Project description:Aneuploidy is prevalent in cancer, conferring fitness advantage, multidrug resistance, and poor prognosis. In contrast, experimentally induced aneuploidy often results in adverse effects and impaired proliferation. This paradox underscores the necessity of cancer cells to adapt to abnormal chromosome numbers. To identify molecular mechanisms of adaptation to aneuploidy, we initiated in vitro evolution of cells with extra chromosomes added via microcell-mediated chromosome transfer. To this end, we cultured cells in a nutrient-rich medium for 50 passages or plated the cells at a low density and selectively collected the largest colonies originating from a single cell (colony selection). The anaylsis global proteoms of the evolved cell lines was then carried out using TMT quantification strategy. This dataset also includes measurements from post-xenograft aneuploid cell line.

Project description:Aneuploidy is prevalent in cancer, conferring fitness advantage, multidrug resistance, and poor prognosis. In contrast, experimentally induced aneuploidy often results in adverse effects and impaired proliferation. This paradox underscores the necessity of cancer cells to adapt to abnormal chromosome numbers. To identify molecular mechanisms of adaptation to aneuploidy, we initiated in vitro evolution of cells with extra chromosomes added via microcell-mediated chromosome transfer. To this end, we cultured cells in a nutrient-rich medium for 50 passages or plated the cells at a low density and selectively collected the largest colonies originating from a single cell (colony selection). One of the striking observations following evolution of cells with extra chromosome 5 in HCT116 cell line was the frequent loss of the 5q, while maintaining the 5p arm after in vitro evolution. Chromosome 5 is a frequent target of large copy number alterations in several malignancies, such as ovarian, gastric, and oesophageal cancer, and malignant myeloid diseases. Moreover, analysis of chromosome arm level events in the TCGA dataset clearly shows that loss of chromosome arm 5q and gain of 5p are among the most frequent events. We asked whether these specific changes in copy numbers of chromosome 5 – loss of 5q with simultaneous retention of 5p – could affect the proliferation of the evolved cells. To this end, we used the recently developed technique ReDACT-TR (Restoring Disomy in Aneuploid cells using CRISPR Targeting with Telomere Replacement (Girish et al., 2023)), and transfected cells of a separate clone of Htr5 (before evolution) with a gRNA that cuts near the centromere of chromosome 5, simultaneously with a cassette encoding ~100 repeats of the human telomere seed sequence. Targeting the q-arm generated two independent cell lines with 5p trisomy (Htr5p_1 and Htr5p_2), which were confirmed by FISH with probes specific for 5p and 5q arms and by shallow WGS. No cell lines with trisomy of the q-arm were generated, but we have obtained two diploid cell lines (Hdi5_1 and Hdi5_2), most likely due to the CRISPR/Cas9 induced loss of chromosome 5 (Papathanasiou, Markoulaki et al., 2021, Tsuchida, Brandes et al., 2023). The anaylsis of global proteomes of the ReDACT cell lines was then carried out using a TMT quantification strategy.

Project description:Chromosomal instability (CIN) refers to the rate at which cells are unable to properly segregate whole chromosomes, leading to aneuploidy. Using young to old-aged human dermal fibroblasts, we observed a dysfunction of the mitotic machinery arising with age that mildly perturbs chromosome segregation fidelity and contributes to the generation of fully senescent cells. Here, we found that elderly cells have an increased number of stable kinetochore-microtubule (k-MT) attachments and decreased efficiency in the correction of improper k-MT interactions. Importantly, chromosome mis-segregation rates in old-aged cells decreased upon both genetic and small molecule enhancement of MT-depolymerizing kinesin-13 activity. Notably, restored chromosome segregation accuracy inhibited the phenotypes of cellular senescence.

Project description:Aneuploidy results in decreased cellular fitness in many different species and model systems. However, aneuploidy is commonly found in cancer cells and often correlates with aggressive growth and poor prognosis, suggesting that the impact of aneuploidy on cellular fitness is context dependent. The BRG1 (SMARCA4) subunit of the SWI/SNF chromatin remodelling complex is a tumour suppressor that is frequently lost in cancer cells. Here, we used a chromosomally stable cell line to test the effect of BRG1 loss on the evolution of aneuploidy. We find that BRG1 deletion leads to an initial loss of fitness in this cell line that improves over time. The improved fitness correlates with a gain of extra copies of chromosome 18. Notably, changes in pathways that are known to promote tolerance to aneuploidy are evident immediately upon loss of BRG1, providing an environment where karyotype changes associated with a fitness advantage can be explored. At least in some genetic backgrounds, therefore, loss of the SWI/SNF complex can contribute to tumourigenesis through tolerance of aneuploidy.

