Splice site and deletion mutations in keratin (KRT1 and KRT10) genes: unusual phenotypic alterations in Scandinavian patients with epidermolytic hyperkeratosis

Epidermolytic hyperkeratosis is a rare autosomal dominant inherited skin disorder caused by keratin 1 or keratin 10 mutations. Keratins are major structural proteins of the epidermis, and in keratinocytes committed to terminal differentiation the intermediate filaments are composed of keratin 1 and keratin 10 heterodimers. The majority of reported mutations (86.6%) are heterozygous single point mutations and most of these are located in the 1A and 2B regions of the highly conserved keratin alpha-helical rod domain. We have studied eight Scandinavian families with epidermolytic hyperkeratosis and identified three point mutations, two codon deletions, two splice site mutations, and a complex deletion/insertion. Two of the point mutations were in the KRT1 gene (F191C and K177N) and the other was in KRT10 (L453P). All three patients had associated palmoplantar keratoderma. The splice site mutations in KRT1 both caused a large deletion removing 22 codons (delta176-197) from the 1A helical domain. Codon deletions were found in KRT1 (delta170-173) and in KRT10 (delta161-162) in two patients with a severe phenotype. A final patient had a more complex mutation with a large deletion (442 bp) together with a large insertion (214 bp) of unknown origin that caused deletion of exon 6 in KRT1. In conclusion, we have found eight novel keratin mutations that cause epidermolytic hyperkeratosis with differing phenotypes. Even when a large part of keratin 1 (46 amino acids) is deleted, surprisingly mild phenotypes can result, suggesting that genotype-phenotype relationships in epidermolytic hyperkeratosis are complex and do not solely depend on the type of mutation but also depend on interactions between the behavior of the mutant protein and the cellular environment.     

Phenotypic heterogeneity in bullous congenital ichthyosiform erythroderma: possible somatic mosaicism for keratin gene mutation in the mildly affected mother of the proband

BACKGROUND: Bullous congenital ichthyosiform erythroderma (BCIE) shows phenotypic variability. An epidermal nevus may represent somatic mosaicism for keratin gene mutation, which produces generalized BCIE in the next generation. This fact provides evidence that a postzygotic mutation can be passed on to the next generation in BCIE. We hypothesized that the same phenomenon occurred in a family with BCIE whose phenotypes were extremely different. OBSERVATIONS: We studied a 19-year-old boy with severe ichthyosiform erythroderma and prominent palmoplantar hyperkeratosis with digital contracture. In contrast, the proband's mother exhibited only mild ichthyosiform skin, granular verrucous lesions, and less severe streaky palmoplantar hyperkeratosis. Mutation analysis in the proband showed a keratin K1 mutation (N187S, ie, an A-to-G transition at the second position of codon 187, resulting in an asparagine-to-serine substitution). In the mother, the same keratin gene mutation was recognized, but only faintly in the leukocyte DNA, indicating that the amount of the mutated allele in leukocyte DNA was very low compared with that from the proband. CONCLUSIONS: We speculate that the mildly affected mother showed keratin 1 gene mosaicism, and that the BCIE phenotype had been transmitted in a severe form through a mechanism that passes the keratin gene mutation to the next generation. These results suggest that mild forms of BCIE may actually represent extensive epidermal nevi/keratin gene mosaicism.     

Analysis of the KRT9 Gene in a Mexican Family with Epidermolytic Palmoplantar Keratoderma

Epidermolytic palmoplantar keratoderma (EPPK), an autosomal‐dominant genodermatosis, is the most frequently occurring hereditary palmoplantar keratoderma. EPPK is characterized by hyperkeratosis of the palms and soles. Approximately 90% of patients present with mutations in the KRT9 gene, which encodes for keratin 9. Many of these mutations are located within the highly conserved coil 1A region of the alpha‐helical rod domain of keratin 9, an important domain for keratin heterodimerization. The objective was to assess the clinical and molecular characteristics of a Mexican family with EPPK. The clinical characteristics of members of this family were analyzed. The KRT9 gene of affected members was polymerase chain reaction amplified from genomic DNA and sequenced. All affected members of the family had hyperkeratosis of the palms and soles with knuckle pads. The R163W mutation in the KRT9 gene was present in all affected individuals who were tested. Although R163W is the most frequent KRT9 mutation in patients with EPPK, only two families have been reported with knuckle pads associated with this mutation. Our findings indicate that knuckle pads can be associated with EPPK and the R163W mutation in a family with a genetic background different from that described here.     

