A factor in sea urchin eggs inhibits transcription in isolated nuclei by sea urchin RNA polymerase III

Isolated nuclei from sea urchin embryos synthesize RNA at a rate comparable to other animal cell nuclei. All three RNA polymerases are active as judged by alpha-amanitin sensitivity and hybridization to specific cloned DNAs. Extracts were prepared from sea urchin eggs and embryos by extraction with 0.35 M KCl. None of the crude extracts had a large effect on total RNA synthesis. However, extracts from sea urchin eggs inhibited RNA polymerase III activity in nuclei from blastula and gastrula embryos. There was no effect on the synthesis of ribosomal RNA by RNA polymerase I or on the synthesis of two RNA polymerase II products, histone mRNA and the sea urchin analogue of U1 RNA. The inhibitor is present in two different species of sea urchin and has been 50-fold purified by diethylaminoethylcellulose and hydroxylapatite chromatography. The inhibitor is not present in extracts prepared from sea urchin blastula embryos.     

Isolation and characterization of developmentally regulated sea urchin U2 snRNA genes

Genes encoding the U2 snRNA have been isolated from the sea urchins, Strongylocentrotus purpuratus and Lytechinus variegatus. Representatives of tandemly repeated gene sets have been isolated from both sea urchin species and a unique U2 gene has also been isolated from L. variegatus. The sequence of the U2 snRNA encoded by the tandemly repeated genes differs in two nucleotides between S. purpuratus and L. variegatus. The unique U2 gene from L. variegatus encodes the same U2 RNA as the tandemly repeated genes. There is a change in the U2 genes expressed between morula and pluteus embryos as judged by a change in the U2 RNA sequence in S. purpuratus embryos. The tandemly repeated genes were expressed at a higher rate in blastula than in gastrula stage relative to the single-copy gene, when the two genes were injected into sea urchin zygotes.     

12S and 9S RNA species. Localization and fate during development of Strongylocentrotus purpuratus eggs

Polyacrylamide gel electrophoresis of total RNA obtained from Strongylocentrotus purpuratus eggs and embryos have shown this material to contain a 12S and 9S RNA species, among others. These two species, found during early development of these cells, were not present in late prism or plutei stages. The RNA was extracted by cold phenol deproteinization in the presence of bentonite and precipitated by alcohol. RNAse, obtained from the 140 000 g egg-supernatant was tested against total RNA extracted from unfertilized eggs, blastulae, gastrulae and plutei embryos. The amount of nucleotides liberated was identical in all cases. Egg-RNAse, in the presence of plutei RNA, did not give rise to the 12S and 9S RNA species.     

Nuclear transport of U1 snRNP in somatic cells: differences in signal requirement compared with Xenopus laevis oocytes

The signal requirement for the nuclear import of U1 RNA in somatic cells from different species was investigated by microinjection of both digoxygenin-labeled wild type and mutant U1 RNA molecules and in vitro reconstituted U1 snRNPs. U1 RNA was shown to be targeted to the nucleus by a temperature-dependent process that requires the prior assembly of RNPs from the common proteins and the microinjected RNA. Competition in the cell between immunoaffinity-purified U1 snRNPs and digoxygenin- labeled U1 snRNPs reconstituted in vitro showed that the transport is saturable and should therefore be a mediated process. The transport of a karyophilic protein under the same conditions was not affected, indicating the existence of a U snRNP-specific transport pathway in somatic cells, as already seen in the Xenopus laevis oocyte system. Surprisingly, the signal requirement for nuclear transport of U1 snRNP was found to differ between oocytes and somatic cells from mouse, monkey and Xenopus, in that the m3GGpppG-cap is no longer an essential signaling component in somatic cells. However, as shown by investigation of the transport kinetics of m3GpppG- and ApppG-capped U1 snRNPs, the m3GpppG-cap accelerates the rate of U1 snRNP import significantly indicating that it has retained a signaling role for nuclear targeting of U1 snRNP in somatic cells. Moreover, our data strongly suggest that cell specific rather than species specific differences account for the differential m3G-cap requirement in nuclear import of U1 snRNPs.     

Oligo(U) sequences present in sea urchin maternal RNA decrease following fertilization

Oligo(U) tracts were identified and measured in RNA from sea urchin eggs and embryos using a quantitative assay based on the amount of [3H]poly(A) protected from RNase T2 in duplexes with the oligo(U). The oligo(U) amounted to 0.0035% of egg RNA (0.063 X 10(-12) g/egg) and decreased to 0.0015% (0.027 X 10(-12) g/embryo) by 2 hr after fertilization. The oligo(U) tracts had a maximum size of 15-30 nucleotides and were associated with two size classes of RNA. In eggs about half were in 100 to 200 nucleotide RNA and half in mRNA-sized molecules. After fertilization, the oligo(U) in the population of large-mRNA-sized molecules was greatly reduced.     

