Zuzana Trebichalská scite author profile

Kyjovská²,

Kloudová³

et al. 2020

Female fertility relies on successful egg development. Besides chromosome segregation, complex structural and biochemical changes in the cytoplasmic compartment are necessary to confer the female gamete the capacity to undergo normal fertilization and sustain embryonic development. Despite the profound impact on egg quality, morphological bases of cytoplasmic maturation remain largely unknown. Here, we report our findings from the ultrastructural analysis of 69 unfertilized human oocytes from 34 young and healthy egg donors. By comparison of samples fixed at three consecutive developmental stages, we explored how ooplasmic architecture changes during meiotic maturation in vitro. The morphometric image analysis supported observation that the major reorganization of cytoplasm occurs before polar body extrusion. The organelles initially concentrated around prophase nucleus were repositioned towards the periphery and evenly distributed throughout the ooplasm. As maturation progressed, distinct secretory apparatus appeared to transform into cortical granules that clustered underneath the oocyteʾs surface. The most prominent feature was the gradual formation of heterologous complexes composed of variable elements of endoplasmic reticulum and multiple mitochondria with primitive morphology. Based on the generated image dataset, we proposed a morphological map of cytoplasmic maturation, which may serve as a reference for future comparative studies. In conclusion, this work improves our understanding of human oocyte morphology, cytoplasmic maturation, and intracellular factors defining human egg quality. Although this analysis involved spare oocytes completing development in vitro, it provides essential insight into the enigmatic process by which human egg progenitors prepare for fertilization.

Perfect date—the review of current research into molecular bases of mammalian fertilization

Holubcová

2020

J Assist Reprod Genet

Fertilization is a multistep process during which two terminally differentiated haploid cells, an egg and a sperm, combine to produce a totipotent diploid zygote. In the early 1950s, it became possible to fertilize mammalian eggs in vitro and study the sequence of cellular and molecular events leading to embryo development. Despite all the achievements of assisted reproduction in the last four decades, remarkably little is known about the molecular aspects of human conception. Current fertility research in animal models is casting more light on the complexity of the process all our lives start with. This review article provides an update on the investigation of mammalian fertilization and highlights the practical implications of scientific discoveries in the context of human reproduction and reproductive medicine.

High-Resolution 3D Reconstruction of Human Oocytes Using Focused Ion Beam Scanning Electron Microscopy

Javůrek

Tatíčková

et al. 2021

Front. Cell Dev. Biol.

The egg plays a pivotal role in the reproduction of our species. Nevertheless, its fundamental biology remains elusive. Transmission electron microscopy is traditionally used to inspect the ultrastructure of female gametes. However, two-dimensional micrographs contain only fragmentary information about the spatial organization of the complex oocyte cytoplasm. Here, we employed the Focused Ion Beam Scanning Electron Microscopy (FIB-SEM) to explore human oocyte intracellular morphology in three dimensions (3D). Volume reconstruction of generated image stacks provided an unprecedented view of ooplasmic architecture. Organelle distribution patterns observed in nine donor oocytes, representing three maturational stages, documented structural changes underlying the process by which the egg acquires developmental competence. 3D image segmentation was performed to extract information about distinct organelle populations, and the following quantitative analysis revealed that the mitochondrion occupies ∼ 4.26% of the maturing oocyte cytoplasm. In summary, this proof-of-concept study demonstrates the potential of large volume electron microscopy to study rare samples of delicate female gametes and paves the way for applying the FIB-SEM technique in human oocyte research.

Cryo-electron tomography of enterovirus cell entry and endosome escape

Ishemgulova

Mukhamedova

et al. 2023

Preprint

Enveloped viruses deliver their genomes into the cell cytoplasm by membrane fusion; in contrast, membrane penetration by non-enveloped viruses is more diverse and less well understood. Enteroviruses, one of the largest groups of non-enveloped viruses, cause diseases ranging from the common cold to life-threatening encephalitis. To initiate infection, most enteroviruses enter cells by endocytosis. However, how enterovirus particles or RNA genomes cross the endosome membrane into the cytoplasm remains unknown. Here we used cryo-electron tomography of infected cells to show that endosomes containing rhinovirus 2, echovirus 18, echovirus 30, or enterovirus 71 deform, rupture, and release their content into the cytoplasm. Blocking endosome acidification with bafilomycin A1 reduced the number of enterovirus particles that released their genomes in endosomes, but did not prevent them from reaching the cytoplasm. Inhibiting N-WASP-mediated post-endocytic membrane remodeling with wiskostatin promoted abortive enterovirus genome release in endosomes. We show that the rupture of endosomes also occurs in uninfected cells. In summary, our results indicate that cellular membrane remodeling disrupts enterovirus-containing endosomes and thus releases the virus genomes and particles into the cytoplasm. Since the studied enteroviruses employ different receptors for cell entry but are all delivered into the cytoplasm by cell-mediated endosome disruption, it is possible that many other enteroviruses utilize endosome rupture to infect cells.

The ultrastructural nature of human oocytes’ cytoplasmatic abnormalities and the role of cytoskeleton dysfunction

Tatíčková

Kyjovská³

et al. 2023

Preprint

Egg quality is a limiting factor of female fertility and assisted reproductive technology (ART) success. Oocytes recovered from hyperstimulated ovaries often display morphological anomalies suspected to compromise their fertilization and developmental potential. Knowledge of (ab)normal oocyte’s intracellular organization is vital to establish reliable criteria for morphological evaluation of oocytes intended for in vitro fertilization (IVF). Here, we investigated the fine morphology of 22 dysmorphic IVF oocytes exhibiting different types of cytoplasmic irregularities, namely (1) refractile bodies, (2) centrally-located cytoplasmic granularity (CLCG), (3) smooth endoplasmic reticulum (SER) disc, and (4) vacuoles. Transmission electron microscopy (TEM) revealed the structural basis of these aberrations and indicated that the underlying cause of two of the studied morphotypes was inordinate organelle clustering. To address the mechanism required for accurate organelle positioning, we used cytoskeleton-targeting chemical compounds and performed a series of inhibition experiments involving a total of 133 human oocytes maturing in vitro. Fluorescence and electron microscopy showed that disruption of actin, not microtubules, led to the aggregation of subcellular structures resembling the morphological pattern seen in abnormal oocytes. These results imply that actin serves as a regulator of organelle distribution during human oocyte maturation. The ultrastructural analogy between dysmorphic eggs retrieved in IVF cycles and oocytes, in which actin network integrity was perturbed, suggests that dysfunction of the actin cytoskeleton might be implicated in generating common cytoplasmic aberrations. Knowledge of human oocytes’ inner workings and the origin of morphological abnormalities is a step forward to more objective egg quality assessment in clinical practice.SUMMARY SENTENCEUltrastructural analysis of eggs exhibiting cytoplasmic abnormalities combined with inhibition experiments indicates that dysfunction of the actin network might be involved in the development of oocyte dysmorphisms.