Three tightly linked genes encoding human type I keratins: conservation of sequence in the 5'-untranslated leader and 5'-upstream regions of coexpressed keratin genes

Tissue selective expression of conditionally-regulated ROCK by gene targeting to a defined locus

ROCK kinases regulate actin-myosin structures downstream of Rho GTPases. We generated mice expressing 4-hydroxytamoxifen (4HT)-regulated human ROCK II (ROCKII:mER) under the transcriptional control of the cytokeratin14 (K14) promoter. The K14-ROCKII:mER minigene was recombineered into a novel cloning vector containing the promoter and first exon of the human HPRT gene, and second and third exons of the mouse Hprt gene. Homologous recombination into the Hprt locus, which is deleted for the promoter and first two exons in HM1 embryonic stem cells, reconstitutes a functional Hprt gene, allowing for growth in HAT (hypoxanthine-aminopterin-thymidine) medium. K14-promoter-driven ROCKII:mER expression was restricted to a superficial cell layer in embryoid bodies, with increased ROCK substrate phosphorylation induced by 4HT. ROCKII:mER-expressing primary murine keratinocytes responded to 4HT with increased substrate phosphorylation and cytoskeleton rearrangements, indicating that ROCKII:mER activity is regulated by 4HT in the target tissue. K14-ROCKII:mER mice will be valuable for examining the role of ROCK in skin development and cancer.

A role for thyroid hormone in wound healing through keratin gene expression

The importance of thyroid hormone (TH) in wound healing is not well understood. To gain insight, we evaluated the impact of TH deficiency on wound-healing genes in cultured keratinocytes. By RT-PCR, keratin 6a (K6a) and 16 (K16) gene expression in TH replete cells was 3.8- (P < 0.005) and 1.9-fold (P < 0.05) greater, respectively, than expression in TH-deficient cells. By real-time PCR, TH replete cell expression of K6a, K16, and K17 was greater than in deficient cells: 18- (P < 0.001), 10- (P < 0.001), and 4-fold (P < 0.005), respectively. To examine TH requirement for optimal wound healing, we contrasted TH-deficient vs. ip T(3)-treated mice. Four days after wounding, ip T(3)-treated mice had twice the degree of wound closure as hypothyroid mice (P < 0.001). By RT-PCR, K6a and K17 gene expression from control mouse skin was greater than from hypothyroid mouse skin: 5- (P < 0.001) and 1.7-fold (P < 0.05), respectively. T(3) is necessary for the keratinocyte proliferation required for optimal wound healing. T(3) exerts influence by stimulating expression of the wound-healing keratin genes. Thus, for hypothyroid patients undergoing surgery that cannot be delayed until euthyroidism is achieved, our data support T(3) treatment for the perioperative period.

The molecular genetics of keratin disorders

Keratins are the type I and II intermediate filament proteins which form a cytoskeletal network within all epithelial cells. They are expressed in pairs in a tissue- and differentiation-specific fashion. Epidermolysis bullosa simplex (EBS) was the first human disorder to be associated with keratin mutations. The abnormal keratin filament aggregates observed in basal cell keratinocytes of some EBS patients are composed of keratins K5 and K14. Dominant mutations in the genes encoding these proteins were shown to disrupt the keratin filament cytoskeleton resulting in cells that are less resilient and blister with mild physical trauma. Identification of mutations in other keratin genes soon followed with attention focussed on disorders showing abnormal clumping of keratin filaments in specific cells. For example, in bullous congenital ichthyosiform erythroderma, clumping of filaments in the suprabasal cells led to the identification of mutations in the suprabasal keratins, K1 and K10. Mutations have now been identified in 18 keratins, all of which produce a fragile cell phenotype. These include ichthyosis bullosa of Siemens (K2e), epidermolytic palmoplantar keratoderma (K1, K9), pachyonychia congenita (K6a, K6b, K16, K17), white sponge nevus (K4, K13), Meesmann's corneal dystrophy (K3, K12), cryptogenic cirrhosis (K8, K18) and monilethrix (hHb6, hHb1).In general, these disorders are inherited as autosomal dominant traits and the mutations act in a dominant-negative manner. Therefore, treatment in the form of gene therapy is difficult, as the mutant gene needs to be inactivated. Ways of achieving this are actively being studied. Reliable mutation detection methods from genomic DNA are now available. This enables rapid screening of patients for keratin mutations. For some of the more severe phenotypes, prenatal diagnosis may be requested and this can now be performed from chorionic villus samples at an early stage of the pregnancy. This review article describes the discovery of, to date, mutations in 18 keratin genes associated with inherited human diseases.

cDNA cloning, expression, and assembly characteristics of mouse keratin 16

There has been speculation as to the existence of the mouse equivalent of human type I keratin 16 (K16). The function of this keratin is particularly intriguing because, in normal epidermis, it is usually confined to hair follicles and only becomes expressed in the suprabasal intrafollicular regions when the epidermis is traumatized. Previous studies suggested that K16 is highly expressed in the skin of mice carrying a truncated K10 gene. We therefore used the skin of heterozygous and homozygous mice to create a cDNA library, and we report here the successful cloning and sequencing of mouse K16. Recent in vitro studies suggested that filaments formed by human K16 are shorter than those formed by other type I keratins. One hypothesis put forward was that a proline residue in the 1B subdomain of the helical domain was responsible. The data presented here demonstrate that this proline is not conserved between mouse and human, casting doubt on the proposed function of this proline residue in filament assembly. In vitro assembly studies showed that mouse K16 produced long filaments in vitro. Also, in contrast to previous observations, transfection studies of PtK2 cells showed that mouse K16 (without the proline) and also human K16 (with the proline) can incorporate into the endogenous K8/K18 network without detrimental effect. In addition, K16 from both species can form filaments de novo when transfected with human K5 into immortalized human lens epithelial cells, which do not express keratins. These results suggest that reduced assembly capabilities due to unusual sequence characteristics in helix 1B are not the key to the unique function of K16. Rather, these data implicate the tail domain of K16 as the more likely protein domain that determines the unique functions.

