Dynamics of keratin assembly: exogenous type I keratin rapidly associates with type II keratin in vivo

Keratin intermediate filaments (IF) are obligate heteropolymers containing equal amounts of type I and type II keratin. We have previously shown that microinjected biotinylated type I keratin is rapidly incorporated into endogenous bundles of keratin IF (tonofilaments) of PtK2 cells. In this study we show that the earliest steps in the assembly of keratin subunits into tonofilaments involve the extremely rapid formation of discrete aggregates of microinjected keratin. These are seen as fluorescent spots containing both type I and type II keratins within 1 min post-injection as determined by double label immunofluorescence. These observations suggest that endogenous type II keratin subunits can be rapidly mobilized from their endogenous state to form complexes with the injected type I protein. Furthermore, confocal microscopy and immunogold electron microscopy suggest that the type I-type II keratin spots from in close association with the endogenous keratin IF network. When the biotinylated protein is injected at concentrations of 0.3-0.5 mg/ml, the organization of the endogenous network of tonofilaments remains undisturbed during incorporation into tonofilaments. However, microinjection of 1.5-2.0 mg/ml of biotinylated type I results in significant alterations in the organization and assembly state of the endogenous keratin IF network soon after microinjection. The results of this study are consistent with the existence of a state of equilibrium between keratin subunits and polymerized keratin IF in epithelial cells, and provide further proof that IF are dynamic elements of the cytoskeleton of mammalian cells.     

Cloning of the human keratin 18 gene and its expression in nonepithelial mouse cells.

Human keratin 18 (K18) and the homologous mouse protein, Endo B, are intermediate filament subunits of the type I keratin class. Both are expressed in many simple epithelial cell types including trophoblasts, the first differentiated cell type to appear during mouse embryogenesis. The K18 gene was identified and cloned from among the 15 to 20 similar sequences identified within the human genome. The identity of the cloned gene was confirmed by comparing the sequence of the first two exons to the K18 cDNA sequence and transfecting the gene into various murine cell lines and verifying the encoded protein as K18 by immunoprecipitation and partial peptide mapping. The transfected K18 gene was expressed in mouse HR9 parietal endodermal cells and mouse fibroblasts even though the fibroblasts fail to express endogenous Endo B. S1 nuclease protection analysis indicated that mRNA synthesized from the transfected K18 gene is initiated at the same position as authentic K18 mRNA found in both BeWo trophoblastoma cells and HeLa cells. Pulse-chase experiments indicated that the human K18 protein is stable in murine parietal endodermal cells (HR9) which express EndoA, a complementary mouse type II keratin. Surprisingly, however, K18 was degraded when synthesized in cells which lack a type II keratin. This turnover of K18 may be an important mechanism by which epithelial cells maintain equal molar amounts of both type I and II keratins. In addition, the levels of the endogenous type I Endo B in parietal endodermal cells were compensatingly down regulated in the presence of the K18 protein, while the levels of the endogenous type II Endo A were not affected in any of the transfected cell lines.     

Sequence and expression of a human type II mesothelial keratin

Using mRNA from cultured human mesothelial cells, we constructed bacterial plasmids and lambda phage vectors that contained cDNA sequences specific for the keratins expressed in these cells. A cloned cDNA encoding keratin K7 (55 kD) was identified by positive hybrid selection. Southern Blot analysis indicated that this sequence is represented only once in the human genome, and Northern Blot analysis demonstrated that the gene encoding K7 is expressed in abundance in cultured bronchial and mesothelial cells, but only weakly in cultured epidermal cells and not at all in liver, colon, or exocervical tissue. The predicted amino acid sequence of this keratin has revealed a striking difference between this keratin and the type II keratins expressed in epidermal cells: whereas all of the epidermal type II keratins thus far sequenced have long nonhelical termini rich in glycine and serine, this mesothelial type II keratin has amino and carboxy terminal regions that are unusually short and lack the inexact repeats of glycine and serine residues.     

