Project description:Aneuploidy, i.e., variation in the number of individual chromosomes (chromosomal aneuploidy) or chromosome segment (segmental aneuploidy) is associated with developmental abnormalities and reduced fitness in all species examined, is the leading cause of miscarriages and mental retardations and a hallmark of cancer. Despite their documented importance in disease the effects of aneuploidies on the transcriptome remains largely unknown. Here we have examined the expression output in seven deficiency heterozygotes as single deficiencies and in all pairwise combinations. The results show that genes in one copy are buffered, i.e., are expressed above the expected 50% expression level compared to wild type and the buffering is general and not influenced by additional haploid regions. Long genes are significantly better buffered than short genes and our analysis suggests that gene length is the primary determinant for the degree of buffering. For short genes the degree of buffering depends on expression level and expression pattern. Furthermore, the results show that in deficiency heterozygotes the expression of genes involved in proteolysis is enhanced and negatively correlates with the degree of buffering. Our results suggest that proteolysis is a general response induced by aneuploidy. We prepared total RNA from flies heterozygous for seven different deletions, Df(3R)ED10953, Df(2L)ED4559, Df(2R)ED1770, Df(2R)ED1612, Df(2L)ED3, Df(3R)ED5071 or Df(3R)ED7665 in two or three single biological replicates or in pairwise combinations, as well as from six biological replicates of wild type control flies.

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). Keywords: dose response

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:Aneuploidy, an incorrect chromosome number, is the leading cause of miscarriages and mental retardation in humans and is a hallmark of cancer. We examined the effects of aneuploidy on primary mouse cells by generating a series of cell lines that carry an extra copy of one of four mouse chromosomes. In all four trisomic lines proliferation was impaired and metabolic properties were altered. Immortalization, the acquisition of the ability to proliferate indefinitely, was also affected by the presence of an additional chromosome, with some chromosomes inhibiting immortalization while others accelerating the process. Our data indicate that aneuploidy decreases not only organismal but also cellular fitness and elicits traits that are shared between different aneuploid cells. Keywords: cell type comparison

Project description:Chromosomal abnormalities are important causes of miscarriages. To delinate the chromosomal abnormalities in miscarriages, 564 miscarriages were collected and analyzed using single nucleotide polymorphism (SNP) array. 336 (59.6%) miscarriages were with abnormal copy number variations (CNVs), including 325 (57.6%) miscarriages with pathogenic CNVs and 11 (2%) miscarriages with variations of unknown significance (VOUS). The remaining 228 (40.4%) miscarriages had no clinically relevant chromosomal variants.

Project description:Aneuploidy, an imbalance in chromosome copy numbers, causes genetic disorders, and drives cancer progression, drug tolerance, and antimicrobial resistance. While aneuploidy can confer stress resistance, it is not well understood how cells overcome the fitness burden caused by aberrant chromosomal copy numbers. Studies using both systematically generated and natural aneuploid yeasts triggered an intense debate about the role of dosage compensation, concluding that aneuploidy is transmitted to the transcriptome and proteome without significant buffering at the chromosome-wide level, and is, at least in lab strains, associated with significant fitness costs. Conversely, systematic sequencing and phenotyping of large collections of natural isolates revealed that aneuploidy is frequent and has few, if any, fitness costs in nature. To address these discrepant findings, we developed a platform that yields highly precise proteomic measurements across large numbers of genetically diverse samples and applied it to natural isolates collected as part of the 1011 genomes project (Peter, J. et al, 2018). For 613 of the isolates, we were able to match the proteomes to their corresponding transcriptomes and genomes, subsequently quantifying the effect of aneuploidy on gene expression by comparing 95 aneuploid with 518 euploid strains. We find, as in previous studies, that aneuploid gene dosage is not buffered chromosome-wide at the transcriptome level. Importantly, in the proteome, we detect an attenuation of aneuploidy by about 25% below the aneuploid gene dosage in natural yeast isolates. Furthermore, this chromosome-wide dosage compensation is associated with the ubiquitin-proteasome system (UPS), which is expressed at higher levels and has increased activity across natural aneuploid strains. Thus, through systematic exploration of the species-wide diversity of the yeast proteome, we shed light on a long-standing debate about the biology of aneuploids, revealing that aneuploidy tolerance is mediated through chromosome-wide dosage compensation at the proteome level.

Project description:We measured gene expression in two isogenic Drosophila lines heterozygous for long deletions. We find that a majority of genes are at least partially compensated at transcription for ½-fold dosage. The degree of compensation does not vary among functional classes of genes. Compensation for deletions is stronger for highly expressed genes than for genes with low expression level. In contrast, the degree of compensation for duplications observed in Gupta et al, 2006, (J. of Biology 5, 3) data for heterozygotes for a duplication is stronger for weakly expressed genes. Thus, transcriptional compensation appears to be based on general regulatory mechanisms that insure high levels of transcription some genes and low transcription levels of other genes, instead of precise maintenance of a particular homeostatic expression level. Given the ubiquity of transcriptional compensation, dominance of wild-type alleles may be at least partially caused by of the regulation at transcription level. Keywords: Genome-wise dosage compensation study

Project description:Buffering and proteolysis are induced upon segmental haploidy in Drosophila melanogaster.

Project description:Aneuploidy, an incorrect chromosome number, is the leading cause of miscarriages and mental retardation in humans and is a hallmark of cancer. We examined the effects of aneuploidy on primary mouse cells by generating a series of cell lines that carry an extra copy of one of four mouse chromosomes. In all four trisomic lines proliferation was impaired and metabolic properties were altered. Immortalization, the acquisition of the ability to proliferate indefinitely, was also affected by the presence of an additional chromosome, with some chromosomes inhibiting immortalization while others accelerating the process. Our data indicate that aneuploidy decreases not only organismal but also cellular fitness and elicits traits that are shared between different aneuploid cells. Experiment Overall Design: The mRNAs from 9 different mouse embryo fibroblast (MEF) lines with a normal complement of chromosomes were compared to mRNAs from 1 MEF line with three copies of chromosome 1, 4 MEF lines with three copies of chrmosome 13, 3 MEF lines with three copies of chromosome 16 and 1 MEF line with three copies of chromosome 19.

Project description:Aneuploidy, the condition of having an abnormal number of chromosomes, is a hallmark of cancer cells. Recent work performed in yeast and mouse models suggests that aneuploidy interferes with cell proliferation and organism development. However, other recent experiments suggested that aneuploidy might play a positive role in tumor initiation and/or progression and in the emergence of chemotherapy as well as antibiotic resistances. Given its general deleterious effects on cellular fitness, how could aneuploidy be beneficial? In this set of experiments we plan to provide evidence that aneuploidy induces phenotypic variation through direct and indirect changes not only at the transcriptome but also at the proteome level.