Localization of actin messenger RNA during early ascidian development

The spatial distribution of RNA sequences during early development of the ascidian, Styela plicata, was determined by in situ hybridization with poly(U) and cloned DNA probes. Styela eggs and embryos contain three colored cytoplasmic regions of specific morphogenetic fates, the ectoplasm, endoplasm, and myoplasm. These cytoplasmic regions participate in ooplasmic segregation after fertilization and are distributed to different cell lineages during early embryogenesis. n situ hybridization with poly(U) suggests that poly(A)+RNA is unevenly distributed in eggs and embryos, with about 45% in the ectoplasm, 50% in the endoplasm, and only 5% in the myoplasm. In situ hybridization with a histone DNA probe showed that histone RNA sequences were not localized in eggs or embryos and distributed between the three cytoplasmic regions according to their volumes. In situ hybridization with an actin DNA probe showed actin RNA was localized in the myoplasm and ectoplasm of eggs and embryos with about 45% present in the myoplasm, 40% in the ectoplasm, and only 15% in the endoplasm. These results suggest that a large proportion of the egg actin mRNA is localized in the myoplasm, participates in ooplasmic segregation after fertilization, and is differentially distributed to the mesodermal cell lineages during embryogenesis. Analysis of the translation products of egg mRNA suggests that the localized mRNA codes for a cytoplasmic actin isoform.     

Cytoskeleton of the mouse egg and embryo: reorganization of planar elements

Examination of detergent-extracted mouse eggs and embryos reveals the existence of two cytoskeletal networks. One network is the typical thin filament network observed in somatic cells while the other is composed of large planar elements. These latter cytoskeletal structures, with individual widths of 60.0 +/- 6.8 nm, alter their spatial organization in a developmental stage-specific manner. The planar elements are composed of filaments with a diameter of 10 nm aligned side-by-side with these filaments exhibiting a linear periodicity of 20.0 +/- 1.6 nm. A biochemical fraction containing components of the planar elements has been prepared from different stages of development and disappearance of prominent polypeptides from this fraction correlates with the altered spatial organization of the planar elements. Ultrastructure and biochemistry of cytoskeletal planar elements in eggs and embryos of the mouse are comparable with cytoskeletal sheets of Syrian hamster eggs and embryos, suggesting these cytoskeletal components may have a functional role in mammalian embryogenesis. Because such structures have not been identified in eggs or embryos of species other than mammals, their function may be unique to mammalian embryogenesis.     

Plant small nuclear RNAs. Nucleolar U3 snRNA is present in plants: partial characterization

Nuclei, isolated from a number of plant species by either of two independent, newly developed methods, regularly contained a common set of low-molecular-mass RNAs. Partial characterization of these RNAs, based on cell fractionation, polyacrylamide gel electrophoretic and chemical sequencing techniques, as well as comparison with literature data, revealed that, in addition to tRNA, 5S RNA and 5.8S RNA, plant nuclei contain two families of low-molecular-mass RNAs, that are counterparts of vertebrate U1 and U5 RNAs respectively, and three individual low-molecular-mass RNA species. One of these may be related to vertebrate U6 RNA. The two others are true eukaryotic U2 and U3 RNAs, respectively, on the basis of the following lines of evidence obtained from analyses of broad bean nuclear RNAs. The 3'-end portion (121 nucleotides sequenced) of broad bean U2 RNA shows a nearly perfect sequence homology with that of authentic pea U2 RNA. Broad bean U3 RNA is localized in the nucleolus and its 3'-end portion (164 nucleotides sequenced) (a) shows sequence homology with that of both rat U3 RNA (48%) and Dictyostelium D2 RNA (39%), (b) has a secondary structure which fits perfectly that proposed for both rat U3 RNA and Dictyostelium D2 RNA, and (c) contains the specific sequence which, in a model based on the primary structure of rat U3 RNA, is supposed to be involved in the processing of eukaryotic 32S pre-ribosomal RNA. This is the first report on the occurrence in plants of nucleolar U3 RNA.     

A family of wheat embryo U2 snRNAs

Summary Evidence is presented for the existence of small nuclear RNAs in a higher plant species. Based on subcellular fractionation experiments, wheat embryos contain at least four putative snRNAs, one of which co-migrates on SDS-polyacrylamide gels with a relatively abundant cytoplasmic RNA, W1. We purified W1 from ribosome-free high speed supernatant fractions for characterization studies. Electrophoresis under partially denaturing conditions resolves this RNA into several components which bear m ₃ ^{2, 2, 7} G-5′ caps and strongly resemble vertebrate U2 snRNA on the basis of modified nucleotide content. Preliminary sequence analyses indicate that wheat embryos contain at least three U2-like RNAs which possess slightly different sequences near their 3′ ends.