Development of single mouse blastomeres enlarged to zygote size in conditions of nucleo-cytoplasmic synchrony

Lab partners: oocytes, embryos and company. A personal view on aspects of oocyte maturation and the development of monozygotic twins

The present review addresses the oocyte and the preimplantation embryo, and is intended to highlight the underlying principle of the "nature versus/and nurture" question. Given the diversity in mammalian oocyte maturation, this review will not be comprehensive but instead will focus on the porcine oocyte. Historically, oogenesis was seen as the development of a passive cell nursed and determined by its somatic compartment. Currently, the advanced analysis of the cross-talk between the maternal environment and the oocyte shows a more balanced relationship: Granulosa cells nurse the oocyte, whereas the latter secretes diffusible factors that regulate proliferation and differentiation of the granulosa cells. Signal molecules of the granulosa cells either prevent the precocious initiation of meiotic maturation or enable oocyte maturation following hormonal stimulation. A similar question emerges in research on monozygotic twins or multiples: In Greek and medieval times, twins were not seen as the result of the common course of nature but were classified as faults. This seems still valid today for the rare and until now mainly unknown genesis of facultative monozygotic twins in mammals. Monozygotic twins are unique subjects for studies of the conceptus-maternal dialogue, the intra-pair similarity and dissimilarity, and the elucidation of the interplay between nature and nurture. In the course of in vivo collections of preimplantation sheep embryos and experiments on embryo splitting and other microsurgical interventions we recorded observations on double blastocysts within a single zona pellucida, double inner cell masses in zona-enclosed blastocysts and double germinal discs in elongating embryos. On the basis of these observations we add some pieces to the puzzle of the post-zygotic genesis of monozygotic twins and on maternal influences on the developing conceptus.

Embryo structure reorganisation reduces the probability of apoptosis in preimplantation mouse embryos

Programmed cell death plays a key role in mammalian development because the morphological events of an organism's formation are dependent on apoptosis. In the mouse development, the first apoptotic waves occur physiologically at the blastocyst stage. Cell number and the mean nucleus to cytoplasm (N/C) ratio increase exponentially throughout subsequent embryo cleavages, while cell volume concurrently decreases from the zygote to blastocyst stage. In this study we tested the hypothesis that reorganisation of the embryo structure by manipulating cell number, the N/C ratio and the cell volume of 2-cell embryos may result in the earlier and more frequent occurrence of apoptosis. The results indicate that doubling ('Aggregates' group) or halving ('Embryos 1/2' group) the initial cell number and modifying embryo volume, ploidy ('Embryos 4n' group) and the N/C ratio ('Embryos 2/1' group) reduce the probability of apoptosis in the resulting embryos. There was a higher probability of apoptosis in the inner cell mass of the blastocyst, but apoptotic cells were never observed at the morula stage in any of the experimental groups. Thus, manipulation of cell number, embryo volume, the N/C ratio and ploidy cause subtle changes in the occurrence of apoptosis, although these are mostly dependent on embryo stage and cell lineage (trophectoderm or inner cell mass), which have the greatest effect on the probability of apoptosis.

Influence of embryo transfer on embryo preimplantation development

OBJECTIVE

To investigate the impact of injection speeds of the transferred load on embryo development.

DESIGN

A laboratory model for in vitro simulation of ET was developed to investigate the impact of varying injection speeds of the transferred load on embryo development.

SETTING

Academic research institutes of reproduction biotechnology and private centers of reproductive medicine.

ANIMAL(S)

Mouse hybrid F(1) females (C57bl/10 J × CBA-H; N = 15) aged 2-3 months.

INTERVENTION(S)

In vitro exposure of mouse embryos with either the fast ET (ejection speed, >1 m/s) or slow ET (ejection speed, <0.1 m/s) and consecutive culture for 36 hours.

MAIN OUTCOME MEASURE(S)

Development rate, morphology and apoptotic index of embryos.

RESULT(S)

The development rate was the slowest in embryos exposed to the fast ET. Morphological changes in response to ET were observed only among embryos exposed to the fast ET. The mean apoptotic index was 17.6% in the group exposed to the fast ET, 5.6% in the group exposed to the slow ET, and 2.58% in the control group.

CONCLUSION(S)

A reduction of the ejection speed of the transferred load allows avoidance of a developmental delay and diminishes injury of the embryos. Therefore, it is reasonable to suggest transferring the embryos at the lowest possible ejection speed.

Influence of embryo transfer on blastocyst viability

OBJECTIVE

To investigate the impact of injection speeds of the transferred load on embryo viability.

DESIGN

Laboratory model for in vitro simulation of embryo transfer (ET).

SETTING

Academic research institutes of reproduction biotechnology and private centers of reproductive medicine.

ANIMAL(S)

Mouse hybrid F1 females, C57bl/10J × CBA-H (N = 15), aged 2 to 3 months.

INTERVENTION(S)

In vitro exposure of mouse blastocysts to either fast ET with an ejection speed of the transferred load of >1 m/s or slow ET with an ejection speed of <0.1 m/s.

MAIN OUTCOME MEASURE(S)

Morphologic changes and apoptotic index of blastocysts.

RESULT(S)

Morphologic changes in response to ET were most prevalent in blastocysts exposed to fast ET. The mean apoptotic index was 52% in the group exposed to fast ET, 25% in the group exposed to slow ET, and 12.8% in control group.

CONCLUSION(S)

Fast ejection of the transferred load can trigger both morphologic changes and apoptosis in mouse blastocysts. A reduction of the ejection speed of the transferred load minimizes injury to the embryos. Therefore, embryos should be transferred at the lowest possible speed.