Mutations in the helix termination motif of mouse type I IRS keratin genes impair the assembly of keratin intermediate filament

Two classical mouse hair coat mutations, Rex (Re) and Rex wavy coat (Re(wc)), are linked to the type I inner root sheath (IRS) keratin genes of chromosome 11. An N-ethyl-N-nitrosourea-induced mutation, M100573, also maps close to the type I IRS keratin genes. In this study, we demonstrate that Re and M100573 mice bear mutations in the type I IRS gene Krt25; Re(wc) mice bear an additional mutation in the type I IRS gene Krt27. These three mutations are located in the helix termination motif of the 2B alpha-helical rod domain of a type I IRS keratin protein. Immunohistological analysis revealed abnormal foam-like immunoreactivity with an antibody raised to type II IRS keratin K71 in the IRS of Re/+ mice. These results suggest that the helix termination motif is essential for the proper assembly of types I and II IRS keratin protein complexes and the formation of keratin intermediate filaments.     

Sequence and expression of a type II keratin, K5, in human epidermal cells.

We report here the cDNA and amino acid sequences of a human 58-kilodalton type II keratin, K5, which is coexpressed with a 50-kilodalton type I keratin partner, K14, in stratified squamous epithelia. Using a probe specific for the 3'-noncoding portion of this K5 cDNA, we demonstrated the existence of a single human gene encoding this sequence. Using Northern (RNA) blot analysis and in situ hybridization with cRNA probes for both K5 and K14, we examined the expression of these mRNAs in the epidermis and in cultured epidermal cells. Our results indicate that the mRNAs for K5 and K14 are coordinately expressed and abundant in the basal layer of the epidermis. As cells undergo a commitment to terminally differentiate, the expression of both mRNAs seems to be downregulated.     

Differential localization of distinct keratin mRNA-species in mouse tongue epithelium by in situ hybridization with specific cDNA probes

The tongue of the adult mouse is covered by a multilayered squamous epithelium which is continuous on the ventral surface, however interrupted on the dorsal surface by many filiform and few fungiform papillae. The filiform papillae themselves are subdivided into an anterior and posterior unit exhibiting different forms of keratinization. Thus, the entire epithelium shows a pronounced morphological diversity of well recognizable tissue units. We have used a highly sensitive in situ hybridization technique to investigate the differential expression of keratin mRNAs in the tongue epithelium. The hybridization probes used were cDNA restriction fragments complementary to the most specific 3'-regions of any given keratin mRNA. We could show that independent of the morphologically different tongue regions, all basal cells uniformly express the mRNA of a type I 52-kD keratin, typical also for basal cells of the epidermis. Immediately above the homogenous basal layer a vertically oriented specialization of the keratin expression occurs within the morphological tissue units. Thus the dorsal interpapillary and ventral epithelium express the mRNAs of a type II 57-kD and a type I 47-kD keratin pair. In contrast, in the anterior unit of the filiform papillae, only the 47-kD mRNA is present, indicating that this keratin may be coexpressed in tongue epithelium with different type II partners. In suprabasal cells of both, the fungiform papillae and the posterior unit of the filiform papillae, a mRNA of a type I 59-kD keratin could be detected; however, its type II 67-kD epidermal counterpart seems not to be present in these cells. Most surprisingly, in distinct cells of both types of papillae, a type I 50-kD keratin mRNA could be localized which usually is associated with epidermal hyperproliferation. In conclusion, the in situ hybridization technique applied has been proved to be a powerful method for detailed studies of differentiation processes, especially in morphologically complex epithelia.     

