Genotype-phenotype correlations in cerebral cavernous malformations patients.

OBJECTIVE: To compare clinical features of CCM1, CCM2, and CCM3 mutation carriers. METHODS: A detailed clinical and molecular analysis of 163 consecutive cerebral cavernous malformation (CCM) families was performed. RESULTS: A deleterious mutation was detected in 128 probands. Three hundred thirty-three mutation carriers were identified (238 CCM1, 67 CCM2, and 28 CCM3). Ninety-four percent of the probands with an affected relative had a mutation compared with 57% of the probands with multiple lesions but no affected relative (p < 0.001). The number of affected individuals per family was lower in CCM3 families (p < 0.05). The proportion of patients with onset of symptoms before 15 years of age was higher in the CCM3 group (p < 0.0025). Cerebral hemorrhage was the most common initial presentation in CCM3 patients. The average number of T2-weighted imaging lesions was similar in the three groups, in contrast with a significantly lower number of gradient-echo sequence lesions in CCM2 patients (p < 0.05). The number of gradient-echo sequence lesions increased more rapidly with age in CCM1 than in CCM2 patients (p < 0.05). INTERPRETATION: Despite similarities among the three groups, there is a significantly lower number of affected individuals in CCM3 pedigrees, CCM3 mutations may confer a higher risk for cerebral hemorrhage, particularly during childhood, and the increment of gradient-echo sequence lesions with age differs between CCM1 and CCM2 patients.

A novel hereditary small vessel disease of the brain.

OBJECTIVE: Only few hereditary ischemic small vessel diseases of the brain (SVDB) have been reported so far. Cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL) is the most frequent of them. Herein, we report a family affected by a SVDB distinct from CADASIL. METHODS: After the occurrence of a small deep infarct associated with white matter lesions both in a 46-year-old man and in his 52-year-old sister, clinical and neuroimaging investigations were conducted in 13 of their relatives originating from Portugal. Other investigations included (1) skin biopsy immunostaining with a Notch3 monoclonal antibody, (2) sequencing of the 23 exons encoding the epidermal growth factor-like domains of the NOTCH3 gene, and (3) a NOTCH3 locus haplotype analysis. RESULTS: Diffuse white matter hyperintensities were observed on T2-weighted magnetic resonance imaging (MRI) in six individuals. In contrast with MRI results in the father and paternal uncle of the proband who were hypertensive, white matter lesions were extensive in the mother who had no vascular risk factor. MRI data in four asymptomatic family members together with the results in the two initial cases were suggestive of an underlying hereditary small vessel disease of the brain. Skin biopsy and NOTCH3 gene mutation screening were negative. Haplotype analysis excluded the NOTCH3 locus. INTERPRETATION: These data strongly suggest that this family is affected by a novel hereditary small vessel disease of the brain and that the mutated gene is distinct from NOTCH3.

ATP1A2 mutations in 11 families with familial hemiplegic migraine.

Familial hemiplegic migraine (FHM) is an autosomal dominant form of migraine with aura. The disease is caused by mutations of at least three genes among which two have been identified, CACNA1A and ATP1A2. Very few mutations have been identified so far in ATP1A2. We screened the coding sequence of ATP1A2 in 26 unrelated FHM probands in whom CACNA1A screening was negative. A total of eight different mutations were identified in 11 of the probands (41%), including six missense mutations, one small deletion leading to a frameshift, and one in frame deletion. All were novel mutations. Two mutations were recurrent, in three and two families, respectively. Genotyping of 94 relatives of these 11 probands identified 47 mutation carriers, among whom 36 were clinically affected. Sequencing of all 23 exons in an ethnically matched panel detected only one exonic coding polymorphism.

Impaired vascular mechanotransduction in a transgenic mouse model of CADASIL arteriopathy.

BACKGROUND AND PURPOSE: CADASIL is an inherited small-vessel disease responsible for lacunar strokes and cognitive impairment. The disease is caused by highly stereotyped mutations in Notch3, the expression of which is highly restricted to vascular smooth muscle cells (VSMCs). The underlying vasculopathy is characterized by degeneration of VSMCs and the accumulation of granular osmiophilic material (GOM) and Notch3 protein within the cell surface of these cells. In this study, we assessed early functional changes related to the expression of mutant Notch3 in resistance arteries. METHODS: Vasomotor function was examined in vitro in arteries from transgenic mice that express a mutant Notch3 in VSMC. Tail artery segments from transgenic and normal wild-type male mice were mounted on small-vessel arteriographs, and reactivity to mechanical (flow and pressure) forces and pharmacological stimuli were determined. Mice were studied at 10 to 11 months of age when VSMC degeneration, GOM deposits, and Notch3 accumulation were not yet present. RESULTS: Passive arterial diameter, contraction to phenylephrine, and endothelium-dependent relaxation to acetylcholine were unaffected in transgenic mice. By contrast, flow-induced dilation was significantly decreased and pressure-induced myogenic tone significantly increased in arteries from transgenic mice compared with wild-type mice. CONCLUSIONS: This is the first study to our knowledge providing evidence that mutant Notch3 impairs selectively the response of resistance arteries to flow and pressure. The data suggest an early role of vascular dysfunction in the pathogenic process of the disease.

Notch3 is required for arterial identity and maturation of vascular smooth muscle cells.

Formation of a fully functional artery proceeds through a multistep process. Here we show that Notch3 is required to generate functional arteries in mice by regulating arterial differentiation and maturation of vascular smooth muscle cells (vSMC). In adult Notch3-/- mice distal arteries exhibit structural defects and arterial myogenic responses are defective. The postnatal maturation stage of vSMC is deficient in Notch3-/- mice. We further show that Notch3 is required for arterial specification of vSMC but not of endothelial cells. Our data reveal Notch3 to be the first cell-autonomous regulator of arterial differentiation and maturation of vSMC.