Cloning from stem cells: different lineages, different species, same story

Following nuclear transfer (NT), the most stringent measure of extensive donor cell reprogramming is development into viable offspring. This is referred to as cloning efficiency and quantified as the proportion of cloned embryos transferred into surrogate mothers that survive into adulthood. Cloning efficiency depends on the ability of the enucleated recipient cell to carry out the reprogramming reactions (‘reprogramming ability’) and the ability of the nuclear donor cell to be reprogrammed (‘reprogrammability’). It has been postulated that reprogrammability of the somatic donor cell epigenome is inversely proportional to its differentiation status. In order to test this hypothesis, reprogrammability was compared between undifferentiated stem cells and their differentiated isogenic progeny. In the mouse, cells of divergent differentiation status from the neuronal, haematopoietic and skin epithelial lineage were tested. In cattle and deer, skeletal muscle and antler cells, respectively, were used as donors. No conclusive correlation between differentiation status and cloning efficiency was found, indicating that somatic donor cell type may not be the limiting factor for cloning success. This may reflect technical limitations of the NT-induced reprogramming assay. Alternatively, differentiation status and reprogrammability may be unrelated, making all cells equally difficult to reprogramme once they have left the ground state of pluripotency.

Developmental potential of isolated blastomeres from early mouse embryos in the presence and absence of LIF and GM-CSF

PURPOSE

The aim of this study was to investigate the developmental potential of isolated blastomeres in the presence and absence of leukemia inhibitory factor (LIF) and granulocyte-macrophage colony stimulating factor (GM-CSF).

METHODS

The blastomeres of two (1/2) and eight cells (1/8) embryos were isolated and cultured in T6 medium in the presence and absence of LIF (1,000 IU/ml) and or GM-CSF (2 ng/ml) up to 120 h. The diameter and cell number of blastocysts were measured.

RESULTS

The developmental rates of 1/2 isolated blastomeres developed to blastocysts stages in the presence and absence of LIF and GM-CSF were 45.80, 35.10 and 48.66, 41.66, respectively. The diameter of blastocysts was higher in GM-CSF group and total cell number of blastocyst in both treated groups was higher than control (P < 0.05). No 1/8 blastomeres developed to morula and blastocyst stages.

CONCLUSIONS

LIF and GM-CSF could improve the development of 1/2 isolated blastomeres.

Donor cell differentiation, reprogramming, and cloning efficiency: elusive or illusive correlation?

Compared to other assisted reproductive technologies, mammalian nuclear transfer (NT) cloning is inefficient in generating viable offspring. It has been postulated that nuclear reprogramming and cloning efficiency can be increased by choosing less differentiated cell types as nuclear donors. This hypothesis is mainly supported by comparative mouse cloning experiments using early blastomeres, embryonic stem (ES) cells, and terminally differentiated somatic donor cells. We have re-evaluated these comparisons, taking into account different NT procedures, the use of donor cells from different genetic backgrounds, sex, cell cycle stages, and the lack of robust statistical significance when post-blastocyst development is compared. We argue that while the reprogrammability of early blastomeres appears to be much higher than that of somatic cells, it has so far not been conclusively determined whether differentiation status affects cloning efficiency within somatic donor cell lineages.

Cloning cattle: the methods in the madness

Somatic cell nuclear transfer (SCNT) is much more widely and efficiently practiced in cattle than in any other species, making this arguably the most important mammal cloned to date. While the initial objective behind cattle cloning was commercially driven--in particular to multiply genetically superior animals with desired phenotypic traits and to produce genetically modified animals-researchers have now started to use bovine SCNT as a tool to address diverse questions in developmental and cell biology. In this paper, we review current cattle cloning methodologies and their potential technical or biological pitfalls at any step of the procedure. In doing so, we focus on one methodological parameter, namely donor cell selection. We emphasize the impact of epigenetic and genetic differences between embryonic, germ, and somatic donor cell types on cloning efficiency. Lastly, we discuss adult phenotypes and fitness of cloned cattle and their offspring and illustrate some of the more imminent commercial cattle cloning applications.

Aggregating embryonic but not somatic nuclear transfer embryos increases cloning efficiency in cattle

Our objectives were to compare the cellular and molecular effects of aggregating bovine embryonic vs. somatic cell nuclear transfer (ECNT vs. SCNT) embryos and to determine whether aggregation can improve cattle cloning efficiency. We reconstructed cloned embryos from: 1) morula-derived blastomeres, 2) six adult male ear skin fibroblast lines, 3) one fetal female lung fibroblast line (BFF), and 4) two transgenic clonal strains derived from BFF. Embryos were cultured either singularly (1X) or as aggregates of three (3X). In vitro-fertilized (IVF) 1X and 3X embryos served as controls. After aggregation, the in vitro development of ECNT but not that of SCNT or IVF embryos was strongly compromised. The inner cell mass (ICM), total cell (TC) numbers, and ICM:TC ratios significantly increased for all the aggregates. The relative concentration of the key embryonic transcript POU5F1 (or OCT4) did not correlate with these increases, remaining unchanged in the ECNT and IVF aggregates and decreasing significantly in the SCNT aggregates. Overall, the IVF and 3X ECNT but not the 1X ECNT embryos had significantly higher relative POU5F1 levels than the SCNT embryos. High POU5F1 levels correlated with high in vivo survival, while no such correlation was noted for the ICM:TC ratios. Development to weaning was more than doubled in the ECNT aggregates (10/51 or 20% vs. 7/85 or 8% for 3X vs. 1X, respectively; P < 0.05). In contrast, the SCNT and IVF controls showed no improvement in survival. These data reveal striking biological differences between embryonic and somatic clones in response to aggregation.