Onset Of Embryonic Transcription Research Articles

Histone H3.3 Variant Dynamics in the Germline of Caenorhabditis elegans

Germline chromatin undergoes dramatic remodeling events involving histone variants during the life cycle of an organism. A universal histone variant, H3.3, is incorporated at sites of active transcription throughout the cell cycle. The presence of H3.3 in chromatin indicates histone turnover, which is the energy-dependent removal of preexisting histones and replacement with new histones. H3.3 is also incorporated during decondensation of the Drosophila sperm pronucleus, indicating a direct role in chromatin remodeling upon fertilization. Here we present a system to monitor histone turnover and chromatin remodeling during Caenorhabditis elegans development by following the developmental dynamics of H3.3. We generated worm strains expressing green fluorescent protein– or yellow fluorescent protein–fused histone H3.3 proteins, HIS-71 and HIS-72. We found that H3.3 is retained in mature sperm chromatin, raising the possibility that it transmits epigenetic information via the male germline. Upon fertilization, maternal H3.3 enters both male and female pronuclei and is incorporated into paternal chromatin, apparently before the onset of embryonic transcription, suggesting that H3.3 can be incorporated independent of transcription. In early embryos, H3.3 becomes specifically depleted from primordial germ cells. Strikingly, the X chromosome becomes deficient in H3.3 during gametogenesis, indicating a low level of histone turnover. These results raise the possibility that the asymmetry in histone turnover between the X chromosome and autosomes is established during gametogenesis. H3.3 patterns are similar to patterns of H3K4 methylation in the primordial germ cells and on the X chromosome during gametogenesis, suggesting that histone turnover and modification are coupled processes. Our demonstration of dynamic H3.3 incorporation in nondividing cells provides a mechanistic basis for chromatin changes during germ cell development.

Myostatin expression during development and chronic stress in zebrafish (Danio rerio).

Myostatin, a member of the transforming growth factor-beta superfamily, is a negative regulator of skeletal muscle mass in mammals. We have studied myostatin expression during embryonic and post-hatching development in zebrafish by semiquantitative RT-PCR. The transcript is present in just-fertilized eggs and declines at 8 h post-fertilization (hpf), suggesting a maternal origin. A secondary rise occurs at 16 hpf, indicating the onset of embryonic transcription at the time of muscle cell differentiation. The level of myostatin mRNA decreases slightly at 24 hpf, when somitogenesis is almost concluded, and rises again at and after hatching, during the period of limited muscle hyperplastic growth that is typical of slow-growing, small fish. In the adult muscle, we found the highest expression of myostatin mRNA and protein, which were detectable by Northern and Western blot analyses respectively. Although only the precursor protein form was revealed in the adult lateral muscle, we demonstrated that zebrafish myostatin is proteolytically processed and secreted in cultured cells, as is its mammalian counterpart. These results suggest that myostatin may play an important regulatory role during myogenesis and muscle growth in fish, as it does in mammals. In chronically stressed fish, grown from 16 days post-fertilization to adulthood in an overcrowded environment, we observed both depression of body growth and a diminished level of myostatin mRNA in the adult muscle, as compared with controls. We propose that chronic stunting in fish brings about a general depression of muscle protein synthesis which does not spare myostatin.

Distinct roles for TBP and TBP-like factor in early embryonic gene transcription in Xenopus.

The TATA-binding protein (TBP) is believed to function as a key component of the general transcription machinery. We tested the role of TBP during the onset of embryonic transcription by antisense oligonucleotide-mediated turnover of maternal TBP messenger RNA. Embryos without detectable TBP initiated gastrulation but died before completing gastrulation. The expression of many genes transcribed by RNA polymerase II and III was reduced; however, some genes were transcribed with an efficiency identical to that of TBP-containing embryos. Using a similar antisense strategy, we found that the TBP-like factor TLF/TRF2 is essential for development past the mid-blastula stage. Because TBP and a TLF factor play complementary roles in embryonic development, our results indicate that although similar mechanistic roles exist in common, TBP and TLF function differentially to control transcription of specific genes.

Fine-structural cytochemical and immunocytochemical observations on nuclear bodies in the bovine 2-cell embryo.

