P-802 TFAP2C is required for proper segregation of developmental markers regulating trophectoderm commitment during mouse preimplantation development

Abstract

Abstract Study question What is the effect of CRISPR/Cas9-mediated knock-out of trophectoderm markers TFAP2A/C on polarization and lineage commitment in mouse? Summary answer CRISPR/Cas9-mediated KO revealed discrepancies in TFAP2A/C function, wherein TFAP2C is dispensable for blastocyst formation but controls the segregation of transcription factors in the mouse embryo. What is known already TFAP2C is an important transcription factor that is expressed solely in trophectoderm (TE) in mouse, and both TE and epiblast in human. Recently, genetic ablation of both TFAP2C and TEAD4 (player of the HIPPO-pathway) completely abolished polarization in mouse, which indicates that TFAP2C might already act before the first lineage segregation takes place. In addition, TFAP2C RNA depletion experiments in mouse embryos revealed a compensatory upregulation of TFAP2A, which indicates functional redundancy. Nonetheless, the question remains how exactly TFAP2C regulates polarization on a molecular level in mouse and whether there is also a functional implication of its isoform TFAP2A. Study design, size, duration Guide RNAs were designed targeting exon 5 of Tfap2c and exon 2 of the Tfap2a gene. CRISPR/Cas9 ribonucleoprotein complexes were delivered into mouse zygotes via electroporation. Additionally, appropriate non-targeted and scramble (inactive crRNA) control groups were included. Morphological analysis, immunofluorescence and next-generation sequencing (NGS) were applied to check for gene editing efficiency and the impact of KO on embryonic development and lineage segregation. Participants/materials, setting, methods Targeted mouse embryos and controls were cultured for a maximum of 4.5 days in vitro. They were stained for different developmental markers, including CDX2 (TE), SOX2 (early ICM), NANOG (epibast, EPI) and SOX17 (hypoblast, PrE) at different stages of development, such as polarization (E2.5), first (E3.5) and second (E4.5) lineage segregation. Immunostaining was used to determine cell number, TE/ICM fraction, marker localization and fluorescence intensity. Embryos were subjected to genetic analysis to determine on-target efficiency. Main results and the role of chance CRISPR/Cas9-mediated electroporation of mouse zygotes generated efficiently complete knock-out embryos. Of the 39 mouse zygotes targeted for TFAP2C, 38 (97%) of them were edited. From the 38 embryos edited for TFAP2C, 24 (62%) embryos displayed 100% frameshift mutations, and were considered KO. TFAP2C KO mouse embryos cultured until E4.5 were still able to form blastocysts (13/15, 87%), but were associated with inferior blastocyst quality compared to the control groups. Furthermore, TFAP2c-null blastocysts could hatch but herniated at multiple places, in contrast to wild-type blastocysts, which typically herniate at one place. In full frameshift TFAP2C KO mouse embryos, we observed delayed CDX2 expression at E2.5 (n = 7). At E3.5 (n = 5), however, CDX2 expression could still be pertained in KO embryos, whereas nuclear localization of SOX2 was disturbed. At E4.5 (n = 6), some primitive endoderm cells were observed in the presumed ICM (SOX17-positive), whereas no NANOG-positive (EPI) cells could be detected. However, some cells of presumed TE of E4.5 TFAP2C-KO embryos displayed erroneous SOX17 or NANOG expression, indicating that they adopted another cell fate irrespective of cell localization. Secondly, we generated TFAP2A KO mouse embryos (3/5, 60%) which exhibited complete morula arrest (100%; n = 3) at E4.5. Limitations, reasons for caution CRISPR/Cas9 is limited by the occurrence of mosaicism (more than one genotype present in an embryo) and potential off-target editing, which we will assess at in silico predicted off-target sites via NGS in mouse embryonic stem cells. The observations of the study will be consolidated by increasing the sample size. Wider implications of the findings Gene editing studies enable us to unravel the molecular interactions that are required for human preimplantation development. Obtaining novel insights into the molecular networks of the TFAP2-transcription factor family could improve our fundamental understanding on the spatial segregation of key transcription factors, which is crucial for successful implantation. Trial registration number Not applicable