A comparison of genomic coding sequences for feather and scale keratins: structural and evolutionary implications.

DNA sequences have been obtained for embryonic chick feather and scale keratin genes. Strong homologies exist between the protein coding regions of the two gene types and between the deduced amino acid sequences of the keratin proteins. Scale keratins are larger than feather keratins and the size difference is mainly attributable to four 13-amino acid repeats between residues 77 and 128 which compose a peptide sequence rich in glycine and tyrosine. The strong similarities between the two peptide structures for feather and scale in the homologous regions suggests a similar conformation within the protein filaments. A likely consequence is that the additional repeat region of the scale protein is located externally to the core filament. Tissue-specific features of filament aggregation may be attributable to this one striking sequence difference between the constituent proteins. It is believed that the genes share a common ancestry and that feather-like keratin genes may have evolved from a scale keratin gene by a single deletion event.     

The Expression of Beta ({beta}) Keratins in the Epidermal Appendages of Reptiles and Birds

The integuments of extant vertebrates display a variety of epidermalappendages whose patterns, morphology and terminal differentiation(epidermal keratins) depend upon interactions between ectodermal(epidermis) and mesodermal (dermis) tissues. In reptiles andbirds, appendage morphogenesis precedes terminal differentiation.Studies have demonstrated that appendage morphogenesis influencesthe expression of the appendage specific keratin genes. However,little is known about the nature of the structural genes expressedby the epidermal appendages of reptiles. How pattern formationand/or appendage morphogenesis influence terminal differentiationof reptilian appendages is not known. The epidermal appendages of reptiles and birds are characterizedby the presence of both alpha () and beta (ß) typekeratin proteins. Studies have focused on the genes of avianß keratins because they are the major structural proteinsof feathers. The occurrence of ß keratin proteinsin the scales and claws of both birds and reptiles and theirimmunological cross-reactivity suggest that the genes for reptilianß keratins may be homologous with those of birds.In bird appendages, the ß keratins are the productsof a large family of homologous genes. Specific members of thisgene family are expressed during the development of each appendage.Recent sequence analyses of feather ß keratins, fromdifferent orders of birds, demonstrate that there is more diversityat the DNA level than was implied by earlier protein sequencingstudies. Immunological techniques show that the same antibodies thatreact with the epidermal ß keratins of the chicken(Gallus domesticus) react with the epidermal ß keratinsof American alligators (Alligator mississippiensis). Furthermore,a peptide sequence (20 amino acids) from an alligator claw ßkeratin is similar to a highly conserved region of avian claw,scale, feather, and feather-like ß keratins. Theseobservations suggest that the ß keratin genes of avianepidermal appendages have homologues in the American alligator.Understanding the origin and evolution of the ß keratingene families in reptiles and birds will undoubtedly add toour understanding of the evolution of skin appendages such asscales and feathers.     

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     

Molecular cloning and characterization of the human beta-like globin gene cluster

The genes encoding human embryonic (epsilon), fetal (G gamma, A gamma) and adult (delta, beta) beta-like globin polypeptides were isolated as a set of overlapping cloned DNA fragments from bacteriophage lambda libraries of high molecular weight (15-20 kb) chromosomal DNA. The 65 kb of DNA represented in these overlapping clones contains the genes for all five beta-like polypeptides, including the embryonic epsilon-globin gene, for which the chromosomal location was previously unknown. All five genes are transcribed from the same DNA strand and are arranged in the order 5'-epsilon-(13.3 kb)-G gamma-(3.5 kb)-A gamma-(13.9 kb)-delta-(5.4 kb)-beta-3'. Thus the genes are positioned on the chromosome in the order of their expression during development. In addition to the five known beta-like globin genes, we have detected two other beta-like globin sequences which do not correspond to known polypeptides. One of these sequences has been mapped to the A gamma-delta intergenic region while the other is located 6-9 kb 5' to the epsilon gene. Cross hybridization experiments between the intergenic sequences of the gene cluster have revealed a nonglobin repeat sequence (*) which is interspersed with the globin genes in the following manner: 5'-**epsilon-*G gamma-A gamma*-**delta-beta*-3'. Fine structure mapping of the region located 5' to the delta-globin gene revealed two repeats with a maximum size of 400 bp, which are separated by approximately 700 bp of DNA not repeated within the cluster. Preliminary experiments indicate that this repeat family is also repeated many times in the human genome.     

Retinoic acid induction of featherlike structures from reticulate scales

Retinoic acid-induced transformation of reticulate scales to feather-like structures (Dhouailly and Hardy, '78) provides a useful model to study biochemical differentiation in avian skin. In this study, immunofluorescent analysis of reticulate scale-feathers (RSFs) indicates that they contain beta keratin in feather barbs and, thus, are true feathers, biochemically. Epidermal cells that would otherwise produce only alpha keratin in reticulate scales are induced to reorganize and differentiate into barb ridge cells that accumulate feather beta keratins. The mechanism for these dramatic morphological and biosynthetic responses to retinoic acid is unknown.     

