bims-mazytr Biomed News
on Maternal‐to‐zygotic transition
Issue of 2025–06–08
fourteen papers selected by
川一刀
  1. Maternal loss of mouse Nlrp2 alters the transcriptome and DNA methylome in GV oocytes and impairs zygotic genome activation in embryos.
  2. Inorganic profiles of preimplantation embryos reveal a role for zinc in blastocyst development.
  3. RNA Pol I activity maintains chromatin condensation and the H3K4me3 gradient essential for oogenesis, independent of ribosome production.
  4. Dissecting pre- to post-implantation transition of DNA methylome-transcriptome dynamics in early mammalian development.
  5. Control of tissue flows and embryo geometry in avian gastrulation.
  6. Characterization of H3K4me3 in mouse oocytes at the metaphase II stage.
  7. Dynamic revelation of early development in mouse embryo via Raman spectroscopy.
  8. High resolution of full-length RNA sequencing deciphers massive transcriptome complexity during zebrafish embryogenesis.
  9. GATAD2B regulates spindle assembly by affecting protein deacetylation during oocyte meiotic maturation.
  10. Oocyte mitochondria link maternal environment to offspring phenotype.
  11. A Comprehensive Review of Mitochondrial Complex I During Mammalian Oocyte Maturation.
  12. Challenges and Opportunities in Spatiotemporal Models of Mammalian Gastrulation.
  13. Dysregulation of alternative splicing patterns in the ovaries of reproductively aged mice.
  14. Association of mitochondrial DNA content and embryo morphology in fully expanded euploid blastocysts.
  1. Clin Epigenetics. 2025 Jun 03. 17(1): 92
    Maternal loss of mouse Nlrp2 alters the transcriptome and DNA methylome in GV oocytes and impairs zygotic genome activation in embryos.
    Zahra Anvar, Michael D Jochum, Imen Chakchouk, Momal Sharif, Hannah Demond, Alvin K To, Daniel C Kraushaar, Ying-Wooi Wan, Michael C Mari, Simon Andrews, Gavin Kelsey, Ignatia B Van den Veyver.
       BACKGROUND: NLRP2 is a subcortical maternal complex (SCMC) protein of mammalian oocytes and preimplantation embryos. SCMC proteins are encoded by maternal effect genes and play a pivotal role in the maternal-to-zygotic transition (MZT), early embryogenesis, and epigenetic (re)programming. Maternal inactivation of genes encoding SCMC proteins has been linked to infertility and subfertility in mice and humans, but the underlying molecular mechanisms for the diverse functions of SCMC proteins, and specifically the role of NLRP2, are incompletely understood.
    RESULTS: We profiled the DNA methylome of pre-ovulatory germinal-vesicle (GV) oocytes from Nlrp2-null, heterozygous (Het), and wild-type (WT) female mice and assessed the transcriptome of GV oocytes and 2-cell embryos from WT and Nlrp2-null females. The absence or reduction of NLRP2 did not alter the distinctive global DNA methylation landscape of GV oocytes, including their unique bimodal methylome patterns and methylation at the germline differentially methylated regions (gDMRs) of imprinted genes. However, altered methylation was observed in a small subset of oocyte-characteristic hyper- and hypomethylated domains and within a minor fraction of genomic regions, particularly in Nlrp2-null oocytes. Transcriptome profiling revealed substantial differences between the Nlrp2-null and WT GV oocytes, including deregulation of many crucial factors involved in oocyte transcriptome modulation and epigenetic reprogramming. Moreover, maternal absence of NLRP2 significantly altered the transcriptome of heterozygous embryos from Nlrp2-null females compared to WT embryos, whereas the transcriptome of heterozygous embryos from Nlrp2-null males was not significantly different from that of WT embryos. Maternal absence of NLRP2 also negatively impacted MZT, as evidenced by the deregulation of a large subset of zygotic genome activation (ZGA)-related genes.
