Project description:Background: Among full autosomal trisomies, only trisomies of chromosome 21 (Down syndrome, DS), 18 (Edward syndrome, ES) and 13 (Patau syndrome, PS) are compatible with postnatal survival. But the mechanisms, how a supernumerary chromosome disrupts the normal development and causes specific phenotypes, are still not fully explained. As an alternative to gene dosage effects due to the trisomic chromosome, a genome-wide transcriptional dysregulation has been postulated. The aim of this study was to define the transcriptional changes in trisomy 13, 18, and 21 during early fetal development in order to define whether (1) overexpression of genes of the trisomic chromosome contributes solely to the phenotype, if (2) all genes of the trisomic chromosome are upregulated similarly and whether the ratio of gene expression is in agreement with the gene dosis, (3) whether the different trisomies behave similarly in the characteristics of transcriptional dysregulation, and (4) whether transcriptional pattern can be potentially used in prenatal diagnosis. Methods: Using oligonucleotide microarrays (Affymetrix, U133 Plus 2.0), we analyzed whole genome expression profiles representing 54.000 probe sets in cultured amniocytes (AC) and chorion villus cells (CV) from pregnancies with a normal karyotype and with trisomies of human chromosomes 21, 18 and 13. Findings: We observed a low to moderate up-regulation for a subset of genes of the trisomic chromosomes. Transcriptional level of approximately 12-13 % of the supernumerary chromosome appeared similar to the respective chromosome pair in normal karyotypes. Expression values as well as the expression patterns of genes from the trisomic chromosome can distinguish the respective trisomic samples from euploid controls. A subset of chromosome 21-genes including the DSCR1-gene involved in fetal heart development was consistently up-regulated in different tissues (AC, CV) of trisomy 21 fetuses whereas only minor changes were found for genes of all other chromosomes. In contrast, in trisomy 13 and trisomy 18 vigorous downstream transcriptional changes were found. Interpretation: Global transcriptome analysis for autosomal trisomies 13, 18, and 21 supported a combination of the two major hypotheses. As several transcriptional pathways are altered, complex regulatory mechanisms are involved in the pathogenesis of autosomal trisomies. A genome-wide transcriptional dysregulation was predominantly observed in trisomies 13 and 18, whereas a more to chromosome 21 restricted expression alteration was found in trisomy 21. Keywords: Trisomy, Down syndrome, Patau syndrome, Edward syndrome, microarray, gene expression, amniocytes, chorion villus cells, gene dosage effect, DSCR1

Project description:Background: Among full autosomal trisomies, only trisomies of chromosome 21 (Down syndrome, DS), 18 (Edward syndrome, ES) and 13 (Patau syndrome, PS) are compatible with postnatal survival. But the mechanisms, how a supernumerary chromosome disrupts the normal development and causes specific phenotypes, are still not fully explained. As an alternative to gene dosage effects due to the trisomic chromosome, a genome-wide transcriptional dysregulation has been postulated. The aim of this study was to define the transcriptional changes in trisomy 13, 18, and 21 during early fetal development in order to define whether (1) overexpression of genes of the trisomic chromosome contributes solely to the phenotype, if (2) all genes of the trisomic chromosome are upregulated similarly and whether the ratio of gene expression is in agreement with the gene dosis, (3) whether the different trisomies behave similarly in the characteristics of transcriptional dysregulation, and (4) whether transcriptional pattern can be potentially used in prenatal diagnosis. Methods: Using oligonucleotide microarrays (Affymetrix, U133 Plus 2.0), we analyzed whole genome expression profiles representing 54.000 probe sets in cultured amniocytes (AC) and chorion villus cells (CV) from pregnancies with a normal karyotype and with trisomies of human chromosomes 21, 18 and 13. Findings: We observed a low to moderate up-regulation for a subset of genes of the trisomic chromosomes. Transcriptional level of approximately 12-13 % of the supernumerary chromosome appeared similar to the respective chromosome pair in normal karyotypes. Expression values as well as the expression patterns of genes from the trisomic chromosome can distinguish the respective trisomic samples from euploid controls. A subset of chromosome 21-genes including the DSCR1-gene involved in fetal heart development was consistently up-regulated in different tissues (AC, CV) of trisomy 21 fetuses whereas only minor changes were found for genes of all other chromosomes. In contrast, in trisomy 13 and trisomy 18 vigorous downstream transcriptional changes were found. Interpretation: Global transcriptome analysis for autosomal trisomies 13, 18, and 21 supported a combination of the two major hypotheses. As several transcriptional pathways are altered, complex regulatory mechanisms are involved in the pathogenesis of autosomal trisomies. A genome-wide transcriptional dysregulation was predominantly observed in trisomies 13 and 18, whereas a more to chromosome 21 restricted expression alteration was found in trisomy 21. Experiment Overall Design: The study included the following samples: Three samples with normal chromosomes in Amniocytes (AC) and chorion villus cells (CV) each, three samples with trisomy 13 in AC, three samples with trisomy 18 in CV, and three samples with trisomy 21 in AC and CV each.

