Project description:An unbalanced karyotype, a condition known as aneuploidy, has a profound impact on cellular physiology and is a hallmark of cancer. Determining how aneuploidy affects cells is thus critical to understanding tumorigenesis. Here we show that aneuploidy interferes with the degradation of autophagosomes within lysosomes. Mis-folded proteins that accumulate in aneuploid cells due to aneuploidy-induced proteomic changes overwhelm the lysosome with cargo, leading to the observed lysosomal degradation defects. Importantly, aneuploid cells respond to lysosomal saturation. They activate a lysosomal stress pathway that specifically increases the expression of genes needed for autophagy-mediated protein degradation. Our results reveal lysosomal saturation as a universal feature of the aneuploid state that must be overcome during tumorigenesis.

Project description:Aneuploidy causes a proliferative disadvantage in all normal cells analyzed to date, yet this condition is associated with a disease characterized by unabated proliferative potential, cancer. The mechanisms that allow cancer cells to tolerate the adverse effects of aneuploidy are not known. To probe this question, we identified aneuploid yeast strains with improved proliferative abilities. Their molecular characterization revealed strain-specific genetic alterations as well as mutations shared between different aneuploid strains. Among the latter, a loss-of-function mutation in the gene encoding the deubiquitinating enzyme Ubp6 improves growth rates in four different aneuploid yeast strains by attenuating the changes in intracellular protein composition caused by aneuploidy. Our results demonstrate the existence of aneuploidy-tolerating mutations that improve the fitness of multiple different aneuploidies and highlight the importance of ubiquitin-proteasomal degradation in suppressing the adverse effects of aneuploidy.

Project description:Aneuploidy, an abnormal chromosome composition, results in a stoichiometric imbalance of protein complexes, which jeopardizes the fitness of aneuploid cells. Aneuploid cells thus need to compensate for the imbalanced DNA levels by regulating their RNA and protein levels, a phenomenon known as dosage compensation. However, the molecular mechanisms involved in dosage compensation in human cells – and whether they can be targeted to selectively kill aneuploid cancer cells – remain unknown. Here, we addressed this question via molecular dissection of multiple diploid vs. aneuploid cell models. Using genomic and functional profiling of a novel isogenic system of RPE1-hTERT cells with various degrees of aneuploidy, we found that aneuploid cells cope with both transcriptional burden and proteotoxic stress. At the mRNA level, aneuploid cells increased RNA synthesis, but concomitantly elevated several RNA degradation pathways, in particular the nonsense-mediated decay (NMD) and the microRNA-mediated mRNA silencing pathways. Consequently, aneuploid cells were more sensitive to the genetic or chemical perturbation of several key components of these RNA degradation pathways. At the protein level, aneuploid cells experienced proteotoxic stress, resulting in reduced translation and increased protein degradation, rendering them more sensitive to proteasome inhibition. These findings were recapitulated across hundreds of human cancer cell lines and primary tumors, confirming that both non-transformed and transformed cells alter their RNA and protein metabolism in order to adapt to the aneuploid state. Our results reveal that aneuploid cells are dependent on the over- or under-activation of several nodes along the gene expression process, identifying these pathways as clinically-actionable vulnerabilities of aneuploid cells.

Project description:Aneuploidy causes a proliferative disadvantage in all cells analyzed to date, yet this condition is associated with a disease characterized by unabated proliferative potential, cancer. The mechanisms that allow cancer cells to tolerate the adverse effects of aneuploidy are not known. To probe this question, we identified aneuploid yeast strains with high proliferative abilities and characterized their genetic alterations. We found both strain-specific genetic alterations and mutations shared between different aneuploid strains. One such mutation, a loss of function mutation in the gene encoding the deubiquitinating enzyme UBP6, improves growth rates in four different aneuploid yeast strains. Our data further suggest that deletion of UBP6 attenuates the effects of aneuploidy on cellular protein composition. Our results demonstrate the existence of aneuploidy-tolerating mutations that improve the fitness of multiple different aneuploidies and highlight the importance of ubiquitin-proteasomal degradation in suppressing the adverse effects of aneuploidy. This dataset contains both expression analysis and CGH of yeast strains bearing extra chromosomes. In all cases, the wt euploid strain grown under the same conditions was used as the reference sample. Reference nucleic acid was generally labeled with Cy3, though some were labeled with Cy5 as indicated in the associated annotations for each array. No replicate arrays are included. Expression Samples: GSM513249-GSM513277 CGH Samples: GSM513278-GSM513369

Project description:Aneuploidy causes severe developmental defects and is a near universal feature of tumor cells. Despite its profound effects, the cellular processes affected by aneuploidy are not well characterized. Here, we examined the consequences of aneuploidy on the proteome of aneuploid budding yeast strains. We show that although protein levels largely scale with gene copy number, subunits of multi-protein complexes are notable exceptions. Posttranslational mechanisms attenuate their expression when their encoding genes are in excess. Our proteomic analyses further revealed a novel aneuploidy-associated protein expression signature characteristic of altered metabolism and redox homeostasis. Indeed aneuploid cells harbor increased levels of reactive oxygen species (ROS). Interestingly, increased protein turnover attenuates ROS levels and this novel aneuploidy-associated signature and improves the fitness of most aneuploid strains. Our results show that aneuploidy causes alterations in metabolism and redox homeostasis. Cells respond to these alterations through both transcriptional and posttranscriptional mechanisms.

