Helle Lybæk

The Complement Control-Related Genes CSMD1 and CSMD2 Associate to Schizophrenia

BACKGROUND Patients with schizophrenia often suffer from cognitive dysfunction, including impaired learning and memory. We recently demonstrated that long-term potentiation in rat hippocampus, a mechanistic model of learning and memory, is linked to gene expression changes in immunity-related processes involved in complement activity and antigen presentation. We therefore aimed to examine whether key regulators of these processes are genetic susceptibility factors in schizophrenia. METHODS Analysis of genetic association was based on data mining of genotypes from a German genome-wide association study and a multiplex GoldenGate tag single nucleotide polymorphism (SNP)-based assay of Norwegian and Danish case-control samples (Scandinavian Collaboration on Psychiatric Etiology), including 1133 patients with schizophrenia and 2444 healthy control subjects. RESULTS Allelic associations were found across all three samples for eight common SNPs in the complement control-related gene CSMD2 (CUB and Sushi Multiple Domains 2) on chromosome 1p35.1-34.3, of which rs911213 reached a statistical significance comparable to that of a genome wide threshold (p value = 4.0 × 10(-8); odd ratio = .73, 95% confidence interval = .65-.82). The second most significant gene was CSMD1 on chromosome 8p23.2, a homologue to CSMD2. In addition, we observed replicated associations in the complement surface receptor CD46 as well as the major histocompatibility complex genes HLA-DMB and HLA-DOA. CONCLUSIONS These data demonstrate a significant role of complement control-related genes in the etiology of schizophrenia and support disease mechanisms that involve the activity of immunity-related pathways in the brain.

An 8.9 Mb 19p13 duplication associated with precocious puberty and a sporadic 3.9 Mb 2q23.3q24.1 deletion containing NR4A2 in mentally retarded members of a family with an intrachromosomal 19p-into-19q between-arm insertion

In a 2 and a half-year-old girl with onset of puberty before the age of 5 months, short stature, hand anomalies and severe mental retardation, an 8.9 Mb interstitial 19p13 duplication containing 215 predicted genes was detected. It was initially assumed that the duplication involved the kisspeptin receptor gene, GPR54, known to stimulate induction of puberty, but more refined duplication mapping excluded this possibility. In an attempt to further understand the genotype–phenotype correlation, global gene expression was measured in skin fibroblasts. The overall expression pattern was quite similar to controls, and only about 25% of the duplicated genes had an expression level that was increased by more than 1.3-fold, with no obvious changes that could explain the precocious puberty. The probands mother carried a balanced between-arm insertion of the duplicated segment that resembled a pericentric inversion. The same insertion was found in several other family members, including one who had lost a daughter with severe mental retardation and menarche at the age of 10 years. Another close relative was severely mentally retarded, but neither dysmorphic nor microcephalic. His phenotype was initially ascribed to a presumed cryptic chromosome 19 imbalance caused by the 19p-into19q insertion, but subsequent array-CGH detected a 3.9-Mb deletion of 2q23.3q24.1. This novel microdeletion involves seven genes, of which FMNL2, a suggested regulator of Rho-GTPases, and NR4A2, an essential gene for differentiation of dopaminergic neurons, may be critical genes for the proposed 2q23q24 microdeletion syndrome.

Severe Progressive Autism Associated with Two de novo Changes: A 2.6-Mb 2q31.1 Deletion and a Balanced t(14;21)(q21.1;p11.2) Translocation with Long-Range Epigenetic Silencing of LRFN5 Expression

In a 19-year-old severely autistic and mentally retarded girl, a balanced de novo t(14;21)(q21.1;p11.2) translocation was found in addition to a de novo 2.6-Mb 2q31.1 deletion containing 15 protein-encoding genes. To investigate if the translocation might contribute to developmental stagnation at the age of 2 years with later regression of skills, i.e. a more severe phenotype than expected from the 2q31.1 deletion, the epigenetic status and expression of genes proximal and distal to the 14q21.1 breakpoint were investigated in Ebstein Barr Virus-transformed lymphoblast and primary skin fibroblast cells. The 14q21.1 breakpoint was found to be located between a cluster of 7 genes 0.1 Mb upstream, starting with FBXO33, and the single and isolated LRFN5 gene 2.1 Mb downstream. Only expression of LRFN5 appeared to be affected by its novel genomic context. In patient fibroblasts, LRFN5 expression was 10-fold reduced compared to LRFN5 expressed in control fibroblasts. In addition, a relative increase in trimethylated histone H3 lysine 9 (H3K9M3)-associated DNA starting exactly at the translocation breakpoint and going 2.5 Mb beyond the LRFN5 gene was found. At the LRFN5 promoter, there was a distinct peak of trimethylated histone H3 lysine 27 (H3K27M3)-associated DNA in addition to a diminished trimethylated histone H3 lysine 4 (H3K4M3) level. We speculate that dysregulation of LRFN5, a postsynaptic density-associated gene, may contribute to the patient’s autism, even though 2 other patients with 14q13.2q21.3 deletions that included LRFN5 were not autistic. More significantly, we have shown that translocations may influence gene expression more than 2 Mb away from the translocation breakpoint.

