Nucleo-cytoplasmic exchange of non-histone proteins in amphibian embryos

Origin and progress of nuclear transfer in nonmammalian animals

This chapter traces the origin and progress of nuclear transfer that later became the paradigm for cloning animals. Classic studies in cytology, embryology, or genetics spanning more than five centuries that led to nuclear transfers in unicellular animals and to those in oocytes of insects, fish and amphibians are reviewed. The impetus for the development of successful nuclear transfers in amphibian oocytes in 1952 was to determine whether or not differentiated somatic cell nuclei are developmentally equivalent to zygote nuclei. Experiments in amphibians demonstrated several important results: (1) specialized somatic cell nuclei are extensively multipotent; (2) fertile adult amphibians can be cloned from embryonic and larval nuclei; (3) serial cloning expands the number of clones; (4) transplanting nuclei into oocyte cytoplasm induces reprogramming of their gene function; and (5) amphibian cloning became the model for cloning mammals. Subsequent studies in mice, a more technically favorable species, revealed that specialized cell nuclei are equivalent to zygote nuclei.

Animal cloning--the route to new genomics in agriculture and medicine

This paper reviews the origin and development of animal cloning in metazoans starting with primitive experiments performed during the late 1880's and early 1900's, followed by nuclear transplantation in amphibians in 1952, then extended to fish and insects in the 1960's, and finally to mammals in the 1980's. Emphasis is placed on the applications of mammalian cloning to agriculture, medicine, and the conservation of endangered species. In addition, the introduction of genes via random insertion or gene targeting into the genome of donor cells to be used for cloning has opened up another route for new genomics in agriculture and medicine. The production of transgenic clones starting in 1997 has indeed contributed a milestone to scientific research. Although cloning efficiency is still low, certain kinds of experiments are quite feasible, and we anticipate improvements in the future.

Nuclear transfer protocol affects messenger RNA expression patterns in cloned bovine blastocysts

The successful production of embryos by nuclear transfer (NT) employing cultured somatic donor cells depends upon a variety of factors. The objective of the present study was to investigate the effects 1) of two different activation protocols, 2) the use of quiescent or nonquiescent donor cells (G(0) or G(1) of the cell cycle), and 3) passage number of donor cells on the relative abundance (RA) of eight specific mRNAs (DNA methyltransferase, DNMT; mammalian achaete-scute homologue, Mash2; glucose transporter-1, Glut-1; heat shock protein 70.1, Hsp; desmocollin II, Dc II; E-cadherin, E-cad; interferon tau, IF; insulin-like growth factor 2 receptor, Igf2r) in single blastocysts employing a semiquantitative reverse transcription-polymerase chain reaction assay. The results were compared with those for their in vitro (IVP)- and in vivo-generated noncloned counterparts. In experiment 1, employing either FBA (fusion before activation) or AFS (fusion and activation simultaneously) to generate NT blastocysts, Hsp mRNAs were not found in NT embryos from either protocol, whereas Hsp transcripts were detectable in IVP embryos. The relative abundance (RA) of IF transcripts was significantly increased in the AFS and IVP groups compared to the FBA treatment. In experiment 2, the use of either G(0) or G(1) donor cells to produce cloned embryos both significantly reduced the relative amount of DNMT transcripts and significantly increased the RA of Mash2 compared to the IVP embryos. In addition, IF transcript levels were significantly elevated in NT blastocysts employing G(1) donor cells for NT compared to IVP embryos and those generated using G(0) cells. In experiment 3, donor cells, either from passsage 5/6 or 8, were employed for NT. DNMT transcripts were significantly decreased, whereas Mash2 transcripts were significantly increased in both NT groups compared to their IVP counterparts. The amount of IF mRNA was significantly higher in P8-derived than in P5/6 and IVP embryos. In experiment 4, the RA of DNMT transcripts was decreased in in vivo-derived blastocysts compared to those produced in vitro. Mash2 expression was increased in in vivo embryos and those IVP embryos produced in medium containing Sigma BSA. The RA of Hsp was higher in IVP embryos produced in serum containing medium than in those produced in Sigma BSA or in vivo. In vivo embryos and those produced in Life Technologies BSA had the lowest expression of IF transcripts. Expression of all other genes was not affected by variation in NT methodology or IVP culture systems throughout experiments 1-4. In conclusion, depending on steps of the cloning procedure NT-derived embryos display marked differences from their IVP- and in vivo-derived counterparts. An aberrant expression pattern in NT embryos was found with respect to genes thought to be involved in stress adaptation, trophoblastic function, and DNA methylation during preimplantation development.

