Cytophotometric and biochemical research on the amount of DNA in the nuclei of loach embryos injected with low-molecular RNA

The cell cycle structure in the cells of loach embryos at the early blastula stage (5 h of development at 21 degrees) is markedly altered under the influence of injection of homologous low molecular weight nuclear RNA and, as a result, the number of cells in G2-phase. The DNA amount in the embryo increases by 20%. At the midblastula stage (7 h) no increase in the number of cells in G2-phase was found.     

Assessment of cytoplasmic effects on the development of mouse embryonic nuclei transferred to enucleated zygotes

In this study, cytoplasmic effects on the development of nuclear transplant embryos were examined. In addition, the production of offspring from nuclear transplant embryos was attempted. Nuclei from cleavage-stage embryos were transplanted to enucleated zygotes at different cell cycle stages and with different cytoplasmic volumes. A greater developmental rate to the blastocyst stage was observed in reconstituted late stage zygotes that received nuclei from late 2-cell stage embryos than in early stage zygotes (46.3% vs. 16.9%). A further increase in developmental rate to the blastocyst stage (85.5%) and in cell number was obtained in reconstituted late stage zygotes with reduced cytoplasmic volume. However, developmental potential of nuclei from 4- and 8-cell stage embryos was very limited, although they were transferred to enucleated late stage zygotes with reduced cytoplasm. After the transfer of blastocysts derived from nuclear transplant embryos to recipient females, live young were obtained from reconstituted embryos that received nuclei from late 2-cell stage embryos (28.6%). These results confirm that the development of nuclear transplant embryos can be affected by recipient cell cycle stage and cytoplasmic volume. Furthermore, the nuclei from late 2-cell stage embryos in which activation of the embryonic genome had occurred can be reprogrammed to a certain extent when transplanted into enucleated zygotes, especially late stage zygotes with reduced cytoplasmic content.     

Similarity of hnRNA sequences in blastula and pluteus stage sea urchin embryos

We have compared the total single-copy sequences transcribed as nuclear RNA in blastula and pluteus stage embryos of the sea urchin Tripneustes gratilla by hybridization of excess nuclear RNA with purified radioactive single-copy DNA. The kinetics of hybridization of either blastula or pluteus nuclear RNA with single-copy DNA show a single pseudo-first-order reaction with 34% of the single-copy genome. From the rate of the reaction and the purity of the nuclear RNA, it can be estimated that the reacting RNAs are present on the average at a concentration of one molecule per 14 nuclei. A mixture of blastula and pluteus RNA also hybridizes with 34% of the single-copy genome, indicating that the total complexity of RNAs transcribed at both stages is no greater than transcribed at each stage alone. The identity of the sequences transcribed by blastula and pluteus embryos was further examined by fractionation of the labeled DNA into sequences complementary and not complementary to pluteus RNA. This was achieved by hybridization of single-copy DNA to high pluteus RNA Cot, and separation of the hybridized and nonhybridized DNA on hydroxylapatite. Using either the DNA complementary or noncomplementary with pluteus RNA, essentially identical amounts of RNA:DNA hybrids are formed at high RNA Cot with blastula or pluteus RNA. Gross changes in the total RNA sequences transcribed do not appear to be involved in the developmental changes between blastula and pluteus, even though 45% of the mRNA sequences change between these two stages (Galau et al., 1976).     

Construction of the nuclear matrix at the transition from maternal to zygotic control of development in the mouse: an immunocytochemical study.

The nuclear matrix is thought to be responsible for DNA organization, DNA replication, RNA synthesis, and RNA processing. We have looked for the presence of nuclear matrix antigens during early mouse embryogenesis. Antibodies to peripheral and interior antigens (P1, Pl1, Pl2, and lamin B) were used to immunolocalize nuclear matrix antigens in germinal vesicle oocytes, metaphase II oocytes, zygotes, two-cell-stage embryos, and eight-cell stage embryos. All antibodies reacted with the nuclei of germinal vesicle oocytes, and two- and eight-cell-stage embryos; however, only P1 and lamin B were present at the pronuclear stage. In eggs collected at the pronuclear stage and cultured to the late two-cell stage in the presence of alpha-amanitin, the matrix morphology was altered for Pl1 and Pl2. alpha-Amanitin had no affect on the distribution of P1 or lamin B antigens. If alpha-amanitin was added 2 hr after cleavage to the two-cell stage, the normal staining pattern of Pl2 was retained. These results suggest that the presence of specific components of an internal matrix is correlated with normal genomic activity.     

