Differential expression of keratin genes during mouse development

Suprabasal layers of the newborn mouse epidermis contain two mRNAs of 2.0 and 2.4 kb which are translated into keratins of 59 and 67 kDa, respectively. To study their expression during development, cDNA sequences corresponding to the 2.0- and the 2.4-kb mRNAs were cloned, characterized by hybridization selection assay, and used as probes to detect keratin sequences in polyadenylated RNA from Day 11, 13, 15, and 17 embryos. In RNA from Day 11 of gestation, two RNAs of 2.8 and 1.8 kb were identified. They were found to have homologies with both epidermal RNAs, suggesting that they are coding for proteins of the keratin family. These two sequences were not detected in sample of later stages. RNAs comigrating with the two epidermal keratin RNAs were identified only in Day 15 and 17 embryos indicating that their expression was induced between Day 13 and 15. Finally, the localization of the 59-kDa keratin mRNA was examined by in situ hybridization. The spinous and granulous cell layers were found to be heavily covered with grains while other regions of the tissue sections were unlabeled. All these results support the hypothesis of a sequential expression of keratins during differentiation of epidermal cells and suggest that proteins related to the keratins expressed specifically in keratinizing cells are expressed earlier during development.     

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.     

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.     

Chicken chromosomal protein HMG-14 and HMG-17 cDNA clones: isolation, characterization and sequence comparison

A cDNA clone coding for the chicken high-mobility group 14 (HMG-14) mRNA has been isolated from a chicken-liver cDNA library by screening with two synthetic oligodeoxynucleotide pools whose sequences were derived from the partial amino acid sequence of the HMG-14 protein. A chicken HMG-17 cDNA clone was also isolated in a similar fashion. Comparison of the two chicken HMG cDNA clones to the corresponding human cDNA sequences shows that chicken and human HMG-14 mRNAs and polypeptides are considerably less similar than are the corresponding HMG-17 sequences. In fact, the chicken HMG-14 is almost as similar to the chicken HMG-17 in amino acid sequence as it is to mammalian HMG-14 polypeptides. HMG-14 and HMG-17 mRNAs seem to contain a conserved sequence element in their 3'-untranslated regions whose function is at present unknown. The chicken HMG-14 and HMG-17 genes, in contrast to their mammalian counterparts, appear to exist as single-copy sequences in the chicken genome, although there appear to exist one or more additional sequences which partially hybridize to HMG-14 cDNA. Chicken HMG-14 mRNA, about 950 nucleotides in length, was detected in chicken liver RNA but was below our detection limits in reticulocyte RNA.     

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.     

Ovine keratome: identification,localisation and genomic organisation of keratin and keratin‐associated proteins

Wool is composed primarily of proteins belonging to the keratin family. These include the keratins and keratin‐associated proteins (KAPs) that are responsible for the structural and mechanical properties of wool fibre. Although all human keratin and KAP genes have been annotated, many of their ovine counterparts remain unknown and even less is known about their genomic organisation. The aim of this study was to use a combinatory approach including comprehensive cDNA and de novo genomic sequencing to identify ovine keratin and KAP genes and their genomic organisation and to validate the keratins and KAPs involved in wool production using ovine expressed sequence tag (EST) libraries and proteomics. The number of genes and their genomic organisation are generally conserved between sheep, cattle and human, despite some unique features in the sheep. Validation by protein mass spectrometry identified multiple keratins (types I and II), epithelial keratins and KAPs. However, 15 EST‐derived genes, including one type II keratin and 14 KAPs, were identified in the sheep genome that were not present in the NCBI gene set, providing a significant increase in the number of keratin genes mapped on the sheep genome.     

Cell type-specific expression of bovine keratin genes as demonstrated by the use of complementary DNA clones

