Modulation of disease severity of dystrophic epidermolysis bullosa by a splice site mutation in combination with a missense mutation in the COL7A1 gene

Dystrophic epidermolysis bullosa (EBD) is a clinically heterogeneous skin disorder, characterized by abnormal anchoring fibrils (AF) and loss of dermal-epidermal adherence. EBD has been linked to the COL7A1 gene at chromosome 3p21 which encodes collagen VII, the major component of the AF. Here we investigated two unrelated EBD families with different clinical phenotypes and novel combinations of recessive and dominant COL7A1 mutations. Both families shared the same recessive heterozygous 14 bp deletion at the exon-intron 115 boundary of the COL7A1 gene. The deletion caused in-frame skipping of exon 115 and the elimination of 29 amino acid residues from the pro-alpha1(VII) polypeptide chain. As a result, procollagen VII was not converted to collagen VII and the C-terminal NC-2 propeptide which is normally removed from the procollagen VII prior to formation of the anchoring fibrils was retained in the skin. All affected individuals also carried missense mutations in exon 73 of COL7A1 which lead to different glycine-to-arginine substitutions in the triple-helical domain of collagen VII. Combination of the deletion mutation with a G2009R substitution resulted in a mild phenotype. In contrast, combination of the deletion with a G2043R substitution led to a severe phenotype. The G2043R substitution was a de novo mutation which alone caused a mild phenotype. Thus, different combinations of dominant and recessive COL7A1 mutations can modulate disease activity of EBD and alter the clinical presentation of the patients.     

A nursing perspective on the interrelationships between theory, research and practice

Recessive dystrophic epidermis bullosa is ultrastructurally characterized by the absence of anchoring fibrils, and genetic analyses have revealed that recessive dystrophic epidermolysis bullosa results from mutations in the type VII collagen gene (COL7A1). The mutations disclosed thus far are largely family specific, with no evidence for mutational hotspot(s). In this study, we report a recurrent premature termination codon mutation detected in two apparently unrelated Italian families in different regions of the country. This mutation, 497insA in exon 4 of COL7A1, was found in combination with two different premature termination codon mutations in these families. Haplotype analysis suggested a shared genetic background in the allele containing the mutation 497insA, suggesting that this genetic lesion may represent an ancestral mutation within the Italian gene pool.     

Novel and de novo glycine substitution mutations in the type VII collagen gene (COL7A1) in dystrophic epidermolysis bullosa: implications for genetic counseling

The dystrophic forms of epidermolysis bullosa (DEB) are due to mutations in the type VII collagen gene (COL7A1). In dominant DEB, a characteristic genetic lesion is a glycine substitution mutation within the collagenous domain of the protein. In this study, we have examined the molecular basis of six new families in which the proband has clinical features and/or ultrastructural findings consistent with DEB. The results revealed a glycine substitution mutation in all six families, four of which are novel and previously unpublished. In three families with clinically unaffected parents, de novo mutations G2043R and G2040V were found. These results emphasize the predominance of glycine substitution mutations in dominant DEB, and indicate that in some cases the phenotype is due to de novo dominant mutations.     

Effects of steady-state versus stochastic exercise on subsequent cycling performance

Mutations in the type VII collagen gene (COL7A1) have been shown to underlie dystrophic epidermolysis bullosa (DEB). The dominantly inherited forms of DEB have been divided into two clinical subcategories, the Pasini (DDEB-P) and the Cockayne-Touraine (DDEB-CT) variants, on the basis of the presence or absence of albopapuloid lesions. In this study, we have examined the molecular basis of DDEB in two Japanese families, one with DDEB-P and the other with DDEB-CT. Mutation detection strategy consisted of polymerase chain reaction amplification of COL7A1 from genomic DNA, followed by heteroduplex analysis and direct nucleotide sequencing. The results revealed heterozygous glycine substitution mutations, G2076D and G2034R, in these families, respectively. Thus, these two variants of DDEB are allelic, and subtle differences in the clinical presentation may reflect the precise position of the mutation along the type VII collagen molecule. Alternatively, the nature of the substituting amino acid (D versus R) may influence the clinical phenotype. This is the first demonstration of a COL7A1 mutation in DDEB-P, and brings the total number of dominant DEB variants with underlying glycine substitutions in COL7A1 to five, including the pretibial and localized variants as well as the Bart's syndrome, in addition to DDEB-P and DDEB-CT.     

