Assessment of chromosomal integrity using a novel live-cell imaging technique in mouse embryos produced by intracytoplasmic sperm injection.

BACKGROUND: Intracytoplasmic sperm injection (ICSI) is a technique in which sperm are injected directly into unfertilized oocytes, whereby offspring can be obtained even with dysfunctional sperm. Despite its advantages in human and animal reproductive technology, the low rate of resultant live offspring is perturbing. One major cause is thought to be embryonic chromosomal abnormalities. However, there is no direct evidence of how these occur or how they affect pregnancy outcomes. METHODS: Chromosomal dynamics during the first mitotic division of mouse embryos were analyzed using a new live-cell imaging technology. After imaging, the embryos' developmental capacities were determined. RESULTS: When ICSI-generated embryos were monitored for their chromosome integrity, some embryos with apparent normal morphology seen by conventional light microscopy had abnormal chromosome segregation (ACS) at the first mitotic division. Chromosomal fragments were misaligned during the first metaphase and formed micronuclear-like structures at the interphase of the 2-cell stage. Similar ACS was also found in mouse embryos produced by microinjecting round spermatids, with even higher frequency. Giemsa staining and immunostaining revealed that these fragments were derived from double-strand DNA breaks in the paternal genome. About half of the embryos with ACS developed into normal-looking morulae or blastocysts and implanted, but almost all of them aborted spontaneously before embryonic day 7.5. CONCLUSIONS: ACS during first mitosis appears to be a major cause of early pregnancy losses in ICSI-generated mouse embryos. Moreover, this novel imaging technology could be applicable as a method for the assessment of embryo quality.

Long-term, six-dimensional live-cell imaging for the mouse preimplantation embryo that does not affect full-term development.

Mammalian preimplantation embryonic development is achieved by tightly coordinated regulation of a great variety of temporal and spatial changes. Therefore, it would be valuable to analyze these events three-dimensionally and dynamically. We have previously developed a live-cell imaging method based on the expression of fluorescent proteins, using mRNA injection and time-lapse florescence microscopy. However, with conventional fluorescent microscopy, three-dimensional images could not be obtained due to the thickness of the embryos and the optical problem in which ;out-of focus blur' cannot be eliminated. Moreover, as the repeated exposure of intense excitation light to the cell yields phototoxicity, long-term observation was detrimental to embryonic development. Here, we improved our imaging system to enable six-dimensional live-cell imaging of mouse preimplantation embryos (x, y and z axes, time-lapse, multicolor and multisample). Importantly, by improving the imaging devices and optimizing the conditions for imaging, such as intensity of excitation and time intervals for image acquisition, the procedure itself was not detrimental to full-term development, although it is a prolonged imaging process. For example, live pups were obtained from embryos to which two different wavelengths of excitation (488 and 561 nm) were applied at 7.5-min intervals for about 70 h, and 51 images were acquired in the z axis at each time point; thus, a total of 56,814 fluorescent images were taken. All the pups were healthy, reproductively normal and not transgenic. Thus, this live-cell imaging technology is safe for full-term mouse development. This offers a novel approach for developmental and reproductive research in that it enables both retrospective and prospective analyses of development. It might also be applicable to assessment of embryo quality in fields such as human reproductive technology and production animal research.

Further characterization of the PW peptide family that inhibits neuron differentiation in Hydra.

From an evolutionary point of view, Hydra has one of the most primitive nervous systems among metazoans. Two different groups of peptides that affect neuron differentiation were identified in a systematic screening of peptide signaling molecules in Hydra. Within the first group of peptides, a neuropeptide, Hym-355, was previously shown to positively regulate neuron differentiation. The second group of peptides encompasses the PW family of peptides that negatively regulate neuron differentiation. In this study, we identified the gene encoding PW peptide preprohormone. Moreover, we made the antibody that specifically recognizes LPW. In situ hybridization and immunohistochemical analyses showed that the PW peptides and the gene encoding them were expressed in ectodermal epithelial cells throughout the body except for the basal disk. The PW peptides are produced by epithelial cells and are therefore termed "epitheliopeptides." Together with Hym-355, the PW family peptides mediate communication between neurons and epithelial cells and thereby maintain a specific density of neurons in Hydra.