A novel mutation of keratin 9 gene (R162P) in a Japanese family with epidermolytic palmoplantar keratoderma

Epidermolytic palmoplantar keratoderma (EPPK) is an autosomal dominant inherited skin disorder characterized by hyperkeratosis of the skin over the palms and soles. Mutations in keratin 9 gene (KRT9) have been demonstrated in EPPK. In this study, we screened a Japanese family with EPPK for KRT9 mutation by polymerase chain reaction amplification of genomic sequences, followed by heteroduplex analysis and direct nucleotide sequencing. The mutation consisted of a G-to-C transversion at codon 162 in exon 1, which was located in the hot spot of the mutations that have been reported previously (R162Q and R162W). However, the amino acid substitution was proline for arginine (R162P) in the 1A rod domain, the highly conserved helix initiation motif of keratin 9. Our result illustrates the repertoire of KRT9 mutation underlying the occurrence of EPPK in a Japanese family and is an important contribution to the investigation of the genotype/phenotype correlation.     

Epidermolytic hyperkeratosis type PS-1 caused by aberrant splicing of KRT1

Mutations in the keratin 1 (KRT1) gene underlie epidermolytic hyperkeratosis (EHK). This autosomal dominant disorder is characterized by phenotypic heterogeneity. In the present study, we assessed a 33-year-old individual presenting with severe palmoplantar keratoderma and histopathological findings suggestive of EHK. We analysed genomic DNA extracted from the patient's blood lymphocytes for pathogenic mutations in KRT1. A heterozygous 4-bp deletion was identified in intron 1 of the gene (591+3_+6delGAGT), suggesting the possibility that it may interfere with the normal splicing of intron 1. We detected a 66-bp deletion in KRT1 mRNA extracted from the patient's skin, predicted to result in the translation of a mutant KRT1 lacking 22 amino acids, including the conserved helix initiation motif. The identification of this unusual and novel mutation underscores the diagnostic importance of sequence analysis of keratin gene noncoding regions.     

Identification of the keratin K9 R162W mutation in patients of Italian origin with epidermolytic palmoplantar keratoderma

Epidermolytic palmoplantar keratoderma (EPPK) is an autosomal dominant skin disorder characterized by hyperkeratosis of the palms and soles associated with histologic findings of hyperkeratosis and epidermolysis. Ultrastructurally, there is vacuolization of the cytoplasm and abnormal keratin filament network with tonofilament clumping. EPPK is caused by mutations in the keratin 9 gene (KRT9), which is expressed exclusively in suprabasal keratinocytes of palmoplantar epidermis. The mutation R162W is the most frequent keratin 9 alteration reported in patients from different geographical areas. We present three unrelated Italian families affected by EPPK in which we confirmed the presence of the R162W mutation, by RT-PCR analysis followed by sequencing of the KRT9 gene, in all affected members. The finding of the same mutation in all patients, together with the previous reports of the disease, strongly suggest that position 162 of the KRT9 gene represents a mutation "hot-spot", probably due to the peculiarity of the sequence.     

Altered distribution of keratinization markers in epidermolytic hyperkeratosis

Epidermolytic hyperkeratosis (EH) is a genetic disorder of keratins associated with epidermal differentiation. Affected individuals carry gene mutations for conserved sequences of keratins K1 or K10. The structural alterations of tonofilaments in EH seem to be a direct consequence of the keratin gene mutations. EH epidermis, however, shows many other unexplained abnormalities including acanthosis, hypergranulosis, and hyperkeratosis. To further elucidate the pathogenetic mechanism of EH, we studied distribution patterns of other keratinization-associated molecules including involucrin, small proline-rich protein (SPRR) 1, loricrin and trichohyalin in the skin of four patients by light and electron microscopic immunohistochemistry in conjunction with conventional transmission electron microscopy. The middle to upper epidermal cells showed moderate to strong immunoreactivities to involucrin, SPRR1 and loricrin antibodies. Both intracellular staining and cell peripheral staining was seen for involucrin and SPRR1 antibodies. Loricrin labelling was prematurely associated with the plasma membrane of granular cells, possibly relating to abnormal keratin filament aggregation and cellular vacuolization. Some loricrin labelling was localized on the keratin aggregates, suggesting intermolecular associations between keratin and loricrin. Trichohyalin, hardly detectable in normal epidermis, was present in some granular and cornified cells in EH in association with keratin filaments, suggesting that it may function as an intermediate filament-associated protein. While cornified cell envelopes were intensely labelled only with loricrin antibodies in normal skin, they were immunoreactive to involucrin, SPRR1 and loricrin antibodies in EH. Sequential change in electron density of the cornified cell envelopes, a constant feature in normal skin, was often absent in EH. These results suggest an altered assembly process of cornified cell envelopes in EH.     