Amphotericin B colloidal dispersion combined with flucytosine with or without fluconazole for treatment of murine cryptococcal meningitis

Junctional epidermolysis bullosa is a heritable, heterogeneous blistering skin disease with mechanically induced dermal-epidermal separation, mild skin atrophy, nail dystrophy, and alopecia. Four unrelated junctional epidermolysis bullosa families with different phenotypes were investigated here and four novel mutations associated with the disease were identified. Patients 1, 2, and 3 had generalized atrophic benign epidermolysis bullosa, with nonscarring blistering and varying degree of alopecia. Patient 4 had the localisata variant of junctional epidermolysis bullosa, with predominantly acral blistering and normal hair. All patients had mutations in the COL17A1 gene encoding collagen XVII, a hemidesmosomal transmembrane protein. Patients 1 and 2 carried homozygous deletions 520delAG and 2965delG, respectively. Patient 3 was compound heterozygous for a missense and a deletion mutation (G539E and 2666delTT), and patient 4 was heterozygous for a known mutation R1226X. The deletions led to premature termination codons and to drastically reduced collagen XVII mRNA and protein levels, consistent with the absence of the collagen in generalized atrophic benign epidermolysis bullosa skin. The missense mutation G539E allowed synthesis of immunoreactive collagen XVII in keratinocytes, but prevented its secretion, thus causing lack of the protein in the skin. The data suggest that different COL17A1 mutations and their combinations can result in a spectrum of biologic and clinical phenotypes of not only generalized atrophic benign epidermolysis bullosa, but also localized junctional epidermolysis bullosa.     

Mutations in the COL1A2 gene of type I collagen that result in nonlethal forms of osteogenesis imperfecta

Although virtually all mutations that result in osteogenesis imperfecta (OI) affect the genes that encode the chains of type I procollagen, the effects of mutations in the COL1A2 gene have received less attention than those in the COL1A1 gene. We have characterized mutations in 4 families that give rise to different OI phenotypes. In three families substitutions of glycine residues by cysteine in the triple helical domain (a single example at position 259 and 2 families in which substitution of glycine at 646 by cysteine) have been identified, and in the fourth a G for A transition at position +4 in intron 33 led to use of an alternative splice site and inclusion of 6 amino acids (val-gly-arg-ile-leu-phe) between residues 585 and 586 of the normal triple helix. The relation between position of substitution of glycine by cysteine in the COL1A2 gene does not follow the pattern developed in the COL1A1 gene. To determine how COL1A2 mutations produce OI phenotypes, we have produced a full-length mouse cDNA into which we plan to place mutations and examine their effects in stably transfected osteogenic cells and in transgenic animals.     

Deletions within COL7A1 exons distant from consensus splice sites alter splicing and produce shortened polypeptides in dominant dystrophic epidermolysis bullosa

We describe two familial cases of dominant dystrophic epidermolysis bullosa (DDEB) that are heterozygous for deletions in COL7A1 that alter splicing, despite intact consensus splice-site sequences. One patient shows a 28-bp genomic deletion (6081del28) in exon 73 associated with the activation of a cryptic donor splice site within this exon; the combination of both defects restores the phase and replaces the last 11 Gly-X-Y repeats of exon 73 by a noncollagenous sequence, Glu-Ser-Leu. The second patient demonstrates a 27-bp deletion in exon 87 (6847del27), causing in-frame skipping of this exon; consensus splice sites, putative branch sites, and introns flanking exons 73 and 87 showed a normal sequence. Keratinocytes from the probands synthesized normal and shortened type VII collagen polypeptides and showed intracellular accumulation of type VII procollagen molecules. This first report of genomic deletions in COL7A1 in DDEB suggests a role for exonic sequences in the control of splicing of COL7A1 pre-mRNA and provides evidence that shortened type VII collagen polypeptides can alter, in a dominant manner, anchoring-fibril formation and can cause DDEB of differing severity.     

