ARTICLE
Auteur(s) : Daniel Shurman1, Jacqueline Losi-Sasaki2, Ronald Grimwood2, Sirpa
Kivirikko3, Elizabeth Tichy2, Jouni Uitto1,*,
Gabriele Richard1,4
1Department of Dermatology and Cutaneous Biology,
Thomas Jefferson University, Philadelphia, PA; USA
2Division of Dermatology, University of Texas Health
Science Center at San Antonio, San Antonio, TX. USA
3Department of Clinical Genetics, Helsinki University
Central Hospital, Helsinki, Finland
4Genedx, Gaithersburg, MD. USA
accepté le 20 Decembre 2005
Epidermolysis bullosa simplex (EBS) with mottled pigmentation (MP)
is a distinct variant of EBS first described by Fisher and
Gedde-Dahl in 1979 [1]. The disorder shows three major
characteristics. First, relatively mild, trauma-induced blistering
of the palms, soles and the extremities is present since infancy or
early childhood. They heal without scarring, milia or
hyperpigmentation, and decrease in frequency with age. Secondly,
also at a young age, the patients develop small, brown,
hyperpigmented macules ranging from 2-5 mm in size. These
lesions tend to coalesce on the trunk and extremities and give the
skin a characteristic mottled pigmentation. Thirdly, acral
hyperkeratotic papules typically develop in adolescence or early
adulthood. Numerous sporadic cases and multi-generation families
have been reported, all being consistent with autosomal dominant
inheritance [1-9].Molecular studies have revealed a single KRT5
missense mutation in all but one EBS-MP family analyzed to date.
The mutation is a C→T transition at position 74 of KRT5 and results
in replacement of a conserved proline residue with leucine at
position 25 (P25L) [10]. The mutation lies in the non-helical
variable head domain of KRT5, thus residing outside the mutation
hot spot regions, namely the helix initiation and termination
motifs and linker regions, found in other more severe forms of EBS.
The P25L mutation does not interfere with alignment and assembly of
keratin intermediate filaments (KIF), thus explaining the mild
blistering phenotype of EBS-MP [10].
Methods
Clinical features of the families
Family 1
We studied a large Mexican family with EBS-MP, which is the first
reported family with this EBS subtype of Hispanic origin. Clinical
evaluation of 6 affected individuals, including an affected father
and 5 of his affected children, revealed small blisters on the
palmoplantar surfaces (Family 1 in ( figure 1 )). All affected
individuals showed characteristic mottled pigmentation of the skin,
which consistently spared the face and was most apparent in the
younger children (( figure 2 )). Consistent
with previously reported cases, the pigmentary changes in the
34-year-old affected father were subtle and had nearly resolved
[10]. In contrast, acral keratotic papules were much more striking
in the older (13- and 14-year-old) children as well as the father.
While only a few discrete acral papules were observed in the
younger children, 2 and 10 years of age, the 11- and 12-year-old
children had experienced a rapid progression, expansion and
confluence of papules along the dorsolateral palms and soles within
the last year. In all cases, the oral mucosa and other mucosal
surfaces were spared and there was no evidence of photosensitivity
in this family.
Family 2
We also studied a 47-year-old female patient of Finnish ancestry
with a family history of EBS-MP (Family 2 in ( figure 1 )). The disorder
manifested in early childhood with hyperpigmentation of the face,
trunk, and legs as well as trauma-induced skin blistering without
evidence for scarring or milia. The patient also had severe,
diffuse palmoplantar keratoderma, papular hyperkeratotic lesions on
the dorsal hands and mild nail dystrophy.
Mutation analysis
With written informed consent of all participants, genomic DNA was
obtained from peripheral blood samples of 11 individuals in Family
1 and the proband of Family 2 (( figure 1 )). The molecular
genetic studies were approved by the Institutional Review Board of
Thomas Jefferson University and adhered to the Declaration of
Helsinki principles. In the proband of each family, the complete
coding sequence (exons 1-9) and exon-intron boundaries of the KRT5
gene were PCR amplified and subjected to bi-directional sequence
analysis. Gene specific primers were created with Primer3
(http://cbr-rbc.nrc-cnrc.gc.ca/cgi-bin/primer3_www.cgi) and BLAST
analysis and are available upon request from the authors. PCR was
performed in 50 μl reactions using 200 ng of DNA, 50 ng of each
primer, 1.0 IU of Taq Polymerase (Qiagen, Valencia, CA) and
standard PCR conditions. Amplicons were separated by agarose gel
electrophoresis, gel-purified (QIAquick gel extraction kit, Qiagen)
and directly sequenced using the BigDye terminator sequencing
system on an ABI Prism 377 sequencer (PE Applied Biosystems, Foster
City, CA). The presence or absence of missense mutation P25L in
other family members and a cohort of 47 unrelated, unaffected
Hispanic control individuals was established by allele-specific
PCR, as previously described [7]. The frequency of 2 sequence
polymorphisms in exon 1 of KRT5, 591C→A (D197E) and 594C→A (T198T),
was determined by sequence analysis.
