Small nuclear RNA transcription and ribonucleoprotein assembly in early Xenopus development

Inventory of European Sea Bass (Dicentrarchus labrax) sncRNAs Vital During Early Teleost Development

During early animal ontogenesis, a plethora of small non-coding RNAs (sncRNAs) are greatly expressed and have been shown to be involved in several regulatory pathways vital to proper development. The rapid advancements in sequencing and computing methodologies in the last decade have paved the way for the production of sequencing data in a broad range of organisms, including teleost species. Consequently, this has led to the discovery of sncRNAs as well as the potentially novel roles of sncRNA in gene regulation. Among the several classes of sncRNAs, microRNAs (miRNAs) have, in particular, been shown to play a key role in development. The present work aims to identify the miRNAs that play important roles during early European sea bass (Dicentrarchus labrax) development. The European sea bass is a species of high commercial impact in European and especially Mediterranean aquaculture. This study reports, for the first time, the identification and characterization of small RNAs that play a part in the 10 developmental stages (from morula to all fins) of the European sea bass. From 10 developmental stages, more than 135 million reads, generated by next-generation sequencing, were retrieved from publicly available databases as well as newly generated. The analysis resulted in about 2,000 sample grouped reads, and their subsequently annotation revealed that the majority of transcripts belonged to the class of miRNAs followed by small nuclear RNAs and small nucleolar RNAs. The analysis of small RNA expression among the developmental stages under study revealed that miRNAs are active throughout development, with the main activity occurring after the earlier stages (morula and 50% epiboly) and at the later stages (first feeding, flexion, and all fins). Furthermore, investigating miRNAs exclusively expressed in one of the stages unraveled five miRNAs with a higher abundance only in the morula stage (miR-155, miR-430a, d1, d2, and miR-458), indicating possible important key roles of those miRNAs in further embryonic development. An additional target search showed putative miRNA-mRNA interactions with possible direct and indirect regulatory functions of the identified miRNAs.

The translational regulation of maternal mRNAs in time and space

Since their discovery, the study of maternal mRNAs has led to the identification of mechanisms underlying their spatiotemporal regulation within the context of oogenesis and early embryogenesis. Following synthesis in the oocyte, maternal mRNAs are translationally silenced and sequestered into storage in cytoplasmic granules. At the same time, their unique distribution patterns throughout the oocyte and embryo are tightly controlled and connected to their functions in downstream embryonic processes. At certain points in oogenesis and early embryogenesis, maternal mRNAs are translationally activated to perform their functions in a timely manner. The cytoplasmic polyadenylation machinery is responsible for the translational activation of maternal mRNAs, and its role in initiating the maternal to zygotic transition events has recently come to light. Here, we summarize the current knowledge on maternal mRNA regulation, with particular focus on cytoplasmic polyadenylation as a mechanism for translational regulation.

Genome-wide analysis reveals conserved transcriptional responses downstream of resting potential change in Xenopus embryos, axolotl regeneration, and human mesenchymal cell differentiation

Endogenous bioelectric signaling via changes in cellular resting potential (V_mem) is a key regulator of patterning during regeneration and embryogenesis in numerous model systems. Depolarization of V_mem has been functionally implicated in dedifferentiation, tumorigenesis, anatomical re‐specification, and appendage regeneration. However, no unbiased analyses have been performed to understand genome‐wide transcriptional responses to V_mem change in vivo. Moreover, it is unknown which genes or gene networks represent conserved targets of bioelectrical signaling across different patterning contexts and species. Here, we use microarray analysis to comparatively analyze transcriptional responses to V_mem depolarization. We compare the response of the transcriptome during embryogenesis (Xenopus development), regeneration (axolotl regeneration), and stem cell differentiation (human mesenchymal stem cells in culture) to identify common networks across model species that are associated with depolarization. Both subnetwork enrichment and PANTHER analyses identified a number of key genetic modules as targets of V_mem change, and also revealed important (well‐conserved) commonalities in bioelectric signal transduction, despite highly diverse experimental contexts and species. Depolarization regulates specific transcriptional networks across all three germ layers (ectoderm, mesoderm, and endoderm) such as cell differentiation and apoptosis, and this information will be used for developing mechanistic models of bioelectric regulation of patterning. Moreover, our analysis reveals that V_mem change regulates transcripts related to important disease pathways such as cancer and neurodegeneration, which may represent novel targets for emerging electroceutical therapies.