Atypical epidermolytic palmoplantar keratoderma presentation associated with a mutation in the keratin 1 gene

BACKGROUND: Epidermolytic palmoplantar keratoderma (EPPK) is an autosomal dominant genodermatosis characterized by epidermolytic hyperkeratosis strictly confined to the palms and soles, and usually associated with mutations in the keratin K9 gene (KRT9). Mutations in the keratin K1 gene (KRT1) have been shown to underlie a variety of phenotypes typically involving generalized epidermolytic hyperkeratosis, but in some cases the phenotype can be more regionally restricted. OBJECTIVES: To identify the genetic defect in two unrelated families initially presenting with EPPK but where careful examination revealed hyperkeratosis extending on to the proximal wrist flexure. Methods Linkage analysis and DNA sequencing. RESULTS: We found that this phenotype is caused by a heterozygous missense mutation in the K1 gene, designated I479T. This mutation lies in the highly conserved helix termination motif of K1, previously shown to be important for keratin assembly and filament formation. In general, mutations in this region of keratins are associated with more severe disease phenotypes. However, K1 mutations in this region and the I479T mutation in particular have previously been associated with both severe and mild bullous congenital ichthyosiform erythroderma phenotypes. When further clinical enquiries were made, several affected individuals in the families studied here were found to have had transient flexural peeling and hyperkeratosis in the neonatal period. CONCLUSIONS: K1 mutations may underlie a phenotype closely resembling EPPK. A history of transient flexural peeling and hyperkeratosis in childhood and palmoplantar keratoderma which extends beyond the boundary of the palmoplantar margins may indicate a K1 mutation rather than a K9 defect. As K1 mutations are also associated with severe widespread phenotypes, with important implications for prognostic and genetic counselling, whole body examination is recommended for patients presenting with EPPK.     

A mutation detection strategy for the human keratin 6A gene and novel missense mutations in two cases of pachyonychia congenita type 1

Pachyonychia congenita type 1 (PC-1) is an autosomal dominant ectodermal dysplasia characterized by hypertrophic nail dystrophy, focal non-epidermolytic palmoplantar keratoderma and variable features of oral leukokeratosis and follicular keratosis. Previously, we have shown that this disease can be caused by mutations in type I keratin K16 and one mutation has been reported in its type II keratin expression partner, K6a. Mutation analysis for K6a has been hampered by the presence of multiple copies of the K6 gene in the human genome, of which some are expressed and others are pseudogenes. Here, we describe a mutation detection strategy where the entire KRT6A gene, approximately 7 kb, is specifically amplified by long-range PCR. Using this technique, we have detected two novel mutations in the 1A domain of the K6a polypeptide, N171K and F174S. Mutations were confirmed in the affected individuals and were excluded from 50 unaffected unrelated individuals by restriction enzyme analysis of KRT6A PCR products. Additionally, mutation N171K was confirmed by RT-PCR in mRNA derived from lesional palmoplantar epidermis of an affected individual, confirming the specificity of the genomic PCR for the functional K6a gene. This, together with a similar strategy which we have developed for the K16 gene, provide a robust system for mutation detection and prenatal diagnosis for patients with PC-1.     

Identification of a de novo keratin 1 mutation in epidermolytic hyperkeratosis with palmoplantar involvement

Epidermolytic hyperkeratosis (EHK) (OMIM 113800) is a generalized skin disease with mostly autosomal dominant inheritance, caused by mutations in keratin 1 or keratin 10. These genes are expressed in suprabasal epidermal layers, resulting in abnormal keratin-intermediate filament cytoskeleton. We present a male patient with generalized hyperkeratosis involving palms and soles. In lesional skin massive hyperkeratosis and cytolysis in the suprabasal layers of the epidermis were observed. Immunohistochemistry staining for keratin 1 (and keratin 10) showed abnormal clumping in suprabasal keratinocytes. By electron microscopy perinuclear intermediate filament clumps were detected in the keratinocytes. A heterozygous missense mutation, designated L187F, was identified in exon 1 of the keratin 1 gene by direct sequencing. This mutation was not detected in his unaffected parents, indicative of a de novo mutational event. The homologous mutation (L187F, also designated L7F) in basal keratin genes keratin 5 or -14 causes epidermolysis bullosa simplex. The amount of keratin 1-mRNA in the patient's skin was not altered compared to controls.We propose that the severe EHK phenotype observed in our patient results from a dominant negative effect of the L187F mutant Keratin 1 allele exerted on keratin 10, the associated partner-keratin. These findings should be helpful for genetic counseling, prenatal diagnosis and studying molecular structure-function relationship in EHK.     