Assessment of insulin action in NIDDM in the presence of dynamic changes in insulin and glucose concentration

The generalized mutilating form of recessive dystrophic epidermolysis bullosa (i.e., the Hallopeau-Siemens type; HS-RDEB) is a life-threatening disease characterized by extreme mucocutaneous fragility associated with absent or markedly altered anchoring fibrils (AF). Recently, we reported linkage between HS-RDEB and the type VII collagen gene (COL7A1), which encodes the major component of AF. In this study, we investigated 52 unrelated HS-RDEB patients and 2 patients with RDEB inversa for the presence, at CpG dinucleotides, of mutations changing CGA arginine codons to premature stop codons TGA within the COL7A1 gene. Eight exons containing 10 CGA codons located in the amino-terminal domain of the COL7A1 gene were studied. Mutation analysis was performed using denaturing gradient gel electrophoresis of PCR-amplified genomic fragments. Direct sequencing of PCR-amplified products with altered electrophoretic mobility led to the characterization of three premature stop codons, each in a single COL7A1 allele, in four patients. Two patients (one affected with HS-RDEB and the other with RDEB inversa) have the same C-to-T transition at arginine codon 109. Two other HS-RDEB patients have a C-to-T transition at arginine 1213 and 1216, respectively. These nonsense mutations predict the truncation of approximately 56%-92% of the polypeptide, including the collagenous and the noncollagenous NC-2 domains. On the basis of linkage analysis, which showed no evidence for locus heterogeneity in RDEB, it is expected that these patients are compound heterozygotes and have additional mutations on the other COL7A1 allele, leading to impaired AF formation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of a glycine substitution and a splice site mutation in the type VII collagen gene in a proband with mitis recessive dystrophic epidermolysis bullosa

Dystrophic epidermolysis bullosa (DEB) is a genodermatosis characterized by fragility of the skin and mucous membranes. Underlying mutations in the DEB phenotype have been detected in the gene encoding type VII collagen (COL7A1), both in the dominant and recessive forms of DEB. In this study, we searched for mutations in a proband with a mild form of DEB by PCR amplification of segments of COL7A1, followed by heteroduplex analysis. Examination of PCR fragments corresponding to exons 3-4 and exons 51-53 revealed heteroduplexes. Direct sequencing of the PCR fragment containing exon 3 revealed a previously reported A-to-G transition in the 5' donor splice site of exon 3 in the proband and in the clinically unaffected father, while direct sequencing of the PCR fragment containing exon 53 revealed a novel glycine substitution G1652R in the proband and in the clinically unaffected mother. Patients with relatively mild DEB and no family history are frequently diagnosed as a de novo case of dominant DEB, although a mild case of RDEB cannot be excluded on the basis of clinical and ultrastructural examination. We proved this case to be a recessively inherited disease. This information had a profound impact on the genetic counselling, because if the disease of the patient were to have had a new dominant mutation, he would have been counselled that the risk of his offspring being affected was one in two, but he could be accurately counselled that the risk of this offspring being affected was as low as the general population.     

