Post-implantation development and cytogenetic analysis of diandric heterozygous diploid mouse embryos

Diandric heterozygous diploid mouse embryos were produced by standard micromanipulatory techniques using eggs from female mice with a normal chromosome constitution and fertilised by homozygous Rb(1.3)1Bnr males containing a pair of large metacentric marker chromosomes in their karyotype. The constructed diandric eggs were transferred to the oviducts of pseudopregnant recipients and subsequently autopsied midday on the eighth day of gestation. From a total of 85 eggs transferred to females that subsequently became pregnant, 30 implanted. Eighteen implantation sites were found to contain resorptions, and 12 egg cylinder stage embryos were recovered. These were cytogenetically examined. In two cases, no mitoses were observed, and in a third embryo of normal size, only a single paternally-derived marker chromosome was present in its mitoses, indicating that this embryo had a normal chromosome constitution. This presumably resulted from a technical error during the micromanipulatory procedure. The remaining nine morphologically small but normal embryos were diploid, and each had two paternally-derived marker chromosomes, thus establishing their ploidy and confirming their diandric origin. G-banding analysis revealed that all of these embryos had an XY sex chromosome constitution. Since the expected XX:XY:YY ratio of 1:2:1 was not observed, it is clear that the XX class embryos were lost at some stage during the pre- or early post-implantation period, though whether they are represented by the resorption sites is not yet established. The YY class would not be expected to be recovered in any case, as these embryos are believed to be lost during early cleavage. The cytogenetic findings reported here are therefore similar to the results of the chromosomal analyses of the human complete hydatidiform moles of dispermic origin, all of which apparently have an XY karyotype. It is unclear why, both in the human and in the mouse, the XX diandric heterozygous diploid group should develop poorly compared to similar embryos with an XY karyotype.     

The sex-chromosome constitution and early postimplantation development of diandric triploid mouse embryos

Diandric triploid mouse embryos were produced by standard micromanipulatory techniques, using eggs isolated from female mice with a normal chromosome constitution that had been mated to homozygous Rb(1.3)1Bnr males (which carry a large metacentric "marker" chromosome, viz., a Robertsonian translocation involving chromosomes 1 and 3). The tripronucleate embryos were transferred to the oviducts of pseudopregnant mice, which were subsequently autopsied at about midday on the 10th day of gestation. Although a relatively small number of the isolated conceptuses consisted of morphologically abnormal egg-cylinder-like structures or empty gestational sacs, most were at clearly distinguishable embryonic stages, from the primitive streak stage to embryos with about 20 pairs of somites present. These embryos all appeared to be morphologically normal but were substantially smaller than normal (diploid) fertilized embryos analyzed at similar stages of development. A total of 63 diandric triploid conceptuses were recovered and analyzed cytogenetically. They were G-banded to determine their sex-chromosome constitution and confirm their diandric triploid status. No obvious difference was observed in the developmental potential of the 58,XXX class of diandric triploids, compared to that of the 58,XXY class. The ratio of 58,XXX to 58,XXY embryos was close to the expected ratio of 1:2, assuming that unfertilized eggs have an equal chance of becoming fertilized by an X- or a Y-bearing spermatozoon and that the additional (i.e., "donor") male pronucleus also has an equal chance of having either an X or a Y sex chromosome present. However, the development of the 58,XYY class appeared to be restricted, even at the stage of gestation analyzed, in that no embryos with this genetic constitution were observed that had progressed beyond the early somite stage. The present findings are discussed in relation to the cytogenetic findings in human triploid conceptuses, the majority of which are spontaneously aborted during the first half of pregnancy. In man, the 69,XYY class (equivalent to the 58,XYY class in our study) is only rarely encountered, and it has been assumed that these triploid embryos are probably lost at a very early stage of gestation.     

The differential staining pattern of the X chromosome in the embryonic and extraembryonic tissues of postimplantation homozygous tetraploid mouse embryos.

