Alpha-synuclein gene duplication: marked intrafamilial variability in two novel pedigrees.

BACKGROUND: Multiplications of the SNCA gene that encodes alpha-synuclein are a rare cause of autosomal dominant Parkinson's disease (PD). METHODS: Here, we describe 2 novel families in which there is autosomal dominant PD associated with SNCA duplication, and we compare the clinical features of all known patients carrying 3 or 4 SNCA copies. RESULTS: Affected members in family A presented with early onset PD that was variably associated with nonmotor features, such as dysautonomia, cognitive deficits, and psychiatric disturbances. In family B, the clinical presentation ranged from early onset PD-dementia with psychiatric disturbances to late onset PD with mild cognitive impairment. CONCLUSIONS: The presence of 4 SNCA copies is associated with a rich phenotype, characterized by earlier onset of motor and nonmotor features compared with patients who bear 3 SNCA copies. The clinical spectrum associated with SNCA duplications is wide, even within a single family, suggesting a role for as yet unidentified genetic or environmental modifiers.

A fetal case of microphthalmia and limb anomalies with abnormal neuronal migration associated with SMOC1 biallelic variants.

Microphthalmia with limb anomalies (MLA, OMIM, 206920) is a rare autosomal-recessive disease caused by biallelic pathogenic variants in the SMOC1 gene. It is characterized by ocular disorders (microphtalmia or anophtalmia) and limb anomalies (oligodactyly, syndactyly, and synostosis of the 4th and 5th metacarpals), variably associated with long bone hypoplasia, horseshoe kidney, venous anomalies, vertebral anomalies, developmental delay, and intellectual disability. Here, we report the case of a woman who interrupted her pregnancy after ultrasound scans revealed a depression of the frontal bone, posterior fossa anomalies, cerebral ventricular enlargement, cleft spine involving the sacral and lower-lumbar vertebrae, and bilateral microphthalmia. Micrognathia, four fingers in both feet and a slight tibial bowing were added to the clinical picture after fetal autopsy. Exome sequencing identified two variants in the SMOC1 gene, each inherited from one of the parents: c.709G>T - p.(Glu237*) on exon 8 and c.1223G>A - p.(Cys408Tyr) on exon 11, both predicted to be pathogenic by different bioinformatics software. Brain histopathology showed an abnormal cortical neuronal migration, which could be related to the SMOC1 protein function, given its role in cellular signaling, proliferation and migration. Finally, we summarize phenotypic and genetic data of known MLA cases showing that our case has some unique features (Chiari II malformation; focal neuropathological alterations) that could be part of the variable phenotype of SMOC1-associated diseases.

Copy number variants in attention-deficit hyperactive disorder: identification of the 15q13 deletion and its functional role.

OBJECTIVES: Evidence has supported a role for rare copy number variants in the etiology of attention-deficit hyperactivity disorder (ADHD), in particular, the region 15q13, which is also a hot spot for several neuropsychiatric disorders. This region spans several genes, but their role and the biological implications remain unclear. METHODS: We carried out, for the first time, an analysis of the 15q13 region in an Italian cohort of 117 ADHD patients and 77 controls using the MLPA method, confirmed by a genome single-nucleotide polymorphism array. In addition, we probed for downstream effects of the 15q13 deletions on gene expression by carrying out a transcriptomic analysis in blood. RESULTS: We found 15q13 deletions in two ADHD patients and identified 129 genes as significantly dysregulated in the blood of the two ADHD patients carrying 15q13 deletions compared with ADHD patients without 15q13 deletions. As expected, genes in the deleted region (KLF13, MTMR10) were downregulated in the two patients with deletions. Moreover, a pathway analysis identified apoptosis, oxidation reduction, and immune response as the mechanisms that were altered most significantly in the ADHD patients with 15q13 deletions. Interestingly, we showed that deletions in KLF13 and CHRNA7 influenced the expression of genes belonging to the same immune/inflammatory and oxidative stress signaling pathways. CONCLUSION: Our findings are consistent with the presence of 15q13 deletions in Italian ADHD patients. More interestingly, we show that pathways related to immune/inflammatory response and oxidative stress signaling are affected by the deletion of KFL13 and CHRNA7. Because the phenotypic effects of 15q13 are pleiotropic, our findings suggest that there are shared biologic pathways among multiple neuropsychiatric conditions.

Multiplex ligation-dependent probe amplification assay for simultaneous detection of Parkinson's disease gene rearrangements.

Parkinson's disease (PD) is a common disorder caused by degeneration of dopaminergic neurons in the substantia nigra and other brain areas. Mutations in several genes have been associated with both autosomal dominant PD and recessive early onset Parkinsonism (EOP). Genomic rearrangements such as deletions or multiplications of one or more exons represent a common mutational mechanism for most of these genes and are not detectable with routine mutation screening techniques. MLPA (Multiplex Ligation-dependent Probe Amplification), is a cheap, simple, rapid, and sensitive tool to detect exon dosage alterations and specific point mutations in selected genes. We tested the recently developed PD-MLPA assay by using 13 positive control samples carrying known mutations in SNCA, LRRK2, Parkin, PINK1, and DJ-1 genes. We then applied this technique to screen 16 EOP patients who were then cross-tested by quantitative PCR (qPCR). All the mutations present in the positive control samples were clearly detected by MLPA. Moreover, three novel Parkin rearrangements were identified among EOP patients and confirmed by qPCR. Only two samples generated false positive duplications of LRRK2 exon 1 and UCH-L1 exon 9, respectively. These results show that PD-MLPA assay can simultaneously and effectively detect rearrangements in most PD genes (SNCA, Parkin, PINK1, and DJ-1) as well as the LRRK2 G2019S common mutation. Thus, the use of this novel platform can improve the analysis of such mutations, facilitating comprehensive genetic testing in PD and EOP.