Developmentally regulated loss and reappearance of immunoreactive somatic histone H1 on chromatin of bovine morula-stage nuclei following transplantation into oocytes

One difference between chromatin of bovine oocytes and blastomeres is that somatic subtypes of histone H1 are undetectable in oocytes and are assembled onto embryonic chromatin during the fourth cell cycle. We investigated whether this chromatin modification is reversed when nuclei containing somatic H1 are transplanted into ooplasts. Donor nuclei obtained from morula-stage bovine embryos were fused to ooplasts at different times before and after parthenogenetic activation of the ooplasts. After fusion, immunoreactive H1 became undetectable, and the loss occurred more rapidly when fusion was performed near the time of ooplast activation compared with several hours after activation, when the host oocytes were at a stage corresponding to interphase. Although the loss of immunoreactive H1 occurred independently of DNA replication and transcription, exposure of reconstructed oocytes to cycloheximide or 6-dymethylaminopurine (6-DMAP) delayed the loss of immunoreactive H1 from transplanted nuclei. During further development of nuclear-transplant embryos, somatic H1 remained undetectable at the 2- and 4-cell stages, and it reappeared on the chromatin at the 8- to 16-cell stage, as previously observed in unmanipulated embryos. We conclude that factors in oocyte cytoplasm are able to modify morula chromatin so that somatic H1 becomes undetectable, and that the amount or activity of these factors declines over time in activated ooplasts.

Karyoplast-cytoplast volume ratio in bovine nuclear transfer embryos: effect on developmental potential

To evaluate the effect of karyoplast-cytoplast ratio on the development of nuclear transfer embryos, karyoplasts from day 4, day 5, and day 6 embryos were transferred to oocytes enucleated with different volumes of cytoplasm: Type 1, removal of a small volume of cytoplasm equivalent to the first polar body, Type 2, removal of a volume of cytoplasm approximately equal to the volume of the respective karyoplast, and Type 3, removal of half of the oocyte volume. In addition, the effect of experimental reduction of karyoplast cytoplasm was investigated in day 4 and day 5 karyoplasts. Intact day 4 karyoplasts fused to Type 3 cytoplasts did not support development to blastocysts, whereas these karyoplasts yielded blastocysts in combination with Type 1 (7%) and Type 2 cytoplasts (12%). After experimental reduction of cytoplasmic volume in day 4 karyoplasts, blastocysts (10%) were also obtained after fusion with Type 3 cytoplasts, probably due to reduction of cytoplasmic chimerism. With day 5 karyoplasts, blastocyst rate was higher in combination with Type 2 (34%) than with Type 1 (19%) and Type 3 cytoplasts (16%; P < 0.05). The use of day 6 intact karyoplasts resulted in a significantly (P < 0.05) higher proportion of blastocysts when fused with Type 2 (38%) or Type 1 cytoplasts (34%) than with Type 3 cytoplasts (16%). These results suggest that enucleation of oocytes with a volume similar to that of the respective karyoplast creates better conditions for cell cycle interactions with all types of karyoplasts than enucleation with minimal or large volume of cytoplasm.

Genomic potential in mammals

Embryos of amphibians, fish, sheep, cattle, swine and rabbits have been multiplied by nuclear transfer. Successful nuclear transfer in these species has been accomplished by transfer of a blastomere from a late stage embryo into an enucleated oocyte or egg with large scale multiplication achieved by serial repetition of the procedure using blastomeres from nuclear transfer embryos. This allows the production of clonal lines, which when appropriately selected for performance in a given trait, can be reproduced to capture in the offspring expression of both additive and nonadditive inheritance. The efficiency of producing offspring from nuclear transfer is low in mammals in both frequency of morula or blastocyst produced and maintenance of pregnancy after embryo transfer. In domestic animals the largest number of offspring from one embryo has been eight calves. Embryos as late as the 64-cell stage in cattle and 120-cell blastocyst in sheep have been used successfully as donors of blastomeres. Recloning has also been done in cattle. Potentially, nuclear transfer provides a mechanism for multiplication and production testing of clonal lines, a method for rapid genetic improvement and a means for rapid propagation of a selected genotype.

Selective association of some hamster-egg-synthesized proteins with decondensing human sperm chromatin

Zona-free hamster eggs were fertilized in vitro with human spermatozoa in a culture medium enriched with either 3H-arginine or 3H-tryptophan. Autoradiography was used to investigate decondensing sperm heads and all pronuclei for the presence of newly synthesized, 3H-labelled proteins. In the case of 3H-arginine-labelled proteins, an intense accumulation of radioactivity was detected in all autoradiograms of chromatin structures. On the other hand, no comparable accumulation was seen for 3H-tryptophan-labelled proteins up to the progressed-pronucleus stage. It is concluded that, as a part of changes of the nucleoproteins in decondensing sperm chromatin, there is an accumulation in the male (as well as in the female) pronucleus of basic nuclear proteins synthesized by the egg during fertilization. Since non-histone, 3H-tryptophan-labelled proteins were not incorporated in the same way, these 3H-arginine-labelled proteins accumulating in pronuclear chromatin during the earliest phase of pronucleus formation are probably histones.

Stable nuclear activation dependent on a protein synthesised during oogenesis

A protein synthesised during oogenesis seems to be essential for the activation, during blastulation, of the nuclear genes essential for gastrulation and organogenesis. Nuclear transplantation experiments show that this interaction between the protein and the blastula nucleus produces a heritable state of nuclear activation.