Amino acid sequence and gene organization of cytokeratin no. 19, an exceptional tail-less intermediate filament protein.

We have isolated a cDNA clone from a bovine bladder urothelium library which encodes the smallest intermediate filament (IF) protein known, i.e. the simple epithelial cytokeratin (equivalent to human cytokeratin 19) previously thought to have mol. wt 40,000. This clone was then used to isolate the corresponding gene from which we have determined the complete nucleotide sequence and deduced the amino acid sequence of the encoded protein. This cytokeratin of 399 amino acids (mol. wt 43,893) is identified as a typical acidic (type I) cytokeratin but differs from all other IF proteins in that it does not show the carboxyterminal, non-alpha-helical tail domain. Instead it contains a 13 amino acids extension of the alpha-helical rod. The gene encoding cytokeratin 19 is also exceptional. It contains only five introns which occur in positions corresponding to intron positions in other IF protein genes. However, an intron which in all other IF proteins demarcates the region corresponding to the transition from the alpha-helical rod into the non-alpha-helical tail is missing in the cytokeratin 19 gene. Using in vitro reconstitution of purified cytokeratin 19 we show that it reacts like other type I cytokeratins in that it does not form, in the absence of a type II cytokeratin partner, typical IF. Instead it forms 40-90 nm rods of 10-11 nm diameter which appear to represent lateral associations of a number of cytokeratin molecules. Our results demonstrate that the non-alpha-helical tail domain is not an indispensable feature of IF proteins. The gene structure of this protein provides a remarkable case of a correlation of a change in protein conformation with an exon boundary.     

Characterization of bovine keratin genes: similarities of exon patterns in genes coding for different keratins.

Four different genomic clones which contain the genes coding for epidermal keratins Ia (mol. wt. approximately 68 000), Ib (68 000), III (60 000) and VIb (54 500) have been selected using cDNA probes and identified by hybrid-selection translation. The genes vary considerably in length, primarily due to differences in intron sizes: keratin Ia, 9.3 kb (approximately 2.55 kb total exons); keratin Ib, 6.0 kb (2.25 kb exons); keratin III, 6.0 kb (2.2 kb exons); keratin VIb, 4.4 kb (1.85 kb exons). The genes for all three representatives of the basic (type II) cytokeratin subfamily, i.e., keratins Ia, Ib and III, contain eight introns of variable sizes (0.1-1.8 kb) and their exon patterns are very similar. The gene coding for keratin VIb, a representative of the acidic (type I) subfamily, contains seven introns, and the size pattern of its five innermost exons closely resembles that of the genes of the type II keratins. Most of the introns are located in regions coding for the alpha-helical cores of these proteins. Mapping of the intron positions by the S1 nuclease technique and sequencing of some exon-intron boundaries has revealed that some of the introns of all four keratin genes have similar positions to each other and to those of the hamster vimentin gene.(ABSTRACT TRUNCATED AT 250 WORDS)     

Enhancer elements directing cell-type-specific expression of cytokeratin genes and changes of the epithelial cytoskeleton by transfections of hybrid cytokeratin genes.

The cytokeratins, which form the intermediate filaments (IFs) characteristic of epithelial cells, are encoded by a large family of genes whose members are differentially expressed in patterns different in the various kinds of epithelia. To identify possible cis-regulatory DNA elements involved in the cell-type-specific expression of these genes, we examined, in transfection assays, 5' upstream sequence intercepts of a certain cytokeratin gene, i.e. that for bovine cytokeratin IV* (CKIV*), in combination with the coding portions of either the chloramphenicol acetyltransferase (CAT) gene or other cytokeratin genes. A 5' upstream region located between the cap-site and nucleotide -605 was found to enhance the specific expression of these reporter genes in bovine mammary gland-derived BMGE + H cells, which express the endogenous gene, but not in bovine kidney epithelium-derived MDBK cells which synthesize cytokeratins other than IV*. This epithelium-type-specific expression was also observed in heterologous combinations, e.g. in murine keratinocytes, but not in other murine cell lines such as 3T3 fibroblasts. When a fragment located between -180 and -605 was coupled to the HSV-TK promoter it stimulated the expression of the reporter gene in a cell-type-specific manner. The enhancer character of this 425 nucleotide long region is also demonstrated. Moreover, the CKIV* promoter/enhancer complex was able to direct the expression of epidermal cytokeratins characteristic for suprabasal differentiation, i.e. bovine cytokeratins Ia and VIb, in cells that normally do not express these genes. We show that the newly synthesized cytokeratins integrate into the pre-existing cytokeratin IF system of the transfected cells and that the forced expression of one of these cytokeratins does not induce the endogenous gene encoding its normal pair partner.     

