CRISPR-on for activation of endogenous SMARCA4 and TFAP2C expression in bovine embryos.

CRISPR-mediated transcriptional activation, also known as CRISPR-on, has proven efficient for activation of individual or multiple endogenous gene expression in cultured cells from several species. However, the potential of CRISPR-on technology in preimplantation mammalian embryos remains to be explored. Here, we report for the first time the successful modulation of endogenous gene expression in bovine embryos by using the CRISPR-on system. As a proof of principle, we targeted the promoter region of either SMARCA4 or TFAP2C genes, transcription factors implicated in trophoblast lineage commitment during embryo development. We demonstrate that CRISPR-on provides temporal control of endogenous gene expression in bovine embryos, by simple cytoplasmic injection of CRISPR RNA components into one cell embryos. dCas9VP160 activator was efficiently delivered and accurately translated into protein, being detected in the nucleus of all microinjected blastomeres. Our approach resulted in the activation of SMARCA expression shortly after microinjection, with a consequent effect on downstream differentiation promoting factors, such as TFAP2C and CDX2. Although targeting of TFAP2C gene did not result in a significant increase in TFAP2C expression, there was a profound induction in CDX2 expression on day 2 of development. Finally, we demonstrate that CRISPR-on system is suitable for gene expression modulation during the preimplantation period, since no detrimental effect was observed on microinjected embryo development. This study constitutes a first step toward the application of the CRISPR-on system for the study of early embryo cell fate decisions in cattle and other mammalian embryos, as well as to design novel strategies that may lead to an improved trophectoderm development.

A dose-dependent response to MEK inhibition determines hypoblast fate in bovine embryos.

BACKGROUND: The segregation of the hypoblast and the emergence of the pluripotent epiblast mark the final stages of blastocyst formation in mammalian embryos. In bovine embryos the formation of the hypoblast has been partially studied, and evidence shows that MEK signalling plays a limited role in the segregation of this lineage. Here we explored the role of different signalling pathways during lineage segregation in the bovine embryo using immunofluorescence analysis of NANOG and SOX17 as readouts of epiblast and hypoblast, respectively. RESULTS: We show that SOX17 starts to be expressed in 16-32-cell stage embryos, whereas NANOG is first detected from 8-cell stage. SOX17 is first co-expressed with NANOG, but these markers become mutually exclusive by the late blastocyst stage. By assessing the expression kinetics of NANOG/SOX17 we show that inhibition of MEK signalling can eliminate SOX17 expression in bovine blastocysts, without altering NANOG expression. Modulation of WNT, PKC and LIF did not affect NANOG expression in the epiblast when used in combination with the ERK inhibitor. CONCLUSIONS: This study shows that SOX17 can be used as a reliable early marker of hypoblast in the bovine, and based on its expression profile we show that the hypoblast segregates in day 7 blastocysts. Furthermore, SOX17 expression is abolished using 1 µM of PD0325901, without affecting the NANOG population in the epiblast. Modulation of WNT, PKC and LIF are not sufficient to support enhanced NANOG expression in the epiblast when combined with ERK inhibitor, indicating that additional signalling pathways should be examined to determine their potential roles in epiblast expansion.

CRISPR-on for Endogenous Activation of SMARCA4 Expression in Bovine Embryos.

The CRISPR-on system is a programmable, simple, and versatile gene activator that has proven to be efficient in cultured cells from several species and in bovine embryos. This technology allows for the precise and specific activation of single endogenous gene expression and also multiplexed gene expression in a simple fashion. Therefore, CRISPR-on has unique advantages over other activator systems and a wide adaptability for studies in basic and applied science, such as cell reprogramming and cell fate differentiation for regenerative medicine.In this chapter, we describe the materials and methods of the CRISPR-on system for activation of the endogenous SMARCA4 expression in bovine embryos.

Effect of Embryo Aggregation on In Vitro Development of Adipose-Derived Mesenchymal Stem Cell-Derived Bovine Clones.

Somatic cell nuclear transfer (SCNT) is a method with unique ability to reprogram the epigenome of a fully differentiated cell. However, its efficiency remains extremely low. In this work, we assessed and combined two simple strategies to improve the SCNT efficiency in the bovine. These are the use of less-differentiated donor cells to facilitate nuclear reprogramming and the embryo aggregation (EA) strategy that is thought to compensate for aberrant epigenome reprogramming. We carefully assessed the optimal time of EA by using in vitro-fertilized (IVF) embryos and evaluated whether the use of adipose-derived mesenchymal stem cells (ASCs) as donor for SCNT together with EA improves the blastocyst rates and quality. Based on our results, we determined that the EA improves the preimplantation embryo development per well of IVF and SCNT embryos. We also demonstrated that day 0 (D0) is the optimal aggregation time that leads to a single blastocyst with uniform distribution of the original blastomeres. This was confirmed in bovine IVF embryos and then, the optimal condition was translated to SCNT embryos. Notably, the relative expression of the trophectoderm (TE) marker KRT18 was significantly different between aggregated and nonaggregated ASC-derived embryos. In the bovine, no effect of the donor cell is observed on the developmental rate, or the embryo quality. Therefore, no synergistic effect of the use of both strategies is observed. Our results suggest that EA at D0 is a simple and accessible strategy that improves the blastocyst rate per well in bovine SCNT and IVF embryos and influence the expression of a TE-related marker. The aggregation of two ASC-derived embryos seems to positively affect the embryo quality, which may improve the postimplantation development.