Molecular cloning of gene sequences regulated during squamous differentiation of tracheal epithelial cells and controlled by retinoic acid

A Review of In Vitro Modelling Approaches to the Identification and Modulation of Squamous Metaplasia in the Human Tracheobronchial Epithelium

Squamous metaplasia in the tracheobronchial epithelium (TBE) involves the replacement of the normal pseudostratified mucociliary epithelium with a stratified squamous epithelium. Squamous metaplasia is considered to be an adaptive response that protects the lumen from the effects of inhaled airborne pollutants, but which might also feature as a pre-neoplastic lesion preceding squamous cell carcinoma. With the exception of transglutaminase I, involucrin, and cytokeratins 5, 6 and 13, few markers that contribute to the squamous phenotype have been identified in human TBE that can be used in diagnosis or to monitor its development in laboratory investigations, and current models are inadequate to provide statistically meaningful data. Therefore, new predictive markers have been identified, and new techniques established, in epithelial in vitro models capable of expressing squamous characteristics, which will be used to identify hazardous exposures and elucidate the mechanisms by which they induce their effects. A protocol for the quantitative detection of transglutaminase activity has been standardised in keratinocytes, based on the enzymatic incorporation of fluorescein–cadaverine (FC) into bis(γ-glutamyl) polyamine cross-links. The specificity of this compound as a transglutaminase substrate was demonstrated by using a range of competitive transglutaminase inhibitors, and by modulation of the squamous pathway. FC incorporation was localised to the cell membrane of terminally differentiating cells, and was not visible in basal, proliferating cells. High calcium-containing medium, nicotine and cigarette smoke condensates (CSC) induced an increase in FC incorporation, providing evidence of their role in enhancing the squamous pathway. Analysis by flow cytometry was used to provide a quantitative assessment of a range of optimised squamous differentiation markers, identified in normal human bronchial epithelia and in a bronchial cell line. Transglutaminase I was induced in a time-dependent manner, in post-confluent cells induced to differentiate down the squamous pathway, whereas involucrin was ubiquitously expressed and the levels of cytokeratins 5, 6 and 18 were reduced. The response of these and other differentiation markers to squamous-inducing conditions is being explored.

Retinoic acid down-regulates VPAC(1) receptors and TGF-beta 3 but up-regulates TGF-beta 2 in lung cancer cells

The effects of retinoic acid (RA) on lung cancer cells were investigated. Both all-trans (t-RA) and 13-cis RA (c-RA) decreased specific (125)I-VIP binding to NCI-H1299 cells in a time- and concentration-dependent manner. After 20 hr, 30 microM t-RA decreased specific (125)I-VIP binding by 60%. By Scatchard analysis, the density of VIP binding sites but not the affinity was reduced by 42%. NCI-H1299 VPAC(1) receptor mRNA was reduced by 48%. VIP caused a 3-fold elevation in the NCI-H1299 cAMP, and the increase in cAMP caused by VIP was reduced by 38% if the NCI-H1299 cells were treated with t-RA. Using the MTT assay, 3 microM t-RA and 3 microM c-RA inhibited NCI-H1299 proliferation by 60 and 23% respectively. Also, transforming growth factor (TGF)-beta2 increased after treatment of NCI-H1299 cells with t-RA whereas TGF-beta 1 mRNA was unaffected and TGF-beta 3 mRNA was decreased. These results suggest that RA may inhibit lung cancer growth by down-regulating VPAC(1) receptor and TGF-beta 3 mRNA but up-regulating TGF-beta 2 mRNA.

Expression, regulation, and function of the SPR family of proteins. A review

The small, proline-rich (SPR) genes consist of three subclasses closely linked on human chromosome 1, a region referred to as the epidermal differentiation complex. SPR genes consist of two exons, with the second exon containing the entire open reading frame. SPRs are expressed in all squamous tissues of the skin, scalp, footpad, vaginal epithelia, and most of the epithelial lining of the digestive tract, including the lip, tongue, esophagus, and forestomach. Although SPR1 is absent in normal mucociliary epithelium of the respiratory tract, epithelia that undergo squamous differentiation in response to vitamin-A deficiency or to injury owing to exposure to environmental toxicants express SPR1. High levels of SPR1 are detected in various diseases and cancers of the skin or respiratory epithelia and in nonkeratinizing papillary adenocarcinomas. SPR expression can be regulated by transcriptional factors, by posttranscriptional factors, or by factors that affect SPR1 mRNA translation or protein turnover. Furthermore, regulation can be affected by the state of cell proliferation. The presence of SPR1 in most of these epithelia, and the absence of SPR3 in normal skin, suggest that these subclasses have distinct functions. Various approaches to the study of the cross-linked envelope (CE) components in identifying SPR1 and SPR2 and in suggesting that SPRs are one of the precursor proteins of the CE. However, expression of SPR1 in nonsquamous tissues and cell lines indicates a function not associated with squamous differentiation. Several studies have demonstrated that SPR1 antibodies react with nuclear proteins and that SPR1 is expressed in cells before entering the G0 phase of the cell cycle. Future studies should clarify the role of SPRs by modifying their contents in CE, and should identify SPR-associated proteins to clarify the cell growth-related role of SPR1.

Regulation of guanylate-binding protein expression in interferon-gamma-treated human epidermal keratinocytes and squamous cell carcinoma cells

Interferon-gamma is a potent inducer of growth arrest and squamous differentiation of human epidermal keratinocytes in vitro. In order to understand the proximate events regulating interferon-gamma action we studied the relationship between interferon-gamma-mediated induction of a cytoplasmic guanylate-binding protein and the expression of growth and differentiation marker genes in normal and transformed keratinocytes. Induction of guanylate-binding protein mRNA by interferon-gamma was detectable at 4 h, was transcription dependent, and preceded changes in the expression of markers of growth arrest (E2F-1 mRNA downregulation) and differentiation (SQ37 mRNA induction). The Ec50 value for guanylate-binding protein induction (4 units interferon-gamma per ml) was lower than previously reported for SQ37 (40 units interferon-gamma per ml). Guanylate-binding protein mRNA appeared to be only moderately downregulated by modulators of the squamous phenotype such as retinoic acid and transforming growth factor-beta1. In addition, mRNA levels of E2F-1 or SQ37 were not altered in several squamous carcinoma cell lines treated with interferon-gamma. In contrast, guanylate-binding protein mRNA was highly induced in all these cell lines following interferon-gamma treatment. Further analysis of the signal transduction pathway mediating interferon-gamma responses using protein kinase inhibitors indicated that guanylate-binding protein induction in normal human epidermal keratinocyte cells was most likely protein kinase C independent. Our data suggest that more than one postreceptor interferon-gamma signaling pathway exists in keratinocytes and that at least one of these pathways is defective in squamous carcinoma cells. Furthermore, our data demonstrated that the failure of the squamous carcinoma cells to undergo interferon-gamma-induced growth arrest and differentiation is not due to an inherent defect in interferon-gamma receptor activation, but most likely is due to a defect in a non-guanylate-binding protein-dependent signaling pathway.

