Variation of female pronucleus reveal oocyte or embryo abnormality: An expert experience deep learning of non-dark box analysis

Background: Pronuclear assessment appears to have the ability to distinguish good and bad embryos in the zygote stage,but paradoxical results were obtained in clinical studies.This situation might be caused by the robust qualitative detection of the development of dynamic pronuclei. Here,we aim to establish a quantitative pronuclear measurement method by applying expert experience deep learning from large annotated datasets. Methods: Convinced handle-annotated 2PN images(13419) were used for deep learning then corresponded errors were recorded through handle check for subsequent parameters adjusting. We used 790 embryos with 52479 PN images from 155 patients for analysis the area of pronuclei and the preimplantation genetic test results.Establishment of the exponential fitting equation and the key coefficient β1 was extracted from the model for quantitative analysis for pronuclear(PN) annotation and automatic recognition. Findings: Based on the female original PN coefficient β1,the chromosome normal rate in the blastocyst with biggest PN area is much higher than that of the blastocyst with smallest PN area(58.06% vs.45.16%, OR=1.68[1.07-2.64];P=0.031).After adjusting coefficient β1 by the first three frames which high variance of outlier PN areas was removed, coefficient β1 at 12 hours and at 14 hours post-insemination,similar but stronger evidence was obtained. All these discrepancies resulted from the female propositus in the PGT(SR) subgroup and smaller chromosomal errors. Conclusion(s): The results suggest that detailed analysis of the images of embryos could improve our understanding of developmental biology. Funding: None

Nuclear-to-cytoplasmic ratios of 1PN and 2PN zygotes after in vitro fertilization of mouse oocytes

Summary Numerous studies have reported comparisons of the nuclear-to-cytoplasmic (NC) ratio during mitosis. However, little information is known about how the pronuclear size is regulated and determined at the end of meiosis II in mammalian zygotes. The present study aims to analyze the NC ratio of female and male pronuclei, and also to compare the size of single pronuclei using photographs that were obtained during experiments to create chimeric hermaphrodites from 2-cell oocytes. The volume of both the female and the male pronucleus was found to correlate with the volume of the oocyte cytoplasm. The NC ratio of the male pronucleus was greater than that of the female pronucleus. The NC ratio of the average volume of the female and male pronuclei was greater than the NC ratio of the mononucleate oocytes. The occurrence of 1PN oocytes was significantly higher when the volume of cytoplasm was lower than the cut-off value. These results indicated that the NC ratio is retained during pronuclear formation. A higher NC ratio in male compared with the female pronucleus indicated structural and/or molecular difference between the two pronuclei. 1PN formation may occur when sperm enters close to the MII spindle.

111 Fertilizing ability of frozen and freeze-dried semen following intracytoplasmic sperm injection of invitro-matured sheep oocytes