Project description:To characterize aneuploidy driven phenotypes in human trisomies, we performed global transcriptome, proteome, and phenotypic analysis of primary human fibroblasts from individuals with Patau (trisomy 13), Edwards (trisomy 18), or Down syndromes.

Project description:We profiled gene expression at the maternal-fetal interface during the second trimester of pregnancy (13-22 wks) in trisomy 13 (T13; Patau syndrome, n = 4), trisomy 18 (T18; Edwards syndrome, n = 4), trisomy 21 (T21; Down syndrome, n = 8), and in euploid pregnancies (n = 4). FISH confirmed the ploidy of the samples. Global transcriptional profiling identified differentially expressed transcripts (? 2-fold) in T21 (n = 160), T18 (n = 80), and T13 (n = 125). The majority were upregulated. Unexpectedly, most of the misexpressed genes were not located on the relevant trisomic chromosome, suggesting genome-wide dysregulation. A much smaller proportion of the differentially expressed transcripts were encoded on the aneuploid chromosome, also implicating gene dosage (1-5). In T21, <10% of the genes were transcribed from that chromosome, all but one from the Down syndrome critical region (21q21-22), which is postulated to play an important role in the clinical phenotype. For T13 and T18, a higher proportion of the overexpressed genes were located on the trisomic chromosome. In T13, 15% of the upregulated genes were on the affected chromosome; 15 resided on the long arm, 13q11-14. In T18, the percentage increased to 24, 15 of which were also located on the long arm (18q11-22). Our data suggested that the placental (and possibly fetal) phenotypes that are associated with T13, T18 and T21 are driven by the combined effects of genome-wide phenomena and increased gene dosage from critical regions of the triploid chromosome. We profiled gene expression at the maternal-fetal interface during the second trimester of pregnancy (13-22 wks) in trisomy 13 (T13; Patau syndrome, n = 4), trisomy 18 (T18; Edwards syndrome, n = 4), trisomy 21 (T21; Down syndrome, n = 8), and in euploid pregnancies (n = 4). FISH confirmed the ploidy of the samples.

Project description:The organization and dynamics of chromatin within the in vivo interphase nucleus and the latter's relationship with transcriptional regulation are still not fully understood. To better understand these relationships, we studied a natural example of chromosomal disorganization: aneuploidy due to trisomies 13, 18 and 21. We hypothesized that the presence of an extra copy of one chromosome alters the CT distribution in the nucleus, which in turn perturbs transcriptional activity. We used microarrays to highlight the overall genome expression changes occurring in amniocytes and fibroblasts carrying a trisomy 13, 18 or 21.

Project description:We profiled gene expression at the maternal-fetal interface during the second trimester of pregnancy (13-22 wks) in trisomy 13 (T13; Patau syndrome, n = 4), trisomy 18 (T18; Edwards syndrome, n = 4), trisomy 21 (T21; Down syndrome, n = 8), and in euploid pregnancies (n = 4). FISH confirmed the ploidy of the samples. Global transcriptional profiling identified differentially expressed transcripts (≥ 2-fold) in T21 (n = 160), T18 (n = 80), and T13 (n = 125). The majority were upregulated. Unexpectedly, most of the misexpressed genes were not located on the relevant trisomic chromosome, suggesting genome-wide dysregulation. A much smaller proportion of the differentially expressed transcripts were encoded on the aneuploid chromosome, also implicating gene dosage (1-5). In T21, <10% of the genes were transcribed from that chromosome, all but one from the Down syndrome critical region (21q21-22), which is postulated to play an important role in the clinical phenotype. For T13 and T18, a higher proportion of the overexpressed genes were located on the trisomic chromosome. In T13, 15% of the upregulated genes were on the affected chromosome; 15 resided on the long arm, 13q11-14. In T18, the percentage increased to 24, 15 of which were also located on the long arm (18q11-22). Our data suggested that the placental (and possibly fetal) phenotypes that are associated with T13, T18 and T21 are driven by the combined effects of genome-wide phenomena and increased gene dosage from critical regions of the triploid chromosome.