Cytokeratins are a family of polypeptides that form the intermediate-sized filament characteristic of epithelial cells. The cytoskeletons of different types of epithelial cells have been reported to possess specific combinations of the members of this protein family. Therefore, we have sought to examine the correspondence between such differential protein expression and the expression of cytokeratin genes at the nucleic acid level. A library of recombinant plasmids carrying cDNA sequences synthesized from bovine epidermal mRNAs was constructed. Clones of about 10(3) base-pairs coding for all the major epidermal keratins of molecular weights of 50,000, 54,000, 59,000, 60,000 and 68,000 were identified by means of hybridization-selection, followed by one and two-dimensional gel electrophoresis of products of translation in vitro. Under stringent conditions, each of these clones hybridizes specifically with its corresponding mRNA and does not show significant cross-hybridization with mRNAs coding for the other keratins, including those belonging to the same subfamily. Using these clones in RNA blot hybridization analysis, we have studied the expression of keratin genes in diverse bovine epithelial tissues (muzzle epidermis, cornea, esophagus, bladder urothelium, liver) and cultured cell lines from kidney (MDBK) and mammary gland (BMGE + H, BMGE -H). In each case we have found a correlation between the respective keratin polypeptides and the corresponding mRNAs. Whereas mRNA coding for keratins Ia and VIb have been found only in epidermis, genes coding for other epidermal keratins are expressed also in certain non-epidermal epithelia and in cells of the BMGE + H line. In contrast, epidermal keratin mRNA sequences have not been detected in liver or bladder tissue, nor in cultured kidney cells (MDBK) or mammary gland cells of the BMGE - H line, which all express a set of cytokeratin polypeptides entirely different from those of epidermis. In all cases, only one mRNA size species has been found, suggesting that in different cell types the same mRNA species is synthesized from the same keratin gene. We conclude that the mechanisms controlling the cell type-specific synthesis of the diverse keratin genes act at a pre-translational level.     

The cDNA sequence of a human epidermal keratin: divergence of sequence but conservation of structure among intermediate filament proteins

We have determined the DNA sequence of a cloned cDNA that is complementary to the mRNA for the 50 kilodalton (kd) human epidermal keratin. This provides the first amino acid sequence for a cytoskeletal keratin. Comparison of this sequence with those of other keratins reveals an evolutionary relationship between the cytoskeletal and the microfibrillar keratins, but shows no homology to matrix or feather keratins. The 50 kd keratin shares 28%-30% homology with partial sequences of other intermediate filament proteins, which suggests that keratins may be the most distantly related members of this class of fibrous proteins. Our computer analyses predict that the 50 kd keratin contains two long alpha-helical domains separated by a cluster of helix-inhibitory residues in the middle of the protein. These findings indicate that despite major sequence divergence among intermediate filament proteins, they retain sequences compatible with secondary structural features that appear to be common to all of them.     

Three cDNA sequences of mouse type I keratins. Cellular localization of the mRNAs in normal and hyperproliferative tissues

We have constructed cDNA libraries with poly(A)+ RNA from normal mouse footpad epidermis and from a squamous cell carcinoma of mouse back skin. Both libraries were screened for type I keratin clones. We present sequence data of three keratin cDNA clones which selected mRNAs coding for two 52-kDa proteins (clones pke 52 and pkSCC 52) as well as for a 50-kDa protein (clone pkSCC50). According to their carboxyl-terminal sequences, the two 52-kDa keratin proteins belong to a group of keratins with serine-rich subdomains adjacent to the alpha-helix, whereas the short carboxyl-terminus of the 50-kDa protein lacks a distinct substructure. Sequentially the two 52-kDa keratins are more closely related to each other than to any other mouse type I keratin. However, in situ hybridization with specific subclones reveals a distinctly different pattern of expression in mouse epithelia. Clone pkSCC 52 contains sequence information for a 52-kDa keratin present in basal cells of epidermis and other stratified epithelia, whereas the pke 52 cDNA encodes a keratin which is predominantly expressed in suprabasal cells of nonepidermal tissues. In terms of nucleotide sequence identities, it cannot precisely be decided which of the two mouse 52-kDa proteins is the equivalent of the human epidermal 50-kDa keratin protein (Hanukoglu, I., and Fuchs, E. (1982) Cell 31, 243-252). In the case of the bovine keratin VII, however (Jorcano, J.L., Rieger, M., Franz, J.K., Schiller, D.L., Moll, R., and Franke, W.W. (1984) J. Mol. Biol. 179, 257-281) the sequence identity values speak for an equivalence with the mouse ke 52 keratin. Obviously, in situ hybridization experiments would best be suited to unravel the precise interspecies relationship between the four highly similar keratins. The discriminatory efficacy of this technique is further emphasized by the demonstration that the mRNA for a 50-kDa keratin is present not only in hyperproliferative epithelia, but also in normal cells of hair follicles.     

