Herlitz's junctional epidermolysis bullosa is linked to mutations in the gene (LAMC2) for the gamma 2 subunit of nicein/kalinin (LAMININ-5).

We have linked Herlitz's junctional epidermolysis bullosa (H-JEB) to the gene (LAMC2) encoding the gamma 2 subunit of nicein/kalinin, an isolaminin (laminin-5) expressed by basal keratinocytes. In four H-JEB kindreds, a maximum two-point lod score of 5.33 at theta = 0 was observed between a microsatellite near LAMC2 at 1q25-31 and the disease. In one family, a homozygous point mutation leading to a premature stop codon (CGA to TGA) was identified in exon 3 of the gene. The segregation of the mutated allele implicates the mutation in the pathology of the disorder and corroborates the linkage results.

Mutations in ATP2C1, encoding a calcium pump, cause Hailey-Hailey disease.

Hailey-Hailey disease (HHD, MIM 16960) is inherited in an autosomal dominant manner and characterized by persistent blisters and erosions of the skin. Impaired intercellular adhesion and epidermal blistering also occur in individuals with pemphigus (which is due to autoantibodies directed against desmosomal proteins) and in patients with Darier disease (DD, MIM 124200), which is caused by mutations in a gene encoding a sarco/endoplasmic reticulum (ER)-Golgi calcium pump. We report here the identification of mutations in ATP2C1, encoding the human homologue of an ATP-powered pump that sequesters calcium into the Golgi in yeast, in 21 HHD kindreds. Regulation of cytoplasmic calcium is impaired in cultured keratinocytes from HHD patients, and the normal epidermal calcium gradient is attenuated in vivo in HHD patients. Our findings not only provide an understanding of the molecular basis of HHD, but also underscore the importance of calcium control to the functioning of stratified squamous epithelia.

Epidermolysis bullosa simplex: evidence in two families for keratin gene abnormalities.

Epidermolysis bullosa simplex (EBS) is characterized by skin blistering due to basal keratinocyte fragility. In one family studied, inheritance of EBS is linked to the gene encoding keratin 14, and a thymine to cytosine mutation in exon 6 of keratin 14 has introduced a proline in the middle of an alpha-helical region. In a second family, inheritance of EBS is linked to loci that map near the keratin 5 gene. These data indicate that abnormalities of either of the components of the keratin intermediate filament heterodipolymer can impair the mechanical stability of these epithelial cells.

Basal cell carcinomas in mice overexpressing sonic hedgehog.

Mutations in the tumor suppressor gene PATCHED (PTC) are found in human patients with the basal cell nevus syndrome, a disease causing developmental defects and tumors, including basal cell carcinomas. Gene regulatory relationships defined in the fruit fly Drosophila suggest that overproduction of Sonic hedgehog (SHH), the ligand for PTC, will mimic loss of ptc function. It is shown here that transgenic mice overexpressing SHH in the skin develop many features of basal cell nevus syndrome, demonstrating that SHH is sufficient to induce basal cell carcinomas in mice. These data suggest that SHH may have a role in human tumorigenesis.

Human homolog of patched, a candidate gene for the basal cell nevus syndrome.

The basal cell nevus syndrome (BCNS) is characterized by developmental abnormalities and by the postnatal occurrence of cancers, especially basal cell carcinomas (BCCs), the most common human cancer. Heritable mutations in BCNS patients and a somatic mutation in a sporadic BCC were identified in a human homolog of the Drosophila patched (ptc) gene. The ptc gene encodes a transmembrane protein that in Drosophila acts in opposition to the Hedgehog signaling protein, controlling cell fates, patterning, and growth in numerous tissues. The human PTC gene appears to be crucial for proper embryonic development and for tumor suppression.

Stratum corneum lipids in disorders of cornification. Steroid sulfatase and cholesterol sulfate in normal desquamation and the pathogenesis of recessive X-linked ichthyosis.

