Identification of the gene coding for the Endo B murine cytokeratin and its methylated, stable inactive state in mouse nonepithelial cells

Mechanisms Regulating Stemness and Differentiation in Embryonal Carcinoma Cells

Just over ten years have passed since the seminal Takahashi-Yamanaka paper, and while most attention nowadays is on induced, embryonic, and cancer stem cells, much of the pioneering work arose from studies with embryonal carcinoma cells (ECCs) derived from teratocarcinomas. This original work was broad in scope, but eventually led the way for us to focus on the components involved in the gene regulation of stemness and differentiation. As the name implies, ECCs are malignant in nature, yet maintain the ability to differentiate into the 3 germ layers and extraembryonic tissues, as well as behave normally when reintroduced into a healthy blastocyst. Retinoic acid signaling has been thoroughly interrogated in ECCs, especially in the F9 and P19 murine cell models, and while we have touched on this aspect, this review purposely highlights how some key transcription factors regulate pluripotency and cell stemness prior to this signaling. Another major focus is on the epigenetic regulation of ECCs and stem cells, and, towards that end, this review closes on what we see as a new frontier in combating aging and human disease, namely, how cellular metabolism shapes the epigenetic landscape and hence the pluripotency of all stem cells.

Apoptosis and keratin intermediate filaments

Intermediate filament (IF) proteins utilize central alpha-helical domains to generate polymeric fibers intermediate in size between actin microfilaments and microtubules. The regions flanking the central structural domains have diverged greatly to permit IF proteins to adopt specialized functions. Keratins represent the largest two groups of IF proteins. Most keratins serve structural functions in hair or epidermis. Intracellular epidermal keratins also provide strength to epithelial sheets. The intracellular type I keratins and other IF proteins are cleaved by caspases during apoptosis to ensure the disposal of the relatively insoluble cellular components. However, recent studies have also revealed an unexpected protective role for keratin 8 during TNF and Fas mediated apoptosis. Evidence for possible functions of keratins both upstream and downstream of apoptotic signaling are considered.

BAG-1 accelerates cell motility of human gastric cancer cells

BAG-1 is a Hsp70/Hsc70-binding protein that interacts with Bcl-2, Raf-1, steroid hormone receptors, Siah-1, and hepatocyte growth factor (HGF) receptors, implying multiple functions for the BAG-1 protein. Here, we provide evidence that gene transfer-mediated overexpression of BAG-1 markedly enhances the motility of human gastric cancer cells. Two independent in vitro migration assays showed that the BAG-1-expressing MKN74 cells exhibited more active migration compared with control transfectants or parent MKN74 cells. In MKN74 cells, the overexpression of BAG-1 affected neither cell adhesion capability nor migration responses to HGF. The promotive effect of BAG-1 on cell migration was similarly observed in transfectants of another human gastric cancer MKN45 cell line. In BAG-1 transfected gastric cancer MKN74 cells, BAG-1 colocalized with cytokeratin as well as actin filaments, and was concentrated at membrane ruffles induced by lysophosphatidic acid (LPA). Taken together, these studies demonstrate that BAG-1 has a novel function as promoter of cell migration in human gastric cancer cells, possibly through cooperation with cytoskeletal proteins.

Identification of a bipotential precursor cell in hepatic cell lines derived from transgenic mice expressing cyto-Met in the liver

Met murine hepatocyte (MMH) lines were established from livers of transgenic mice expressing constitutively active human Met. These lines harbor two cell types: epithelial cells resembling the parental populations and flattened cells with multiple projections and a dispersed growth habit that are designated palmate. Epithelial cells express the liver-enriched transcription factors HNF4 and HNF1alpha, and proteins associated with epithelial cell differentiation. Treatments that modulate their differentiation state, including acidic FGF, induce hepatic functions. Palmate cells show none of these properties. However, they can differentiate along the hepatic cell lineage, giving rise to: (a) epithelial cells that express hepatic transcription factors and are competent to express hepatic functions; (b) bile duct-like structures in three-dimensional Matrigel cultures. Derivation of epithelial from palmate cells is confirmed by characterization of the progeny of individually fished cells. Furthermore, karyotype analysis confirms the direction of the phenotypic transition: palmate cells are diploid and the epithelial cells are hypotetraploid. The clonal isolation of the palmate cell, an immortalized nontransformed bipotential cell that does not yet express the liver-enriched transcription factors and is a precursor of the epithelial-hepatocyte in MMH lines, provides a new tool for the study of mechanisms controlling liver development.

A regulatory element of the human keratin 18 gene with AP-1-dependent promoter activity

The human keratin 18 (K18) gene is expressed in a restricted but diverse subset of differentiated epithelial tissues and carcinomas. The 10-kilobase pair K18 gene contains all of the genetic information necessary for tissue-specific, copy number-dependent and integration site-independent expression in transgenic mice. We identified a 100-base pair regulatory element that activates the K18 proximal promoter in the presence of the previously identified first intron enhancer. Deletion of the element greatly diminished K18 expression. This regulatory element also has cryptic, AP-1-dependent promoter activity in the absence of the normal promoter, which results in 10-40-fold higher levels of K18 RNA expression in transgenic mice. The high activity of this cryptic promoter is dependent upon the first intron enhancer. These experiments define interactive regulatory regions of the K18 gene that modulate expression in diverse epithelial cell types and identify an unusual regulatory element with promoter activity that may be useful for high level heterologous gene expression in transgenic animals.

Hepatocyte nuclear factor 4 provokes expression of epithelial marker genes, acting as a morphogen in dedifferentiated hepatoma cells

We have recently shown that stable expression of an epitope-tagged cDNA of the hepatocyte- enriched transcription factor, hepatocyte nuclear factor (HNF)4, in dedifferentiated rat hepatoma H5 cells is sufficient to provoke reexpression of a set of hepatocyte marker genes. Here, we demonstrate that the effects of HNF4 expression extend to the reestablishment of differentiated epithelial cell morphology and simple epithelial polarity. The acquisition of epithelial morphology occurs in two steps. First, expression of HNF4 results in reexpression of cytokeratin proteins and partial reestablishment of E-cadherin production. Only the transfectants are competent to respond to the synthetic glucocorticoid dexamethasone, which induces the second step of morphogenesis, including formation of the junctional complex and expression of a polarized cell phenotype. Cell fusion experiments revealed that the transfectant cells, which show only partial restoration of E-cadherin expression, produce an extinguisher that is capable of acting in trans to downregulate the E-cadherin gene of well-differentiated hepatoma cells. Bypass of this repression by stable expression of E-cadherin in H5 cells is sufficient to establish some epithelial cell characteristics, implying that the morphogenic potential of HNF4 in hepatic cells acts via activation of the E-cadherin gene. Thus, HNF4 seems to integrate the genetic programs of liver-specific gene expression and epithelial morphogenesis.