Dynamic control of Cajal body number during zebrafish embryogenesis

The Cajal body (CB) is an evolutionarily conserved nuclear subcompartment, enriched in components of the RNA processing machinery. The composition and dynamics of CBs in cells of living organisms is not well understood. Here we establish the zebrafish embryo as a model system to investigate the properties of CBs during rapid growth and cell division, taking advantage of the ease of live-cell imaging. We show that zebrafish embryo CBs contain coilin and multiple components of the pre-mRNA splicing machinery. Histone mRNA 3' end processing factors, present in CBs in some systems, were instead concentrated in a distinct nuclear body. CBs were present in embryos before and after activation of zygotic gene expression, indicating a maternal contribution of CB components. During the first 24 hours of development, embryonic cells displayed up to 30 CBs per nucleus; these dispersed prior to mitosis and reassembled within minutes upon daughter cell nucleus formation. Following zygotic genome activation, snRNP biogenesis was required for CB assembly and maintenance, suggesting a self-assembly process that determines CB numbers in embryos. Differentiation into muscle, neurons and epidermis was associated with the achievement of a steady state number of 2 CBs per nucleus. We propose that CB number is regulated during development to respond to the demands of gene expression in a rapidly growing embryo.

A subset of Drosophila integrator proteins is essential for efficient U7 snRNA and spliceosomal snRNA 3'-end formation

Proper gene expression relies on a class of ubiquitously expressed, uridine-rich small nuclear RNAs (snRNAs) transcribed by RNA polymerase II (RNAPII). Vertebrate snRNAs are transcribed from a unique promoter, which is required for proper 3'-end formation, and cleavage of the nascent transcript involves the activity of a poorly understood set of proteins called the Integrator complex. To examine 3'-end formation in Drosophila melanogaster, we developed a cell-based reporter that monitors aberrant 3'-end formation of snRNA through the gain in expression of green fluorescent protein (GFP). We used this reporter in Drosophila S2 cells to determine requirements for U7 snRNA 3'-end formation and found that processing was strongly dependent upon nucleotides located within the 3' stem-loop as well as sequences likely to comprise the Drosophila equivalent of the vertebrate 3' box. Substitution of the actin promoter for the snRNA promoter abolished proper 3'-end formation, demonstrating the conserved requirement for an snRNA promoter in Drosophila. We tested the requirement for all Drosophila Integrator subunits and found that Integrators 1, 4, 9, and 11 were essential for 3'-end formation and that Integrators 3 and 10 may be dispensable for processing. Depletion of cleavage and polyadenylation factors or of histone pre-mRNA processing factors did not affect U7 snRNA processing efficiency, demonstrating that the Integrator complex does not share components with the mRNA 3'-end processing machinery. Finally, flies harboring mutations in either Integrator 4 or 7 fail to complete development and accumulate significant levels of misprocessed snRNA in the larval stages.

Pre-mRNA splicing in the nuclei of Xenopus oocytes

Xenopus oocytes have been utilized in a number of laboratories as an experimental system to study a variety of biological processes. Here, we describe its application to functional studies of spliceosomal small nuclear RNAs (snRNAs) in pre-messenger RNA (pre-mRNA) splicing, a process that occurs extremely efficiently in Xenopus oocytes. A DNA oligonucleotide complementary to an snRNA of interest is injected into the oocyte cytoplasm. The oligonucleotide subsequently diffuses into the nucleus and hybridizes to the target snRNA, thereby triggering snRNA degradation via endogenous RNase H activity. By the time the endogenous snRNA is depleted, the DNA oligonucleotide itself is degraded by endogenous deoxyribonuclease (DNase) activity. In principle, this procedure enables one to quantitatively deplete any snRNA of choice. Subsequently, a rescuing snRNA that is constructed in vitro may be injected into the snRNA-depleted oocytes to restore the splicing function. After reconstitution, a radiolabeled splicing substrate is injected into the nuclei of the oocytes. These oocyte nuclei are then manually isolated and used to prepare both nuclear RNA for splicing assays and nuclear extract for spliceosome assembly assays. The ability of an injected rescuing snRNA to reconstitute splicing can therefore be tested. Because all types of rescuing snRNAs (e.g., mutant snRNAs, snRNAs with or without modified nucleotides) can be constructed readily, the results obtained from this procedure provide valuable information on the function of a particular snRNA of interest in pre-mRNA splicing.

