In vitro biosynthesis of mouse hair keratins under the direction of follicular RNA.

A hair follicle-enriched fraction from neonatal C57BL/6J mouse skin has been obtained by a newly-developed preparative procedure. RNA isolated from this source directs protein synthesis in a cell-free translation system derived from rabbit reticulocytes. Translation products in the molecular weight range of keratins (45,000-70,000 Mr) are encoded by RNA species which sediment at 18S on sucrose density gradients. Proteins of 63K, 59K, 58K, 47K and 46K Mr were identified as keratins on the basis of electrophoretic mobilities identical with authentic hair keratins and by immunoprecipitation with keratin antiserum.

Differential expression of type I hair keratins.

The hair follicle provides an excellent system in which to study growth and differentiation. Hair keratins are useful tissue-specific molecular markers for these events. By comparing a second mouse Type I hair keratin cDNA clone, MHKA-2, with our previously described MHKA-1, we have been able to contrast the nucleotide sequences and corresponding deduced amino acid sequences of the smallest (mHa4) and the largest (mHa1) major Type I hair keratins. Both nucleotide sequences and both deduced amino acid sequences share high identity but have distinct segments suitable for generation of specific molecular probes. Comparison of amino acid sequences adjacent to the central helical domains has demonstrated homologous subdomains, designated H1 and H2, in the Type I hair keratin nonhelical termini. Although there is only 56% amino acid identity in the carboxy-terminal nonhelical domains, a common sequence, T-------CGPC----R, has been identified in this domain, suggesting a possible common functional role for this portion of the molecule. In addition, it appears that mHa4 may differ in part from mHa1 by deletion of a segment between the H2 subdomain and the conserved sequence. Staining of mouse and human hair follicles with AmHa1, a monospecific polyclonal antibody for mHa1, and AE13, an antibody specific for all Type I hair keratins, suggests differential expression of individual Type I hair keratins in both species. This supports our hypothesis that distinct functional requirements are satisfied by the multiplicity of hair keratins.

Human hair keratins.

Human hair keratins were among the first to be studied but it is only recently that sufficient information has been obtained to gain a basic biologic perspective of these proteins. Hair keratins are members of the intermediate filament family of proteins, yet are sufficiently divergent from epidermal keratins to warrant separate classification: type Ia and IIa ("hard"/hair keratins) and type Ib and IIb (epidermal and other "soft" keratins). As with hair keratins from other species, the human proteins may be distinguished from their epidermal counterparts by a relatively higher cysteine content, 7.6% versus 2.9%, respectively. This feature reflects utilization of disulfide bonding in producing a tougher, more durable structure in the tissues in which the hair keratins are distributed. Although prominent in hair, their distribution is not strictly limited to this tissue. A number of molecular characteristics have been elucidated from human hair keratin gene studies including amino acid sequence data for a type Ia hair keratin. Studies of various pedigrees has revealed a fairly wide latitude of variation in human hair keratin expression that is tolerated without associated obvious hair phenotypic change. Thus, a foundation of knowledge regarding these proteins has emerged and continues to evolve.

Cloning and characterization of a mouse type I hair keratin cDNA.

A cDNA library was prepared from poly(A)-containing C57BL/6J mouse hair-root-enriched mRNA. The library was screened using a radiolabeled nucleic acid probe prepared from a sheep wool, Type I keratin cDNA clone (SWK2). Clone MHKA-1 was shown to contain a mouse hair, Type I keratin cDNA insert by positive hybridization-selection translation assay, and by the corresponding deduced amino acid sequence. The size of the cDNA insert is 1585 bp (excluding homopolymer tails) and on the basis of Northern blot analysis it corresponds to a mRNA of approximately 1.6 Kb. The cloned cDNA sequence includes the entire coding region for a protein of 416 amino acids (including the initiation methionine). Comparison of the deduced amino acid sequence with that of sheep wool, Type I keratin (8c1) reveals an overall corresponding sequence identity of 87%. In contrast, the MHKA-1 protein is significantly less similar to non-hair Type I keratins. An additional 3 amino acids (adjacent proline residues) not present in the wool protein have been identified near the middle of the carboxy-terminal end of the mouse protein. MHKA-1 is the first of a series of mouse hair follicle cDNA clones to be identified and characterized that will enable us to study follicular regulatory mechanisms and the interrelationships among the proteins in the mammalian hair follicle.