    CONCLUSIONS: This study demonstrates that NLRP2 is essential for shaping the transcriptome of GV oocytes and preimplantation embryos. Maternal loss of Nlrp2 negatively impacts ZGA. Our findings that the DNA methylome of Het and Nlrp2-null oocytes was subtly changed, and that gene-body DNA methylation differences did not correlate with gene expression differences, suggest that posttranscriptional changes in transcript stability, rather than altered transcription itself, are primarily responsible for the changed transcriptome of Nlrp2-null oocytes.
    Keywords:  DNA methylation; Imprinted genes; Oocyte; Subcortical maternal complex
    DOI:  https://doi.org/10.1186/s13148-025-01889-x
  2. bioRxiv. 2025 May 18. pii: 2025.05.14.654061. [Epub ahead of print]
    Inorganic profiles of preimplantation embryos reveal a role for zinc in blastocyst development.
    Julia L Balough, Thomas V O'Halloran, Francesca E Duncan, Teresa K Woodruff.
      Elements such as iron, copper and zinc play essential roles in the mammalian oocyte, egg, and embryo, however among these metals, zinc plays unique regulatory roles. Temporal fluctuations in zinc concentrations drive reproductive milestones such as meiotic resumption, egg activation, and initiation of the mitotic cell cycle. Roles for zinc in late preimplantation embryo development, have not been well characterized. Using a quantitative element approach we report the inorganic profiles of mouse embryos progressing through the late blastocyst stage. We find that blastocysts, like oocytes and eggs, and distinct to somatic cells, maintain higher levels of zinc than copper and iron. All three of these essential metals are more abundant in the inner cell mass, which contains the population of pluripotent stem cells that give rise to the fetus, relative to the trophectoderm which gives rise to the placenta and extraembryonic tissues. To test whether zinc abundance was associated with mitotic progress and cell fate lineage, we perturbed zinc homeostasis during blastocyst formation by artificially raising intracellular zinc concentrations with zinc pyrithione. This treatment during the morula-to-blastocyst transition when cell fate lineages emerge resulted in an elevation of zinc in the ICM. This treatment did not impact cell number, but did increase expression of the pluripotency and epiblast marker, Nanog , and decreased expression of the primitive endoderm marker, Gata4 . These results demonstrate that the inorganic profiles of the late preimplantation embryo retain elemental hallmarks of earlier developmental stages and perturbation of zinc levels alters pluripotency gene expression in the blastocyst.
    DOI:  https://doi.org/10.1101/2025.05.14.654061
  3. bioRxiv. 2025 May 12. pii: 2025.05.07.652530. [Epub ahead of print]
    RNA Pol I activity maintains chromatin condensation and the H3K4me3 gradient essential for oogenesis, independent of ribosome production.
    Raquel Mejia-Trujillo, Qiuxia Zhao, Ayesha Rahman, Elif Sarinay Cenik.
      Oogenesis requires extensive and dynamic chromatin remodeling that primes gene promoters for later transcriptional activation during embryonic development. Here, we uncover a pivotal, non-canonical role for RNA Polymerase I (Pol I) in driving these chromatin state transitions during Caenorhabditis elegans oogenesis. Using the auxin-inducible degron system to selectively deplete either a Pol I-specific catalytic subunit or a ribosome assembly factor, we disentangle the consequences of impaired nucleolar integrity from reductions in ribosome biogenesis. Strikingly, although disrupting ribosome assembly caused minimal effects on oocyte production, loss of nucleolar structure via Pol I depletion led to severe meiotic chromosome abnormalities, widespread changes in chromatin accessibility, and a dampening of the typical distal-proximal H3K4me3 gradient required for oogenesis, resulting in fewer but significantly larger oocytes. Despite their promoters becoming more accessible, oogenesis genes did not show large changes in steady-state mRNA, consistent with transcriptional repression prior to fertilization. Instead, Pol I depletion prematurely remodeled oogenic chromatin, through a misdirection of H3K4me3 deposition towards promoters normally primed for zygotic genome activation. These findings reveal an epigenetic gating function for nucleolar integrity in oocyte maturation: Pol I preserves three-dimensional chromatin organization and maintains proper spatiotemporal regulation of histone modifications, independent of ribosome production. Given the evolutionary conservation of nucleolar dynamics and histone modifications during gametogenesis, our work suggests that nucleolar stress, whether from environmental factors, aging, or genetic disorders, could broadly compromise fertility by disrupting oogenic chromatin priming.