Analysis of the cDNA and gene encoding a cytoplasmic intermediate filament (IF) protein from the cephalochordate Branchiostoma lanceolatum; implications for the evolution of the IF protein family.

We report the molecular cloning of a full-length cDNA encoding a non-neuronal cytoplasmic intermediate filament (IF) protein of the cephalochordate Branchiostoma lanceolatum. Sequence and structural characteristics of IF-1 reveal a close relation to vertebrate IF proteins: they all lack the extended coil 1b version and the lamin tail homology found in protostomic IF proteins. This implies that divergence of type I to IV IF genes from a common ancestor either coincided with the origin of chordates or occurred at an earlier stage in the evolution of deuterostomes. The structural organization of the cephalochordate gene shows a closer relation to vertebrate type III genes than to type I or II genes. The single gene (approximately 19 kb) is composed of 7 exons and 6 introns which are all located within the sequence encoding the rod domain. The positions and phases of the introns show perfect homology to vertebrate type III genes. In line with the absence of protein sequence similarity of the tail domain, the Branchiostoma gene does not possess the introns interrupting this region in type III genes of vertebrates.     

Analysis of cytokeratin domains by cloning and expression of intact and deleted polypeptides in Escherichia coli.

Using recombination of an appropriate expression vector system (pINDU) with a complete cDNA encoding a basic (type II) cytokeratin, i.e. cytokeratin 8 (1) of Xenopus laevis, we transformed Escherichia coli cells to synthesize considerable amounts of an insoluble eukaryotic cytoskeletal protein. The cytokeratin was deposited in large 'inclusion bodies' in the bacterial cytoplasm but did not form detectable filamentous structures. However, when the E. coli-expressed cytokeratin was purified and combined in vitro with an authentic cytokeratin of the complementary, i.e. acidic (type I) subfamily, it formed typical intermediate-sized filaments (IFs). Using Bal31 deletion from either the 5' or the 3' end of the cDNA, series of polypeptides progressively deleted from the amino or the carboxy terminus were produced in E. coli and identified by monoclonal antibodies. These assays allowed the mapping of epitopes. The deletion polypeptides of cytokeratin 8 were further examined to localize the region(s) involved in the heterotypic binding of alpha-helices of type I cytokeratins, using an in vitro nitrocellulose blot binding assay. We show that a region of 37 amino acids located in the central portion of coil 2 of the alpha-helical rod domain is sufficient for the specific recognition of a radiolabelled type I cytokeratin, i.e. cytokeratin 18 (D) from rat liver. In addition, deletion polypeptides containing only coil 1 of the alpha-helical rod also bind strongly the complementary cytokeratin. This indicates that the capability of heterotypic recognition and complex formation is not restricted to a single signal sequence but is located in distant and independent alpha-helical domains.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of two types of keratin polypeptides within the acidic cytokeratin subfamily I

