stimulatory and can replace BPE as a growth factor requirement. This finding was in agreement with the fact that BPE growth requirement could be replaced by cholera toxin or dibutyryl cAMP. These results suggested that both BPE and cholera toxin operated by activation of a cAMP-dependent mitogenic pathway. Seven gram-negative bacterial lipopolysaccharides (LPS) and three gram-positive bacterial lipotechoic acids (LT) were tested for their effects on NHU clonal growth. Three out of the five LPS derived from Escherichia coli (strains 055:B5, 0128:B12, and 0127:B8), LPS from Klebsiella pneumoniae, and LPS from Pseudomonas aeruginosa all showed significant growth inhibitory effects at minimally effective doses ranging from 5 to 25 micrograms/ml. LPS derived from E. coli strain (0111:B4) had no growth effects at the highest concentration tested (100 micrograms/ml). In contrast, LT derived from Streptococcus pyogenes, S. faecalis, Staphylococcus aureas, and Bacillus subtilis all markedly enhanced clonal growth at concentrations ranging from 1 microgram/ml less than [LT] less than 50 micrograms/ml. LT from Strep. pyogenes was inhibitory to clonal growth at 100 micrograms/ml. The growth inhibitory effects of LPS were shown to be sensitive to the presence of hydrocortisone in the growth medium, indicating that LPS effects on growth are mediated via the arachidonic acid cascade. We speculate that these results indicate a link between the susceptibility of uroepithelial tissue to the pathogenic microflora seen in urinary tract diseases and the differential sensitivity of proliferation-competent uroepithelial cells to growth inhibition by LPS produced by gram-negative bacteria. However, further studies with uropathogenic serotypes will be necessary to corroborate this possibility. The growth-stimulating activity of LTs produced by gram-positive bacteria may be due to their ability to bind to cell-associated fibronectin and to activate the fibronectin receptor as part of ligand receptor-induced mitogenic transmembrane signalling pathway.

Carrier-mediated sulfate transport in human ureteral epithelial cells cultured in serum-free medium.

Sulfate transport studies were carried out in secondary cultures of epithelial cells isolated from the human ureter. Results demonstrate the presence of carrier-mediated SO4(2-) transport as supported by three lines of evidence: 1) saturation kinetics, 2) substrate specificity, and 3) inhibition by the anion transport inhibitor 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS). The DIDS-insensitive component of SO4(2-) transport was markedly lower than the DIDS-sensitive component and was not affected by changes in extracellular pH (pHo) or Cl- concentration. The mechanism of this DIDS-insensitive component is not clear. The DIDS-sensitive component of SO4(2-) uptake was a saturable function of the extracellular sulfate concentration ([SO4(2-)]o). Increasing the extracellular chloride concentration ([Cl-]o) inhibited DIDS-sensitive SO4(2-) uptake competitively. Taken together with the fact that increasing [Cl-]o stimulated SO4(2-) efflux, these results suggest that SO4(2-) uptake in uroepithelial cells occurs via SO4(2-)-Cl- anion exchange. Cis-inhibition studies with a variety of anions indicate that this anion-exchange system may be shared by S2O3(2-) and MoO4(2-) but not by NO3- and H2PO4-. SO4(2-) uptake was stimulated at decreasing pHo with a pK approximately 7.4. Decreasing pHo from 7 to 6 lowered the apparent Michaelis constant significantly but had no significant effect on kcat, suggesting that protons may increase the affinity of the SO4(2-) transporter for SO4(2-). SO4(2-) efflux was inhibited at low pHo and was stimulated by increasing [Cl-]o. This study is the first to demonstrate an ion transport process in epithelial cell cultures isolated from the human ureter. In contrast to epithelial cells from the upper urinary tract, no Na(+)-dependent SO4(2-) transport could be demonstrated in these lower urinary tract epithelial cells. In conclusion, the major mechanism for SO4(2-) transport in ureteral epithelial cells is a carrier-mediated, DIDS-sensitive, pHo-sensitive SO4(2-)/Cl- anion-exchange mechanism. These studies suggest that varying [SO4(2-)]o and [Cl-]o or pHo in the ureteral lumen will affect SO4(2-) influx and efflux and may influence the size of the intracellular pool of SO4(2-) available for macromolecular sulfation in these cells.

Characterization of human gingival keratinocytes cultured in a serum-free medium.