    DOI:  https://doi.org/10.1101/2025.05.07.652530
  4. Cell Rep. 2025 Jun 03. pii: S2211-1247(25)00561-3. [Epub ahead of print]44(6): 115790
    Dissecting pre- to post-implantation transition of DNA methylome-transcriptome dynamics in early mammalian development.
    Qingyuan Zhu, Ying Liu, Xin Hao, Shengyi Yan, Jitao Ge, Changqing Zheng, Xianwen Ren, Fan Zhou.
      Pre- to post-implantation transition is an essential step for early mammalian development. The epigenome dynamics such as DNA methylome and transcriptome of embryos have been analyzed, while the coordination between these two molecular layers controlling lineage fate remained elusive. Here, with a multidimensional profiling of peri-implantation embryos, we present the emerging lineage-specific DNA methylation (DNAme) patterns across species. The maternal and paternal DNA methylation levels exhibit differential dynamics in transposon elements. Genes with lineage-specific unmethylated promoters early in development retain this state and are expressed later, suggesting a role in lineage fate determination. By measuring both molecular dimensions simultaneously in individual developing cells, we identified a group of gene promoters with positive correlation between DNAme and RNAex along epiblast development. Functional validation suggested DNAme at these promoters contributes to non-canonical DNAme-RNAex dynamics, potentially via complex TF-mediated or epigenetic regulation. This study provides clues for understanding molecular regulation of peri-implantation embryogenesis.
    Keywords:  CP: Developmental biology; CP: Molecular biology; DNA methylome; early mammalian development; pre- to post-implantation transition; transcriptome
    DOI:  https://doi.org/10.1016/j.celrep.2025.115790
  5. Nat Commun. 2025 Jun 04. 16(1): 5174
    Control of tissue flows and embryo geometry in avian gastrulation.
    Guillermo Serrano Nájera, Alex M Plum, Ben Steventon, Cornelis J Weijer, Mattia Serra.
      Embryonic tissues undergo coordinated flows during avian gastrulation to establish the body plan. Here, we elucidate how the interplay between embryonic and extraembryonic tissues affects the chick embryo's size and shape. These two distinct geometric changes are each associated with dynamic curves across which trajectories separate (kinematic repellers). Through physical modeling and experimental manipulations of both embryonic and extraembryonic tissues, we selectively eliminate either or both repellers in model and experiments, revealing their mechanistic origins. We find that embryo size is affected by the competition between extraembryonic epiboly and embryonic myosin-driven contraction-which persists when mesoderm induction is blocked. Instead, the characteristic shape change from circular to pear-shaped arises from myosin-driven cell intercalations in the mesendoderm, irrespective of epiboly. These findings elucidate modular mechanisms controlling avian gastrulation flows and provide a mechanistic basis for the independent control of embryo size and shape during development.
    DOI:  https://doi.org/10.1038/s41467-025-60249-8
  6. J Biol Chem. 2025 May 29. pii: S0021-9258(25)02158-1. [Epub ahead of print] 110308
    Characterization of H3K4me3 in mouse oocytes at the metaphase II stage.
    Atsushi Takasu, Toshiaki Hino, Osamu Takenouchi, Yasuki Miyagawa, Zhihua Liang, Shota Tanaka, Tomoya Mimura, Chisato Ida, Yuki Matsuo, Yuna Lee, Haruka Ikegami, Miho Ohsugi, Shogo Matoba, Atsuo Ogura, Kazuo Yamagata, Kazuya Matsumoto, Tomoya S Kitajima, Kei Miyamoto.