Regulation of the transglutaminase I gene. Identification of DNA elements involved in its transcriptional control in tracheobronchial epithelial cells

The transglutaminase I (TGase I) gene encodes an enzyme that catalyzes the cross-linking of structural proteins involved in the formation of the cornified envelope during squamous cell differentiation. To identify DNA elements important for the transcriptional control of the TGase I gene, we analyzed the ability of a 2.9-kilobase pair (kb) upstream regulatory region to control the expression of a reporter gene in vivo and in vitro. Transgenic mice bearing the pTG(-2.9kb)CAT construct exhibited the same pattern of tissue-specific expression of CAT as reported for TGase I. Deletion analysis in transiently transfected rabbit tracheal epithelial cells indicated that two sequences from bp -490 to -470 and from -54 to -37 are involved in the activation of TGase I transcription. Point mutation analysis and mobility shift assays showed that the sequence located between -54 and -37 is a functional Sp1-like transcription element. Sp1 and Sp3, but not Sp2, are part of nuclear protein complexes from differentiated RbTE cells binding to this site. The element TGATGTCA between bp -490 and -470 is contained in a larger 22-bp palindrome and resembles the consensus cAMP response element-binding protein (CREB)/AP-1 element recognized by dimeric complexes of members of the CREB, ATF, Fos, and Jun families. Mutations in this sequence greatly reduced promoter activity. Supershift analysis identified CREB1, JunB, c-Fos, Fra-1, and c-Jun in protein complexes isolated from differentiated rabbit tracheal epithelial cells binding to this site. Our study shows that the Sp1- and CREB/AP-1-like sites act in concert to stimulate transcription of the TGase I gene. The 2.9-kb promoter region could guide expression of specific genes in the granular layer of the epidermis and could be useful in gene therapy.

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.

Suppression of relaxin gene expression by retinoids in squamous differentiated rabbit tracheal epithelial cells

Northern blot analysis of total RNA from a variety of rabbit tissues indicated that placenta is the primary site of expression of the protein hormone relaxin (previously called SQ10) in rabbits. Relaxin was not detected by this method in other rabbit tissues, including normal trachea and several squamous tissues. However, relaxin is highly induced during squamous cell differentiation in cultured rabbit tracheal epithelial (RbTE) cells. Retinoic acid and retinoids that selectively bind to the nuclear retinoid receptors, the retinoic acid receptors (RARs) and the retinoid X receptors (RXRs), and induce RARE- or RXRE-dependent transactivation as well as repression of AP-1-dependent transactivation, were all effective in suppressing relaxin expression. In addition, the retinoid SR11302, which exhibits only anti-AP-1 activity but does not induce RARE- or RXRE-dependent transactivation, was also able to inhibit relaxin expression. These results suggest that the suppression of relaxin expression is related to the anti-AP-1 activity of retinoids. To determine whether the relaxin gene is regulated by retinoids at the level of transcription, a 4.3 kb fragment of the 5' flanking region of the rabbit relaxin gene was cloned and analyzed. This regulatory region included a classic TATA-box as well as consensus sequences for several transcription factors, including CREB, NF-kappaB and AP-1. The ability of the 4.3 kb regulatory region to control the transcription of a luciferase reporter gene was analyzed in transiently transfected, squamous-differentiated RbTE cells. The results demonstrated that this regulatory region caused strong transactivation of the reporter gene. This transactivation was inhibited by retinoic acid, suggesting retinoid control at the transcriptional level. Deletion analysis indicated that multiple regulatory elements are involved in the regulation of relaxin gene expression during squamous differentiation as well as in the suppression by retinoids.

Epidermal differentiation and squamous metaplasia: from stem cell to cell death

Epidermal differentiation is a multi-step process defined by a cascade of interrelated changes in the expression of growth-regulatory and differentiation-specific genes (Fig. 1). Irreversible growth arrest is an early event in epidermal differentiation which occurs when cells transit from the basal to the innermost suprabasal layer of the skin and begin to express squamous-specific genes. In culture, interferon gamma, phorbol esters, confluence and growth in suspension are effective signals to induce irreversible growth arrest and differentiation. The induction of differentiation-specific genes occurs either concomitantly with or following growth arrest and is believed to be linked to the molecular events that control irreversible growth arrest. Such a link has been demonstrated in other cell systems undergoing terminal differentiation, such as myogenesis and adipogenesis. Genes encoding proteins involved in the formation of the cross-linked envelope are one set of squamous-specific genes which are induced in the suprabasal layers and include transglutaminase I and III, involucrin, loricrin and cornifins/small proline-rich proteins. Squamous-specific genes exhibit not only different patterns of tissue-specific expression but are also induced at different stages during differentiation, suggesting that transcription of individual genes is regulated by distinct mechanisms. The latter is supported by the identification of different sets of regulatory elements controlling the transcription of these genes. The importance of understanding both the mechanisms that regulate growth arrest and the differentiation program is emphasized by the association found between specific skin diseases and genetic alterations in growth-regulatory genes as well as differentiation markers. In addition, studies into those mechanisms will provide insight into the control of squamous metaplasia and the development of squamous cell carcinomas.

Differential expression of human cornifin alpha and beta in squamous differentiating epithelial tissues and several skin lesions

Cornifins/small proline-rich proteins (SPRRs) belong to a family of proline-rich proteins that function as cornified envelope precursors. We report here an immunohistochemical analysis of human cornifin-alpha and -beta expression in several stratified squamous epithelia. In normal human skin, cornifin-alpha was expressed in the granular layer of the epidermis of palmoplantar skin, in the inner lining cells of the follicular infundibulum, and in the inner root sheath of the hair follicle. It was also expressed in the upper squamous layers of the oral, esophageal, and vaginal epithelia. Cornifin-beta was detected in oral, esophageal, and vaginal epithelia, but not in normal skin. Immunoblot analysis revealed quantitative differences in cornifin-alpha expression in skin from different regions. Studies of specimens from various skin diseases showed that (i) cornifin-alpha was upregulated in inflammatory skin diseases, hyperplastic lesions, and in well-differentiated squamous cell carcinomas (SCCs), (ii) the expression of cornifin-beta was absent in inflammatory skin but was detected in highly differentiated keratinocytes in well-differentiated SCCs of the skin and some other hyperproliferative skin lesions, and in SCCs of the oral mucosa and esophagus. Northern blot analysis revealed that cornifin-alpha mRNA was present in all the squamous epithelial tissues studied, whereas cornifin-beta mRNA was expressed in oral mucosal epithelia and verrucous carcinoma of the skin but neither in normal nor in psoriatic skin. These results indicate that (i) the amount of cornifin alpha/SPRR1 expression in normal human skin depends on the body region, (ii) cornifin-alpha/SPRR1, but not cornifin-beta, contributes to the integrity of the hair follicle, and (iii) the expression of cornifin-beta is induced in some hyperplastic skin diseases only when the keratinocytes undergo extensive squamous differentiation.