Primary cultures of keratinocytes were established from gingival tissue explanted on the surface of type I collagen gels and fed a serum-containing medium. Cells could be routinely subcultured for at least five passages in a basal nutrient medium (MCDB 153) containing low calcium (0.1 mM), and supplemented with ethanolamine, phosphoethanolamine, hydrocortisone, insulin, epidermal growth factor and protein of bovine pituitary extract. Cells seeded at low densities doubled exponentially in number every 24-30 h and formed a confluent monolayer within 10-14 days. Phase-contrast light and transmission electron microscopy showed that the keratinocyte cultures had features typical of epithelial cells, including desmosomes and perinuclear tonofilament bundles. Immunofluorescent microscopy showed the presence of specific keratin proteins in basal cells of proliferating cultures. Gel electrophoresis of the insoluble cytosolic proteins of gingival and skin keratinocytes showed several differences. Suspension of dividing gingival keratinocytes in 1.3% methylcellulose medium induced greater than 50% cross-linked envelopes, suggesting the existence of a terminal differentiation pathway in gingival basal cells. Clonal growth experiments showed that both insulin and epidermal growth factor were required for optimal clonal growth. The growth of subcultures was arrested and the unstratified epithelial monolayer induced to form a stratified sheet by replacing the growth medium with basal MCDB 153 medium depleted of growth factors and containing 2 mM calcium. Sheets of stratified gingival epithelium formed on and later released from the dish by enzymatic treatment may be suitable for a variety of experimental and clinical uses.

Biologically active aromatic retinoids bearing azido photoaffinity-labeling groups and their binding to cellular retinoic acid-binding protein.

Retinoids bearing azido photoaffinity-labeling groups (azidoretinoids) have potential as probes for investigating the molecular mechanisms of action of all-trans-retinoic acid (RA) as mediated by its cellular retinoic acid-binding protein (CRABP) and nuclear receptor proteins. Two new azidoretinoids, 3-azido-4-[2-(5,6,7,8-tetrahydro-5,5,8,8-tetramethyl-2-naphthalenyl)-1E- propen-1-yl]-benzonic acid and 4-(4-azido-5,6,7,8-tetrahydro-5,5,8,8-tetramethyl-2-anthracenyl)be nzoic acid were synthesized, and evaluated for their in vitro biological potency, and binding affinity for CRABP. Like RA, these aromatic azides had significant activity in modulating cell differentiation in retinoid-deficient hamster tracheal organ culture (ED500.02 nM and 0.03 nM, respectively) and in the inhibition of the induction of ornithine decarboxylase in mouse epidermis (ED50 7.0 nmol and 0.5 nmol, respectively). They also possessed high binding affinity for CRABP (ID50 0.9 microM and 0.85 microM, respectively). The tritiated aromatic azides were further evaluated for their ability to bind covalently to CRABP after photolysis. On photolysis at -78 degrees C, the two radiolabeled azidoretinoids formed stable adducts with CRABP. Treatment of the adducts with either RA or p-chloromercuriphenylsulfonic acid (CMPS) and subsequent dialysis did not cause any dissociation, indicating the formation of a covalent bond. In contrast, treatment of the unirradiated complexes with RA or CMPS led to dissociation of the complex. Synthesis of affinity labels and characterization of CRABP-retinoid complexes should provide useful information on the ligand-binding regions and insights into the mechanism of action of RA.

Retinoid receptor antisense DNAs inhibit alkaline phosphatase induction and clonogenicity in malignant keratinocytes.

Antisense oligodeoxynucleotides [oligo(dN)s] corresponding to human cellular retinol-binding protein I (cRBP) and human nuclear retinoic acid receptor alpha (hnRAR) were synthesized. Exposure of human malignant keratinocytes to these oligo(dN)s significantly attenuated the level of cytoplasmic cRBP and hnRAR in a concentration- and time-dependent manner. Further, the induction of alkaline phosphatase by retinol in these cells was blocked by treatment with 30 microM antisense oligo(dN) to cRBP or hnRAR but not by 30 microM of sense oligo(dN) to cRBP. Antisense oligo(dN) treatments concomitantly induced cell rounding, loss of cell-cell attachment, and cell adhesion to the substratum. By contrast, treatment of cells with an anticytokinetic agent, cytochalasin B, or with a cytostatic concentration of sodium azide failed to reduce cytoplasmic cRBP or hnRAR from nuclear extracts, even though antisense oligo(dN)-like changes in cell morphology were observed. Treatment of the cells for greater than 2.75 hr with 20-40 microM of either antisense oligo(dN) also led to the loss of clonogenic potential. These results show that both cytoplasmic and nuclear receptors for retinoids are important in the transduction of a retinoid signal response critical to cellular growth and differentiation. Our findings also suggest that defined genes, which are specified by retinoids and their receptors, may account for the pleiotropic effect of vitamin A compounds.

Biosynthesis of proteoglycans by proliferating and differentiating normal human keratinocytes cultured in serum-free medium.