Freeze-drying is a novel technique that permits the storage of semen at room temperature for long time periods, retaining their fertilizing capacity. The main objective of this work was to compare the fertilization ability of frozen-thawed (FT) and freeze-dried (FD) ram semen following intracytoplasmic sperm injection (ICSI) of invitro-matured (IVM) sheep oocytes. Oocytes were recovered by slicing the ovaries of slaughtered sheep. Selected cumulus-oocyte complexes (COCs) were IVM for 24h in tissue culture medium 199 (TCM-199) supplemented with 10% heat-treated oestrous sheep serum (ESS), 0.36mM pyruvate, FSH (1IUmL−1), and luteinising hormone (LH; 1IUmL−1) under mineral oil in a humidified atmosphere of 5% CO2, at 38.5°C. Semen was collected from fertile adult rams using an artificial vagina and processed for (1) freezing and thawing (Khalifa and Lymberopoulos, 2013 Cell Tissue Bank 14, 687-698; https://doi.org/10.1007/s10561-012-9357-6) or (2) freeze-drying and rehydration according to Arav et al. (2018 J. Assist. Reprod. Genet. 35, 1149-115; https://doi.org/10.1007/s10815-018-1145-1) protocols. For FD protocol, sperm samples were diluted in a sugar solution of trehalose and sorbitol (LyoB) and dehydrated for 24h. Later, the samples were rehydrated in a warming solution and diluted in TCM-199 before ICSI. After maturation, metaphase II (MII) oocytes with a polar body were injected with FT or FD sperm. Briefly, oocytes were transferred into groups of six in an ICSI dish containing 6-µL drops of holding medium (TCM-199 + 5% fetal bovine serum) and 3-µL drops of PVP for the sperm samples. Injection was carried out with an inverted microscope (Olympus IX73) connected to a micromanipulation system (Narishige) using ICSI pipettes with 7-µm internal diameter. Within 1h, ICSI oocytes were activated with 5 µM ionomycin for 4min and invitro cultured in modified synthetic oviductal fluid medium (Bogliolo et al. 2011 Reprod. Fertil. Dev. 23, 809-817; https://doi.org/10.1071/RD11023). After 17-21h, injected oocytes were fixed and stained in a solution of ethanol Hoechst 33342 and classified as FPN (one female pronucleus and one condensed sperm head), MPN (one male pronucleus and one MII), 2PN (two pronuclei, male and female), 3PN (three or more pronuclei), and NPN (no pronuclei). Data were analysed using analysis of variance (two-way ANOVA) followed by Tukey post hoc test with SAS software, version 9.4. The ICSI-FD group had a higher number of NPN and a lower number of 2PN than did the ICSI-FT group (P<0.05). We think that more technical advances in the FD process as well as the rehydration procedure are necessary to improve the application of FD ovine semen for invitro fertilization by ICSI in sheep, but in any case these results have showed that FD could be a useful tool for the future of invitro embryo production. Table 1.Pronuclear formation at 17-21h post-injection1 Treatment n FPN MPN 2PN 3PN NPN FT 71 9.66±4.12 4.26±1.48 48.13±2.79a 5.97±4.16 31.98±6.75a FD 65 6.16±2.26 1.39±1.39 20.15±4.14b 10.57±6.59 61.73±6.89b a,bValues in the same column with different superscript letters differ significantly (P<0.05). 1Data are presented as mean±s.e.m. FPN=female pronucleus, MPN=one male pronucleus and one metaphase II oocyte, 2PN=two pronuclei, male and female, 3PN=three or more pronuclei, NPN=no pronuclei. Funding was provided by Spanish MINECO Grant AGL2017-85837-R, Spanish MECD pre-doctoral grant FPU15/00773, and Spanish MECD mobility grant EST18/00472 to Irene Menéndez Blanco.

Exchanges of histone methylation and variants during mouse zygotic genome activation

SummaryMinor and major zygotic genome activation (ZGA) are crucial for preimplantation development. During this process, histone variants and methylation influence chromatin accessibility and consequently regulated the expression of zygotic genes. However, the detailed exchanges of these modifications during ZGA remain to be determined. In the present study, the epigenetic modifications of histone 3 on lysine 9 (H3K9), 27 (H3K27) and 36 (H3K36), as well as four histone variants were determined during minor and major ZGA and in post-ZGA stages of mouse embryos. Firstly, microH2A1, H3K27me3 and H3K36me3 were asymmetrically stained in the female pronucleus during minor ZGA but lost staining in major ZGA. Secondly, H3K9me2 and H3K9me3 were strongly stained in the female pronucleus, but weakly stained in the male pronucleus and disappeared after ZGA. Thirdly, H2A.Z and H3.3 were symmetrically stained in male and female pronuclei during minor ZGA. Moreover, H3K27me2 was not statistically changed during mouse early development, while H3K36me2 was only detected in 2- and 4-cell embryos. In conclusion, our data revealed dynamics of histone methylation and variants during mice ZGA and provided details of their exchange in mice embryogenesis. Moreover, we further inferred that macroH2A1, H2A.Z, H3K9me2/3 and H3K27me2/3 may play crucial roles during mouse ZGA.