Cytoskeletal filaments of the α-keratin type (cytokeratins) are a characteristic of epithelial cells. In diverse mammals (man, cow and rodents) these cytokeratins consist of a family of approximately 20 polypeptides, which may be divided into the more acidic (I) and the more basic (II) subfamilies. These two subfamilies show only limited amino acid sequence homology. In contrast, nucleic acid hybridization experiments and peptide maps have been interpreted to show that polypeptides of the same subfamily share extended sequence homology.We compare two polypeptides of the acidic cytokeratin subfamily, VIb (M_r 54,000) and VII (M_r 50,000), which are co-expressed in large amounts in bovine epidermal keratinocytes. These two epidermal keratins can be distinguished by specific antibodies and show different patterns of expression among several bovine tissues and cultured cells. In addition, they differ in the stability of their complexes with basic keratin polypeptides and in their tryptic peptide maps. The amino acid sequences deduced from the nucleotide sequences of complementary DNA clones containing the 3′ ends of the messenger RNAs for these keratins are compared with each other and with available amino acid sequences of human, murine and amphibian epidermal keratins. Bovine keratins VIb and VII share considerable sequence homology in the α-helical portion (68% residues identical) but lack significant homology in the extrahelical portion. Bovine keratin VIb shows, in its α-helical region, a pronounced sequence homology (88% identity) to the murine epidermal keratin of M_r 59,000. In addition, the non-helical carboxy-terminal regions of both proteins are glycinerich and contain a canonic sequence GGG^S_GYGG, which may be repeated several times. Moreover, their mRNAs present a highly conserved stretch of 236 nucleotides containing, in the murine sequence, the end of the coding and all of the non-coding region (81% identical nucleotides). Bovine keratin VII is considerably different from the murine M_r 59,000 keratin but is almost identical to the human cytokeratin number 14 of M_r 50,000, both in the α-helical and in the non-α-helical regions of the proteins, and the mRNAs of the human and the bovine keratins also display a high homology in their 3′ non-coding ends.The results show that in the same species keratins of the same subfamily can differ considerably, whereas equivalent keratin polypeptides of different species are readily identified by characteristic sequence homologies in the α-helical and the non-helical regions as well as in the 3′ non-coding portions of their mRNAs. Among the members of the acidic subfamily I of cytokeratin polypeptides that are co-expressed in bovine epidermis, at least two types can be distinguished by their carboxy-terminal sequences. One type is characterized by its abundance of glycine residues, a consensus GGG^S_GYGG heptapeptide sequence, which may be repeated several times, and an extended stretch of high RNA sequence homology in the 3′ non-coding part. The other type shows a predominance of serine and valine residues, a subterminal GGG^S_GYGG sequence (which has been maintained in Xenopus, cow and man) and also a high level of homology in the 3′ non-coding part of the mRNA. The data indicate that individual keratin type specificity overrides species diversity, both at the protein and the mRNA level. We discuss the evolutionary conservation and the tissue distribution of these two types of acidic keratin polypeptides as well as their possible biological functions.     

Low level expression of cytokeratins 8, 18 and 19 in vascular smooth muscle cells of human umbilical cord and in cultured cells derived therefrom, with an analysis of the chromosomal locus containing the cytokeratin 19 gene

Of the various intermediate filament (IF) proteins certain cytokeratins, usually a hallmark of epithelial differentiation, can also be detected in some non-epithelial cells in low amounts. We have studied a representative case of this atypical expression, the smooth muscle cells of the blood vessel walls of the human umbilical cord, at the protein and nucleic acid level, by light and electron microscopic immunolocalization, gel electrophoresis and immunoblotting of cytoskeletal proteins, and mRNA identification by Northern blotting. For the latter we have used sensitive probes for various cytokeratins, including new probes for cytokeratin 19. We also describe the chromosome 17 locus comprising the genes for cytokeratins 15 and 19, and we emphasize the occurrence of several unusual and evolutionarily stable sequence elements in the introns of the cytokeratin 19 gene. Most, perhaps all smooth muscle cells of these blood vessels, positively identified by the presence of desmin and smooth muscle type alpha-actin, are immunostained by antibodies specific for cytokeratins 8 and 18, and a subpopulation also contains cytokeratin 19. Immunoelectron microscopy indicates that these cytokeratins are arranged in IFs that are distributed differently from the majority of the IFs formed by desmin and vimentin. Gel electrophoresis of cytoskeletal proteins from microdissected vascular wall tissue shows that the amounts of cytokeratins 8 and 18 present in these tissues are very low, representing less than 1% of the total IF protein, and that cytokeratin 19 is present only in trace amounts. Correspondingly, the contents of mRNAs for cytokeratins 8, 18 and 19 in these tissues are much lower than those present in epithelial cells examined in parallel. We have also established cell cultures derived from umbilical cord vascular smooth muscles that have maintained the expression of cytokeratins 8, 18 and 19, together with vimentin and the smooth muscle type alpha-actin, but do not synthesize desmin. In these cell cultures the cytokeratins are present in much higher amounts than in the original tissue and form IFs that, surprisingly, show a similar distribution as the vimentin IFs and, upon treatment of the cells with colcemid, collapse into juxtanuclear aggregates, often even more effectively than the vimentin IFs do. We conclude that in a certain subtype of smooth muscle cells, the genes encoding cytokeratins of the "simple epithelial type", i.e., cytokeratins 8, 18 and 19, are expressed and that the low level expression of these genes is compatible with myogenic differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Differentially expressed bovine cytokeratin genes. Analysis of gene linkage and evolutionary conservation of 5''-upstream sequences.

