C329X in KRIT1 is a founder mutation among CCM patients in Sardinia.

Cerebral cavernous malformations (CCMs) are CNS vascular anomalies associated with seizures, headaches and hemorrhagic strokes and represent 10-20% of cerebral lesions. CCM is present in 0.1-0.5 of the population. This disorder most often occurs sporadically but may also be familial. Familial cases are inherited as a dominant trait with incomplete penetrance and are estimated to account for KRIT1 10-40% of the patients. The identification of the genes involved in such disorders allows to characterize carriers of the mutations without clear symptoms. The first gene involved in CCM1 is KRIT1. In addition to two other genes have been described: MGC4607 (CCM2) and PDCD10 (CCM3). We selected 13 patients belonging to seven Sardinian families on the basis of clinical symptoms and Magnetic Resonance results. In MGC4607 gene an undescribed exon five deletion likely producing a truncated protein was identified in one family. In two patients with clear phenotype and in three asymptomatic relatives a 4 bp deletion in exon 9 of KRIT1 gene, leading to a premature stop codon, was detected. A unique nonsense mutation (C329X) has been found in seven patients and two asymptomatic subjects belonging to four unrelated families. Haplotype analysis revealed a common origin of this mutation. These data suggest a "founder effect" in Sardinia for the C329X mutation, similar to other mutations described in different populations.

Defective temporal processing of sensory stimuli in DYT1 mutation carriers: a new endophenotype of dystonia?

DYT1 primary torsion dystonia is an autosomal dominant movement disorder due to a 3-bp GAG deletion in the TOR1A gene, which becomes manifest in only 30-40% of mutation carriers. Investigating the factors regulating this reduced penetrance might add new insight into the mechanisms underlying the disease. The pathophysiology of dystonia has been related to basal ganglia dysfunctions that lead to the most prominent motor symptoms. However, subclinical sensory deficits have also been reported, particularly in adult-onset focal dystonia. Sensory abnormalities in different forms of sporadic dystonia have been revealed by using a psychophysical method, namely, the temporal discrimination threshold (TDT), quantified as the shortest time interval at which the two stimuli are perceived as separate. Little or no information about the presence of sensory abnormalities in DYT1 gene manifesting and non-manifesting carriers is available. With the aim of disclosing possible associations between sensory deficits and the DYT1 mutation, we assessed TDTs of DYT1 manifesting patients (n = 9); DYT1 non-manifesting relatives (n = 11); non-carrier relatives (n = 9); external control subjects (n = 11). Pairs of tactile, visual or visuo-tactile stimuli were delivered in blocked, counterbalanced order. Intervals between stimuli increased from 0 to 400 ms (in 10 ms steps). On each trial, subjects had to report whether stimuli occurred simultaneously or asynchronously. We measured the first out of three consecutive inter-stimulus intervals at which subjects recognized the two stimuli as temporally separated (TDT) and the first of three consecutive intervals at which they also reported correctly which stimulus in the pair preceded (or followed) the other temporal order judgment (TOJ). Results showed higher tactile and visuo-tactile TDTs and TOJs in DYT1 carriers, both manifesting and non-manifesting, compared with non-carrier relatives and with external control subjects (for all comparisons, P < 0.039). This finding indicates that the DYT1 mutation determines subclinical sensory alterations, which could be disclosed by a psychophysical task. Moreover, these results have the notable implication that sensory deficits in dystonia are not a mere consequence of abnormal movements, but they may even occur before overt clinical manifestations, representing a subclinical phenotype in DYT1 mutation carriers.

A locus for familial skewed X chromosome inactivation maps to chromosome Xq25 in a family with a female manifesting Lowe syndrome.

In mammals, X-linked gene products can be dosage compensated between males and females by inactivation of one of the two X chromosomes in the developing female embryos. X inactivation choice is usually random in embryo mammals, but several mechanisms can influence the choice determining skewed X inactivation. As a consequence, females heterozygous for X-linked recessive disease can manifest the full phenotype. Herein, we report a family with extremely skewed X inactivation that produced the full phenotype of Lowe syndrome, a recessive X-linked disease, in a female. The X chromosome inactivation studies detected an extremely skewed inactivation pattern with a ratio of 100:0 in the propositus as well as in five out of seven unaffected female relatives in four generations. The OCRL1 "de novo" mutation resides in the active paternally inherited X chromosome. X chromosome haplotype analysis suggests the presence of a locus for the familial skewed X inactivation in chromosome Xq25 most likely controlling X chromosome choice in X inactivation or cell proliferation. The description of this case adds Lowe syndrome to the list of X-linked disorders which may manifest the full phenotype in females because of the skewed X inactivation.