Nuclear bodies occurring during the 2-cell stage of bovine embryos (obtained either by in vitro fertilisation of in vitro matured ovarian oocytes, or collection after fertilisation and cleavage in vivo) were studied using ultrastructural cytochemistry and immunocytochemistry to determine whether their occurrence may be linked with the onset of embryonic transcription. In addition, the species-specific ultrastructural features of the interchromatin structures of the 2-cell bovine embryo were displayed. Three different types of nuclear bodies were distinguished: (i) nucleolus precursor bodies (NPBs), (ii) loose bodies (LBs) and (iii) dense bodies (DBs). In order to determine their possible functional significance, we considered parallels between these three nuclear entities and interchromatin compartments reported in other cells. As detected by their preferential ribonucleoprotein staining, all types of nuclear bodies contained ribonucleoproteins. In contrast to the other types of nuclear bodies studied, NPBs contained argyrophilic proteins but in no case they did show morphological features of functional nucleoli. Both compact and vacuolated forms of NPBs were seen in both in vivo and in vitro embryos, sometimes simultaneously in the same nucleus. LBs and DBs reacted with antibodies to Sm antigen, indicating the presence of a group of nucleoplasmic, non-nucleolar small nuclear ribonucleoproteins (snRNPs). The immunoreactivity for Sm antigen was more intense and homogeneous in DBs than in LBs. DBs were seen in both categories of embryo. A possible kinship of DBs with the sphere organelle known from oocytes of different animal species or the prominent spherical inclusions of the early mouse embryo nuclei is suggested. The last type of intranuclear body, the LBs, showed a composite structure. Their granular component, occurring in clusters and displaying immunoreactivity for Sm antigen, was similar to interchromatin granules and was therefore named IG-like granules. Another component forming the LBs showed a much finer structure and a lower immunoreactivity with anti-Sm antibodies. We suggest that this amorphous component may be related to the IG-associated zone. All three types of intranuclear bodies were often seen close together, suggesting their possible mutual functional relationship. From these and other observations we conclude that the intranuclear bodies in 2-cell bovine embryos correspond, with the exception of the NPB, to similar structures/compartments supposed to accumulate inactive spliceosomal components in certain phases of somatic cell nucleus functions. Accordingly, the occurrence of such nuclear bodies does not represent cytological evidence for RNA synthesis. In contrast to this, an important morphological feature revealing the status of the bovine 2-cell embryo is the vacuolisation of the NPB.

Transcriptionally repressed germ cells lack a subpopulation of phosphorylated RNA polymerase II in early embryos of Caenorhabditis elegans and Drosophila melanogaster.

Early embryonic germ cells in C. elegans and D. melanogaster fail to express many messenger RNAs expressed in somatic cells. In contrast, we find that ribosomal RNAs are expressed in both cell types. We show that this deficiency in mRNA production correlates with the absence of a specific phosphoepitope on the carboxy-terminal domain of RNA polymerase II. In both C. elegans and Drosophila embryos, this phosphoepitope appears in somatic nuclei coincident with the onset of embryonic transcription, but remains absent from germ cells until these cells associate with the gut primordium during gastrulation. In contrast, a second distinct RNA polymerase II phosphoepitope is present continuously in both somatic and germ cells. The germ-line-specific factor PIE-1 is required to block mRNA production in the germ lineage of early C. elegans embryos (Seydoux, G., Mello, C. C., Pettitt, J., Wood, W. B., Priess, J. R. and Fire, A. (1996) Nature 382, 713-716). We show here that PIE-1 is also required for the germ-line-specific pattern of RNA polymerase II phosphorylation. These observations link inhibition of mRNA production in embryonic germ cells to a specific modification in the phosphorylation pattern of RNA polymerase II and suggest that repression of RNA polymerase II activity may be part of an evolutionarily conserved mechanism that distinguishes germ line from soma during early embryogenesis. In addition, these studies also suggest that different phosphorylated isoforms of RNA polymerase II perform distinct functions.

Onset of transcription in Patella vulgata coincides with cell cycle elongation and expression of tubulin genes.

In this study we show that the onset of embryonic transcription in the marine snail Patella vulgata coincides with the start of the sixth cleavage, when the cell-cycle elongates and divisions become asynchronous. Changes in mRNA content before and after onset of transcription were initially demonstrated by in vitro translation of isolated mRNA from different stages. Before the sixth cleavage, three major mRNAs encoding proteins of 36, 50 and 52 kDa were present. These proteins probably correspond to cyclin A and B and ribonucleotide reductase. After this stage, three major proteins with molecular weights of 36.5, 52.5 and 53 kDa were found after in vitro translation. Via hybrid selected translation and differential screening cDNAs corresponding to the 52.5 and 53 kDa proteins were cloned. The encoded proteins resemble tubulins from other animals to a high extent (between 96.5 and 93.1% identity for α-tubulin and 97.9 and 75.9% for β-tubulin). The 36.5 kDa protein is the previously described actin. Both tubulins were expressed at or shortly after the first asynchronous division after the fifth cleavage.

