Project description:To study the effect of structural changes on expression, we assessed gene expression in genomic disorder mouse models. Both a microdeletion and its reciprocal microduplication mapping to mouse chromosome 11 (MMU11), which model the rearrangements present in Smith-Magenis (SMS) and Potocki-Lupski (PTLS) syndromes patients, respectively, have been engineered. We profiled the transcriptome of five different tissues affected in human patients in mice with 1n (Deletion/+), 2n (+/+), 3n (Duplication/+) and uniallelic 2n (Deletion/Duplication) copies of the same region in an identical genetic background. The most differentially expressed transcripts between the four studied genotypes were ranked. A highly significant propensity, are mapping to the engineered SMS/PTLS interval in the different tissues. A statistically significant overrepresentation of the genes mapping to the flanks of the engineered interval was also found in the top-ranked differentially expressed genes. A phenomenon efficient across multiple cell lineages and that extends along the entire length of the chromosome, tens of megabases from the breakpoints. These long-range effects are unidirectional and uncoupled from the number of copies of the copy number variation (CNV) genes. Thus, our results suggest that the assortment of genes mapping to a chromosome is not random. They also indicate that a structural change at a given position of the human genome may cause the same perturbation in particular pathways regardless of gene dosage. An issue that should be considered in appreciating the contribution of this class of variation to phenotypic features. Keywords: Genetic modification Comparisons of heterozygous mice carrying a duplication, Dp(11)17/+, a deletion, Df(11)17)/+, or both rearrangements, Df(11)17/Dp(11)17, with wild-type mice. Gene expression of at least two male individuals of each of the four genotypes were measured in hippocampus, cerebellum, testis, kidney and heart.

Project description:The aim of the experiment is to illuminate the molecular mechanisms of cellular reprogramming. We have isolated cells at intermediate stages of reprogramming and analysed their gene expression profiles. D6s4B5 1N- are CD44+ ICAM1-, Nanog-GFP-, D6s4B5 1N+ are CD44+ ICAM1-, Nanog-GFP+, D6s4B5 2N- are CD44- ICAM1-, Nanog-GFP-, D6s4B5 2N+ are CD44- ICAM1-, Nanog-GFP+, D6s4B5 3N- are CD44- ICAM1+, Nanog-GFP-, D6s4B5 3N+ are CD44- ICAM1+, Nanog-GFP+, all from day 10 of reprogramming. Day15 D6s4B5 3N+ are CD44- ICAM1+, Nanog-GFP+ from day 15, iPSC are an established iPSC clone, E14 a reference Embryonic Stem Cell line and MEF are Mouse Embryonic Fibroblasts generated with an iPSC clone D6s4B5.

Project description:Background Triploidy can occur in all species but is often lethal in birds and mammals. In amphibian, invertebrates and numerous species of fishes, triploid animals are viable and undistinguishable from diploid individuals. Gametogenesis is often affected and most animals are sterile for at least one sex, and gametes for the other sex are often unfertile. Although the majority of triploid oysters are sterile (beta individuals, 3nb), a low but persistent proportion of male and female animals produce gametes (alpha individuals, 3na). Thus, oysters constitute a unique model to study the effect of triploidy on germ cells development of both male and females. In this study, we used microarray to study the consequences of polyploidy on triploid oyster germ cells mitosis and meiosis. Results We compared the transcriptome of gonads of 3na and 3nb oyster gonads over the course of gametogenesis to the transcriptome of diploid (2n) oyster gonads. This study allowed us to reveal an increase in DNA repair and apoptosis through the NF-kappaB pathway, and a decrease in actin remodeling and chromatin remodeling in all 3n oysters. The comparison of 3na and 3nb individuals with 2n revealed that a pachytene checkpoints may be responsible for the success in gametogenesis of 3na individuals and for the observed delay in gametogenesis. However, the sterility of 3nb individuals can be explained by a disruption of sex determinism mechanisms. Indeed 3nb females express male-specific genes including enkurin and an Elav-like gene, and 3nb males express female-specific genes including Forkhead box L2 and beta-catenin. Conclusions Our results bring back to the front of the research field the questions of genetic sex determinism, mitosis/meiosis control, pachytene checkpoint, and cell type specific DNA damage pathways. Furthermore, this study identifies numerous new candidate genes which function should now be studied in details in oysters and in other triploid animals in order to elucidate the complex mechanisms involved in the regulation of triploid cells division. Triploid spats were obtained by crossing tetraploid males and diploid females in the ifremer experimental hatchery (La tremblade, Charente Maritime, France). We performed microarray analysis on a total of 35 individual triploid gonads that can be grouped as follow: 3n stage 0 (4 individuals), 3n alpha Stage 1 (8 individuals), 3n beta Stage 1 (8 individuals), 3n alpha Stage 3 male (4 individuals), 3n beta Stage 3 male (3 individuals), 3n alpha Stage 3 female (4 individuals), and 3n beta stage 3 female (4 individuals).