Cytokeratins are a family of approximately 20 polypeptides which form the intermediate-sized filaments (IFs) characteristic of epithelial cells. They are synthesized co-ordinately as 'pairs' consisting of one representative from each of the two cytokeratin subfamilies, i.e. the acidic (type I) and the more basic (type II) polypeptides, in cell type-specific combinations. We have isolated and characterized the genes coding for four bovine cytokeratins of the basic (type II) subfamily, i.e. cytokeratins Ib, III, IV and 6*, by Southern blot hybridization, hybridization-selection-translation experiments, hetero-duplex mapping, and partial sequencing of the exons coding for the hypervariable carboxy-terminal 'tail' regions of the proteins and the 3'-non-translated ends of the mRNAs which are distinct for the individual cytokeratin polypeptides. Limited 'chromosomal walk' experiments demonstrated that the genes are organized into two tandems, i.e. 6*----Ib and III----IV, in which they are separated by approximately 11 kb. RNA analysis by Northern and dot blots show that both genes of the III----IV tandem are co-expressed in some bovine tissues (muzzle epidermis, hoof pad and tongue mucosa) and cultured cells (BMGE + H) but that in other tissues, cornea for example, only the gene encoding III is expressed. Unexpectedly, the genes linked in the tandem 6*----Ib are not co-expressed in any of the tissues examined. mRNA from gene 6* has been found in tongue mucosa but in none of the other cell lines and tissues examined, whereas mRNA for cytokeratin Ib is expressed in cornea and muzzle epidermis but not in, for example, tongue mucosa and in the epidermis of the heel pad.(ABSTRACT TRUNCATED AT 250 WORDS)     

Organization of a type I keratin gene. Evidence for evolution of intermediate filaments from a common ancestral gene

The genomic structure of the mouse 59-kDa keratin gene, a Type I intermediate filament (IF) gene is presented. A comparison of the organization of this gene with that of the human 67-kDa keratin, a Type II IF gene, and hamster vimentin, a Type III IF gene, suggests a common evolutionary origin for Type I, II, and III IF genes. Most introns in these three types of IF genes occur at similar positions within the region encoding sequences predicted to form coiled-coils, but do not delineate structural subdomains. Interestingly though, most of the introns interrupt at or near the beginning of the characteristic 7-residue (heptad) repeat of sequences which form the coiled-coil. These data suggest that the three types of IF genes arose from a common ancestor which may have been assembled from smaller units containing multiple heptad repeats. Subsequent duplication events may then have formed the three known alpha-helical types and each of their various members.     

Chromosomal assignments of human type I and type II cytokeratin genes to different chromosomes

The chromosomal location of representative members of the type I and type II subfamilies of the cytokeratin multigene family was determined using specific cDNA probes in Southern blot hybridization with DNA from somatic cell hybrids. Our results show that the gene encoding human type II cytokeratin 4 resides on chromosome 12 and that encoding type I cytokeratin 15 is located on chromosome 17. The results indicate that cytokeratins are not concentrated in only one cluster. The possibility of the existence of separate type I and type II cytokeratin gene clusters is discussed.     