The in‐vitro block to development and initiation of transcription in early equine embryos

SummaryCoculture of early cleavage‐stage equine embryos with other cell types, primarily oviductal epithelial cells, can support development to blastocysts in vitro. Embryos cultured in complex medium without cellular support develop at a significantly poorer rate and appear to undergo a developmental block in vitro.In 2 experiments, 1–8‐cell embryos (n = 15) were cultured in Ham's F12: Dulbecco's MEM for 5 days or until morphological degeneration occurred. Embryos were assessed for stage of development and quality score on a daily basis. At the end of culture, embryos were stained to determine the number of nuclei present or were fixed and sectioned for evaluation by light microscopy. Additional embryos (n = 8) collected on Days 2–7 after ovulation were labelled with [3H]uridine and incorporation was determined by autoradiography.Of 15 embryos cultured without cellular support, 3 reached the morula stage and the remaining 12 embryos cleaved to the 8–16‐cell stage before undergoing morphological degeneration. [3H]uridine was incorporated into embryos at the 8‐cell stage or later, but no incorporation was detected in embryos at the 4‐cell stage. These results indicate that early equine embryos appear to undergo a developmental block in vitro at the 8–16‐cell stage, relief of which is temporally associated with the onset of embryonic transcription.

The Etl-1 gene encodes a nuclear protein differentially expressed during early mouse development.

Recently, we isolated a novel mouse gene, Etl-1 (Enhancer-trap-locus-1), whose deduced amino acid sequence shows in its C-terminal portion striking homology to the brahma protein (BRM), a transcriptional regulator of homeotic genes in Drosophila, and to SNF2/SWI2, a transcriptional regulator of various genes in Saccharomyces cerevisiae. Here we report the generation of antibodies against the Etl-1 gene product (ETL-1) and describe the subcellular localization as well as the expression and distribution of the ETL-1 protein during mouse pre- and early post-implantation development. ETL-1 is a nuclear protein and is expressed in a biphasic manner during early embryogenesis. Moderate levels of ETL-1 were detected in unfertilized and fertilized eggs but in the latter the protein was not concentrated in the pronuclei and seemed evenly distributed throughout the cytoplasm. In two-cell embryos nuclear ETL-1 protein accumulated transiently and levels decreased during subsequent cleavage development. After the morula stage, ETL-1 levels increased again; in blastocysts high levels of ETL-1 were present in inner cell mass cells whereas trophectoderm cells contained little or no ETL-1. During subsequent development essentially all cell types except parietal endoderm and trophoblast cells contained high levels of ETL-1. Our results imply that nuclear ETL-1 is dispensable for the progression to the two cell stage, and suggest that during cleavage ETL-1 might be needed at the onset of embryonic transcription. In blastocysts ETL-1 function might be specifically required in cells of the inner cell mass and later in most cells of the embryo proper and extraembryonic ectoderm lineage.

Mobilization of specific maternal RNA species into polysomes after fertilization in Xenopus laevis.

Unfertilized eggs of many species contain large amounts of maternal mRNA that are used to support protein synthesis during the first few hours of development, before the onset of embryonic transcription. We have examined the accumulation of nonpolysomal maternal RNAs in polysomes after fertilization in Xenopus laevis by measuring the distributions of specific sequences in nonpolysomal and polysomal fractions. In an arbitrary selection of 18 maternal sequences that are largely nonpolysomal in the full-grown oocyte, 13 became enriched in polysomes by the 16-cell cleavage stage. One sequence accumulated only 50% in polysomes at this time, while four sequences became polysomal later than the 16-cell stage. Several RNA sequences decreased in titer during early embryogenesis and were rare during organogenesis. Sequences that are mobilized rapidly and efficiently into polysomes shortly after fertilization and whose cellular concentrations are highest in embryos before organogenesis may provide genetic information for developmental functions restricted to very early embryogenesis. These experiments serve to identify such sequences in Xenopus.