A founder synonymous COL7A1 mutation in three Danish families with dominant dystrophic epidermolysis bullosa pruriginosa identifies exonic regulatory sequences required for exon 87 splicing

Dystrophic epidermolysis bullosa pruriginosa (DEB-Pr) (OMIM 604129) represents a distinct variant within the DEB clinical spectrum. It is characterized by intense pruritus and distinctive nodular prurigo-like and/or hypertrophic lichenoid lesions mainly localized on the arms, legs and upper shoulders. DEB-Pr is caused by either dominant (DDEB-Pr) or recessive mutations in the COL7A1 gene encoding type VII collagen (COLVII). The full spectrum of COL7A1 mutations in DEB-Pr remains elusive and the genotype-phenotype correlation is largely incomplete. Here, we report and functionally characterize a previously unrecognized translationally silent exonic COL7A1 mutation that results in skipping of exon 87 and is associated with DDEB-Pr phenotypes in several members of three apparently unrelated Danish families. A haplotype segregation study suggested a common ancestor in these kindred. Functional splicing analysis of the mutant exon by a COL7A1 minigene construct and computational prediction for splicing regulatory cis-sequences prove that the mutation alters the activity of an exonic splicing enhancer (ESE) critical for exon inclusion. These findings substantiate for the first time the involvement of an ESE mutation in the pathogenesis of DEB and have implications for genetic counselling of Danish families with DDEB.     

Mutation analysis and characterization of COL7A1 mutations in dystrophic epidermolysis bullosa

Abstract:  Dystrophic epidermolysis bullosa (DEB) is inherited in both an autosomal dominant DEB and autosomal recessive manner RDEB, both of which result from mutations in the type VII collagen gene ( COL7A1 ). To date, 324 pathogenic mutations have been detected within COL7A1 in different variants of DEB; many mutations are clustered in exon 73 (10.74%) which is close to the 39 amino acid interruption region. Dominant dystrophic epidermolysis bullosa usually involves glycine substitutions within the triple helix of COL7A1 although other missense mutations, deletions or splice-site mutations may underlie some cases. In recessive dystrophic epidermolysis bullosa, the mutations include nonsense, splice site, deletions or insertions, 'silent' glycine substitutions within the triple helix and non-glycine missense mutations within the triple helix or non-collagenous NC-2 domain. The nature of mutations in COL7A1 and their positions correlate reasonably logically with the severity of the resulting phenotypes.     

Dystrophic epidermolysis bullosa pruriginosa is not associated with frequent FLG gene mutations

Background  Dystrophic epidermolysis bullosa pruriginosa (DEB-Pr; OMIM 604129) is a rare manifestation of dystrophic epidermolysis bullosa (DEB), characterized by pruritus, nodular prurigo-like lesions and fragility of the skin mainly in the extremities. Fewer than 40 patients with autosomal dominant or recessive inheritance, or sporadic DEB-Pr, have been described in the literature.
Objectives  To disclose mutations in DEB-Pr and to elucidate the role of other pathogenic factors which may influence the pruriginous phenotype.
Methods  Seven patients with typical clinical features of DEB-Pr were studied.
Results  In all patients, mutations in the gene encoding collagen VII ( COL7A1 ) were disclosed, two of them novel (p.G2623V, p.E2736K). Three mutations were dominant, three recessive and one de novo . In the families with dominant DEB there were one or more members with DEB-Pr, but also at least one affected sibling who did not develop DEB-Pr. In six of seven patients, the clinical history revealed factors that initially induced pruritus, such as atopy, pregnancy, thyroid hormone imbalance, diabetes, infections and contact sensitization. Common filaggrin mutations were ruled out in all patients and normal filaggrin staining was found in the skin samples.
Conclusions  DEB-Pr develops as a result of COL7A1 gene mutations and acquired phenotype-modifying factors. Filaggrin mutations did not contribute to the pruriginous phenotype in the present patient cohort.     