Normal human keratinocytes (NHK) were cultured in serum-free medium, containing low (0.1 mM) or high (2 mM) calcium, to obtain proliferating and differentiating cultures, respectively. Proteoglycan (PG) synthesis of proliferating and differentiating NHK was investigated. Cultures were labeled with 35S-sulfate, and the PGs were extracted from medium and cell layer. The newly synthesized PGs were isolated by ion-exchange chromatography on a column of DEAE-Sephacel. The molecular properties of the PGs and the size and composition of glycosaminoglycans (GAGs) were determined. In general, the PGs are relatively small size (Mr 70,000-120,000). The PGs of proliferating cultures are larger in molecular size than the PGs of differentiating cultures, and this is due to the degradation of the GAG chains. The molecular weight of the GAG chains of proliferating NHK ranged from 4,800 to 22,000, and the range for GAGs from differentiating cultures varied from 2,800 to 9,600. By compositional analysis, these PGs proved to contain heparan sulfate, chondroitin sulfate, and dermatan sulfate as determined by nitrous acid degradation, and chondroitinase ACII and ABC digestion. No significant differences were found in the overall GAG composition of the medium secreted PGs of proliferating and differentiating cultures. In contrast, cell-associated PGs of differentiating cells had higher levels of heparan sulfate than those of proliferating cells.

Human squamous carcinoma cells express complex defects in the control of proliferation and differentiation.

Four human squamous carcinoma cell (SCC) lines (SCC-9, SCC-13, SCC-15, and SCC-25) were studied to characterize their relative ability to control proliferation and differentiation. These experiments were based on previous data that established that in normal human keratinocytes three distinct and sequential steps are involved in the integrated control of proliferation and differentiation: 1) reversible growth-arrest at a predifferentiation state, 2) irreversible loss of proliferative potential, and 3) terminal differentiation. The current results show that SCC can show changes in the culture conditions required to undergo reversible growth-arrest and SCC can express partial or complete defects in their ability to irreversibly growth-arrest or terminally differentiate. For example, SCC-9 and SCC-25 cannot irreversibly growth-arrest or terminally differentiate, SCC-13 can irreversibly growth-arrest but cannot terminally differentiate, and SCC-15 can irreversibly growth-arrest and terminally differentiate to a moderate extent. These results therefore extend previous data by establishing that the malignant transformation of human epithelial cells does not simply result from defects in the control of terminal differentiation but rather from a combination of complex defects in the regulation of proliferation and differentiation.

Reversal by retinoids of keratinization induced by benzo[alpha]pyrene in normal hamster tracheal explants: comparison with the assay involving organ culture of tracheas from vitamin A-deficient hamsters.

In a defined culture system for hamster tracheal explants, the activity of 12 different retinoids was evaluated for reversal of keratinization induced by exposure to the carcinogen, benzo[alpha]pyrene (BP-HTOC assay). The effects of retinoids in this system were compared to those in a defined culture system for tracheal explants from vitamin A-deficient hamsters (standard-HTOC assay). In both assays, all-trans-retinoic acid (RA) and 13-cis-RA were the most active retinoids. For RA and 13-cis-RA, the values of ED50 determined in the BP-HTOC bioassay were 4 x 10(-12) and 1 x 10(-11) M, respectively, whereas the corresponding values in the standard HTOC assay were 2 x 10(-11) and 3.3 x 10(-10) M. For all 12 retinoids, the ED50 values from the BP-HTOC were lower than those from the standard-HTOC assay, and there was also a statistically significant correlation between the rank-ordering of ED50 values from the 2 assays. Among 3 N-(retinoyl)amino acids examined in both assays, N-(retinoyl)leucine was the most active, N-(retinoyl)phenylalanine the least active, and N-(retinoyl)alanine intermediate. Among a novel series of bifunctional retinoic acid analogues, the dicarboxyl derivative was the most active. On the basis of these results, the BP-HTOC assay appears to be one of the most sensitive assays for retinoids yet developed. This assay is an appropriate model for evaluating the chemopreventive potential of new retinoids in vitro.

Biologic mechanisms for the regulation of normal human keratinocyte proliferation and differentiation.

Normal human keratinocytes can be grown in serum-free medium, and the integrated control of their proliferation and differentiation can be modulated experimentally. The growth of cultured human keratinocytes can also be specifically arrested at either reversible or irreversible growth arrest states. Reversible growth arrest is induced by culture in medium containing TGF-beta or ethionine or in medium deficient of isoleucine. Irreversible growth arrest is induced by culture in razoxane-containing medium or by routine passage of keratinocytes until senescence results. The current studies were performed to determine from which growth arrest states keratinocyte differentiation occurs. Cells were therefore growth-arrested at each state, and they were then incubated in several different differentiation-promoting culture conditions. The results show that differentiation, as determined by morphologic, cytochemical, and immunofluorescent assays, can be induced from multiple reversible and irreversible growth arrest states by a series of complex biologic mechanisms. More specifically, at least three distinct stages appear to be involved in the process of keratinocyte differentiation. First, cells arrest their growth at a reversible predifferentiation state. Second, cells irreversibly lose their proliferative potential. Finally, cells express the terminally differentiated keratinocyte phenotype.

