DNA methylation status of bovine blastocysts obtained from peripubertal oocyte donors

Morin-Doré, Léonie; Blondin, Patrick; Vigneault, Christian; Grand, François‐Xavier; Labrecque, Rémi; Sirard, Marc‐André

doi:10.1002/mrd.23399

Cited by 5 publications

(4 citation statements)

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“…Maternal ART procedures such as OS and IVM were linked to a higher frequency of imprinting defects in embryos (Kindsfather et al, 2019; Market‐Velker et al, 2010; Santos et al, 2010); however, evidence in the mouse (Anckaert et al, 2013; Denomme et al, 2011; Kindsfather et al, 2019) and the bovine (Heinzmann et al, 2011) models suggest that oocyte methylation is not affected by these procedures. Similarly, methylation differences were observed in blastocysts derived from bovine oocytes of prepubertal donors of varying ages (Morin‐Doré et al, 2020). The present study provides new evidence to more accurately describe the acquisition of DNA methylation at IGF2R, KCNQ1, PLAGL1, and SNRPN bovine maternally imprinted genes and its relationship to oocyte development.…”

Section: Discussionmentioning

confidence: 85%

“…Differences in follicular development dynamics (Currin et al, 2021; Landry, Labrecque, et al, 2018; Landry, Rossi‐Perazza, et al, 2018; Warzych et al, 2017) result in oocytes collected from prepubertal donors to enter atresia faster than their mature donor counterparts when left in the follicle longer before OPU (Landry, Labrecque, et al, 2018; Landry, Rossi‐Perazza, et al, 2018). Moreover, molecular evidence highlighted transcriptomic (Morin‐Doré et al, 2017) and epigenetic (Morin‐Doré et al, 2020) differences between embryos derived from mature and immature oocyte donors. In a previous study, we also observed that the donor's age coupled with ART affected maternally imprinted genes in embryonic and trophoblastic cells of Days 7 and 12 embryos (Lafontaine et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

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IGF2R, KCNQ1, PLAGL1, and SNRPN DNA methylation is completed in bovine by the early antral follicle stage

Lafontaine

Sirard

2022

Molecular Reproduction Devel

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Imprinted genes are inherited with different DNA methylation patterns depending on the maternal or paternal origin of the allele. In cattle (Bos taurus), abnormal methylation of these genes is linked to the large offspring syndrome, a neonatal overgrowth phenotype analogous to the human Beckwith–Wiedemann syndrome. We hypothesized that in bovine oocytes, some of the methylation patterns on maternally imprinted genes are acquired in the last phase of folliculogenesis. The pyrosequencing analysis of IGF2R, KCNQ1, PLAGL1, and SNRPN imprinted genes showed no clear progression of methylation in oocytes from follicles 1–2 mm (late pre antral/early antral) and up. Instead, these oocytes displayed complete methylation at the imprinted differentially methylated regions (>80%). Other mechanisms related to imprint maintenance should be investigated to explain the hypomethylation at IGF2R, KCNQ1, PLAGL1, and SNRPN maternally imprinted sites observed in some bovine embryos.

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Section: Discussionmentioning

confidence: 85%

Section: Introductionmentioning

confidence: 99%

IGF2R, KCNQ1, PLAGL1, and SNRPN DNA methylation is completed in bovine by the early antral follicle stage

Lafontaine

Sirard

2022

Molecular Reproduction Devel

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“…In addition to the methods described above, pre-implantation bovine embryos have been studied using a variety of other tools too (Table 10). Ribosome profile High-resolution ribosome fractionation, polysome profiling, RNA-seq [198] DNA methylation landscape Anti-5-methylcytosine (5-MeC) antibody, methylation-sensitive high-resolution melting analysis (MS-HRM), bisulfite sequencing [75,[242][243][244][245][246][247][248] mRNA localization In situ hybridization [63,80,249,250] Chromosomal abnormalities 5% Giemsa staining (1250× magnification) [251] Automation/artificial intelligence (AI)-based microscopy Use of genetic algorithms, artificial neural networks, automatic feature extraction from images and supervised learning to formulate AI-based computer-assisted scoring systems (CASS)/predictive models [1,[252][253][254][255][256] Gene knockdown Cytosine base editing, CRISPR/Cas-9 gene editing, siRNA-mediated gene knockdown [79,182,196,197,257] Characterization of extracellular vesicles Nanoparticle tracking analysis, electron microscopy, small RNA sequencing [258][259][260] Multi-omics approaches Integrating transcriptomic and epigenetic data and integrating metabolomics and epigenetic data [261,262]…”