      Central functions of histone modifications in germ cell and embryonic development have been documented. Accumulating evidence suggests that oocytes possess unique profiles of histone modifications, among which histone H3 lysine 4 trimethylation (H3K4me3) is broadly spread on the mouse oocyte chromosomes at the metaphase II (MII) stage, unlike later embryonic stages. However, the characteristics and developmental roles of H3K4me3 on MII chromosomes are unclear. Here, we discovered that H3K4me3 was abundantly localized on some of the MII oocyte chromosomes facing the cortical side. Using multicolor FISH and CRISPR-Sirius-based labeling of chromosomes, we revealed that the X chromosome tended to be localized at the cortical side with strong H3K4me3 signals. Anchoring oocyte chromosomes to the cortex may play a role in the asymmetric H3K4me3 distribution. Furthermore, we found that the forced removal of H3K4me3 through the overexpression of a specific lysine demethylase in MII oocytes resulted in abnormal chromosome-spindle structure and impaired preimplantation development after in vitro fertilization. These findings highlight the developmental function of H3K4me3 in transcriptionally-silent MII oocytes.
    Keywords:  Chromosome; H3K4me3; Mouse; Oocyte; Pre-implantation development
    DOI:  https://doi.org/10.1016/j.jbc.2025.110308
  7. Spectrochim Acta A Mol Biomol Spectrosc. 2025 Dec 05. pii: S1386-1425(25)00781-4. [Epub ahead of print]342 126475
    Dynamic revelation of early development in mouse embryo via Raman spectroscopy.
    Chenwei He, Shan Huang, Runxin Yi, Jun Zhang, Nan Yan, Lingyin Kong, Kaidi Yu, Qingkai Guo, FangFang Dong, Bo Liang, Shuai Zhou, Junqiang Zhang.
      Non-invasive embryo quality assessment techniques in clinical practice remain in early developmental phase, highlighting the critical need to expand technical methods and improve evaluation accuracy.This study applies Raman spectroscopy to characterize glucose and lipid metabolic profiles during the early development of mouse embryos, aiming to explore the possibility of both as biomarkers for non-invasive assessment of embryo quality. Through semi-quantitative analysis, this research demonstrate that the average glucose metabolism remains relatively stable from Day 0 to 3 post conception (D0-3), followed by a significant increase in consumption around D3, and robust metabolic activity during D4-D5. The study also confirms the pivotal role of glucose metabolism in facilitating blastocyst formation. Additionally, Raman imaging was employed to visualize distribution of structural components and the dynamic lipid metabolism changes across 1-cell, 2-cell, and 4-cell stages, providing novel insights into quantitative lipidomic analysis of early embryos.
    Keywords:  Glucose metabolism; Lipid metabolism; Non-invasive embryo quality assessment; Raman Spectroscopy
    DOI:  https://doi.org/10.1016/j.saa.2025.126475
  8. BMC Biol. 2025 Jun 04. 23(1): 155
    High resolution of full-length RNA sequencing deciphers massive transcriptome complexity during zebrafish embryogenesis.
    Jing Bo, Wenyu Fang, Jing Wang, Shunping He, Liandong Yang.
       BACKGROUND: The zebrafish has significantly advanced our understanding of human disease and development, with nearly 70% of single-copy protein-coding genes conserved between the species. However, research on zebrafish is limited by gaps in existing genome annotations, which are primarily based on computational predictions and short-read sequencing data.
    RESULTS: To address this issue, we employed the PacBio Sequel II platform to generate a time-series full-length transcriptome landscape of zebrafish embryogenesis, covering 21 time points from embryo to six days post-fertilization. Our analysis uncovered 2113 previously unannotated genes and 33,018 novel isoforms of previously annotated genes, substantially expanding the current zebrafish gene annotations. We verified these findings using various methods, including domain prediction, homology analysis, conservation analysis, transcript quantification with short-read RNA-seq, and promoter position information with H3K4me3 and CAGE-seq. Furthermore, we analyzed the dynamic expression of transcripts across the 21 developmental stages using next-generation sequencing data, identifying variable splicing events throughout these stages.