Methylation of an ETS site in the intron enhancer of the keratin 18 gene participates in tissue-specific repression

The activities of ETS transcription factors are modulated by posttranscriptional modifications and cooperation with other proteins. Another factor which could alter the regulation of genes by ETS transcription factors is DNA methylation of their cognate binding sites. The optimal activity of the keratin 18 (K18) gene is dependent upon an ETS binding site within an enhancer region located in the first intron. The methylation of the ETS binding site was correlated with the repression of the K18 gene in normal human tissues and in K18 transgenic mouse tissues. Neither recombinant ETS2 nor endogenous spleen ETS binding activities bound the methylated site effectively. Increased expression of the K18 gene in spleens of transgenic mice by use of an alternative, cryptic promoter 700 bp upstream of the enhancer resulted in modestly decreased methylation of the K18 ETS site and increased RNA expression. Expression in transgenic mice of a mutant K18 gene, which was still capable of activation by ETS factors but was no longer a substrate for DNA methylation of the ETS site, was fivefold higher in spleen and heart. However, expression in other organs such as liver and intestine was similar to that of the wild-type gene. This result suggests that DNA methylation of the K18 ETS site may be functionally important in the tissue-specific repression of the K18 gene. Epigenetic modification of the binding sites for some ETS transcription factors may result in a refractory transcriptional response even in the presence of necessary trans-acting activities.

Cytokeratin expression in human arteries pertinent to intimal thickening formation in the ductus arteriosus

Expression of epithelial cytokeratins type 8, 18 and 19 can be used to study smooth muscle cell differentiation during development. We studied the differentiation of smooth muscle cells in the ductus arteriosus before and during intimal thickening and compared the changes occurring in this vessel with the adjoining elastic ascending and descending aorta and the pulmonary trunk. The ductus arteriosus, a vessel connecting the pulmonary trunk and the aorta during fetal life, constricts shorty after birth and eventually closes. Effective closure occurs only in the case of well developed intimal thickening. Cytokeratin expression during fetal development was greatest in the media of the ascending aorta and pulmonary artery, while in the ductus and descending aorta cytokeratin staining was slight. These results suggest that ductus smooth muscle cells and the smooth muscle cells of the descending aorta show a more advanced differentiation as compared to the ascending aorta and pulmonary artery. At neonatal stages cytokeratin expression in the descending aorta, pulmonary artery and the ascending aorta had disappeared as was expected with increased differentiation. In the neonatal ductus arteriosus reexpression of cytokeratins was found in cell clusters in the hyaluronic acid rich environment of the intimal thickening and in the inner media. Reexpression of cytokeratins, especially when organized in clusters, may reflect changes in gene regulation. Therefore the clusters of cytokeratin positive cells in the ductus may be indicative of extensive changes, occurring during closure of this vessel in the neonatal period, in which inner media and intima are especially involved.

Oncogenic regulation and function of keratins 8 and 18

Keratin 8 (K8) and keratin 18 (K18) are the most common and characteristic members of the large intermediate filament gene family expressed in 'simple' or single layer epithelial tissues of the body. Their persistent expression in tumor cells derived from these epithelia has led to the wide spread use of keratin monoclonal antibodies as aids in the detection and identification of carcinomas. Oncogenes which activate ras signal transduction pathways stimulate expression of the K18 gene through transcription factors including members of the AP-1 (jun and fos) and ETS families. The persistent expression of K8 and K18 may reflect the integrated transcriptional activation of such transcription factors and, in the cases of ectopic expression, an escape from the suppressive epigenetic mechanisms of DNA methylation and chromatin condensation. Comparison of the mechanisms of transcriptional control of K18 expression with expression patterns documented in both normal and pathological conditions leads to the proposal that persistent K8 and K18 expression is a reflection of the action of multiple different oncogenes converging on the nucleus through a limited number of transcription factors to then influence the expression of a large number of genes including these keratins. Furthermore, correlation of various tumor cell characteristics including invasive behavior and drug sensitivity with K8 and K18 expression has stimulated consideration of the possible functions of these proteins in both normal development and in tumorigenesis. Recent developments in the analysis of the functions of these intermediate filament proteins provide new insights into diverse functions influenced by K8 and K18.

Transcription factor regulation of epidermal keratinocyte gene expression

The epidermis is a tissue that undergoes a very complex and tightly controlled differentiation program. The elaboration of this program is generally flawless, resulting in the production of an effective protective barrier for the organism. Many of the genes expressed during keratinocyte differentiation are expressed in a coordinate manner; this suggests that common regulatory models may emerge. The simplest model envisions a 'common regulatory element' that is possessed by all genes that are regulated together (e.g., involucrin and transglutaminase type 1). Studies to date, however, have not identified any such elements and, if anything, the available studies suggest that appropriate expression of each gene is achieved using sometime subtly and sometime grossly different mechanisms. Recent studies indicate that a variety of transcription factors (AP1, AP2, POU domain. Sp1, STAT factors) are expressed in the epidermis and, in many cases, multiple members of several families are present (e.g., AP1 and POU domain factors). The simultaneous expression of multiple members of a single transcription factor family provides numerous opportunities for complex regulation. Some studies suggest that specific members of these families interact with specific keratinocyte genes. The best studied of these families in epidermis is the AP1 family of factors. All of the known AP1 factors are expressed in epidermis [52] and each is expressed in a specific spatial pattern that suggests the potential to regulate multiple genes. It will be important to determine the role of each of these members in regulating keratinocyte gene expression. Finally, information is beginning to emerge regarding signal transduction in keratinocytes. Some of the early events in signal transduction have been identified (e.g., PLC and PKC activation, etc.) and some of the molecular targets of these pathways (e.g., AP1 transcription factors) are beginning to be identified. Eventually we can expect to elucidation of all of the steps between the interaction of the stimulating agent with its receptor and the activation of target gene expression.

The consensus sequence of a major Alu subfamily contains a functional retinoic acid response element

Alu repeats are interspersed repetitive DNA elements specific to primates that are present in 500,000 to 1 million copies. We show here that an Alu sequence encodes functional binding sites for retinoic acid receptors, which are members of the nuclear receptor family of transcription factors. The consensus sequences for the evolutionarily recent Alu subclasses contain three hexamer half sites, related to the consensus AGGTCA, arranged as direct repeats with a spacing of 2 bp, which is consistent with the binding specificities of retinoic acid receptors. An analysis was made of the DNA binding and transactivation potential of these sites from an Alu sequence that has been previously implicated in the regulation of the keratin K18 gene. These Alu double half sites are shown to bind bacterially synthesized retinoic acid receptors as assayed by electrophoretic mobility shift assays. These sites are further shown to function as a retinoic acid response element in transiently transfected CV-1 cells, increasing transcription of a reporter gene by a factor of approximately 35-fold. This transactivation requires cotransfection with vectors expressing retinoic acid receptors, as well as the presence of all-trans-retinoic acid, which is consistent with the known function of retinoic acid receptors as ligand-inducible transcription factors. The random insertion of potentially thousands of Alu repeats containing retinoic acid response elements throughout the primate genome is likely to have altered the expression of numerous genes, thereby contributing to evolutionary potential.

