Neurofibromatosis type 1 (NF1), initially described by
von Recklinghausen, is one of the most common single gene
disorders, with an incidence of around 1 in 3000. The main
diagnostic features of NF1 are café-au-lait patches, peripheral
neurofibromas and lisch nodules. Café-au-lait patches are
sometimes present at birth, but often appear in the first few
years of life, increasing in size and number. A child at risk who
has no café-au-lait patches by the age of five is extremely
unlikely to be affected. Freckling in the axillae, groins or base
of the neck is common and generally only seen in people with
NF1. Peripheral neurofibromas usually start to appear around
puberty and tend to increase in number through adult life.
The number of neurofibromas varies widely between different
subjects from very few to several hundred. Lisch nodules
(iris hamartomas) are not visible to the naked eye but can be
seen using a slit lamp. Minor features of NF1 include short
stature and macrocephaly. Complications of NF1 are listed
in the box and occur in about one third of affected
individuals. Malignancy (mainly embryonal tumours or
neurosarcomas) occur in about 5% of affected
individuals. Learning disability occurs in about one
third of children, but severe mental retardation in
only 1 to 2%.
Saturday, April 11, 2009
The gene for NF1
The gene for NF1 was localised to chromosome 17 in 1987
and cloned in 1990. The gene contains 59 exons and encodes
of protein called neurofibromin, which appear to be involved
in the control of cell growth and differentiation. Mutation
analysis is not routine because of the large size of the gene and
the difficulty in identifying mutations. Prenatal diagnosis by
linkage analysis is possible in families with two or more affected
individuals. NF1 has a very variable phenotype and prenatal
testing does not predict the likely severity of the condition. Up
to one third of cases arise by a new mutation.
and cloned in 1990. The gene contains 59 exons and encodes
of protein called neurofibromin, which appear to be involved
in the control of cell growth and differentiation. Mutation
analysis is not routine because of the large size of the gene and
the difficulty in identifying mutations. Prenatal diagnosis by
linkage analysis is possible in families with two or more affected
individuals. NF1 has a very variable phenotype and prenatal
testing does not predict the likely severity of the condition. Up
to one third of cases arise by a new mutation.
Neurofibromatos
Neurofibromatos is type 2 (NF2) is a disorder distinct from
NF1. It is characterised by schwannomas (usually bilateral) and
other cranial and spinal tumours. Café-au-lait patches and
peripheral neurofibromas can also occur, as in NF1. Survival is
reduced in NF2, with the mean age of death being around 32
years. NF2 follows autosomal dominant inheritance with about
50% of cases representing new mutations. The NF2 gene, whose
protein product has been called merlin, is a tumour suppressor
gene located on chromosome 22. Mutation analysis of the NF2
gene contributes to confirmation of diagnosis in clinically
affected individuals and enables presymptomatic testing of
relatives at risk, identifying those who will require annual
clinical and radiological screening.
NF1. It is characterised by schwannomas (usually bilateral) and
other cranial and spinal tumours. Café-au-lait patches and
peripheral neurofibromas can also occur, as in NF1. Survival is
reduced in NF2, with the mean age of death being around 32
years. NF2 follows autosomal dominant inheritance with about
50% of cases representing new mutations. The NF2 gene, whose
protein product has been called merlin, is a tumour suppressor
gene located on chromosome 22. Mutation analysis of the NF2
gene contributes to confirmation of diagnosis in clinically
affected individuals and enables presymptomatic testing of
relatives at risk, identifying those who will require annual
clinical and radiological screening.
Tuberous sclerosis complex
Tuberous sclerosis complex (TSC) is an autosomal dominant
disorder with a birth incidence of about 1 in 6000. TSC is very
variable in its clinical presentation. The classical triad of mental
retardation, epilepsy and adenosum sebaceum are present in
only 30% of cases. TSC is characterised by hamartomas in
multiple organ systems, commonly the skin, CNS, kidneys,
heart and eyes. The ectodermal manifestations of the condition
are shown in the table. CNS manifestations include cortical
tumours that are associated with epilepsy and mental
retardation, and subependymal nodules that are found in 95%
of subjects on MRI brain scans. Subependymal giant cell
astrocytomas develop in about 6% of affected individuals. TSC
is associated with both infantile spasms and epilepsy occurring
later in childhood. Learning disability is frequently associated.
