Chromosomal mosaicism in human blastocysts: a cytogenetic comparison of trophectoderm and inner cell mass after next-generation sequencing.

RESEARCH QUESTION: What is the incidence of chromosomal mosaicism in human blastocysts and can a single trophectoderm (TE) biopsy accurately predict the chromosomal constitution of the inner cell mass (ICM)? DESIGN: Observational study in 46 surplus cryopreserved preimplantation embryos of unknown chromosomal constitution. For each embryo, a TE biopsy was performed and the ICM was collected separately. Both samples underwent next-generation sequencing (NGS) for cytogenetic analysis and were classified as chromosomally normal, abnormal or mosaic. Mosaic samples were classified as low or high mosaic, based on the majority dominance of either normal or abnormal cells in the biopsied sample. Findings within each embryo were compared. RESULTS: Chromosomal mosaicism was detected in 59% (n = 27/46) of the embryos, with a cytogenetic concordance rate between TE and corresponding ICM of 48% (n = 22/46). Concordance was higher from a clinical perspective: in 86% of embryos with a high-mosaic or abnormal TE, the ICM was also high-mosaic or abnormal. In 88% of the blastocysts with a normal or low-mosaic TE biopsy, a normal or low-mosaic ICM was observed. CONCLUSION: Despite the low cytogenetic concordance rate due to chromosomal mosaicism present in blastocysts, it was found that a single TE biopsy could correctly predict whether the ICM consists of mostly normal or abnormal cells in the majority of cases.

In vitro capture and characterization of embryonic rosette-stage pluripotency between naive and primed states.

Following implantation, the naive pluripotent epiblast of the mouse blastocyst generates a rosette, undergoes lumenogenesis and forms the primed pluripotent egg cylinder, which is able to generate the embryonic tissues. How pluripotency progression and morphogenesis are linked and whether intermediate pluripotent states exist remain controversial. We identify here a rosette pluripotent state defined by the co-expression of naive factors with the transcription factor OTX2. Downregulation of blastocyst WNT signals drives the transition into rosette pluripotency by inducing OTX2. The rosette then activates MEK signals that induce lumenogenesis and drive progression to primed pluripotency. Consequently, combined WNT and MEK inhibition supports rosette-like stem cells, a self-renewing naive-primed intermediate. Rosette-like stem cells erase constitutive heterochromatin marks and display a primed chromatin landscape, with bivalently marked primed pluripotency genes. Nonetheless, WNT induces reversion to naive pluripotency. The rosette is therefore a reversible pluripotent intermediate whereby control over both pluripotency progression and morphogenesis pivots from WNT to MEK signals.

Paternal heterochromatin formation in human embryos is H3K9/HP1 directed and primed by sperm-derived histone modifications.

The different configurations of maternal and paternal chromatin, acquired during oogenesis and spermatogenesis, have to be rearranged after fertilization to form a functional embryonic genome. In the paternal genome, nucleosomal chromatin domains are re-established after the protamine-to-histone exchange. We investigated the formation of constitutive heterochromatin (cHC) in human preimplantation embryos. Our results show that histones carrying canonical cHC modifications are retained in cHC regions of sperm chromatin. These modified histones are transmitted to the oocyte and contribute to the formation of paternal embryonic cHC. Subsequently, the modifications are recognized by the H3K9/HP1 pathway maternal chromatin modifiers and propagated over the embryonic cleavage divisions. These results are in contrast to what has been described for mouse embryos, in which paternal cHC lacks canonical modifications and is initially established by Polycomb group proteins. Our results show intergenerational epigenetic inheritance of the cHC structure in human embryos.

A universal method for sequential immunofluorescent analysis of chromatin and chromatin-associated proteins on chromosome spreads.

Immunofluorescence has been widely used to study histone modification dynamics and chromosome-associated proteins that regulate the segregation of chromosomes during cell divisions. Since many of these regulatory proteins interact (in)directly to exert their proper function, it is of interest to detect these proteins simultaneously, to establish their spatiotemporal relation. However, the detection of multiple epitopes on the same material is limited by the availability of antibodies derived from different host species. For Western blot membranes, buffers were developed to remove antibodies after the first round of detection and enable a second round of detection. In this study, we establish that this "stripping" principle can also be applied for sequential immunofluorescence on chromosome preparations. We first adapted a drying down fixation technique for the use on cultured cells from different primary cells and cell lines. These chromosome spreads were subsequently used to optimize the stripping procedure for this application. We investigated feasibility and reliability of detection of histones and their posttranslational modifications as well as chromatin interacting proteins in two subsequent rounds of immunofluorescence. We conclude that this method is a reliable option when spatial resolution and co-expression need to be investigated and the material or the choice of antibodies is limited.