Tissue-specific and efficient expression of the human simple epithelial keratin 8 gene in transgenic mice

Keratin 8 is a type II intermediate filament protein found in simple epithelia. We have introduced a 12 kb DNA fragment of the human K8 locus into the germ line of mice. The transgene, containing 1.1 kb of 5′ flanking sequences, 7.7 kb corresponding to the body of the gene and 3.2 kb of 3′ flanking sequences, was expressed in all six lines obtained. Immunolocalization and RNA analysis of adult tissues showed that the tissue-specific expression pattern of the transgene was almost indistinguishable from that of the endogenous gene. This pattern was found in organs containing single epithelial cell types, such as trachea, lung, stomach, intestine, liver, kidney, thymus and glands. The highest expressing line, however, also produced human K8 in tissues such as stratified epithelia, where it formed part of the pre-existing keratin cytoskeleton of basal cells. Steady state levels of human K8 RNA were proportional to the copy number of the transgene, but transgene expression was less efficient, per gene copy, than that of the endogenous gene. When in the 12 kb DNA fragment the exons and introns of the gene were replaced by the Escherichia coli lacZ gene, the resulting construct showed no expression in transgenic mice. This suggests that 5′ and 3′ flanking sequences, in the absence of intragenic sequences, are not sufficient for K8 expression and that important control elements are located in the body of the K8 gene.

AP-1, ETS, and transcriptional silencers regulate retinoic acid-dependent induction of keratin 18 in embryonic cells

The differentiation of both embryonal carcinoma (EC) and embryonic stem (ES) cells can be triggered in culture by exposure to retinoic acid and results in the transcriptional induction of both the endogenous mouse keratin 18 (mK18) intermediate filament gene and an experimentally introduced human keratin 18 (K18) gene as well as a variety of other markers characteristic of extraembryonic endoderm. The induction of K18 in EC cells is limited, in part, by low levels of ETS and AP-1 transcription factor activities which bind to sites within a complex enhancer element located within the first intron of K18. RNA levels of ETS-2, c-Jun, and JunB increase upon the differentiation of ES cells and correlate with increased expression of K18. Occupancy of the ETS site, detected by in vivo footprinting methods, correlates with K18 induction in ES cells. In somatic cells, the ETS and AP-1 elements mediate induction by a variety of oncogenes associated with the ras signal transduction pathway. In EC cells, in addition to the induction by these limiting transcription factors, relief from negative regulation is mediated by three silencer elements located within the first intron of the K18 gene. These silencer elements function in F9 EC cells but not their differentiated derivatives, and their activity is correlated with proteins in F9 EC nuclei which bind to the silencers and are reduced in the nuclei of differentiated F9 cells. The induction of K18, associated with the differentiation of EC cells to extraembryonic endoderm, is due to a combination of relief from negative regulation and activation by members of the ETS and AP-1 transcription factor families.

AP-1, ETS, and transcriptional silencers regulate retinoic acid-dependent induction of keratin 18 in embryonic cells

The differentiation of both embryonal carcinoma (EC) and embryonic stem (ES) cells can be triggered in culture by exposure to retinoic acid and results in the transcriptional induction of both the endogenous mouse keratin 18 (mK18) intermediate filament gene and an experimentally introduced human keratin 18 (K18) gene as well as a variety of other markers characteristic of extraembryonic endoderm. The induction of K18 in EC cells is limited, in part, by low levels of ETS and AP-1 transcription factor activities which bind to sites within a complex enhancer element located within the first intron of K18. RNA levels of ETS-2, c-Jun, and JunB increase upon the differentiation of ES cells and correlate with increased expression of K18. Occupancy of the ETS site, detected by in vivo footprinting methods, correlates with K18 induction in ES cells. In somatic cells, the ETS and AP-1 elements mediate induction by a variety of oncogenes associated with the ras signal transduction pathway. In EC cells, in addition to the induction by these limiting transcription factors, relief from negative regulation is mediated by three silencer elements located within the first intron of the K18 gene. These silencer elements function in F9 EC cells but not their differentiated derivatives, and their activity is correlated with proteins in F9 EC nuclei which bind to the silencers and are reduced in the nuclei of differentiated F9 cells. The induction of K18, associated with the differentiation of EC cells to extraembryonic endoderm, is due to a combination of relief from negative regulation and activation by members of the ETS and AP-1 transcription factor families.

A novel pathway for retinoic acid-induced differentiation of F9 cells that is distinct from receptor-mediated trans-activation

Retinoic acid (RA) has striking effects on vertebrate development and induces differentiation of several lines of cells including embryonal carcinoma F9 cells. It is generally accepted that the actions of RA are mediated by nuclear receptors for RA. However, we now provide evidence that F9 cells can differentiate in response to RA without trans-activation by nuclear receptors. Irreversible differentiation of F9 cells was induced by 18 h of exposure to RA with subsequent incubation in the absence of RA. This induction of differentiation was not blocked after inhibition of protein synthesis and mRNA synthesis during the 18-h treatment with RA, but the endogenous RA receptors failed to activate transcription from their target genes that contain the receptor-binding sequences. During the commitment to RA-induced differentiation, at least five sets of four phosphorylated proteins underwent changes in the absence of protein synthesis de novo. These results suggest that there is a novel pathway for the action of RA that is independent of nuclear receptor-mediated trans-activation.

Activation of the mouse cytokeratin A (endo A) gene in teratocarcinoma F9 cells by the histone deacetylase inhibitor Trichostatin A

Treatment of cultured cells with sodium butyrate, that is the histone deacetylase inhibitor, induces the histone hyperacetylation and the expressions of various mammalian genes without affecting the level of protein synthesis. However, butyrate is a non-specific inhibitor of deacetylase because of its effects on various other enzymes and nuclear proteins other than histones. On the other hand, Trichostatin A (TSA) was recently found to be a potent and specific inhibitor of histone deacetylase. We examined the effect of TSA on the expression of mouse cytokeratin A (endo A). TSA increased endoA expression in F9 cells, and was effective at a much lower concentration than sodium butyrate. We also examined the changes of chromatin structure induced by the two drugs by a DNase I-hypersensitivity assay. Both drugs induced the formation of a DNase I-hypersensitive site (DH site) in only the promoter region. The precise mechanism(s) by which the two drugs increase endoA gene expression is unknown, but these results suggest that endoA expression is induced by inhibition of histone deacetylase and that the effect is at the transcriptional level.

Oncogene activation of human keratin 18 transcription via the Ras signal transduction pathway

Keratin 8 (K8) and keratin 18 (K18) are intermediate filament proteins normally expressed in simple epithelial tissues and persistently expressed in a wide variety of carcinomas. Ectopic expression of K8 and K18 occurs in some epidermal and murine skin carcinomas induced by chemical carcinogenesis or oncogenic ras expression. We show here that K18 is a direct target of the Ras signal transduction pathway, by demonstrating that activated Ha-Ras, as well as activated Src, Lck, or Raf, stimulates the transcription of K18. This activation is mediated by an enhancer element containing essential and closely spaced Ets and AP-1 transcription factor binding sites. Oncogene activation of K18 transcription provides a molecular explanation for the persistent and sometimes unexpected expression of K18 in such a wide variety of tumors.