Attention deficit hyperactivity disorder is associated with TSC
and severe retardation occurs in about 40% of cases. Renal
angiomyolipomas or renal cysts are usually bilateral and
multiple, but mainly asymptomatic. Their frequency increases
with age. Angiomyolipomas may cause abdominal pain, with or
without haematuria, and multiple cysts can lead to renal failure.
There may be a small increase in the risk of renal carcinoma in
TSC. Cardiac rhabdomyomas are detected by echocardiography
in 50% of children with TSC. These can cause outflow tract
obstruction or arrhythmias, but tend to resolve with age.
Ophthalmic features of TSC include retinal hamartomas,
which are usually asymptomatic.
disorder with a birth incidence of about 1 in 6000. TSC is very
variable in its clinical presentation. The classical triad of mental
retardation, epilepsy and adenosum sebaceum are present in
only 30% of cases. TSC is characterised by hamartomas in
multiple organ systems, commonly the skin, CNS, kidneys,
heart and eyes. The ectodermal manifestations of the condition
are shown in the table. CNS manifestations include cortical
tumours that are associated with epilepsy and mental
retardation, and subependymal nodules that are found in 95%
of subjects on MRI brain scans. Subependymal giant cell
astrocytomas develop in about 6% of affected individuals. TSC
is associated with both infantile spasms and epilepsy occurring
later in childhood. Learning disability is frequently associated.
Attention deficit hyperactivity disorder is associated with TSC
and severe retardation occurs in about 40% of cases. Renal
angiomyolipomas or renal cysts are usually bilateral and
multiple, but mainly asymptomatic. Their frequency increases
with age. Angiomyolipomas may cause abdominal pain, with or
without haematuria, and multiple cysts can lead to renal failure.
There may be a small increase in the risk of renal carcinoma in
TSC. Cardiac rhabdomyomas are detected by echocardiography
in 50% of children with TSC. These can cause outflow tract
obstruction or arrhythmias, but tend to resolve with age.
Ophthalmic features of TSC include retinal hamartomas,
which are usually asymptomatic.
TSC follows autosomal dominant inheritance
TSC follows autosomal dominant inheritance but has very
variable expression both within and between families. Fifty
per cent of cases are sporadic. First degree relatives of an
affected individual need careful clinical examination to detect
minor features of the condition. The value of other
investigations in subjects with no clinical features is not of
proven benefit.
variable expression both within and between families. Fifty
per cent of cases are sporadic. First degree relatives of an
affected individual need careful clinical examination to detect
minor features of the condition. The value of other
investigations in subjects with no clinical features is not of
proven benefit.
Two genes causing TSC
genes causing TSC have been identified: TSC1 on
chromosome 9 and TSC2 on chromosome 16. The products of
these genes have been called hamartin and tuberin respectively.
Current strategies for mutation analysis do not identify the
underlying mutation in all cases. However, when a mutation is
detected, this aids diagnosis in atypical cases, can be used to
investigate apparently unaffected parents of an affected child,
and enables prenatal diagnosis. Mutations of both TSC1 and
TSC2 are found in familial and sporadic TSC cases. There is no
observable difference in the clinical presentation between TSC1
and TSC2 cases, although it has been suggested that intellectual
disability is more frequent in sporadic cases with TSC2 than
TSC1 mutations.
chromosome 9 and TSC2 on chromosome 16. The products of
these genes have been called hamartin and tuberin respectively.
Current strategies for mutation analysis do not identify the
underlying mutation in all cases. However, when a mutation is
detected, this aids diagnosis in atypical cases, can be used to
investigate apparently unaffected parents of an affected child,
and enables prenatal diagnosis. Mutations of both TSC1 and
TSC2 are found in familial and sporadic TSC cases. There is no
observable difference in the clinical presentation between TSC1
and TSC2 cases, although it has been suggested that intellectual
disability is more frequent in sporadic cases with TSC2 than
TSC1 mutations.
Connective tissue disorders
Marfan syndrome is an autosomal dominant disorder affecting
connective tissues caused by mutation in the gene encoding
fibrillin 1 (FBN1). The disorder has an incidence of at least 1 in
10 000. It arises by new mutation in 25–30% of cases. In some
familial cases, the diagnosis may have gone unrecognised in
previously affected relatives because of mild presentation and
the absence of complications.
connective tissues caused by mutation in the gene encoding
fibrillin 1 (FBN1). The disorder has an incidence of at least 1 in
10 000. It arises by new mutation in 25–30% of cases. In some
familial cases, the diagnosis may have gone unrecognised in
previously affected relatives because of mild presentation and
the absence of complications.
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