The pH-sensitive dual-emission fluorophore SNARF-1 coupled with a laser confocal microspectrofluorimeter was used to measure the internal pH (pHi) in different subcellular and subnuclear compartments of early mouse embryos. By this method we analysed the first cell cycle of naturally fertilised embryos in order to detect possible pHi changes correlated to cellular events, particularly the onset of replication or transcription and the first mitosis. Throughout interphase, significant differences of pHi were observed between cytoplasm and pronuclei, and, even more striking, between these compartments and nucleolus precursor bodies, whose pHi was systematically lower. We could detect significant pHi change neither during the replication phase nor at the onset of zygotic transcription, but pHi increased at the end of the one-cell stage in both cytoplasm and chromatin regions, a process that seemed specifically correlated with mitosis.
The second cleavage of the mouse embryo is asynchronous. Some recent investigators have proposed that the sequence of division of blastomeres in two-cell embryos may predict the ultimate location of the descendants of these blastomeres within the blastocyst. To verify this model, we tracked the cells derived from two-cell stage blastomeres using tetramethylrhodamine-conjugated dextran as a lineage tracer. In the first variant of the experiment, we labeled one of two blastomeres in two-cell embryos and subsequently recorded which blastomere cleaved first. In the second variant of the experiment, fluorescent dextran was injected at the three-cell stage into the blastomere that had not yet cleaved. Subsequently, the fate of the progeny of labeled and unlabeled blastomeres was followed up to the blastocyst stage. Our results suggest that allocation of cells into the embryonic and abembryonic parts of the blastocyst is not determined by the order of cleavage of the first two blastomeres.
Spontaneous diploid-triploid chimaeras occur sporadically in various mammalian species including man, but so far have never been produced experimentally. In order to get a deeper insight into the developmental consequences of this anomaly, we have developed two procedures that enabled for the first time to produce routinely diploid-triploid embryos, foetuses, and animals in the mouse. These procedures are: (1) aggregation of cleaving diploid embryos with triploid embryos produced by suppression of the second polar body in zygotes, and (2) fusion of a haploid karyoplast with one blastomere of the two-cell diploid embryos. The first procedure yielded 23 living and 6 dead postimplantation embryos and foetuses (age: 8th-19th day) out of which 22 were chimaeric. In addition, three chimaeric neonates reached adulthood. Two animals were fertile, and one--an overt chimaera--was an infertile male. The rate of postimplantation development of aggregation chimaeras was normal or only slightly retarded, and with one exception the foetuses were morphologically normal. Generally, the highest contribution of the 3n component in extra-embryonic structures was noted in the yolk sac, and usually it was higher than its contribution to the organs of the body. Chimaerism was most often noted in the liver, the heart, the intestine, and the lungs. Participation of triploid cells to all tissues studied, both in the body and in extra-embryonic structures, appeared to decrease slightly as development progressed. The second procedure yielded 10 foetuses and 6 adults. Three foetuses were chimaeric. Six fertile adults were probably non-chimaeras: the triploid component was absent in the coat and in the blood.
Experimental production of hybrid embryos between Mus musculus L. and Rattus norvegicus L. was achieved by nuclear transplantation using both ovulated oocytes in metaphase II and pronuclear zygotes. Recipient egg-cells were of mouse origin in all cases. The developmental potential of hybrids was examined in vivo. Nucleo-cytoplasmic hybrids resulting from the introduction of rat metaphase II chromosomes into enucleated mouse oocytes, which were subsequently activated, were regularly blocked at the 1- or 2-cell stage. Nuclear (genetic) hybrids produced by transfer of a rat nucleus (in the form of metaphase II chromosomes or a pronucleus) into a nucleated mouse recipient (oocyte or zygote) were capable of development to the 5- to 8-cell stage. Transplantation of rat cytoplasm alone to intact metaphase II oocytes, followed by oocyte activation, generated cytoplasmic hybrids which developed to the morula stage. In control experiments (nuclear transfer between mouse oocytes or zygotes), a high proportion of embryos formed morulae and blastocysts. These results demonstrate that the rat nucleus is incapable of functioning in mouse cytoplasm, that introduction of the rat genome into intact mouse egg-cells impairs normal development, and that transfer of foreign (rat) cytoplasm into mouse egg-cells affects preimplantation development of manipulated embryos.
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