Tumorigenic and molecular characterization of novel phorbol ester-resistant and -sensitive lines of mice.

Two outbred lines of CD-1 mice were developed using males and females in an initiation (dimethylbenz[a]anthracene; DMBA), promotion (12-O-tetradecanoylphorbol-13-acetate; TPA) challenge, posttumorigenesis breeding protocol. Our results indicate that the phorbol ester-sensitive (PESTI) line developed tumors at a rate 4.1 times faster than the CD-1 parental line, while the phorbol ester-resistant (PERTI) line developed tumors at a rate 36 times slower than the CD-1 parents. The average number of tumors per mouse reached levels of 27.5 at 12 wk in the PESTI line, 0.1 at 16 wk in the PERTI line, and 6.7 at 16 wk in the CD-1 line. Biochemical tests showed that the PESTI line had both a high basal level and an enhanced epidermal ornithine decarboxylase (E.C. 4.1.1.17) response to TPA, the latter being nine times that of the PERTI line at their maximum dosages. An autoradiographic analysis of in vivo epidermal cell protein phosphorylation indicated marked differences in basal protein phosphorylation profiles (with high phosphate incorporation, PERTI, 112.7, 95.5, 64.4, 40.8, 18.6, 17.4, and 12.3 kDa; PESTI, 64.4, 40.8, 31.8, and 12.3 kDa) as well as TPA-dependent changes in these profiles (difference from basal levels, PERTI, 31.8 and 12.8 kDa; PESTI, 139.6, 126.3, 37.2, and 18.6 kDa). These heterogeneous profiles indicate strong genetic segregation of these protein kinase C target substrates.(ABSTRACT TRUNCATED AT 250 WORDS)

Propagation of differentiating normal human tracheobronchial epithelial cells in serum-free medium.

Serial-passage cultures of normal human tracheobronchial (TB) epithelial cells that exhibit functional differentiation have been established in serum-free medium supplemented with bovine pituitary extract (25 micrograms/ml), insulin (5 micrograms/ml), hydrocortisone (0.5 micrograms/ml), EGF (5 ng/ml), 10(-6)M each of ethanolamine and phosphoethanolamine, and antibiotics. The cells proliferated in this medium with a population doubling time of approximately 80 hours. Further, the passaged cultures retained differentiated morphology as evidenced by secretion of glycoproteins, binding of concanavalin A lectin, and presence of alcian blue and periodic acid Schiff-positive material in their cytoplasm. Ultrastructural observations further supported the functional epithelial nature of the cultures. Most cells exhibited characteristic microvilli on cell surfaces and showed junctional complexes between them. The cytoplasm contained a large number of perinuclear secretory vesicles, a characteristic feature of the differentiated cells. These cultures provide an excellent model to study factors that regulate synthesis and secretion of glycoproteins in normal human TB cells.

Suppression of tumorigenicity by the cell-cycle-dependent control of cellular differentiation and proliferation.

The experiments described in this report were designed to determine if suppression of tumorigenicity can be mediated by cell-cycle-dependent mechanisms that control cellular differentiation and/or proliferation in mesenchymal stem cells of the 3T3 T type. These cells were employed because they possess distinct, well-characterized cell-cycle-dependent mechanisms to control both cellular differentiation and proliferation. To achieve our goal we developed by non-mutagenic procedures 23 clonal variants of 3T3 T stem cells that expressed one of 4 distinct phenotypes for the regulation of cellular differentiation and proliferation. Six clones expressed combined defects in the control of differentiation and proliferation; 6 expressed intact mechanisms to control proliferation but defects in the control of differentiation; and 3 expressed intact mechanisms to control differentiation but defects in the control of proliferation. Finally, 8 clones expressed no detectable phenotypic defects in the control of either differentiation or proliferation. Once isolated and characterized, each of these clones was assayed for its tumorigenic potential. The results establish that clones which express combined defects in the control of differentiation and proliferation are highly tumorigenic. By contrast, tumorigenicity is markedly suppressed in clones that maintain the ability to control their proliferation or their differentiation. Furthermore, clones that maintained the ability to control both proliferation and differentiation showed no evidence of tumorigenicity. These data are interpreted to suggest that stringently regulated control of cellular differentiation and/or proliferation can act as a cancer suppressor mechanism.