A glycine substitution in the COL7A1 gene causes mild RDEB in a Pakistani family

Pathogenic glycine substitutions can cause destabilization of the triple helix and a diverse range of heritable connective tissue disorders, dependent on the collagen gene in which the mutation occurs. Mutations in the type VII collagen gene (COL7A1) cause an inherited mechanobullous skin disease known as dystrophic epidermolysis bullosa (DEB). Typically, the dominant forms (DDEB) result from glycine substitutions within COL7A1, whereas other glycine mutations are 'silent' in the heterozygous state and produce disease only when they are homozygous. We studied three affected individuals from a large inbred Pakistani family with a history of skin fragility and scarring indicative of dystrophic EB. We identified a new glycine substitution within the collagenous region in exon 94 of the COL7A1 gene. This mutation, designated G2422V, resulted in a glycine (GGA) to valine (GTA) substitution presumably causing a destabilization of the protein by interrupting the Gly-X-Y repeats. This finding expands the allelic series of COL7A1 mutations underlying mild recessive dystrophic epidermolysis bullosa (RDEB) and sheds further light upon regions of the type VII collagen triple helix that are tolerant of heterozygous glycine substitutions.     

A recurrent glycine substitution mutation, G2043R, in the type VII collagen gene (COL7A1) in dominant dystrophic epidermolysis bullosa

Dystrophic epidermolysis bullosa (DEB) is caused by mutations in the type VII collagen gene (COL7A1). Nearly all cases of dominant DEB are caused by glycine substitution mutations occurring within the triple helical region of type VII collagen, and most of the mutations are unique to individual families. In this study, we identified a patient of Hispanic-Mexican origin with a mild form of DEB, which resulted from a de novo dominant glycine substitution, G2043R, in exon 73 of COL7A1. We also investigated a Scottish family with a three-generation pedigree of dominant DEB, in whom the same glycine to arginine substitution mutation was demonstrated. This particular mutation has also been detected previously in three other families with dominant DEB: one Italian, one Hungarian and one Norwegian. Given the widespread geographical distribution of this mutation and the demonstration of its occurrence as a de novo event, G2043R therefore represents the first example of a mutational hotspot in dominant DEB. Interestingly, although both the Mexican and Scottish families we studied had some clinical features in keeping with the Pasini form of the disorder, there was considerable interfamilial variability as well as intrafamilial diversity in the affected individuals.     

Review of collagen VII sequence variants found in Australasian patients with dystrophic epidermolysis bullosa reveals nine novel COL7A1 variants

BACKGROUND: Dystrophic epidermolysis bullosa (DEB) is an inherited skin fragility disorder where blistering occurs in the sub-lamina densa zone at the level of anchoring fibrils (AFs) of the dermo-epidermal junction. Both autosomal dominant (DDEB) and recessive (RDEB) result from mutations in the type VII collagen gene (COL7A1). OBJECTIVE: The purpose of this study was to understand the genotype-phenotype correlation in Australian patients with DEB. METHODS: Skin biopsies from patients were processed for immunofluorescence mapping, the COL7A1 gene was screened for sequence variants. RESULTS: We report 14 Australian families with different forms of dystrophic epidermolysis bullosa (DEB) with 23 different COL7A1 allelic variants, nine of which were novel. Four cases of RDEB-HS combined two premature termination codon (PTC) variants and three other cases of RDEB-HS with combined PTC and spice-site or glycine substitution variants. G2043R, a de novo dominant variant, was also identified in this study. Four "silent" glycine substitutions were found in this study, G2775S, G1673R, G1338V and G2719A. EB17, with combined R2791W and G2210V variants, had a DDEB-Pasini phenotype, in contrast to two family members who had severe DDEB pruriginosa, with the same genotype. CONCLUSION: In this study, the RDEB variants included nonsense variants, splice site variants, internal deletions or insertions, "silent" glycine substitutions within the triple helix or N or C terminal ends of the triple helix and non-glycine missense variants within the triple helix domain. DDEB usually involves glycine substitutions within the triple helix of COL7A1 although other missense variants or splice-site alterations may underlie some cases.     

