Your search keyword '"consequences of aneuploidy"' showing total 5 results

1. Consequences of Chromosome Loss: Why Do Cells Need Each Chromosome Twice?

Author

Chunduri, Narendra Kumar, Barthel, Karen, and Storchova, Zuzana

Subjects

*CHROMOSOMES, *CELL cycle, *ANEUPLOIDY, *DRUG resistance

Abstract

Aneuploidy is a cellular state with an unbalanced chromosome number that deviates from the usual euploid status. During evolution, elaborate cellular mechanisms have evolved to maintain the correct chromosome content over generations. The rare errors often lead to cell death, cell cycle arrest, or impaired proliferation. At the same time, aneuploidy can provide a growth advantage under selective conditions in a stressful, frequently changing environment. This is likely why aneuploidy is commonly found in cancer cells, where it correlates with malignancy, drug resistance, and poor prognosis. To understand this "aneuploidy paradox", model systems have been established and analyzed to investigate the consequences of aneuploidy. Most of the evidence to date has been based on models with chromosomes gains, but chromosome losses and recurrent monosomies can also be found in cancer. We summarize the current models of chromosome loss and our understanding of its consequences, particularly in comparison to chromosome gains. [ABSTRACT FROM AUTHOR]

Published

2022

2. Consequences of Chromosome Loss: Why Do Cells Need Each Chromosome Twice?

Author

Narendra Kumar Chunduri, Karen Barthel, and Zuzana Storchova

Subjects

aneuploidy, monosomy, chromosome loss, haploinsufficiency, gene dosage, consequences of aneuploidy, Cytology, QH573-671

Abstract

Aneuploidy is a cellular state with an unbalanced chromosome number that deviates from the usual euploid status. During evolution, elaborate cellular mechanisms have evolved to maintain the correct chromosome content over generations. The rare errors often lead to cell death, cell cycle arrest, or impaired proliferation. At the same time, aneuploidy can provide a growth advantage under selective conditions in a stressful, frequently changing environment. This is likely why aneuploidy is commonly found in cancer cells, where it correlates with malignancy, drug resistance, and poor prognosis. To understand this “aneuploidy paradox”, model systems have been established and analyzed to investigate the consequences of aneuploidy. Most of the evidence to date has been based on models with chromosomes gains, but chromosome losses and recurrent monosomies can also be found in cancer. We summarize the current models of chromosome loss and our understanding of its consequences, particularly in comparison to chromosome gains.

Published

2022

3. Consequences of Chromosome Loss

Subjects

ANEUPLOIDY, UVEAL MELANOMA, PROTEOTOXIC STRESS, ALLELIC LOSS, gene dosage, ACUTE MYELOID-LEUKEMIA, TUMOR-SUPPRESSOR GENE, haploinsufficiency, chromosome loss, chromosome loss in cancers, GLOBAL ANALYSIS, consequences of aneuploidy, POOR-PROGNOSIS, MIS-SEGREGATION, monosomy, aneuploidy, GENOMIC INSTABILITY

Abstract

Aneuploidy is a cellular state with an unbalanced chromosome number that deviates from the usual euploid status. During evolution, elaborate cellular mechanisms have evolved to maintain the correct chromosome content over generations. The rare errors often lead to cell death, cell cycle arrest, or impaired proliferation. At the same time, aneuploidy can provide a growth advantage under selective conditions in a stressful, frequently changing environment. This is likely why aneuploidy is commonly found in cancer cells, where it correlates with malignancy, drug resistance, and poor prognosis. To understand this "aneuploidy paradox", model systems have been established and analyzed to investigate the consequences of aneuploidy. Most of the evidence to date has been based on models with chromosomes gains, but chromosome losses and recurrent monosomies can also be found in cancer. We summarize the current models of chromosome loss and our understanding of its consequences, particularly in comparison to chromosome gains.