The pathological scaling in recessive x-linked ichthyosis is associated with accumulation of abnormal quantities of cholesterol sulfate in stratum corneum (J. Clin. Invest. 68:1404-1410, 1981). To determine whether or not cholesterol sulfate accumulates in recessive x-linked ichthyosis as a direct result of the missing enzyme, steroid sulfatase, we quantitated both steroid sulfatase and its substrate, we quantitated both steroid sulfatase and its substrate, cholesterol sulfate, in different epidermal strata, as well as within stratum corneum subcellular fractions obtained from normal human and neonatal mouse epidermis and from patients with recessive x-linked ichthyosis. In normal human and mouse epidermis, steroid sulfatase activity peaked in the stratum granulosum and stratum corneum, and negligible activity was detectable in lower epidermal layers. In contrast, in recessive x-linked ichthyosis epidermis, enzyme levels were virtually undetectable at all levels. In normal human stratum corneum, up to 10 times more steroid sulfatase activity was present in purified peripheral membrane preparations than in the whole tissue. Whereas in normal human epidermis cholesterol sulfate levels were lowest in the basal/spinous layer, and highest in the stratum granulosum, in recessive x-linked ichthyosis the levels were only slightly higher in the lower epidermis, but continued to climb in the stratum corneum. In both normal and in recessive x-linked ichthyosis stratum corneum, cholesterol sulfate appeared primarily within membrane domains, paralleling the pattern of steroid sulfatase localization. Finally, the role of excess cholesterol sulfate in the pathogenesis of recessive x-linked ichthyosis was directly tested by topical applications of this substance, which produced visible scaling in hairless mice in parallel to an increased cholesterol sulfate content of the stratum corneum. These results demonstrate an intimate relationship between steroid sulfatase and cholesterol sulfate in normal epidermis: both are concentrated in the outer epidermis (stratum corneum and stratum granulosum), and both are localized to membrane domains. Presumably, as a result of this distribution pattern, continued enzymatic degradation of substrate occurs in normal epidermis, thereby preventing excessive accumulation of cholesterol sulfate. In contrast, in recessive x-linked ichthyosis, degradation of cholesterol sulfate does not occur and cholesterol sulfate accumulates specifically in the stratum corneum, where it produces visible scale.

Detection of carriers for X-linked ichthyosis by Southern blot analysis and identification of one family with a de novo mutation.

Scaling in patients with recessive X-linked ichthyosis is caused by lack of activity of the enzyme steroid sulfatase. In approximately 90% of kindreds, this lack is the result of a DNA deletion large enough to eliminate the coding region completely. We have used Southern blot hybridization of DNA isolated from peripheral blood leukocytes to measure gene dosage of the steroid sulfatase gene. This readily detects a half-normal dosage in women who are carriers and therefore can be used to diagnose the carrier status of female relatives of 90% of patients with the disease. We have found one family in whom the deletion arose on an allele inherited from the proband's clinically normal maternal grandfather.

Glucocorticoid receptors of normal human epidermis.

Epidermal cytosol of adult humans can bind dexamethasone, and this binding resembles that by glucocorticoid receptors of other tissues as judged by 4 criteria: affinity of binding, specificity of binding, molecular size of receptor-steroid complexes, and ability of these complexes to bind to nuclei. For demonstration of these receptors, epidermis can be separated by trypsinization but only after preliminary incubation of the skin with molybdate ion, which prevents inactivation of receptors when heated to 22 degree C. The presence of these receptors suggest that glucocorticoids may act directly on the epidermis. Five glucocorticoids that are used topically all displaced 3H-dexamethasone from the receptor in vitro but the affinity of this binding correlates imperfectly with the potency of the steroids when used in vivo.

Biochemical identification of alpha-fodrin and protein 4.1 in human keratinocytes.

The mature erythrocyte has a cytoskeleton of less complexity than that of nucleated cells and has been elucidated in greater detail. Two of its major components are the heterodimeric protein spectrin and protein 4.1. We report here our isolation from human keratinocytes of immunoreactive forms of both protein 4.1 and of alpha-fodrin, the extra-erythrocytic form of alpha-spectrin. These keratinocyte proteins are approximately 125 kD and 240 kD in size, respectively. We also have isolated clones containing alpha-fodrin and protein 4.1 sequences from a human keratinocyte cDNA library. These sequences confirm the active transcription in keratinocytes of the alpha-fodrin and protein 4.1 genes. Both alpha-fodrin and protein 4.1 mRNA are detectable by Northern blot analysis in human keratinocytes, where their abundance appears not to be regulated by calcium concentration in the medium.

Cholesterol sulfotransferase of newborn mouse epidermis.

