Regulation of Protein Synthesis in Embryos of Ilyanassa obsoleta

Much of the protein synthesis during early development in Ilyanassaresults from the translation of oogenetic mRNA. We show thatmicrotubule proteins are products of this translation, and thattheir synthesis is subject to translation level regulation.We also show that translation level regulation is involved inthe function of the polar lobe by making comparisons of theelectrophoretic patterns of synthesis of ¹⁴C labeled proteinsof normal embryos with the patterns of synthesis of ³H labeledproteins of embryos from which the polar lobes had been removedat the trefoil stage. Controls utilizing biochemical and morphologicalmarkers were performed to assure that normal and delobed embryoswere developing at equivalent rates. The expression of significantdifferences in the patterns of protein synthesis were foundbetween normal and delobed embryos, and these differences werenot dependent upon concomitant RNA synthesis. These differenceswere observable as early as after only 24 hours of development,although organogenesis does not begin until much later in development.Therefore, the observed differences probably reflect determinativeevents. The results support the hypothesis that the developmentaldeterminants of the polar lobe may include specific, preformedmRNA sequences, or specific regulators of translation.     

Post-transcriptional regulation of protein synthesis in Ilyanassa embryos and isolated polar lobes

The experimental removal of the polar lobe, an anucleate cytoplasmic protrusion formed in preparation for the first cleavage, from the egg of Ilyanassa obsoleta results in grossly abnormal embryonic development. In experiments reported here normal and delobed embryos, as well as isolated polar lobes, were incubated with [³⁵S]methionine for 4 hr beginning at the completion of the first cleavage or 21 hr later during epiboly. Proteins were extracted and examined by fluorography after resolution by two-dimensional polyacrylamide gel electrophoresis. In normal embryos the synthesis of several proteins begins or ends between the two stages investigated. In isolated polar lobes a subset of these developmental changes in protein synthesis occurs, indicating that the regulation of these events is independent of concomitant nuclear activity and probably involves selective regulation of the translation of mRNA stored in the eggs. The patterns of protein synthesis in normal embryos and delobed embryos are qualitatively extremely similar, though quantitative differences are also observed. No proteins can be detected which are synthesized exclusively in polar lobes.     

Polar lobe specific regulation of translation in embryos of Ilyanassa obsoleta.

Comparisons of the patterns of synthesis of ¹⁴C-labeled proteins of normal embryos of Ilyanassa with the patterns of synthesis of ³H-labeled proteins of embryos from which the polar lobes had been removed at the trefoil stage were made by coelectrophoresis on polyacrylamide disc gels. Controls utilizing biochemical and morphological markers were performed to assure that normal and delobed embryos were developing at equivalent rates. The expression of significant differences in the patterns of protein synthesis were found between normal and delobed embryos, and these differences were not dependent upon concomitant RNA synthesis. These differences were observable as early as after only 24 hr of development, although organogenesis does not begin until much later in development. Therefore, the observed differences probably reflect determininative events. The results support the hypothesis that the developmental determinants of the polar lobe may include specific, preformed mRNA sequences, or specific regulators of translation.     

Distribution of histone H1 alpha among cells of the sea urchin embryo

We have used immunofluorescent staining of sea urchin embryos to study how histone H1 alpha is distributed among progeny cells formed after the cessation of its synthesis. Our results are consistent with H1 alpha being distributed to both daughter cells at mitosis, resulting in it being most concentrated in cells that stop dividing shortly after H1 alpha synthesis ends, while cells that continue to divide dilute their H1 alpha content in proportion to the number of cell divisions. This rules out our earlier suggestion that H1 alpha becomes segregated in dividing cells. In addition, our results show that most dividing cells of the 3-day embryo contain predominantly H1 beta and H1 gamma. Since these subtypes are known not to undergo phosphorylation, this finding has implications regarding the roles of H1 phosphorylation in the cell cycle.     