Project description:To define the specific function of Pax3:Foxo1a in G2/M stage, we compared whole mRNA expressions of mouse alveolar rhabdomyosarcoma tumor cells in G2/M stage (4N) with or without Pax3:Foko1a knockdown (si_YFP or si_control). The exerimental plan will include triplicate samples for sorted cells at G1/G0 (2N) and G2/M (4N) and dupicate samples for S (3N) phase cells for a total of 16 samples.

Project description:The Dp1Tyb mouse model for Down syndrome contains a duplication of 23Mb of mouse chromosome 16 (Mmu16) that is orthologous to human chromosome 21 (Hsa21). This region contains 145 coding genes, and thus these genes are present in 3 copies. Dp1Tyb mice display congenital heart defects, similar to the ones seen in people with Down syndrome. These defects include ventricular and atrio-ventricular septal defects and are seen at embryonic day 14.5 (E14.5) of gestation. One of the 145 genes present in 3 copies in Dp1Tyb mice codes for a kinase called DYRK1A. We found that by crossing Dp1Tyb mice with mice carrying a heterozygous Dyrk1a loss of function allele, thereby reducing the dosage of the Dyrk1a gene from 3 to 2 copies, we rescue the congenital heart defects. Thus 3 copies of Dyrk1a are required to cause heart defects, and, presumably, increased DYRK1A protein is required for the heart defects. We compared the phosphoproteome in Dp1Tyb versus Dp1TybDyrk1a+/+/- embryonic hearts in order to discover alterations in phosphoproteins that could pinpoint molecular mechanisms that give rise to the congenital heart defects. The two strains (Dp1Tyb and Dp1TybDyrk1a+/+/-) differ only in the copy number of Dyrk1a (3 v 2) and thus differences in phosphoproteins would include both direct and indirect targets of DYRK1A activity.

Project description:Chromosomal instability which involves deletion and duplication of chromosomes or chromosome parts is a common feature of cancers, and deficiency screens are commonly used as a method to find genes involved in different biological pathways. Still, how gene expression from whole chromosomes or large chromosomal domains is affected by deficiencies, duplications or chromosome loss is largely unknown. Using expression microarrays of deficiency hemizygotes and a duplication hemizygote we show that expressed genes are significantly buffered when present in a deficiency hemizygote and that the buffering effect is general and not mainly caused by feedback regulation of individual genes. Differentially expressed genes are in general better buffered than ubiquitously expressed genes when present in one copy. When present in three copies, differentially expressed genes are in general less buffered than ubiquitously expressed genes. Furthermore, we show that the 4th chromosome is compensated in response to dose differences. Our results suggest that general mechanisms exist to stimulate and to repress gene expression of aneuploidy regions and on the 4th chromosome this compensation is mediated by POF (Painting of Fourth). Experiment Overall Design: We prepared total RNA from flies heterozygous for three different deletions, Df(2L)J-H, Df (2L)ED4470, Df(2L)ED4651, flies heterozygous for the duplication Dp(2;2)Cam3 and flies with only one chromosome 4, or three copies of the 4th chromosome, as well as from wild type control flies. Three biological replicates of all genotypes were prepared.

Project description:The biological significance of a small supernumerary marker chromosome generating a 9p24.1 duplication/triplication including a triplication of the GLDC gene encoding glycine decarboxylase in two patients with psychosis is unclear. Performing functional genomic fine-mapping using a series of copy number variant mouse models, we identify that additional copies of Gldc reduce extracellular glycine levels as determined by optical FRET in dentate gyrus (DG) but not in CA1, suppressed long-term potentiation (LTP) in mPP-DG synapses but not in CA3-CA1 synapses, reduced the activity of biochemical pathways implicated in schizophrenia and mitochondrial bioenergetics, and displayed prepulse inhibition, startle habituation, latent inhibition, working memory, sociability and social preference deficits. Our results thus provide a link between a genomic copy number variation, biochemical, cellular and behavioral phenotypes, demonstrating that GLDC negatively regulates excitatory neurotransmission, supporting the view that extra copies of GLDC in the genome may contribute significantly to the development of neuropsychiatric disorders.