表皮松解性角化过度型鱼鳞病两家系基因突变研究

目的 探讨两个表皮松解性角化过度型鱼鳞病（EHK）家系的基因突变情况。 方法 收集两个EHK家系的临床资料,提取外周血DNA,通过PCR扩增角蛋白基因KRT1和KRT10编码区的全部外显子及其侧翼序列并测序,以表型正常家系成员及50例健康人作为对照。结果 发现两个家系中患者均存在KRT10基因突变,分别为KRT10的剪接位点突变c.1030-2A > G和错义突变c.467G > A,在家系中健康人及健康对照者未发现上述突变。结论 剪接位点突变c.1030-2A > G和错义突变c.467G > A,可能分别是导致这两个家系临床表型的原因。     

Disruption of the suprabasal keratin network by mutation M150T in the helix initiation motif of keratin 10 does not affect cornified cell envelope formation in human epidermis

Keratin 10 (K10) is known to be tightly bound to the cornified cell envelope (CCE) and this binding is thought to play an important role in enhancing the structural integrity of the cornified cells. Bullous congenital ichthyosiform erythroderma (BCIE) is a genetic disorder of keratinization caused by gene mutations in the conserved sequences of keratin 1 (K1) or K10, which leads to abnormal suprabasal keratin network assembly. In BCIE patients' skin, the keratin network abnormalities make the upper spinous and granular keratinocytes fragile and result in blister formation. However, the exact pathomechanism of the hyperkeratosis seen in BCIE is still unknown. The involvement of the CCE in the pathomechanism of hyperkeratosis in BCIE is controversial. Abnormal CCE assembly may cause hyperkeratosis as reported in cases of lamellar ichthyosis. Binding of K10 to CCE is thought to be a vital connection between the suprabasal keratin filament network and CCE. We hypothesize that abnormal suprabasal keratin assembly caused by either K1 or K10 mutations can disrupt CCE formation, resulting in the hyperkeratosis observed in BCIE. To clarify whether K10 and keratin network defects affect CCE formation in vivo, the ultrastructural and immunohistological features of CCE were studied in the epidermis of two Japanese BCIE patients from two independent families carrying an identical missense mutation M150T in the helix initiation motif of K10. Ultrastructurally, a 15-nm-thick, dense, normal-appearing CCE was formed at the cell periphery of the keratinized epidermal cells. Light and electron microscopic immunolabeling revealed that the major CCE precursor proteins, involucrin and loricrin, were normally distributed and restricted to CCE of the epidermis. Immunofluorescent labeling showed that epidermal TGases, TGase 1, TGase 2 and TGase 3, were expressed normally in the epidermis. These findings suggest that a normal CCE is formed during the process of human epidermal keratinization, even if the suprabasal keratin filament network is disrupted as with this particular K10 mutation, M150T in BCIE.     

单纯型大疱性表皮松解症Weber-Cockayne亚型一家系角蛋白5基因突变的检测

鉴定单纯型大疱性表皮松解症Weber-Cockayne亚型一家系中的基因突变位点。方法:应用聚合酶链反应(PCR)及DNA直接测序的方法,检测患者角蛋白5(KRT5)及角蛋白14(KRT14)基因的全部编码序列;针对所发现的突变,以限制性内切酶片段长度多态性(RFLP)分析加以验证。结果:该家系患者存在KRT5基因突变:第2外显子第596位碱基由腺嘌呤突变为胞嘧啶,导致第199位氨基酸由赖氨酸变为苏氨酸(K199T),而正常对照无此替代。结论:KRT5K199T为导致此家系中患者临床表现的特异突变,此突变位点为国内外首次报道。     

R156C mutation of keratin 10 causes mild form of epidermolytic hyperkeratosis

A 37-year-old Japanese male presented to us with persistent asteatotic skin with mild erythema on the trunk and extremities. Skin biopsy from the left knee showed marked epidermal acanthosis and hyperkeratosis, and milder granular degeneration. Ultrastructural analysis revealed clumping of the keratin filaments within suprabasal keratinocytes of the epidermis. Following direct sequencing, we found a single nucleotide substitution in one allele at the residue position 466 of the 1A rod domain segment (CGC to TGC, arginine to cysteine; R156C) in keratin 10. Clinical manifestations and molecular analysis indicated that R156C mutation in keratin 10 gene (KRT10) causes a mild form of epidermolytic hyperkeratosis (EHK) in the presented case.     