Exon 87 skipping of the COL7A1 gene in dominant dystrophic epidermolysis bullosa

Dystrophic epidermolysis bullosa (DEB) is a rare, inherited, blistering disorder resulting from mutations in the COL7A1 gene, which encodes the anchoring fibrils, type VII collagen. We herein describe a further Japanese girl diagnosed with dominant DEB (DDEB). She had blisters sporadically and erosions healed with mild scarring and milia on the knees and pretibial regions. Severe pruritus was present at this time. Direct nucleotide sequencing of genomic DNA disclosed a heterozygous same splice-site mutation c.6900G>A in the COL7A1, which causes in-frame exon 87 skipping. So far, five different COL7A1 mutations leading to exon 87 skipping have been identified in rare forms of DEB: four DDEB pruriginosa and one pretibial DDEB. Therefore, a recent study suggested that exon 87 skipping in COL7A1 was related to the phenotype of DDEB pruriginosa. When she was 18 years old, however, the blister formation and pruritus markedly decreased. Therefore, her clinical symptoms were consistent to very mild DDEB but not to DDEB pruriginosa. Taken together, in-frame exon 87 skipping through c.6900G>A mutation may account for the mild skin features, rather than DDEB pruriginosa, in the present case.     

A new glycine substitution mutation in the COL7A1 gene in a Chinese family with dominant dystrophic epidermolysis bullosa

Dystrophic epidermolysis bullosa (DEB) is caused by mutations in the COL7A1 gene encoding type VII collagen, the major component of anchoring fibrils. The characteristic genetic lesion in dominant DEB (DDEB) is a glycine substitution in the collagenous domain of the protein. In this study, we identified a Chinese family with a four-generation pedigree of DDEB, in whom a novel glycine substitution mutation in COL7A1 was demonstrated. A heterozygous nucleotide G-->A transition at position 6208 in exon 74 of COL7A1 was detected, which resulted in a glycine to arginine substitution (G2070R) in the triple-helical domain of type VII collagen. This substitution was not found in 110 unrelated normal alleles. This report emphasizes the predominance of glycine substitution mutations in DDEB and contributes to the expanding database on COL7A1 mutations.     

Identical glycine substitution mutations in type VII collagen may underlie both dominant and recessive forms of dystrophic epidermolysis bullosa

Autosomal dominant and recessive forms of dystrophic epidermolysis bullosa (DEB) result from mutations in the type VII collagen gene (COL7A1). Although paradigms have emerged for genotype/phenotype correlation in DEB, some pathogenic mutations in COL7A1, notably glycine substitutions within the type VII collagen triple helix, may lead to diagnostic difficulties, since certain glycine substitutions can result in either dominant or recessive mutant alleles. Delineation of glycine substitution mutations into two discrete groups, however, is made difficult by observations that, for some particular glycine substitutions in type VII collagen, the same mutation can result in both dominant and recessive disease. In this report we describe four further glycine missense mutations: p.Gly1483Asp, p.Gly1770Ser, p.Gly2213Arg and p.Gly2369Ser, which can lead to either dominant or recessive DEB, and which result in a spectrum of clinical abnormalities. We also identify a further 30 new glycine substitution mutations that cause either dominant or recessive DEB, but not both. In screening the COL7A1 gene for mutations in individuals with DEB our data highlight that delineation of glycine substitutions in type VII collagen has important implications for genetic counselling.     