Project description:PD-L1 Inhibitor Regulates the miR-33a-5p/PTEN Signaling Pathway and Can Be Targeted to Sensitize Glioblastomas to Radiation. Glioblastoma (GBM) is the most common and lethal brain tumor in adults. Ionizing radiation (IR) is a standard treatment for GBM patients and results in DNA damage. However, the clinical efficacy of IR is limited due to therapeutic resistance. The programmed death ligand 1 (PD-L1) blockade has a shown the potential to increase the efficacy of radiotherapy by inhibiting DNA damage and repair responses. The miR-33a-5p is an essential microRNA that promotes GBM growth and self-renewal. In this study, we investigated whether a PD-L1 inhibitor (a small molecule inhibitor) exerted radio-sensitive effects to impart an anti-tumor function in GBM cells by modulating miR-33a-5p. U87 MG cells and U251 cells were pretreated with PD-L1 inhibitor. The PD-L1 inhibitor-induced radio-sensitivity in these cells was assessed by assaying cellular apoptosis, clonogenic survival assays, and migration. TargetScan and luciferase assay showed that miR-33a-5p targeted the phosphatase and tensin homolog (PTEN) 3' untranslated region. The expression level of PTEN was measured by western blotting, and was also silenced using small interfering RNAs. The levels of DNA damage following radiation was measured by the presence of γ-H2AX foci, cell cycle, and the mRNA of the DNA damage-related genes, BRCA1, NBS1, RAD50, and MRE11. Our results demonstrated that the PD-L1 inhibitor significantly decreased the expression of the target gene, miR-33a-5p. In addition, pretreatment of U87 MG and U251 cells with the PD-L1 inhibitor increased radio-sensitivity, as indicated by increased apoptosis, while decreased survival and migration of GBM cells. Mir-33a-5p overexpression or silencing PTEN in U87 MG and U251 cells significantly attenuated PD-L1 radiosensitive effect. Additionally, PD-L1 inhibitor treatment suppressed the expression of the DNA damage response-related genes, BRCA1, NBS1, RAD50, and MRE11. Our results demonstrated a novel role for the PD-L1 inhibitor in inducing radio- sensitivity in GBM cells, where inhibiting miR-33a-5p, leading to PTEN activated, and inducing DNA damage was crucial for antitumor immunotherapies to treat GBM.

Project description:Alternative RNA splicing can generate distinct protein isoforms to allow for the differential control of cell processes across cell types. The chromosome segregation and cell division programs associated with somatic mitosis and germline meiosis display dramatic differences such as kinetochore orientation, cohesin removal, or the presence of a gap phase. These changes in chromosome segregation require alterations to the established cell division machinery. However, it remains unclear what aspects of kinetochore function and its regulatory control differ between the mitotic and meiotic cell divisions to rewire these core processes. Additionally, the alternative splice isoforms that differentially modulate distinct cell division programs have remained elusive. Here, we demonstrate that mammalian germ cells express an alternative mRNA splice isoform for the kinetochore component, DSN1, a subunit of the MIS12 complex that links the centromeres to spindle microtubules during chromosome segregation. This germline DSN1 isoform bypasses the requirement for Aurora kinase phosphorylation for its centromere localization due to the absence of a key regulatory region allowing DSN1 to display persistent centromere localization. Expression of the germline DSN1 isoform in somatic cells results in constitutive kinetochore localization, chromosome segregation errors, and growth defects, providing an explanation for its tight cell type-specific expression. Reciprocally, precisely eliminating expression of the germline-specific DSN1 splice isoform in mouse models disrupts oocyte maturation and early embryonic divisions coupled with a reduction in fertility. Together, this work identifies a germline-specific splice isoform for a chromosome segregation component and implicates its role in mammalian fertility.