Alu sequence involvement in transcriptional insulation of the keratin 18 gene in transgenic mice

The human keratin 18 (K18) gene is expressed in a variety of adult simple epithelial tissues, including liver, intestine, lung, and kidney, but is not normally found in skin, muscle, heart, spleen, or most of the brain. Transgenic animals derived from the cloned K18 gene express the transgene in appropriate tissues at levels directly proportional to the copy number and independently of the sites of integration. We have investigated in transgenic mice the dependence of K18 gene expression on the distal 5' and 3' flanking sequences and upon the RNA polymerase III promoter of an Alu repetitive DNA transcription unit immediately upstream of the K18 promoter. Integration site-independent expression of tandemly duplicated K18 transgenes requires the presence of either an 825-bp fragment of the 5' flanking sequence or the 3.5-kb 3' flanking sequence. Mutation of the RNA polymerase III promoter of the Alu element within the 825-bp fragment abolishes copy number-dependent expression in kidney but does not abolish integration site-independent expression when assayed in the absence of the 3' flanking sequence of the K18 gene. The characteristics of integration site-independent expression and copy number-dependent expression are separable. In addition, the formation of the chromatin state of the K18 gene, which likely restricts the tissue-specific expression of this gene, is not dependent upon the distal flanking sequences of the 10-kb K18 gene but rather may depend on internal regulatory regions of the gene.

Alu sequence involvement in transcriptional insulation of the keratin 18 gene in transgenic mice

The human keratin 18 (K18) gene is expressed in a variety of adult simple epithelial tissues, including liver, intestine, lung, and kidney, but is not normally found in skin, muscle, heart, spleen, or most of the brain. Transgenic animals derived from the cloned K18 gene express the transgene in appropriate tissues at levels directly proportional to the copy number and independently of the sites of integration. We have investigated in transgenic mice the dependence of K18 gene expression on the distal 5' and 3' flanking sequences and upon the RNA polymerase III promoter of an Alu repetitive DNA transcription unit immediately upstream of the K18 promoter. Integration site-independent expression of tandemly duplicated K18 transgenes requires the presence of either an 825-bp fragment of the 5' flanking sequence or the 3.5-kb 3' flanking sequence. Mutation of the RNA polymerase III promoter of the Alu element within the 825-bp fragment abolishes copy number-dependent expression in kidney but does not abolish integration site-independent expression when assayed in the absence of the 3' flanking sequence of the K18 gene. The characteristics of integration site-independent expression and copy number-dependent expression are separable. In addition, the formation of the chromatin state of the K18 gene, which likely restricts the tissue-specific expression of this gene, is not dependent upon the distal flanking sequences of the 10-kb K18 gene but rather may depend on internal regulatory regions of the gene.

A 300 bp 5′-upstream sequence of a differentiation-dependent rabbit K3 keratin gene can serve as a keratinocyte-specific promoter

Keratinocytes of the suprabasal compartment of many stratified epithelia synthesize as a major differentiation product a keratin pair, consisting of an acidic and a basic keratin, which accounts for 10–20% of the newly synthesized proteins. While genes of several differentiation-related keratins have been cloned and studied, relatively little is known about the molecular basis underlying their tissue-specific and differentiation-dependent expression. We have chosen to study, as a prototype of these genes, the gene of K3 keratin, which has the unique property of being expressed in the majority of corneal epithelial basal cells but suprabasally in peripheral cornea, the site of corneal epithelial stem cells. Using a monoclonal antibody, AE5, specific for K3 keratin, and a fragment of human K3 gene as probes, we have isolated several cDNA and genomic clones of rabbit K3 keratin. One genomic clone has been sequenced and characterized, and the identity of its coding sequence with that of cDNAs indicates that it corresponds to the single, functional rabbit K3 gene. Transfection assays showed that its 3.6 kb 5′-upstream sequence can drive a chloramphenicol acetyl transferase (CAT) reporter gene to express in cultured corneal and esophageal epithelial cells, but not in mesothelial and kidney epithelial cells or fibroblasts, all of rabbit origin. Serial deletion experiments narrowed this keratinocyte-specific promoter to within -300 bp upstream of the transcription initiation site. Its activity is not regulated by the coding or 3′-noncoding sequences that have been tested so far. This 300 bp 5′-upstream sequence of K3 keratin gene, which can function in vitro as a keratinocyte-specific promoter, contains two clusters of partially overlapping motifs, one with an NFkB consensus sequence and another with a GC box. The combinatorial effects of these multiple motifs and their cognate binding proteins may play an important role in regulating the expression of this tissue-restricted and differentiation-dependent keratin gene.

Transcriptional insulation of the human keratin 18 gene in transgenic mice

Expression of the 10-kb human keratin 18 (K18) gene in transgenic mice results in efficient and appropriate tissue-specific expression in a variety of internal epithelial organs, including liver, lung, intestine, kidney, and the ependymal epithelium of brain, but not in spleen, heart, or skeletal muscle. Expression at the RNA level is directly proportional to the number of integrated K18 transgenes. These results indicate that the K18 gene is able to insulate itself both from the commonly observed cis-acting effects of the sites of integration and from the potential complications of duplicated copies of the gene arranged in head-to-tail fashion. To begin to identify the K18 gene sequences responsible for this property of transcriptional insulation, additional transgenic mouse lines containing deletions of either the 5' or 3' distal end of the K18 gene have been characterized. Deletion of 1.5 kb of the distal 5' flanking sequence has no effect upon either the tissue specificity or the copy number-dependent behavior of the transgene. In contrast, deletion of the 3.5-kb 3' flanking sequence of the gene results in the loss of the copy number-dependent behavior of the gene in liver and intestine. However, expression in kidney, lung, and brain remains efficient and copy number dependent in these transgenic mice. Furthermore, herpes simplex virus thymidine kinase gene expression is copy number dependent in transgenic mice when the gene is located between the distal 5'- and 3'-flanking sequences of the K18 gene. Each adult transgenic male expressed the thymidine kinase gene in testes and brain and proportionally to the number of integrated transgenes. We conclude that the characteristic of copy number-dependent expression of the K18 gene is tissue specific because the sequence requirements for transcriptional insulation in adult liver and intestine are different from those for lung and kidney. In addition, the behavior of the transgenic thymidine kinase gene in testes and brain suggests that the property of transcriptional insulation of the K18 gene may be conferred by the distal flanking sequences of the K18 gene and, additionally, may function for other genes.