Two delta-crystallin polypeptides are derived from a cloned delta 1-crystallin cDNA

Previous studies have shown that there are 2 similar delta-crystallin genes (delta 1 and delta 2) and at least 2 delta-crystallin polypeptides in the chicken eye lens. We show here that both delta-crystallin polypeptides can be synthesized from mRNA transcribed in vitro from a cloned delta 1-crystallin cDNA. Both polypeptides co-migrate in SDS-urea-polyacrylamide electrophoresis with their authentic counterparts isolated from 15-day-old embryonic chicken lenses, and both react with sheep anti-chicken delta-crystallin serum. Screening nearly 900 delta-crystallin cDNA clones from a 15-day-old embryonic lens library with an oligonucleotide probe specific for exon 2 of the delta 2-crystallin gene failed to detect any delta 2 cDNA clones, indicating that the delta 2 gene produces little or no mRNA in the lens at this stage of development. Our results suggest that both of the observed delta-crystallin polypeptides are derived from mRNA transcribed from the delta 1 gene, with heterogeneity arising at the translational or co-translational level.     

Integration of different keratins into the same filament system after microinjection of mRNA for epidermal keratins into kidney epithelial cells

We have isolated poly (A)+ RNA, highly enriched in keratin mRNA from bovine muzzle epidermis, and injected it into epithelial cells of a different type, i.e., cultured kidney epithelial cells of the same (MDBK) or taxonomically distant (PtK2) species. Both recipient cell lines contain keratin polypeptides that are different from those present in epidermal cells. Using keratin subtype-specific antibodies in immunofluorescence and immunoelectron microscopy, we show that foreign keratin mRNAs when injected into a different type of epithelial cell can recruit polyribosomes and are translated together with the keratin mRNAs of the host cell. Foreign epidermal keratins are excluded from vimentin filaments and other structures but readily coassemble with the endogenous keratins and appear to be integrated into the meshwork of the preexisting kidney-type keratin filaments. Our observations indicate that different sets of keratin polypeptides from the same or different species can coassemble in the living cell into a common filament system. Thus we have developed a procedure that allows experimental alteration of the intermediate filament cytoskeleton within living epithelial cells.     

Molecular cloning and characterization of the Endo B cytokeratin expressed in preimplantation mouse embryos

A cDNA clone of a keratin-related, intermediate filament protein, designated Endo B, was constructed from size-fractionated parietal endodermal mRNA and characterized. The 1466-nucleotide cDNA insert contains an open reading frame of 1272 nucleotides that would result in 5' and 3' noncoding sequences of 54 and 60 nucleotides, respectively. The predicted amino acid composition, molecular weight (47,400), and peptide pattern correlate well with data obtained on the isolated protein. The predicted amino acid sequence fits easily into the general domain structure suggested for all intermediate filament proteins with a unique amino-terminal head domain, a large conserved central domain of predominantly alpha-helical structure, and a relatively unique carboxyl-terminal or tail domain. Over the entire molecule, Endo B is 43% identical with human 52-kDa epidermal type I keratin. However, over two of the three regions contained in the central domain that are predicted to form coiled-coil structures, the Endo B is 54-68% identical with other type I keratin sequences. This homology, along with the presence of the completely conserved sequence DNARLAADDFR-KYE, which is found in all type I keratins, permits the unambiguous identification of Endo B as a type I keratin. Comparison of the Endo B sequence to other intermediate filament proteins reveals 22 residues which are identical in all intermediate filament proteins regardless of whether filament formation requires only one type of protein subunit (vimentin, desmin, glial fibrillar acidic protein, or a neurofilament protein) or two dissimilar types (type I and type II keratins). Endo B mRNA was detectable in RNA isolated from F9 cells treated with retinoic acid for 48 h. Approximately three to five genes homologous to Endo B were detected in the mouse genome.     

Effects of UV, 4-NQO and TPA on gene expression in cultured human epidermal keratinocytes.

In an approach to study effects of UV light on gene expression in human epidermal keratinocytes, a cDNA library was constructed from poly(A)RNA isolated after UV irradiation from cultured keratinocytes. The cDNA library was differentially screened with labelled cDNA probes synthesized on poly(A)RNA isolated from UV irradiated or nonirradiated keratinocytes. Forty clones were selected and subjected to further analysis, 31 of them are described in this report. Whereas total mRNA synthesis is reduced after UV irradiation or treatment with 4-NQO Northern blot analysis revealed that there is an at least relative increase in the level of mRNAs corresponding to the majority of the isolated cDNA clones. Among these 15 were identified as corresponding to mRNAs for 50K and 56K keratins and for 50K- and 46K-related keratin. In addition, clones were found corresponding to the proteinase inhibitor cystatin A and to the glyceraldehyde 3-phosphate dehydrogenase (GAPDH). Treatment of keratinocytes with the tumor promoter TPA had no effect on the mRNA level for most of the clones except those corresponding to keratins. Our results indicate that in keratinocytes UV irradiation leads to a relative increase in the level of some mRNAs.     