(C57BL x CBA)F1 hybrid female mice were mated with hemizygous Rb(X.2)2Ad males to distinguish the paternal X chromosome. Homozygous tetraploids were produced by blastomere fusion at the 2-cell stage, and 161 of these were transferred to recipients and analysed on the 10th day of gestation. 59 implants contained resorptions and 76 contained either an embryo and/or extraembryonic membranes. 38 (20, XXXX and 18, XXYY) were analysed to investigate their X-inactivation pattern. Embryonic and yolk sac endodermally- and mesodermally-derived samples were analysed by G-banding and by Kanda analysis. In the XX and XY controls, the predicted pattern of X-inactivation was observed, though 12.2% of metaphases in the XX series displayed no X-inactivation. In the XY series the Y chromosome was seen in a high proportion of metaphases. In the XXXX tetraploids, 8 cell lineages were recognized with regard to their X-inactivation pattern, though most belonged to the following 3 categories: (XmXm)XpXp, Xm(XmXp)Xp and XmXm(XpXp). The other categories were only rarely encountered. In the embryonic and mesodermally-derived tissue the ratio of these groups was close to 1:2:1, whereas in the endodermally-derived tissue it was 1:4.11:4.88, due to preferential paternal X-inactivation. A significant but small proportion of all 3 tissues analysed displayed no evidence of X-inactivation. Indirect evidence suggests that this represents a genuine group because of the high efficiency of the Kanda staining. The presence of the Xm(XmXp)Xp category is consistent with the expectation that X-inactivation occurs randomly in 2 of the 4 X chromosomes present. The presence of small numbers of preparations with no evidence of X-inactivation and other unexpected categories suggests that these are probably selected against during development.     

Development of in vivo derived diploid and tetraploid pig embryos in a modified medium NCSU 37

The aim of this study was to assess development of diploid and tetraploid in vivo derived pig embryos cultured in a modified medium NCSU 37 in an atmosphere with reduced concentration of oxygen. The tetraploid embryos were produced by electrofusion of two-cell embryos that had been cultured in vitro from the one-cell stage before fusion (cultured two-cell embryos) or by fusion of freshly recovered two-cell embryos. Development to blastocyst stage of tetraploid embryos, generated from the cultured two-cell embryos was significantly inferior to the development of control one-cell embryos (29.1 +/- 9.7% versus 66.8 +/- 9.7%; P < 0.05). However, development of tetraploid embryos produced from the freshly recovered two-cell embryos and control two-cell embryos was very similar (89.9 +/- 6.1% versus 81.3 +/- 3.4%). Detection of chromosomes 1 and 10 by in situ hybridization showed that more than 85% of the cultured control embryos were diploid while 15% of the embryos were mosaic. Among the fused embryos 50% were tetraploid, 29% mosaic and 21% diploid. These data indicate that the modified medium NCSU 37 provides optimum environment for pre-implantation development of pig diploid and tetraploid embryos.     

Production of bovine tetrapolid embryos by electrofusion and their developmental capability in vitro

Optimal conditions of electrofusion for blastomeres of two-cell bovine embryos to produce tetraploid embryos were investigated. The high fusion rate (73–95%), viability, and develop mental capacity were obtained under a field strength of 1.0 kV/cm with direct current pulses of 10 or 25 μsec duration applied twice. Cytological study showed that 78.6% (11/14 embryos) of embryos exposed to electrofusion had tetraploid chromosome sets and the others were diploid or hexaploid. The tetraploid embryos had the capability to develop up to morulae stage in vitro.     

Effect of exogenous hormones on the ovulation of primary and secondary oocytes in LT/Sv strain mice

LT/Sv strain mice ovulate both primary and secondary oocytes. These are fertilizable and give rise to digynic triploid and normal diploid conceptuses, respectively. A previous study [Kaufman and Speirs, 1987] had indicated that just over 20% of embryos recovered on the 10th day of gestation from spontaneously ovulating females had a triploid chromosome constitution. This value was considerably lower than might have been expected by extrapolation from earlier studies in which LT/Sv mice had been given exogenous gonadotrophins. In the present study, therefore, cytogenetic analysis of fertilized eggs was performed at the first cleavage mitosis in (1) spontaneously ovulating females mated to F1 hybrid males, and (2) superovulated females mated to similar males. Additional females from group (1) were autopsied on the 10th day of gestation, and the ploidy of embryos isolated at this stage of gestation was determined. Exposure to exogenous gonadotrophins significantly increased the proportion of eggs that were ovulated as primary oocytes (34.4%), compared to the situation observed following spontaneous ovulation (24.4%). All the triploids encountered in both series were of the digynic type and characteristically (for LT/Sv mice) had an oocyte-derived set with 40 chromosomes present, and a sperm-derived set containing 20 chromosomes. Similar numbers of eggs were recovered from spontaneously ovulating females on the 1st and 10th days of gestation, and the incidence of triploidy observed on the 10th day was 22.1%. The influence of exogenous hormones in increasing the “spontaneous” level of triploidy in LT/Sv and in other strains of mice is briefly reviewed.     