Cytokeratin domains involved in heterotypic complex formation determined by in-vitro binding assays

Cytokeratins are constituent proteins of intermediate filaments (IFs) that form heterotypic tetrameric IF subunits containing two polypeptide chains of each of the two cytokeratin subfamilies, i.e. the acidic (type I) and the basic (type II). To locate the molecular domains involved in the formation of these heterotypic complexes, we have developed a binding assay in which total cellular or cytoskeletal polypeptides, or proteolytically prepared cytokeratin fragments, are separated by one-, or two-dimensional gel electrophoresis, blot-transferred on to nitrocellulose paper and probed with radio-iodinated purified cytokeratin polypeptides or fragments thereof, using buffers of various ionic strengths with or without 4 M-urea. Using these polypeptides in the binding assay, specific heterotypic binding was observed between complementary cytokeratin polypeptides of the two subfamilies (but not with other IF proteins) and between the corresponding alpha-helical rod domain fragments. Both rod coils 1 and 2 of the type II cytokeratin 8 bound to the rod (coils 1 and 2) fragment of type I cytokeratins, and this binding occurred at both low and high ionic strengths. The results obtained indicate that: (1) the binding between cytokeratin polypeptides of the complementary type is stronger and more selective than interactions of cytokeratins with other IF and non-IF proteins; (2) both the head and the tail portions of the proteins are not required for heterotypic complex formation; (3) the complementarity information located in the alpha-helical portions of the rod domain, and in short sequences immediately flanking them, is sufficient to discriminate between the two types of cytokeratins and to secure the formation of heterotypic cytokeratin complexes; (4) both coils 1 and 2 of the rod can contribute to this association; and (5) the formation of the heterotypic cytokeratin complex is not critically dependent upon ionic interactions. Our results are further compatible with the concept that the heterotypic binding takes place between cytokeratin homodimer coiled-coils.     

Amino acid sequence of the carboxy-terminal part of an acidic type I cytokeratin of molecular weight 51 000 from Xenopus laevis epidermis as predicted from the cDNA sequence

The DNA sequence of a clone from a cDNA library made from Xenopus laevis skin is described. This sequence represents the 3'-terminal end of an mRNA which codes for an epidermal cytokeratin polypeptide of mol. wt. 51 000 of the acidic (type I) subfamily as identified by hybridization-selection of mRNAs, followed by gel electrophoretic identification of the polypeptides synthesized by translation in vitro. The partial amino acid sequence of the amphibian cytokeratin shows strong similarity to type I cytoskeletal keratins from human (mol. wt. 50 000) and murine (mol. wt. 59 000) epidermis. In the non alpha-helical tail region the human and the non-mammalian (Xenopus) keratins are more similar to each other than to the murine protein, indicating that the former are equivalent cytokeratin polypeptides and belonging to a special subclass of type I keratin polypeptides devoid of glycine-rich regions in the carboxy-terminal portion. The evolutionary conservativity of the genes coding for cytokeratins is discussed.     

Cell density and cell shape-related regulation of vimentin and cytokeratin synthesis : Inhibition of vimentin synthesis and appearance of a new 45 kD cytokeratin in dense epithelial cell cultures

The pattern of the intermediate type filament protein synthesis was examined in cultured bovine mammary gland epithelial (BMGE) cells under conditions of varied cell shape and cell-cell contact. In dense monolayer and suspension cultures BMGE cells expressed a new cytokeratin of 45 kD identified as a member of the acidic subfamily of cytokeratins. This polypeptide has a phosphorylated component and is dissociated from the cytokeratins complex in the presence of 6.5 M urea. The mRNA of the new cytokeratin accumulated in dense cell cultures, as revealed by in vitro translation in a cell-free system. In BMGE-H cells that express also vimentin, the synthesis of vimentin decreased dramatically in dense cell cultures, while the synthesis of the 45 kD cytokeratin was maximal under these conditions. The results suggest that the expression of certain cytokeratins and that of vimentin can be coordinately regulated by factors in the cellular environment that effect cell shape and cell surface contacts.     