    CONCLUSIONS: Collectively, our study provides a high-resolution and significantly improved transcriptome annotation during zebrafish embryogenesis, offering a valuable resource for the zebrafish research community.
    Keywords:  Embryogenesis; Long-read sequencing; Zebrafish; Zygotic genome activation
    DOI:  https://doi.org/10.1186/s12915-025-02271-2
  9. Anim Biosci. 2025 Jun 04.
    GATAD2B regulates spindle assembly by affecting protein deacetylation during oocyte meiotic maturation.
    Qian Xu, Lina Yu, Yuling Lin, Aolei Guo, Yang Zhang, Zhe Zhang, Guijun Yan, Haixiang Sun, Guangyi Cao.
       Objective: Oocyte quality is critical for the stable transmission of genetic information and affects early embryonic development. But the precise mechanisms governing oocyte meiotic progression remains largely unclear. Transcription regulation through chromatin compaction and decompaction is regulated through various chromatin-remodeling complexes such as nucleosome remodeling and histone deacetylation (NuRD) complex. GATAD2B is known to be a component of the NuRD complex but whether GATAD2B regulates chromatin modification in mouse oocyte meiosis remains unclear. We hope to explore the role of GATAD2B in mouse oocyte meiosis.
    Methods: In this study, we initially utilized western blot and immunofluorescence to delineate the expression and subcellular localization of GATAD2B during oocyte meiotic maturation. To further elucidate the role of GATAD2B in regulating oocyte meiotic division, we employed the method of microinjection of Gatad2b-specific siRNA to knock down the protein expression of GATAD2B. Subsequently, dynamic changes in oocyte meiotic division were captured in real-time using live-cell imaging with Geri. Additionally, spindle staining, DNA staining, spread analysis, and reanalysis of RNA-seq data were performed to investigate the mechanisms through which GATAD2B regulates oocyte meiotic division.
    Results: GATAD2B was stably expressed during oocyte meiosis and was significantly increased during the MII stage. To further explore the effect of GATAD2B on oocyte meiotic maturation, we observed increased abnormal spindle, severe chromosome misalignment and MI block in GATAD2B knocked-down oocytes. Interestingly, the distribution of microtubule organizing center was abnormal and aneuploidy was significantly increased in Gatad2b-KD oocytes. In addition, some deacetylation-related genes were significantly downregulated and acetylated proteins accumulated abnormally in Gatad2b-KD oocytes.
    Conclusion: These findings implicate GATAD2B as a novel regulator of histone deacetylation during oocyte maturation and provide evidence that such deacetylation is required for proper spindle assembly.
    Keywords:  GATAD2B; Oocyte; deacetylation; meiosis; spindle
    DOI:  https://doi.org/10.5713/ab.25.0013
  10. bioRxiv. 2025 May 16. pii: 2025.05.13.653493. [Epub ahead of print]
    Oocyte mitochondria link maternal environment to offspring phenotype.
    Jason F Cooper, Kim Nguyen, Darrick Gates, Emily Wolfrum, Colt Capan, Hyoungjoo Lee, Devia Williams, Chidozie Okoye, Kelsie Nauta, Ximena Sanchez-Avila, Ryan T Kelly, Ryan Sheldon, Andrew P Wojtovich, Nicholas O Burton.
