Monilethrix: a keratin hHb6 mutation is co-dominant with variable expression

Novel KRT83 and KRT86 mutations associated with monilethrix

Monilethrix is an autosomal dominant hair disorder caused by mutations in the hard keratins KRT81, KRT83 and KRT86. The affected hairs are fragile and break easily, leading to scarring alopecia. Follicular hyperkeratosis in the neck and on extensor sides of extremities is a frequently associated finding. The disorder is rare, but probably underreported because its manifestations may be mild. Mutations in KRT81 and KRT86 are the most common. Here, we report new cases from Venezuela, the Netherlands, Belgium and France. The Venezuelan kindred is special for having patients with digenic novel nucleotide changes, a KRT86 mutation associated with monilethrix and a KRT81 variant of unknown clinical significance. In the French and Dutch patients, we found novel KRT86 and KRT83 mutations. Our findings expand the mutational spectrum associated with monilethrix.

A mutation in the type II hair keratin KRT86 gene in a Han family with monilethrix

Monilethrix, a congenital disease of hair, is usually associated with mutations in keratin genes, like KRT81, KRT83 and KRT86. We conducted this study to investigate the mutation of type II human basic hair keratin hHb/KRT gene in a Han family with monilethrix and obtain information for potential pathogenic mechanism study of monilethrix. Peripheral blood samples were drawn for genomic DNA detection. Exon 1 and exon 7 of the KRT81, KRT83 and KRT86 genes were amplified by PCR. All PCR products were sequenced directly using an ABI 310 DNA sequencer. These sequences were aligned with the standard sequences in GenBank using the BLAST software. PCR products were digested with restriction endonuclease and restriction fragment length polymorphism (RFLP) analysis was performed. In this study, we identified one novel mutation, which is a heterozygous transitional mutation of G→A at position 1,289 in exon 7 of the KRT86 gene [R430Q (KRT86)]. RFLP assays for the novel mutation excluded the possibility of polymorphism. The R430Q mutation of the KRT86 gene may be pathogenic for monilethrix. Meanwhile, we did not find any novel mutation or recurrent mutation in exons 1 and 7 of KRT81 and KRT83 and exon 1 of KRT86. There is a potential pathogenic gene in the subjects and our results expand the spectrum of mutations in the hHb6 gene.

Monilethrix treated with minoxidil

In literature many different therapies are proposed to treat Monilethrix, but a definitive therapy still doe not exist. We decided to treat four patients affected by Monilethrix, with topical minoxidil 2%, 1 ml night and day for 1 year. Minoxidil led to a an increase of normal hair shaft without any side effects in all the patients. Therefore topical minoxidil 2% could be considered a good therapy to treat Monilethrix.

An autosomal recessive form of monilethrix is caused by mutations in DSG4: clinical overlap with localized autosomal recessive hypotrichosis

Monilethrix is a structural defect of the hair shaft usually inherited in an autosomal dominant fashion and caused by mutations in the hHb1, hHb3, and hHb6 keratin genes. Autosomal recessive inheritance in this disease has been sporadically reported. We encountered 12 Jewish families from Iraq, Iran, and Morocco with microscopic findings of monilethrix, but with no evidence of vertical transmission. Since no mutations were found in these three hair keratin genes, we examined nine chromosomal regions containing gene clusters encoding skin and hair genes. On chromosome 18q, a common haplotype in the homozygous state was found among all seven Iraqi patients, but not in 20 controls (P<0.0001). Sequencing of the main candidate gene from this region revealed four different mutations in desmoglein 4 (DSG4). Mutations in DSG4 have been previously reported in localized autosomal recessive hypotrichosis, a disorder that shares the clinical features of monilethrix but lacks the characteristic microscopic appearance of the hair shaft. Our findings have important implications for genetic counseling to monilethrix patients and families, and suggest that DSG4-associated hair disorders may be more common than previously thought.

Keratins of the Human Hair Follicle

Substantial progress has been made regarding the elucidation of differentiation processes of the human hair follicle. This review first describes the genomic organization of the human hair keratin gene family and the complex expression characteristics of hair keratins in the hair-forming compartment. Sections describe the role and fate of hair keratins in the diseased hair follicle, particularly hereditary disorders and hair follicle-derived tumors. Also included is a report on the actual state of knowledge concerning the regulation of hair keratin expression. In the second part of this review, essentially the same principles are applied to outline more recent and, thus, occasionally fewer data on specialized epithelial keratins expressed in various tissue constituents of the external sheaths and the companion layer of the follicle. A closing outlook highlights issues that need to be explored further to deepen our insight into the biology and genetics of the hair follicle.