Effect of donor cell cycle stage on chromatin and spindle morphology in nuclear transplant rabbit embryos.

We investigated the influence of the cell cycle stage of the nuclear donor on prematurely condensed chromatin (PCC) and spindle morphology and on chromosome constitution in rabbit nuclear transplant embryos. The configuration of PCC following nuclear transplantation with G1, early S, and late S phase donor nuclei (G1, early S, and late S transplants, respectively) was characterized in whole mounts and chromosome spreads. In addition, the influence of the donor cell cycle stage on chromosome constitution in cleavage stage-manipulated embryos was determined. Within 2 h after fusion of the donor blastomere, the recipient oocyte cytoplasm was able to induce formation de novo of a metaphase plate associated with a spindle in G1, early S, and late S transplants. Metaphase chromosomes and spindle were intact in most cases of PCC in G1 transplants. However, these structures displayed minor abnormalities in early S transplants and gross abnormalities in late S transplants, such as incomplete or absent spindle formation and incomplete chromatin condensation. Normal chromosomes were present in G1 and early S transplants, whereas chromosome abnormalities were detected in late S transplants. The results indicate that morphology of prematurely condensed G1 and early S chromatin has a minor influence on chromosome constitution of manipulated embryos. That of late S chromatin, however, affects chromosome constitution in embryos and may account for reduced development of nuclear transplant embryos when late S phase donor nuclei are used.     

Cytogenetic study of silver-staining NOR in 8-cell-stage mouse blastomeres fused to 1-cell-stage embryos

Isolated blastomeres from 8- to 16-cell-stage embryos were fused by standard micromanipulatory means with either unfertilized eggs or fertilized or haploid parthenogenetically activated pronuclear-stage embryos. The hybrid eggs/embryos were incubated overnight in the presence of Colcemid until they had entered the first cleavage division. Air-dried chromosome preparations were then stained with silver nitrate in order to detect active nucleolar organizing regions (NOR). While control unfertilized eggs and 1-cell-stage fertilized and parthenogenetically activated embryos showed no evidence of silver-staining NOR-positive regions, the metaphase plates from 8- to 16-cell embryos showed characteristic NOR-positive regions, while their interphase nuclei also showed a characteristic reticular staining appearance. When hybrids between blastomere nuclei and unfertilized eggs were examined, none of the blastomere nuclei entered mitosis. However, when hybrids between blastomere nuclei and fertilized embryos were examined, in two thirds of the embryos, a single blastomere-derived diploid metaphase plate was present in association with two pronuclear-derived haploid metaphase plates. In most instances, the blastomere-derived chromosomes did not display silver-nitrate-staining NOR. Similar findings were observed when the blastomere-derived chromosomes in hybrids between blastomere nuclei and haploid parthenogenetic embryos were analysed. In the majority of cases, when blastomere nuclei remained in interphase, the characteristic silver-nitrate-staining fine reticular material either was not seen, or the nuclear contents were dispersed into clumps of chromatin-like material. Occasionally, the diploid chromosomes in the hybrids displayed morphological abnormalities. Our findings suggest that the cytoplasm of activated (but not nonactivated) 1-cell embryos is capable of influencing the nucleolar activity of the introduced 8- to 16-cell nuclei, effectively erasing from their chromosomes the memory of at least three previous rounds of rRNA synthesis.     

Postimplantation development of tetraploid mouse embryos produced by electrofusion

Despite the fact that a variety of experimental techniques have been devised over the years to induce tetraploid mammalian embryonic development, success rates to date have been limited. Apart from the early study by Snow, who obtained development to term of a limited number of cytochalasin B-induced tetraploid mouse embryos, no other researchers have achieved development of tetraploid embryos beyond the early postimplantation period. We now report advanced postimplantation development of tetraploid mouse embryos following electrofusion of blastomeres at the 2-cell stage, and subsequent transfer of these 1-cell 'fused' embryos to appropriate recipients. Cytogenetic analysis of the extraembryonic membranes of all of the postimplantation embryos encountered in the present study has provided an unequivocal means of confirming their tetraploid chromosome constitution. A preliminary morphological and histological analysis of the tetraploid embryos obtained by this technique has revealed that characteristic craniofacial abnormalities particularly involving the forebrain and eyes were consistently observed, and these features were often associated with abnormalities of the vertebral axis and heart. The most advanced viable embryo in this series was recovered on the 15th day of gestation, and its morphological features suggest that it was developmentally equivalent to a normal embryo of about 13.5-14 days p.c.     