Regulation of cornifin alpha expression in the vaginal and uterine epithelium by estrogen and retinoic acid

In this study, we analyze the regulation of the squamous-specific gene, cornifin alpha, by estrogen and retinoic acid in vaginal and uterine epithelial cells. In ovariectomized animals, the vaginal epithelium consists of a stratified, nonkeratinizing epithelium which changes into a highly-stratified, keratinizing epithelium upon treatment with estradiol. This transition is accompanied by a dramatic induction of the crosslinked envelope precursor, cornifin alpha. An increase in cornifin mRNA can be detected as early as 3 h after treatment. A similar effect is observed for the synthetic estrogenic agent diethylstilbestrol while other steroid hormones, including testosterone, progesterone or dexamethasone have little effect on cornifin expression. In contrast to the vagina, estradiol induces neither squamous differentiation nor expression of cornifin alpha in the uterine epithelium. Similar to the action of estradiol, vitamin A-deficiency greatly enhances squamous differentiation and keratinization in the vaginal epithelium. But unlike estradiol, it induces squamous metaplasia in the normally columnar, uterine epithelium, which eventually is replaced by a keratinizing epithelium in severe deficiency. This transition is associated with an induction of cornifin alpha expression. Immunohistochemical and in situ hybridization analysis localizes cornifin protein and mRNA in the suprabasal layers of the squamous epithelium. Our results demonstrate that estrogen and retinoids play key roles in the regulation of differentiation and cornifin alpha expression in the uterine and vaginal epithelium.

Localization and expression of cornifin-alpha/SPRR1 in mouse epidermis, anagen hair follicles, and skin neoplasms

Recently, cornifin-alpha/SPPR1 has been identified as a putative precursor protein of the cornified cell envelope. In this study, the expression and localization of cornifin-alpha/SPPR1 was examined in untreated and tumor promoter-treated mouse skin, hair follicles, and skin neoplasms. Western analysis with antiserum (SQ37A) to a rabbit cornifin-alpha peptide or antiserum (SQ37C) to a human SPRR1 peptide demonstrated a 31-kDa immunoreactive protein in mouse epidermis and Northern analysis revealed the presence of a 1-kb mRNA. Immunohistochemical staining of mouse skin with SQ37A or SQ37C revealed intense and specific staining of the infundibulum, isthmus, and of Henle's layer of the inner root sheath of the lower anagen hair follicle and weak staining of the telogen follicle and the suprabasal layers of the epidermis. Treatment of mouse skin with 12-0-tetradecanoyl-phorbol-13-acetate (TPA) produced a large increase in cornifin-alpha/SPRR1 protein and mRNA. Immunohistochemical localization of cornifin-alpha/SPRR1 in TPA-treated skin indicated that cornifin-alpha/SPRR1 was increased in the suprabasal epidermis but not in the follicle. sn-1,2,-didecanoylglycerol, a model lipid second messenger, produced an increase in cornifin-alpha/SPRR1 protein similar to that of TPA, while mirex, a non-phorbol ester-type promoter had no effect. Topical doses of retinoic acid did not repress TPA-induced cornifin-alpha/SPRR1 expression. Papillomas demonstrated a 10- and 100-fold increase in cornifin-alpha/SPRR1 protein and mRNA, and expression was restricted to suprabasal cells. Squamous cell carcinomas exhibited an intermediate level of cornifin-alpha protein, and expression was restricted to keratinized areas. These data indicate: i) cornifin-alpha/SPRR1 is expressed in mouse skin; ii) cornifin-alpha/SPRR1 is localized to specific areas of the anagen hair follicle with weak staining in the telogen follicle and epidermis; iii) epidermal cornifin-alpha/SPRR1 expression is induced by phorbol ester and sn-1,2-didecanoylglycerol but not mirex, and iv) papillomas and squamous cell carcinomas demonstrate a constitutive increase in cornifin-alpha/SPRR1 in differentiated areas of the neoplasms.

Cloning and regulation of cornifin beta, a new member of the cornifin/spr family. Suppression by retinoic acid receptor-selective retinoids

In this study, we describe the isolation and characterization of a cDNA clone C12 that encodes a new member of the cornifin/small proline-rich protein (spr) family, which we have named cornifin beta. C12 encodes a 1.1-kilobase pair mRNA and a 24.3-kDa cytosolic protein with a high proline content (19%). Its total amino acid sequence exhibits a 37-66% identity while the first 30 amino acids at the amino terminus are 87% identical to that of members of the cornifin family. At its carboxyl terminus, cornifin beta contains 21 tandem repeats of an octapeptide. Cornifin beta expression is restricted to several squamous epithelia. It is highly expressed in esophagus, tongue, and oral mucosa but, in contrast to cornifin alpha, is not detectable in the epidermis. Both retinoic acid and a retinoid selective for the nuclear retinoic acid receptors were very potent suppressors of cornifin beta expression while an analog selective for the nuclear retinoid X receptors was much less effective, suggesting that a specific retinoid signaling pathway is involved in this suppression. Cornifin beta can function through some of its Gln residues as an amine acceptor in transglutaminase-catalyzed cross-linking reactions. These results indicate that cornifin beta functions as a cross-linked envelope precursor.

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.

Retinoic acid-regulated cellular differentiation and mucin gene expression in isolated rabbit tracheal-epithelial cells in culture

Rabbit tracheal epithelial cells were cultured in a serum-free and hormone-supplemented medium with and without retinoic acid. The cells showed time-dependent mucin gene expression when cultured in the medium with retinoic acid. In the absence of retinoic acid, however, mucin mRNA was barely detectable in the cells. When retinoic acid was added back to the medium, the mucin message was prominent again. Actinomycin D and cycloheximide did not inhibit mucin gene expression. The mucin message was slightly elevated by cAMP agonists. A mucin antisense oligomer inhibited the retinoic acid-induced mucin mRNA expression and secretion, thus offering an alternate approach in the management of mucus hypersecretion in upper airway respiratory diseases such as chronic bronchitis, asthma, and cystic fibrosis.