Fucosylated glycoconjugates in mouse preimplantation embryos

Preimplantation mouse embryos were metabolically labelled with 3H or 14C-fucose to investigate the synthesis of fucosylated macromolecules. Scintillation counting revealed that there was a progressive increase in both total fucose taken up by the embryo and incorporation of fucose into TCA-precipitable material as embryos developed from the 4-cell to the blastocyst stage. This was reflected in the increasing intensity of bands on autoradiographs of radioactive fucose labelled proteins separated on 10% SDS-PAGs between the 4-cell embryo (at which stage bands were first detectable) and the blastocyst. Minor qualitative changes in fucoproteins were detected at the time of compaction and additional bands appeared at the blastocyst stage. Preliminary analysis of fucolipids in 6- to 8-cell embryos indicated that an approximately equal amount of fucose was incorporated into lipid and protein. Autoradiographs of semi-thin sections of 3H-fucose-labelled embryos showed substantial amounts of radioactive material in the vicinity of the plasma membrane both adjacent to other cells and facing the zona pellucida. These data would support a predominant role for fucoconjugates in cell surface events in the preimplantation embryo from the 8-cell stage.     

Synchronization of cell division in eight-cell bovine embryos produced in vitro: Effects of nocodazole

Current methods of arresting and synchronizing cell division have not been very successful and have had few applications in embryo studies. Our objective was to determine the reliability of a metaphase arrest agent, nocodazole, for halting and synchronizing blastomere division in cleavage-stage bovine embryos, and to verify its reversibility and toxicity in vitro. Eight-cell-stage embryos obtained at 58 hr postinsemination were treated with varying concentrations of nocodazole for 12 hr. Treated embryos were assessed for cleavage arrest, chromatin morphology, DNA synthesis, and histone H1 and myelin basic protein (MBP) kinase activity, and were scored for blastocyst formation and hatching rate. They were subsequently fixed to count the number of nuclei. Complete arrest of cell division was observed at concentrations of 0.4 μg ml⁻¹ and above. Removal from nocodazole treatment led to immediate release from cleavage arrest, and was followed by synchronized mitosis, histone H1 kinase deactivation, and reentry into interphase within 3–5 hr. DNA synthesis was reinitiated at 6 hr after release. Although cell numbers and hatching rate decreased, the proportion of embryos reaching blastocyst stage was not significantly affected in nocodazole-treated embryos. It is concluded that nocodazole is a suitable choice for the cell-cycle synchronization of donor embryos for use in studies on the interactions between nucleus and cytoplasm during early embryogenesis. © 1996 Wiley-Liss, Inc.     

The synthesis and secretion of collagen by cultured sea urchin micromeres

Circumstantial evidence in several previous studies has suggested that sea urchin embryo micromeres, the source of primary mesenchyme cells which produce the embryonic skeleton, contribute to the extracellular matrix of the embryo by synthesizing collagen. A direct test of this possibility was carried out by culturing isolated micromeres of the sea urchin Stronglyocentrotus purpuratus in artificial sea water containing 4% (v/v) horse serum. Under these conditions the micromeres divide and differentiate to produce spicules with the same timing as intact embryos. Collagen synthesis was determined by labeling cultures with [3H]proline or [35S]methionine and the medium and cell layer were assayed for collagen. The results indicate that by the second day in culture micromeres synthesize and secrete a collagenase-sensitive protein doublet with a molecular weight of about 210 kDa. Densitometry indicates a 2:1 ratio of the respective bands in the doublet which is characteristic of Type I collagen. The doublet is insensitive to digestion with pepsin. This differential sensitivity is characteristic of collagen. Over 90% of the collagen synthesized by micromeres is soluble in the seawater culture medium. On days 2-4 in culture, collagen accounts for 5% of the total protein synthesized and secreted. Additional collagenase-sensitive bands are noted at 145 and 51 kDa. The relationship of the described collagen metabolism to previously characterized collagen gene expression in sea urchin embryos is discussed.     

Rates of histone synthesis during early development of Rana pipiens

Newly synthesized histones have been extracted from Rana pipiens oocytes or cleaving embryos previously injected with [³H]lysine or [³H]arginine. The radioactive proteins were fractionated by cation-exchange chromatography and electrophoresis on acid/urea or SDS-polyacrylamide gels; histones were identified by coelectrophoresis with authentic markers. From percentage total incorporation in the putative histones, and absolute rates of lysine or arginine incorporation, rates of histone synthesis were estimated. Rates of histone synthesis in two-cell embryos were at least 10-fold higher than in maturing oocytes. Between the two-cell and blastula stages, the rate increased an additional threefold, from about 1200 pg hr^?1 per embryo to about 4500 pg hr^?1 per embryo. While all histone classes are synthesized during cleavage, synthesis of the various classes is not coordinated; histones are not synthesized in the same relative proportions at which they are found in blastula chromatin. The synthesis of histone H4 in particular is barely detectable during cleavage. This, and other observations, suggested the existence of cytoplasmic histone pools. In approaching the possible existence of histone pools, the amount of H4 present in oocytes was determined. Oocytes contain about 74 ng of H4, an amount sufficient to allow development to the blastula stage. These data are compared to those reported by others on histone synthesis during cleavage in Xenopus.     