Identical triplets and twins developed from isolated blastomeres of 8- and 16-cell mouse embryos supported with tetraploid blastomeres

We studied the developmental potential of single blastomeres from early cleavage mouse embryos. Eight- and sixteen-cell diploid mouse embryos were disaggregated and single blastomeres from eight-cell embryos or pairs of sister blastomeres from sixteen-cell embryos were aggregated with 4, 5 or 6 tetraploid blastomeres from 4-cell embryos. Each diploid donor embryo gave eight sister aggregates, which later were manipulated together as one group (set). The aggregates were cultured in vitro until the blastocyst stage, when they were transferred (in sets) to the oviducts of pseudopregnant recipients. Eighteen live foetuses or pups were obtained from the transfer (11.0% of transferred blastocysts) and out of those, eleven developed into fertile adults (one triplet, one pair of twins and four singletons). In all surviving adults, pups and living foetuses, only diploid cells were detected in their organs and tissues as shown by analysis of coat pigmentation and distribution of glucose phosphate isomerase isoforms. In order to explain the observed high rate of mortality of transferred blastocysts, in an accompanying experiment, the diploid and tetraploid blastomeres were labelled with different fluorochromes and then aggregated. These experiments showed the diploid cells to be present not only in the inner cell mass (ICM) but also in the trophectoderm. The low number of diploid cells and the predominance of tetraploid cells in the ICM of chimaeric blastocysts might have been responsible for high postimplantation mortality of our experimental embryos.     

Production of identical mouse twins and a triplet with predicted gender

The aim of this study was to develop a method to generate identical twins and triplets with predicted gender. As a first step toward that aim, single blastomeres obtained from EGFP expressing eight-cell stage embryos and either diploid or tetraploid host embryos were used to compose chimera. We could follow the fate of EGFP expressing diploid blastomere derived cells in 3.5- and 4.5-day-old chimera embryos in vitro. We found that the diploid blastomere-derived cells had significantly higher chance to contribute to the inner cell mass if tetraploid host embryos were applied. After that, we developed a quick and reliable multiplex PCR strategy for sex diagnosis from single blastomeres by simultaneous amplification of the homologous ZFX and ZFY genes. By composed chimeras using single blastomeres, derived from sexed eight-cell stage embryos and a tetraploid host embryo, we could get preplanned sex newborns, wholly derived from these blastomeres. Among these mice, identical twins and a triplet were identified by microsatellite analysis. Unlike clones produced by nuclear transfer, these mice are identical at both the nuclear as well as mitochondrial DNA level. Therefore, the tetraploid embryo complementation method to produce monozygotic twins and triplets could be a valuable tool both in biomedical and agricultural applications.     

Altered apoptosis/autophagy and epigenetic modifications cause the impaired postimplantation octaploid embryonic development in mice

Polyploids are pervasive in plants and have large impacts on crop breeding, but natural polyploids are rare in animals. Mouse diploid embryos can be induced to become tetraploid by blastomere fusion at the 2-cell stage and tetraploid embryos can develop to the blastocyst stage in vitro. However, there is little information regarding mouse octaploid embryonic development and precise mechanisms contributing to octaploid embryonic developmental limitations are unknown. To investigate the genetic and epigenetic mechanisms underlying octaploid embryonic development, we generated mouse octaploid embryos and evaluated the in vitro/in vivo developmental potential. Here we show that octaploid embryos can develop to the blastocyst stage in vitro, but all fetus impaired immediately after implantation. Our results indicate that cell lineage specification of octaploid embryo was disorganized. Furthermore, these octaploid embryos showed increased apoptosis as well as alterations in epigenetic modifications when compared with diploid embryos. Thus, our cumulative data provide cues for why mouse octaploid embryonic development is limited and its failed postimplantation development.     

