Teresa Olbrich scite author profile

The recent development of haploid cell lines has facilitated forward genetic screenings in mammalian cells. These lines include nearhaploid human cell lines isolated from a patient with chronic myelogenous leukemia (KBM7 and HAP1), as well as haploid embryonic stem cells derived from several organisms. In all cases, haploidy was shown to be an unstable state, so that cultures of mammalian haploid cells rapidly become enriched in diploids. Here we show that the observed diploidization is due to a proliferative disadvantage of haploid cells compared with diploid cells. Accordingly, single-cell-sorted haploid mammalian cells maintain the haploid state for prolonged periods, owing to the absence of competing diploids. Although the duration of interphase is similar in haploid and diploid cells, haploid cells spend longer in mitosis, indicative of problems in chromosome segregation. In agreement with this, a substantial proportion of the haploids die at or shortly after the last mitosis through activation of a p53-dependent cytotoxic response. Finally, we show that p53 deletion stabilizes haploidy in human HAP1 cells and haploid mouse embryonic stem cells. We propose that, similar to aneuploidy or tetraploidy, haploidy triggers a p53-dependent response that limits the fitness of mammalian cells.haploidy | embryonic stem cells | p53 | HAP1 | chromosome segregation T he main advantage of yeast as a model organism for genetic studies is the availability of haploid cells, so that the mutation of a single allele can suffice to reveal a phenotype. This approach has been of enormous importance for biomedical research in recent decades, as exemplified by the number of Nobel Prizes awarded to discoveries that used yeast as a model system, including the discovery of autophagy, telomeres, and the cell cycle (1). In any case, there are questions intrinsic to mammalian biology, such as stemness or differentiation, that are difficult to address using yeast as a model, and that could be answered by the availability of mammalian haploid cell lines.

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Dynamics of histone H3.3 deposition in proliferating and senescent cells reveals a DAXX-dependent targeting to PML-NBs important for pericentromeric heterochromatin organization

Corpet¹,

Olbrich

Gwerder³

et al. 2013

Cell Cycle

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Oncogene-induced senescence is a permanent cell cycle arrest characterized by extensive chromatin reorganization. Here, we investigated the specific targeting and dynamics of histone H3 variants in human primary senescent cells. We show that newly synthesized epitope-tagged H3.3 is incorporated in senescent cells but does not accumulate in senescence-associated heterochromatin foci (SAHF). Instead, we observe that new H3.3 colocalizes with its specific histone chaperones within the promyelocytic leukemia nuclear bodies (PML-NBs) and is targeted to PML-NBs in a DAXX-dependent manner both in proliferating and senescent cells. We further show that overexpression of DAXX enhances targeting of H3.3 in large PML-NBs devoid of transcriptional activity and promotes the accumulation of HP1, independently of H3K9me3. Loss of H3.3 from pericentromeric heterochromatin upon DAXX or PML depletion suggests that the targeting of H3.3 to PML-NBs is implicated in pericentromeric heterochromatin organization. Together, our results underline the importance of the replication-independent chromatin assembly pathway for histone replacement in non-dividing senescent cells and establish PML-NBs as important regulatory sites for the incorporation of new H3.3 into chromatin.

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TRF2-mediated telomere protection is dispensable in pluripotent stem cells

Markiewicz-Potoczny

Lobanova

Loeb

et al. 2020

Nature

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Teresa Olbrich

A p53-dependent response limits the viability of mammalian haploid cells

Dynamics of histone H3.3 deposition in proliferating and senescent cells reveals a DAXX-dependent targeting to PML-NBs important for pericentromeric heterochromatin organization

TRF2-mediated telomere protection is dispensable in pluripotent stem cells

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