Characterization of a 190-kilobase pair domain of human type I hair keratin genes

Polymerase chain reaction-based screening of an arrayed human P1 artificial chromosome (PAC) library using primer pairs specific for the human type I hair keratins hHa3-II or hHa6, led to the isolation of two PAC clones, which covered 190 kilobase pairs (kbp) of genomic DNA and contained nine human type I hair keratin genes, one transcribed hair keratin pseudogene, as well as one orphan exon. The hair keratin genes are 4-7 kbp in size, exhibit intergenic distances of 5-8 kbp, and display the same direction of transcription. With one exception, all hair keratin genes are organized into 7 exons and 6 positionally conserved introns. On the basis of sequence homologies, the genes can be grouped into three subclusters of tandemly arranged genes. One subcluster harbors the highly related genes hHa1, hHa3-I, hHa3-II, and hHa4. A second subcluster of highly related genes comprises the novel genes hHa7 and hHa8, as well as pseudogene PsihHaA, while the structurally less related genes hHa6, hHa5, and hHa2 are constituents of the third subcluster. As shown by reverse transcription-polymerase chain reaction, all hair keratin genes, including the pseudogene, are expressed in the human hair follicle. The transcribed pseudogene PsihHaA contains a premature stop codon in exon 4 and exhibits aberrant pre-mRNA splicing. Evolutionary tree construction reveals an early divergence of hair keratin genes from cytokeratin genes, followed by the segregation of the genes into the three subclusters. We suspect that the 190-kbp domain contains the entire complement of human type I hair keratin genes.

Analysis of sequences controlling tissue-specific and hyperproliferation-related keratin 6 gene expression in transgenic mice

Keratin 6 (K6) is an intermediate filament protein found in hair follicles and in several internal stratified epithelia. This keratin has been the focus of special attention because it is also strongly induced in epidermal interfollicular keratinocytes in hyperproliferative situations and in certain conditions leading to abnormal differentiation. To localize and identify the sequences controlling this complex expression pattern, and because of their potential use in transgenic mouse models and gene therapy strategies for epidermal hyperproliferative disorders, we have thoroughly analyzed a 9 kbp region of this gene previously shown to direct proper tissue-specific and inducible expression in transgenic mice. To reproduce the K6 constitutive expression pattern, cooperation is necessary between elements located in at least two different regions, one distal between -9 and -4 kbp and one proximal between -830 and -125 bp with respect to the CAP site. The ability to induce expression under hyperproliferative conditions resides in the 2.4 kbp fragment preceding the transcription start site. When this DNA fragment was analyzed in more detail, we found that all subfragments tested contained regulatory elements necessary for inducible expression. Thus, a complex organization of K6 regulatory elements emerges, as both the constitutive and the inducible expressions of this gene are under the control of multiple elements dispersed throughout relatively large 5' flanking DNA fragments. These findings will allow the expression of cloned genes in transgenic mouse skin in response to pathological or applied hyperproliferative stimuli, avoiding the effects of their constitutive expression in other epithelia.

Keratin 8 and 18 expression in mesenchymal progenitor cells of regenerating limbs is associated with cell proliferation and differentiation

Keratins are considered markers of epithelial differentiation. In lower vertebrates, however, immunoreactivity for keratin 8 and 18 has been reported in nonepithelial cells, particularly in mesenchymal progenitor cells of regenerating complex body structures. To confirm that such reactivity does indeed reflect keratin expression and to investigate their possible role in regeneration, we have isolated clones coding for the newt homologues of keratin 8 and 18 (NvK8 and NvK18, respectively) and studied their distribution and changes in their expression following experimental manipulations. Analysis of NvK8 and NvK18 transcripts confirms that K8 and K18 are expressed in the blastemal cells of regenerating newt limbs and that their expression is first observed 3-5 days after amputation, when the blastemal cells start to proliferate under the influence of the nerve, whose presence is essential for regeneration to proceed. In contrast, no induction of these keratins is observed following amputation of a larval limb at a stage when organogenesis is proceeding in a nerve-independent manner. To establish whether there is a causal relationship between keratin expression and cell proliferation in the adult limb blastema, we have investigated whether their expression is nerve-dependent and whether suppression of their expression in cultured blastemal cells affects cell division and differentiation. Analysis of keratins in denervated limbs demonstrates that the nerve is not necessary to induce their expression. However, treatment of cultured blastemal cells with K8 and K18 anti-sense oligonucleotides significantly decreases DNA synthesis and induces changes in cell morphology, suggesting that expression of these keratins during regeneration may be necessary for the maintenance of the undifferentiated and proliferative state of blastemal cells.

Chicken keratin-19: cloning of cDNA and analysis of expression in the chicken embryonic gut

From many recent studies, it has been argued that keratins (cytokeratins) play important roles in the morphogenesis and differentiation of organ development. To learn the role of keratin in digestive tract development, a cDNA of the chicken homolog of keratin-19 (GK-19) was cloned and its expression pattern was analyzed in the digestive tract of chicken embryos. The GK-19 full-length sequence was approximately 1.6 kb and showed more than 80% similarity to human and mouse keratin-19. The result of in situ hybridization with the proventriculus (glandular stomach) of different developmental stages showed that GK-19 expression disappeared specifically in the glandular epithelium from day 6 to day 9 of incubation. Furthermore, GK-19 was localized in the notochord, floor plate, anterior lobe of the pituitary gland and mesonephros. These results suggest the possibility that GK-19 may have multiple roles in organogenesis during embryogenesis.