De novo mutations in monilethrix

Mutations in the hair keratins hHb1 and hHb6 have been recently reported to cause monilethrix, an autosomal dominant hair shaft disorder, characterized by variable degrees of hair fragility and follicular hyperkeratosis. We found 10 families with monilethrix in whicn the parents were not clinically affected, and sequenced the hair keratin hHb1, hHb2 and hHb6 genes in seven patients. In five patients no mutations were found, while in two patients we identified de novo germline missense mutations at the helix termination motif: E402K (hHb6) and E413K (hHb1).

Recurrent missense mutations in the hair keratin gene hHb6 in monilethrix

Monilethrix is an autosomal dominant hair disorder characterized by a beaded appearance of the hair resulting from periodic thinning of the shaft (MIM 158000). The phenotype shows variable penetrance and results in hair fragility and patchy dystrophic alopecia. Mutations of the helix-encoded region in two hair-specific keratins (hHb1 and hHb6) have been identified as responsible for this disorder. We investigated two unrelated families from Russia and Colombia with monilethrix and found two missense mutations in hHb6. In the Russian family, we found a G to A transition at the first base of codon 402, resulting in a lysine substitution (GAG to AAG), designated E402K. In the Colombian family, affected patients carried a missense mutation of codon 413, involving a transition from G to A causing a lysine substitution (GAG to AAG), designated E413K. These two mutations have been identified in other monilethrix families from Europe. Our findings extend the body of evidence implicating recurrent hHb6 and hHb1 mutations in monilethrix families from around the world.

Clinical relevance of hair microscopy in alopecia

Hair microscopy can clarify the cause of hair loss in a range of diagnoses. Most of these are associated with hair breakage, the rest are related to lack of growth. Hair breakage may be due to excessive trauma or underlying susceptibility, where structural clues may be present. Lack of growth reflects follicular dynamics and represents the central mechanism of most common causes of alopecia. In such conditions, microscopy only reveals nonspecific confirmation of short anagen. Although this may assist clinical diagnosis, microscopy in alopecia only allows exclusion of diagnoses related to hair breakage. Confidence in the outcome of hair microscopy is based on the size of the sample of hairs, the length of the hair, the characteristics of the observations and the experience of the person undertaking the microscopy.

A novel type II cytokeratin, mK6irs, is expressed in the Huxley and Henle layers of the mouse inner root sheath

Hair follicle differentiation involves the expression of both epithelial-type keratins or cytokeratins and hair keratins as well as hair keratin-associated proteins. In this study, a cDNA clone encoding a cytokeratin family member was isolated using RNA differential display techniques. The predicted amino acid sequence derived from this clone, revealed a homology with a number of cytokeratins, not only in the central alpha-helical regions but also in the conserved portions of the amino and carboxy terminal domains, indicating that this protein represents a new member of the mouse type II cytokeratin family. Northern blot analysis showed expression in mouse skin, but not in other tissues, including tongue, esophagus, and forestomach. One- and two-dimensional western blot analysis showed that this new cytokeratin was 57 kDa in size and ran slightly below the area of cytokeratin 5, which corresponded to that of the cytokeratin 6 family members. Both RNA in situ hybridization and immunohistochemical studies of mouse anagen hair follicles demonstrated expression of this cytokeratin in the inner root sheath hair cone during anagen III and in the Henle and Huxley layers of the inner root sheath during anagen VI. The expression of the new cytokeratin began in the hair bulb and progressed up to the height of the keratogenous zone. Taken together the sum of the data analyzed, we have termed this novel cytokeratin mK6irs (mouse gene nomenclature k2-6g) to indicate both its similar mobility with K6 in two-dimensional gels and its specific expression in the inner root sheath of the hair follicle.

Two different mutations in the same codon of a type II hair keratin (hHb6) in patients with monilethrix

Monilethrix is an autosomal dominant hair disorder characterized by a beaded appearance of the hair due to periodic thinning of the shaft. The phenotype shows variable penetrance and results in hair fragility and patchy dystrophic alopecia. Mutations of the helix-encoding region in two hair-specific keratins (hHb1 and hHb6) have been identified. We have now investigated two unrelated monilethrix patients and identified two different novel heterozygous point mutations of the same codon in exon 7 of the hHb6 gene. Dystrophic hair samples obtained from both patients showed the typical beaded appearance by scanning electron microscopy. Both mutations affected the first base of codon 402 (glutamic acid). In patient A, a G to C transition occurred causing a glutamine substitution (GAG to CAG: E402Q) whereas in patient B, the transition was G to A yielding a lysine substitution (GAG to AAG: E402K). The sequence of the 1A helical regions of hHb1 and hHb6 as well as the 2B helical region of hHb1, were normal. Unaffected relatives did not have the hHb6 mutation and this codon was found to be highly conserved showing no alteration in the normal population (100 alleles examined). Both mutations disrupted a Taq I restriction site and restriction fragment length polymorphism analysis showed that a diagnostic 361 bp fragment could confirm the mutation. Thus, two new point mutations of the hair-specific keratin gene hHb6 have been identified in this genetic disease.