Transcriptional insulation of the human keratin 18 gene in transgenic mice

Expression of the 10-kb human keratin 18 (K18) gene in transgenic mice results in efficient and appropriate tissue-specific expression in a variety of internal epithelial organs, including liver, lung, intestine, kidney, and the ependymal epithelium of brain, but not in spleen, heart, or skeletal muscle. Expression at the RNA level is directly proportional to the number of integrated K18 transgenes. These results indicate that the K18 gene is able to insulate itself both from the commonly observed cis-acting effects of the sites of integration and from the potential complications of duplicated copies of the gene arranged in head-to-tail fashion. To begin to identify the K18 gene sequences responsible for this property of transcriptional insulation, additional transgenic mouse lines containing deletions of either the 5' or 3' distal end of the K18 gene have been characterized. Deletion of 1.5 kb of the distal 5' flanking sequence has no effect upon either the tissue specificity or the copy number-dependent behavior of the transgene. In contrast, deletion of the 3.5-kb 3' flanking sequence of the gene results in the loss of the copy number-dependent behavior of the gene in liver and intestine. However, expression in kidney, lung, and brain remains efficient and copy number dependent in these transgenic mice. Furthermore, herpes simplex virus thymidine kinase gene expression is copy number dependent in transgenic mice when the gene is located between the distal 5'- and 3'-flanking sequences of the K18 gene. Each adult transgenic male expressed the thymidine kinase gene in testes and brain and proportionally to the number of integrated transgenes. We conclude that the characteristic of copy number-dependent expression of the K18 gene is tissue specific because the sequence requirements for transcriptional insulation in adult liver and intestine are different from those for lung and kidney. In addition, the behavior of the transgenic thymidine kinase gene in testes and brain suggests that the property of transcriptional insulation of the K18 gene may be conferred by the distal flanking sequences of the K18 gene and, additionally, may function for other genes.

cis regulation of the keratin 18 gene in transgenic mice

The gene coding for human keratin 18 (K18), a type I intermediate filament protein found in a variety of simple epithelia, is regulated correctly in transgenic mice but is promiscuously expressed after direct transfection into cell culture lines. We have begun an investigation of the mechanisms responsible for the correct regulation of K18 with a comparison of the chromatin state of K18 in permissive and nonpermissive transgenic mouse tissues to identify seven expression-specific, DNase-hypersensitive sites that correlate with known or potential regulatory regions of the gene. Four of these sites are associated with the proximal promoter region and the first intron that has been implicated previously in the transcriptional control of K18. Two hypersensitive sites are associated with a conserved Alu repetitive sequence located immediately upstream of the proximal promoter elements. Transcription of this Alu element in a direction opposite that of K18 was correlated with K18 expression in transgenic tissues. The final hypersensitive site was mapped to exon 6. The potential importance of this region for the expression of K18 was supported by the results of transient expression of the gene and various deleted constructions. In addition, exon 6 and the intron 1 regulatory region were distinguished from the remainder of K18 by differential DNA methylation in expressing and nonexpressing tissues. The CpG-rich proximal promoter and first exon regions remain unmethylated in both permissive and nonpermissive tissues. These results suggest that DNA methylation is not the primary mechanism of control of the gene. An Alu RNA polymerase III transcription unit and exon 6 are implicated in regulation of K18.

Identification of differentiation-dependent DNase I-hypersensitive sites in the mouse EndoA gene

DNase I hypersensitive (DH) sites in a 12-kb genomic fragment carrying the mouse EndoA gene were examined to obtain information on the changes in chromatin structure associated with activation of this gene encoding extra-endodermal cytoskeletal protein A (EndoA) during early mouse embryogenesis. Seven DH sites were found in this locus in parietal yolk-sac-like cells, PYS-2, which produce EndoA constitutively. In differentiated mouse teratocarcinoma F9 cells that produce EndoA inductively, this locus has three DH sites. In both cell lines, these sites were mapped to the upstream region of the promoter, the promoter and the 3' enhancer region. The DNA of PYS-2 cells has one more DH site within the first exon and three additional DH sites within the first intron. These DH sites are not present in DNA from BALB/c 3T3 cells and undifferentiated F9 cells that do not produce EndoA. Thus, the formation of these differentiation-dependent DH sites is required for the differentiation-specific expression of the mouse EndoA. In addition, another strong DH site, which may be associated with the B2 element expression, was detected in the third intron of the gene in undifferentiated F9 cells.

cis regulation of the keratin 18 gene in transgenic mice

The gene coding for human keratin 18 (K18), a type I intermediate filament protein found in a variety of simple epithelia, is regulated correctly in transgenic mice but is promiscuously expressed after direct transfection into cell culture lines. We have begun an investigation of the mechanisms responsible for the correct regulation of K18 with a comparison of the chromatin state of K18 in permissive and nonpermissive transgenic mouse tissues to identify seven expression-specific, DNase-hypersensitive sites that correlate with known or potential regulatory regions of the gene. Four of these sites are associated with the proximal promoter region and the first intron that has been implicated previously in the transcriptional control of K18. Two hypersensitive sites are associated with a conserved Alu repetitive sequence located immediately upstream of the proximal promoter elements. Transcription of this Alu element in a direction opposite that of K18 was correlated with K18 expression in transgenic tissues. The final hypersensitive site was mapped to exon 6. The potential importance of this region for the expression of K18 was supported by the results of transient expression of the gene and various deleted constructions. In addition, exon 6 and the intron 1 regulatory region were distinguished from the remainder of K18 by differential DNA methylation in expressing and nonexpressing tissues. The CpG-rich proximal promoter and first exon regions remain unmethylated in both permissive and nonpermissive tissues. These results suggest that DNA methylation is not the primary mechanism of control of the gene. An Alu RNA polymerase III transcription unit and exon 6 are implicated in regulation of K18.

A position- and orientation-dependent element in the first intron is required for expression of the mouse hprt gene in embryonic stem cells

The gene (hprt) coding for mouse HPRT (hypoxanthine phosphoribosyltransferase) is transcribed from a promoter lacking CAAT and TATAA boxes. It is expressed ubiquitously, albeit at different levels, in all tissues and cultured cells. During investigations to characterise hprt transcription control elements required in embryonic stem (ES) cells and to develop compact hprt minigenes for gene-targeting strategies, we discovered a requirement for intron-1 sequences for expression in ES cells. The essential intron-1 element, which is 420 bp long, is located 230 bp downstream from the transcription start point and is shown to increase transcription from the hprt promoter in a position- and orientation-dependent manner. We propose that this element is an integral downstream part of the hprt promoter.

The role of the basement membrane in differential expression of keratin proteins in epithelial cells

Extracellular matrix is considered to play an important role in determining the phenotype of cells with which it interacts. Here we have investigated the possibility that extracellular matrix is involved in specifying the pattern of keratin expression in epithelial cells. For these studies, we have developed an explant system in which epithelial cells from one type of stratified epithelial tissue, namely conjunctiva, are maintained on an extracellular matrix substrate derived from a different tissue, namely cornea. These ocular tissues are ideal for such analyses since they express distinct sets of keratins. For example, bovine conjunctival epithelium processed for immunofluorescence is not recognized by antibody preparations against keratin K3 or K12. In contrast, K3 and K12 antibodies generate intense staining in bovine corneal epithelium. At the immunochemical level, conjunctival cells in situ appear to possess no K12 and only trace amounts of K3, whereas corneal epithelial cells in situ possess both K3 and K12. When conjunctival cells are maintained on a corneal substrate with an intact basement membrane for 10 days in vitro they begin to express keratin K12 as determined by immunofluorescence. On the other hand, conjunctival cells that are maintained on a corneal substrate lacking a basement membrane fail to show staining with K12 antibodies. Conjunctival cells begin to show intense staining using K3 antibodies within about 10 days of being placed in culture regardless of their substrate. These results indicate that basement membrane can play a positive role in determining cell-specific expression of certain keratins such as K12. However, other keratins such as K3 may be "unmasked" and/or their expression may be upregulated simply by placing conjunctival epithelial cells in culture. We speculate that in conjunctiva K3 expression is influenced by certain negative exogenous factors. We discuss the possible means of regulation of keratin expression in our model system.