In situ hybridization study of cytokeratin 4, 13, 16 and 19 mRNAs in human developing junctional epithelium

Cytokeratins (CKs) are now considered to be reliable markers for following the development and differentiation of epithelial tissue. We have investigated the pathway of differentiation in human developing junctional epithelium using monoclonal antibodies and two-dimensional gel electrophoresis of microdissected tissue to identify CK 19, CK 16, CK 14, CK 13, CK 6, CK 5, CK 4 in the junctional epithelium (JE) over partially erupted human teeth. The CK profile was similar to that of developing oral epithelia, suggesting that the junctional epithelium in teeth during eruption is of odontogenic origin. The present study used in situ hybridization to determine the distribution of the mRNAs of CKs 19, 16, 13 and 4 in human developing junctional epithelium and to examine the correlation between mRNAs and their encoded proteins. CK 19 mRNA was abundant in the basal cell layers of the primary junctional epithelium (PJE) but less concentrated in the suprabasal layers. CK16, 13 and 4 mRNAs were abundant in the basal cell layers of the PJE. The parabasal cell layers reacted intensely to the cRNA probe complementary to CK16 mRNA, as were the reactions in the suprabasal cell layers of the PJE for the CK 13 and 4 probes. Our results demonstrate that the PJE express the genes encoding for CKs 16 and 4 that have been revealed previously only by electrophoresis. They therefore confirm that the PJE is a well-differentiated stratified epithelium with a complex unique phenotype that produces CKs specific for basal cells (CK 19), CKs associated with hyperproliferation (CK 16), and finally those associated with stratification (CKs 4 and 13). Only synthesis of CK 19 protein and mRNA are strictly parallel. CKs 4 and 13 mRNAs are present in basal and suprasal cells, while their encoded proteins were not, except for CK 13 in suprabasal cell layers of PJE, where the amount of its mRNAs was coincident with the expression of the protein.

Differential expression of cytokeratin mRNA and protein in normal prostate, prostatic intraepithelial neoplasia, and invasive carcinoma

The expression of cytokeratin (CK) mRNA for CK5, -8, -14, -16, and -19 was investigated in normal prostate, prostatic intraepithelial neoplasia (PIN) lesions, and invasive carcinoma using in situ hybridization. Protein localization was carried out in adjacent sections using immunohistochemistry and correlated with mRNA expression. Snap-frozen human prostate samples including 22 examples of normal glands, 20 cases of PIN lesions, and 12 cases of invasive carcinoma were examined. CK5 and -14 mRNA and protein were prominently expressed only in the basal cells of normal glands and PIN lesions. CK14 mRNA was absent in the luminal cells of the most of the PIN lesions but was seen at a low level in some PIN lesions. CK14 protein was not detected in any PIN lesion, suggesting that, if the cell that makes up the PIN lesions is derived from a basal cell, CK14 translation is depressed although a low level of CK14 mRNA may persist. CK8 mRNA and protein were constitutively expressed in all epithelia of normal and abnormal prostate tissues. CK19 mRNA and protein were persistently expressed in both basal and luminal cells of the tubular portion of normal glands as well as PIN lesions, but were expressed heterogeneously in both basal and luminal cells of normal alveoli. CK16 mRNA was expressed in a similar pattern as CK19, but CK16 protein was not detected either in normal or in abnormal prostate tissues. In conclusion, the expression of CK19 in PIN lesions is similar to its tubular expression and would support an origin of PIN lesions from this structure rather than the alveolar portion of the glands. The similar cytokeratin expression between PIN lesions and invasive carcinoma further supports the concept that PIN is a precursor lesion of invasive carcinoma.

Intermediate filament expression in prostate cancer

The human prostate is composed of a series of tubular-alveolar glands and their ducts surrounded by a fibro-muscular stroma. The parenchymal glands secrete the seminal fluid and are anatomically arranged into the central, peripheral, and transitional zones. In this chapter the pattern of intermediate filament expression by the various epithelial components of the ducts, tubuloalveolar glands, and stroma are described. The changes which occur during malignant transformation from normal glands to prostatic intraepithelial neoplasia and subsequent invasive carcinoma are presented. The usefulness of cytokeratin markers in the diagnosis of prostate carcinoma is also discussed.

Activation of the silent human cytokeratin 17 pseudogene-promoter region by cryptic enhancer elements of the cytokeratin 17 gene

We have previously described the three loci CK-CA, CK-CB and CK-CC in the human genome that contain clustered type-I cytokeratin genes and reported the complete nucleic acid sequences of the functional cytokeratin 17 gene located in CK-CA and two closely related pseudogenes present in CK-CB and CK-CC [Troyanovsky, S.M., Leube, R.E. & Franke, W.W. (1992) Eur. J. Cell Biol. 59, 127-137]. By nucleic acid sequence analysis, we now show that extensive similarities between the functional gene and the pseudogenes exist in the 5'-upstream region. However, despite the high degree of nucleic acid identity (94%), only the 5'-upstream region of the functional gene was able to induce significant transcriptional activity in transfected cells of epithelial origin. Using chimeric upstream regions consisting of different fragments from the pseudogene and the functional gene, we made the surprising observation that cis elements in the proximal 5'-upstream region of the pseudogene promoter can cooperate with distal enhancer elements of the functional gene to induce strong chloramphenicol-O-acetyltransferase activity in transfected HeLa cells. A major site in the proximal upstream region was identified by deoxyribonuclease protection experiments to be necessary for this cooperative effect. The structure and properties of this element were further analysed by transfection of different chloramphenicol-O-acetyltransferase gene constructs, and by nucleic acid sequence comparison to corresponding regions of the related cytokeratins 14 and 16. It is concluded that the upstream regions identified in this study contribute to the strong expression of the human cytokeratin 17 gene in a coordinated fashion.