A new keratin 5 mutation (K199T) in a family with Weber-Cockayne epidermolysis bullosa simplex

A new missense mutation in the keratin 5 gene (KRT5) in a Chinese family with Weber-Cockayne type epidermolysis bullosa simplex is reported. Direct sequencing identified a heterozygous A --> C substitution at nucleotide 596 altering codon 199 of KRT5 from lysine to threonine in all affected family members, but not in the unaffected family members or in 50 unrelated control samples. The mutation is designated K199T. This mutated lysine residue is sited within the 1A domain of keratin 5 and is highly conserved among all type II keratins. The mutation may perturb the alignment of tonofilaments and, as a consequence, result in skin fragility and blistering.     

Two cases of primarily palmoplantar keratoderma associated with novel mutations in keratin 1

Mutations in keratin 1 were initially described in the classical form of bullous congenital ichthyosiform erythroderma (also known as epidermolytic hyperkeratosis). More recently the range of phenotypes associated with mutations in this gene has been extended to include annular ichthyosiform erythroderma and mild epidermolytic palmoplantar keratoderma. Here we present two novel mutations in the keratin 1 gene (KRT1): a 5' donor splice site mutation in exon 1 (591 + 2T > A) that predicts a 22 amino acid in-frame deletion in the keratin 1 1A domain; and an in-frame deletion in exon 7 (1376del24) that predicts a foreshortened 2B coiled-coil domain of keratin 1. In each case these mutations are associated with palmoplantar keratoderma and mild ichthyosis, largely limited to the flexural areas. These mutations appear to have a less damaging effect than previously reported mis-sense mutations sited in the helix boundary motifs. This report extends the range of phenotypes associated with mutations in KRT1.     

A novel mutation (p.Thr198Ser) in the 1A helix of keratin 5 causes the localized variant of Epidermolysis Bullosa Simplex

Abstract:  A novel missense mutation (p.Thr198Ser) in the 1A helix of keratin 5 (K5) has been identified in a four-generation family with a history of the localized variant of epidermolysis bullosa simplex (EBS-loc), a genetic skin fragility disorder caused by K5 or K14 mutations. Genomic DNA was isolated from blood samples of patients and their healthy relatives, and all exons of the genes encoding K5 and K14 (KRT5 and KRT14) were amplified by PCR and directly sequenced. The identified mutation was confirmed by mismatch allele-specific (MM-AS)-PCR and restriction enzyme digestion with Rsa I. K5 p.Thr198Ser lies at the C-terminal end of the 1A helical domain and is considered to be outside of the main mutation hotspot region. This is the first reported mutation to affect position 30 of the 1A helix (1A:T30S) in any of the 54 known keratins.     

Epidermolytic palmoplantar keratoderma due to a novel type of keratin mutation, a 3-bp insertion in the keratin 9 helix termination motif

Epidermolytic palmoplantar keratoderma (EPPK) is an autosomal dominant genodermatosis characterized by diffuse keratoderma, typically with an erythematous border. Histologically, palmoplantar epidermis shows suprabasal cytolysis and ultrastructurally, tonofilament aggregation with overlying epidermolytic hyperkeratosis. Mutations in the KRT9 gene, encoding keratin 9 (K9), a cytoskeletal protein expressed exclusively in suprabasal keratinocytes of palmoplantar epidermis, have been reported to cause EPPK. To date, all KRT9 defects reported in EPPK have been missense mutations in exon 1, which encodes the start of the alpha-helical rod domain. However, based on studies of other keratin disorders, it was postulated that mutations at the other end of the rod domain might also produce the EPPK phenotype. Here, we report the first mutation in the 2B domain of KRT9, 1362ins3, leading to an insertion of histidine in the helix termination motif of the K9 polypeptide. Insertional mutations have not been previously described in keratins. The phenotype of this case is similar to EPPK caused by 1A domain mutations, demonstrating that mutations in either of the helix boundary motif sequences of K9 are detrimental to keratin function and keratinocyte structure.