Abstract
Purpose
To analyze the initiation of compaction in human embryos in vitro by using time-lapse cinematography (TLC), with the goal of determining the precise timing of compaction and clarifying the morphological changes underlying the compaction process.
Methods
One hundred and fifteen embryos donated by couples with no further need for embryo-transfer were used in this study. Donated embryos were thawed and processed, and then their morphological behavior during the initiation of compaction was dynamically observed via time-lapse cinematography (TLC) for 5 days.
Results
Although the initiation of compaction occurred throughout the period from the 4-cell to 16-cell stage, 99 (86.1 %) embryos initiated compaction at the 8-cell stage or later, with initiation at the 8-cell stage being most frequent (22.6 %). Of these 99 embryos, 49.5 % developed into good-quality blastocysts. In contrast, of the 16 (13.9 %) embryos that initiated compaction prior to the 8-cell stage, only 18.8 % developed into good-quality blastocysts. Embryos that initiated compaction before the 8-cell stage showed significantly higher numbers of multinucleated blastomeres, due to asynchronism in nuclear division at the third mitotic division resulting from cytokinetic failure.
Conclusions
The initiation of compaction primarily occurs at the third mitotic division or later in human embryos. Embryos that initiate compaction before the 8-cell stage are usually associated with aberrant embryonic development (i.e., cytokinetic failure accompanied by karyokinesis).
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Introduction
The first morphologically evident event in the differentiation of mammalian embryos is the process of compaction, which in turn has an important influence on the subsequent processes of blastocyst formation, the initiation of inner cell mass formation, and trophectoderm differentiation. During compaction, unique cell surface changes occur, involving microvilli redistribution, changes to the gap and tight junctions, mitotic proliferation, and cytoplasmic polarization. Cell-to-cell adhesion increases and intercellular contacts are maximized until the boundaries between cells become obscured, with the resultant formation of the morula. The expression of these functions requires zygotic transcription and differentiation into distinct cell lineages, which occurs at the 2-cell stage in the mouse [1–3].
The onset of compaction varies among species. Compaction is most prominent in the mouse, where it appears at the 8-cell stage, whereas in bovines it begins at the 16-cell to 32-cell stage, and in the rabbit it commences at the 32-cell to 64-cell stage [2, 4, 5]. Compaction is less marked in the rhesus monkey and baboon, where it appears at the 16-cell to 32-cell stage, and in pig embryos compaction is not established until shortly before blastocyst formation [1, 6–8]. Moreover, micro-structural analyses of the cell surfaces during compaction in primate embryos, including those of humans, revealed blastomeres that were flattened against each other, with a reduction of the intervening cleft, while the length and density of the microvilli gradually increased until obvious changes became apparent at day 4 [2, 9]. However, little is known regarding the exact details of this critical event in human embryogenesis, and both the precise timing of compaction and the underlying mechanisms controlling the process have yet to be clarified [2].
Time-lapse cinematography (TLC) techniques, originally developed by the authors based on a study by Payne [10], have enabled us to precisely observe the morphology of human embryonic development in vitro. TLC provides high-resolution, continuous imaging, in which the various components of the cell can be distinguished and monitored during the recording period. Thus far, we have used this technique to study the fertilization process and embryonic development up to hatching [11–13].
Here, we used TLC to analyze the initiation of compaction in human embryos in vitro. We observed several novel phenomena during the initiation of compaction that were closely related to the formation of multinucleated blastomeres (MNBs).
Materials and methods
TLC was conducted as described previously [11, 12]. Briefly, we used an inverted microscope (IX-71; Olympus, Tokyo, Japan) with Nomarski differential interference contrast (DIC) optics (Olympus) and a micromanipulator (Narishige, Japan) covered with a handcrafted chamber made of acrylic resin. An air heater was placed in the corner of the chamber to maintain the optimal temperature. Our system also contained a small acrylic chamber surrounded by a small water bath on the stage of the microscope. A glass-bottom dish with a microdrop of culture medium (5 μL) was placed in the center of the small chamber. Humidified CO2 gas was infused into the chamber through the water bath, and the volume of flowing CO2 and temperature were adjusted to the optimal values (temperature, 37.0 ± 0.2 °C; pH, 7.37 ± 0.05) within the microdrop covered with mineral oil (Sage, Pasadena, CA). The inverted microscope was equipped with a charge-coupled device (CCD) digital camera (Roper Scientific Photometrics, Tucson, AZ), which was connected to a computer, and images were displayed by using MetaMorph software (Universal Imaging Co, Downingtown, PA). In total, 2,000 to 8,000 digital images of each cultured embryo were acquired over a period of 5 days, with an exposure time of 1/20 s. (Fig. 1).