Lineage-specific and differentiation-dependent expression of K12 keratin in rabbit corneal/limbal epithelial cells: cDNA cloning and northern blot analysis

Corneal epithelial cells synthesize an acidic (55 kDa) K12 and a basic (64 kDa) K3 keratin as their major differentiation products during an advanced stage of differentiation. In this paper, we describe the cDNA cloning of rabbit K12 keratin. We used a 36 base pairs (bp) oligonucleotide corresponding to a consensus sequence of many known acidic keratins as a probe to screen a cDNA library of normal rabbit corneal epithelium. Several partial cDNA clones were isolated. Hybrid-selection showed that the 3'keratin chain-specific portion of the cDNA hybridizes with K12 mRNA. A rabbit antiserum raised against the C-terminus of the cDNA-deduced amino acid sequence recognizes, in immunoblotting, the K12 keratin. In situ hybridization showed that K12 mRNA is present in all cell layers of central corneal epithelium, but in only the suprabasal cells of limbal epithelium indicating a parallel expression pattern between K12 and K3. Cultured rabbit corneal epithelial cells initially synthesize K14/K5 keratins, but later when the cells become heavily stratified they synthesize large quantities of K12 and K3 mRNAs, as detected by Northern blotting. Cultured esophageal epithelial cells do not make K12 mRNA confirming the tissue-specificity of K12 expression. Although it has been suggested that conjunctival epithelial cells can trans-differentiate into a bona fide corneal epithelium, we showed here that cultured conjunctival cells do not synthesize significant amounts of K12/K3 mRNAs. These results strongly suggest that conjunctival epithelial cells, whose differentiation can be modulated significantly by the extracellular matrix, form a lineage intrinsically distinct from the corneal/limbal epithelial lineage.

Cornea-specific expression of K12 keratin during mouse development

The full-length cDNA of mouse K12 keratin was characterized by sequencing overlapping cDNA clones isolated from a mouse cornea cDNA library. Using Northern blot hybridization, the radio-labeled cDNA hybridized to a 1.9 kb mRNA from adult cornea, but not from other mouse tissues including snout, esophagus, tongue, and skin. During mouse development, corneas do not express K12 mRNA until 4 days postnatal when the epithelium begins to stratify as judged by Northern blot and in situ hybridization. In situ hybridization with 3H-labeled cDNA probe and immunohistochemical studies with antibodies against a synthetic oligo-peptide deduced from rabbit K12 cDNA demonstrate that this mouse K12 keratin is expressed in all cell layers of adult corneal epithelium, and the suprabasal layers, but not the basal layer of the limbal epithelium. Epidermal growth factor (EGF) has been shown to promote epithelium stratification of cultured chicken and human corneas in vitro. To examine whether EGF can promote K12 expression, EGF was administered to neonatal mice. The results indicate that EGF retards K12 expression by corneal epithelial cells, even though it promotes corneal epithelial stratification during mouse development. Taken together, our results demonstrate that the expression of K12 keratin is cornea-specific, differentiation-dependent, and developmentally regulated.

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.

Chromosomal mapping of human cytokeratin 13 gene (KRT13)

In the present study the human cytokeratin 13 gene (KRT13), encoding a polypeptide characteristic of internal stratified epithelia, has been mapped with the help of the polymerase chain reaction and somatic cell hybrids to chromosome 17. In situ hybridization of a KRT13 cDNA probe to metaphase chromosomes allowed the assignment of the KRT13 gene within the q12-q21.2 region of chromosome 17.

Interferon-γ regulates expression of a novel keratin classe I gene

Interferon (IFN)-gamma has been implicated in the pathogenesis of several autoimmune disorders and inflammatory skin diseases. To identify novel mediators involved in the IFN-gamma response we have used differential hybridization of a cDNA library prepared from IFN-gamma-treated HeLa cells to isolate a gene that is induced following treatment with IFN-gamma. We report here the molecular cloning and characterization of a cDNA detecting a 1.6-kb mRNA that accumulated in response to IFN-gamma but not in response to IFN-alpha or IFN-beta. The gene is regulated by IFN-gamma in human cell lines of epithelial origin. The mRNA encodes a predicted protein of 432 amino acids and the primary structure of the protein demonstrates that it is a novel member of developmentally regulated keratin class I genes.

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.

Aberrant in vitro expression of keratin K13 induced by Ca2+ and vitamin A acid in mouse epidermal cell lines