Lack of resistance to erythromycin, rifampicin and ciprofloxacin in 98 clinical isolates of Legionella pneumophila

Epidermolysis bullosa simplex Dowling-Meara (MIM# 1317600) is the most severe of the three common epidermolysis bullosa simplex subtypes. In addition to the palmoplantar distribution seen in other epidermolysis bullosa simplex subtypes, extensive herpetiform blistering spontaneously develops on the trunk and limbs and may lead to scarring or milia formation. The keratin 5 and keratin 14 genes encode proteins that form the primary structural components of the basal epidermal keratinocytes, mutations in either of these genes can cause epidermolysis bullosa simplex. In this study we sequenced these genes in a family with epidermolysis bullosa simplex Dowling-Meara. We report a novel T to C transition in the helix termination peptide of K5 that causes a nonconservative substitution of a highly conserved amino acid within this critical region (I466T). This mutation adds to those previously reported and provides further evidence of phenotype-genotype correlation in epidermolysis bullosa simplex.     

Tetravinyl-tetramethylcyclo-tetrasiloxane (tetravinyl D4) is a mutagen in Rat2lambda lacI fibroblasts

We describe a patient with sporadic dystrophic epidermolysis bullosa associated with well-documented atopic dermatitis. We discuss this case in relation to a newly described clinical subtype of epidermolysis bullosa known as epidermolysis bullosa pruriginosa, a dystrophic variant associated with prominent pruritus. The relations of this case of sporadic dystrophic epidermolysis bullosa with other dominantly inherited forms of dystrophic epidermolysis bullosa such as the Pasini variant, the pretibial variant, and Bart's syndrome are also discussed. The role of atopic dermatitis in exacerbating dystrophic epidermolysis bullosa in this patient raises an important consideration in the care of this group of patients.     

Outcome of neonatal stroke in full-term infants without significant birth asphyxia

Ehlers-Danlos syndrome (EDS) is a heterogeneous group of connective tissue disorders. Recently mutations have been found in the genes for type V collagen in a small number of people with the most common forms of EDS, types I and II. Here we characterise a COL5A2 mutation in an EDS II family. Cultured dermal fibroblasts obtained from an affected subject synthesised abnormal type V collagen. Haplotype analysis excluded COL5A1 but was concordant with COL5A2 as the disease locus. The entire open reading frame of the COL5A2 cDNA was directly sequenced and a single base mutation detected. It substituted a glycine residue within the triple helical domain (G934R) of alpha2(V) collagen, typical of the dominant negative changes in other collagens, which cause various other inherited connective tissue disorders. All three affected family members possessed the single base change, which was absent in 50 normal chromosomes.     

Control of G1 in the developing Drosophila eye: rca1 regulates Cyclin A

Ehlers-Danlos syndrome (EDS) type VII results from defects in the conversion of type I procollagen to collagen as a consequence of mutations in the substrate that alter the protease cleavage site (EDS type VIIA and VIIB) or in the protease itself (EDS type VIIC). We identified seven additional families in which EDS type VII is either dominantly inherited (one family with EDS type VIIB) or due to new dominant mutations (one family with EDS type VIIA and five families with EDS type VIIB). In six families, the mutations alter the consensus splice junctions, and, in the seventh family, the exon is deleted entirely. The COL1A1 mutation produced the most severe phenotypic effects, whereas those in the COL1A2 gene, regardless of the location or effect, produced congenital hip dislocation and other joint instability that was sometimes very marked. Fractures are seen in some people with EDS type VII, consistent with alterations in mineral deposition on collagen fibrils in bony tissues. These new findings expand the array of mutations known to cause EDS type VII and provide insight into genotype/phenotype relationships in these genes.     

