[Causes and Consequences of Genome Instability in Psychiatric and Neurodegenerative Diseases].

Each neuron has 100-10000 connections (synapses) with other neural cells, therefore genome pathologies affecting a small proportion of brain cells are capable of causing dysfunction of the entire central nervous system (CNS). Recently, genome and chromosome instability has been uncovered in neurodegeneration (Alzheimer's disease, ataxia telangiectasia). Somatic tissue-specific mosaicism was observed in the brain of individuals with neuropsychiatric diseases including schizophrenia, autism, intellectual disability, and epilepsy. The study of genetic processes in neurons allows determination of a certain number of genetic pathways and candidate processes, modifications of which can cause impaired genome stability. Brain-specific somatic mutations generally occur at the earliest stages of development. Accordingly, genome variability and somatic mosaicism are expected to be mediated by cell cycle regulation, DNA repair, DNA replication, and programmed cell death in the brain. Endomitosis, endoreduplication, and abortive entrance to the cell cycle are also commonly observed in neurodegeneration. Brain-specific genome instability maybe a key element in the pathogenic cascade of neurodegeneration. Here we review the current state of knowledge concerning somatic genome variations in neurodegenerative and psychiatric diseases and analyze the causes and consequences of genomic instability in the CNS.

[Epigenomic variations manifesting as a loss of heterozygosity affecting imprinted genes represent a molecular mechanism of autism spectrum disorders and intellectual disability in children]. / Épigenomnye variatsii v vide poteri geterozigotnosti, zatragivaiushchei imprintirovannye geny, kak molekuliarnyi mekhanizm rasstroistv autisticheskogo spektra i umstvennoi otstalosti u detei.

AIM: Long continuous stretches of homozygosity (LCSH) are regularly detected in studies using molecular karyotyping (SNP array). Despite this type of variation being able to provide meaningful data on the parents' kinship, uniparental disomy and chromosome rearrangements, LCSH are rarely considered as a possible epigenetic cause of neurodevelopmental disorders. Despite their direct relationship to imprinting, LCSH in imprinted loci have not been considered in terms of pathogenicity. The present work is aimed at studying LCSH in chromosomal regions containing imprinted genes previously associated with disease in children with idiopathic intellectual disability, autism, congenital malformations and/or epilepsy. MATERIAL AND METHODS: Five hundred and four patients with autism spectrum disorders and intellectual disability were examined. RESULTS: LCSH affecting imprinted loci associated with various diseases were identified in 40 (7.9%) individuals. Chromosomal region 7q21.3 was affected in twenty three cases, 15q11.2 in twelve, 11p15.5 in five, 7q32.2 in four. Four patients had 2 LCSH affecting imprinted loci. Besides one LCSH in 7q31.33q32.3 (~4 Mbp) region, all LCSH were 1-1.6 Mbp. Clinically, these cases resembled the corresponding imprinting diseases (e.g. Silver-Russell, Beckwith-Wiedemann, Prader-Willi, Angelman syndromes). Parental kinship was identified in 8 cases (1.59%), which were not affected by LCSH at imprinted loci. CONCLUSION: The present study shows that LCSH affecting chromosomal regions 7q21.3, 7q32.2, 11p15.5 and 15p11.2 occur in about 7.9% of children with intellectual disability, autism, congenital malformations and/or epilepsy. Consequently, this type of epigenetic mutations is obviously common in a group of children with neurodevelopmental disorders. LCSH less than 2.5-10 Mbp are usually ignored in molecular karyotyping (SNP array) studies and, therefore, an important epigenetic cause of intellectual disability, autism or epilepsy with high probability remains without attention.

[Structural variations of the genome in autistic spectrum disorders with intellectual disability]. / Strukturnye variatsii genoma pri autisticheskikh rasstroistvakh s umstvennoi otstalost'yu.

AIM: To analyze structural variations in the genome in children with autism and intellectual disability. MATERIAL AND METHODS: Using high-resolution karyotyping (AffymetrixCytoScan HD Array) and original bioinformatic technology, 200 children with autism and intellectual disability were studied. RESULTS AND CONCLUSION: Data on structural variations in the genome in children with autism and intellectual disability are provided. Causative genomic pathology (chromosome abnormalities and copy number variations - CNV) was determined in 97 cases (48.5%). Based on these RESULTS: 24 candidate genes for autism with intellectual disability were selected. In 16 cases (8%), the chromosome mosaicism manifested as aneuploidy of whole autosomes and sex chromosomes (gonosomes) was identified. In 87 children (43.5%), there were genomic variations, which are characteristic of the so-called «grey zone¼ of genetic pathology in mental illnesses. Bioinformatic analysis showed that these genomic variations had a pleiotropic effect on the phenotype.