Transient expression of mouse hair keratins in transfected HeLa cells: interactions between "hard" and "soft" keratins.

Although it has been shown previously that an acidic (type I) "soft" keratin can interact with many basic (type II) "soft" keratins to form 10-nm intermediate filaments, it has been unclear whether "soft" keratins are compatible with the "hard" keratins typically found in hair and nail. To address this issue and to generate more structural information about hard keratins, we have isolated and sequenced a cDNA clone that encodes a mouse hair basic keratin (b4). Our sequence data revealed new information regarding the structural conservation of hard keratins as a group, being significantly different from soft keratins. Using expression vectors containing appropriate cDNA inserts, we studied the expression of this basic (b4) as well as an acidic (a1) mouse hair keratin in HeLa cells. The expression of these alien hair keratins in the transfected cells was surveyed using a panel of monoclonal and polyclonal antibodies. Our results indicated that the basic and acidic hair keratin readily incorporated into the existing endogenous soft keratin network of HeLa cells. Overproduction of hair keratin, however, occasionally led to the formation of cytoplasmic aggregates containing both hard and soft keratins. These data suggest that although small amounts of newly synthesized hair keratins can incorporate into the "scaffolding" of the preformed soft keratin filament network, possibly through dynamic subunit exchange, overproduction of hard keratins can lead to the partial collapse of the soft keratin network. These observations, along with the deduced amino acid sequence data, support and extend the concept that hard and soft keratins, although closely related, are divergent enough to justify their being divided into two separate subgroups.

Hair-specific keratins: characterization and expression of a mouse type I keratin gene.

A genomic clone for a member of the mouse type I hair keratin protein family has been isolated and analyzed in order to study the regulation of this keratin during the hair growth cycle. The coding sequence is divided into seven exons. The gene structure is typical of keratins in particular and intermediate filaments in general in that the intron-exon borders are not located at the domain borders of the protein. Comparison with a sheep wool keratin gene shows that the splice sites in the two hair keratin genes are found at identical locations relative to the amino acid sequence of the proteins. Similarly, comparison of the promoter areas of these genes shows several areas of nucleotide sequence conservation, including the area around the TATA box and an SV40 core enhancer sequence. In addition, a high degree of sequence identity exists in the fourth intron. In situ hybridization shows that transcripts of this gene are first found in the relatively undifferentiated proximal cortex area in the keratogenous zone of mouse vibrissae.

Chromosomal localization of mouse hair keratin genes.

Many genetic defects are known to cause abnormal development of the coat in mice. Hair keratin genes would seem to be particularly promising candidates among the potential targets of these mutations in mice and of inherited hair-related abnormalities in humans as well. We used specific probes from cloned and sequenced mouse hair keratin cDNAs (MHKA-2, MHKB-1, and MHKB-2) to assess linkage of hair keratin genes and mouse mutations. We analyzed DNA from the progeny of interspecies backcrossed mice for segregation of hair mutations, hair ("hard") keratin alleles, and epidermal ("soft") keratin alleles (Krt-1 and Krt-2 loci). The results suggest that most, if not all, hair keratin genes (types Ia and IIa) are part of the Krt-1 locus on chromosome 11 and Krt-2 locus on chromosome 15, respectively. Linkage of the hair keratin genes and the mutations Re, Den, and Bsk on chromosome 11, and Ca, Sha, and Ve on chromosome 15 suggests that these mutations may possibly involve altered hair keratin expression or structure. In addition, the nondispersion of homologous keratin genes in the mammalian genome suggests that a domain organization of the genes has influenced evolution of the keratin gene family and that the organization may play a significant role in tissue-specific and developmental regulation of keratin gene expression as well.