      During oogenesis and maturation oocytes undergo a recently discovered mitochondrial electron transport chain (ETC) remodeling in flies 1 , frogs 1 , and humans 2 . This conserved oocyte ETC remodeling is regulated by maternal insulin signaling, but its role in biology remains unclear. In the model animal Caenorhabditis elegans , we previously found that insulin signaling to oocytes regulates offspring's ability to adapt to future osmotic stress by altering offspring metabolism. However, the molecular mechanisms that function in oocytes to mediate this intergenerational stress response are similarly unknown. Here, we developed a low-input oocyte proteomics workflow and combined it with our C. elegans intergenerational stress response model to find that both a mother's environment and maternal insulin signaling regulate the abundance of ETC proteins in oocytes - particularly the abundance of proteins involved in the transfer of electrons from QH 2 to cytochrome C by ETC Complex III. Using genetic perturbations of ETC function we further found that promoting ETC Complex III function in oocytes was both necessary and sufficient to link a mother's environment to adaptive changes in offspring metabolism. Lastly, we found that the effects of Complex III dysfunction in oocytes on offspring were mediated via an AMP-kinase (AAK-2) dependent mechanism and that AAK-2 functions in offspring to promote ATP preservation and glycerol metabolism in response to stress. Collectively, our data suggest that the role of oocyte ETC remodeling in biology includes linking maternal environments to changes in offspring metabolism that promote offspring survival in the environment experienced by their mother.
    DOI:  https://doi.org/10.1101/2025.05.13.653493
  11. Genesis. 2025 Jun;63(3): e70017
    A Comprehensive Review of Mitochondrial Complex I During Mammalian Oocyte Maturation.
    Nazlican Bozdemir, Ceren Cakir, Ulas Topcu, Fatma Uysal.
      This review provides a comprehensive overview of Complex I during mammalian oocyte maturation. Complex I (NADH:ubiquinone oxidoreductase) is a crucial member of the electron transport chain and serves two principal functions during oxidative phosphorylation: NADH oxidation and proton pumping. It is located at the inner mitochondrial membrane and consists of 14 core and 31 accessory subunits that are necessary for its function and assembly. Moreover, Complex I is the primary site of reactive oxygen species (ROS) production among the different tissues. In light of the literature, it has been demonstrated that ROS and oxidative stress are significantly important among the various factors that can affect oocyte maturation. Factors such as malnutrition, alcohol use, obesity, PCOS, aging, and smoking are some of the common causes of infertility. Each one of them causes disruption in the equilibrium of the body's redox system and related with oxidative stress. During oocyte maturation, excessive ROS levels are associated with chromosomal errors and developmental insufficiency. In addition, excess oxidative stress adversely affects embryo growth and development and may cause fetal embryopathies with damage to macromolecules in the cytoskeleton. At this particular juncture, Complex I plays a key role in determining ROS production and the success of the oocyte maturation. This review evaluates mitochondrial Complex I's function, structure, and its crucial role during oocyte maturation.
    Keywords:  ROS; complex I; mitochondria; oocyte maturation; oogenesis; oxidative stress
    DOI:  https://doi.org/10.1002/dvg.70017
  12. Annu Rev Cell Dev Biol. 2025 Jun 04.
    Challenges and Opportunities in Spatiotemporal Models of Mammalian Gastrulation.
    Hernan Rubinstein, Yoav Mayshar, Yonatan Stelzer.
      How cells diversify to form an embryo represents a profound interdisciplinary challenge. Decades of innovative research using model organisms have uncovered principles of lineage specification, morphogenesis, epigenetic mechanisms, and gene regulation that underlie this fundamental process. As biology enters the genomic era, marked by rapid convergence of technological and computational advances, construction of quantitative and heuristic models of development becomes increasingly feasible. In gastrulation, a founding population of equipotent stem cells rapidly diversifies in a highly canonical manner to form the basic body plan. This review discusses considerations required to establish a time-resolved model that reflects the cellular and molecular aspects involved in this process. Building on insights from recent studies and the transformative potential of evolving technologies and experimental frameworks, we discuss how to devise such a model by integrating multiple molecular modalities at the single-cell level within the spatial context as a benchmark for studying cell specification.
