| 1 | Cytogenet. Genome Res. 2011 -1 135: 228-40 |
|---|
| PMID | 22085975 |
| Title | Disentangling the myriad genomics of complex disorders, specifically focusing on autism, epilepsy, and schizophrenia. |
| Abstract | Analyses of structural genome variation by array-CGH have dramatically enhanced our ability to detect copy number variations (CNVs). De novo CNVs and those co-segregating with disease in a family are generally interpreted as pathogenic. Yet, often CNVs, such as recurrent microdeletions in region 15q13.3, are not so clearly pathogenic. Here we discuss potential confounding mechanisms that may lead to the phenotypic pleiotropy of CNVs, such as unmasking of recessive alleles by hemizygous deletions, interaction of CNVs with other loci and genes, genetic epistasis, allelic exclusion, and somatic mosaicism. We illustrate some of these mechanisms with a detailed analysis of recent studies of CNVs involving MCPH1, AUTS2, CNTNAP2, and mutations in GRIN2B. Next we discuss the clinical ramifications of these findings and urge workers to avoid 'diagnostic fatalism' (i.e., halting all genetic investigation after the detection of a single CNV) and address some of the future challenges likely to result from implementations of next generation sequencing techniques. |
| SCZ Keywords | schizophrenia |
| 2 | J Psychiatr Res 2014 May 52: 44-9 |
|---|
| PMID | 24507884 |
| Title | Combined analysis of exon splicing and genome wide polymorphism data predict schizophrenia risk loci. |
| Abstract | schizophrenia has a strong genetic basis, and genome-wide association studies (GWAS) have shown that effect sizes for individual genetic variants which increase disease risk are small, making detection and validation of true disease-associated risk variants extremely challenging. Specifically, we first identify genes with exons showing differential expression between cases and controls, indicating a splicing mechanism that may contribute to variation in disease risk and focus on those showing consistent differential expression between blood and brain tissue. We then perform a genome-wide screen for SNPs associated with both normalised exon intensity of these genes (so called splicing QTLs) as well as association with schizophrenia. We identified a number of significantly associated loci with a biologically plausible role in schizophrenia, including MCPH1, DLG3, ZC3H13, and BICD2, and additional loci that influence splicing of these genes, including YWHAH. Our approach of integrating genome-wide exon intensity with genome-wide polymorphism data has identified a number of plausible SZ associated loci. |
| SCZ Keywords | schizophrenia |
| 3 | Biol. Psychiatry 2014 Jun 75: 961-9 |
|---|
| PMID | 23958183 |
| Title | The genome in three dimensions: a new frontier in human brain research. |
| Abstract | Less than 1.5% of the human genome encodes protein. However, vast portions of the human genome are subject to transcriptional and epigenetic regulation, and many noncoding regulatory DNA elements are thought to regulate the spatial organization of interphase chromosomes. For example, chromosomal "loopings" are pivotal for the orderly process of gene expression, by enabling distal regulatory enhancer or silencer elements to directly interact with proximal promoter and transcription start sites, potentially bypassing hundreds of kilobases of interspersed sequence on the linear genome. To date, however, epigenetic studies in the human brain are mostly limited to the exploration of DNA methylation and posttranslational modifications of the nucleosome core histones. In contrast, very little is known about the regulation of supranucleosomal structures. Here, we show that chromosome conformation capture, a widely used approach to study higher-order chromatin, is applicable to tissue collected postmortem, thereby informing about genome organization in the human brain. We introduce chromosome conformation capture protocols for brain and compare higher-order chromatin structures at the chromosome 6p22.2-22.1 schizophrenia and bipolar disorder susceptibility locus, and additional neurodevelopmental risk genes, (DPP10, MCPH1) in adult prefrontal cortex and various cell culture systems, including neurons derived from reprogrammed skin cells. We predict that the exploration of three-dimensional genome architectures and function will open up new frontiers in human brain research and psychiatric genetics and provide novel insights into the epigenetic risk architectures of regulatory noncoding DNA. |
| SCZ Keywords | schizophrenia |