ARTICLE
Auteur(s) : Marco
Castori1, Silvia Majore1, Francesco
Romanelli2, Biagio Didona3, Paola
Grammatico1, Giovanna Zambruno4
1Medical Genetics, Experimental Medicine Department,
University La Sapienza, S. Camillo-Forlanini Hospital,
Circonvallazione Gianicolense 87, 00152 Rome, Italy
2Medical Pathophysiology Department, University La
Sapienza, Viale del Policlinico 155, 00161 Rome, Italy
3I Division of Dermatology, IDI-IRCCS, Via dei Monti di
Creta 104, 00167 Rome, Italy
4Laboratory of Molecular and Cell Biology, IDI-IRCCS,
Via dei Monti di Creta 104, 00167 Rome, Italy
accepté le 29 Août 2007
Neurofibromatosis 1 (NF1) is an autosomal dominant multisystemic
disorder with a birth incidence of 1:2,500 and a minimum prevalence
of 1:4,000-5,000. It is caused by germline mutations in the NF1
gene, mapping to 17q11.2 [1]. In contrast, segmental NF1 (SNF1) is
a rarer condition, which occurs in 1:36,000-40,000 individuals and
is usually characterized by the regionally limited distribution of
NF1 skin lesions [2]. The original hypothesis by Crowe et al.
(1956) [3] that SNF1 may result from NF1 somatic mutations arising
after conception in the developing embryo has recently been
substantiated at the molecular level [4]. While there is a
consensus statement concerning the minimum diagnostic criteria for
generalized NF1 [5], the diagnosis of SNF1 is essentially based on
multiple specific pigmentary changes (i.e. multiple café-au-lait
spots, freckling) and/or neurofibromas intermingled with areas of
otherwise healthy skin, often configuring specific mosaic
patterns.
Oculo-auriculo-vertebral spectrum (OAVS), including Goldenhar
syndrome, is the most common first and second branchial arch
malformation syndrome, affecting approximately one in 5,600
individuals [6]. OAVS primarily involves aural, oral and mandibular
development. Its clinical spectrum is extremely wide and the main
clinical features comprise external ear anomalies, ranging from
anotia to preauricular tags, conductive/neurosensorial hearing
loss, epibulbar dermoids, mandibular hypoplasia, a variable degree
of facial asymmetry, and axial skeleton anomalies, including
cervical and upper thoracic metamere malformations [7]. OAVS is
both etiologically and pathogenetically heterogeneous. In fact,
chromosomal imbalances, mendelian mutations as well as
environmental factors have been equally evoked to explain the wide
spectrum of anomalies observed in this condition [8]. However, only
a fragmented picture has emerged to date about the biological basis
of OAVS and no causative gene has been identified so far.
Here, we report a 24-year-old female presenting a constellation
of features fitting with both SNF1 and OAVS. To the best of our
knowledge, this association has never been reported in the
literature.
Case report
A 24-year-old female came to our observation for genetic counseling
and was subsequently referred to the IDI Hospital for evaluation of
skin lesions. She was the second child of unrelated parents and had
an older sister and a younger brother who are healthy. Family
history was unremarkable especially for skin diseases and
malformations. She was born at term by normal delivery and after an
uneventful pregnancy. At birth, a large prearicular tag was
observed on the left side and two smaller ones were present on the
right. At that time, no other abnormality was registered. Skin
hyperpigmented changes were first noted at 2 years, after the
child’s first significant sun exposure. The lesions appeared on the
left shoulder and then progressively expanded over the homolateral
axillary fold, arm, breast, and hemi-abdomen. The large skin tag on
the left cheek was surgically removed at 3 years of age. Somatic
and psychomotor development was normal.
Physical examination revealed marked facial asymmetry with left
mandibular hypoplasia. The ears were not significantly malformed,
although two small preauricular tags were noted on the right one
(figure 1A). On
the left cheek, the surgical scar was still visible (figure 1B) and a deep
cartilagineous remnant of the preauricular tag could be appreciated
by palpation. Exploration of the oral cavity demonstrated the
presence of a non-traumatic substance defect affecting the left
margin of the tongue, most likely secondary to localized muscle
hypoplasia (figure
1C). A large light brown lesion extending over the left
scapular region, homolateral shoulder, breast and hemi-abdomen with
indented margins and sharp midline demarcation was evident (figure 2A and B).