Normally the expression of the murine type I keratin K13 is restricted to differentiating cells of internal squamous epithelia which line the oral cavity and the upper digestive tract. Recently, however, we were able to show that K13 is aberrantly but constitutively expressed without its normal type II partner K4 also in differentiating parts of 7,12-dimethylbenz(a)anthracene (DMBA/TPA) 12-O-tetradecanoylphorbol-13-acetate-induced squamous cell carcinomas of mouse back skin, whereas its likewise suprabasal expression in papillomas is variable (Nischt et al., Mol. Carcinogenesis 1, 96-108, 1988). In an attempt to reproduce the aberrant expression of K13 in a mouse in vitro system, we have investigated eight established murine epidermal cell lines for their putative ability to express K13. The cell lines differed distinctly in their derivation and comprised cell lines originating from DMBA/TPA induced papillomas (line SP1) or DMBA-treated adult mouse epidermis (line 308) as well as cell lines derived from DMBA or DMBA/TPA-treated primary epidermal keratinocytes (lines PDV and MCA 3D) and cell lines which arose spontaneously by long-term culture of normal epidermal keratinocytes (lines HEL 30 degrees HEL 37 degrees, HELP I and HELP III). We show that, independent of their derivation, all cell lines possess the intrinsic property to aberrantly express K13. Invariably the K13 gene is not expressed when the lines are cultured under low Ca2+ conditions (0.05 mM) and thus prevented from differentiation. Its expression can, however, be induced either by increasing the extracellular Ca2+ concentration or by the addition of physiological concentrations of vitamin A acid to low Ca2+ medium. Whereas in the latter case, K13 expression occurs without concomitant induction of morphological differentiation of the cells, Ca2+ elevation in the culture medium induces squamous differentiation and K13 expression occurs only in differentiating cells, thus reflecting the situation observed in in vivo tumors. All cell lines exhibit a concentration optimum for the stimulatory agents; however, the degree of maximal K13 expression varies considerably among the individual cell lines and shows a striking correlation with the reported tumorigenicity of the lines after transplantation to animals. In contrast, a tentatively suggested correlation between the activation of the Ha-ras gene and the aberrant expression of K13 (Nischt et al., Mol. Carcinogenesis 1, 96-108, 1988) could not definitely be confirmed since we observed K13 expression also in three cell lines which did not carry a mutation in codon 61 of the Ha-ras gene.(ABSTRACT TRUNCATED AT 400 WORDS)

An ultrahigh-sulphur keratin gene of the human hair cuticle is located at 11q13 and cross-hybridizes with sequences at 11p15

A human hair cuticle ultrahigh-sulphur keratin Q (UHSK) gene (KRN1) has been mapped by Southern analysis of a somatic cell hybrid panel and by in situ hybridization. A probe containing the coding region of this gene mapped to 11pter- greater than 11q21 using the hybrid cell panel and on in situ hybridization mapped to two regions on chromosome 11: the distal part of 11p15, most likely 11p15.5, and the distal part of 11q13, most likely 11q13.5. A probe from the 3' noncoding region of KRN1 mapped to 11q13.5 indicating that this was the map location of the cloned gene. The sequence of 11p15.5 is termed KRN1-like (KRN1L). The results reveal that the cuticle UHSK gene family is clustered in the human genome.

Cell type-specific and efficient synthesis of human cytokeratin 19 in transgenic mice

In studies designed to identify cis-regulatory elements involved in the cell-type-specific expression of human cytokeratin (CK) genes we have dissected from the major type I CK gene locus on chromosome 17 a region containing the gene that encodes CK 19, with flanking segments of different lengths, and have examined the expression of related gene constructs in transgenic mice. Adult transgenic mice have been characterized by immunohistochemistry, gel-electrophoretic analyses of cytoskeletal proteins and genomic DNA (Southern blots). We have found that a construct harbouring the transcriptional unit plus approximately 0.7 kb downstream from the polyA-addition site and an immediately adjacent 5' upstream segment of approximately 3.6 kb, when combined with a further 5' upstream element of -6.4 - -8.6 kb, is sufficient to guarantee the synthesis of human CK 19 in the same cells and to a similar extent as the murine genome expresses its endogenous CK 19 gene. The findings demonstrate that all cis-elements necessary for the specific and efficient expression of a single type I CK gene, in the context of epithelial differentiation, can be located in the vicinity of the gene itself and that more-distant elements are not required.

Structural features in the heptad substructure and longer range repeats of two-stranded alpha-fibrous proteins

Considerable sequence data have been collected from the intermediate filament proteins and other alpha-fibrous proteins including myosin, tropomyosin, paramyosin, desmoplakin and M-protein. The data show that there is a clear preference for some amino acids to occur in specific positions within the heptad substructure that characterizes the sequences which form the coiled-coil rod domain in this class of proteins. The results also indicate that although there are major similarities between the various proteins there are also key differences. In all cases, however, significant regularities in the linear disposition of the acidic and the basic residues in the coiled-coil segments can be related to modes of chain and molecular aggregation. In particular a clear trend has been observed which relates the mode of molecular aggregation to the number of interchain ionic interactions per heptad pair.

Three parallel linkage groups of human acidic keratin genes

Two regions of human genomic DNA, each containing several keratin genes, were isolated and partially sequenced. The keratin genes are inactive, having suffered deleterious mutations. Both regions contain at least four keratin genes arranged in a head-to-tail orientation including a pseudogene for keratin K#16. Within each segment there are two keratin genes in close linkage with only 1.5 kb of DNA between them. Sequence comparison of the two regions showed 98.9% identity in both the coding and the intronic segments of the pseudogenes. The pseudogenes show 94% identity to their functional counterparts. Southern hybridization analysis showed that the segments are paralogous, not allelic. The regions are products of two independent, recent duplication events. The first occurred approximately 24 million years ago, after the separation of primates from the rhesus/baboon line. The second is specific for the human lineage, having occurred approximately 3.8 million years ago. Analysis of the genomic DNAs of primates showed the presence of only one of the regions in the DNAs of gibbon and gorilla, while rhesus monkey and baboon were missing both copies. We conclude that the human keratin genes are still actively evolving, with new duplications having occurred as recently as after the separation of human and gorilla ancestors.