Evolutionary dynamics of introns and their open reading frames in the U7 region of the mitochondrial rnl gene in species of Ceratocystis

The mtDNA rnl-U7 region has been examined for the presence of introns in selected species of the genus Ceratocystis. Comparative sequence analysis identified group I and group II introns encoding single and double motif LAGLIDADG open reading frames (ORFs) at the following positions L1671, L1787, and L1923. In addition downstream of the rnl-U7 region group I introns were detected at positions L1971 and L2231, and a group II intron at L2059. A GIY-YIG type ORF was located within one mL1923 LAGLIDADG type ORF and a degenerated GIY-YIG ORF fused to a nad2 gene fragment was found in association with the mL1971 group I intron. The diversity of composite elements that appear to be sporadically distributed among closely related species of Ceratocystis illustrates the potential for homing endonucleases and their associated introns to invade new sites. Phylogenetic analysis showed that single motif LADGLIDADG ORFs related to the mL1923 ORFs have invaded the L1787 group II intron and the L1671 group I intron. Phylogenetic analysis of intron encoded single and double motif LAGLIDADG ORFs also showed that these ORFs transferred four times from group I into group II B1 type introns.     

Structure of an invertebrate gene encoding cytoplasmic intermediate filament (IF) proteins: implications for the origin and the diversification of IF proteins.

The structure of the single gene encoding the cytoplasmic intermediate filament (IF) proteins in non-neuronal cells of the gastropod Helix aspersa is described. Genomic and cDNA sequences show that the gene is composed of 10 introns and 11 exons, spanning greater than 60 kb of DNA. Alternative RNA processing accounts for two mRNA families which encode two IF proteins differing only in their C-terminal sequence. The intron/exon organization of the Helix rod domain is identical to that of the vertebrate type III IF genes in spite of low overall protein sequence homology and the presence of an additional 42 residues in coil 1b of the invertebrate sequence. Intron position homology extends to the entire coding sequence comprising both the rod and tail domains when the invertebrate IF gene is compared with the nuclear lamin LIII gene of Xenopus laevis presented in the accompanying report of Döring and Stick. In contrast the intron patterns of the tail domains of the invertebrate IF and the lamin genes differ from those of the vertebrate type III genes. The combined data are in line with an evolutionary descent of cytoplasmic IF proteins from a nuclear lamin-like progenitor and suggest a mechanism for this derivation. The unique position of intron 7 in the Helix IF gene indicates that the archetype IF gene arose by the elimination of the nuclear localization sequence due to the recruitment of a novel splice site. The presumptive structural organization of the archetype IF gene allows predictions with respect to the later diversification of metazoan IF genes. Whereas models proposing a direct derivation of neurofilament genes seem unlikely, the earlier speculation of an mRNA transposition mechanism is compatible with current results.     

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.     

Cytokeratin expression in simple epithelia

Cytokeratin A (no. 8) is a cytoskeletal protein (Mr, approximately 53,000 in bovine cells) which is typical of all simple epithelia, is widespread in all cultured epithelial cells, and together with its partner cytokeratin D, is the first cytokeratin expressed during embryogenesis (synonyms for this protein are Endo A and TROMA-1 antigen). We isolated a clone (pKB8(1] from a pUC8 cDNA library prepared from poly(A)+-RNA of bovine bladder urothelium which contains the 3' nontranslated portion and the sequence coding for the carboxyterminal tail and almost the whole of the alpha-helical rod (369 amino acids). Northern-blot analysis showed that the mRNA coding for this cytokeratin is specifically synthesized in various epithelial tissues and in epithelial cell culture lines. The amino acid sequence of this cytokeratin, when compared with the sequences of other intermediate filament (IF) proteins, exhibits a high and specific homology with other cytokeratins of the basic (type II) subfamily; this homology is, however, restricted to the rod portion. The tail region, which is rich in hydroxy-amino acids (approximately 35%), is unique among the type-II cytokeratins in that it does not exhibit subdivision in three domains, specifically lacking the glycine-rich middle domain. Sequence comparison with a partial sequence of the corresponding cytokeratin of the amphibian species, Xenopus laevis, indicated high evolutionary conservation. The high sequence homology of bovine cytokeratin A with published sequences of human tissue polypeptide antigen (TPA), a soluble serum component used as tumor marker in clinical oncology, supports the view that TPA is a proteolytically solubilized fragment containing the rod portion of human cytokeratin no. 8. Our analysis of clone pKB8(1) made possible the first comparison of a simple epithelial cytokeratin with epidermal keratins and other IF proteins. This showed that, in some important molecular features, cytokeratin A (no. 8) differs drastically from the epidermal members of the same cytokeratin subfamily, probably reflecting different cellular functions of the tail region in stratified and simple epithelia.