Microarray analysis reveals down-regulation of the tumour suppressor gene WWOX and up-regulation of the oncogene TYMS in intracranial sporadic meningiomas

Background In order to investigate pathways that may influence on tumour development in meningiomas, we performed high throughput microarray analysis of the RNA expression and DNA copy number of 22 WHO grade I and five WHO grade II meningiomas. Since meningiomas derive from arachnoid cap cells, we used samples from four patients operated for arachnoid cysts as control tissue. Results The expression of the tumour suppressor gene WW containing oxidoreductase (WWOX) was down-regulated, and the thymidylate synthase (TYMS) oncogene was up-regulated in all meningiomas as compared to arachnoid cysts. Unsupervised RNA cluster analysis showed that fibrous meningiomas gathered in two clusters, and thus were more homogeneous than the other meningiomas. The other histological subgroups could not be linked to any uniform gene expression signatures. Rearrangements were most abundant on chromosomes 1 and 22, but were identified on all except chromosome 16. The fibrous and mixed meningiomas generally had chromosomal deletions. Duplications were more frequent in the meningothelial meningiomas. WHO grade II meningiomas had increased chromosomal instability. Conclusion Decreased expression of the WWOX tumour suppressor gene and increased expression of the TYMS oncogene may be of importance for the development of human intracranial meningiomas. We have identified several genes (BMPR1B, DMD, RAMP1) with expression signatures specific for fibrous meningiomas. CGH analysis revealed distinct chromosomal patterns in relation to the histological subtypes of the meningiomas.

A de novo 1.5 Mb microdeletion on chromosome 14q23.2-23.3 in a patient with autism and spherocytosis

Autism is a neuro‐developmental disorder characterized by deficits in social interaction and communication as well as restricted interests or repetitive behaviors. Cytogenetic studies have implicated large chromosomal aberrations in the etiology of approximately 5–7% of autism patients, and the recent advent of array‐based techniques allows the exploration of submicroscopic copy number variations (CNVs). We genotyped a 14‐year‐old boy with autism, spherocytosis and other physical dysmorphia, his parents, and two non‐autistic siblings with the Illumina Human 1M Beadchip as part of a study of the molecular genetics of autism and determined copy number variants using the PennCNV algorithm. We identified and validated a de novo 1.5 Mb microdeletion of 14q23.2‐23.3 in our autistic patient. This region contains 15 genes, including spectrin beta (SPTB), encoding a cytoskeletal protein previously associated with spherocytosis, methylenetetrahydrofolate dehydrogenase 1 (MTHFD1), a folate metabolizing enzyme previously associated with bipoloar disorder and schizophrenia, pleckstrin homology domain‐containing family G member 3 (PLEKHG3), a guanide nucleotide exchange enriched in the brain, and churchill domain containing protein 1 (CHURC1), homologs of which regulate neuronal development in model organisms. While a similar deletion has previously been reported in a family with spherocytosis, severe learning disabilities, and mild mental retardation, this is the first implication of chr14q23.2‐23.3 in the etiology of autism and points to MTHFD1, PLEKHG3, and CHURC1 as potential candidate genes contributing to autism risk. Autism Res 2011,4:221–227.

A 2.1 Mb deletion adjacent but distal to a 14q21q23 paracentric inversion in a family with spherocytosis and severe learning difficulties

A familial q21.1q23.2‐inversion on chromosome 14 that co‐segregated with spherocytosis and learning difficulties or mild mental retardation was extensively investigated by bacterial artificial chromosome fluorescence in situ hybridization and array‐comparative genomic hybridization. As expected, a deletion of the beta‐spectrin gene SPTB, a known cause of spherocytosis, was found. More unexpectedly, this deletion was ∼1.6 Mb distal to the 14q23.2‐inversion breakpoint. The deletion spanned ∼2.1 Mb and contained 15 annotated genes in addition to SPTB, among them PLEKHG3, a guanide nucleotide exchange factor for Rho GTPases. This gene is highly expressed in the brain and our best candidate for causing the mild mental retardation. The case illustrates that inversions can be associated with microdeletions close to but not including one of the inversion breakpoints.

RevSex duplication-induced and sex-related differences in the SOX9 regulatory region chromatin landscape in human fibroblasts.