The molecular basis of dystrophic epidermolysis bullosa in Mexico

BACKGROUND: Type VII collagen gene (COL7A1) mutations are the cause of dystrophic epidermolysis bullosa (DEB), but most mutations are specific to individual families, and there are limited data on the nature of COL7A1 mutations in certain ethnic populations. OBJECTIVE: To determine the molecular basis of DEB in Hispanic Mexican patients. METHODS: Patients were recruited through a newly established support group, Fundacion DEBRA Mexico. Molecular analysis was performed by polymerase chain reaction (PCR) of genomic DNA using COL7A1-specific primers, heteroduplex analysis, and direct nucleotide sequencing. RESULTS: Fifty-nine of a possible 67 COL7A1 mutations (88%) were identified in 36 affected individuals (31 recessive, five dominant) in 21 families. Recessive mutations included six frameshift mutations, four silent glycine substitutions, and two splice-site mutations. Dominant mutations comprised a de novo glycine substitution and an internal deletion. Conclusions This study establishes the molecular basis of DEB in a group of Mexican patients. Only two of the mutations have been identified previously in other ethnic groups; the remainder are specific to this population. These new data are helpful in facilitating the accurate diagnosis of DEB subtype, in improving genetic counseling, and in providing further insight into the pathophysiology of this mechanobullous disease.     

A de novo glycine substitution mutation in the collagenous domain of COL7A1 in dominant dystrophic epidermolysis bullosa

Abstract Dystrophic epidermolysis bullosa (DEB) is a hereditary mechanobullous disorder characterized by fragility of the skin and mucous membrane due to abnormalities of anchoring fibrils. Both dominant and recessive DEB have been shown to be caused by mutations in COL7A1, the gene encoding type VII collagen which is the major component of anchoring fibrils. De novo mutation in dominant DEB is rare. In this study, we report a novel de novo glycine substitution mutation in COL7A1 in a Chinese female patient presenting with mild DEB. In search of the mutation, we scanned the entire COL7A1 using polymerase chain reaction (PCR) amplification of all exons of COL7A1, followed by heteroduplex analysis and direct sequencing of the PCR products that exhibited heteroduplex pattern. A G-to-A transition at nucleotide position 6082 within exon 73 of COL7A1was detected. The mutation converted a glycine to an arginine (G2028R) within the triple-helical domain of type VII collagen. It was confirmed that the mutation was present only in the proband. Haplotype analyses suggested that the case arose as a de novo occurrence of autosomal dominant DEB. Received: 1 September 1998 / Revised: 23 November 1999 / Accepted: 26 November 1999     

The G2028R glycine substitution mutation in COL7A1 leads to marked inter-familiar clinical heterogeneity in dominant dystrophic epidermolysis bullosa

BACKGROUND: Glycine substitution mutations in COL7A1 not only cause dominant dystrophic epidermolysis bullosa (DDEB), but can also be silent mutations which lead to recessive dystrophic epidermolysis bullosa (RDEB) in combination with additional mutations in the other allele. OBJECTIVE: In this study, we have examined a large American Caucasian pedigree in which 10 family members from four generations presented with simple toenail dystrophy without skin fragility in autosomal dominant manner. METHOD: We sequenced COL7A1 of this pedigree. RESULTS: Mutational analysis indeed detected a heterozygous G-to-A transition at nucleotide position 6082 leading to G2028R in all the affected members. Surprisingly, mutation database revealed that this G2028R mutation had been previously identified in two distinct Asian families with DDEB showing apparent skin fragility and blister formation. One case was a 17-month-old Chinese female with classical phenotype of DDEB and the other was a 27-year-old Japanese female with typical epidermolysis bullosa (EB) pruriginosa. To better understand the molecular mechanisms of this marked inter-familiar clinical heterogeneity, we examined the entire sequence of all the exons and exon-intron borders as well as the promoter region of COL7A1 in all the three families. Sequence results demonstrated no significant nucleotide difference in COL7A1 among the three pedigrees. CONCLUSION: This paper has demonstrated for the first time that identical COL7A1 glycine substitutions can cause remarkably heterogeneous clinical phenotypes extending from simple toe nail dystrophy without skin fragility to typical DDEB and EB pruriginosa. In addition, the fact of inter-familiar, not intra-familiar clinical heterogeneity associated with G2028R suggest that the other molecular mechanisms not controlled by COL7A1 coding sequence might be responsible for the clinical heterogeneity.     