The small proline-rich proteins constitute a multigene family of differentially regulated cornified cell envelope precursor proteins

Loricrin, involucrin, small proline-rich protein (SPRR)1, SPRR2, and SPRR3 genes are located within a cluster of 1.5 Mbp on chromosome 1q21 and most likely evolved from a common ancestor. Monospecific polyclonal antibodies and cDNA probes were produced to investigate SPRR transcripts and proteins. SPRR expression was restricted to terminally differentiating squamous cells, preferentially located at the cell periphery, and immunoreactivity was greatly reduced in cells with a mature cornified cell envelope. Furthermore, detectable SPRR2 and SPRR3 levels were strongly increased in differentiating keratinocyte cultures after addition of LTB-2, a specific inhibitor of transglutaminases, suggesting that they are precursor proteins of the cornified cell envelope. In normal epidermis, SPRR1 was restricted to appendageal areas, SPRR2 was expressed coherently, and SPRR3 was completely absent. In the upper digestive tract, SPRR1 was expressed in sublingual and tongue epithelium, SPRR2 was mostly restricted to lingual papillae, and SPRR3 was abundant in oral and esophageal epithelium. In psoriatic epidermis, SPRR1 and SPRR2 were expressed at much higher levels than in normal epidermis. Addition of 10(-7) M retinoic acid to cultured differentiating keratinocytes significantly down-regulated the expression of SPRR2 and SPRR3 transcripts and slightly decreased that of SPRR1. Thus, SPRR1, SPRR2, and SPRR3 are differentially expressed in vivo and in vitro, suggesting that the SPRR multigene family evolved to serve as highly specialized cornified cell envelope precursor proteins in stratified epithelia.

Retinoic acid negatively regulates beta 4 integrin expression and suppresses the malignant phenotype in a Lewis lung carcinoma cell line

Retinoic acid (RA) is a potent inhibitor of the malignant phenotype and of tumour cell growth. We observed that in vitro RA treatment of a highly metastatic lung carcinoma cell line (C87) induced a marked reduction in the amount of the beta 4 integrin subunit. The downregulation of this adhesion molecule was assessed by immunofluorescence, immunoprecipitation, and northern analysis. In order to investigate the effects of RA on the malignant phenotype in C87 cells we performed morphological and functional analysis after RA treatment. We found that RA was able to produce marked changes in C87 cell shape, increasing the number of flat cells (90% of the total cell population), and significantly inhibiting the malignant and invasive phenotype of C87 cells. RA treatment suppressed their clonogenic potential in soft agar (control, 20 +/- 5; RA, 0), and strongly reduced their chemotactic and chemoinvasive capacity (chemotaxis: control, 231 +/- 5; RA, 28 +/- 0; chemoinvasion: control, 132 +/- 11; RA = 2 +/- 1). FACS analysis and cell count, however, indicated that RA reduced the growth of C87 cells only partially. After 72 h of treatment we observed only a 10% reduction in the S phase fraction of the cell population. Finally, the reduced lung colony-forming ability, observed after i.v. injection of RA-treated cells (lung foci/animal: RA-treated cells, 1 +/- 0.1; untreated, 8.5 +/- 0.8), further supports the conclusion that in this murine lung carcinoma cell line a marked reduction in the expression of the beta 4 integrin subunit is associated with a marked inhibition of the malignant phenotype.

Expression of a squamous cell marker, the spr1 gene, is posttranscriptionally down-regulated by retinol in airway epithelium

Vitamin A (retinol) is required for the normal mucociliary differentiation of respiratory epithelium. A depletion of vitamin A promotes squamous cell metaplasia. To understand how vitamin A suppresses squamous cell differentiation, the expression of a squamous cell differentiation marker, the small proline-rich protein gene (spr1), was studied in cultured monkey tracheobronchial epithelial (TBE) cells. The expression of the spr1 gene was inhibited about 40 fold by retinol. The mRNA levels of the spr1 gene started to decline within 6 h of retinol treatment and reached a minimum level after 7 days. The inhibition by retinol was concentration dependent and did not require concurrent protein synthesis. The inhibition of the spr1 mRNA by retinol was not due to a decrease in the transcription rate of its gene but due to a decrease in its stability, as determined by nuclear run-on assays and mRNA half-life measurement, respectively. This result was further supported by a DNA transfection study using a chimeric construct containing the spr1 promoter region and the chloramphenicol acetyltransferase (CAT) reporter gene. The CAT activity in transfected cells was not inhibited by retinol. These results suggest that spr1 gene expression is posttranscriptionally down-regulated by retinol.

A small proline-rich protein regulated by vitamin A in tracheal epithelial cells is induced in lung tumors

In cell-free translations of RNA from primary cultures of pig trachea surface epithelial cells, we observed that a 20 kD proline-rich protein (sPRP) is induced during culturing (Biochem. Biophys. Res. Commun. 1990; 172:1304-1309). Subsequently, a cDNA encoding sPRP has been cloned from pig tracheal cell mRNA and sequenced. This cDNA shows a high similarity to cDNAs cloned from monkey tracheal cells cultured in vitamin A-free medium and from UV-irradiated human epidermal keratinocytes. Amino acid sequences from these cDNAs are exceptionally rich in proline, glutamine, cysteine, and lysine but contain no aromatic amino acids. Two repeats of 12 amino acids on the N-terminus are followed by multiple 8 amino acid repeats. When compared with monkey trachea and human keratinocyte cDNAs, the sPRP cDNA from pig trachea has an additional 24 bp nucleotide repeat. Antiserum raised to a synthetic peptide (23 amino acids) on the C-terminus of sPRP (C23-antiserum) reacted with the 20 kD sPRP in immunoprecipitations from cell-free translations. On Northern blot analysis, sPRP cDNA hybridized to RNAs of similar sizes in tracheal cells from cat, rabbit, and lamb. sPRP was not detected in tracheal cells that were cultured with 10(-9) M arotinoid. Since sPRP is considered a putative squamous cell differentiation marker, experiments using lung tumors were performed. sPRP mRNA levels were dramatically increased in squamous lung tumors that were induced by injecting hamsters with 4-(methylnitrosamino)- 1-(3-pyridyl)-1-butanone, a tobacco-specific nitrosamine. In situ hybridization with tissue sections prepared from these lung tumors revealed that cells around the keratin pearls contained high levels of sPRP mRNA.