Lowe syndrome.

Lowe syndrome (the oculocerebrorenal syndrome of Lowe, OCRL) is a multisystem disorder characterised by anomalies affecting the eye, the nervous system and the kidney. It is a uncommon, panethnic, X-linked disease, with estimated prevalence in the general population of approximately 1 in 500,000. Bilateral cataract and severe hypotonia are present at birth. In the subsequent weeks or months, a proximal renal tubulopathy (Fanconi-type) becomes evident and the ocular picture may be complicated by glaucoma and cheloids. Psychomotor retardation is evident in childhood, while behavioural problems prevail and renal complications arise in adolescence. The mutation of the gene OCRL1 localized at Xq26.1, coding for the enzyme phosphatidylinositol (4,5) bisphosphate 5 phosphatase, PtdIns (4,5)P2, in the trans-Golgi network is responsible for the disease. Both enzymatic and molecular testing are available for confirmation of the diagnosis and for prenatal detection of the disease. The treatment includes: cataract extraction, glaucoma control, physical and speech therapy, use of drugs to address behavioural problems, and correction of the tubular acidosis and the bone disease with the use of bicarbonate, phosphate, potassium and water. Life span rarely exceeds 40 years.

Reflex periodic spasms induced by eating.

We report on two patients with reflex periodic spasms (PS) triggered by eating. Both patients also had significant cognitive and motor deficits. In both patients, reflex eating PS started during meal and occurred repeatedly at intervals of about 5-30 s, and the whole episode lasted about 10-15 min with 15-20 consecutive PS. Clinically, each PS was characterized by the trunk and head flexion, eyeball elevation, abduction of the upper limbs, and loss of consciousness. Ictal EEG recordings of PS revealed high-voltage sharp slow waves followed by a brief 1-2s voltage attenuation. Simultaneous EMG recording of right and left deltoid muscles revealed an abrupt increase of tone lasting 0.5-1.5s. In two patients, the origins of reflex PS were perirolandic suprasylvian and temporolimbic, respectively, because the first patient had focal epilepsy associated with cortical malformation including bilateral opercular dysplasia and the second one had cryptogenic temporal lobe epilepsy.

OCRL mutation analysis in Italian patients with Lowe syndrome.

The oculocerebrorenal syndrome of Lowe (OCRL, also called OCRL1) is a rare X-linked disorder characterized by major abnormalities of eyes, nervous system, and kidneys. The gene responsible for OCRL was identified by positional cloning and encodes an inositol polyphosphate-5-phosphatase. We performed the molecular analysis in 9 Italian patients and 26 relatives and we detected the mutations in all the examined patients. Eight mutations out of nine had never been described and consisted of truncating mutations (frameshift, nonsense, splice site and genomic deletion), and missense mutations. The mutations were distributed in the second half of the gene as previously described in other populations. In three cases the mutations were absent in the mothers confirming the occurrence of novel mutations in this disorder. Our results on the Italian population are similar to the data previously obtained in other populations.

Phenotypic variability of DYT1-PTD: does the clinical spectrum include psychogenic dystonia?

Primary torsion dystonia (PTD) is a clinically and genetically heterogeneous group of movement disorders, usually inherited in an autosomal dominant manner with reduced (30-40%) penetrance. The DYT1 gene on chromosome 9q34 is responsible for most cases of early limb-onset PTD. DYT1-PTD clinical spectrum is broad, as the disease may present with several degrees of body involvement and severity. We identified an Italian family with 4 members definitely affected by PTD, genetically diagnosed as carriers of the GAG mutation at DYT1 gene. Phenotype was homogeneous when considering the presentation at onset (limb involvement and early onset), the disease progression was variable; in the subjects of the last generation, the disease progressed to a severe, generalized PTD; in the remaining 2 subjects, dystonia presented with writer's cramp or upper body segmental dystonia of mild severity. One family member, carrier of the GAG mutation on DYT1 gene and mother of the most severely affected individual, presented with a clinically established psychogenic movement disorder resembling dystonia initially diagnosed as a severe generalized PTD. Psychogenic movement disorders are among the most controversial and challenging diseases to diagnose, in particular when the affected individual belongs to a family with an inherited movement disorder.