Project description:Aneuploidy, a condition characterized by whole chromosome gains and losses, is often associated with significant cellular stress and decreased fitness. However, whether and how cells respond to the aneuploid state has remained controversial. In aneuploid budding yeast, two opposing gene expression patterns have been reported: an environmental stress response (ESR) and a “common aneuploidy gene-expression” (CAGE) signature, in which many ESR genes are oppositely regulated. Here, we investigate and bring clarity to this controversy. We show that the CAGE signature is not an aneuploidy-specific gene expression signature but is the result of euploid control cells, but not aneuploid cells, having grown into stationary phase. Because growth into stationary phase is amongst the strongest inducers of the ESR, the ESR in aneuploid cells was masked when stationary phase euploid cells were used for normalization in transcriptomic studies. When exponentially growing euploid cells are used in gene expression comparisons with aneuploid cells, the CAGE signature is no longer evident in aneuploid cells. Instead, aneuploid cells are found to exhibit the ESR. We further show that the ESR causes a selective loss of ribosomes in aneuploid cells, providing an explanation for the decreased cellular density in aneuploid cells. We conclude that aneuploid budding yeast cells mount the ESR, rather than a CAGE signature, in response to aneuploidy-induced cellular stresses that results in selective ribosome loss.

Project description:Aneuploidy, an uneven number of chromosomes, leads to severe developmental defects in mammals and is also a hallmark of cancer. However, whether aneuploidy is a driving cause or a consequence of tumor formation remains controversial. Paradoxically, existing studies based on aneuploid yeast and mouse fibroblasts have shown that aneuploidy is usually detrimental to cellular fitness. Here, we examined the effects of aneuploidy on mouse embryonic stem cells. Using a novel genetic scheme, we generated a series of aneuploid cell lines that each carries an extra copy of single chromosomes and then characterized the traits shared by these cell lines. All the aneuploid cell lines had rapid proliferation rates and enhanced colony formation efficiencies. They were less dependent on growth factors for self-renewal and showed a reduced capacity to differentiate in vitro. Moreover, xenografted aneuploid stem cells formed teratomas more efficiently, with features of neoplastic progression. These findings demonstrate that aneuploidy enhances the self-renewal capacities of stem cells and reduces their differentiation abilities.

Project description:Aneuploidy, an uneven number of chromosomes, leads to severe developmental defects in mammals and is also a hallmark of cancer. However, whether aneuploidy is a driving cause or a consequence of tumor formation remains controversial. Paradoxically, existing studies based on aneuploid yeast and mouse fibroblasts have shown that aneuploidy is usually detrimental to cellular fitness. Here, we examined the effects of aneuploidy on mouse embryonic stem cells. Using a novel genetic scheme, we generated a series of aneuploid cell lines that each carries an extra copy of single chromosomes and then characterized the traits shared by these cell lines. All the aneuploid cell lines had rapid proliferation rates and enhanced colony formation efficiencies. They were less dependent on growth factors for self-renewal and showed a reduced capacity to differentiate in vitro. Moreover, xenografted aneuploid stem cells formed teratomas more efficiently, with features of neoplastic progression. These findings demonstrate that aneuploidy enhances the self-renewal capacities of stem cells and reduces their differentiation abilities.

Project description:In all primary cells analyzed to date, aneuploidy is associated with poor proliferation. Yet, how abnormal karyotypes affect cancer – a disease characterized by both aneuploidy and heightened proliferative capacity – is largely unknown. Here, I demonstrate that the transcriptional alterations caused by aneuploidy in primary cells are also present in chromosomally-unstable cancer cell lines, but are not common to all aneuploid cancers. Moreover, chromosomally-unstable cancer lines display increased glycolytic and TCA-cycle flux, as is also observed in primary aneuploid cells. The biological response to aneuploidy is associated with cellular stress and slow proliferation, and a 70-gene signature derived from primary aneuploid cells is a strong predictor of increased survival in several cancers. Inversely, a transcriptional signature derived from clonal aneuploidy in tumors correlates with high mitotic activity and poor prognosis. I speculate that there are two types of aneuploidy in cancer: clonal aneuploidy, which is selected during tumor evolution and is associated with robust growth, and sub-clonal aneuploidy, which is caused by chromosomal instability (CIN) and more closely resembles the stressed state of primary aneuploid cells. Nonetheless, CIN is not benign: a subset of genes upregulated in high-CIN cancers predict aggressive disease in human patients in a proliferation-independent manner.

Project description:Aneuploidy is a hallmark of human cancer, yet the molecular mechanisms to cope with aneuploidy-induced cellular stresses remain largely unknown. Here, we induced chromosome mis-segregation in non-transformed RPE1-hTERT cells and derived multiple stable clones with various degrees of aneuploidy. We performed an unbiased genomic, transcriptomic and proteomic profiling of 6 isogenic clones, using whole-exome DNA, mRNA and miRNA sequencing, as well as proteomics. Concomitantly, we functionally interrogated their cellular vulnerabilities, using genome-wide CRISPR/Cas9 and large-scale drug screens. Aneuploid clones activated the DNA damage response, and were consequently more resistant to further DNA damage induction. Aneuploid cells also exhibited elevated RAF/MEK/ERK pathway activity, and were more sensitive to clinically-relevant drugs targeting this pathway, and in particular to CRAF inhibition. Importantly, CRAF and MEK inhibition sensitized aneuploid cells to DNA damage-inducing chemotherapies and to PARP inhibitors. These results were validated in human cancer cell lines. Overall, our study provides a comprehensive resource for genetically-matched karyotypically-stable cells of various aneuploidy states, revealing a novel therapeutically-relevant cellular dependency of aneuploid cells. This submission contains the raw files, the library used for the analysis, and the corresponding DIA-NN report and associated files.