Chromosome errors in human eggs shape natural fertility over reproductive life span.

Chromosome errors, or aneuploidy, affect an exceptionally high number of human conceptions, causing pregnancy loss and congenital disorders. Here, we have followed chromosome segregation in human oocytes from females aged 9 to 43 years and report that aneuploidy follows a U-curve. Specific segregation error types show different age dependencies, providing a quantitative explanation for the U-curve. Whole-chromosome nondisjunction events are preferentially associated with increased aneuploidy in young girls, whereas centromeric and more extensive cohesion loss limit fertility as women age. Our findings suggest that chromosomal errors originating in oocytes determine the curve of natural fertility in humans.

Tripolar chromosome segregation drives the association between maternal genotype at variants spanning PLK4 and aneuploidy in human preimplantation embryos.

Aneuploidy is prevalent in human embryos and is the leading cause of pregnancy loss. Many aneuploidies arise during oogenesis, increasing with maternal age. Superimposed on these meiotic aneuploidies are frequent errors occurring during early mitotic divisions, contributing to widespread chromosomal mosaicism. Here we reanalyzed a published dataset comprising preimplantation genetic testing for aneuploidy in 24 653 blastomere biopsies from day-3 cleavage-stage embryos, as well as 17 051 trophectoderm biopsies from day-5 blastocysts. We focused on complex abnormalities that affected multiple chromosomes simultaneously, seeking insights into their formation. In addition to well-described patterns such as triploidy and haploidy, we identified 4.7% of blastomeres possessing characteristic hypodiploid karyotypes. We inferred this signature to have arisen from tripolar chromosome segregation in normally fertilized diploid zygotes or their descendant diploid cells. This could occur via segregation on a tripolar mitotic spindle or by rapid sequential bipolar mitoses without an intervening S-phase. Both models are consistent with time-lapse data from an intersecting set of 77 cleavage-stage embryos, which were enriched for the tripolar signature among embryos exhibiting abnormal cleavage. The tripolar signature was strongly associated with common maternal genetic variants spanning the centrosomal regulator PLK4, driving the association we previously reported with overall mitotic errors. Our findings are consistent with the known capacity of PLK4 to induce tripolar mitosis or precocious M-phase upon dysregulation. Together, our data support tripolar chromosome segregation as a key mechanism generating complex aneuploidy in cleavage-stage embryos and implicate maternal genotype at a quantitative trait locus spanning PLK4 as a factor influencing its occurrence.

Characterization of the Escherichia coli K-12 ydhYVWXUT operon: regulation by FNR, NarL and NarP.

In Escherichia coli K-12 the expression of many genes is controlled by the oxygen-responsive transcription factor FNR and the nitrate- and nitrite-responsive two-component systems NarXL and NarPQ. Here, the ydhY gene is shown to be the first gene of a six-gene operon (ydhYVWXUT) that encodes proteins predicted to be components of an oxidoreductase. Mapping the ydhY-T transcript start and site-directed mutagenesis confirmed that the ydhY-T genes are transcribed from an FNR-dependent class II promoter and showed that the FNR site is centred at -42.5. In the presence of nitrate or nitrite, NarXL and NarPQ repressed ydhY-T expression. Analysis of the DNA sequence of the ydhY promoter region (PydhY) revealed the presence of four heptameric sequences similar to NarL/P binding sites centred at -42, -16, +6 and +15. The latter heptamers are arranged as a 7-2-7 inverted repeat, which is required for recognition by NarP. Accordingly, NarP protected the 7-2-7 region in DNase I footprints, and mutation of either heptamer +6 or heptamer +15 impaired nitrite-mediated repression, whereas mutation of heptamer -42 and heptamer -16 did not affect the response to nitrite. The NarL protein also protected the 7-2-7 region, but in contrast to NarP, the NarL footprint extended further upstream to encompass the -16 heptamer. The extended NarL footprint was consistent with the presence of multiple NarL-PydhY complexes in gel retardation assays. Mutation of heptamer -42, which is located within the FNR binding site, or heptamer +6 (but not heptamers -16 or +15) impaired nitrate-mediated repression. Thus, although the region of the ydhY-T promoter containing the -16 and +15 heptamers was recognized by NarL in vitro, mutation of these heptamers did not affect NarL-mediated repression in vivo.