A novel splice site mutation in collagen type VII gene in a Chinese family with dominant dystrophic epidermolysis bullosa pruriginosa

Dystrophic epidermolysis bullosa pruriginosa, a subtype of epidermolysis bullosa dystrophica and a heterogeneous inherited disease, is characterized by pruritus, excoriated nodular prurigo-like lesions, skin fragility, altered anchoring fibrils and loss of dermal-epidermal adhesion. Mutation in type VII collagen gene (COL7A1) is thought to be implicated in the underlying change for dystrophic epidermolysis bullosa pruriginosa. We report here a large family of dominant dystrophic epidermolysis bullosa pruriginosa. Mutation analysis using polymerase chain reaction and direct sequencing demonstrated a novel nucleotide substitution of 6899A-->G in exon 87 in one COL7A1 allele of the proband and 18 affected family members. This substitution was not found in 100 normal alleles. Polymerase chain reaction and sequencing of the cDNA, reverse transcribed from the proband's peripheral lymphocyte RNA, suggest that this mutation causes aberrant COL7A1 mRNA splicing of exon 87 skipping. Clinical features and pedigree analysis suggest that 6899A-->G substitution is a mutation with full penetrance and variable expressivity.     

Diagnostic dilemma of “sporadic” cases of dystrophic epidermolysis bullosa: a new dominant or mitis recessive mutation?

Abstract: Dystrophic forms of epidermolysis bullosa (DEB), characterized by mutations in the type VII collagen gene (COL7A1), are inherited either in an autosomal dominant or autosomal recessive fashion, and sporadic, de novo cases have also been reported. Clinically, the dominant forms (DDEB) can be indistinguishable from the mild, mitis forms of recessively inherited DEB (M-RDEB). This situation poses a dilemma in case of families with 1 mildly affected individual and clinically normal parents: Is it a new dominant or mitis recessive DEB? In this study we review 2 cases with mild DEB, the parents being clinically normal. One of the cases was shown to be a compound heterozygote for 2 silent missense mutations (R2063W/G2366S), thus being diagnosed as M-RDEB. The second case had a single glycine substitution mutation (G2079E) in COL7A1 and had therefore DDEB. These findings have implications for the genetic counseling of these families concerning the risk of recurrence of the disease in subsequent pregnancies in the present and future generations.     

Glycine substitution mutations by different amino acids in the same codon of COL7A1 lead to heterogeneous clinical phenotypes of dominant dystrophic epidermolysis bullosa

Abstract Dystrophic epidermolysis bullosa (DEB), caused by mutations in the gene encoding type VII collagen (COL7A1), is known to show heterogeneous clinical phenotypes. Certain correlations between the nature or position of COL7A1 mutations and the resultant DEB phenotypes have been suggested, although such relationships may be more complex than initially thought. The purpose of the present study was to clarify the molecular basis of two different subtypes of dominant DEB (DDEB), EB pruriginosa and classical type. Interestingly, we found that both cases were caused by a missense glycine substitution mutation by different amino acids in the same codon of COL7A1 (G2028R and G2028A). These results further support the notion that different glycine substitution mutations in the same codon can lead to heterogeneous clinical phenotypes of DDEB, EB pruriginosa and classical type. Received: 17 December 1999 / Revised: 17 April 2000 / Accepted: 19 June 2000     

Dilemmas in distinguishing between dominant and recessive forms of dystrophic epidermolysis bullosa

BACKGROUND: Dystrophic epidermolysis bullosa (DEB) is a heterogeneous inherited blistering skin disorder. The mode of inheritance may be autosomal dominant or recessive but all forms of DEB result from mutations in the gene encoding the anchoring fibril protein, type VII collagen, COL7A1. Consequently, in spite of careful clinical and skin biopsy examination, it may be difficult to distinguish mild recessive cases from de novo dominant disease in families with clinically normal parents and no other affected siblings; this distinction has significant implications for the accuracy of genetic counselling. OBJECTIVES: To assess whether COL7A1 mutation analysis might help determine mode of inheritance in mild to moderate DEB. METHODS: We performed COL7A1 screening using heteroduplex analysis and direct nucleotide sequencing in four individuals with mild to moderate "sporadic" DEB and clinically unaffected parents. RESULTS: In each patient, we identified a heterozygous glycine substitution within the type VII collagen triple helix. However, in two cases these mutations had been inherited in trans with a non-sense mutation on the other allele (i.e. autosomal recessive DEB). In the other two cases, no additional mutation was identified and neither mutation was present in parental DNA (i.e. de novo dominant disease). CONCLUSIONS: This study highlights the usefulness of DNA sequencing in determining the inherited basis of some sporadic cases of DEB. However, delineation of glycine substitutions should prompt comprehensive COL7A1 gene sequencing in the affected individual, as well as clinical assessment of parents and mutation screening in parental DNA, if the true mode of inheritance is to be established correctly.     