One hundred and nineteen embryos were donated by couples with no further need for embryo transfer, and these were used in this study after obtaining informed consent. The donated embryos had been cryopreserved at an early stage (pronuclear stage to 4-cell stage) via the slow-cooling method (Air water Inc., Japan) or ultra-rapid vitrification (Kitazato Co., Japan). Cleavage stage embryos were graded by Veeck’s criteria [14] and blastocyst stage embryo were graded as per Gardner’s grading system [15]. After thawing, the embryos were cultured for 24 to 48 h, and embryo quality was assessed via the modified Veeck’s criteria. Blastocyst stage embryos that were evaluated as good quality (i.e., quality 3BB or greater according to the Gardner grading system) were used for time-lapse recording. Of the 119 embryos donated, 115 successfully developed to the blastocyst stage, and were included in the study.
Ethical approval
This study was approved by the ethics committee of the Japanese Institution for Standardizing Assisted Reproductive Technology (JISART).
Statistical analysis
Results were analyzed by the Student’s t-test (double-sided). Statistical significance was defined as a P-value less than 0.05.
Results
As expected from previous study [2, 9, 16, 17], TLC analysis of 115 embryos showed that the blastomeres became more flattened, and the intercellular boundaries became obscured during compaction. Blastulation occurred after complete compaction of the embryos (Fig. 2, Supplemental Movie No. 1 (online resource 1)).
Although the initiation of compaction occurred from the 4-cell to the 16-cell stage (Fig. 3), compaction most commonly commenced at the 8-cell stage (26/115 embryos; 22.6 %). Furthermore, 86.1 % (99/115) embryos initiated compaction at the 8-cell stage or later. Of these, 49.5 % (49/99) developed into good quality blastocysts. In contrast, only 13.9 % (16/115) of embryos initiated compaction before the 8-cell stage (Fig. 3), and only 18.8 % (3/16) of these developed into good quality blastocysts (Table 1). Thus, good quality blastocysts were significantly more likely to develop from embryos that initiated compaction at the 8-cell stage or later, compared with embryos that initiated compaction earlier (P = 0.293; Table 1).
Moreover, 93.8 % (15/16) of embryos that initiated compaction before the 8-cell stage showed multinucleation within at least one blastomere (Table 2). In addition, 62.5 % (10/16) of the embryos that exhibited early initiation of compaction showed cytokinetic failure after formation of the cleavage furrow (Table 2, Fig. 4, Supplemental Movie No. 2 (online resource 2)).
Discussion
After several cellular divisions in the initial stages of embryonic development, the intercellular boundaries become obscured in a process called compaction, which maximizes intercellular contact and results in the formation of the morula. The cell-cell adhesion protein E-cadherin is first expressed during compaction, enabling the cells to adhere more tightly [2, 9, 16–18]. The obvious morphological changes are accompanied by functional changes resulting from the shift in the gene transcription profile from the maternal to the zygotic genome. These functional changes lead to the differentiation of the cells into the inner cell mass and trophectoderm, which is essential for blastocyst formation.
Here, by using our TLC technique, we observed a novel phenomenon regarding compaction in human embryonic development. Although the timing of the initiation of compaction ranged from the 4-cell to 16-cell stage in human embryos, compaction was initiated at or just after the 8-cell stage in nearly 90 % of the embryos analyzed. This result indicates that the initiation of compaction is physiologically likely to occur at or after the third mitotic division. In addition, while 49.5 % of the embryos that initiated compaction after the 8-cell stage developed into good quality blastocysts, only 18.8 % of the embryos that compacted earlier became good quality blastocysts. Furthermore, the embryos that underwent early initiation of compaction displayed a high incidence of MNBs (average, 93.8 %), and embryos with at least one MNB did not develop into good quality or hatched blastocysts. These data indicate that the early initiation of compaction is strongly associated with the incidence of MNBs, which in turn is related to polyploidy of the blastomeres. Moreover, 68.8 % of the early-compacting embryos displayed cytokinetic failure after the cytoplasmic furrow had formed, indicating that the embryos with MNBs were generated from a novel mechanism whereby the blastomeres underwent cytokinetic failure with karyokinesis during mitotic division. Therefore, embryos with MNBs appear to have low developmental potential due to the presence of abnormal blastomeres (i.e., aberrant ploidy) [19].