New approaches and concepts in the study of differentiation of oral epithelia

Epithelial structural proteins, the keratins and keratin-associated proteins, are useful as markers of differentiation because their expression is both region-specific and differentiation-specific. In general, basal cells in all stratified oral epithelia express similar keratins, while the suprabasal cells express a specific set of markers indicating commitment to a distinct program of differentiation. Critical factors in the regulation of epithelial protein expression are now under investigation. The promoter regions of keratin genes are being characterized to determine what sequences within the genes are responsible for differential expression. One important extracellular factor that influences epithelial protein expression is retinol (vitamin A), which exerts its effects via a group of nuclear receptor proteins that may also be expressed in a region-specific manner. These molecular biological approaches enhance our understanding of the mechanisms regulating differentiation of oral epithelia and its regional complexity.

Unusual patterns of keratin expression in the overlying epidermis of patients with dermatofibromas: biochemical alterations in the epidermis as a consequence of dermal tumors

Dermatofibromas are frequently associated with acanthosis of the overlying epidermis. Using monospecific antisera and cRNA probes, we have examined the pattern of expression of keratin and keratin mRNA in the affected epidermis of patients with these dermal tumors. Our studies reveal several abnormalities in keratin expression within the thickened areas of overlying epidermis. In two of 15 patients, we detected K6 and K16, keratins which are frequently associated with epidermal diseases of hyperproliferation but are not present in normal epidermis. In both cases, K6 and K16 were found in suprabasal layers, similar to that seen for psoriasis and squamous cell carcinomas. Expression of K6 and K16 in skin samples from patients with dermatofibromas seemed to be dependent upon how near was the tumor to the overlying epidermis, and possibly upon the degree of cellularity within the tumor mass. A second aberration in keratin expression, and one which did not appear to be linked to K6/K16 expression, was the altered expression of the basal epidermal keratin K14. Expression of this keratin and its mRNA was variable, often extending into multiple suprabasal layers and including both basal-like and squamous-like cells. In contrast to the expression of K6/K16, aberrant expression of K14 was a relatively frequent event, occurring in greater than 70% of the dermatofibroma skin samples examined. These observations provide the first biochemical evidence in support of previous morphologic studies, indicating that alterations in epidermal differentiation can occur as a consequence of dermal skin tumors.

A family of type I keratin genes and the homeobox-2 gene complex are closely linked to the rex locus on mouse chromosome 11

Type I and type II keratins are major constituents of intermediate filaments that play a fundamental role in the cytoskeletal network. By using both somatic cell hybrids and conventional and interspecific linkage crosses, several genes encoding type I keratins, including the epidermal keratin K10, were shown to be closely linked to the homeobox-2 complex and the rex locus on mouse chromosome 11. The absence of crossovers between type I keratin-encoding genes and rex (N = 239), a locus affecting hair development, raises the possibility that mutations at rex and neighboring loci affecting skin and hair development involve type I keratin genes.

Molecular cloning and characterization of cDNA encoding mouse cytokeratin no. 19

We have isolated cDNA clones encoding the mouse cytokeratin No. 19 (Ck 19) from an intestinal cDNA library using synthetic oligodeoxyribonucleotides as probes. We obtained four independent clones, which correspond to about 1.4-kb of ck19 cDNA. Nucleotide sequence analysis revealed that these cDNAs encode a protein of 44,541 Da composed of 403 amino acids (aa). The deduced aa sequence defines an alpha-helical central domain, and suggests that the protein lacks a C-terminal non-alpha-helical tail segment, characteristic of the human and bovine 40-kDa keratins (Ck19). The overall aa identity between mouse Ck19 and human and bovine Ck19 is very high, 82.7% and 82.4%, respectively. The coil-forming central domain of mouse Ck19 has 45-65% similarity to other type-I Ck polypeptides, while it displays only 20-30% similarity to type-II Ck polypeptides. Northern blot analysis showed that mouse ck19 mRNA is strongly expressed in adult intestine, stomach and uterus. Interestingly, it is expressed in a placental cell line and a retinoic acid-treated mouse teratocarcinoma cell line (F9), but not in a parietal yolk sac endoderm-like cell line (PYS-2). This pattern of expression is very similar to that for the mouse gene encoding extra-embryonic endodermal cytoskeletal protein C (EndoC), suggesting they may be the same.

Two type II keratin genes are localized on human chromosome 12

Human genomic DNA containing two type II keratin genes, one coding for keratin 1 (K1, a 68-kD basic protein) and another closely linked type II gene 10-15 kb upstream (K?, gene product unknown), was isolated on a single cosmid clone. EcoRI restriction fragments of the cosmid were subcloned into pGEM-3Z, and specific probes comprising the C-terminal coding and 3' noncoding regions of the two genes were constructed. The type II keratin genes were localized by in situ hybridization of the subcloned probes to normal human lymphocyte chromosomes. In a total of 70 chromosome spreads hybridized with the K? probe (gHK?-3', PstI, 800 bp), 36 of the 105 grains observed were on chromosome 12, and 32 of these were clustered on the long arm near the centromere (12q11-13). In 100 labeled metaphases hybridized with the K1 probe (gHK1-3', BamHI-PstI, 2100 bp), 53 grains localized to chromosome 12 and 46 of these were found in the same region (q11-13). Therefore, both the gene for human keratin 1, a specific marker for terminal differentiation in mammalian epidermis, and another closely linked unknown type II keratin gene (K?, 10-15 kb upstream of K1) are on the long arm (q11-13) of human chromosome 12.

