Molecular cloning of PRD-like homeobox genes expressed in bovine oocytes and early IVF embryos.

BACKGROUND: Embryonic genome activation (EGA) is a critical step in early embryonic development, as it marks the transition from relying on maternal factors to the initiation of transcription from embryo's own genome. The factors associated with EGA are not well understood and need further investigation. PRD-like (PRDL) homeodomain transcription factors (TFs) are considered to play crucial roles in this early event during development but these TFs have evolved differently, even within mammalian lineages. Different numbers of PRDL TFs have been predicted in bovine (Bos taurus); however, their divergent evolution requires species-specific confirmation and functional investigations. RESULTS: In this study, we conducted molecular cloning of mRNAs for the PRDL TFs ARGFX, DUXA, LEUTX, NOBOX, TPRX1, TPRX2, and TPRX3 in bovine oocytes or in vitro fertilized (IVF) preimplantation embryos. Our results confirmed the expression of PRDL TF genes in early bovine development at the cDNA level and uncovered their structures. For each investigated PRDL TF gene, we isolated at least one homeodomain-encoding cDNA fragment, indicative of DNA binding and thus potential role in transcriptional regulation in developing bovine embryos. Additionally, our cDNA cloning approach allowed us to reveal breed-related differences in bovine, as evidenced by the identification of a high number of single nucleotide variants (SNVs) across the PRDL class homeobox genes. Subsequently, we observed the prediction of the 9aa transactivation domain (9aaTAD) motif in the putative protein sequence of TPRX3 leading us to conduct functional analysis of this gene. We demonstrated that the TPRX3 overexpression in bovine fibroblast induces not only protein-coding genes but also short noncoding RNAs involved in splicing and RNA editing. We supported this finding by identifying a shared set of genes between our and published bovine early embryo development datasets. CONCLUSIONS: Providing full-length cDNA evidence for previously predicted homeobox genes that belong to PRDL class improves the annotation of the bovine genome. Updating the annotation with seven developmentally-important genes will enhance the accuracy of RNAseq analysis with datasets derived from bovine preimplantation embryos. In addition, the absence of TPRX3 in humans highlights the species-specific and TF-specific regulation of biological processes during early embryo development.

Investigating the impact of vitrification on bovine ovarian tissue morphology, follicle survival, and transcriptomic signature.

PURPOSE: Ovarian tissue cryopreservation is vital for fertility preservation, yet its effect on ovarian tissue follicle survival and transcriptomic signature requires further investigation. This study delves into the effects of vitrification on tissue morphology, function, and transcriptomic changes, helping to find possibilities for vitrification protocol improvements. METHODS: Ovarian cortex from 19 bovine animals were used to conduct pre- and post-vitrification culture followed by histological assessment, immunohistochemistry, and TUNEL assay. Follicles' functionality was assessed for viability and growth within the tissue and in isolated cultures. RNA-sequencing of ovarian tissue was used to explore the transcriptomic alterations caused by vitrification. RESULTS: Follicle density, cell proliferation, and DNA damage in ovarian stroma were unaffected by vitrification. However, vitrified cultured tissue exhibited reduced follicle density of primordial/primary and antral follicles, while freshly cultured tissue manifested reduction of antral follicles. Increased stromal cell proliferation and DNA damage occurred in both groups post-culture. Isolated follicles from vitrified tissue exhibited similar viability to fresh follicles until day 4, after which the survival dropped. RNA-sequencing revealed minor effects of vitrification on transcriptomic signatures, while culture induced significant gene expression changes in both groups. The altered expression of WNT and hormonal regulation pathway genes post-vitrification suggests the molecular targets for vitrification protocol refinement. CONCLUSION: Vitrification minimally affects tissue morphology, follicle density, and transcriptomic signature post-thawing. However, culture revealed notable changes in vitrified tissue samples, including reduced follicle density, decreased isolated follicle survival, and alteration in WNT signalling and ovarian hormonal regulation pathways, highlighted them as possible limitations of the current vitrification protocol.

Optimized single-cell RNA sequencing protocol to study early genome activation in mammalian preimplantation development.

Here, we present a modification of single-cell tagged reverse transcription protocol to study gene expression on a single-cell level or with limited RNA input. We describe different enzymes for reverse transcription and cDNA amplification, modified lysis buffer, and additional clean-up steps before cDNA amplification. We also detail an optimized single-cell RNA sequencing method for handpicked single cells, or tens to hundreds of cells, as input material to study mammalian preimplantation development. For complete details on the use and execution of this protocol, please refer to Ezer et al.1.