Expression of cornifin in squamous differentiating epithelial tissues, including psoriatic and retinoic acid-treated skin

The expression of cornifin, a putative cross-linked envelope precursor, was investigated in several squamous differentiating tissues by in situ hybridization and immunohistochemical analysis. Cornifin mRNA and protein, which are absent in the normal mucociliary tracheal epithelium, are induced in the suprabasal layers of the squamous metaplastic tracheal epithelium of vitamin A-deficient hamsters. Similar to the induction of squamous metaplasia in vivo, culture of rabbit tracheal cells in the absence of retinoids results in squamous differentiation and expression of cornifin. This induction of cornifin expression is suppressed by retinoic acid and several of its analogs. Cornifin mRNA and protein are also detected in the suprabasal layers of the squamous epithelium of rabbit esophagus and tongue. The distribution of cornifin in human epidermis was compared with that of two other crosslinked envelope precursor proteins, involucrin and loricrin. The localization of cornifin and involucrin is very similar. Both are induced in the spinous layer and appear at an earlier stage during epidermal differentiation than loricrin. The expression of cornifin is greatly increased in psoriatic skin. Cornifin mRNA is barely detectable in normal epidermis, whereas it is present at relatively high levels in the suprabasal layers of psoriatic epidermis. Topical treatment with RA results in thickening of the skin and increases the level of cornifin mRNA and protein in the upper spinous layers of mouse skin. Cornifin expression correlates generally with squamous differentiation in a variety of tissues and is abnormally regulated in psoriatic skin and in skin treated topically with retinoic acid.

Retinoid-dependent transcriptional suppression of cytokeratin gene expression in human epidermal squamous cell carcinoma cells

We have previously demonstrated that cytokeratin levels are coordinately regulated in normal cultured human keratinocytes. In the present study we examine the mechanism of this regulation using human squamous cell carcinoma (SCC) cells. Treatment of SCC-13 cells with 20 or 200 nM trans-retinoic acid results in nearly complete suppression of cytokeratin K5 and K6 expression. This change is accompanied by a simultaneous reduction (> 20-fold) in the level of the mRNAs encoding K5 and K6. Transcriptional analysis indicates that the transcription rate of the K5 and K6 genes drops by approximately four to fivefold in retinoid treated nuclei. Retinol (2000 nM) also promotes this change. In contrast, cytokeratin K19 does not increase in the presence of retinoic acid, thus the normal coordinate regulation of keratin gene expression by retinoids appears to be uncoupled in SCC-13 cells. However, this does not represent a general defect in positive regulation of gene expression by retinoids, since in a transient transfection assay trans-retinoic acid positively regulates a reporter plasmid containing the retinoid response element from the retinoic acid receptor-beta gene. The synthetic retinoids Ro 13-6298 (ethyl ester) and its metabolic derivative Ro 13-7410 (free acid) are both active in modulating the differentiation of normal keratinocytes. In contrast, only Ro 13-7410 is active in SCC-13 cells. As Ro 13-6298 binds poorly to the retinoic acid receptors, this suggests that SCC-13 cells, unlike normal keratinocytes, lack the ability to convert Ro 13-6298 to the active Ro 13-7410.(ABSTRACT TRUNCATED AT 250 WORDS)

Squamous cell metaplasia in the human lung: molecular characteristics of epithelial stratification

Squamous cell metaplasia (SCM) is a frequent epithelial alteration of the human tracheobronchial mucosa. This review pays particular attention to the fact that SCM can mimic esophageal, and in some instances even skin-type differentiation, showing striking similarities not only in morphology but also in terms of gene expression. Therefore, characterization of this dynamic process lends insight into the process of stratification, squamous cell formation, and "keratinization" in a pathologically relevant in vivo situation in man. First, the concept of metaplasia is presented with certain historical viewpoints on histogenesis. Then, the morphological characteristics of normal bronchial epithelium are compared with the altered phenotype of cells in SCM. These changes are described as a disturbance of the finely tuned balance of differentiation and proliferation through the action of a variety of extrinsic and intrinsic factors. Molecular aspects of altered cell/cell and cell/extracellular matrix interactions in stratified compared with single-layered epithelia are discussed with reference to SCM in the lung. Intracellular organizational and compositional changes are then summarized with special emphasis on the differential distribution of the cytokeratin (CK) polypeptides. Finally, the still unresolved problems of the histogenetic relationships between normal bronchial mucosa, SCM, and pulmonary neoplasms are addressed. As these questions remain open, examples for detection of well defined "markers" are provided that may be employed as objective criteria for determining clinically important cellular differentiation features.

Regulation of epidermal keratin expression by retinoic acid and thyroid hormone

In the epidermis, retinoic acid (RA) is known to regulate the gene expression of keratins, the intermediate filament proteins of epithelial cells. We have cloned the upstream regulatory regions of three human epidermal keratin genes, K5, K10, and K14, and engineered DNA constructs in which these regions drive expression of the CAT reporter gene. By co-transfecting the constructs into various epithelial cell types along with the vectors expressing the nuclear receptors for RA and thyroid hormone (T3), we have shown that RA and T3 directly regulate expression of these three keratin genes through the action of their nuclear receptors. In this paper, we review our previous results to stress that RA has a dual effect on keratin expression in epidermis: both direct and indirect. We also analyze the DNA sequences upstream from those three RA-regulated keratin genes and identify the clusters of degenerate consensus half-site motifs, which may comprise the putative retinoic acid recognition elements (RAREs). Furthermore, our recent results concerning the regulation of K5 and K14 expression by the RA receptor are also shown; these confirm our predictions regarding the location of the RAREs in epidermal keratin genes.

Annexin I and involucrin are cross-linked by particulate transglutaminase into the cornified cell envelope of squamous cell carcinoma Y1

The squamous cell carcinoma line, SqCC/Y1, like natural squamous epithelia, forms a cornified cell envelope during differentiation which can be directly correlated with an increase in particulate transglutaminase activity. When transglutaminase is activated in these cells by calcium ionophore X-537A, annexin I and involucrin become incorporated into the cornified cell envelope and cannot be extracted with solutions containing sodium dodecyl sulfate (SDS) and beta-mercaptoethanol. This effect is specific for annexin I; thus, the amounts of annexins II and IV that were extractable from cells by SDS and beta-mercaptoethanol did not change following treatment with ionophore X-537A. Annexin I could be cross-linked in vitro to itself and to other endogenous proteins by transglutaminase extracted from the particulate fraction of SqCC/Y1 cells. Immunofluorescence studies showed that cross-linked annexin I and involucrin form an envelope-like structure in SqCC/Y1 cells during differentiation that cannot be extracted by EGTA and Triton X-100. The amount of staining of this envelope structure corresponded directly to the particulate transglutaminase activity of these cells. Annexin I monoclonal and polyclonal antibodies were shown to bind to purified cornified cell envelopes from SqCC/Y1. These studies suggest that particulate transglutaminase regulates a function of annexin I during the differentiation of SqCC/Y1 cells by covalently cross-linking this protein into the cornified cell envelope.