Oocyte-sperm interactions in the fertilization of birds

A thorough understanding of the mechanisms leading to the interaction between the sperm and the ovum in the process of fertilization in birds can facilitate more effective programming and control of the reproduction of these animals in breeding farms. In addition, it may allow the introduction of extracorporeal fertilization techniques, which may be important in the creation of transgenic animals and the reproduction of endangered species. In birds, the process of fertilization is not well known. It is conditioned by a series of interactions between mature reproductive cells. Oocytes are formed in the ovarian follicles of the left ovary. After ovulation, an ovum in the metaphase of the second meiotic division enters the oviduct along with the inner perivitelline layer (IPVL). It gets fertilized in this infundibulum. Male gametes are formed in paired testes located in the abdominal cavity. Sperm cells in the female reproductive tract do not require capacitation and are already fully capable of fertilization. As a result of internal insemination, male reproductive cells enter the oviduct. In this organ, they are selected and stored in the primary and secondary sperm storage tubules of the mucous membrane. They are released in batches shortly before ovulation. After reaching the oocyte, the sperm binds to the IPVL. This induces an acrosomal reaction that allows the male reproductive cells to penetrate to the surface of the oocyte, especially at the germinal pole. Next, as a result of physiological polyspermy, many sperm cells reach the ooplasm where they form haploid male pronucleus. This phenomenon is necessary to activate an polylecithal egg and produce a haploid female pronucleus. In the final stage, the female pronucleus merges with the single male pronucleus, which leads to the formation of a diploid zygote. The excess male pronuclei present in ooplasm are broken down by endonucleases (DNases). Understanding the mechanisms leading to the interaction between sperm and oocyte in birds may allow for more accurate programming and breeding of these animals in poultry farms and the introduction of extracorporeal fertilization techniques. In addition, it could be useful for the reproduction of endangered bird species

Intra-ooplasmic injection of a multiple number of sperm to induce androgenesis and polyploidy in the dojo loach Misgurnus anguillicaudatus (Teleostei: Cobitidae)

SummaryPolyspermy was initiated by microinjecting a multiple number of sperm into the activated and dechorionated eggs of dojo loach Misgurnus anguillicaudatus (Teleostei: Cobitidae). A 10-nl sperm suspension from an albino (recessive trait) male (105, 106, 107 or 108 sperm ml −1) was microinjected into eggs from a wild-type female. Although the rates of embryos developing into the blastula stage in the injection group at the highest sperm concentration were similar to that of the control group, the hatching rates of the injection group were much lower. A large proportion of embryos that developed from the injected eggs was haploid and were mosaics containing haploid cells. Most of the haploid and mosaic embryos inherited only paternally derived alleles in the microsatellite markers (i.e. androgenesis was initiated by injecting multiple sperm). In contrast, some haploid embryos contained both paternal and maternal alleles despite haploidy, suggesting that they were mosaics consisting of cells with either paternal or maternal inheritance. The injected eggs displayed diploid, hypotriploid and triploid cells, all of which included both maternally and paternally derived alleles. One albino tetraploid with only paternal alleles was also observed from the injected eggs. These results suggested that part of the sperm microinjected into the ooplasm should form a male pronucleus/pronuclei, which could develop by androgenesis or could fuse with the female pronucleus/pronuclei. Therefore, microinjection of multiple sperm should be considered a potential technique to induce androgenesis and polyploidy.

Morphology of gametes, post-fertilization events and the effect of temperature on the embryonic development of Astyanax altiparanae (Teleostei, Characidae)

SummaryThe aim of this study was to describe the morphology of gametes, post-fertilization events and subsequent temperature effects on the early developmental stages of the neotropical species Astyanax altiparanae. The sperm of this species presents a typical morphology of teleost sperm with a spherical head (diameter = 1.88 µm), midpiece (diameter = 0.75 µm) and a single flagellum (length = 18.67 µm). The extrusion of the second polar body and fusion of male and female pronucleus were reported for the first time in this species. Additionally, we observed the formation of the fertilization cone, which prevents polyspermic fertilization. Developmental stages at 22°C, 26°C and 30°C gave rise to fertilization rates at 91.12, 91.42 and 93.04% respectively. Hatching occurred at 25 hpf at 22°C, 16 hpf at 26°C and 11 hpf at 30°C and the hatching rates were 61.78%, 62.90% and 59.45%, respectively. At 22°C, the second polar body was extruded at ≈6 mpf and the male and female pronucleus fused at ≈10 mpf. This fundamental information is important for the field and opens up new possibilities in fish biotechnology, including micromanipulation and chromosome-set manipulation.

