Immunoelectron microscopical distribution of poly(ADP-ribose)polymerase in the mammalian cell nucleus

The ultrastructural distribution of poly(ADP-ribose)polymerase has been studied using a specific antibody and immunocytochemistry with immunogold markers. In situ localization in synchronized Chinese hamster ovary cells reveals the antibody associated with mitotic chromosomes, and later with condensed chromatin and perichromatin regions in G1 phase. During S and G2, the label occurs mostly on perichromatin regions where perichromatin fibrils are also observed. In the nucleolus, the label appears especially on the dense fibrillar component and to a minor extent on the granular component. Immunolabeled spread active chromatin preparations from exponentially growing cultured mouse P815 cells indicate preferential association of the antibody with nascent nonribosomal RNP fibrils compared to inactive chromatin. The results, suggesting a relationship between the poly(ADP-ribose)polymerase occurrence and RNA (or RNP) formation, are discussed in view of the present knowledge about possible relations between poly(ADP-ribosylation) and synthesis of RNA and DNA.     

Analysis of chromatin structure in mouse preimplantation embryos by fluorescent recovery after photobleaching

Zygotes are totipotent cells that have the ability to differentiate into all cell types. It is believed that this ability is lost gradually and differentiation occurs along with the progression of preimplantation development. Here, we hypothesized that the loose chromatin structure is involved in the totipotency of one-cell stage embryos and that the change from loose to tight chromatin structure is associated with the loss of totipotency. To address this hypothesis, we investigated the mobility of eGFP-tagged histone H2B (eGFP-H2B), which is an index for the looseness of chromatin, during preimplantation development based on fluorescent recovery after photobleaching (FRAP) analysis. The highest mobility of eGFP-H2B was observed in pronuclei in 1-cell stage embryos and mobility gradually decreased during preimplantation development. The decrease in mobility between the 1- and 2-cell stages depended on DNA synthesis in 2-cell stage embryos. In nuclear transferred embryos, chromatin in the pseudopronuclei loosened to a level comparable to the pronuclei in 1-cell stage embryos. These results indicated that the mobility of eGFP-H2B is negatively correlated with the degree of differentiation of preimplantation embryos. Therefore, we suggest that highly loosened chromatin is involved in totipotency of 1-cell embryos and the loss of looseness is associated with differentiation during preimplantation development.     

RNA and protein synthesis in preimplantation rabbit embryos

A phenol-sodium dodecyl sulfate procedure has been used to extract DNA, RNA, and protein from 3-, 4.5-, and 6.5-day-old preimplantation rabbit embryos that were incubated for different lengths of time in the presence of labeled precursors. The results suggest that the newly-synthesized RNA and protein are more stable in the growing blastocyst than in the trophoblast at the time of implantation.This conclusion was derived from the results of embryo incorporation kinetics. The results also suggest that the increase in protein and RNA content in preimplantation rabbit blastocysts was preceded by an increase in protein synthesis accompanied by low catabolism.     

Functional foles of insulin and insulinlike growth factors in preimplantation mouse embryo development

Summary Growth factors are known to play important roles in cellular proliferation and differentiation. However, little information is available concerning their roles in the earliest stages of mammalian development. The effect of physiologic levels of insulin, insulinlike growth factor-I, and insulinlike growth factor II (IGF-I and-II) on DNA, RNA, and protein synthesis in preimplantation stages of the mouse are described in this study. Quantitative studies of the incorporation of labeled thymidine, uridine, and methionine into trichloroacetic acid-insoluble material by different developmental stages of preimplantation mouse embryos labeled in vitro, indicate that physiologic levels of insulin stimulated DNA, RNA, and protein synthesis with significant effects observed first at the morula stage of development. In contrast, neither IGF-I nor IGF-II stimulated DNA, RNA, or protein synthesis to a significant degree under the same experimental conditions. These results suggest a functional role for insulin at the earliest stages of mammalian embryogenesis. This work was supported by grant HD 23511 from the National Institutes of Health, Bethesda, MD.     