The expression of mutant epidermal keratin cDNAs transfected in simple epithelial and squamous cell carcinoma lines

We have deleted cDNA sequences encoding portions of the carboxy-terminal end of a human type I epidermal keratin K14, and examined the molecular consequences of forcing the expression of these mutants in simple epithelial and squamous cell carcinoma lines. To follow the expression of our mutant products in transfected cells, we have tagged the 3' end of the K14 coding sequence with a sequence encoding an antigenic domain of the neuropeptide substance P. Using DNA transfection and immunohistochemistry (with an antibody against substance P), we have identified a collection of mutants that have a wide range of morphological effects on the endogenous keratin filament networks of transfected cells. Mutants that are missing most of the nonhelical carboxy-terminal domain of K14 incorporate into the endogenous keratin filaments without any visible perturbations on the network. In contrast, mutants that are missing as few as 10 of the 310 amino acids of the central alpha-helical domain of the polypeptide cause gross alterations in the keratin network. In some cases, the entire cytoskeletal network of keratins was disrupted, leaving no evidence of 8-nm filaments. These results reveal the existence of a dynamic exchange between newly synthesized subunits and preexisting keratin filaments.     

Cloning of a type I keratin from goldfish optic nerve: differential expression of keratins during regeneration

We report the cDNA sequence and predicted amino acid sequence of a novel type I keratin, designated as GK50, and show that keratin expression in the goldfish optic nerve is highly complex. The GK50 protein is one of at least three type I keratins expressed in goldfish optic nerve based on both antibody reactivity and blot-binding to the type II keratin ON3. After optic nerve crush in situ hybridization shows a localized increase in GK50 mRNA expression in the crush zone. This is in contrast to ON3 mRNA which shows a localized increase that is limited to the proximal and distal margins of the crush zone, suggesting a diversity of keratin expression in different cell types of the goldfish optic nerve.     

Making a connection: direct binding between keratin intermediate filaments and desmosomal proteins

In epidermal cells, keratin intermediate filaments connect with desmosomes to form extensive cadherin-mediated cytoskeletal architectures. Desmoplakin (DPI), a desmosomal component lacking a transmembrane domain, has been implicated in this interaction, although most studies have been conducted with cells that contain few or no desmosomes, and efforts to demonstrate direct interactions between desmoplakin and intermediate filaments have not been successful. In this report, we explore the biochemical nature of the connections between keratin filaments and desmosomes in epidermal keratinocytes. We show that the carboxy terminal "tail" of DPI associates directly with the amino terminal "head" of type II epidermal keratins, including K1, K2, K5, and K6. We have engineered and purified recombinant K5 head and DPI tail, and we demonstrate direct interaction in vitro by solution- binding assays and by ligand blot assays. This marked association is not seen with simple epithelial type II keratins, vimentin, or with type I keratins, providing a possible explanation for the greater stability of the epidermal keratin filament architecture over that of other cell types. We have identified an 18-amino acid residue stretch in the K5 head that is conserved only among type II epidermal keratins and that appears to play some role in DPI tail binding. This finding might have important implications for understanding a recent point mutation found within this binding site in a family with a blistering skin disorder.     

Sequence, evolution and tissue expression patterns of an epidermal type I keratin from the shark Scyliorhinus stellaris

From the shark Scyliorhinus stellaris we cloned and sequenced a cDNA encoding a novel type I keratin, termed SstK10. By MALDI-MS peptide mass fingerprinting of cytoskeletal proteins separated on polyacrylamide gels, we assigned SstK10 to a 46-kDa protein which is the major epidermal type I ("IE") keratin in this fish and is specifically expressed in stratified epithelia. In a phylogenetic tree based on type I keratin sequences and with lamprey keratins applied as outgroup, SstK10 branches off in a rather basal position. This tree strongly supports the concept that teleost keratins and tetrapod keratins resulted from two independent gene radiation processes. The only exception is human K18 because its orthologs have been found in all jawed vertebrates (Gnathostomata) studied; in the tree, they form a common, most early branch, with the shark version, SstK18, in the most basal position. Thus, the sequences of SstK10 and SstK18 also favor the classical view of vertebrate evolution that considers the cartilaginous fishes as the most ancient living Gnathostomata. To determine the overall expression patterns of epidermal ("E") and simple epithelial ("S") keratins in this shark, we furthermore tested a panel of monoclonal anti-keratin antibodies by immunofluorescence microscopy of frozen tissue sections, and in immunoblots of cytoskeletal preparations, demonstrating that immunodetection of specific keratins is a convenient method to characterize epithelial tissues in shark.     