Structural features and sites of expression of a new murine 65 kD and 48 kD hair-related keratin pair, associated with a special type of parakeratotic epithelial differentiation

In the course of studies on local keratin phenotypes in the epidermis of the adult mouse, we have identified a new 65 kD and 48 kD keratin pair. In mouse skin, this keratin pair is only expressed in suprabasal cells of adult mouse tail scale epidermis which is characterized by the complete absence of a granular layer and the formation of a remarkably compact stratum corneum. A second site in which the 65 kD and 48 kD keratin pair is suprabasally expressed and whose morphology corresponds to that of tail scale epidermis is found in the posterior unit of the complex filiform papillae of mouse tongue. The causal relationship of the expression of the 65 kD and 48 kD keratins with this particular type of a non-pathological epithelial parakeratosis is emphasized by the suppression of the mRNA synthesis of the two keratins during retinoic acid mediated orthokeratotic conversion of tail scale epidermis. Apart from tail scale epidermis and the posterior unit of the filiform papillae, the 65 kD and 48 kD keratin pair is, however, also coexpressed with "hard" alpha keratins in suprabulbar cells of hair follicles and in suprabasal cells of the central core unit of the lingual filiform papillae. The non alpha-helical domains of the two new keratins are rich in cysteine and proline residues and lack the typical subdomains into which epithelial keratins of both types can be divided. This structural resemblance of the 65 kD and 48 kD keratins to "hard" alpha keratins is supported by comparative flexibility predictions for their non alpha-helical domains. Phylogenetic investigations then show that the 65 kD and 48 kD keratin pair has evolved together with hair keratins, but has diverged from these during evolution to constitute an independent branch of a pair of hair-related keratins. In view of this exceptional position of the 65 kD and 48 kD keratins within the keratin multigene family, their expression has apparently been adopted by rare anatomical sites in which an orthokeratinized stratum corneum would be too soft and a hard keratinized structure would be too rigid to meet the functional requirement of the respective epithelia.     

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.     

Preimplantation mouse embryos and liver express the same type I keratin gene product

The cytoskeletal B protein isolated from extraembryonic endodermal cells (Endo B) is a 50-kDa subunit of intermediate filaments that is expressed in trophoblast and extraembryonic endoderm of early mouse embryos. Endo B was compared to cytokeratin D of adult mouse liver by immunoprecipitation, two-dimensional gel electrophoresis, and peptide mapping. The two proteins were indistinguishable. A cDNA probe for Endo B mRNA identified mRNA species of similar size in liver and endoderm, and primer extension analysis indicates that the Endo B mRNAs from the two cell types have similar 5' ends. An internal fragment of the Endo B cDNA was found to cross-hybridize with a conservative domain of a human type I keratin cDNA under low stringency conditions, demonstrating that Endo B is related to type I keratins. However, under stringent conditions necessary for genomic Southern analysis, mouse and human genomic fragments homologous to the Endo B cDNA were distinct from those defined by hybridization with the type I keratin cDNA. These results indicate that Endo B is related to the type I keratin family and expands the number of type I keratin genes identified in both the mouse and human genomes. It is likely that extraembryonic endoderm, one of the first differentiated cell types of the mammalian embryo, and adult liver express the same Endo B gene.     

Identification, expression, and localization of β keratin gene products during development of avian scutate scales