Retinoic acid-induced differentiation of a nontumorigenic embryonal carcinoma cell mutant created through retroviral insertion

A mutant embryonal carcinoma cell line, NR1-6, was created through retroviral insertion. We have previously reported that due to a single insertional event the mutant cell line is altered in regard to both its morphology and its tumorigenic capacity. We now report that this same cell line is also aberrant in its differentiative potential following exposure to the morphogen retinoic acid (RA). Unlike the parental NR1-0 cells, the NR1-6 cells apparently do not respond to RA by elaborating primitive endodermal derivatives in monolayer culture but rather appear morphologically to differentiate into mesodermal cells. This hypothesis is substantiated by the observation that RA treatment induces the transcription of both Endo A and B mRNA in parental but not mutant cells. No differences have been observed in the transcription of other RA sensitive markers such as c-myc, tissue plasminogen activator, collagen type IV, and laminin. In addition, the mutant cells are quantitatively much more sensitive to RA induction than are the parental cells, achieving full differentiation within 72 h of treatment with 10(-10) M RA. The parental cells, in contrast, will only differentiate at concentrations of 10(-5) or 10(-6) M RA, following 5 to 7 days of treatment. A spontaneous revertant cell line, which was isolated from an NR1-6 population and lacks the retroviral insert, is identical to the parental population in all parameters. Therefore, these data indicate that, in this case at least, a single genetic locus is involved in regulating both the qualitative and quantitative response of EC cells to RA-induced differentiation, as well as their morphology and tumorigenic potential.

JunB does not inhibit the induction of c-Jun during the retinoic acid induced differentiation of F9 cells

JunB, a member of the jun gene family of transcription factors, is distinguished from c-Jun by its differential activity on certain arrangements of promoter regulatory elements and the ability of JunB to inhibit the action of cJun in both transforming and trans-activating assays. We have tested the potential negative regulatory role of JunB during the retinoic acid induced differentiation of F9 murine embryonal carcinoma cells. Constitutive expression of high levels of JunB in F9 cells failed to inhibit the differentiation dependent induction of c-Jun or the coincident expression of differentiation markers keratin 8 and 18, tissue plasminogen activator, and laminin B1. Among these marker genes, keratin 18, has been shown to contain an AP-1 binding site, TGA(C/G)TCA, which is essential for high level, differentiation dependent expression and which is transactivated by Jun and Fos proteins. These results suggest that JunB does not play a major negative or positive regulatory role during the retinoic acid induced differentiation of F9 cells.

Intermediate filament molecular biology

Epidermal keratin intermediate filaments appear to have a structural function. The functions of other intermediate filaments are being elucidated using a combination of molecular genetic methods, including the expression of dominant negative mutant proteins and gene targeting. The differential expression of intermediate filament genes is regulated by both the accessibility of multiple regulatory elements and the activity or level of multiple positive and negative transcription factors.

Aberrant expression of the simple epithelial type II keratin 8 by mouse skin carcinomas but not papillomas

Keratins have been demonstrated to be suitable markers of changes taking place during epithelial neoplasia. Therefore, we analyzed 18 mouse skin tumors (nine papillomas and nine squamous cell carcinomas), induced either by two-stage carcinogenesis with 7,12-dimethylbenz[a]anthracene(DMBA)/12-O-tetradecanoylphorbol-13-acetat e or complete carcinogenesis with DMBA, by immunofluorescence with a monoclonal antibody to keratin (K) 8 (TROMA-1). Immunoperoxidase staining and immunoblotting were also used on selected tumor samples to further explore for the presence of K8. All of the papillomas tested were negative for the presence of K8, whereas the carcinomas were positive. The level of K8 expression in carcinomas showed a positive correlation with the degree of malignancy. Northern blot analysis using a K8 cDNA probe suggested that control of K8 expression in mouse skin tumors occurs at the transcriptional level. Double-label immunofluorescence staining using TROMA-1 and RK13 antibodies demonstrated that K8 did not generally colocalize with K13, a keratin normally found in internal stratified epithelial but aberrantly expressed in mouse epidermal tumors. Furthermore, tumors expressing high levels of K8 showed a reduced expression of K13. Histological examination of immunoperoxidase-stained tumors demonstrated that K8-positive cells were mainly found in anaplastic areas, whereas K13 foci were restricted to well-differentiated regions. Our results demonstrate that K8 expression is a marker of late stages of carcinoma progression in the mouse skin carcinogenesis model.

Hair-specific keratins: characterization and expression of a mouse type I keratin gene

A genomic clone for a member of the mouse type I hair keratin protein family has been isolated and analyzed in order to study the regulation of this keratin during the hair growth cycle. The coding sequence is divided into seven exons. The gene structure is typical of keratins in particular and intermediate filaments in general in that the intron-exon borders are not located at the domain borders of the protein. Comparison with a sheep wool keratin gene shows that the splice sites in the two hair keratin genes are found at identical locations relative to the amino acid sequence of the proteins. Similarly, comparison of the promoter areas of these genes shows several areas of nucleotide sequence conservation, including the area around the TATA box and an SV40 core enhancer sequence. In addition, a high degree of sequence identity exists in the fourth intron. In situ hybridization shows that transcripts of this gene are first found in the relatively undifferentiated proximal cortex area in the keratogenous zone of mouse vibrissae.

Transcription factor AP2 and its role in epidermal-specific gene expression

The epidermis is a stratified squamous epithelium whose major differentiation-specific products are keratins. To elucidate factors controlling keratinocyte-specific gene expression, we previously identified proximal and distal regulatory elements that act synergistically to drive keratinocyte-specific expression of the gene encoding human epidermal keratin K14. Control by the proximal element is mediated by a transcription factor, KER1, which is more abundant in nuclear extracts of keratinocytes than in extracts of other cell types, including fibroblasts, lymphocytes, and simple epithelial cells. In this report, we identify this factor as transcription factor AP2, shown to be transcribed in cells of epidermal and neural crest lineages. Furthermore, we demonstrate functional AP2 binding sites upstream from three additional epidermal genes, suggesting that AP2 may be generally involved in epidermal gene regulation. Finally, although AP2 is necessary, it is not sufficient for epidermal gene expression: a distal element contributes to tissue-specific expression of the human keratin K14 gene as judged by its ability to enhance expression of a heterologous promoter in keratinocytes but not in hepatoma cells. These results imply that a combination of factors is likely to contribute to epidermal-specific expression of the human keratin K14 gene.