Three cases of de novo dominant dystrophic epidermolysis bullosa associated with the mutation G2043R in COL7A1

In the absence of a positive family history, it is often difficult to determine whether a single case of mild-to-moderately severe dystrophic epidermolysis bullosa (DEB) represents autosomal recessive or de novo dominant disease. Recent molecular analyses of the type VII collagen gene, COL7A1, have established that the vast majority of such cases are recessive in nature. Nevertheless, a small number of de novo dominant patients have been documented. In this report, we describe three further examples of de novo dominant disease. In each case the COL7A1 mutation comprised the same glycine substitution, G2043R. This mutation has previously been reported in both dominant DEB pedigrees and as a de novo phenomenon and is the most common COL7A1 mutation in dominant DEB throughout the world. These cases emphasize the importance of molecular analysis in providing accurate genetic counselling in this genodermatosis.     

Generalized dystrophic epidermolysis bullosa: identification of a novel, homozygous glycine substitution, G2031S, in exon 73 of COL7A1 in monozygous triplets

We report monozygous triplets affected with dystrophic epidermolysis bullosa (DEB). The female triplets were delivered by Caesarean section and skin fragility of each child, which was partly induced by trauma, was apparent from the third to fourth day of life. Clinically, the triplets were equally affected. Mutation analysis in this family revealed a novel recessively expressed glycine substitution, G2031S, in exon 73 of the collagen VII gene COL7A1. Most glycine substitutions in this gene region encoding for the triple helical domain of collagen VII are associated with milder, dominantly inherited phenotypes. By contrast, the novel point mutation of this study is clinically silent in the heterozygous state and leads to a severe DEB subtype when homozygous.     

High frequency of the 425A-->G splice-site mutation and novel mutations of the COL7A1 gene in central Europe: significance for future mutation detection strategies in dystrophic epidermolysis bullosa

BACKGROUND: Mutations in the type VII collagen gene (COL7A1) are responsible for dominant and recessive forms of dystrophic epidermolysis bullosa (DEB). These mutations are usually specific for individual families; only a few cases of recurring mutations have been identified. OBJECTIVES: Forty-three unrelated Hungarian and German patients with different DEB phenotypes were screened for novel and recurrent COL7A1 mutations. METHODS: All patients were classified based on clinical and genetic findings, skin immunofluorescent antigen mapping, and electron microscopic studies. Mutation analysis was performed by amplification of genomic DNA with polymerase chain reaction using COL7A1-specific primers, heteroduplex analysis, and direct nucleotide sequencing. Restriction endonuclease digestion was used for family screening and mutation verification. Results In this group of patients, the splice-site mutation 425A-->G was observed frequently, in 11 of 86 alleles (12.8%), once in homozygous form and in nine cases in heterozygous form. One of 100 control alleles from clinically unaffected individuals also carried the mutation. We also identified three novel mutations: the 976-3C-->A splice-site mutation, and the 4929delT and 8441-15del20 deletions. CONCLUSIONS: High recurrence of the splice-site mutation 425A-->G in central European patients with DEB should be taken into account when designing COL7A1 mutation detection strategies. Reporting of three novel COL7A1 mutations in this study further emphasizes the molecular heterogeneity of DEB and provides more information for studies on genotype-phenotype correlations in different DEB subtypes.