Cultured keratinocyte allografts and wound healing in severe recessive dystrophic epidermolysis bullosa

BACKGROUND: Patients with recessive dystrophic epidermolysis bullosa (RDEB) frequently have painful erosions that are slow to heal. There is no definitive treatment; therefore any therapy that improves wound healing would be beneficial to these patients. OBJECTIVE: Our purpose was to assess the effects of cultured allogeneic keratinocytes on wound healing in RDEB. METHODS: Ten patients with RDEB and dermatome-induced superficial dermal wounds were studied. Cultured keratinocyte grafts were applied to part of the wound, with another part left ungrafted. Both sites were assessed clinically and microscopically, particularly with regard to basement membrane zone reconstitution. RESULTS: Apart from minor differences in keratinocyte differentiation and a moderate analgesic effect induced by the graft, there were no other distinguishing findings in wound healing in the grafted and nongrafted sites. CONCLUSION: There was little clinical benefit from cultured keratinocyte allografts in wound healing in RDEB. However, this study showed that RDEB keratinocytes have an inherent capacity to express some type VII collagen epitopes transiently during wound healing, although this was not associated with the detection of anchoring fibrils.     

Novel K5 and K14 mutations in German patients with the Weber-Cockayne variant of epidermolysis bullosa simplex

We report novel keratin 5 and 14 gene mutations in four unrelated German families with the localized subtype of the dominantly inherited blistering disease epidermolysis bullosa simplex Weber-Cockayne (MIM# 131800). The mutations are located in the keratin 14 L12 linker region (D273G), the keratin 5 L12 linker (M327K and D328H), and the H1 domain of keratin 5 (P156L). These mutations add to those previously reported and provide further evidence of phenotype-genotype correlations in epidermolysis bullosa simplex subtypes. The above mutations in mildly affected patients underline the relevance of the keratin linker regions for the epidermolysis bullosa simplex Weber-Cockayne phenotype and keratin filament integrity. In addition, they confirm that the gene segments encoding the linker regions represent hotspots for mutations.     

The C-propeptide domain of procollagen can be replaced with a transmembrane domain without affecting trimer formation or collagen triple helix folding during biosynthesis

The folding and assembly of procollagen occurs within the cell through a series of discrete steps leading to the formation of a stable trimer consisting of three distinct domains: the N-propeptide, the C-propeptide and the collagen triple helix flanked at either end by short telopeptides. We have established a semi-permeabilized cell system which allows us to study the initial stages in the folding and assembly of procollagen as they would occur in the intact cell. By studying the folding and assembly of the C-propeptide domain in isolation, and a procollagen molecule which lacks the C-propeptide, we have shown that this domain directs the initial association event and is required to allow triple helix formation. However, the essential function of this domain does not include triple helix nucleation or alignment, since this can occur when the C-propeptide is substituted with a single transmembrane domain. Also the telopeptide region is not involved in triple helix nucleation; however, a minimum of two hydroxyproline-containing Gly-X-Y triplets at the C-terminal end of the triple helix are required for nucleation to occur. Thus, the C-propeptide is required solely to ensure association of the monomeric chains; once these are brought together, the triple helix is able to nucleate and fold to form a correctly aligned triple helix.     

A cDNA cassette system for the synthesis of recombinant procollagens. Variants of procollagen II lacking a D-period are secreted as triple-helical monomers

Currently there is a lack of experimental systems for defining the functional domains of the fibrillar collagens. Here we describe an experimental strategy that employs the polymerase chain reaction (PCR) to create a series of cDNA cassettes coding for seven separate domains of procollagen II. The system was used to prepare novel recombinant procollagens II from which one of the four repetitive D-periods of the triple helix was deleted. Four constructs, each lacking a different D-period, were expressed in stably transfected mammalian cells (HT-1080). Truncated procollagens of the predicted size were recovered from the medium. All were triple-helical as assayed by circular dichroism. Therefore, deletion of a complete D-period containing 234 amino acids does not destabilize the triple helix of homotrimeric collagen II as much as some naturally occurring mutations in the heterotrimeric monomer of collagen I that delete shorter sequences or that convert obligate glycine residues to residues with bulkier side chains. Moreover, the results suggest that the strategy developed here can be used to map in detail the binding sites on fibrillar collagens for other components of the extracellular matrix and for the binding, spreading and signaling of cells.