Histone H5 and H1 cross-reacting material is restricted to erythroid cells in chicken

Monoclonal H5 antibodies and a polyclonal antiserum, raised against the globular domain of chicken H5 (GH5) but which cross-reacts with histone H1(0) from mouse liver, were used to search for H5 or H1 (0)-like proteins in chicken embryo and adult tissue sections by indirect immunofluorescence. Chicken cell lines in culture were examined for H5 protein and H5 mRNA. Histone H5 was detected only in erythroid cells in tissue sections of chicken embryos or adult livers. H5 protein and H5 mRNA were found only in erythroid cells in culture. No cross-reacting proteins were detected in any other tissue or cell line examined.     

Remodeling of sperm chromatin following fertilization: nucleosome repeat length and histone variant transitions in the absence of DNA synthesis

Within the first cell cycle following fertilization the average nucleosomal repeat length of sea urchin male pronuclear chromatin declines by 30-40 base pairs to a value typical of that found in the embryo. This decline occurs after a lag of about 30 min postfertilization, and is accompanied by replication of the male chromatin and accumulation of cleavage-stage (CS) core histone variants. When replication is inhibited by greater than 95% with aphidicolin, the decline in repeat length still occurs, although it is slightly retarded. The decline in repeat length also occurs when protein synthesis is blocked by greater than 98% and DNA synthesis by 60-70% with emetine. The adjustment of nucleosome repeat length therefore can occur in vivo without extensive movement of replication forks across the length of the chromatin, or normal progression of the cell cycle, and appears to require no proteins synthesized postfertilization. Blocking of DNA synthesis or protein synthesis also does not prevent the normal histone variant transitions involved in male pronuclear chromatin remodeling. Although their accumulation is slowed, CS core variants eventually become the predominant male pronuclear histones in their classes when replication is inhibited. Since a shortening of the average nucleosomal repeat length of approximately 10-20% is not sufficient to account for this large acquisition of CS variants, some of the sperm (Sp) core histones are probably displaced from the replication-blocked pronucleus. Therefore, accumulation of CS H2A and CS H2B are temporally correlated with the repeat length transition, whereas replication, normal progression of the cell cycle, and the early histone transitions involving SpH1 and SpH2B are not.     

The interconversion of purine nucleotides during Ilyanassa embryogenesis

The phosphorylation and interconversion of purines was measured after pulsing normal and lobeless Ilyanassa embryos with [2-³H]-adenosine. The isolated polar lobe phosphorylated and interconverted purines to the same extent as the intact egg, and the removal of this anucleate structure did not significantly impair these functions in the lobeless egg. All components of the egg, i.e. the polar lobe and lobeless egg, were equally effective in the synthesis of dATP.     

Activation of p34cdc2 protein kinase activity in meiotic and mitotic cell cycles in mouse oocytes and embryos.

p34cdc2 protein kinase is a universal regulator of M-phase in eukaryotic cell cycle. To investigate the regulation of meiotic and mitotic cell cycle in mammals, we examined the changes in phosphorylation states of p34cdc2 and its histone H1 kinase activity in mouse oocytes and embryos. We showed that p34cdc2 has three different migrating bands (referred to as upper, middle and lower bands) on SDS-PAGE followed by immunoblotting with anti-PSTAIR antibody, and that the upper and middle bands are phosphorylated forms since these two bands shifted to the lower one by alkaline phosphatase treatment. In meiotic cell cycle, only germinal vesicle (GV) stage oocytes had the three forms. The phosphorylated forms decreased gradually in oocytes up to 2 h after isolation from follicles, and thereafter the phosphorylation states did not change significantly until metaphase II. However, the histone H1 kinase activity oscillated, being activated at the first and second metaphase in meiosis and inactivated at the time of the first polar body extrusion. These results suggest that changes in phosphorylation states of p34cdc2 triggered its activation at the first metaphase, but not inactivation and reactivation at the first and second metaphase, respectively. In mitotic cell cycle, phosphorylated forms appeared at 4 h after insemination, increased greatly just before metaphase, and were dephosphorylated in metaphase. Histone H1 kinase activity was high only at metaphase. This kinase activation is probably triggered by dephosphorylation of p34cdc2.