Identification of a new squamous cell differentiation marker and its suppression by retinoids

Rabbit tracheobronchial epithelial cells (RbTE) can undergo squamous cell differentiation under defined culture conditions and, therefore, have been used as a model to study the regulation of squamous cell differentiation markers. In the present study, we identified a 20-kDa protein, designated rSQ20, in the serum-free growth medium conditioned by RbTE cells undergoing squamous cell differentiation. The protein was also found in extracts of squamous differentiated cells. rSQ20 was labeled by cells incubated with [35S]methionine but not with [3H]glucosamine, suggesting that it is not a glycoprotein. Undifferentiated cells did not produce this protein. rSQ20 was detected in the conditioned medium of RbTE cells after they reached a confluent and growth-arrested state, and thereafter its level increased markedly and concurrently with an increase in type I (epidermal) transglutaminase, an established marker of squamous cell differentiation. rSQ20 found in concentrated conditioned medium of squamous differentiated RbTE cells was eluted from a gel filtration column as a protein of 20 kDa, similar to that found by gel electrophoresis under denaturing conditions, suggesting that it is not a multimeric protein. A protein with an apparent molecular weight of 16 kDa (rSQ16), probably the product of partial proteolysis of rSQ20, was often found in various amounts in the conditioned medium of differentiated RbTE cells. beta-All-trans retinoic acid and other vitamin A analogues (retinoids), which suppress squamous cell differentiation, inhibited the expression of rSQ20 in RbTE cells. RbTE cells immortalized by transfection with SV40 large T antigen as well as malignantly transformed derivatives obtained from the immortalized cells by further transfection with v-Ha-ras secreted SQ20 and SQ16 when grown to high cell densities although their squamous differentiation was impaired. An analogous protein with an apparent molecular weight of 16 kDa, designated hSQ16, was detected in the medium of differentiated normal human bronchial epithelial (NHBE) cells and normal human epidermal keratinocytes (NHEK). No such protein could be detected in the medium in which undifferentiated NHBE or NHEK cells were grown. These results suggest that rSQ20 and hSQ16 are new markers of squamous cell differentiation.

Differential regulation of the expression of transforming growth factor-beta mRNAs by growth factors and retinoic acid in chicken embryo chondrocytes, myocytes, and fibroblasts

Transforming growth factor-beta (TGF-beta) autoregulates its expression in several mammalian cell types. We now report that addition of TGF-beta s 1, 2, and 3 to primary chicken embryo cells differentially affects expression of the messenger RNAs for the different TGF-beta isoforms depending on the cell type. In cultured sternal chondrocytes, addition of TGF-beta s 1, 2, or 3 results in an increase in the steady-state levels of the messenger RNAs for TGF-beta s 2 and 3, but does not change expression of TGF-beta 4 mRNA. In contrast, in cultured cardiac myocytes, addition of TGF-beta s 1, 2, or 3 results in an increase in expression of TGF-beta s 3 and 4 mRNAs, but does not change expression of TGF-beta 2 mRNA. Moreover, expression of TGF-beta s 2, 3, and 4 mRNAs is not affected by addition of any of the TGF-beta s to fibroblasts. Addition of platelet-derived growth factor (PDGF), epidermal growth factor (EGF), or interleukin-1 (IL-1) to these chicken cells also has differential effects on expression of the different TGF-beta mRNAs depending on the cell type. Retinoic acid also has contrasting effects on chondrocytes and myocytes either increasing or decreasing, respectively, expression of TGF-beta s 2 and 3 mRNAs and TGF-beta 2 protein. Our results indicate a complex pattern of regulation of the different TGF-beta genes by themselves as well as by PDGF, EGF, IL-1, dexamethasone, TPA, and retinoic acid in chicken embryo cells.

The molecular cloning and expression of two CRABP cDNAs from human skin

Retinoic acid (RA) is known to have a profound effect on the growth and differentiation of human epidermal cells in vivo and in vitro. One of the proteins thought to be involved in mediating the action of RA is the cellular retinoic acid-binding protein (CRABP). We have used PCR technology to generate cDNAs for two distinct CRABPs from human skin and skin-derived cells. One is highly homologous to the CRABP I cDNAs previously cloned from bovine and murine sources. The second shares extensive deduced amino acid homology with CRABP II, a protein recently described in newborn rat and embryonic chick. Although both mRNAs can be detected in neonatal foreskin, CRABP II mRNA is the predominant one in this tissue, as well as in cultured newborn fibroblasts and keratinocytes. Northern blot analysis showed CRABP II mRNA level was only slightly reduced by addition of 10(-6) or 10(-5) M RA to cultures of neonatal foreskin-derived fibroblasts, as was the CRABP I mRNA level in cultured human gut epithelial cells. In contrast, expression of CRABP II mRNA by cultured neonatal keratinocytes was strongly downregulated by RA. We conclude that CRABP II is the predominant CRABP in human skin, at least in the newborn period, and that it is differentially regulated in fibroblasts versus keratinocytes. Our data are consistent with a role for CRABP in regulating the amount of RA delivered to the nucleus.

Expression of nuclear retinoic acid receptors in normal tracheobronchial cells and in lung carcinoma cells

Retinoids are important regulators of the growth and differentiation of tracheobronchial epithelial cells. To determine the mechanism of action of retinoids in these cells, we began to examine the expression of nuclear retinoic acid receptors (RARs) in normal human and rabbit tracheobronchial epithelial (HBE and RbTE, respectively) cells and in several lung carcinoma cell lines. A specific nuclear RAR-binding activity with a molecular weight of 50,000 was identified in these cells. A correlation was found between the binding of several retinoids to this RAR and their ability to inhibit transglutaminase Type I activity. Normal HBE and RbTE cells contained two RAR alpha mRNA transcripts, 2.6 and 3.5 kb in size, and one 3.1 kb RAR gamma transcript. RAR beta transcripts were undetectable in HBE cells. RAR expression was unchanged during squamous differentiation. Treatment of HBE and RbTE cells with 100 nM retinoic acid increased RAR beta mRNA expression but did not change the levels of RAR alpha and RAR gamma. In contrast, retinoic acid suppressed in these cells the level of involucrin, transglutaminase Type I, and SQ37 mRNA. In comparison with normal HBE cells, certain lung carcinoma cell lines appear to have an altered expression of RAR beta and RAR gamma. Human bronchial fibroblasts (HBF) expressed RAR alpha and RAR gamma transcripts of the same size as HBE cells. HBF cells contain low levels of a 2.9- and 3.3-kb RAR beta mRNA. Treatment of HBF cells with retinoic acid increased the level of RAR beta mRNA in a time-dependent manner; the maximal induction was about 15-fold. On the basis of these findings we hypothesize that RARs are involved in the suppression of squamous differentiation in tracheobronchial epithelial cells and that lung fibroblasts are target cells for retinoids.

