Causes and consequences of chromosome segregation error in preimplantation embryos

Vázquez-Diez, Cayetana; FitzHarris, Greg

doi:10.1530/rep-17-0569

Cited by 60 publications

(41 citation statements)

References 110 publications

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“…The difference likely pertains to the observation that some SAC components assemble at the nucleus in interphase [92], such that bisection prior to germinal vesicle breakdown effectively concentrates SAC components, whereas bisection after germinal vesicle breakdown reduces cell volume without influencing SAC component concentrations [90,91]. Whether the effect of size will be more apparent in the human oocyte, which is approximately three to four times greater in volume than mouse, and whether the same principle causes the SAC to strengthen during early embryonic development, when cell divisions are also error prone and cells progressively decrease in size and nuclear-cytoplasmic ratio increases [93,94], will be interesting to determine.…”

Section: Idiosyncratic Spindle Assembly Checkpoint In Oocyte Meiosis-imentioning

confidence: 99%

Segregating Chromosomes in the Mammalian Oocyte

Mihajlović

FitzHarris

2018

Current Biology

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Chromosome segregation errors in human oocytes lead to aneuploid embryos that cause infertility and birth defects. Here we provide an overview of the chromosome-segregation process in the mammalian oocyte, highlighting mechanistic differences between oocytes and somatic cells that render oocytes so prone to segregation error. These differences include the extremely large size of the oocyte cytoplasm, the unique geometry of meiosis-I chromosomes, idiosyncratic function of the spindle assembly checkpoint, and dramatically altered oocyte cell-cycle control and spindle assembly, as compared to typical somatic cells. We summarise recent work suggesting that aging leads to a further deterioration in fidelity of chromosome segregation by impacting multiple components of the chromosome-segregation machinery. In addition, we compare and contrast recent results from mouse and human oocytes, which exhibit overlapping defects to differing extents. We conclude that the striking propensity of the oocyte to mis-segregate chromosomes reflects the unique challenges faced by the spindle in a highly unusual cellular environment.

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Section: Idiosyncratic Spindle Assembly Checkpoint In Oocyte Meiosis-imentioning

confidence: 99%

Segregating Chromosomes in the Mammalian Oocyte

Mihajlović

FitzHarris

2018

Current Biology

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“…Genetic surveys of in vitro fertilized (IVF) human embryos consistently reveal substantial levels of aneuploidy-whole chromosome gains and losses that trace their origins to diverse mechanisms of chromosome mis-segregation. These include (primarily maternal) meiotic mechanisms such as non-disjunction, precocious separation of sister chromatids, and reverse segregation (Ottolini et al 2015) , as well as mitotic mechanisms such as mitotic non-disjunction, anaphase lag, and endoreplication (Vázquez-Diez and FitzHarris 2018) . In contrast to meiotic errors, which uniformly affect all embryonic cells, mitotic errors generate chromosomal mosaicism, whereby different cells possess distinct chromosome complements.…”

Section: Introductionmentioning

confidence: 99%

Single-cell analysis of human embryos reveals diverse patterns of aneuploidy and mosaicism

Starostik

Sosina

McCoy

2020

Preprint

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Less than half of human zygotes survive to live birth, primarily due to aneuploidies of meiotic or mitotic origin. Mitotic errors lead to chromosomal mosaicism, defined by multiple cell lineages with distinct chromosome complements. The incidence and fitness consequences of chromosomal mosaicism in human embryos remain controversial, with most previous studies based on bulk DNA assays or comparisons of multiple biopsies of a few embryonic cells. Single-cell genomic data provide an opportunity to quantify mosaicism on an embryo-wide scale. To this end, we extended an approach to infer aneuploidies based on chromosome dosage-associated changes in gene expression by integrating signatures of allelic imbalance. We applied this method to published single-cell RNA sequencing data from 74 disaggregated human embryos, spanning the morula to blastocyst stages. Our analysis revealed widespread mosaic aneuploidies across preimplantation development, with 59 of 74 (80%) embryos harboring at least one aneuploid cell (1% FDR). By clustering copy number calls, we reconstructed histories of chromosome mis-segregation, distinguishing meiotic and early mitotic errors from those occurring after lineage differentiation. We observed no significant enrichment of aneuploid cells in the trophectoderm compared to the inner cell mass, though we do detect such an enrichment in published data from later post-implantation stages. Finally, we observed that aneuploid cells exhibit upregulation of immune response genes, as well as downregulation of genes involved in proliferation, metabolism, and protein processing, consistent with stress responses previously documented in other stages and systems. Together, our work provides a high-resolution view of aneuploidy in preimplantation embryos and supports the conclusion that low-level mosaicism is a common feature of early human development.

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“…By age 42, the incidence of aneuploidy may increase up to 80%, according to (Capalbo et al, « Human Female Meiosis Revised »). Not all segregation errors are due to aberrant meiotic divisions though, and additionally, a high rate of segregation errors is observed in the following mitotic divisions at later stages of embryogenesis, up to the blastocyst stage (Schneider and Ellenberg 2019;Vázquez-Diez and FitzHarris 2018). Today, with more commonly used medically assisted reproduction and the increase of maternal age at first pregnancies, it is indispensable to gain a better comprehension of the regulatory mechanisms put in place to segregate the genetic material in meiosis and early mitotic divisions in the embryo.…”

Section: Introductionmentioning

confidence: 99%

Cycling through mammalian meiosis: B-type cyclins in oocytes

Bouftas

Wassmann

2019

Cell Cycle

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B-type cyclins in association with Cdk1 mediate key steps of mitosis and meiosis, by phosphorylating a plethora of substrates. Progression through the meiotic cell cycle requires the execution of two cell divisions named meiosis I and II without intervening S-phase, to obtain haploid gametes. These two divisions are highly asymmetric in the large oocyte. Chromosome segregation in meiosis I and sister chromatid segregation in meiosis II requires the sharp, switch-like inactivation of Cdk1 activity, which is brought about by degradation of B-type cyclins and counteracting phosphatases. Importantly and contrary to mitosis, inactivation of Cdk1 must not allow S-phase to take place at exit from meiosis I. Here, we describe recent studies on the regulation of translation and degradation of B-type cyclins in mouse oocytes, and how far their roles are redundant or specific, with a special focus on the recently discovered oocyte-specific role of cyclin B3.

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Causes and consequences of chromosome segregation error in preimplantation embryos

Cited by 60 publications

References 110 publications

Segregating Chromosomes in the Mammalian Oocyte

Segregating Chromosomes in the Mammalian Oocyte

Single-cell analysis of human embryos reveals diverse patterns of aneuploidy and mosaicism

Cycling through mammalian meiosis: B-type cyclins in oocytes

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