Amphioxus type I keratin cDNA and the evolution of intermediate filament genes.

We report the cloning of an intermediate filament (IF) cDNA from the cephalochordate amphioxus that encodes a protein assignable to the type I keratin group. This is the first type I keratin reported from an invertebrate. Molecular phylogenetic analyses reveal that amphioxus also possesses a type II keratin, and that the genes encoding short-rod IF proteins underwent different patterns of duplication in vertebrates and their closest relatives, the cephalochordates. Extensive IF gene duplication and divergence may have facilitated the origin of new specialised cell types in vertebrates.     

Terrestrial vertebrates have two keratin gene clusters; striking differences in teleost fish

Keratins I and II form the largest subgroups of mammalian intermediate filament (IF) proteins and account as obligatory heteropolymers for the keratin filaments of epithelia. All human type I genes except for the K18 gene are clustered on chromosome 17q21, while all type II genes form a cluster on chromosome 12q13, that ends with the type I gene K18. Highly related keratin gene clusters are found in rat and mouse. Since fish seem to lack a keratin II cluster we screened the recently established draft genomes of a bird (chicken) and an amphibian (Xenopus). The results show that keratin I and II gene clusters are a feature of all terrestrial vertebrates. Because hair with its multiple hair keratins and inner root sheath keratins is a mammalian acquisition, the keratin gene clusters of chicken and Xenopus tropicalis have only about half the number of genes found in mammals. Within the type I clusters all genes have the same orientation. In type II clusters there is a rare gene of opposite orientation. Finally we show that the genes for keratins 8 and 18, which are the first expression pair in embryology, are not only adjacent in mammals, but also in Xenopus and three different fish. Thus neighboring K8 and K18 genes seem a feature shared by all vertebrates. In contrast to the two well defined keratin gene clusters of terrestrial vertebrates, three teleost fish show an excess of type I over type II genes, the lack of a keratin type II gene cluster and a striking dispersal of type I genes, that are probably the result of the teleost-specific whole genome duplication followed by a massive gene loss. This raises the question whether keratin gene clusters extend beyond the ancestral bony vertebrate to cartilage fish and lamprey. We also analyzed the complement of non-keratin IF genes of the chicken. Surprisingly, an additional nuclear lamin gene, previously overlooked by cDNA cloning, is documented on chromosome 10. The two splice variants closely resemble the lamin LIII a + b of amphibia and fish. This lamin gene is lost on the mammalian lineage.     

Novel Rana keratin genes and their expression during larval to adult epidermal conversion in bullfrog tadpoles

The conversion of the larval to adult epidermis during metamorphosis of tadpoles of bullfrog, Rana catesbeiana, was investigated utilizing newly cloned Rana keratin cDNAs as probes. Rana larval keratin (RLK) cDNA (rlk) was cloned using highly specific antisera against Xenopus larval keratin (XLK). Tail skin proteins of bullfrog tadpoles were separated by 2-dimensional gel electrophoresis and subjected to Western blot analysis with anti-XLK antisera. The Rana antigen detected by this method was sequenced and identified as a type II keratin. We cloned rlk from tadpole skin by PCR utilizing primers designed from these peptide sequences of RLK. RLK predicted by nucleotide sequences of rlk was a 549 amino acid -long type II keratin. Subtractive cloning between the body and the tail skin of bullfrog tadpole yielded a cDNA (rak) of Rana adult keratin (RAK). RAK was a 433 amino acid-long type I keratin. We also cloned a Rana keratin 8 (RK8) cDNA (rk8) from bullfrog tadpole epidermis. RK8 was 502 amino acid-long and homologous to cytokeratin 8. Northern blot analyses and in situ hybridization experiments showed that rlk was actively expressed through prometamorphosis in larva-specific epidermal cells called skein cells and became completely inactive at the climax stage of metamorphosis and in the adult skin. RAK mRNA was expressed in basal cells of the tadpole epidermis and germinative cells in the adult epidermis. The expression of rlk and rak was down- and up-regulated by thyroid hormone (TH), respectively. In contrast, there was no change in the expression of RK8 during spontaneous and TH-induced metamorphosis. RK8 mRNA was exclusively expressed in apical cells of the larval epidermis. These patterns of keratin gene expression indicated that the expression of keratin genes is differently regulated by TH depending on the type of larval epidermal cells. The present study demonstrated the usefulness of these genes for the study of molecular mechanism of postembryonic epidermal development and differentiation.     