It was recently shown that duplications of the RevSex element, located 0.5 Mb upstream of SOX9, cause XX-disorder of sex development (DSD), and that deletions cause XY-DSD. To explore how a 148 kb RevSex duplication could have turned on gonadal SOX9 expression in the absence of SRY in an XX-male, we examined the chromatin landscape in primary skin fibroblast cultures from the index, his RevSex duplication-carrier father and six controls. The ENCODE project supports the notion that chromatin state maps show overlap between different cell types, i.e., that our study of fibroblasts could be of biological relevance. We examined the SOX9 regulatory region by high-resolution ChIP-on-chip experiments (a kind of “chromatin-CGH”) and DNA methylation investigations. The RevSex duplication was associated with chromatin changes predicting better accessibility of the SRY-responsive TESCO enhancer region 14–15 kb upstream of SOX9. Four kb downstream of the TESCO evolutionary conserved region, a peak of the enhancer/promoter-associated H3K4me3 mark was found together with a major dip of the repressive H3K9me3 chromatin mark. Similar differences were also found when three control males were compared with three control females. A marked male/female difference was a more open chromatin signature in males starting ~400 kb upstream of SOX9 and increasing toward the SOX9 promoter. In the RevSex duplication-carrier father, two positions of DNA hypomethylation were also found, one corresponding to the H3K4me3 peak mentioned above. Our results suggest that the RevSex duplication could operate by inducing long-range epigenetic changes. Furthermore, the differences in chromatin state maps between males and females suggest that the Y chromosome or X chromosome dosage may affect chromatin conformation, i.e., that sex-dependent gene regulation may take place by chromatin modification.

DCLK1 Variants Are Associated across Schizophrenia and Attention Deficit/Hyperactivity Disorder

Doublecortin and calmodulin like kinase 1 (DCLK1) is implicated in synaptic plasticity and neurodevelopment. Genetic variants in DCLK1 are associated with cognitive traits, specifically verbal memory and general cognition. We investigated the role of DCLK1 variants in three psychiatric disorders that have neuro-cognitive dysfunctions: schizophrenia (SCZ), bipolar affective disorder (BP) and attention deficit/hyperactivity disorder (ADHD). We mined six genome wide association studies (GWASs) that were available publically or through collaboration; three for BP, two for SCZ and one for ADHD. We also genotyped the DCLK1 region in additional samples of cases with SCZ, BP or ADHD and controls that had not been whole-genome typed. In total, 9895 subjects were analysed, including 5308 normal controls and 4,587 patients (1,125 with SCZ, 2,496 with BP and 966 with ADHD). Several DCLK1 variants were associated with disease phenotypes in the different samples. The main effect was observed for rs7989807 in intron 3, which was strongly associated with SCZ alone and even more so when cases with SCZ and ADHD were combined (P-value = 4×10−5 and 4×10−6, respectively). Associations were also observed with additional markers in intron 3 (combination of SCZ, ADHD and BP), intron 19 (SCZ+BP) and the 3′UTR (SCZ+BP). Our results suggest that genetic variants in DCLK1 are associated with SCZ and, to a lesser extent, with ADHD and BP. Interestingly the association is strongest when SCZ and ADHD are considered together, suggesting common genetic susceptibility. Given that DCLK1 variants were previously found to be associated with cognitive traits, these results are consistent with the role of DCLK1 in neurodevelopment and synaptic plasticity.

Array-CGH fine mapping of minor and cryptic HR-CGH detected genomic imbalances in 80 out of 590 patients with abnormal development

During a 6-year period, 590 patients suspected of having a minor or cryptic genomic imbalance as the cause of mental retardation with dysmorphic signs +/− malformations have been investigated with high-resolution comparative genomic hybridisation (HR-CGH) in our diagnostic laboratory. Thirty-six patients had a small chromosomal aberration detected by routine karyotyping, and 554 patients had a normal G-banded karyotype. In the latter group, a genomic imbalance was detected by HR-CGH in 40 patients (7.2%): 29 deletions, 3 duplications, 4 unbalanced translocations, and 4 occult trisomy mosaicisms. When microarray-based comparative genomic hybridisation (array-CGH) became available, all HR-CGH-positive samples were also investigated by 1 Mb resolution array-CGH for more precise mapping. From the 514 patients with normal HR-CGH findings, a subset of 20 patients with particularly high suspicion of having a chromosomal imbalance was selected for array-CGH. In four of them (20%), an imbalance was detected: three deletions and one duplication. Of note, 73 out of the 80 array-CGH mapped patients had a de novo chromosomal rearrangement (91%). Taken together, this work provides phenotype–genotype information on 80 patients with minor and cryptic chromosomal imbalances.

Inheritance of a terminal 7.1 Mb 18p deletion flanked by a 2.3 Mb duplication from a physically normal mother

Inheritance of a Terminal 7.1 Mb 18p Deletion Flanked by a 2.3 Mb Duplication From a Physically Normal Mother Doriana Misceo, Karen Helene Orstavik, Helle Lybaek, Inger Sandvig, Eli Ormerod, Gunnar Houge, and Eirik Frengen* Faculty of Medicine, Institute of Medical Genetics, University of Oslo, Oslo, Norway Department of Medical Genetics, Ulleva l University Hospital, Oslo, Norway Department of Medical Genetics, Rikshospitalet University Hospital, Oslo, Norway Faculty Division Rikshospitalet, University of Oslo, Oslo, Norway Center for Medical Genetics and Molecular Medicine, Haukeland University Hospital, Bergen, Norway Department of Pediatrics, Rikshospitalet University Hospital, Oslo, Norway