Project description:Background. Most methods for constructing aneuploid yeast strains that have gained a specific chromosome rely on spontaneous failures of cell division fidelity. In Saccharomyces cerevisiae, extra chromosomes can be obtained when errors in meiosis or mitosis lead to nondisjunction, or when nuclear breakdown occurs in heterokaryons. We describe a strategy for constructing N+1 disomes that does not require such spontaneous failures. The method combines two well-characterized genetic tools: a conditional centromere that transiently blocks disjunction of one specific chromosome, and a duplication marker assay that identifies disomes among daughter cells. To test the strategy, we targeted chromosomes III, IV, and VI for duplication. Results. The centromere of each target chromosome was replaced by a conditional centromere that can be blocked by growth in galactose, and ura3::HIS3, a duplication marker. Transient exposure to galactose induced the appearance of colonies carrying duplicated markers for chromosomes III or IV, but not VI. Microarray-based comparative genomic hybridization (CGH) confirmed that disomic strains carrying extra chromosome III or IV were generated. Chromosome VI contains several genes known to be deleterious when overexpressed, including the beta-tubulin gene TUB2. To test whether a tubulin stoichiometry imbalance prevents viability in cells carrying an extra chromosome VI, we supplied the parent strain with extra copies of the alpha-tubulin gene TUB1, then induced nondisjunction. Galactose-dependent chromosome VI disomes were produced, as revealed by CGH. Some chromosome VI disomes also carried extra, unselected copies of additional chromosomes. Conclusions. This method causes efficient nondisjunction of a targeted chromosome and allows resulting disomic cells to be identified and maintained. We used the method to test the role of tubulin imbalance in the apparent lethality of disomic chromosome VI. Our results indicate that a tubulin imbalance is necessary for disomic VI lethality, but it may not be the only dosage-dependent effect. Keywords: comparative genomic hybridization, CGH

Project description:Inverted duplications are a common type of copy number variation (CNV) in germline and somatic genomes. Large duplications that include many genes can lead to both neurodevelopmental phenotypes in children and gene amplifications in tumors. There are several models for inverted duplication formation, most of which include a dicentric chromosome intermediate followed by breakage-fusion-bridge (BFB) cycles, but the mechanisms that give rise to the inverted dicentric chromosome in most inverted duplications remain unknown. Here we have combined high-resolution array CGH, custom sequence capture, next-generation sequencing, and long-range PCR to analyze the breakpoints of 50 nonrecurrent inverted duplications in patients with intellectual disability, autism, and congenital anomalies. Sequence analysis of breakpoint junctions reveals a normal-copy disomic spacer between inverted and non-inverted copies of the duplication. Further, short inverted repeats are present at the boundary of the disomic spacer and the inverted duplication. These data support a mechanism of inverted duplication formation whereby a chromosome with a double-strand break intrastrand pairs with itself to form a “hairpin” intermediate that, after DNA replication, produces a dicentric inverted chromosome with a disomic spacer corresponding to the site of the hairpin. We also find evidence of short insertions and inversions at inverted duplication junctions, consistent with a DNA replication-based CNV mechanism. This process can give rise to inverted duplications adjacent to terminal deletions, inverted duplications juxtaposed to translocations, and inverted duplication ring chromosomes

Project description:The systematic deep sequencing analysis provided a comprehensive understanding of the transcriptome complexity of 2n and 3n Fujian oyster. This information broadens our understanding of the mechanisms of C.angulata polyploidization and contributes to molecular and genetic research by enriching the oyster database. This is the first report on genome-wide transcriptional analysis of adductor muscle of diploid and triploid Fujian oyster and has demonstrated triploid oysters are morphologically almost identical to their diploid counterparts, but have faster growth, due to the reorientation of energetic allocation from gametogenesis to somatic investment. This study provides a foundation for further analysis of the gene expression patterns and signaling pathways which regulate the molecular mechanisms of diploid and triploid oyster.