An early role of maternal mRNA in establishing the dorsoventral pattern in pelle mutant Drosophila embryos

Mutations of the maternal effect locus pelle (pll) cause dorsalized Drosophila embryos. In extreme mutants, the embryo develops into a long hollow tube of dorsal cuticular structures with no sign of ventral pattern elements. Injection of wild-type cytoplasm or poly(A)+RNA into mutant pll embryos partially restores the normal pattern. Rescuing activity is present in the wild-type cytoplasm until the late blastoderm stage, but is already absent from the poly(A)+RNA fraction by the time of pole cell formation. At the same time, pll embryos fail to respond to injected biologically active poly(A)+RNA. This indicates that pll+ mRNA is lost early from the pool of maternal RNA and that there is a non-RNA component of rescue. This component, most likely the pll+ protein, appears to be unequally distributed in wild-type embryos.     

Effects of pancreozymin, urecholine and actinomycin D on the metabolism of ribonucleic acid by canine pancreas

1. Canine pancreas slices were incubated with [6-(14)C]orotic acid and the rate of its incorporation into RNA was measured. RNA was fractionated by shaking homogenates with phenol at 2 degrees , 50 degrees , 65 degrees and 80 degrees . Cytoplasmic RNA was extracted at the lowest temperature and nuclear RNA at the higher temperatures. The samples were centrifuged through sucrose gradients and the E(260) and (14)C-sedimentation patterns determined. Incorporation of orotic acid was very rapid into cytoplasmic 4s RNA. This probably represents end-group turnover. No incorporation into cytoplasmic ribosomal RNA was observed. 2. The nuclear 50 degrees -RNA exhibited two E(260) peaks, at 18s and 28s. This portion of the sample contained but moderate amounts of [(14)C]RNA. The highly labelled material had sedimentation coefficients in the range 35-50s. The nuclear 65 degrees -RNA showed an E(260) peak at 16s. The [(14)C]RNA peak occurred at 25-35s and this portion demonstrated the highest specific activity of any RNA fraction. 3. The 50 degrees -RNA, 65 degrees -RNA and 80 degrees -RNA were hydrolysed and their base compositions were determined. All three samples possess a ribosomal type of composition (G+C)/(A+U)=(1.4-1.7). For this reason they are considered to contain ribosomal precursor RNA as their major constituent. 4. Actinomycin D (0.5mug./ml.) in the incubation medium inhibited incorporation of orotic acid into both nuclear fractions but not into 4s RNA. 5. The cholinergic drug Urecholine inhibited incorporation into the heavy, high-specific-activity portions of the nuclear fractions but did not inhibit incorporation into the ribosomal precursor type of nuclear RNA. A similar result was also obtained with the hormone pancreozymin. Moderate inhibition of incorporation of orotic acid into 4s RNA likewise resulted from the presence of the drug and the hormone.     

Nuclear protein synthesis in a temperature-sensitive Chinese hamster ovary cell line at 40 degrees C

We examined the incorporation of radioactive amino acids into nuclear proteins occurring at nonpermissive conditions in tsH1 Chinese hamster ovary cells with a temperature-sensitive defect in cytosol nonmitochondrial protein synthesis. In leucine-free medium at 40 degrees C, total cellular protein synthesis declined by 1-1.5%/min. As reported by others, preincubating these cells at 42 degrees C for 5-10 min sharply increased the rate of decline. The synthesis of acidic nuclear proteins at nonpermissive conditions (40 degrees C + 300 micrograms/ml cycloheximide) was demonstrated by the nuclear incorporation of 3H-tryptophan. Radioactivity, seen by autoradiography to be associated with these isolated Triton-X-100-washed nuclei, was released after incubating labelled nuclei with proteolytic enzymes. During incubation of tsH1 cells at nonpermissive conditions, pulse/chase experiments were consistent with the loss of some nuclear radioactivity into the cytoplasm. The distribution of cytosol and nuclear proteins, labelled at permissive or nonpermissive conditions and separated by isoelectric focusing, differed quantitatively and probably qualitatively, confirming the residual synthesis of acidic nuclear proteins at 40 degrees C in the presence of cycloheximide. Most newly synthesized acidic proteins retained by nuclei from cells labeled at nonpermissive conditions were present in a transciptionally active chromatin fraction. Although under these conditions the apparent rate of cellular RNA synthesis was unchanged, inhibiting residual cycloheximide-resistant nuclear protein synthesis with puromycin proportionately reduced RNA synthesis. Preincubating cells with 20 micrograms/ml of actinomycin D did not inhibit residual labelling of nuclear proteins; effects on residual nuclear labelling of impaired mitochondrial respiration were ambiguous. Nuclear proteins labelled under nonpermissive conditions probably included some of the 'prompt' heat shock proteins recently described. Provided certain assumptions are correct, our results are consistent with very limited protein synthesis associated with and even intrinsic to cell nuclei. They also suggest that this residual cycloheximide-resistant protein synthesis could be concerned with optimum synthesis or processing of certain nuclear RNA species.     