Project description:Aneuploidy, and especially the presence of unpaired chromosomal axes during meiosis, can cause infertility. However, it is not known if extra, unpaired autosomal chromosome segments acquire characteristic protein modifications and undergo transcriptional silencing (meiotic silencing of unpaired chromatin, or MSUC) similar to the unpaired regions of the X and Y chromosomes during spermatogenesis. We used three mouse models of Down syndrome, involving either an extra chromosome or translocation trisomy, to test requirements and consequences of meiotic protein modification and gene silencing in spermatocytes. These models reveal that copy number alone is not sufficient for up-regulation of genes in the trisomic interval, and that MSUC-promoting modifications are not sufficient for down-regulation of genes that reside in unpaired chromatin during meiosis. The position of a trisomic region relative to a centromere, the pairing status of the centromere, and the physical extent of the unpaired chromosomal region all affected assembly of meiotic protein modifications typical of MSUC. One key determinant to modification of unpaired chromatin and infertility in trisomy male mice appears to be proximity of unpaired chromatin to a centromere. Furthermore, the presence of an extra, unpaired centromere, but not translocation trisomy, causes global misregulation of transcription in spermatocytes. Thus, neither trisomy per se, nor chromatin modifications of unpaired chromosomal segments, have major effects on gene expression or meiotic success, but an intact unpaired chromosome has profoundly negative effects on meiotic gene expression.

Project description:Trisomy is a form of aneuploidy associated with embryonic and postnatal abnormalities in mammals. Understanding the underlying mechanisms involved in mutant phenotypes is broadly important and may lead to new strategies to treat clinical manifestations in individuals with trisomies, such as trisomy 21 (Down syndrome). While increased gene dosage effects due to a trisomy may account for the mutant phenotypes, there is also the possibility that phenotypic consequences of a trisomy can arise because of the presence of a freely segregating extra chromosome with its own centromere, i.e., a ‘free trisomy’ independent of gene dosage effects. Presently, there are no reports of attempts to functionally separate these two types of effects. To fill this gap, here we describe a strategy that employed two new mouse models of Down syndrome, Ts65Dn;Df(17)2Yey/+ and Dp(16)1Yey/Df(16)8Yey. Both models carry triplications of the same 103 human chromosome 21 gene orthologs; however, only Ts65Dn;Df(17)2Yey/+ mice carry a free trisomy. Comparative analysis of these two models revealed the gene dosage-independent effect of an extra chromosome at the phenotypic level for the first time, as reflected by impairments of Ts65Dn;Df(17)2Yey/+ males in T-maze tests when compared with Dp(16)1Yey/Df(16)8Yey males. Results from the transcriptomic analysis suggest the extra chromosome may play a major role in trisomy-associated expression alterations of disomic genes beyond gene dosage effects. This model system can now be used to deepen our mechanistic understanding of this common human aneuploidy and obtain new insights into the effects of free trisomies in other human diseases such as cancers.

Project description:Phenotypes in chromosome abnormalities do not arise as a mere summation of the specific effects of dosage-sensitive genes, but as a result of the synergistic actions of whole chromosomes. Recent studies on yeast and mammalian cells have demonstrated that aneuploidy exerts detrimental effects on organismal growth and development, regardless of the karyotype, suggesting that aneuploidy-associated stress plays an important role in disease pathogenesis. However, whether and how this effect alters cellular homeostasis and long-term features of human disease are not fully understood. Here, we aimed to investigate cellular stress responses in human trisomy syndromes, using fibroblasts and induced pluripotent stem cells (iPSCs). Dermal fibroblasts derived from patients with trisomy 21, 18 and 13 showed a severe impairment of cell proliferation and enhanced premature senescence. These phenomena were accompanied by perturbation of protein homeostasis, leading to the accumulation of protein aggregates. We found that treatment with sodium 4-phenylbutyrate (4-PBA), a chemical chaperone, decreased the protein aggregates in trisomy fibroblasts. Notably, 4-PBA treatment successfully prevented the progression of premature senescence in secondary fibroblasts derived from trisomy 21 iPSCs. Our study reveals aneuploidy-associated stress as a potential therapeutic target for human trisomies, including Down syndrome.

Project description:Several studies have investigated the gene expression profiles in trisomies 21 and 18 to identify the expression signatures that are characteristic of each of these specific aneuploidy conditions. We hypothesized that the viability of cells with gross genomic imbalances might be associated with the activation of resilience mechanisms that are common to different trisomies and that are reflected by specific shared gene expression patterns. Microarray gene expression analysis of amniocytes from fetuses with trisomy 21 or trisomy 18 was conducted to detect such common expression signatures. Comparative analysis of significantly differentially expressed genes in trisomies 18 and 21 identified 6 dysregulated genes common to both trisomies: OTUD5, ADAMTSL1, TADA2A, PPID, PIAS2, and MAPRE2. These genes are involved in apoptosis, ubiquitination, protein folding, and cell division. Functional analysis demonstrated that both trisomies showed dysregulation of the PI3K/AKT pathway, cell cycle G2/M DNA damage checkpoint regulation, and cell death and survival, as well as inhibition of the upstream regulator TP53. Our data demonstrated that trisomies 18 and 21 share common gene expression signatures, implying that common mechanisms of resilience might be activated in aneuploid cells to resist large genomic imbalances. Studies of other trisomies might further clarify mechanisms activated in trisomy syndromes.