Complete structure of the gene for human keratin 18

The complete sequence of the human keratin 18 (K18) gene was determined. The K18 gene is 3791 bp in length and the K18 protein is coded for by seven exons. The exon structure of K18 has been conserved compared to that of other keratin genes, with the exception of a single 3' terminal exon that codes for the tail domain of the protein that is represented by two exons in epidermal keratins. The K18 gene contains an unusual AG/GC donor splice site of intron 3 instead of the consensus AG/GT sequence. This variation is not seen in any other intermediate filament genes. The promoter region of the gene contains a TATA box, six potential SP1 binding sites, and 10 copies of CACCC boxes but lacks any CCAAT boxes and is surprisingly different from the immediately 5' flanking region of the homologous mouse Endo B gene. However, both genes contain small CpG islands surrounding the 5' end of exon 1 and, in addition, conserve repetitive Alu potential transcription units approximately 300 nt upstream of the transcriptional start site.

Identification of an orthologous mammalian cytokeratin gene. High degree of intron sequence conservation during evolution of human cytokeratin 10

Among the human acidic (type I) cytokeratins, components 10 and 11 are especially interesting, as they are under various kinds of expression control. They are synthesized in the suprabasal cell layers of certain stratified epithelia, notably epidermis, in an endogenous differentiation program; they are expressed in certain epithelial tumours but not in others; they can appear de novo in certain pathological situations such as in squamous metaplasias; and their expression in vivo and in vitro is under positive influence of extracellular calcium concentrations and is reduced in the presence of vitamin A or other retinoids. To provide a basis for studies of the various regulatory elements, we have isolated the human gene encoding cytokeratin 10, using a cDNA probe derived from the corresponding bovine gene, and have sequenced the mRNA coding region as well as adjacent regions approximately 1500 bases 5' upstream and 1000 bases 3' downstream. The eight exons encode a polypeptide 59,535 Mr, i.e. somewhat larger than the corresponding bovine and murine proteins. The deduced amino acid sequences display a high degree of homology, which is not restricted to the exons and the 5' and 3' adjacent regions but, surprisingly, is also evident in the seven introns, some of which contain extended sequence elements with 70% identical nucleotides and more, i.e. similar to the homology in the adjacent exons. This exceptionally high level of conservation of intron sequences is discussed in relation to the recently accumulating evidence of the occurrence of intron sequences important in the regulation of the expression of members of other multigene families during development.

Complete sequence of a type-I microfibrillar wool keratin gene

We have isolated and sequenced the gene encoding a type-I microfibrillar wool keratin (47.6 kDa) together with about 500 bp of flanking DNA at each end. The primary transcript is 5180 bp in length, with seven exons. The positions of the introns are highly conserved in regions of the gene coding for the alpha-helical protein domains common to all intermediate filaments. The 5'-flanking region contains sequences similar to published consensus sequences from a variety of other keratins, including the high-sulfur wool matrix proteins. Further upstream, this region also contains artiodactyl-specific middle-repetitive DNA of the 'C-A3' family and intron II displays regions similar to a recently described sequence known as an Art2 element.

Chromosomal mapping of human keratin genes: evidence of non-linkage

We have determined the chromosomal location of the genes for the human keratin intermediate filament proteins K1 (type II; 67 kDa) and K10 (type I; 57 kDa) by the use of specific cDNA clones in conjunction with somatic cell hybrid analysis and in situ hybridization. The K1 keratin gene maps to chromosome region 12q11----q13; the K10 keratin gene maps to chromosome region 17q12----q21. Each gene has been mapped relative to other genes known to be localized on chromosomes 12 and 17, respectively. In somatic cell hybrid analysis, the K1 gene segregates concordantly with the Hox-3 homeo box gene cluster at chromosome region 12p12----q13. The K10 gene localizes to a region proximal to a breakpoint at 17q21 which is involved in a t(17;21)(q21;q22) translocation associated with an acute leukemia. K10 appears to be distal (telomeric) to the gene loci for G-CSF, erb-A, and Her-2, which map to chromosome region 17q12----q21. The NGFR gene and Hox-2 homeo box locus are localized distal to the 17q21 break point and thus distal to the K10 gene. These data demonstrate that keratin genes K1 and K10, which are coexpressed in terminally differentiated epidermis, are not linked in the human genome, implying the existence of trans-acting factors involved in the regulation of expression of these genes.

The sequence of the human epidermal 58-kD (#5) type II keratin reveals an absence of 5' upstream sequence conservation between coexpressed epidermal keratins

We report the isolation and sequencing of cDNA and genomic clones encoding the complete sequence of the human 58-kD epidermal keratin (#5). The sequence specifies a protein of 62,471 daltons that contains a central alpha-helical segment capable of forming a coiled-coil structure flanked by regions that are not alpha-helical. A comparison of the primary sequence with the known sequences of other intermediate filament proteins reveals many common motifs. The 58-kD keratin is highly similar to other type II keratins and less similar to type I keratins and other intermediate filament proteins. The 58-kD keratin is regulated by retinoids in several tissues and is one of four keratins abundantly expressed in epidermal keratinocytes, where it may be important in maintaining structural integrity of the integument. A comparison of the keratin 5 sequence with coexpressed keratin 14 reveals an absence of sequence conservation in regulatory regions and suggests that common sequence elements may not be necessary for coordinate expression of type I and type II keratin partners. Interestingly, keratin 5 contains only one region weakly resembling the SV40 enhancer-like sequence found in some other keratins indicating that this sequence motif may not be necessary for regulation or abundant expression of all epidermal keratins.