Electron microscopic analysis of chromatin replication in the cellular blastoderm drosophila melanogaster embryo

Transmission electron microscopic techniques were used to study the spatial distribution of replicons and the ultrastructure of chromatin in the S phase genome of cellular blastoderm Drosophila melanogaster embryos. We observed chromatin exhibiting distinct bifurcations along each fiber during the initial 20 min of the first cell cycle of blastulation. We interpreted the “bubble-like” configurations produced by adjacent bifurcations as intermediate structures in chromatin replication (that is, replicons). We observed homologous ribonucleoprotein (RNP) fiber arrays on both chromatid arms within some replicons, implying DNA sequence homology and reinforcing the identification of such arms as daughter chromatid fibers. We did not observe replicon configurations on chromatin obtained from embryos staged at more than 20 min into cellular blastulation. Daughter chromatid fibers, however, were identified by the presence of identical RNP fiber arrays on chromatid strands arranged in parallel on the electron microscope grid.We examined the distribution of replicon structures on the cellular blastoderm genome and compared it with electron microscopic data on DNA replication in cleavage embryos (Blumenthal, Kriegstein and Hogness, 1973). S phase is completed in slightly < 4 min during cleavage, or approximately one fifth the time required for DNA synthesis in cellular blastoderm embryos. The mean distance separating adjacent replication origins at cellularization was estimated to be 10.6 kilobases (kb), a value 35% greater than the 7.9 kb inter-origin average determined for cleavage embryos. In contrast to the near-simultaneous activation of replication origins during cleavage replication, we observed that replication origins are not activated synchronously at cellular blastulation. We concluded that the marked increase in the duration of S phase is effected by a reduction in the frequency of replication activation events which occur asynchronously during genome replication at cellularization.We found that the ultrastructure of newly replicated chromatin exhibited a morphology indistinguishable from nucleosomal chromatin. Unreplicated chromatin fibers separating adjacent replicons also exhibit spherical subunits. We inferred that the spherical structures on replicating chromatin are nucleosomes and concluded that histones are not disassociated from the DNA significantly prior to DNA replication, and that a very rapid reassociation of nucleosomes occurs on both daughter DNA molecules following replication.     

Sister subchromatid exchanged segments and chromosome structure

The relationship between the synthesis of acidic nuclear proteins, phosphoproteins, RNA and chromatin ultrastructural pattern was studied in regenerating rat hepatocytes after partial hepatectomy. α-Amanitin induced, as early as 30 min after injection, a reduction of RNA synthesis to about 50% of the control level; the degree of inhibition had remained the same at 2 h after poisoning. No change was detected either in acidic nuclear protein synthesis or in phosphorylation for the whole time examined. The DNA-containing structures, demonstrated by the Gautier staining procedure, were in a dispersed pattern either in untreated regenerating hepatocytes or 30 min after α-amanitin administration to rats; but they did appear in a condensed form 1 h and more especially 2 h after toxin injection. In untreated regenerating hepatocytes, the regressive EDTA staining method for RNP revealed a large quantity of perichromatin fibrils which remained unchanged 30 min after α-amanitin treatment and were diminished at 1 h and strongly reduced 2 h thereafter.Cycloheximide treatment promptly reduced the synthesis of nuclear acidic proteins while leaving unchanged the synthesis of RNA; the quantity of perichromatin fibrils and the loosened appearance of DNA-containing structures were the same as in the control rat nuclei.Our results showed that the ultrastructural pattern of chromatin was not directly related either to the synthesis of RNA or to acidic nuclear proteins or to the phosphorylation of phosphoproteins; on the contrary, a strict relationship with the quantity of perichromatin fibrils was demonstrated. The possible interaction of perichromatin fibrils with other chromatin components was discussed as a possible regulatory mechanism of chromatin pattern.     

Perichromatin fibrils and chromatin ultrastructural pattern

The relationship between the synthesis of acidic nuclear proteins, phosphoproteins, RNA and chromatin ultrastructural pattern was studied in regenerating rat hepatocytes after partial hepatectomy. α-Amanitin induced, as early as 30 min after injection, a reduction of RNA synthesis to about 50% of the control level; the degree of inhibition had remained the same at 2 h after poisoning. No change was detected either in acidic nuclear protein synthesis or in phosphorylation for the whole time examined. The DNA-containing structures, demonstrated by the Gautier staining procedure, were in a dispersed pattern either in untreated regenerating hepatocytes or 30 min after α-amanitin administration to rats; but they did appear in a condensed form 1 h and more especially 2 h after toxin injection. In untreated regenerating hepatocytes, the regressive EDTA staining method for RNP revealed a large quantity of perichromatin fibrils which remained unchanged 30 min after α-amanitin treatment and were diminished at 1 h and strongly reduced 2 h thereafter.Cycloheximide treatment promptly reduced the synthesis of nuclear acidic proteins while leaving unchanged the synthesis of RNA; the quantity of perichromatin fibrils and the loosened appearance of DNA-containing structures were the same as in the control rat nuclei.Our results showed that the ultrastructural pattern of chromatin was not directly related either to the synthesis of RNA or to acidic nuclear proteins or to the phosphorylation of phosphoproteins; on the contrary, a strict relationship with the quantity of perichromatin fibrils was demonstrated. The possible interaction of perichromatin fibrils with other chromatin components was discussed as a possible regulatory mechanism of chromatin pattern.     