Intense freckling on the left axilla extended beyond the anterior
axillary fold to the thoracic skin, where it was intermingled with
the huge hyperpigmented patch (figure 2C and D). Six
round/oval café-au-lait spots with a diameter over 15 mm were
present along the left arm (figure 2D and E). The rest
of the body surface was unaffected and there was no evidence of
neurofibromas. The proband also presented scoliosis associated with
a considerable lower limb asymmetry (i.e. left leg 2.5 cm
shorter than the right one).
A skull X-ray demonstrated marked hypoplasia of the left
hemimandibula particularly affecting the ramus, without involvement
of the homolateral maxillary bone (figure 3A). This finding
was confirmed by radiographic orthopanoramic (figure 3B). Spine
roentgenographic exam disclosed multiple costo-vertebral anomalies
mainly involving the cervical and thoracic metameres and including
C2-C3 vertebral block, the presence of an additional cervical
vertebra fused with T1, thirteen pair of ribs, posterior arch
schisis of C6 and T2, and a malformed lumbar vertebra resulting
from the fusion of L3 with a right hemivertebra below (i.e.
semisegmented hemivertebra; figure 4). Neurosensorial
hearing loss exclusively affecting the left ear was demonstrated by
audiological investigation. Ophthalmologic surveys, including
fundoscopy and slit-lamp examination, heart, abdominal and kidney
ultrasounds were all negative. Peripheral lymphocyte karyotype at
400-band level on 100 metaphases resulted normal female.
Discussion
In the present patient, the diagnosis of SNF1 was established by
the presence of multiple café-au-lait spots limited to the left
upper limb, homolateral axillary lentigines and a huge
hyperpigmented area with indented margins on the trunk, sharp
midline demarcation and presenting with a “block” pattern. On the
other hand, bilateral preauricular skin tags, unilateral mandibular
hypoplasia, facial asymmetry, and cervical vertebral anomalies are
diagnostic for OAVS (table 1). Such
complex phenotypes may give rise to three distinct possible
explanations: (i) the pleiotropic action of a single gene; (ii) two
distinct events with an etiopathogenetic correlation; or (iii) the
occasional association of two unrelated events.
A late postzygotic NF1 mutation can easily explain the localized
café-au-lait spots and axillary freckling observed in our patient.
In addition, the flag-like distribution of the huge hyperpigmented
patch may be interpreted either as a large atypical café-au-lait
spot, or as the mosaic manifestation of the background skin
pigmentation, usually observed in generalized NF1. The
identification of the causative NF1 mutation in SNF1 patients is
complicated by several factors. In fact, clinical manifestations of
SNF1 are extremely variable and the predominance of either
pigmentary lesions or neurofibromas most likely depends on the cell
type (s) bearing the mutation. In particular, it has been
postulated that in SNF1 with isolated pigmentary changes, the
mutation could be limited to melanocytes and/or keratinocytes [2,
9]. Moreover, the proportion of mutated cells may be so low that
DNA analysis from cultured fibroblasts/keratinocytes could not be
adequate to seek evidence for mosaicism and cell cloning with
allele-specific polymerase chain reaction might be required [10].
Unfortunately, in the present case, we have not been able to
confirm the mosaicism molecularly because the patient refused a
skin biopsy.
In two SNF1 patients, the affected segment appeared smaller than
the unaffected body counterpart [2, 4]. It has been speculated that
the regional hypoplasia may reflect the localized effect of the
mutated NF1 gene on body growth, as demonstrated by the frequent
final height reduction in generalized NF1. In our patient, the
hemimandibular, tongue and lower limb hypoplasia is homolateral to
the SNF1 manifestations. However, these structures did not display
any pigmentary lesion and, therefore, a direct influence of NF1
mutation on their development is unlikely. Moreover, preauricular
skin tags and vertebral segmentation defects do not belong to the
phenotypic manifestations of this gene. In particular, spine
malformations observed in our patient are clinically and
radiographically distinct from those causing dystrophic scoliosis
in generalized NF1 [11]. Thus, the pleiotropic action of NF1 could
not explain the entire spectrum of abnormalities reported in this
case.