    DOI:  https://doi.org/10.1146/annurev-cellbio-101323-125216
  13. bioRxiv. 2025 May 23. pii: 2025.05.19.654918. [Epub ahead of print]
    Dysregulation of alternative splicing patterns in the ovaries of reproductively aged mice.
    Nehemiah S Alvarez, Pavla Brachova.
      Female reproductive aging is characterized by progressive deterioration of ovarian function, yet the molecular mechanisms driving these changes remain incompletely understood. Here, we used long-read direct RNA-sequencing to map transcript isoform changes in mouse ovaries across reproductive age. Comparing young and aged mice after controlled gonadotropin stimulation, we identified widespread alternative splicing changes, including shifts in exon usage, splice site selection, and transcript boundaries. Aged ovaries exhibited increased isoform diversity, favoring distal start and end sites, and a significant rise in exon skipping and intron retention events. Many of these age-biased splicing events altered open reading frames, introduced premature stop codons, or disrupted conserved protein domains. Notably, mitochondrial genes were disproportionately affected. We highlight Ndufs4 , a mitochondrial Complex I subunit, as a case in which aging promotes the alternative splicing of a truncated isoform lacking the canonical Pfam domain. Structural modeling suggests this splice variant could impair Complex I function, resulting in increased ROS production. Our data suggest a mechanistic link between splicing and mitochondrial dysfunction in the aging ovary. These findings support the model of the splicing-energy-aging axis in ovarian physiology, wherein declining mitochondrial function and adaptive or maladaptive splicing changes are intertwined. Our study reveals that alternative splicing is not merely a byproduct of aging but a dynamic, transcriptome-wide regulatory layer that may influence ovarian longevity. These insights open new avenues for investigating post-transcriptional mechanisms in reproductive aging and underscore the need to consider isoform-level regulation in models of ovarian decline.
    In brief: Reproductive aging is associated with changes in alternative splicing patterns in the mouse ovary. Our study identifies alterations in exon usage that may have altered protein function and important roles in ovarian physiology as well as in reproductive aging.
    DOI:  https://doi.org/10.1101/2025.05.19.654918
  14. Hum Fertil (Camb). 2025 Dec;28(1): 2501547
    Association of mitochondrial DNA content and embryo morphology in fully expanded euploid blastocysts.
    Ivo Karač, Gary G Ramsey, Romana Gračan, Sanja Vujisić Živković, Kristian Bodulić.
      Over the past two decades, mitochondrial DNA (mtDNA) content has been studied as a potential biomarker for embryo viability and implantation success during in vitro fertilization (IVF) procedures. However, its reliability for embryo selection remains uncertain. Therefore, our study aimed to examine the relationship between blastocyst mtDNA content and blastocyst quality, timing of fully expanded blastocyst formation, and cleavage-stage embryo quality in blastocysts biopsied at the uniform expansion stage. We analyzed bioinformatics data from 125 day-5 and day-6 blastocysts from women aged 18 to 35 years. Each blastocyst was biopsied at expansion stage 4 and classified as euploid through preimplantation genetic testing for aneuploidy using next-generation sequencing. Blastocysts were categorized into four groups based on quality and the day of biopsy. Poor-quality day-6 blastocysts exhibited lower mtDNA levels compared to good-quality day-5 blastocysts (p = 0.006), poor-quality day-5 blastocysts (p = 0.008), and good-quality day-6 blastocysts (p = 0.003). Embryos with day-3 grades lower than 2.5 displayed lower blastocyst mtDNA levels compared to those graded 1 (p < 0.001), 1.5 (p < 0.001), and 2 (p < 0.001). These findings suggest further insights into the interplay between blastocyst mtDNA content and preimplantation embryo morphology. Nonetheless, mtDNA remains an unreliable biomarker for assessing embryo viability, warranting further investigation to determine its clinical relevance.
    Keywords:  Blastocyst; euploid; mitochondrial DNA; morphology; next-generation sequencing: embryo; preimplantation diagnosis
    DOI:  https://doi.org/10.1080/14647273.2025.2501547
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