Studies in vitro on mouse-egg radiosensitivity from fertilization up to the first cleavage

Super-ovulated eggs from the Balb/c strain were incubated, at various times after injection of HCG, in Whitten's medium containing tritiated thymidine. They were fixed on the following day at the 2-cell stage and prepared for autoradiography. On the basis of the results, pregnant mice were irradiated with various doses of X-rays at 15 h post HCG (fertilization), 19 h (phonuclear stage before DNA synthesis), 24 h (maximal DNA synthesis) and 27.5 h (DNA synthesis completed). On the day following irradiation, embryos were collected and classified into incleaved or 2-cell embryos, and development of the 2-cell embryos was followed in culture.

Irradiation was most effective when administered at 19 h after injection of HCG. Such a treatment increased the mortality before the first cleavage and, thereafter, from the 8-cell (100 rad) or morula stage (25, 50 rad). Blastocyst hatching and implantation were also impaired. Irradiation at other times was much less harmful for the embryos, which died mainly from the blastocyst stage. Finally, radiosensitivities of the mouse zygote at the various times studied can be estimated as follows: fertilization, + + +; pronuclear stage before DNA synthesis, + + + + +; maximal DNA synthesis, +; DNA synthesis terminated, + +.     

SELECTIVE INHIBITION BY APHIDICOLIN OF THE ACTIVITY OF DNA POLYMERASE ALPHA LEADS TO BLOCKADE OF DNA SYNTHESIS AND CELL DIVISION IN SEA URCHIN EMBRYOS

Aphidicolin at 2 μg/ml caused 90% inhibition of mitotic cell division of sea urchin embryos at the I-cell stage. However, at 40 μg/ml it did not affect meiotic maturational divisions of starfish oocytes, which do not involve DNA replication. At 2 μg/ml it caused 90% inhibition of incorporation of tritiated thymidine into DNA of sea urchin embryos but did not affect protein or RNA synthesis even at a higher concentration. At 2 μg/ml it also caused 90% inhibition of the activity of DNA polymerase α, obtained from the nuclear fraction of sea urchin embryos, but did not affect the activity of DNA polymerase β or γ. These findings suggest that DNA polymerase α is responsible for replication of DNA in sea urchin embryos.     

A re-investigation of the ribonuclease sensitivity of a DNA demethylation reaction in chicken embryo and G8 mouse myoblasts.

Recently published results (Nucleic Acids Res. 26, 5573-5580, 1998) suggest that the ribonuclease sensitivity of the DNA demethylation reaction may be an experimental artifact due to the possible tight binding of the nucleases to the methylated DNA substrate. Using an improved protocol we show for two different systems that demethylation of hemimethylated DNA is indeed sensitive to micrococcal nuclease, requires RNA and is not an experimental artifact. The purified 5-MeC-DNA glycosylase from chicken embryos and G8 mouse myoblasts was first incubated for 5 min at 37 degrees C with micrococcal nuclease in the presence of Ca2+ in the absence of the DNA substrate. Upon blocking the nuclease activity by the addition of 25 mM EGTA, the DNA demethylation reaction was initiated by adding the labeled hemimethylated DNA substrate to the reaction mixture. Under these conditions the DNA demethylation reaction was abolished. In parallel controls, where the purified 5-MeC-DNA glycosylase was pre-incubated at 37 degrees C with the nuclease, Ca2+ and EGTA or with the nuclease and EGTA, RNA was not degraded and no inhibition of the demethylation reaction was obtained. As has already been shown for chicken embryos, the loss of 5-MeC-DNA glycosylase activity from G8 myoblasts following nuclease treatment can also be restored by the addition of synthetic RNA complementary to the methylated strand of the substrate DNA. No reactivation of 5-MeC-DNA glycosylase is obtained by complementation with a random RNA sequence, the RNA sequence complementary to the non-methylated strand or DNA, thus ruling out a non-specific competition of the RNA for the binding of the nuclease to the labeled DNA substrate.     

Nuclear translocation of phospholipase C-zeta, an egg-activating factor, during early embryonic development

Phospholipase C-zeta (PLCzeta), a strong candidate of the egg-activating sperm factor, causes intracellular Ca2+ oscillations and egg activation, and is subsequently accumulated into the pronucleus (PN), when expressed in mouse eggs by injection of RNA encoding PLCzeta. Changes in the localization of expressed PLCzeta were investigated by tagging with a fluorescent protein. PLCzeta began to translocate into the PN formed at 5-6 h after RNA injection and increased there. Observation in the same embryo revealed that PLCzeta in the PN dispersed to the cytoplasm upon nuclear envelope breakdown and translocated again into the nucleus after cleavage. The dynamics was found in the second mitosis as well. When RNA was injected into fertilization-originated 1-cell embryos or blastomere(s) of 2-8-cell embryos, the nuclear localization of expressed PLCzeta was recognized in every embryo up to blastocyst. Thus, PLCzeta exhibited alternative cytoplasm/nucleus localization during development. This supports the view that the sperm factor could control cell cycle-dependent generation of Ca2+ oscillations in early embryogenesis.     