Results
All affected members of Family 1 and the proband of Family 2 were
found to be heterozygous for the C to T transition at position 74
in exon 1 of KRT5, replacing the proline codon (CCG) at position 25
with a leucine codon (CTG), a mutation denoted as P25L (( figure 1 )). In
addition, 3 affected individuals of Family 1, all of whom had acral
hyperkeratotic lesions, were heterozygous for two previously
described polymorphisms 591C→A (D197E) and 594C→A (T198T) [10, 11]
(( figure 1 )).
Although the allelic frequency of both the coding polymorphism
D197E and the silent polymorphism T198T in a Hispanic control
cohort was relatively high (29%; 27 out of 94 alleles for both), it
is conceivable that the presence of D197E might modulate the
clinical phenotype of EBS-MP and increase the susceptibility for
developing acral hyperkeratotic papules. This hypothesis, however,
needs further investigation.
Discussion
To date, 23 patients with EBS-MP from 9 unrelated,
non-consanguineous families have been reported to harbor the P25L
mutation in KRT5, including families from diverse ethnic and
geographic backgrounds from Japan, UK, Germany, Ireland, The
Netherlands, and Scandinavia. As demonstrated here, the P25L
mutation has also occurred in Hispanic and Finnish families, thus
strongly refuting a founder effect in EBS-MP. Irvine et al. (2001)
determined that P25L lies inside an 18 amino acid sequence that is
highly conserved across several types of intermediate filaments in
different species. In this region, the pattern of SXXSXXXPXXXR is
likely to be involved in phosphorylation and/or O-linked
glycosylation, and the presence of a CpG dinucleotide in codon 25
makes it vulnerable to mutation, reflecting the hypermutability of
5-methyl-cytosine [9].
In vitro studies, in the context of the P25L mutation, have
demonstrated that K5 clones lacking the amino terminus were still
able to form normal appearing 10 nm K14/K5 tetramers [12]. However,
it has been demonstrated that transfection of kidney epithelial
cells with K5 DNA harboring the P25L mutation resulted in the
formation of slightly shortened K14/K5 intermediate filaments, and
cells expressing the mutant K5 DNA showed signs of cytoskeletal
collapse in comparison to wild-type K5 controls [10]. Furthermore,
there is experimental evidence for the role of V1 in maintaining
the dynamic nature of intermediate filaments and in protein-protein
interactions [13]. This notion is supported by an earlier
observation that the P25L mutation lies in a region of K5 that
extends out from the keratin tetramers [14]. Improper keratin
intermediate filament function provides a likely explanation for
the cell fragility observed in EBS-MP as it has been well described
for other forms of EBS. However, the pathomechanisms responsible
for the unusual pigmentation and hyperkeratotic lesions in EBS-MP
remain unexplained. It has been hypothesized that accumulation of
mature melanosomes in those basal keratinocytes that demonstrate
perinuclear vacuolization and cytolysis is responsible for both
blisters and mottled pigmentation [10]. It has also been suggested
that the V1 head region of K5 interacts with dynein, a cytoskeletal
protein involved in melanosome transport [15]. Finally, it is
conceivable that the P25L mutation might interfere with normal
binding of the V1 domain of K5 with desmoplakin, which might alter
cell-cell signaling and change the homeostatic proliferation and
differentiation of the local epidermis [16].
The molecular findings in the Hispanic and Finnish EBS-MP
families reported here confirm previous studies and underscore that
the missense mutation P25L in KRT5 is consistently associated with
an EBS-MP phenotype. Most likely, this mutation is responsible for
all major clinical findings of EBS-MP, thus emphasizing the
importance of keratin intermediate filament function for skin
fragility, melanosome transport, and epidermal differentiation and
proliferation.
Acknowledgments
We are grateful to the families that participated in our study.
Carol Kelly assisted in preparation of this manuscript. This work
was supported in part by the NIH/NIAMS grants K08-AR02141 and
P01-AR38923.
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