Section: Less Commonly Used Toolsmentioning

confidence: 99%

Pre-Implantation Bovine Embryo Evaluation—From Optics to Omics and Beyond

Rabel

Marchioretto

Bangert

et al. 2023

Animals

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Approximately 80% of the ~1.5 million bovine embryos transferred in 2021 were in vitro produced. However, only ~27% of the transferred IVP embryos will result in live births. The ~73% pregnancy failures are partly due to transferring poor-quality embryos, a result of erroneous stereomicroscopy-based morphological evaluation, the current method of choice for pre-transfer embryo evaluation. Numerous microscopic (e.g., differential interference contrast, electron, fluorescent, time-lapse, and artificial-intelligence-based microscopy) and non-microscopic (e.g., genomics, transcriptomics, epigenomics, proteomics, metabolomics, and nuclear magnetic resonance) methodologies have been tested to find an embryo evaluation technique that is superior to morphologic evaluation. Many of these research tools can accurately determine embryo quality/viability; however, most are invasive, expensive, laborious, technically sophisticated, and/or time-consuming, making them futile in the context of in-field embryo evaluation. However accurate they may be, using complex methods, such as RNA sequencing, SNP chips, mass spectrometry, and multiphoton microscopy, at thousands of embryo production/collection facilities is impractical. Therefore, future research is warranted to innovate field-friendly, simple benchtop tests using findings already available, particularly from omics-based research methodologies. Time-lapse monitoring and artificial-intelligence-based automated image analysis also have the potential for accurate embryo evaluation; however, further research is warranted to innovate economically feasible options for in-field applications.

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“…In mice (Zhang et al 2019) and bovine (Ispada et al 2020), the supplementation of culture media with α-KG during in vitro development interferes with DNA methylation/demethylation dynamics. Still in bovine, the analysis of the effect of the paternal and maternal age (very young bulls and cows) (Morin-Doré et al 2020, Wu et al 2020, as well as the exposure to ketone bodies (β-hydroxybutyrate) in post-partum cows, presented evidence that these three conditions share a common metabolic stress (an energy deficit) and have a similar impact on the early embryos: epigenetic alterations, reduction of their own metabolism, and induction of mitochondrial dysfunction (Wu & Sirard 2020). Surprisingly, in vitro culture seems to create a similar picture of embryos being forced into an 'economy mode' as an adaptation to suboptimal metabolic environment.…”

Section: Metaboloepigenetic Events In Early Embryonic Developmentmentioning

confidence: 99%

DOHaD: A Menagerie of Adaptations and Perspectives: The interplay between early embryo metabolism and mitoepigenetic programming of development

2023

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Initially perceived simply as an ATP producer, mitochondria also participate in a wide range of other cellular functions. Mitochondrial communication with the nucleus, as well as signaling to other cellular compartments is critical to cell homeostasis. Therefore, during early mammalian development, mitochondrial function is reported as a key element for survival. Any mitochondrial dysfunction may reflect in poor oocyte quality and may impair embryo development with possible long-lasting consequences to cell functions and the overall embryo phenotype. Growing evidence suggests that the availability of metabolic modulators can alter the landscape of epigenetic modifications in the nuclear genome providing an important layer for the regulation of nuclear-encoded gene expression. However, whether mitochondria could also be subjected to such similar epigenetic alterations and the mechanisms involved remain largely obscure and controversial. Mitochondrial epigenetics, also known as ‘mitoepigenetics’ is an intriguing regulatory mechanism in mitochondrial DNA (mtDNA)-encoded gene expression. In this review, we summarized the recent advances in mitoepigenetics, with a special focus on mtDNA methylation in reproductive biology and preimplantation development. A better comprehension of the regulatory role of mitoepigenetics will help the understanding of mitochondrial dysfunction and provide novel strategies for in vitro production systems and assisted reproduction technologies, as well as prevent metabolic-related stress and diseases.

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DNA methylation status of bovine blastocysts obtained from peripubertal oocyte donors

Cited by 5 publications

References 62 publications

IGF2R, KCNQ1, PLAGL1, and SNRPN DNA methylation is completed in bovine by the early antral follicle stage

IGF2R, KCNQ1, PLAGL1, and SNRPN DNA methylation is completed in bovine by the early antral follicle stage

Pre-Implantation Bovine Embryo Evaluation—From Optics to Omics and Beyond

DOHaD: A Menagerie of Adaptations and Perspectives: The interplay between early embryo metabolism and mitoepigenetic programming of development

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