Published

2022

4. Spindle checkpoint deficiency is tolerated by murine epidermal cells but not hair follicle stem cells.

Author

Foijer, Floris, DiTommaso, Tia, Donati, Giacomo, Hautaviita, Katta, Xie, Stephanie Z., Heath, Emma, Smyth, Ian, Watt, Fiona M., Sorger, Peter K., and Bradley, Allan

Subjects

*HAIR follicles, *MITOSIS, *STEM cells, *LABORATORY mice, *CANCER cells, *ANEUPLOIDY

Abstract

The spindle assembly checkpoint (SAC) ensures correct chromosome segregation during mitosis by preventing aneuploidy, an event that is detrimental to the fitness and survival of normal cells but oncogenic in tumor cells. Deletion of SAC genes is incompatible with early mouse development, and RNAi-mediated depletion of SAC components in cultured cells results in rapid death. Here we describe the use of a conditional KO of mouse Mad2, an essential component of the SAC signaling cascade, as a means to selectively induce chromosome instability and aneuploidy in the epidermis of the skin. We observe that SAC inactivation is tolerated by interfollicular epidermal cells but results in depletion of hair follicle bulge stem cells. Eventually, a histologically normal epidermis develops within ∼1 mo after birth, albeit without any hair. Mad2-deficient cells in this epidermis exhibited abnormal transcription of metabolic genes, consistent with aneuploid cell state. Hair follicle bulge stem cells were completely absent, despite the continued presence of rudimentary hair follicles. These data demonstrate that different cell lineages within a single tissue respond differently to chromosome instability: some proliferating cell lineages can survive, but stem cells are highly sensitive. [ABSTRACT FROM AUTHOR]

Published

2013

5. Spindle checkpoint deficiency is tolerated by murine epidermal cells but not hair follicle stem cells

Author

Floris Foijer, Fiona M. Watt, Emma Heath, Tia DiTommaso, Peter K. Sorger, Allan Bradley, Katta Hautaviita, Ian M. Smyth, Stephanie Z. Xie, and Giacomo Donati

Subjects

Mad2, Cells, Knockout, Aneuploidy, Cell Cycle Proteins, Spindle Apparatus, Biology, Mouse models, Polymerase Chain Reaction, Fluorescence, Mice, Chromosome instability, medicine, Whole chromosome instability, Animals, Mitosis, Cells, Cultured, In Situ Hybridization, Fluorescence, In Situ Hybridization, Oligonucleotide Array Sequence Analysis, Mice, Knockout, Cultured, Multidisciplinary, Epidermis (botany), integumentary system, Stem Cells, Biological Sciences, medicine.disease, Flow Cytometry, Immunohistochemistry, Epidermal stem cell biology, Spindle apparatus, Cell biology, Spindle checkpoint, Epidermal Cells, Consequences of aneuploidy, Epidermis, Hair, Mad2 Proteins, RNA Interference, Stem cell

Abstract

The spindle assembly checkpoint (SAC) ensures correct chromosome segregation during mitosis by preventing aneuploidy, an event that is detrimental to the fitness and survival of normal cells but oncogenic in tumor cells. Deletion of SAC genes is incompatible with early mouse development, and RNAi-mediated depletion of SAC components in cultured cells results in rapid death. Here we describe the use of a conditional KO of mouse Mad2 , an essential component of the SAC signaling cascade, as a means to selectively induce chromosome instability and aneuploidy in the epidermis of the skin. We observe that SAC inactivation is tolerated by interfollicular epidermal cells but results in depletion of hair follicle bulge stem cells. Eventually, a histologically normal epidermis develops within ∼1 mo after birth, albeit without any hair. Mad2-deficient cells in this epidermis exhibited abnormal transcription of metabolic genes, consistent with aneuploid cell state. Hair follicle bulge stem cells were completely absent, despite the continued presence of rudimentary hair follicles. These data demonstrate that different cell lineages within a single tissue respond differently to chromosome instability: some proliferating cell lineages can survive, but stem cells are highly sensitive.

Published

2013