Mammalian keratin gene families: organisation of genes coding for the B2 high-sulphur proteins of sheep wool.

We have isolated two genomic clones containing three B2 high-sulphur keratin genes from a sheep genomic library constructed in Charon 4A. These genes do not contain intervening sequences. Two genes, encoding the B2A and B2D proteins are closely linked in the genome, being separated by 1.9 kb, and are transcribed in the same direction. Although there is extensive sequence conservation in the 5' non-coding and coding regions, the 3' non-coding regions diverge both in length and sequence. Within the 5' non-coding region adjacent to the initiating AUG there is a highly conserved 18 bp sequence which is also present in another gene coding for a member of a different, unrelated high-sulphur keratin family. In the B2A-B2D intergene region, tightly linked to the B2D gene, there is a putative, divergently transcribed gene.     

The keratin BIIIB gene family: isolation of cDNA clones and structure of a gene and a related pseudogene

The nucleotide sequence of cDNA clones encoding the three major BIIIB high-sulfur wool keratin proteins (BIIIB2, 3, and 4) and the structure of a BIIIB4 gene and a BIIIB3 pseudogene are reported. Although Southern blot analysis indicates that the BIIIB genes comprise a multigene family in the sheep genome, they are poorly represented in genomic DNA libraries. The family sequence homology of the coding region extends into the 5' and 3' untranslated regions and the near 5' flanking region of the BIIIB3 and 4 genes. These homologies suggest that the BIIIB3 and 4 genes represent the latest gene duplication event in the evolution of the BIIIB multigene family. Like the genes coding for other wool keratin matrix protein components, the BIIIB genes have the conserved 18-bp sequence immediately 5' to the initiation codon and also appear to lack introns.     

Evolutionary relationships among copies of feather beta ({beta}) keratin genes from several avian orders

The feather beta (β) keratins of the white leghorn chicken (order Galliformes, Gallus gallus domesticus) are the products of a multigene family that includes claw, feather, feather-like, and scale genes (Presland et al. 1989a). Here we characterize the feather β-keratin genes in additional bird species. We designed primers for polymerase chain reactions (PCR) using sequences available from chicken, cloned the resulting amplicons to isolate individual copies, and sequenced multiple clones from each PCR reaction for which we obtained amplicons of the expected size. Feather β-keratins of 18 species from eight avian orders demonstrate DNA sequence variation within and among taxa, even in the protein-coding regions of the genes. Phylogenies of these data suggest that Galliformes (fowl-like birds), Psittaciformes (parrots), and possibly Falconiformes (birds of prey) existed as separate lineages before duplication of the feather β-keratin gene began in Ciconiiformes (herons, storks, and allies), Gruiformes (cranes, rails, and allies), and Piciformes (woodpeckers and allies). Sequences from single species of Coraciiformes (kingfishers) and Columbiformes (pigeons) are monophyletic and strikingly divergent, suggesting feather β-keratin genes in these birds also diverged after these species last shared a common ancestor with the other taxa investigated. Overall, these data demonstrate considerable variation in this structural protein in the relatively recent history of birds, and raise questions concerning the origin and homology of claw, feather-like, and scale β-keratins of birds and the reptilian β-keratins.     

The structure and expression of a gene encoding chick claw keratin.

A cDNA library was constructed from embryonic chick claw mRNA and a claw keratin (cKer)-encoding clone was isolated and sequenced. Subsequently, a genomic clone, containing four cKer-encoding genes (cKer) was isolated and one of the genes (cKer1) was completely sequenced. The cKerl gene appears to be differentially expressed in the keratinizing tissue appendages of the embryonic chick, being abundantly expressed in the claw and at a low level in feather tissue. Comparison of the deduced amino acid (aa) sequence of the cKer to those of feather (fKer) and scale keratins (sKer) showed that the regions conserved between fKer and sKer are also found in the cKer. The glycine-rich as repeat region characteristic of sKer is also present in a shortened form in the cKer sequence. Like the fKer genes (fKer) and the feather histidine-rich protein-encoding gene (HRP), the cKer1 gene also contains one intron which interrupts the 5'-noncoding region at an equivalent position to that found in the fKer and HRP genes. Genomic Southern analysis using the cKer cDNA as a probe indicated the presence of several related genes in the chick genome.     

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)     

Localization of the gene for human simple epithelial keratin 18 to chromosome 12 using polymerase chain reaction.

Many human genes encoding keratin intermediate filament proteins are clustered on chromosomes 17 (the type I genes) and 12 (the type II genes). Some have not yet been localized, notably the genes for the primary embryonic keratins 8 and 18, normally expressed in simple epithelia: this is because the numerous pseudogenes for these keratins have made it difficult to identify the true functional gene in each case. Through the use of human-specific primers from within introns of the published gene sequence for human type I keratin 18, human genomic DNA has been specifically amplified using the polymerase chain reaction. A single reaction product was obtained. DNA from a characterized series of mouse-human somatic cell hybrid lines was tested for the presence of sequences able to initiate the chain reaction from these primers, and the presence or absence of this genomic DNA PCR product allowed us to assign a gene for human keratin 18 to chromosome 12 unambiguously. This differs from the location of other human type I keratins on chromosome 17 and may indicate the early divergence of the genes for stratifying cell keratins from that of simple, or embryonic, keratin 18.     