The Effect of α-Amanitin on Nucleic Acid Synthesis in Preimplantation Mouse Embryos

It has been hypothesized that multiple forms of RNA polymerase may play a role in the control of development and differentiation in eukaryotic organisms. For this to be true, three criteria must be met. First, multiple forms of RNA polymerase must be demonstrated. Second, the relative proportion of the enzyme forms must be shown to change with development or differentiation. And third, the types of RNA synthesized must correlate with the types of RNA polymerase present at each developmental stage. We have previously reported data satisfying the first two criteria for preimplantation mouse embryos. The present paper probes the third criterion in this differentiating system.
It was found that although the proportion of the RNA polymerase enzyme forms changes from the 8-cell to the blastocyst stage of development, the types of newly synthesized nucleic acids at each of these stages were similar. Furthermore, inhibition of rRNA, mRNA, and tRNA, by α-amanitin, was identical for 8-cell and blastocyst embryos. The only difference between these two stages was that DNA synthesis in blastocysts was more sensitive to inhibition by α-amanitin than DNA synthesis in 8-cell embryos. We conclude that the synthesis of different classes of RNA by preimplantation mouse embryos is not simply controlled by changes in the levels of the multiple forms of RNA polymerase.     

Fate of donor mitochondrial DNA in cloned bovine embryos produced by microinjection of cumulus cells

This study examined the fate of donor mitochondrial DNA during preimplantation development after nuclear transfer (NT) in cattle. Frozen-thawed cumulus cells were used as donor cells in the nuclear transfer. Mitochondrial DNA heteroplasmy in the nuclear transfer embryos was analyzed by allele-specific PCR (AS-PCR), direct DNA sequencing, and DNA chromatography. AS-PCR analysis for the detection of donor mitochondrial DNA was performed at the 1-, 2-, 4-, 8-, 16-cell, morula, and blastocyst stages of the embryos. The mitochondrial DNA from donor cells was detected at all developmental stages of the nuclear transfer embryos. However, mitochondrial DNA heteroplasmy was not observed in direct DNA sequencing of displacement-loop sequence from nuclear-transfer-derived blastocyst embryos. To confirm the mtDNA heteroplasmy in cloned embryos, the AS-PCR product from NT-derived blastocysts was analyzed by DNA sequencing and DNA chromatography. The nucleotides of NT-derived blastocysts were in accordance with the nucleotides from donor cells. These results indicate that the foreign cytoplasmic genome from donor cells was not destroyed by cytoplasmic events during preimplantation development that followed nuclear transfer.     

Cytogenetic analysis of oocytes and early preimplantation embryos from XO mice.

The cytoplasm of early sea urchin embryos contains nonribosomal, high molecular weight RNA both associated with ribosomes in polysomes and free of ribosomes in particles termed free RNP. In a 1-hr labeling period, 50% of the newly synthesized RNA enters the pool of ribosome-free RNP particles during the cleavage stages, and this percentage decreases until less than 20% of the new RNA in the mesenchyme blastula stage is found in the free RNP. mRNA from both polysomes and free RNP contain poly(A)(+) and poly(A)(?) species. During the cleavage stages only 8–10% of the RNA from each fraction is polyadenylated; however, in the blastula, 40–50% of the nonhistone polysomal RNA is polyadenylated while only 22–30% of the free RNP RNA is polyadenylated. At any developmental stage, the poly(A)(+)RNA from the free RNA and polysomes have identical sedimentation profiles; this is also the case for the poly(A)(?)RNA except for the absence of the 9 S histone mRNA from the free RNP. Changes in poly(A)(+)RNA content and sedimentation profiles during development occur simultaneously in the free RNP and the polysomes. Kinetic studies of these two RNP populations as well as nuclear RNP show that the bulk of the free RNP are not unusually stable cytoplasmic components. The free RNP decay with a half-life of about 40 min while nuclear RNA and polysomal RNA display half-lives of about 12 and 65 min, respectively. Further, the rate of synthesis of the free RNP is not consistent with their being the only precursors for polysomes. Our estimates of the rates of synthesis for nuclear RNA, polysomes, and free RNP are, respectively, 1.1 × 10^?15, 2.2 × 10^?16, and 5.0 × 15^?17 g/min/nucleus. The data on free RNP is discussed in terms of translational regulation of protein synthesis in the developing sea urchin.