Decreased biosynthesis of Forssman glycolipid after retinoic acid-induced differentiation of mouse F9 teratocarcinoma cells. Lectin-affinity chromatography of the glycolipid-derived oligosaccharide

Glycolipids synthesized by the mouse teratocarcinoma F9 cells and F9 cells (RA/F9 cells) induced to differentiate by a 3-day treatment with 0.1 microM all-trans-retinoic acid were analyzed. Both F9 cells and RA/F9 cells were incubated in media containing either D-[6-3H]galactose or D-[6-3H]glucosamine; the metabolically-radiolabeled glycolipids were isolated and the oligosaccharides were released from the glycolipids by ozonolysis and alkali fragmentation. From both cells, a single major pentasaccharide was isolated from the mixture of neutral [3H]oligosaccharides by affinity chromatography on a column of immobilized Helix pomatia agglutinin. The structure of this oligosaccharide was analyzed by methylation analysis and specific exoglycosidase treatments and identified as the Forssman pentasaccharide alpha-D-GalpNAc-(1----3)-beta-D-GalpNAc-(1----4)-alpha-D-Galp-(1----4)-b eta-D- Galp-(1----4)-D-Glc. There was a 3-4-fold decreased amount of the Forssman pentasaccharide from RA/F9 cells relative to F9 cells. In contrast, there were no major differences between these cells in the levels of globoside, the precursor to Forssman glycolipid. To investigate the basis for the decline in Forssman glycolipid synthesis upon differentiation, the activity of UDP-D-Gal-NAc:GbOse4Cer alpha-(1----3)-N-acetyl-D-galactosaminyltransferase (Forssman synthase) was determined in extracts of both the F9 and RA/F9 cells. The specific activity of Forssman synthase was approximately 70% lower in differentiated relative to the nondifferentiated cells. These data demonstrated that F9 cells synthesize authentic Forssman glycolipid, and that its expression and the activity of Forssman synthase were decreased following induced cellular differentiation.

Induction of extracellular matrix gene expression in normal human keratinocytes by transforming growth factor beta is altered by cellular differentiation

Changes in epithelial substrate have been related to the cellular capacity for proliferation and to changes in cellular behavior. The effect of TGF beta 1 on the expression of the basement membrane genes, fibronectin, laminin B1, and collagen alpha 1 (IV), was examined. Northern analysis revealed that treatment of normal human epidermal keratinocytes with 100 pM TGF beta 1 increased the expression of each extracellular matrix (ECM) gene within 4 h of treatment. Maximal induction was reached within 24 h after treatment. The induction of ECM mRNA expression was dose dependent and was observed at doses as low as 1-3 pM TGF beta 1. Incremental doses of TGF beta 1 also increased cellular levels of fibronectin protein in undifferentiated keratinocytes and resulted in increased secretion of fibronectin. Squamous-differentiated cultures of keratinocytes expressed lower levels of the extracellular matrix RNAs than did undifferentiated cells. Treatment of these differentiated cells with TGF beta 1 induced the expression of fibronectin mRNA to levels seen in TGF beta-treated, undifferentiated keratinocytes but only marginally increased the expression of collagen alpha 1 (IV) and laminin B1 mRNA. The increased fibronectin mRNA expression in the differentiated keratinocytes was also reflected by increased accumulation of cellular and secreted fibronectin protein. The inclusion of cycloheximide in the protocol indicated that TGF beta induction of collagen alpha 1 (IV) mRNA was signaled by proteins already present in the cells but that TGF beta required the synthesis of a protein(s) to fully induce expression of fibronectin and laminin B1 mRNA. The differential regulation of these genes in differentiated cells may be important to TGF beta action in regulating reepithelialization.

Changes in gene expression following exposure of nulli-SCCl murine embryonal carcinoma cells to inducers of differentiation: characterization of a down-regulated mRNA

cDNA libraries have been generated from Nulli-SCCl murine embryonal carcinoma (EC) cells untreated or treated for 24 h with all-trans retinoic acid (RA) or hexamethylenebisacetamide (HMBA), two chemically unrelated inducers of differentiation of EC cells. The libraries were screened for gene sequences whose expression was differentially regulated by one or both compounds. Of 20,000 cDNA clones screened, only 12 showed reproducible quantitative differences. One of the latter clones (pH 34) has been studied in detail. pH 34 cDNA hybridizes with a polyadenylated RNA (650 nucleotides) which is abundant in untreated Nulli-SCCl EC cells but whose steady-state levels decrease within 6 h of exposure to HMBA, reaching a minimum at 24 h. RA has a less-marked effect on this mRNA. Addition of inducers to the cells in fresh medium produces an early (15 min) transient increase in pH 34 mRNA levels. Nuclear run-on experiments are consistent with the view that the decrease in pH 34 mRNA is due to post-transcriptional events. Subclones of pH 34 in pGEM-4 were used to synthesize mRNA which could be translated in vitro into a 14-kDa protein. DNA sequencing of the pH 34 cDNA revealed that it is 607 bp in length with a single open reading frame capable of encoding a protein of 118 amino acids. Primer extension experiments revealed that the insert contains the full 5' sequence. Comparison with known sequences failed to reveal significant homology with previously sequenced proteins.

Thymosin beta 10 levels in developing human brain and its regulation by retinoic acid in the HTB-10 neuroblastoma

Human fetal brain expresses high levels of a polypeptide identified by protein biochemistry and molecular cloning as thymosin beta 10. Within the first 18 months after birth, the thymosin beta 10 content of human brain falls to undetectable levels. In order to establish the molecular basis of this process we screened a number of human tumor cell lines derived from the nervous system for the presence of thymosin beta 10. All of the cell line expressed authentic thymosin beta 10. However, in the HTB-10 neuroblastoma, retinoic acid caused a reduction in the level of thymosin beta 10. This effect of the retinoid was conditional upon its continual presence in the tissue culture medium and was not evident in the other cell lines examined. These results suggest that the thymosin beta 10 gene may be a target for retinoids in the developing nervous system.