DNA methylation and gene expression

A large body of evidence demonstrates that DNA methylation plays a role in gene regulation in animal cells. Not only is there a correlation between gene transcription and undermethylation, but also transfection experiments clearly show that the presence of methyl moieties inhibits gene expression in vivo. Furthermore, gene activation can be induced by treatment of cells with 5-azacytidine, a potent demethylating agent. Methylation appears to influence gene expression by affecting the interactions with DNA of both chromatin proteins and specific transcription factors. Although methylation patterns are very stable in somatic cells, the early embryo is characterized by large alterations in DNA modification. New methodologies are now becoming available for studying methylation at this stage and in the germ line. During development, tissue-specific genes undergo demethylation in their tissue of expression. In tissue culture cells this process is highly specific and appears to involve an active mechanism which takes place in the absence of DNA replication. The X chromosome undergoes inactivation during development; this is accompanied by de novo methylation, which appears necessary to stably maintain its silent state. As opposed to the programmed changes in DNA methylation which occur in vivo, immortalized tissue culture cells demonstrate alterations in DNA modification which take place over a long time scale and which appear to be the result of selective pressures present during the growth of these cells in culture.

Sequence of EndoA gene encoding mouse cytokeratin and its methylation state in the CpG-rich region

A genomic clone obtained from mouse liver DNA using a mouse cytokeratin EndoA cDNA probe revealed the complete sequence of the EndoA gene. The gene is divided into nine exons and the exon-intron pattern has been conserved compared to that of other type-II cytokeratin-encoding genes. The 5' upstream, 3' downstream and first and third introns contain potential regulatory sequences, including polyoma virus enhancer motifs (PEA1 and PEA3) and AP-1 elements. The 5' regions upstream of the EndoA, EndoB and Ck8 genes contain homologous sequences surrounding the TATA boxes. In addition, a CpG dinucleotide cluster region was located around the first exon. This CpG cluster region was found to be hypomethylated in endodermal PYS-2 cells, retinoic acid-treated F9 cells, and F9 embryonal carcinoma cells, but hypermethylated in BALB/C 3T3 fibroblast cells that do not express EndoA. These findings may provide a clue to understanding the molecular mechanisms of EndoA gene expression.

Retinoid-mediated transcriptional regulation of keratin genes in human epidermal and squamous cell carcinoma cells

Vitamin A and other retinoids profoundly inhibit morphological and biochemical features of epidermal differentiation in vivo and in vitro. To elucidate the molecular mechanisms underlying the differential expression of epidermal keratins and their regulation by retinoids, we examined retinoid-mediated changes in total protein expression, protein synthesis, mRNA expression, and transcription in cultured human keratinocytes and in squamous cell carcinoma (SCC-13) cells of epidermal origin. Our studies revealed that the epidermal keratins, K5, K6, K14, and K16, their mRNAs, and their transcripts were diminished relative to actin as a consequence of retinoic acid (RA) treatment. The effects were most pronounced in SCC-13 and were detected as early as 6 hr post-RA treatment, with enhancement over an additional 24-48 hr. Repression was also observed when 5' upstream sequences of K14 or K5 genes were used to drive expression of a chloramphenicol acetyltransferase reporter gene in SCC-13 keratinocytes. Both cell types were found to express mRNAs for the RA receptors alpha and gamma, which may be involved in the RA-mediated transcriptional changes in these cells. The rapid transcriptional changes in epidermal keratin genes were in striking contrast to the previously reported slow transcriptional changes in simple epithelial keratin genes.

The promoter of the endo A cytokeratin gene is activated by a 3' downstream enhancer

Mouse cytokeratin EndoA is an intermediate filament subunit of the type II cytokeratin class which initiates expression in trophectoderm cells of blastocyst during embryogenesis. To identify the regulatory elements of the endo A gene, we constructed a series of CAT expression vectors and transfected them into PYS-2 cells. We found an enhancer element locating 1 kb downstream from the endo A gene which acts on both the endo A and SV40 promoters. This enhancer consists of six direct repeated sequences with homology to the PEA3 motif in polyoma virus alpha enhancer core. In undifferentiated F9 embryonal carcinoma cells, expression of the construct containing the enhancer was not detected. These results indicate that one of the regulatory mechanisms of endo A gene expression is the 3' downstream enhancer.

Regulation of intermediate filament gene expression

Members of the intermediate filament protein family exhibit complex patterns of development-specific and tissue-specific expression. Studies exploring the mechanisms of gene regulation are underway and key regulatory factors are currently being described and isolated for certain genes encoding intermediate filament proteins. Selected systems from this diverse group of about 50 genes will be discussed.

A single human keratin 18 gene is expressed in diverse epithelial cells of transgenic mice

The expression of keratin 18 (K18) is restricted in humans primarily to a variety of single layered or simple epithelia. However, direct introduction of a cloned K18 gene into cultured, somatic cells by DNA transfection has been shown to result in the promiscuous expression of K18 even while the endogenous mouse form of K18 (Endo B) remains silent. To determine if the cloned K18 genomic DNA fragment contains sufficient information to be regulated appropriately when subjected to a normal developmental environment, and to determine if the cloned gene is expressed in diverse epithelia, the K18 gene, including 2.5 kb of 5' flanking sequence and 3.5 kb of 3' flanking sequence, has been introduced into the germ line of mice. Mice from all three resulting K18 transgenic lines express the gene in an appropriate tissue-specific pattern that includes hepatocytes, simple epithelia of the intestinal tract, ductal cells of several glands and epithelial cells of the thymus. No expression of K18 was found in muscle, heart, or in most of the brain even in mice carrying 18 copies of the K18 gene. In most tissues, the level of K18 RNA was directly proportional to copy number and was as efficiently expressed as the endogenous Endo B gene. The K18 protein was identified by both protein blotting methods and indirect immunofluorescence staining. No pathological consequences of overexpression of the K18 gene were observed. The cloned K18 gene appears to contain all cis-acting DNA sequences necessary for appropriate expression. In addition, diverse epithelial cell types are able to express this single human gene.

High levels of de novo methylation and altered chromatin structure at CpG islands in cell lines

CpG islands are normally methylation free in cells of the animal, even when the associated gene is transcriptionally silent. In mouse NIH 3T3 and L cells, however, over half of the islands are heavily methylated. Near identity of the methylated subset in the two cell lines suggested that methylation is confined to genes that are nonessential in culture. In agreement with this, islands at several tissue-specific genes, but not at housekeeping genes, have become methylated in many human and mouse cell lines. At the chromatin level, methylated islands are Mspl resistant compared with their nonmethylated counterparts. We suggest that mutation-like gene inactivation due to CpG island methylation is widespread in many cell lines and could explain the loss of cell type-specific functions in culture.