Project description:Chromosome loss that results in monosomy has detrimental consequences for human cells, but the underlying molecular mechanisms remain enigmatic. Using p53 deficient monosomic cell lines, we found that chromosome loss impairs proliferation and genomic stability. Transcriptome and proteome analysis revealed a partial compensation of the gene dosage changes that mitigates the effects of chromosome loss. Monosomy triggers global gene expression changes that differ from the effects of trisomy. Strikingly, ribosome biogenesis and translation were commonly downregulated in monosomic cells. Polysome profiling and translation analysis suggest that the defects arise due to haploinsufficiency of ribosomal genes. The ensuing ribosome biogenesis stress triggers the p53 pathway and G1 arrest when TP53 is reintroduced into monosomic cells. Accordingly, impaired ribosome biogenesis and p53 inactivation are associated with monosomy in cancer. Our first systematic study of monosomy in human cells demonstrates that haploinsufficiency of ribosomal genes presents a dominant negative phenotype of monosomy.

Project description:X chromosome inactivation (XCI) compensates for differences in X-chromosome number between male and female mammals. XCI is orchestrated by Xist RNA, whose expression in early development leads to transcriptional silencing of one X-chromosome in the female. Knockout studies have established a requirement for Xist, with inviability of female embryos that inherit an Xist deletion from the father. Here, we report that female mice lacking Xist RNA can, surprisingly, develop and survive to term. Xist-null females are born at lower frequency and are smaller at birth, but organogenesis is mostly normal. Transcriptomic analysis indicates significant overexpression of hundreds of X-linked genes across multiple tissues. Therefore, Xist-null mice can develop to term in spite of a deficiency of dosage compensation. However, the degree of X-autosomal dosage imbalance was less than anticipated (1.14- to 1.36-fold). Thus, partial dosage compensation can be achieved without Xist, supporting the idea of inherent genome balance. Nevertheless, to date, none of the mutant mice has survived beyond weaning stage. Sudden death is associated with failure of postnatal organ maturation. Our data suggest Xist-independent mechanisms of dosage compensation and demonstrate that small deviations from X-autosomal balance can have profound effects on overall fitness. RNA-sequencing of tail-tip fibroblasts (TTFs), spleen, liver and heart tissue from Xist-null and control female mice. Sequencing performed with 50nt read length on Illumina HiSeq2000 or 2500. Data consists of 3 biological replicates for TTFs (6 datasets) and 2 biological replicates for tissues (12 datasets).

Project description:Aneuploidy is a frequent feature of human tumors. Germline mutations leading to aneuploidy are very rare in humans, and their tumor-promoting properties are mostly unknown at the molecular level. We report here novel germline biallelic mutations in MAD1L1, the gene encoding the Spindle Assembly Checkpoint (SAC) protein MAD1, in a 36-year-old female with a dozen of neoplasias, including five malignant tumors. Functional studies in peripheral blood cells demonstrated lack of full-length protein and deficient SAC response, resulting in ~30-40% of aneuploid cells as detected by cytogenetic and single-cell (sc) DNA analysis. scRNA-seq analysis of proband blood cells identified mitochondrial stress accompanied by systemic inflammation with enhanced interferon and NFkB signaling. The inference of chromosomal aberrations from scRNA-seq analysis detected inflammatory signals both in aneuploid and euploid cells, suggesting a non-cell autonomous response to aneuploidy. In addition to random aneuploidies, MAD1L1 mutations resulted in specific clonal expansions of T-cells with chromosome 18 gains and enhanced cytotoxic profile, as well as intermediate B-cells with chromosome 12 gains and transcriptomic signatures characteristic of chronic lymphocytic leukemia cells. These data point to MAD1L1 mutations as the cause of a new variant of mosaic variegated aneuploidy syndrome (MVA) with systemic inflammation and unprecedented tumor susceptibility.

Project description:Biopsies from six individuals of each of the categories active CD (CDA), inactive CD (CD) and healthy controls (N) were analyzed for gene expression using microarray. The biopsies were obtained by ileo-colonoscopy and snap-frozen in nitrogen before RNA-isolation. A gastrointestinal pathologist classified the biopsies into normal, chronic active or chronic inactive inflammation based on Hematoxylin-Eosin stain of tissue sections from adjacent biopsies. Samples with discrepancy between endoscopic and histologic diagnoses were excluded from the final analysis, and uploaded with "NaN". The patients with chronic inactive inflammation all previously had verified CD of the terminal ileum. Patients coming to endoscopy for other reasons than IBD and with normal endoscopic and histological findings served as controls.