Genomic organization of the human folate receptor genes on chromosome 11q13.

There has been interest in the high affinity folate receptor (FOLR) recently because of its high expression in the majority of ovarian tumors. The FOLR genes are part of a family that includes an adult gene, a fetal gene, and one or more pseudogenes, which have been localized to chromosome 11. As a step toward understanding why the adult FOLR gene product is expressed on tumors, we have determined the organization of all the human FOLR-related genes. YAC clones were isolated using the adult FOLR probe. The organization of the locus was determined by PFGE of YAC DNA and by YAC fragmentation. Four FOLR-related genes were found within 140 kb. The adult and fetal genes are not more than 23 kb apart, with the 3' end of the adult gene facing the 5' of the fetal gene. A physical map of over 900 kb of the surrounding region was also constructed. The chromosomal assignment of the FOLR locus was refined to 11q13.3-q13.5 telomeric of the FGF3 locus using fluorescence in situ hybridization.     

Isolation and characterisation of keratin mRNA from the scale epidermis of the embryonic chick

The keratin polypeptides of the epidermis from the leg scale region of 17-day-old embryonic chicks were extracted as S-carboxymethylated derivatives and characterised by electrophoresis on SDS and pH 9.5 urea gels including a combination of both in two dimensions. Proteins were isolated that gave X-ray diffraction patterns typical of alpha- and beta- (avian feather) keratins. An mRNA fraction was isolated from 17-day-old scale tissue by guanidinium chloride extraction and sucrose gradient fractionation. The mRNA was translated in the wheat germ system to give a major product indistinguishable from the molecular weight class (Mr 14 500) of scale beta-keratin polypeptides. A cDNA library was constructed in pBR322 from a 15 S mRNA subfraction and two recombinant clones were selected by their strong hybridisation to cDNA prepared from the 15 S mRNA. The sequencing of these has yielded details of the relatedness of two scale keratin genes including their 3' untranslated regions. Almost half of the protein sequences of the two homologous scale keratins has been deduced and a notable feature of the scale keratin structure appears to be the presence of at least two sequence domains consisting of 13 amino acid repeats.     

Ig VH, DH, and JH germ-line gene segments linked by overlapping cosmid clones of rabbit DNA

Overlapping cosmid clones of rabbit germ-line DNA containing VH, DH and JH gene segments were isolated. The map of this cluster of cosmid clones indicated that the rabbit VH and JH regions were separated by 63 kb. Hybridization of Southern blots of these cosmid clones with two different DH segment probes identified a total of six DH segments within the region between the VH and JH regions. The nucleotide sequences of the JH region and one of the DH segments have been determined. The DH segment has conserved heptamer and nonamer sequences separated by 12 and 11 bp at the 3' and 5' sides, respectively, of the coding region and hence, appears to be a functional gene. The nucleotide sequence of the JH region revealed four functional JH gene segments and one JH pseudogene. Inasmuch as the JH region had previously been linked by contiguous overlapping clones with C mu, C gamma, C epsilon, and one C alpha gene, this VH-DH-JH cluster and the clones containing the Ig H chain C region genes represent 190 kb of contiguous germ-line DNA of the Ig H chain locus.     

Somatic DNA rearrangement generates functional rat immunoglobulin kappa chain genes: the J kappa gene cluster is longer in rat than in mouse

The kappa immunoglobulin (Ig) genes from rat kidney and from rat myeloma cells were cloned and analyzed. In kidney DNA one C kappa species is observed by Southern blotting and cloning in phage vectors; this gene most likely represents the embryonic configuration. In the IR52 myeloma DNA two C kappa species are observed: one in the same configuration seen in kidney and one which has undergone a rearrangement. This somatic rearrangement has brought the expressed V region to within 2.7 kb 5' of the C kappa coding region; the rearrangement site is within the J kappa cluster which we have mapped. The rat somatic Ig rearrangement, therefore, closely resembles that seen in mouse Ig genes. In the rat embryonic fragment two J kappa segments were mapped at 2 and 4.3 kb 5' from the C kappa coding region. Therefore, the rat J kappa cluster extends over about 2.3 kb, a region much longer than the 1.4 kb of the mouse and human J kappa clusters. In the region between C kappa and the expressed J kappa of IR52 myeloma DNA, and XbaI site present in the embryonic kappa gene has been lost. A somatic mutation has therefore occurred in the intervening sequence DNA approx. 0.7 kb 3' from the V/J recombination site. Southern blots of rat kidney DNA hybridized with different rat V kappa probes showed non-overlapping sets of bands which correspond to different subgroups, each composed of 8-10 closely related V kappa genes.