Activation of an intron enhancer within the keratin 18 gene by expression of c-fos and c-jun in undifferentiated F9 embryonal carcinoma cells

The mouse forms of human keratins 18 and 8 (K18 and K8) are the first members of the large intermediate filament gene family to be expressed during embryogenesis. To identify potential regulatory elements of the human K18 gene, various recombinant constructions were expressed in cultured cells. An enhancer element was found in the first intron that functions on both the K18 and thymidine kinase promoters in differentiated cells. In F9 embryonal carcinoma cells, the level of expression was low in the presence or absence of the first intron. Cotransfection of F9 cells with K18 constructs that include the first intron and increasing amounts of an expression vector of c-jun results in a modest increase in the reporter gene expression. Cotransfection of the same construct with increasing amount of the mouse c-fos gene results in activation of the reporter gene by as much as 15-fold, with a near linear response to the amount of c-fos gene added. Site-specific mutagenesis of a putative AP-1 site within the intron abolishes trans-activation by c-fos in F9 cells. Furthermore, induction of c-fos in a derivative of F9 cells results in increased expression of the endogenous mouse form of K18. Cotransfection with c-jun or c-fos expression vectors had little effect on the expression of the K18 reporter construct in a parietal endodermal cell line already expressing the endogenous mouse gene. These results identify an enhancer within the first intron of K18 that may interact directly with c-jun and c-fos via a conserved AP-1-binding site. K18 expression in undifferentiated F9 cells may be limited by the low levels of c-jun and c-fos.

Tissue-specific expression of murine keratin K13 in internal stratified squamous epithelia and its aberrant expression during two-stage mouse skin carcinogenesis is associated with the methylation state of a distinct CpG site in the remote 5'-flanking region of the gene

Under normal conditions, the expression of the murine type-I keratin K13 is restricted to the suprabasal, differentiating cell layers of internal stratified squamous epithelia that line the oral cavity and the upper digestive tract. It is, however, also expressed aberrantly but constitutively in only the differentiating parts of 7,12-dimethylbenz[alpha]anthracene/12.0-tetradecanoyl-phorbol-13-acetate (DMBA/TPA) induced malignant epidermal tumors of the back skin of mice, whereas its likewise suprabasal expression in papillomas is highly variable [27]. In an approach to unravel regulatory DNA sequence elements involved in the tissue-specific and aberrant K13 expression, the 5'-flanking region of the gene was analyzed with regard to potential methylation sites and DNase hypersensitive regions. We report on the identification of a CpG dinucleotide (designated M1; located about 2.3 kb upstream of the transcriptional start site), whose methylation state correlates with the differential gene activity in various epithelia and tumors. We show that in K13-nonexpressing integumental epidermis the M1 site is methylated in both suprabasal and basal cells. In contrast, internal stratified squamous epithelia (i.e. tongue, esophagus, forestomach) exhibit an unmethylated M1 site not only in their suprabasal. K13-expressing cells, but also in basal cells--in which, however, the keratin is not yet synthesized. The identical situation is encountered in DMBA TPA-induced moderately differentiating epidermal squamous cell carcinomas with compartmentalized K13 expression. In papillomas we observed a striking correlation between the extent of both suprabasally expressed K13 protein and demonstrable DNA copies carrying an unmethylated M1 site. Moreover we found that the sequence region around the M1 site was DNAseI hypersensitive in K13-expressing malignant tumors, but DNaseI insensitive in K13-nonexpressing epithelia and cells. DNAseI hypersensitivity in K13-expressing tissues was, however, independent of an active transcription of the gene in differentiating cells or transcriptional inertia in basal cells. These results strongly suggest that the sequence element around the demethylated M1 site is involved in a multi-level control mechanism mediating the selective expression of the K13 gene in internal squamous epithelia and in DMBA/TPA-induced epidermal tumors.

Organization and sequence of the human gene encoding cytokeratin 8

Among the various intermediate filament (IF) proteins, cytokeratin 8 (CK8) is especially remarkable as it is produced early in embryogenesis, is the only type-II CK occurring in many simple epithelial cells, and can also be synthesized in certain non-epithelial cells. Using a cDNA probe specific for human CK8 we have isolated an approx. 14-kb genomic clone (in phage lambda EMBL3) which contains the gene encoding human CK8. The gene comprising a total of 7766 nucleotides (nt) from the transcription start point, determined by primer extension analysis, to the polyadenylation site, determined from cDNA sequencing, and a 1030-nt 5' upstream region have been sequenced. The sequence of 485 amino acids (aa) deduced from the exon sequences (Mr 53,532) shows strong homology with the corresponding gene products of bovine, murine and amphibian (Xenopus laevis) origins. Surprisingly, the ck8 gene contains only seven introns instead of eight as found in all other genes of the same (type-II) CK subfamily; while all seven introns occur in identical positions as in the other type-II CK-encoding genes, intron V of these genes is missing in the ck8 gene. Intron I of ck8 is remarkably long (2534 nt) and contains a cluster of potential regulatory sequences, including three Sp1 sites, and an extended Alu-element. In Southern-blot analyses, we found only one intron-containing gene encoding CK8 in the human genome, and by heterologous transfection experiments we showed that this gene is correctly transcribed in non-human cells expressing the orthologous gene.(ABSTRACT TRUNCATED AT 250 WORDS)

The v-ras oncogene inhibits the expression of differentiation markers and facilitates expression of cytokeratins 8 and 18 in mouse keratinocytes

Cultured mouse keratinocytes can be initiated in vitro by the introduction of a v-rasHa gene by viral transduction. Previous studies indicated that v-rasHa-transduced keratinocytes have a high proliferation rate in medium with 0.05 mM Ca2+ and resist terminal differentiation in medium with greater than 0.1 mM Ca2+, a culture condition in which normal cells mature into squames. The current studies demonstrate that v-rasHa keratinocytes do not express transcripts or protein for epidermal early differentiation markers keratins 1 and 10 when cells are challenged with 0.12 mM Ca2+, which is a signal for expression of these genes in normal cells. Both transcript and protein for the late differentiation marker loricrin are also diminished in v-ras keratinocytes, but filaggrin, also a late differentiation-related gene product, is expressed in nearly normal amounts but at a different Ca2+ optimum. Modification of intracellular Ca2+ with ionomycin failed to restore the expression of any suprabasal keratinocyte markers. In contrast to the effects on normal products of keratinocyte differentiation, the introduction of the v-rasHa gene facilitated the expression of keratins 8 (K8) and 18 (K18). These keratins are characteristic of embryonic cells and cells of simple adult epithelia but not stratified squamous epithelia such as skin. Like normal differentiation markers, the expression of K8 and K18 was dependent both on the v-ras oncogene and the Ca2+ concentration of the culture medium, with greater than 0.1 mM Ca2+ being optimal. At the optimal Ca2+ level, the majority of v-ras keratinocytes expressed K8 and K18 after 96 h, and many cells had reduced amounts of the normal keratinocyte cytokeratin K14. These studies indicate that the v-ras gene causes substantial reprogramming of epidermal physiology, producing an unusual phenotype devoid of early suprabasal markers but at least partially permissive for late marker expression. Furthermore, the Ca2(+)-dependent expression of K8 and K18 suggests that a normal signalling pathway used in keratinocyte differentiation is diverted to an abnormal endpoint.