Identification of novel mutations in basic hair keratins hHb1 and hHb6 in monilethrix: implications for protein structure and clinical phenotype

Monilethrix is an hereditary hair dystrophy recently shown to be due to mutations in the helix termination motif of two type II (basic) human hair keratin genes, hHb1 and hHb6. It has been suggested that mutation in hHb1 produces a less severe phenotype. We have studied hair keratin genes and clinical features in 18 unrelated pedigrees of monilethrix from Germany, Scotland, Northern Ireland, and Portugal, in 13 of which mutations have not previously been identified. By examining the rod domains of hHb1, hHb3 and hHb6, we have identified mutations in nine of the new pedigrees. We again found the glutamine-lysine substitution (E413K) in the helix termination motif of hHb6 in two families, and in another, the corresponding E413K substitution in the hHb1 gene. In four families a similar substitution E402K was present in a nearby residue. In addition two novel mutations within the helix initiation motif of hHb6 were found in Scottish and Portuguese cases, in whom the same highly conserved asparagine residue N114 was mutated to histidine (N114H) or aspartic acid (N114D) residues, respectively. In four other monilethrix pedigrees mutations in these domains of hHb1, hHb3, and hHb6 were not found. The mutations identified predict a variety of possible structural consequences for the keratin molecule. A comparison of clinical features and severity between cases with hHb1 and hHb6 mutations does not suggest distinct effects on phenotype, with the possible exception of nail dystrophy, commoner with hHb1 defects. Other factors are required to explain the marked variation in clinical severity within and between cases.

Monilethrix: a novel mutation (Glu402Lys) in the helix termination motif and the first causative mutation (Asn114Asp) in the helix initiation motif of the type II hair keratin hHb6

Monilethrix, a rare human hair disorder with autosomal dominant transmission, can be caused by mutations in hair keratins. Up to now, causative mutations have only been found in two type II cortex keratins, hHb6 and hHb1. In these hair keratins, the helix termination motif, HTM, was the only site in which mutations were located. The most frequent mutation, which has been found in 22 cases, was a Glu413Lys substitution in hHb6, whereas other mutations, i.e., hHb6 Glu413Asp, hHb1 Glu413Lys, and hHb1 Glu402Lys, have been reported in a distinctly lower number of cases. In this study, we describe the equivalent of the hHb1 Glu402Lys mutation in the HTM of cortex keratin hHb6. The mutation occurred in an American family in which it could only be detected in one clinically affected individual. Thus the underlying G-->A transition represents a spontaneous germ-line mutation in the hHb6 gene. This new mutation indicates that both the hHb6/hHb1 Glu413Lys substitution and the hHb6/hHb1 Glu402Lys substitution, represent mutational hotspots in the HTM of type II cortex keratins. However, we also describe a monilethrix-causing mutation in the helix initiation motif, HIM, of the cortex keratin hHb6. The critical Asn114Asp substitution was only found in affected members of a large Swedish three-generation family. Considering that since childhood, half of the affected individuals suffer from complete baldness and follicular keratosis, the new HIM mutation seems to be associated with a rather severe disease phenotype. In conclusion, our data strongly suggest that monilethrix is a disease of the hair cortex, whose etiology is interesting in that causative mutations seem to be restricted to type II hair keratins.

Identification of a genetic defect in the hairless gene in atrichia with papular lesions: evidence for phenotypic heterogeneity among inherited atrichias

Recently, we showed that atrichia with papular lesions (APL), a rare inherited form of alopecia, is transmitted as an autosomal recessive trait in a large inbred kindred of Israeli-Arab origin. Furthermore, we mapped the APL locus to a 5-cM region of chromosome 8p12 in this family. The human "hairless" gene is a candidate target gene for the disease mutation because it maps to the APL locus and because it was recently found to be mutated in a related but clinically distinct form of alopecia known as "alopecia universalis" or "congenital alopecia." In the present study, the coding sequence of the hairless gene was compared by reverse transcription-PCR in fibroblast cell lines derived from an affected patient and an unrelated individual. We identified a single-base deletion (3434delC) in the hairless gene that cosegregated with the disease phenotype in the family. This deletion is predicted to cause a frameshift mutation in the highly conserved C-terminal part of the hairless protein, a region putatively involved in the transcription factor activity of the hairless gene product. The present results are indicative of phenotypic heterogeneity in inherited atrichias caused by mutations in the hairless gene, suggesting different roles for the regions mutated in APL and in other forms of congenital atrichia during hair development.