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Query: UMLS:C0036341 (
schizophrenia
)
60,220
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We have discovered two genes,
RSRC1
and ARHGAP18, associated with
schizophrenia
and in an independent study provided additional support for this association. We have both discovered and verified the association of two genes,
RSRC1
and ARHGAP18, with
schizophrenia
. We combined a genome-wide screening strategy with neuroimaging measures as the quantitative phenotype and identified the single nucleotide polymorphisms (SNPs) related to these genes as consistently associated with the phenotypic variation. To control for the risk of false positives, the empirical P-value for association significance was calculated using permutation testing. The quantitative phenotype was Blood-Oxygen-Level Dependent (BOLD) Contrast activation in the left dorsal lateral prefrontal cortex measured during a working memory task. The differential distribution of SNPs associated with these two genes in cases and controls was then corroborated in a larger, independent sample of patients with
schizophrenia
(n=82) and healthy controls (n=91), thus suggesting a putative etiological function for both genes in
schizophrenia
. Up until now these genes have not been linked to any neuropsychiatric illness, although both genes have a function in prenatal brain development. We introduce the use of functional magnetic resonance imaging activation as a quantitative phenotype in conjunction with genome-wide association as a gene discovery tool.
...
PMID:Gene discovery through imaging genetics: identification of two novel genes associated with schizophrenia. 1906 46
The imaging genetics approach to studying the genetic basis of disease leverages the individual strengths of both neuroimaging and genetic studies by visualizing and quantifying the brain activation patterns in the context of genetic background. Brain imaging as an intermediate phenotype can help clarify the functional link among genes, the molecular networks in which they participate, and brain circuitry and function. Integrating genetic data from a genome-wide association study (GWAS) with brain imaging as a quantitative trait (QT) phenotype can increase the statistical power to identify risk genes. A QT analysis using brain imaging (DLPFC activation during a working memory task) as a quantitative trait has identified unanticipated risk genes for
schizophrenia
. Several of these genes (
RSRC1
, ARHGAP18, ROBO1-ROBO2, GPC1, TNIK, and CTXN3-SLC12A2) have functions related to progenitor cell proliferation, migration, and differentiation, cytoskeleton reorganization, axonal connectivity, and development of forebrain structures. These genes, however, do not function in isolation but rather through gene regulatory networks. To obtain a deeper understanding how the GWAS-identified genes participate in larger gene regulatory networks, we measured correlations among transcript levels in the mouse and human postmortem tissue and performed a gene set enrichment analysis (GSEA) that identified several microRNA associated with
schizophrenia
(448, 218, 137). The results of such computational approaches can be further validated in animal experiments in which the networks are experimentally studied and perturbed with specific compounds. Glypican 1 and FGF17 mouse models for example, can be used to study such gene regulatory networks. The model demonstrates epistatic interactions between FGF and glypican on brain development and may be a useful model of negative symptom
schizophrenia
.
...
PMID:Identifying gene regulatory networks in schizophrenia. 2060 Sep 88
RSRC1
, whose polymorphism is associated with altered brain function in
schizophrenia
, is a member of the serine and arginine rich-related protein family. Through homozygosity mapping and whole exome sequencing we show that
RSRC1
mutation causes an autosomal recessive syndrome of intellectual disability, aberrant behaviour, hypotonia and mild facial dysmorphism with normal brain MRI. Further, we show that
RSRC1
is ubiquitously expressed, and that the
RSRC1
mutation triggers nonsense-mediated mRNA decay of the
RSRC1
transcript in patients' fibroblasts. Short hairpin RNA (shRNA)-mediated lentiviral silencing and overexpression of
RSRC1
in SH-SY5Y cells demonstrated that
RSRC1
has a role in alternative splicing and transcription regulation. Transcriptome profiling of
RSRC1
-silenced cells unravelled specific differentially expressed genes previously associated with intellectual disability, hypotonia and
schizophrenia
, relevant to the disease phenotype. Protein-protein interaction network modelling suggested possible intermediate interactions by which
RSRC1
affects gene-specific differential expression. Patient-derived induced pluripotent stem cells, differentiated into neural progenitor cells, showed expression dynamics similar to the
RSRC1
-silenced SH-SY5Y model. Notably, patient neural progenitor cells had 9.6-fold downregulated expression of IGFBP3, whose brain expression is affected by MECP2, aberrant in Rett syndrome. Interestingly, Igfbp3-null mice have behavioural impairment, abnormal synaptic function and monoaminergic neurotransmission, likely correlating with the disease phenotype.
...
PMID:RSRC1 mutation affects intellect and behaviour through aberrant splicing and transcription, downregulating IGFBP3. 2952 54
