Recent schizophrenia (SCZ) studies have reported an increased burden of de novo copy number variants (CNVs) and identified specific high-risk CNVs, although with variable phenotype expressivity. However, the pathogenesis of SCZ has not been fully elucidated. Using array comparative genomic hybridization, we performed a high-resolution genome-wide CNV analysis on a mainly (92%) Japanese population (1699 SCZ cases and 824 controls) and identified 7066 rare CNVs, 70.0% of which were small (<100 kb). Clinically significant CNVs were significantly more frequent in cases than in controls (odds ratio=3.04, P=9.3 × 10, 9.0% of cases). We confirmed a significant association of X-chromosome aneuploidies with SCZ and identified 11 de novo CNVs (e.g., MBD5 deletion) in cases. In patients with clinically significant CNVs, 41.7% had a history of congenital/developmental phenotypes, and the rate of treatment resistance was significantly higher (odds ratio=2.79, P=0.0036). We found more severe clinical manifestations in patients with two clinically significant CNVs. Gene set analysis replicated previous findings (e.g., synapse, calcium signaling) and identified novel biological pathways including oxidative stress response, genomic integrity, kinase and small GTPase signaling. Furthermore, involvement of multiple SCZ candidate genes and biological pathways in the pathogenesis of SCZ was suggested in established SCZ-associated CNV loci. Our study shows the high genetic heterogeneity of SCZ and its clinical features and raises the possibility that genomic instability is involved in its pathogenesis, which may be related to the increased burden of de novo CNVs and variable expressivity of CNVs.
SummaryThe vegetative growth of Arabidopsis thaliana can be divided into two phases. The transition from the juvenile (early) phase to the adult (later) phase is associated with changes in several morphological features of leaves, such as the shape of leaf blades, the number of trichomes and patterns of venation. In a screening of mutants with altered morphological identities of leaves, we found one which we named juvenile lea¯ess and misshapen shoot apical meristem (jam). The mutation represented a new allele of the WUSCHEL (WUS) gene, and, in its presence, plants produced no juvenile leaves. Analysis of the morphology of mutant plants revealed that all the rosette leaves had characteristics of adult leaves. The formation of the ®rst rosette leaf in the wus(jam) mutant was markedly delayed, and occurred at the almost same time as formation of the third or fourth leaf in wild-type plants. In the wild-type, these leaves correspond to the ®rst adult leaves. Analysis by RT±PCR showed that transcripts of WUS accumulated in shoot apices and roots, but not in cotyledons and leaves. The present results suggest that the WUS gene controls the morphological traits of rosette leaves either directly or indirectly. In view of the predicted function of the WUS gene, namely maintenance of stem cells within the shoot apical meristem, we suggest that the lack of juvenile leaves in the mutant might have been caused by interruption of leaf initiation during the juvenile phase or by halting of an entire process of formation of juvenile leaves.
We have investigated physical distances and directions of transposition of the maize transposable element Ac in Arabidopsis thaliana. We prepared a transferred DNA (T-DNA) construct that carried a non-autonomous derivative of Ac with a site for cleavage by endonuclease I-SceI (designated dAc-I-RS element). Another cleavage site was also introduced into the T-DNA region outside dAc-I-RS. Three transgenic Arabidopsis plants were generated, each of which had a single copy of the T-DNA at a different chromosomal location. These transgenic plants were crossed with the Arabidopsis that carried the gene for Ac transposase and progeny in which dAc-I-RS had been transposed were isolated. After digestion of the genomic DNA of these progeny with endonuclease I-SceI, sizes of segment of DNA were determined by pulse-field gel electrophoresis. We also performed linkage analysis for the transposed elements and sites of mutations near the elements. Our results showed that 50% of all transposition events had occurred within 1,700 kb on the same chromosome, with 35% within 200 kb, and that the elements transposed in both directions on the chromosome with roughly equal probability. The data thus indicate that the Ac-Ds system is most useful for tagging of genes that are present within 200 kb of the chromosomal site of Ac in Arabidopsis. In addition, determination of the precise localization of the transposed dAc-I-RS element should definitely assist in map-based cloning of genes around insertion sites.
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