Recent studies of the epidermis in patients with recessive X-linked ichthyosis indicate that cholesterol sulfate is an important endogenous substrate for steroid sulfatase in the stratum corneum. We report here that cholesterol sulfotransferase, which converts cholesterol to cholesterol sulfate, is present in the lower living epidermis. Epidermal cytosol also sulfates phenols and some steroids, and such reactions may be important in defending against compounds absorbed percutaneously and in modulating the pharmacologic activity of topical medicaments. Sodium salicylate and sodium citrate inhibit the sulfotransferase activity noncompetitively, and inhibition of cholesterol sulfate formation may be important in the desquamative action of these topical "keratolytics."

Partial dominance of a keratin 14 mutation in epidermolysis bullosa simplex--increased severity of disease in a homozygote.

Epidermolysis bullosa simplex is a disease in which keratin gene mutations cause the production of defective intermediate filaments, which leads in turn to epidermal basal cell fragility and blistering. The inheritance in nearly all kindreds is autosomal dominant, most kindreds have missense mutations, and the encoded proteins appear to exert a dominant negative function. One previously reported patient with generalized blistering had a fully dominant mutation of keratin 5; in that kindred a homozygote was affected no more severely than the heterozygotes. By contrast we report here a keratin 14 mutation that causes blistering limited to the hands and feet in heterozygotes, but homozygotes have more severe, widespread blistering of the skin and mucous membranes. Thus keratin gene mutations may be not only fully recessive or fully dominant but also partially dominant as well.

Keratin 14 gene mutations in patients with epidermolysis bullosa simplex.

Mutations in genes encoding the keratin intermediate filaments expressed in basal cells have been identified in some families with epidermolysis bullosa simplex as the proximate cause of the fragility. We have systematically scanned genomic sequences of one of these keratins, keratin 14, for mutations in patients from 49 apparently independent kindreds using single-strand conformation polymorphism analysis. The ten mutations identified are clustered at three sites--the ends of the helices and the L12 linker region, mutation sites that have been identified in past, more limited studies. Early onset of blistering in these ten families is correlated with more widespread distribution of lesions.

Hailey-Hailey disease is not allelic to Darier's disease.

Hailey-Hailey (Familial Benign Chronic Pemphigus) Disease is a rare autosomal dominant disorder characterized by blisters caused by suprabasal epidermal acantholysis. Another autosomal dominant skin disease, Darier's disease, has clinical and histologic features which overlap those of Hailey-Hailey disease and recently has been mapped to chromosome 12q23-q24.1. We have used linkage analysis to test whether or not a mutation in this region might also underlie Hailey-Hailey disease. This analysis, using polymorphic loci tightly linked to Darier's disease, excluded this region as the site for the disease-causing mutation in two kindreds affected with Hailey-Hailey disease.

Mutations of keratin 9 in two families with palmoplantar epidermolytic hyperkeratosis.

The hereditary palmoplantar keratodermas are a heterogeneous group of diseases unified by thickening of the stratum corneum of the palms and soles with consequent painful fissuring, discomfort on pressure, and resultant disability. One of the histologic patterns underlying palmoplantar hyperkeratosis is that of epidermolytic hyperkeratosis. Because that histologic pattern has been found in its generalized form to be due to keratin gene mutations, we assessed the inheritance of the form localized to the palms and soles. In each of two families studied, the mutant gene causing the disease is linked strongly to the chromosome 17 cluster of genes encoding type I keratins, and mutations are present in the conserved helix initiation region of keratin 9 in affected members of both kindreds. These data, as well as those generated recently by others, indicate that keratin gene mutations may underlie not only the generalized phenotype but also this more localized phenotype of epidermolytic hyperkeratosis and suggest one mechanism by which skin diseases can achieve their characteristic localization.

Evidence against keratin gene mutations in a family with ichthyosis hystrix Curth-Macklin.

Ichthyosis hystrix Curth-Macklin is a rare autosomal dominant disease characterized clinically by hyperkeratosis and ultrastructurally by disruption of the keratin intermediate filament network of suprabasal keratinocytes. We have used linkage analysis to test whether a keratin gene mutation might underlie this disease. This analysis excluded the keratin gene loci as the sites for the disease-causing mutation in one affected kindred.