Keratin 13 expression is linked to squamous differentiation in rabbit tracheal epithelial cells and down-regulated by retinoic acid

Rabbit tracheal epithelial (RbTE) cells in primary culture undergo at confluence a multistep program of squamous differentiation. This study examines the expression of keratins in RbTE cells in relation to this differentiation process. During the exponential growth phase RbTE cells are undifferentiated and express three major keratins, K5, K14, and K19, and two minor keratins, K6 and K16. Squamous differentiation is accompanied by increased expression of keratins K6, K16, and K19, and in particular of keratin K13, which reacts specifically with the monoclonal antibody AE8. These changes in keratin synthesis coincide with the commitment to terminal differentiation. Retinoic acid, an inhibitor of the expression of the squamous differentiated phenotype, inhibits the increase in the expression of K6, K16, and K13 and reduces the expression of K5 and K14; however, retinoic acid treatment results in increased levels of keratin K19 and K18. Retinoic acid inhibits the expression of K16 and K13 at concentrations as low as 10(-9)-10(-10) M. At least some of these changes in keratins appear to be related to alterations in the cellular levels of the respective mRNAs. Our results indicate that specific changes in keratin expression, in particular keratin K13, correlate with the onset of squamous differentiation in RbTE cells. Induction of the expression of keratin K13 may function as a marker of squamous differentiation in tracheobronchial epithelial cells.

Molecular biology of keratinocyte differentiation

Epidermal keratinocytes (skin cells) are highly specialized epithelial cells designed to perform a very specific function, separation of the organism from its environment. To accomplish this the cells synthesize precursors and assemble them into two distinct structures, the cornified envelope and keratin intermediate filaments. The intermediate filaments are assembled from keratin monomers and the cornified envelope is assembled from a protein called involucrin and several other proteins. Expression of involucrin and the keratins genes are regulated as a function of the stage of keratinocyte differentiation and by various external agents such as calcium and vitamin A. To study the function of these structures and the regulation of precursor production we have cloned cDNA and genomic clones encoding involucrin and four of the keratin polypeptides. Retinoids profoundly alter the differentiation pattern of human epidermal keratinocytes, but the underlying biochemical basis of this change is not known. In this report we describe retinoid-promoted changes in keratin gene expression that may, in part, be responsible for the alteration in cellular phenotype in the presence of the vitamin. We also describe the novel structure of the human 40 kD keratin, a member of the keratin family that is retinoid responsive and is likely to be important during epidermal development. Finally, we describe the structure of the envelope precursor protein, involucrin, as determined from its DNA sequence and speculate on its role in cornified envelope formation.

Enhancing effect of a phorbol ester and of retinoic acid on glucocorticoid induction of chenodeoxycholate hydroxylation in hepatoma cultures

In cultures of the differentiated clones Faza 967, Fao and HF, derived from Reuber hepatoma, physiological doses of glucocorticoid induce chenodeoxycholate 6 beta-hydroxylation, a microsomal cytochrome-P-450-mediated activity (enhanced in liver by phenobarbital and not by benzo[a]anthracene). Whereas 12-O-tetradecanoylphorbol 13-acetate (TPA) alone has no effect the tumor promoter, when added to dexamethasone, enhances this induction. This enhancement, half-maximum with 10 ng/ml TPA, is a function of the dose between 1 ng/ml and 50 ng/ml; 50 ng/ml (80 nM) increase 4-7-fold the induction rate (as measured in cultures by the amount of bile acid hydroxylated per 10(6) cells in 24 h, and in homogenates from treated cells) and 2.5-fold the maximum activity attained by the third day of induction. When added to cultures of the dedifferentiated clone H5, treated with benzo[a]anthracene, TPA does not influence benzo[a]pyrene hydroxylase induction, as shown by the total and relative amounts of the various hydrosoluble benzo[a]pyrene metabolites. TPA does not affect tyrosine aminotransferase induction in dexamethasone-treated Fao cultures. The enhancement is not suppressed by indomethacin, an inhibitor of prostaglandin synthesis. After dexamethasone removal from induced Faza 967 cultures, addition of TPA to the medium does not affect the decay rate of the chenodeoxycholate-hydroxylating activity. Retinoic acid similarly enhances the induction by dexamethasone of chenodeoxycholate hydroxylation, both in treated Faza 967 cultures and in homogenates from treated cultures. The effects of TPA and retinoic acid are additive. These results suggest a possible cooperation at the transcriptional level between transactive factors, involving TPA-mediated alterations, retinoic acid and glucocorticoid receptors. The system described might provide a convenient experimental approach in the study of its mechanism.

Human bronchial epithelial cells with integrated SV40 virus T antigen genes retain the ability to undergo squamous differentiation

Human bronchial epithelial cells transformed by either DNA virus infection (SV40 or Adenovirus 12-SV40 hybrid virus) or transfection with the SV40 large T antigen gene were studied for their ability to undergo squamous differentiation when exposed to 12-O-tetradecanoylphorbol-13 acetate (TPA), transforming growth factor-beta 1 (TGF-beta 1), or fetal bovine serum (FBS), agents that induce the squamous differentiation of normal human bronchial epithelial cells. Squamous differentiation occurred in all ten T-antigen-positive cell cultures when they were exposed to either FBS or TGF-beta 1, but none differentiated when exposed to TPA. From one cell line, designated BEAS-2B, two subclones were isolated, one of which was induced to undergo squamous differentiation by FBS, and a second that failed to undergo squamous differentiation and was mitogenically stimulated when exposed to serum. These phenotypically different subclones provide a new in vitro cellular system for delineating the mechanism(s) of human bronchial epithelial cell squamous differentiation in response to FBS or TGF-beta 1.

Human bronchial epithelial cells synthesize cholesterol sulfate during squamous differentiation in vitro

Epithelial cells of the airways can, under pathological conditions, undergo squamous metaplasia. The accumulation of cholesterol sulfate has recently been described as a new marker for squamous cell differentiation in rabbit tracheal epithelial cells. We now report that normal human bronchial epithelial cells in culture metabolically incorporated [35S]-sulfate and [3H]-mevalonate into material indistinguishable from cholesterol sulfate by the criteria of solubility in organic solvents, behavior on ion-exchange chromatography, susceptibility to solvolysis, and behavior on thin-layer chromatography before and after solvolysis. The accumulation of cholesterol [35S]-sulfate correlated well with squamous cell differentiation (as measured by cross-linked envelope formation), which occurred when the cells reached confluency. The increase in the level of cholesterol sulfate could be inhibited by the inclusion of retinoic acid in the cell-culture medium. The addition of phorbol-12-myristate-13-acetate or the presence of high Ca2+ concentration in the medium stimulated the accumulation of cholesterol sulfate. An increased activity of cholesterol sulfotransferase seems to account for the cholesterol sulfate accumulation. The original observation of cholesterol sulfate accumulation during squamous differentiation thus extends across species lines and strengthens the suggestion that the cholesterol sulfate may play an important role in this type of differentiation. Moreover, cholesterol sulfate provides a sensitive biochemical marker to study this pathway of differentiation of human bronchial epithelial cells.