Mouse hair keratin cDNA: implications and sequences.

An efficient method is described for the isolation of mouse hair follicle mRNAs. The RNA contains two peaks of mRNA activity, 11S and 18S. The larger-sized group of mRNAs encodes keratins of 46K, 47K, 58K, 59K, and 63K Mr. cDNAs were prepared using the follicular mRNAs as templates and cloned to produce a library. Initial screening of this library has identified five acidic and six basic mouse hair keratin clones.

Alopecia areata. A clinical overview.

Alopecia areata is a common disorder usually diagnosed on the basis of history and physical findings alone. Although most patients have a good prognosis and can be successfully treated with available medications, treatment can be slow and emotionally difficult. Early recognition, intervention involving topical and/or intralesional therapy, and education can provide patients with comforting reassurance about eventual recovery.

Hair transplantation between identical twins.

Hair transplantation between monozygotic twins was used to repair a marked congenital, nonprogressive alopecia of the scalp. The alopecia was due to a follicular aplasia that, along with several other abnormalities of the integumentary system, affected only one of the twins. This case represents a unique application of isograft transplantation.

Angora mouse mutation: altered hair cycle, follicular dystrophy, phenotypic maintenance of skin grafts, and changes in keratin expression.

Angora is an autosomal recessive mouse mutation caused by a deletion of approximately 2 kilobases in the fibroblast growth factor 5 (Fgf5) gene. Phenotypically, homozygous angora (Fgf5go/Fgf5go) mice have excessively long truncal hair and can be differentiated from heterozygous (+/Fgf5go) and wild-type (+/+) littermates by 21 days of age. Abnormal hair length is due to a prolongation of the anagen phase of the hair cycle of approximately 3 days. In addition, widely scattered hair follicles produce structurally defective hair shafts that twist within the follicle, presumably causing secondary hyperplasia of the outer root sheath and epidermis adjacent to the follicle. These follicular abnormalities were accentuated by immunohistochemical detection of mouse specific keratin 6, a nonspecific marker of epidermal hyperplasia. These abnormalities could be identified from birth throughout life in angora mice genotyped by polymerase chain reaction techniques. Moreover, the long truncal hair phenotype was maintained in skin grafted onto C.B-17/Sz-scid/scid mice that had normal pelage hairs and hair cycles, suggesting that circulating or diffusible humoral factors regulating the mouse hair cycle are not involved in this mutation. The angora mutation provides another useful mouse model for studying the hair cycle and its modulation.

Assembly of hair keratins in transfected epithelial cells.

To define the interactions required for the filament assembly of differentiation-specific keratins, active copies of mouse hair keratin mHa1 and mHb4 genes were introduced into a rat kangaroo kidney epithelial cell line (PtK2) and a rat stratified squamous epithelial cell line (rat epidermal keratinocyte). In PtK2 transient transfectants, when introduced individually or in combination, mHa1 and mHb4 formed aggregates of ring-like structures of various sizes at the perinuclear region with no evidence of organization into a keratin network. These aggregates altered the distribution of the endogenous keratins and vimentin. In most of the cells carrying the ring-like structures of mHa1 and mHb4 around the nucleus, the endogenous keratin network collapsed and localized around the nucleus. Furthermore, the densely accumulated endogenous keratin surrounded the ring-like aggregates with partial co-localization. However, when transfected into the rat epidermal keratinocytes, mHa1 and mHb4 were able to co-localize with the well-developed cytoskeleton of endogenous keratins. These results showed that, in contrast to keratin pairs K5/K14 and K8/K18, the mHa1/mHb4 pair is unable to develop an extensive keratin network on its own and that there are possible differential abilities among these hair keratins and other keratins to form well-developed cytoplasmic networks.