Epidermal-dermal interactions influence morphogenesis and expression of the beta keratin gene family during development of scales in the embryonic chick. The underlying mechanisms by which these interactions control beta keratin expression are not understood. However, the present study of beta keratin gene expression during avian epidermal differentiation contributes new information with which to investigate the role of tissue interactions in this process. Using beta keratin-specific synthetic oligonucleotide probe, beta keratin mRNA was hybrid-selected from total poly A+ RNA of scutate scales. Seven beta keratin polypeptides were translated in vitro and could be identified by their positions in two-dimensional gels among the detergent-insoluble extracts of scutate scale epidermis. In vivo phosphorylation studies suggested that an additional three beta keratin polypeptides were present as phosphoproteins. The temporal appearance of beta keratin mRNA and the corresponding polypeptides was followed during scutate scale development. Polyclonal antiserum made against two of the beta keratin polypeptides was used for immunohistochemical and immunogold electron-microscopic analysis of beta keratin tissue distribution. Immunological reactivity was observed specifically along the outer scale surface in epidermal cells above the stratum germinativum. Immunogold beads were localized on 3-nm filament bundles. In situ hybridization with a beta keratin-specific RNA probe demonstrated that mRNA accumulated in the same regional manner as the polypeptides. This selective expression of beta keratin genes in specific regions of the developing scutate scale suggests that epidermal-dermal interactions provide not only for morphological events, but also for control of complex patterns of histogenesis and biochemical differentiation.     

Chromosomal localization of acidic and basic keratin genes of the domestic dog

Our laboratories are interested in characterizing genes involved in the myriad of heritable diseases affecting the domestic dog, Canis lupus familiaris, and in development of detailed genetic and physical maps of the canine genome. Included in these efforts is examination of conservation of the genetic organization, structure, and function of gene families involved in diseases of the canine skin, skeleton, and eye. To that end, study of the highly conserved keratin gene family was undertaken. Keratins belong to the superfamily of intermediate filaments and are the major structural proteins of the epidermis, hair, and nail. The keratins are highly conserved throughout vertebrate evolution both at the DNA and amino acid sequence levels. Mutations in genes encoding epithelial keratins are known to cause various diseases in humans, and similar histopathological presentations have been reported in the dog. The keratins are divided into two groups, type I (acidic) and type II (basic). In the human, the genes encoding the acidic and basic keratins are clustered on Chrs 17 and 12, respectively. The same genetic arrangement is seen in the mouse with the acidic and basic keratin gene clusters found on Chrs 11 and 15, respectively. Reported here are the chromosomal localization of acidic and basic canine keratin genes as well as supportive sequence data. Fluorescence in situ hybridization (FISH) experiments with clones isolated from a canine genomic library suggest that the acidic keratin gene cluster resides on CFA9 and the basic keratin gene cluster is located on CFA27. Received: 25 September 1998 / Accepted: 1 December 1998     

Avian scale development: XI. Immunoelectron microscopic localization of alpha and beta keratins in the scutate scale

Epithelial-mesenchymal interactions play important roles in morphogenesis, histogenesis, and keratinization of the vertebrate integument. In the anterior metatarsal region of the chicken, morphogenesis results in the formation of distinct overlapping scutate scales. Recent studies have shown that the dermis of scutate scales is involved in the expression of the beta keratin gene products, which characterize terminal differentiation of the epidermis on the outer scale surface (Sawyer et al.: Dev. Biol. 101:8-18, '84; Shames and Sawyer: Dev. Biol. 116:15-22, '86; Shames and Sawyer: In A.A. Moscona and A. Monroy (eds), R.H. Sawyer (Vol. ed): Current Topics in Developmental Biology. Vol. 22: The Molecular and Developmental Biology of Keratins. New York: Academic Press, pp. 235-253, '87). Since alpha and beta keratins are both found in the scutate scale and are members of two different multigene families, it is important to know the precise location of these distinct keratins within the epidermis. In the present study, we have used protein A-gold immunoelectron microscopy with antisera made against avian alpha and beta keratins to specifically localize these keratins during development of the scutate scale to better understand the relationship between dermal cues and terminal differentiation. We find that the bundles of 3-nm filaments, characteristic of tissues known to produce beta keratins, react specifically with antiserum which recognizes beta keratin polypeptides and are found in the embryonic subperiderm that covers the entire scutate scale and in the stratum intermedium and stratum corneum making up the platelike beta stratum of the outer scale surface. Secondly, we find that 8-10-nm tonofilaments react specifically with antiserum that recognizes alpha keratin polypeptides and are located in the germinative basal cells and the lowermost cells of the stratum intermedium of the outer scale surface, as well as in the embryonic alpha stratum, which is lost from the outer surface of the scale at hatching. The alpha keratins are found throughout the epidermis of the inner surface of the scale and the hinge region. Thus, the present study further supports the hypothesis that the tissue interactions responsible for the formation of the beta stratum of scutate scales do not directly activate the synthesis of beta keratins in the germinative cells but influence these cells so that they or their progeny will activate specific beta keratin genes at the appropriate time and place.