The epidermal intermediate filament proteins of tunicates are distant keratins; a polymerisation-competent hetero coiled coil of the Styela D protein and Xenopus keratin 8

Two novel cytoplasmic intermediate filament (IF) proteins (C and D) from the tunicate (urochordate) Styela are characterised as putative keratin orthologs. The coexpression of C and D in all epidermal cells and the obligatory heteropolymeric IF assembly of the recombinant proteins argue for keratin orthologs, but the sequences do not directly reveal which protein behaves as a keratin I or II ortholog. This problem is solved by the finding that keratin 8, a type II keratin from man or Xenopus, forms chimeric IF when mixed with Styela D. Mutant proteins of Styela D and keratin 8 with a single cysteine in equivalent positions show that these chimeric IF are, like vertebrate keratin filaments, based on the hetero coiled coil. We propose that Styela D retains, in spite of its strong sequence drift, important molecular features of type I keratins. By inference Styela C reflects a type II ortholog. We discuss that type I to III IF proteins are expressed along the chordate branch of metazoa.     

The two-chain coiled-coil molecule of native epidermal keratin intermediate filaments is a type I-type II heterodimer.

The composition of the two-chain coiled-coil molecule of murine epidermal keratin intermediate filaments (KIF) containing keratins 1 (type II) and 10 (type I) has been explored using native-type KIF as well as KIF reassembled in vitro from protein dissolved in urea solutions or from mixtures of 3H-labeled and unlabeled purified chains. By use of cross-linking, high resolution polyacrylamide gel electrophoresis and blotting for 3H-labeled keratins or with an anti-mouse keratin 10 antibody, it was found that individual keratin chains form type I or type II homodimers and homotetramers in solution that do not assemble into KIF in vitro. When mixed in urea solutions of 5 M or greater, such homo-oligomers rapidly rearrange into mostly heterodimers and heterotetramers that support filament assembly. On the other hand, prekeratin, isolated from newborn mouse epidermis with 0.1 M sodium citrate buffer, pH 2.6, under conditions that do not dissociate the native coiled-coil molecule, consists exclusively of type I-II heterodimers and heterotetramers. It is necessary to dissolve prekeratin in 8-9.5 M urea for several hours in order to dissociate the native heterodimer molecule and incorporate tracer amounts of a single 3H-labeled keratin chain. These data establish that native KIF consist of heterodimer coiled-coil molecules. Furthermore, heterodimers are much more stable than homodimers and are the favored form of association in solution. However, some homodimers (10-30% of total) always form after dissolution in concentrated urea and can be assimilated into KIF during reassembly in vitro. The isolation of alpha-helix-enriched dimer particles from the 2B region of the rod domains upon limited proteolysis confirmed the presence of mostly heterodimer and some homodimer molecules in reassembled KIF. These properties of keratin chains in urea solutions hereby clarify a number of conflicting reports in the literature concerning the composition of the coiled-coil molecule. The presence of some homo-oligomeric species in reassembled KIF correlates with earlier observations of polymorphism as well as stoichiometry.