Propagation of senescent mice using nuclear transfer embryonic stem cell lines.

Senescent mice are often infertile, and the cloning success rate decreases with age, making it almost impossible to produce cloned progeny directly from such animals. In this study, we tried to produce offspring from such "unclonable" senescent mice using nuclear transfer techniques. Donor fibroblasts were obtained from the tail tips of mice aged up to 2 years and 9 months. Although most attempts failed to produce cloned mice by direct somatic cell nuclear transfer, we managed to establish nuclear transfer embryonic stem (ntES) cell lines from all aged mice with an establishment rate of 10-25%, irrespective of sex or strain. Finally, cloned mice were obtained from these ntES cells by a second round of nuclear transfer. In addition, healthy offspring was obtained from all aged donors via germline transmission of ntES cells in chimeric mice. This technique is thus applicable to the propagation of a variety of animals, irrespective of age or fertile potential.

Tet-on inducible system combined with in ovo electroporation dissects multiple roles of genes in somitogenesis of chicken embryos.

The in ovo electroporation technique in chicken embryos has enabled investigators to uncover the functions of numerous developmental genes. In this technique, the ubiquitous promoter, CAGGS (CMV base), has often been used for overexpression experiments. However, if a given gene plays a role in multiple steps of development and if overexpression of this gene causes fatal consequences at the time of electroporation, its roles in later steps of development would be overlooked. Thus, a technique with which expression of an electroporated DNA can be controlled in a stage-specific manner needs to be formulated. Here we show for the first time that the tetracycline-controlled expression method, "tet-on" and "tet-off", works efficiently to regulate gene expression in electroporated chicken embryos. We demonstrate that the onset or termination of expression of an electroporated DNA can be precisely controlled by timing the administration of tetracycline into an egg. Furthermore, with this technique we have revealed previously unknown roles of RhoA, cMeso-1 and Pax2 in early somitogenesis. In particular, cMeso-1 appears to be involved in cell condensation of a newly forming somite by regulating Pax2 and NCAM expression. Thus, the novel molecular technique in chickens proposed in this study provides a useful tool to investigate stage-specific roles of developmental genes.

Successful mouse cloning of an outbred strain by trichostatin A treatment after somatic nuclear transfer.

Although the somatic cloning technique has been used for numerous applications and basic research of reprogramming in various species, extremely low success rates have plagued this technique for a decade. Further in mice, the "clonable" strains have been limited to mainly hybrid F1 strains such as B6D2F1. Recently, we established a new efficient cloning technique using trichostatin A (TSA) which leads to a 2-5 fold increase in success rates for mouse cloning of B6D2F1 cumulus cells. To further test the validity of this TSA cloning technique, we tried to clone the adult ICR mouse, an outbred strain, which has never been directly cloned before. Only when TSA was used did we obtain both male and female cloned mice from cumulus and fibroblast cells of adult ICR mice with 4-5% success rates, which is comparable to 5-7% of B6D2F1. Thus, the TSA treatment is the first cloning technique to allow us to successfully clone outbred mice, demonstrating that this technique not only improves the success rates of cloning from hybrid strains, but also enables mouse cloning from normally "unclonable" strains.

Efficient establishment of mouse embryonic stem cell lines from single blastomeres and polar bodies.