Activation of expression of hedgehog target genes in basal cell carcinomas.

Mutations in hedgehog signaling pathway genes, especially PTC1 and SMO, are pivotal to the development of basal cell carcinomas. The study of basal cell carcinoma gene expression not only may elucidate mechanisms by which hedgehog signaling abnormalities produce aberrant tumor cell behavior but also can provide data on in vivo hedgehog target gene control in humans. We have found, in comparison with normal skin, that basal cell carcinomas have increased levels of mRNA for PTC1, GLI1, HIP, WNT2B, and WNT5a; decreased levels of mRNA for c-MYC, c-FOS, and WNT4; and unchanged levels of mRNA for PTC2, GLI2, WNT7B, and BMP2 and 4. These findings suggest that mutations in hedgehog signaling pathway genes may exert both cell autonomous and indirect effects and indicate that basal cell carcinoma tumor cells have a phenotype that at least in some aspects resembles that of epidermal stem cells.

Linkage of the epidermolytic hyperkeratosis phenotype and the region of the type II keratin gene cluster on chromosome 12.

Bullous congenital ichthyosiform erythroderma (epidermolytic hyperkeratosis) is a severe, generalized, lifelong disease of the skin. As in epidermolysis bullosa simplex, intraepidermal blisters and clumping of keratin intermediate filaments are characteristic. We report here linkage of the inheritance of this disease to the region of chromosome 12q containing the genes encoding type II keratins. This suggests that keratin gene mutations may underlie this complex hyperproliferative and hyperkeratotic phenotype.

Identification of mutations in the human PATCHED gene in sporadic basal cell carcinomas and in patients with the basal cell nevus syndrome.

Mutations in PATCHED (PTC), the human homolog of the Drosophila patched gene, have been identified in most exons of the gene in patients with the basal cell nevus syndrome and in sporadic basal cell carcinomas. We have screened the 23 PTC exons for mutations using single strand conformation polymorphism analysis of DNA from 86 basal cell nevus syndrome probands, 26 sporadic basal cell carcinomas, and seven basal cell nevus syndrome-associated basal cell carcinomas. This screen identified mutations located in eight exons in 13 of the basal cell nevus syndrome patients and in three of the tumors. The most common mutations were frameshifts resulting in premature chain termination. These results provide further evidence for the crucial role of PTC as a tumor suppressor in human keratinocytes.

Recessive X-linked ichthyosis: lack of immunologically detectable steroid sulfatase enzyme protein.

Patients with recessive X-linked ichthyosis (RXLI), one hereditary form of scaly skin, lack activity of the enzyme steroid sulfatase in all tissues studied. To investigate the molecular defect underlying the lack of enzyme activity, we prepared antisera against normal enzyme by injecting normal placental microsomal suspensions or partially purified steroid sulfatase into rabbits. Antibody activity was assessed by immunoprecipitation of detergent solubilized steroid sulfatase. In addition, we prepared rabbit antisera against RXLI placental microsomal suspensions. To detect immunologically cross-reactive material in patients' placentas, extracts were studied by immunoblot techniques and by competition with normal enzyme for antibody binding. Patients' extracts did not contain immunoreactive material co-migrating on electrophoresis with purified enzyme nor did they inhibit immunoprecipitation of normal enzyme. Sera from rabbits immunized with RXLI placental microsomes contain no antibodies to normal steroid sulfatase, as judged by their failure to immunoprecipitate normal enzyme or to react with normal steroid sulfatase on immunoblot. Thus the mutation in RXLI appears to reduce steroid sulfatase enzyme protein as well as enzyme activity.

Parental origin of chromosome 9q22.3-q31 lost in basal cell carcinomas from basal cell nevus syndrome patients.

The basal cell nevus syndrome is an autosomal dominant disease, one of the most prominent phenotypic features of which is a large number of cutaneous basal cell carcinomas. The gene whose mutation underlies this disease has been mapped to chromosome 9q22.3-q31, and basal cell carcinomas frequently have allelic losses including this site. We report here that the chromosome 9q22.3-q31 lost in 24 basal cell carcinomas from basal cell nevus syndrome patients was the one predicted by linkage to contain the wild-type gene. Hence these data are compatible with the exception that the product of the basal cell nevus syndrome gene acts as a tumor suppressor.