Clinical features of cerebral cavernous malformations patients with KRIT1 mutations.

Cerebral Cavernous Malformations (CCM/OMIM 604214) are vascular malformations causing seizures and cerebral hemorrhages. They occur as a sporadic and autosomal dominant condition, the latter being characterized by the presence of multiple CCM lesions. Stereotyped truncating mutations of KRIT1, the sole CCM gene identified so far, have been identified in CCM1 linked families but the clinical features associated with KRIT1 mutations have not yet been assessed in a large series of patients. We conducted a detailed clinical, neuroradiological and molecular analysis of 64 consecutively recruited CCM families segregating a KRIT1 mutation. Those families included 202 KRIT1 mutation carriers. Among the 202 KRIT1 mutation carriers, 126 individuals were symptomatic and 76 symptom-free. Mean age at clinical onset was 29.7 years (range, 2-72); initial clinical manifestations were seizures in 55% of the cases and cerebral hemorrhages in 32%. Average number of lesions on T2 weighted MRI was 4.9 (+/-7.2) and on gradient echo sequences 19.8 (+/-33.2). Twenty-six mutation carriers harbored only one lesion on T2-weighted MRI, including 4 mutation carriers, aged from 18 to 55 yr-old, who presented only one CCM lesion both on T2-weighted and on highly sensitive gradient echo MRI sequences. Five symptom free mutation carriers, aged from 27 to 48 yr-old, did not have any detectable lesion both on T2WI and gradient echo MRI sequences. Within KRIT1/CCM1 families, both clinical and radiological penetrance are incomplete and age dependent. Importantly for genetic counseling, nearly half of the KRIT1 mutation carriers aged 50 or more are symptom-free. The presence of only one lesion, even when using gradient echo MRI sequences, can be observed in some patients with an hereditary form of the disease. Incomplete neuroradiological penetrance precludes the use of cerebral MRI to firmly establish a non carrier status, even at an adult age and even when using highly sensitive gradient echo MRI. Altogether these data suggest that the hereditary nature of the disorder may be overlooked in some mutation carriers presenting as sporadic cases with a unique lesion.

Transgenic mice expressing mutant Notch3 develop vascular alterations characteristic of cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy.

Cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL) is an increasingly recognized adult-onset autosomal dominant vascular dementia, caused by highly stereotyped mutations in the Notch3 receptor. CADASIL is a widespread angiopathy characterized by a degeneration of vascular smooth muscle cells (VSMCs) and the abnormal accumulation of electron-dense granular material called GOM and Notch3 protein, because of an impaired clearance. Evidence that VSMCs are the primary target of the pathogenic process is supported by the restricted expression of Notch3 in these cells but mechanisms of their degeneration remain essentially unknown. We generated transgenic mice in which the SM22alpha promoter drove, in VSMCs, the expression of a full-length human Notch3 carrying the Arg90Cys mutation, a CADASIL archetypal mutation. Transgenic mice showed no evidence of prominent brain parenchyma damage but demonstrated the two hallmarks of the CADASIL angiopathy, GOM deposits and Notch3 accumulation, within both the cerebral and peripheral arteries. Of interest, arteries of the tail were more severely affected with prominent signs of VSMC degeneration. Time-course analysis of vessel changes revealed that disruption of normal VSMC anchorage to adjacent extracellular matrix and cells, VSMC cytoskeleton changes as well as starting signs of VSMC degeneration, which were detected around 10 months of age, preceded Notch3 and GOM accumulation appearance, which were observed only by 14 to 16 months of age. In conclusion, we have generated transgenic mice that recapitulate the characteristic vascular lesions observed in CADASIL. Our results indicate that Notch3 or GOM accumulation are unlikely to be the prerequisites for the induction of VSMC degeneration and suggest that degeneration of VSMCs may rather be triggered by the disruption of their normal anchorage, based on the important role of adhesion for cell survival.

Spectrum and expression analysis of KRIT1 mutations in 121 consecutive and unrelated patients with Cerebral Cavernous Malformations.

Cerebral Cavernous Malformations (CCM/MIM 604214) are vascular malformations characterised by abnormally enlarged capillary cavities without intervening brain parenchyma. Clinical manifestations include seizures, cerebral haemorrhages and focal neurological deficits. They occur as a sporadic or autosomal dominant condition. Most often, sporadic cases have only one lesion and familial cases are characterised by a high frequency of multiple lesions. Three CCM loci were previously mapped on 7q (CCM1), 7p (CCM2) and 3q (CCM3) and CCM1 gene was identified as coding Krit1, a protein of unknown function, which was shown initially to interact in yeast two hybrid assays with Rap1A, a small ras GTPase and more recently to Icap1alpha, a modulator of beta1 integrin signal transduction. Herein, we screened KRIT1 gene in 121 unrelated, consecutively recruited, CCM probands having at least one affected relative and/or showing multiple lesions on cerebral MRI. Fifty-two of these probands (43%) were shown to carry a KRIT1 mutation. Forty-two distinct mutations were identified including six recurrent ones. Three-quarters of these mutations were located in the C-terminal half of the gene, mostly within exons 13, 15 and 17. All of them are predicted to lead to a premature stop codon. No missense mutation was identified. The only two nucleotide substitutions predicted to be missense mutations led in fact to an abnormal splicing and a premature stop codon. Altogether these data suggest that KRIT1 mRNA decay due to the presence of premature stop codons and Krit1 haploinsufficiency may be the underlying mechanism of CCM.