Recently, ES cell lines were established from single blastomeres taken from eight-cell embryos in mice and humans with success rates of 4% and 2%, respectively, which suggests that the method could be used in regenerative medicine to reduce ethical concerns over harm to embryos. However, those studies used other ES cells as supporting cells. Here, we report a simple and highly efficient method of establishing mouse ES cell lines from single blastomeres, in which single blastomeres are simply plated onto a feeder layer of mouse embryonic fibroblasts with modified ES cell medium. A total of 112 ES cell lines were established from two-cell (establishment rate, 50%-69%), early four-cell (28%-40%), late four-cell (22%), and eight-cell (14%-16%) stage embryos. We also successfully established 18 parthenogenetic ES cell lines from first (36%-40%) and second polar bodies (33%), the nuclei of which were reconstructed to embryos by nuclear transfer. Most cell lines examined maintained normal karyotypes and expressed markers of pluripotency, including germline transmission in chimeric mice. Our results suggest that the single cells of all early-stage embryos or polar bodies have the potential to be converted into ES cells without any special treatment.

Mesenchymal-to-epithelial transition during somitic segmentation: a novel approach to studying the roles of Rho family GTPases in morphogenesis.

During early development in vertebrates, cells change their shapes dramatically both from epithelial to mesenchymal and also from mesenchymal to epithelial, enabling the body to form complex tissues and organs. Using somitogenesis as a novel model, Rho family GTPases have recently been shown to play essential and differential roles in individual cell behaviors in actual developing embryos. Levels of Cdc42 activity provide a binary switch wherein high Cdc42 levels allow the cells to remain mesenchymal, while low Cdc42 levels produce epithelialization. Rac1 activity needs to be precisely controlled for proper epithelialization through the bHLH transcription factor Paraxis. Somitogenesis is expected to serve as an excellent model with which one can understand how the functions of developmental genes are resolved into the morphogenetic behavior of individual cells.

Pax 2 expression in mesodermal segmentation and its relationship with EphA4 and Lunatic-fringe during chicken somitogenesis.

In the Pax gene family, which encodes DNA-binding proteins, Pax 2 has been known to play important roles in the formation of the midbrain/hindbrain boundary, eye, inner ear and kidney in vertebrates (Bioessays 19 (1997) 755). In this article, we report a segmentally regulated pattern of Pax 2 expression during chicken somitogenesis. Pax 2 mRNA is localized in the rostral end of the unsegmented presomitic mesoderm (PSM), abutting anteriorly on a prospective segmentation border. This pattern repeats every segmentation cycle (90 min) observed in ovo and also in the half embryo culture assay in which one half of PSM along the midline is fixed immediately while the other half is cultured for a given period. We also determined the sequence of changes in Pax 2 expression during a segmentation cycle by comparing the pattern of Pax 2 with that of Lunatic-fringe (L-fringe), known to cycle periodically in posterior PSM. A systematic comparison of the expression patterns between Pax 2, L-fringe and EphA4 further highlighted a close relationship between EphA4 and Pax 2 during a segmentation cycle. Lastly, Pax 2 is not segmentally expressed in mouse PSM, suggestive of species (avian)-specific mechanisms underlying somitic segmentation.

Pax 2 expression in mesodermal segmentation and its relationship with EphA4 and Lunatic-fringe during chicken somitogenesis.

In the Pax gene family, which encodes DNA-binding proteins, Pax 2 has been known to play important roles in the formation of the midbrain/hindbrain boundary, eye, inner ear and kidney in vertebrates (Bioessays 19 (1997) 755). In this article, we report a segmentally regulated pattern of Pax 2 expression during chicken somitogenesis. Pax 2 mRNA is localized in the rostral end of the unsegmented presomitic mesoderm (PSM), abutting anteriorly on a prospective segmentation border. This pattern repeats every segmentation cycle (90 min) observed in ovo and also in the half embryo culture assay in which one half of PSM along the midline is fixed immediately while the other half is cultured for a given period. We also determined the sequence of changes in Pax 2 expression during a segmentation cycle by comparing the pattern of Pax 2 with that of Lunatic-fringe (L-fringe), known to cycle periodically in posterior PSM. A systematic comparison of the expression patterns between Pax 2, L-fringe and EphA4 further highlighted a close relationship between EphA4 and Pax 2 during a segmentation cycle. Lastly, Pax 2 is not segmentally expressed in mouse PSM, suggestive of species (avian)-specific mechanisms underlying somitic segmentation.