Gabriella Bartalini

High rate of mosaicism in tuberous sclerosis complex.

Six families with mosaicism are identified in a series of 62 unrelated families with a mutation in one of the two tuberous sclerosis complex (TSC) genes, TSC1 or TSC2. In five families, somatic mosaicism was present in a mildly affected parent of an index patient. In one family with clinically unaffected parents, gonadal mosaicism was detected after TSC was found in three children. The detection of mosaicism has consequences for genetic counseling of the families involved, as changed risks apply to individuals with mosaicism, both siblings and parents. Clinical investigation of parents of patients with seemingly sporadic mutations is essential to determine their residual chance of gonadal and/or somatic mosaicism, unless a mosaic pattern is detected in the index patient, proving a de novo event. In our data set, the exclusion of signs of TSC in the parents of a patient with TSC reduced the chance of one of the parents to be a (mosaic) mutation carrier from 10% to 2%. In the five families with somatic mosaicism, the parent was given the diagnosis after the diagnosis was made in the child.

An unbalanced submicroscopic translocation t(8;16)(q24.3;p13.3)pat associated with tuberous sclerosis complex, adult polycystic kidney disease, and hypomelanosis of Ito

We report on a familial submicroscopic translocation involving chromosomes 8 and 16. The proband of the family had a clinical picture suggestive of a large deletion in the chromosome 16p13.3 area, as he was affected with tuberous sclerosis complex (TSC) and had α thalassaemia trait, and his half brother, who also had TSC, may have suffered additionally from polycystic kidney disease (PKD). FISH studies provided evidence for a familial translocation t(8;16)(q24.3;p13.3) with an unbalanced form in the proband and a balanced form in the father and in a paternal aunt.  The unbalanced translocation caused the index patient to be deleted for the chromosome 16p13.3-pter region, with the most proximal breakpoint described to date for terminal 16p deletions. In addition, FISH analysis showed a duplication for the distal 8q region. Since the index patient also had hypomelanosis of Ito (HI), either of the chromosomal areas involved in the translocation may be a candidate region for an HI determining gene. Furthermore, it is noteworthy that both carriers of the balanced translocation showed a nodular goitre, while the proband has hypothyroidism.

Medial temporal lobe dysgenesis in Muenke syndrome and hypochondroplasia

Hypochondroplasia (HCH) and Muenke syndrome (MS) are caused by mutations on FGFR3 gene. FGFR3 is known to play a role in controlling nervous system development. We describe the clinical and neuroradiological findings of the first two patients, to our knowledge, affected by HCH and MS, respectively, in whom bilateral dysgenesis of the medial temporal lobe structures has been observed. In both patients diagnosis was confirmed by molecular analysis. They were mentally normal and showed similarities in early‐onset temporal lobe‐related seizures. In both patients EEG recorded bilateral temporal region discharges. MRI detected temporal lobe anomalies with inadequate differentiation between white and gray matter, defective gyri, and abnormally shaped hippocampus.

Electroencephalographic and epileptic patterns in X chromosome anomalies.

Although epilepsy and mental retardation are commonly observed in individuals with chromosomal aberrations, the identification of EEG/epileptic profiles in those with specific chromosome anomalies remains difficult. A few syndromes seem to show peculiar clinical and EEG associations. The authors report an electroclinical investigation on a group of patients carrying X chromosome anomalies: 16 patients with Turners syndrome, 17 with Klinefelters syndrome, 1 with an X–autosomal rearrangement, 2 with Xq isochromosome [Xq(i)], and 7 with triple X syndrome. Epilepsy and/or EEG anomalies were found in three of the patients with Klinefelters syndrome, in one patient with an X–autosomal rearrangement, and in five of those with triple X syndrome. No epilepsy or EEG anomalies were detected in the other patients. Epilepsy may be associated with Klinefelters syndrome. In addition, the authors found that an electroclinical pattern, represented by paroxysmal activity in the posterior regions (temporo-parieto-occipital areas) with complex partial seizures and easily controlled by antiepileptic drugs, may be present in patients with triple X syndrome. In contrast, gross X–autosomal rearrangements are associated with polymorphic EEG/epileptic findings. Although further studies are needed to validate these observations, they clearly confirm the strict relationship between X chromosome anomalies and epilepsy.

Missense mutations to the TSC1 gene cause tuberous sclerosis complex

Tuberous sclerosis complex (TSC) is an autosomal dominant disorder characterised by the development of hamartomas in a variety of organs and tissues. The disease is caused by mutations in either the TSC1 gene on chromosome 9q34 or the TSC2 gene on chromosome 16p13.3. The TSC1 and TSC2 gene products, TSC1 and TSC2, interact to form a protein complex that inhibits signal transduction to the downstream effectors of the mammalian target of rapamycin (mTOR). Here we investigate the effects of putative TSC1 missense mutations identified in individuals with signs and/or symptoms of TSC on TSC1–TSC2 complex formation and mTOR signalling. We show that specific amino-acid substitutions close to the N-terminal of TSC1 reduce steady-state levels of TSC1, resulting in the activation of mTOR signalling and leading to the symptoms of TSC.