Cleavage rates of diploid and tetraploid mouse embryos during the preimplantation period

Despite the fact that spontaneous tetraploidy is a rare phenomenon in mice, such embryos may be produced experimentally by a variety of means, though only a very limited degree of postimplantation development has been achieved. Despite this apparent limitation, much data on the rate of development of preimplantation tetraploid embryos has been published. However, the findings from these studies has often been conflicting. In the light of the recent successful achievement of advanced postimplantation tetraploid development in our laboratory, we decided it was an opportune time to re-evaluate the preimplantation development of these embryos in as near to optimal conditions as we could achieve. Three groups were studied, namely 1) control (diploid) embryos developing in vivo, 2) control (diploid) embryos that had been isolated at the 2-cell stage, briefly retained in culture, then transferred to the oviducts of pseudopregnant recipients, and 3) tetraploid embryos produced by electrofusion of blastomeres at the 2-cell stage, then transferred to the oviducts of pseudopregnant recipients. Embryos were isolated from females from each group at specific times after the HCG injection to induce ovulation. The total cell number of each embryo was established and the log mean values were plotted against time. From the gradients of the lines it was possible to establish that there was a significant difference between the cell doubling time of the transferred controls (group 2) compared to the in vivo controls (group 1) with cell doubling times of 15.86 +/- 1.45 h and 10.27 +/- 0.24 h, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Frequency of sex chromosomal mosaicism in bovine embryos and its effects on sexing using a single blastomere by PCR

Assessment of nuclear status is important when a biopsied single blastomere is used for embryo sexing. In this study we investigated the nuclear status of blastomeres derived from 8- to 16-cell stage in vitro fertilised bovine embryos to determine the representativeness of a single blastomere for embryo sexing. In 24 embryos analysed, the agreement in sex determination between a biopsied single blastomere and a matched blastocyst by polymerase chain reaction (PCR) was 83.3%. To clarify the discrepancies, karyotypes of blastomeres in 8- to 16-cell stage bovine embryos were analysed. We applied vinblastine sulfate at various concentrations and for different exposure times for metaphase plate induction in 8- to 16-cell stage bovine embryos. The 1.0 mg/ml vinblastine sulfate treatment for 15 h was selected as the most effective condition for induction of a metaphase plate (> 45%). Among 22 embryos under these conditions, only 8 of 10 that had a normal diploid chromosome complement showed a sex chromosomal composition of XX or XY (36.4%) and 2 diploid embryos showed mosaicism of the opposite sex of XX and XY in blastomeres of the embryo (9.1%). One haploid embryo contained only one X-chromosome (4.5%). Four of another 11 embryos with a mixoploid chromosomal complement contained a haploid blastomere with a wrong sex chromosome (18.2%). In conclusion, assessment of nuclear status of 8- to 16-cell stage bovine embryos revealed that morphologically normal embryos had a considerable proportion of mixoploid blastomeres and sex chromosomal mosaicism; these could be the cause of discrepancies in the sex between biopsied single blastomeres and matched blastocysts by PCR.     

Meiotic maternal chromosomes introduced to the late mouse zygote are recruited to later embryonic divisions

The aim of this study was to investigate the fate of an additional female genome introduced to a dividing zygote. Maternal chromatin in the form of karyoplasts containing a metaphase II spindle were fused to zygotes blocked in anaphase or telophase of the first cleavage. Permanent preparations made 20-40 min after fusion at anaphase revealed that the donor maternal chromosomes had entered anaphase or telophase in 16 out of 18 cases. A further two groups of embryos that were fused at either anaphase or anaphase/telophase were cultured to the first division. Division occurred 50 min after fusion in both groups of embryos (86 and 85.1%, respectively), of which most divided to two cells (80 and 71.6% of total) and the remainder divided to three cells. About two thirds of two-cell embryos contained an extra nucleus in one blastomere. Nuclei containing donor maternal chromosomes reached a similar size to recipient nuclei in 68% of embryos derived from anaphase-blocked zygotes, in contrast to 31.1% of embryos derived from anaphase/telophase-blocked embryos. Replication of DNA in donor nuclei closely followed the timing and intensity of that in control embryos. When fixed 24 hr after fusion, one third of embryos were still at the two-cell stage, with one or both blastomeres showing a single metaphase plate of the second cleavage. In the remaining embryos, three or four cells were present, some containing two nuclei. Blastocysts developed in 50% of fused embryos and three young were born after transfer of cleaving hybrid embryos to recipients. Chromosome preparations from bone marrow of the young contained 3-4 tetraploid metaphase plates per several hundred plates counted compared with none in control embryos. In conclusion, additional maternal chromosomes can be introduced at the late-dividing zygote and join the embryonic cell cycles during subsequent divisions. This method may provide a useful approach for studying changes specific to the maternal genome during early cell cycles of the mammalian embryo.     