Based on the incidence of MNBs and theoretical considerations, we hypothesize that embryos that initiate compaction at the 4-cell stage have cytokinetic failure with karyokinesis in all four blastomeres, embryos that initiate compaction at the 5-cell stage are derived from one blastomere that cleaved normally and three that underwent cytokinetic failure, embryos that initiate compaction at the 6-cell stage are derived from two blastomeres that cleaved normally and two with cytokinetic failure, and embryos that initiated compaction at the 7-cell stage were derived from three blastomeres that cleaved normally and one with cytokinetic failure. However, as two dimensional TLC is not able to automatically adjust the focus in all blastomeres, we could not evaluate the morphokinesis in all blastomeres in detail in this study.
Of the 16 embryos that showed early compaction, one 6-cell stage and two 7-cell stage embryos developed into good quality embryos. Based on our hypothesis above, this finding suggests that the two blastomeres that cleaved normally in the production of the 6-cell embryo, and the three blastomeres that cleaved normally in the production of the 7-cell embryos developed further into morphologically good quality blastocysts.
In this study, we used TLC to study human embryonic development in vitro in donated early stage embryos that had been frozen then thawed. The clinical backgrounds of the couples who donated embryos for the study were representative of those of couples undergoing assisted reproduction; however, because only embryos that were viable after thawing and remained good quality 24 to 48 h later were included in the study, selection bias cannot be ruled out. In addition, we were not able to determine the real time required for the initiation of compaction from insemination, because the embryos had been frozen. However, our finding that the presence of MNBs is common in embryos that undergo early compaction indicates that the use of such embryos in clinical practice should be carefully considered.
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Acknowledgments
We would like to express our particular thanks to D. Payne and S. Flaherty in Adelaide, Australia, for their invaluable support in the development of a new in vitro culture system for time-lapse cinematography. We also would like to especially thank N. Murakami for image editing. Finally, this work was supported by all the staff in the Reproductive Centre, Mio Fertility Clinic.
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Capsule In the human embryos in vitro, compaction initiated at the third mitotic division or later, and multinucleated blastomeres (MNBs) were associated with cytoplasmic failure accompanied by karyokinesis, particularly when compaction occurred before the 8-cell stage.
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Normal embryonic development from the 4-cell stage to the blastocyst stage. This movie shows an embryo that initiated compaction at the 8-cell stage. Further cleavage of the embryo occurred concurrently with compaction. In the process of compaction, the blastomeres became more flattened, cell-to-cell contact increased, and intercellular boundaries became obscured. Finally, the cells appeared to unify into one cluster, with blastulation occurring after complete compaction of the embryo. This embryo developed into a good quality blastocyst and hatched from the zona pellucida. (MPG 49362 kb)
Multinucleated blastomere formation. This movie shows an embryo that initiated compaction prior to the 8-cell stage and formed a multinucleated blastomere (MNB). The 4-cell stage embryo had a single nucleus in each blastomere; however, roughly 22.5 h later, the nuclear membrane disappeared, and the blastomere subsequently began to cleave, with formation of the cleavage furrow. At 22 h and 58 min, when the cleavage furrow was at its deepest, the embryo did not complete the cleavage and the blastomere returned to its original shape, in which multiple nuclei had appeared. (MOV 14608 kb)
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Iwata, K., Yumoto, K., Sugishima, M. et al. Analysis of compaction initiation in human embryos by using time-lapse cinematography. J Assist Reprod Genet 31, 421–426 (2014). https://doi.org/10.1007/s10815-014-0195-2
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DOI: https://doi.org/10.1007/s10815-014-0195-2