Early-onset parkinsonism caused by alpha-synuclein gene triplication: Clinical and genetic findings in a novel family.

Introduction: Triplications of SNCA, the gene encoding for α-synuclein, cause a very rare Mendelian form of early-onset parkinsonism combined with cognitive and autonomic dysfunctions. Only six families with SNCA triplications have been described so far, limiting our knowledge of the associated phenotype. In this study, we report clinical and genetic findings in a new Italian family with SNCA triplication.

VACTERL Association Etiology: The Impact of de novo and Rare Copy Number Variations.

Copy number variations (CNVs), either DNA gains or losses, have been found at common regions throughout the human genome. Most CNVs neither have a pathogenic significance nor result in disease-related phenotypes but, instead, reflect the normal population variance. However, larger CNVs, which often arise de novo, are frequently associated with human disease.

Structural genome variations in individuals with childhood cancer and tumour predisposition syndromes.

Background: Previous studies have shown a high prevalence of syndromes in children with cancer. We described four patterns of co-occurring morphological abnormalities indicating new tumour predisposition syndromes. These patterns were named after their key-abnormalities: blepharophimosis (BP), epicanthal folds (EF), asymmetric lower limbs (LLA) and Sydney creases (SC) pattern.

Copy number detection in discordant monozygotic twins of Congenital Diaphragmatic Hernia (CDH) and Esophageal Atresia (EA) cohorts.

The occurrence of phenotypic differences between monozygotic (MZ) twins is commonly attributed to environmental factors, assuming that MZ twins have a complete identical genetic make-up. Yet, recently several lines of evidence showed that both genetic and epigenetic factors could have a role in phenotypic discordance after all. A high occurrence of copy number variation (CNV) differences was observed within MZ twin pairs discordant for Parkinson's disease, thereby stressing on the importance of post-zygotic mutations as disease-predisposing events.

Visualization, analysis, and design of COMBO-FISH probes in the grid-based GLOBE 3D genome platform.

The genome architecture in cell nuclei plays an important role in modern microscopy for the monitoring of medical diagnosis and therapy since changes of function and dynamics of genes are interlinked with changing geometrical parameters. The planning of corresponding diagnostic experiments and their imaging is a complex and often interactive IT intensive challenge and thus makes high-performance grids a necessity. To detect genetic changes we recently developed a new form of fluorescence in situ hybridization (FISH) - COMBinatorial Oligonucleotide FISH (COMBO-FISH) - which labels small nucleotide sequences clustering at a desired genomic location.