Parental origin of the two additional haploid sets of chromosomes in an embryo with tetraploidy

We report on the molecular investigations performed on an embryo with tetraploidy, karyotype 92,XXXY. The embryo was spontaneously aborted after eight weeks of gestation. Molecular analyses were performed in order to determine the parental origin and mode of formation of the two additional haploid sets of chromosomes. Microsatellite markers mapping to pericentromeric chromosome regions were used. Our results show a maternal origin of one additional set of chromosomes most likely due to the incorporation of the polar body of meiosis I and a paternal origin of the second additional set of chromosomes most likely due to dispermy. The karyotype 92,XXXY is rather unusual, indeed the vast majority of cases with tetraploidy have the karyotypes 92,XXXX or 92,XXYY. To the best of our knowledge this is the first case with 92,XXXY for which molecular investigations have been performed.     

Effect of Initiation Time of Hydrostatic Pressure Shock on Chromosome Set Doubling of Tetraploidization in Turbot <Emphasis Type="Italic">Scophthalmus maximus</Emphasis>

The objective of the study was to clarify the effects of initiation time on chromosome set doubling induced by hydrostatic pressure shock through nuclear phase fluorescent microscopy in turbot Scophthalmus maximus. The ratio of developmentally delayed embryo and chromosome counting was used to assess induction efficiency. For the embryos subjected to a pressure of 67.5 MPa for 6 min at prometaphase (A group), chromosomes recovered to the pre-treatment condition after 11-min recovering. The first nuclear division and cytokinesis proceeded normally. During the second cell cycle, chromosomes did not enter into metaphase after prometaphase, but spread around for about 13 min, then assembled together and formed a large nucleus without anaphase separation; the second nuclear division and cytokinesis was inhibited. The ratio of developmentally delayed embryo showed that the second mitosis of 78% A group embryo was inhibited. The result of chromosome counting showed that the tetraploidization rate of A group was 72%. For the embryos subjected to a pressure of 67.5 MPa for 6 min at anaphase (B group), chromosomes recovered to the pre-treatment condition after about 31-min recovering. Afterwards, one telophase nucleus formed without anaphase separation; the first nuclear division was inhibited. The time of the first cleavage furrow occurrence of B group embryos delayed 27 min compared with that of A group embryos. With the first cytokinesis proceeding normally, 81.3% B group embryos were at two-cell stage around the middle of the second cell cycle after treatment. Those embryos were one of the two blastomeres containing DNA and the other without DNA. The first nuclear division of those embryos was inhibited. During the third cell cycle after treatment, 65.2% of those abovementioned embryos were at four-cell stage, cytokinesis occurred in both blastomeres, and nuclear division only occurred in the blastomere containing DNA. Of those abovementioned embryos, 14.0% were at three-cell stage and cytokinesis only occurred in the blastomere containing DNA. The result of chromosome counting showed that the tetraploidization rate of B group was only 7%. To summarize what had been mentioned above, mechanisms on chromosome set doubling of tetraploid induction would be different with different initiation time of hydrostatic pressure treatment. Chromosome set doubling was mainly due to inhibition of the second mitosis when hydrostatic pressure treatment was performed at prometaphase. Otherwise, chromosome set doubling was mainly due to inhibition of the first nuclear division when hydrostatic pressure treatment was performed at anaphase. Induction efficiency of tetraploidization resulted from inhibition of the second cleavage was higher than which resulted from inhibition of the first nuclear division. This study was the first to reveal biological mechanisms on the two viewpoints of chromosome set doubling through effect of initiation time of hydrostatic pressure treatment on chromosome set doubling in tetraploid induction.     

Ploidy of bovine nuclear transfer blastocysts reconstructed using in vitro produced blastomere donors