Localization of keratin mRNA in human tracheobronchial epithelium and bronchogenic carcinomas by in situ hybridization

An in situ hybridization technique was applied to detect expression of keratin mRNAs in xenotransplanted human tracheobronchial epithelium and lung carcinomas. Tissues from eight tracheas repopulated with cells from five different noncancerous donors and 15 squamous cell carcinomas were used. Using a K6 (56 kd) human keratin cDNA (KA-1) and a K14 (50 kd) cDNA (KB-2) as probes, radiolabeled by nick-translation with 3H-dATP/TTP, the specificity and significant differences in the levels of silver grains on various epithelial lesions in formalin-fixed, paraffin-embedded tissue sections were demonstrated. In situ hybridization with either KA-1 or KB-2 probe showed similar localization of silver grains in all histologic types in consecutive tissue sections. In xenotransplanted tracheobronchial epithelia, very few grains were seen over cells of simple, pseudostratified, or stratified epithelia two to three cell layers thick. Nonkeratinizing stratified hyperplastic epithelia of more than three cell layers showed uniform localization of numerous grains throughout the lesions. In contrast, epidermoid metaplasias exhibited a dense and localized pattern of grains on the basal and parabasal cell layers with a decrease in grain density toward the surface layers. Carcinoma cells from bronchogenic squamous cell carcinomas showed a higher density and more uniform localization of grains. Well-differentiated carcinoma cells contained more keratin mRNAs than moderately to poorly differentiated carcinoma cells. This evidence obtained with the KA-1 and KB-2 probes demonstrates the different localization patterns of keratin mRNAs in different epithelial lesions. In addition, the levels of mRNA expressed show a positive correlation with the degree of squamous differentiation. It was of particular interest that an ordered program of keratin mRNA expression proportional to the level of cellular differentiation was observed in epidermoid metaplasias. Both of these probes serve as keratinization markers of human tracheobronchial epithelial lesions.

Concerted gene duplications in the two keratin gene families

Evolutionary trees were derived from the keratin protein sequences using the Phylogeny Analysis Using Parsimony (PAUP) set of programs. Three major unexpected conclusions were derived from the analysis: The smallest keratin protein subunit, K#19 (Moll et al. 1982), is not the most primitive one, but has evolved to fulfill a highly specialized function, presumably to redress the unbalanced synthesis of keratin subunits. Second, the ancestors of keratins expressed in the early embryonic stages, K#8 and K#18, were the first to diverge from the ancestors of all the other keratins. The branches leading to these two keratins are relatively short, indicating a comparatively strong selection against changes in the sequences of these two proteins. Third, the two keratin families show extraordinary parallelism in their patterns of gene duplications. In both families the genes expressed in embryos diverged first, later bursts of gene duplications created the subfamilies expressed in various differentiated cells, and relatively recent gene duplications gave rise to the hair keratin genes and separated the basal cell-specific keratin from those expressed under hyperproliferative conditions. The parallelism of gene duplications in the two keratin gene families implies a mechanism in which duplications in one family influence duplication events in the other family.

Potential applications of anti-keratin antibodies in oral diagnosis

Recent progress in understanding the biology of keratins together with the development of monoclonal antibodies to individual keratin proteins provide the foundation for studying keratin expression in normal and pathological oral epithelia. Areas of oral pathology in which the examination of epithelial keratin profiles may yield information of potential diagnostic value are discussed. Examples of altered keratin expression in epithelial dysplasia, oral cancer and odontogenic cysts and tumours are presented. Immunocytochemical demonstration of individual keratins can clarify the composition of complex epithelia and may help to establish epithelial lineage or indicate progression changes in tumours. Some problems in the application and interpretation of keratin immunocytochemistry are also considered.

The transfection of epidermal keratin genes into fibroblasts and simple epithelial cells: evidence for inducing a type I keratin by a type II gene

Through gene transfection studies, we have discovered that the forced expression of a foreign type II epidermal keratin in fibroblasts can trigger the expression of an endogenous type I epidermal keratin. Both the transfected and the induced proteins participate in the formation of filamentous structures. Interestingly, this regulation appears to be unidirectional: the expression of a transfected type I keratin does not induce type II expression. Rather, nonfilamentous aggregates of type I protein accumulate in the cytoplasm. In contrast, simple epithelial cells transfected with either a type I or a type II epidermal keratin gene do not respond by inducing the expression of a host epidermal keratin. In this case, the foreign protein is incorporated into the endogenous keratin network. These results suggest the possibility that type I keratin expression may be dependent on the accumulation of unpolymerized type II keratin.

Comparison of mouse and human keratin 18: a component of intermediate filaments expressed prior to implantation

Keratin 18 is a type-I keratin that is found in a variety of simple epithelial tissues. In mice, the corresponding protein, called Endo B, is expressed at the 4- to 8-cell stage of mouse development and may be one of the first intermediate-filament proteins synthesized after fertilization. A cDNA clone for keratin 18, designated pK18, was isolated from a human placental cDNA library by hybridization with the mouse Endo-B probe. It was characterized by hybridization selection of RNA, translation, immunoprecipitation, Northern blotting, and sequence analysis. Synthetic T7 polymerase transcripts of the cDNA were indistinguishable in size from keratin-18 mRNA, suggesting that pK18 represents a full-length copy of the RNA. The cDNA insert is 1,428 nucleotides long and contains a single open reading frame of 1,342 nucleotides coding for 429 amino acids. The deduced amino acid sequence is 89.7% identical with that of Endo B. The only extensive difference between the two sequences is due to 9 additional amino acids being present in the last half of the N-terminal domain of keratin 18. The 38-nucleotide-long 3' noncoding region of the cDNA is 75% identical with the corresponding portion of Endo B. The 5' noncoding regions are 59% identical. The expression of keratin-18 mRNA was found to vary more than tenfold when HeLa cells and BeWo trophoblastic cells were compared.