Fertilization in the cestode Echinococcus multilocularis (Cyclophyllidea, Taeniidae)

Fertilization in the taeniid cestode Echinococcus multilocularis with uniflagellate spermatozoa was examined by means of transmission electron microscopy (TEM). Fertilization in this species occurs in the oviduct lumen or in the fertilization canal proximal to the ootype, where the formation of the embryonic capsule precludes sperm contact with the oocytes. Cortical granules are not present in the cytoplasm of the oocytes of this species, however, several large bodies containing granular material where frequently observed. Spermatozoa coil spirally around the oocytes and syngamy occurs by lateral fusion of oocyte and sperm plasma membranes. In the ootype, one vitellocyte associates with fertilized oocyte, forming a membranous capsule which encloses both cell types. In this stage, the spirally coiled sperm body adheres partly to the external oocyte surface, and partially enters into the perinuclear cytoplasm. The electron-dense sperm nucleus becomes progressively electron-lucent within the oocyte cytoplasm after penetration. Simultaneously with chromatin decondensation, the elongated sperm pronucleus changes shape, forming a spherical male pronucleus, which attains the size of the female pronucleus. Cleavage begins immediately after pronuclear fusion.

Polyspermy in birds: sperm numbers and embryo survival

Polyspermy is a major puzzle in reproductive biology. In some taxa, multiple sperm enter the ovum as part of the normal fertilization process, whereas in others, penetration of the ovum by more than one sperm is lethal. In birds, several sperm typically enter the germinal disc, yet only one fuses with the female pronucleus. It is unclear whether supernumerary sperm play an essential role in the avian fertilization process and, if they do, how females regulate the progression of sperm through the oviduct to ensure an appropriate number reach the ovum. Here, we show that when very few sperm penetrate the avian ovum, embryos are unlikely to survive beyond the earliest stages of development. We also show that when the number of inseminated sperm is limited, a greater proportion than expected reach and penetrate the ovum, indicating that females compensate for low sperm numbers in the oviduct. Our results suggest a functional role for supernumerary sperm in the processes of fertilization and early embryogenesis, providing an exciting expansion of our understanding of sperm function in birds.

Chronological Reorganization of Microtubules, Actin Microfilaments, and Chromatin during the First Cell Cycle in Swamp Buffalo (Bubalus bubalis) Embryos

This paper aimed to study the dynamics of early embryonic development, in terms of redistribution of cytoskeleton (microtubules, actin microfilaments) and chromatin configurations during the first cell cycle in swamp buffalo embryos. Oocytes were matured and fertilizedin vitro, and they were fixed at various time points after IVF. At 6 h after IVF, 44.4% matured oocytes were penetrated by spermatozoa. Partial ZP digestion, however, did not improve fertilization rate compared to control (P>.05). At 12 h after IVF, the fertilized oocytes progressed to the second meiotic division and formed the female pronucleus simultaneously with the paternal chromatin continued to decondense. A sperm aster was observed radiating from the base of the decondensing sperm head. At 18 h after IVF, most presumptive zygotes had reached the pronuclear stage. The sperm aster was concurrently enlarged to assist the migration and apposition of pronuclei. Cell cleavage was facilitated by microfilaments and firstly observed by 30 h after IVF. In conclusion, the cytoskeleton actively involves with the process of fertilization and cleavage in swamp buffalo oocytes. The centrosomal material is paternally inherited. Fertilization failure is predominantly caused by poor sperm penetration. However, partial digestion of ZP did not improve fertilization rate.