The hypothesis that our patient is affected by two distinct
genetic disorders (i.e. SNF1 and OAVS) is very probable. However,
their spatial relationship (i.e. the co-occurrence of SNF1,
hemimandibular and tongue hypoplasia, as well as more severe ear
anomalies on the same body side) might underlie a common
etiopathogenetic mechanism. Oculo-auriculo-vertebral spectrum is a
developmental field defect which occurs early in blastogenesis
(i.e. during the 2nd-4th gestational week)
and recognizes a wide spectrum of genetic and environmental causes
[12]. This condition has occasionally been associated with
chromosome mosaicism, such as mosaic trisomy 7, 9, 18 and 22
[13-16], thus suggesting that, at least in a proportion of cases,
it may be caused by a postzygotic mutation. On a pathogenetic
perspective, some authors suggested that OAVS craniofacial
anomalies may be considered as the consequence of an abnormality of
neural crest cell migration into the developing first and second
branchial arches [8, 17]. Therefore, in the present patient, most,
if not all, of the observed anomalies could be related to the
dysfunction of cells derived from the same embryonic structure, as,
admittedly, melanocytes also derive from neural crests. According
to this hypothesis, a single postzygotic mutational event, such as
a two-breakpoint chromosome abnormality (e.g. reciprocal
translocation, or deletion) or an epigenetic mutation, has
simultaneously involved NF1 and a second, still unknown gene
responsible for the OAVS phenotype. Interestingly, a patient
presenting localized multiple neurofibromas in close proximity with
a nevus sebaceous of Jadassohn has been described [18], suggesting
that the coexistence of SNF1 and other entities caused by
post-zygotic mutations could be underestimated.
A further causal relationship for the association of SNF1 and
OAVS could be considered in our patient. Oculo-auriculo-vertebral
spectrum is etiologically heterogeneous and, in selected cases,
might result from an in utero disruptive vascular event [8, 19]. On
the other hand, it is well known that the NF1 phenotype may also
include vascular anomalies, such as congenital heart disease.
Moreover, alterations of vascular field formation during early
embryogenesis have been evoked to explain the relatively high
frequency of structural abnormalities in this condition [20].
Therefore, it might be hypothesized that, in our patient, a NF1
postzygotic mutation has interacted with additional genetic and/or
non-genetic factor (s) capable of directly influencing
angiogenesis, and, thus, facilitating the occurrence of OAVS
features on the same body side.
Finally, it is also possible that the concurrent observation of
SNF1 and OAVS in the same patient is occasional. However, if we
combine the overall frequency of OAVS and SNF1 in the general
population, the probability of an occasional association is
1:201,600,000. Moreover, if we consider that OAVS is more
pronounced on the left body side (as observed in our patient) in
only 33% cases [6] and that, in case of an occasional association,
SNF1 may involve either body halves with the same frequency (i.e.
50%), this probability lowers to 1:1,209,600,000. Given this
extreme rarity, our patient might truly represent the first
reported example of this occasional association. However, she
received the proper diagnosis only in her thirties, thus suggesting
that the co-occurrence of SNF1 and OAVS could be overlooked,
especially in younger patients and a possible etiopathogenetic link
between these two sporadic conditions cannot be excluded. Future
studies are needed to confirm this hypothesis, which, at the
moment, is entirely based on clinical evidence.
Table 1 Clinical features of the present patient
|
Disease features
|
Our patient
|
|
Segmental neurofibromatosis 1a
|
|
|
Multiple café-au-lait spots
|
+
|
|
Freckling
|
+
|
|
Background skin hyperpigmentation
|
±
|
|
Cutaneous neurofibromas
|
-
|
|
Plexiform neurofibromas
|
-
|
|
Lisch nodules
|
-
|
|
Oculo-auriculo-vertebral spectrumb
|
|
|
Facial asymmetry/ hemifacial microsomia
|
+
|
|
Epibulbar dermoid/lipodermoid
|
-
|
|
Microtia (including isolated preauricular tags)
|
+
|
|
Deafness
|
+
|
|
Mandibular hypoplasia
|
+
|
|
Facial cleft (including eyelid coloboma)
|
-
|
|
Vertebral defects (mainly cervical)
|
+
|
aIn segmental neurofibromatosis 1, disease features are
usually confined to a well demarcated skin region. The most common
clinical presentation of segmental neurofibromatosis 1 is
pigmentary changes only. Isolated neurofibromas or the association
of pigmentary changes and neurofibromas are more rare. The
occurrence of Lisch nodules is exceptional.
bThe clinical manifestations of
oculo-auriculo-vertebral spectrum also include a wide range of
non-specific cephalic and extracephalic malformations (mainly
affecting radius, heart, genitourinary and central nervous
systems).
Acknowledgements
Financial support: this work was supported by the Italian Ministry
of Health (“Ricerca Corrente”). Conflict of interest: none.
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