Autoradiographic studies on the distribution of labeled maternal RNA in early mouse embryos

Maternal RNA of mouse eggs and embryos was labeled by exposure of growing ovarian oocytes to 3H-uridine in vivo 8 to 16 days before ovulation and fertilization. Labeled embryos from the 1-cell stage to the blastocyst stage were collected, fixed, and autoradiographs of plastic sections prepared. The observed grain density was similar in the pronuclei and in the cytoplasm of 1-cell embryos. Knowing the volumes of nucleus and cytoplasm, it was determined that 3% of the maternal RNA was found in the pronuclei. It is suggested that some of this nuclear RNA may be stable small nuclear RNAs (e.g. U1 RNA) retained from the germinal vesicle stage through meiotic maturation. During the 2-cell stage and beyond, maternal RNA is degraded and labeled precursor is reincorporated into nuclear RNA, making it difficult to accurately quantitate the amount of nuclear maternal RNA. It is known that about one third of the total maternal RNA is lost between the 8-cell and blastocyst stages. It was found that cytoplasmic grain densities in inner and outer cells of the morula and blastocyst were not significantly different. Thus, the loss of maternal RNA does not proceed more rapidly in the differentiating trophoblast than in the inner cell mass.     

A possible maternal-effect mutant of Xenopus laevis: II. Studies of RNA synthesis in dissociated embryonic cells

Embryos from a female of Xenopus laevis (designated as no. 65) arrest development at gastrulation and are assumed to be ova-deficient mutant. We dissociated these embryos and studied RNA synthesis at different stages. The cells from the ova-deficient embryos reaggregated quite actively as wild-type embryo cells until the late gastrula stage. RNA synthesis was normal at the early blastula stage but greatly inhibited by the late blastula (stage 9.5) stage, when the synthesis of DNA and protein was still not inhibited appreciably. Thus, inhibition in RNA synthesis appears to be the first manifestation of the maternal defect that occurs before the gastrulation arrest.     

Synthesis of histone mRNA sequences in isolated nuclei of cleavage stage sea urchin embryos

A qualitative assay for detection of histone mRNA sequences in nuclear RNA was developed using actinomycin D-CsCl gradients to separate histone DNA from bulk DNA by differences in buoyant density. A significant amount of RNA synthesized in vitro in isolated nuclei from early blastula stage sea urchin embryos hybridized coincident with the histone DNA satellite, and this hybridization was competed out by unlabeled “9S” polysomal RNA purified from embryos at the same stage of development. The biogenesis of these histone mRNA sequences appeared similar as observed during in vivo and in vitro synthesis. Nuclear RNA from embryos pulse labeled in vivo was found to lack histone sequences, suggesting a rapid exit time for these sequences from the nucleus. Attempts to study the exit of histone sequences from isolated nuclei labeled in vitro also suggested a rapid exit time for histone sequences. The histone sequences were synthesized to a much lesser extent in isolated nuclei from late blastula stage embryos, as anticipated from the much reduced amount of histone mRNA labeled on polysomes at this stage.     

APLP2, a member of the Alzheimer precursor protein family, is required for correct genomic segregation in dividing mouse cells.

The mouse amyloid precursor-like protein 2 (APLP2) belongs to the Alzheimer peptide precursor family. A possible role in pre-implantation development had been suggested previously, and was investigated further by creating a large deletion in the genomic locus. While heterozygous mice developed normally, homozygous embryos were arrested before reaching the blastocyst stage. One-cell embryos which contained protein of maternal origin underwent a limited number of cleavages. The progressive disappearance of the protein at stages 4 and beyond correlated with the appearance of extensive cytopathological effects. Nuclear DNA contents of the arrested embryos departed widely from the normal 2-4C value, thus suggesting a role for the protein in replication and/or segregation of the embryonic genome. Embryonic mortality was not due to the untimely initiation of programmed cell death, and it occurred before the stage at which apoptotic cells normally appear. The same abnormal distribution of DNA contents was seen in primary cultures of Aplp2 +/- embryonic fibroblasts following transfection of an expression vector for Aplp2 antisense RNA with green fluorescent protein (GFP) expressed from a co-transfected construct. Daughter cells derived from a GFP-positive cell showed abnormal DNA contents both >4C and <2C, thus indicating a role for the protein in the mitotic segregation of the genome and establishment of the proper nuclear structure.