Central nervous system imaging in reevaluation of patients with neurofibromatosis type 1

We report the results of the reevaluation of 24 patients with neurofibromatosis type 1 (NF1) using central nervous system (CNS) imaging techniques. The first examination by computed tomography (CT) or magnetic resonance imaging (MRI) indicated the presence of optic glioma in three cases, “unidentified bright objects” (UBOs) in six, and a suspected right frontal tumor in one. In two patients optic glioma and UBOs were both present and in one of them a bulbar tumor was also suspected. Later imaging examinations revealed the appearance of optic glioma in three more cases and UBOs in nine. In two of these patients both optic glioma and UBOs were present. This study indicates that the likelihood of detecting imaging abnormalities in patients with NF1 increases when systematic follow-up is performed. Optic gliomas are characteristic of pediatric patients; they rarely give rise to clinical manifestations (1/6 cases) and in general progress very slowly. For these reasons, therapeutic strategy must be carefully considered and individually decided. UBOs are very frequent findings in pediatric patients with NF 1 and therefore they must be considered diagnostically relevant. They are not related to clinical manifestations and spontaneous regression has been observed. The nature of these imaging abnormalities is still unknown, but because they do not behave like tumors, useless and dangerous therapeutic procedures should not be employed.

Chromosome 18 aberrations and epilepsy: A review

Epilepsy is commonly observed in patients with chromosomal aberrations. We evaluated epilepsy and electroencephalographic (EEG) features in a group of patients carrying aberrations of chromosome 18. Fourteen patients were recruited: five with an 18p deletion syndrome (18pDS); six with an 18q deletion syndrome (18qDS); two with trisomy 18p syndrome; and one with a 45,XY,t(17‐18) (cen‐q11.2) karyotype. Patients with 18pDS had neither epilepsy nor EEG anomalies; four patients with 18qDS had epilepsy with partial seizures occurring during infancy or early childhood. Partial seizures were also present in both patients with trisomy 18p. By contrast, mixed seizures were observed in the patient carrying a translocation between chromosomes 17 and 18. Our data and a re‐evaluation of the literature suggest that epilepsy is infrequent in patients with 18pDS. Conversely, partial seizures and focal EEG anomalies may be observed in those with patients with 18qDS. Our observations suggest that the haplo‐insufficiency of genes located on the long arm of chromosome 18 is more likely to be associated with epilepsy, than is haplo‐insufficiency of genes located on the short arm. While further EEG/clinical investigations are needed to validate these observations, this study indicates a possible relationship between chromosome 18 genes and epilepsy.

Epilepsy and electroencephalographic anomalies in chromosome 2 aberrations. A review.

UNLABELLED Epilepsy and electroencephalographic (EEG) anomalies are common in subjects carrying chromosomal aberrations. We report clinical and EEG investigations on 13 patients carrying chromosome 2 anomalies, including two patients with inversions, six with translocations, two with partial duplications and three with interstitial deletion syndromes. Epilepsy and/or EEG anomalies were found in one patient with a chromosome 2 translocation, in both of those carrying partial duplications and in all three with interstitial deletion syndromes. No epilepsy or EEG anomalies were detected in the remaining patients. CONCLUSIONS Epilepsy may be associated with chromosome 2 aberrations. Gross rearrangements involving the long arm of chromosome 2 might be more often associated with epilepsy than those involving the short arm. The association of epilepsy with chromosome 2 duplications is less clear. In particular, our observations and a review of the literature appear to suggest that a strict relationship between epilepsy and interstitial deletions involving the 2q24-q31 region. In the latter disorder tonic and focal seizures occur early in life. Generalized and focal myoclonic jerks tend to appear in infancy and are subsequently followed by seizures mixed in type. Seizures usually persist up to late childhood and are drug resistant. Further studies are necessary to better define the electroclinical patterns of patients carrying deletions in 2q24-q31. These may help to direct systematic study of this--probably underestimated--cause of severe epilepsy.

Pubertal disorders in inv dup(15) syndrome.

Duplication of chromosome 15 (inv dup[15] chromosome) is the most common supernumerary marker chromosome in humans. Inv dup(15) chromosomes are commonly associated with mental retardation ,epilepsy ,behavioral problems and structural malformations. Ten patients (4 male ,6 female) were detected with inv dup(15) syndrome. At clinical follow-up three girls showed pubertal disorders: two with central precocious puberty and one with ovarian dysgenesis. As has already been found in other patients with chromosome 15p abnormalities ,we believe that gynecological disorder is an important clinical finding also in patients with inv dup(15) syndrome. We report the first data of a systematic endocrinological study on inv dup(15) syndrome which suggest that endocrine investigation in these patients is both warranted and useful. Moreover ,our observations confirm that a karyotype analysis in patients in whom precocious puberty is associated with mental retardation is mandatory.

Biochemical diagnosis of Canavan disease

Canavan disease (CD) is a rare autosomal recessive disorder characterized by macrocephaly and progressive leukodystrophy. Up to now biopsy or necropsy were required to define the diagnosis. Recently the disease has been related to N-acetylaspartic aciduria and deficiency of aspartoacylase, an enzyme possibly involved in the myelin synthesis. These biochemical findings have provided a diagnostic marker for the disease. We report a new case of infantile CD in which the demonstration of N-acetylaspartic aciduria and a marked deficiency of aspartoacylase activity confirmed the diagnosis.