The higher rate of embryonic loss in nuclear transfer compared to in vitro produced embryos may be due to chromosome abnormalities that occur during preimplantation in vitro development. Because little is known about ploidy errors in nuclear transfer embryos, this was examined using embryos reconstructed from in vitro produced embryo donors. In vitro matured oocytes were enucleated and then activated using calcium ionophore A23187 followed by 6-dimethylaminopurine (6-DMAP). Subsequently, embryos were reconstructed using blastomeres from day 4-5 in vitro produced donors. The embryos were cultured until day 7 at which time blastocyst nuclei were extracted and chromosome abnormalities were evaluated by fluorescent in situ hybridization using two probes that bind to the subcentromeric regions on chromosomes 6 and 7. In 16 nuclear transfer blastocysts generated from 5 donor embryos, 53.8 +/- 20.2 (mean % +/- SD) nuclei/embryo were examined. Of these 16, 7 embryos (43.8%) were potentially abnormal because in these, 1.1%, 1.4%, 5.3%, 7.5%, 26.3%, 30.4%, and 66.2% % of the nuclei had a chromosome composition deviating from the diploid condition, indicating a wide degree of variation between embryos. These errors comprised mainly triploid (8.2 +/- 10.3 [0-26.3]: % +/- SD [range]) and tetraploid (10.6 +/- 19.9 [0-54.9]) nuclei with other ploidy combinations accounting for only 0.9 +/- 2.1 [0-2.1]% of deviant nuclei. The proportion of completely normal nuclear transfer embryos was no less than those produced by in vitro fertilization but the distribution of chromosome abnormalities was different (p = 0.0002). In conclusion, nuclear transfer embryos reconstructed using blastomere cells can produce over 50% blastocysts with a diploid chromosome complement. However, the contribution of chromosome abnormalities to embryonic loss in the remaining embryos deserves further investigation.     

The pattern of X-chromosome inactivation in the embryonic and extra-embryonic tissues of post-implantation digynic triploid LT/Sv strain mouse embryos

Spontaneously cycling LT/Sv strain female mice were mated to hemizygous Rb(X.2)2Ad males in order to facilitate the distinction of the paternal X chromosome, and the pregnant females were autopsied at about midday on the tenth day of gestation. Out of a total of 222 analysable embryos recovered, 165 (74.3%) were diploid and 57 (25.7%) were triploid. Of the triploids, 26 had an XXY and 31 an XXX sex chromosome constitution. Both embryonic and extra-embryonic tissue samples from the triploids were analysed cytogenetically by G-banding and by the Kanda technique to investigate their X-inactivation pattern. The yolk sac samples were separated enzymatically into their endodermally-derived and mesodermally-derived components, and these were similarly analysed, as were similar samples from a selection of control XmXp diploid embryos. In the case of the XmXmY digynic triploid embryos, a single darkly-staining Xm chromosome was observed in 485 (82.9%) out of 585, 304 (73.3%) out of 415, and 165 (44.7%) out of 369 metaphases from the embryonic, yolk sac mesodermally-derived and yolk sac endodermally-derived tissues, respectively. The absence of a darkly staining X-chromosome in the other metaphase spreads could either indicate that both X-chromosomes present were active, or that the Kanda technique had failed to differentially stain the inactive X-chromosome(s) present. In the case of the XmXmXp digynic triploid embryos, virtually all of the tissues analysed comprised two distinct cell lineages, namely those with two darkly-staining X-chromosomes, and those with a single darkly staining X-chromosome.(ABSTRACT TRUNCATED AT 250 WORDS)     

Use of fluorescence in situ hybridization for gross mapping of transgenes and screening for homozygous plants in transgenic barley ( Hordeum vulgare L.)

Introduced transgenes, uidA, sgfp (S65T) and/or bar, were localized using fluorescence in situ hybridization (FISH) on metaphase chromosomes of transgenic barley produced by microparticle bombardment of immature embryos. Of the 19 independent transgenic lines (eight diploid and 11 tetraploid), nine had uidA and ten had s gfp (S65T). All lines tested had three or more copies of the transgenes and 18 out of 19 lines had visibly different integration sites. At a gross level, it appeared that no preferential integration sites of foreign DNA among chromosomes were present in the lines tested; however, a distal preference for transgene integration was observed within the chromosome. In diploid T0 plants that gave a 3:1 segregation ratio of transgene expression in the T1, only single integration sites were detected on one of the homologous chromosomes. Homozygous diploid plants had doublet signals on a pair of homologous chromosomes. All tetraploid T0 plants that gave a 3:1 segregation ratio in the T1 generation had only a single integration site on one of the homologous chromosomes. In contrast, the single tetraploid T0 plant with a 35:1 segregation ratio in the T1 generation had doublet signals on a pair of homologous chromosomes. In the one tetraploid T0 line, which had a homozygote-like segregation ratio (45:0), there were doublet signals at two loci on separate chromosomes. We conclude that the application of FISH for analysis of transgenic plants is useful for the gross localization of transgene(s) and for early screening of homozygous plants.