Assembly and breakdown of Cajal bodies in accessory nuclei of Hymenoptera

In some species of insects, oocytes have vesicular organelles, termed accessory nuclei (ANs). The ANs form by budding off from the nuclear envelope of the oocyte and are filled with translucent matrix containing dense inclusions. One type of these inclusions contains coilin and small nuclear ribonucleoproteins (snRNPs) and is homologous to Cajal bodies. We describe the early events in the morphogenesis of Cajal bodies in the ANs (ANCBs) of the common wasp, Vespula germanica, and show that they contain survival of motor neurons (SMN) protein. We present evidence that in the wasp, ANCBs form by the gradual accumulation of aggregates composed of SMN and small nuclear RNAs. We also show that ANCBs break down and disperse within the ANs as the ANs, which initially surround the oocyte nucleus, localize to the oocyte cortex. The components of dispersed ANCBs are retained within ANs until the end of oogenesis, which suggests that their function may be required at the onset of embryonic development. Because the morphology and behavior of ANs and their Cajal body-like inclusions are conserved in two other hymenopteran species, these features might be characteristic of all hymenopterans.

The stem-loop binding protein (SLBP1) is present in coiled bodies of the Xenopus germinal vesicle

The stem-loop binding protein (SLBP1) binds the 3' stem-loop of histone pre-mRNA and is required for efficient processing of histone transcripts in the nucleus. We examined the localization of SLBP1 in the germinal vesicle of Xenopus laevis oocytes. In spread preparations of germinal vesicle contents, an anti-SLBP1 antibody stained coiled bodies and specific chromosomal loci, including terminal granules, axial granules, and some loops. After injection of myc-tagged SLBP1 transcripts into the oocyte cytoplasm, newly translated myc-SLBP1 protein was detectable in coiled bodies within 4 h and in terminal and axial granules by 8 h. To identify the region(s) of SLBP1 necessary for subnuclear localization, we subcloned various parts of the SLBP1 cDNA and injected transcripts of these into the cytoplasm of oocytes. We determined that 113 amino acids at the carboxy terminus of SLBP1 are sufficient for coiled body localization and that disruption of a previously defined RNA-binding domain did not alter this localization. Coiled bodies also contain the U7 small nuclear ribonucleoprotein particle (snRNP), which participates in cleavage of the 3' end of histone pre-mRNA. The colocalization of SLBP1 and the U7 snRNP in the coiled body suggests coordinated control of their functions, perhaps through a larger histone-processing particle. Some coiled bodies are attached to the lampbrush chromosomes at the histone gene loci, consistent with the view that coiled bodies in the oocyte recruit histone-processing factors to the sites of histone pre-mRNA transcription. The non-histone chromosomal sites at which SLBP1 is found include the genes coding for 5 S rRNA, U1 snRNA, and U2 snRNA, suggesting a wider role for SLBP1 in the biosynthesis of small non-spliced RNAs.

Coilin can form a complex with the U7 small nuclear ribonucleoprotein

Coiled bodies (CBs) in the amphibian oocyte nucleus are spherical structures up to 10 microm or more in diameter, much larger than their somatic counterparts, which rarely exceed 1 microm. Oocyte CBs may have smaller granules attached to their surface or embedded within them, which are identical in structure and composition to the many hundreds of B-snurposomes found free in the nucleoplasm. The matrix of the CBs contains the diagnostic protein p80-coilin, which is colocalized with the U7 small nuclear ribonucleoprotein (snRNP), whereas the attached and embedded B-snurposomes contain splicing snRNPs. A few of the 50-100 CBs in the oocyte nucleus are attached to lampbrush chromosomes at the histone gene loci. By coimmunoprecipitation we show that coilin and the U7 snRNP can form a weak but specific complex in the nucleoplasm, which is dependent on the special U7 Sm-binding site. Under the same conditions coilin does not associate with the U1 and U2 snRNPs. Coilin is a nucleic acid-binding protein, as shown by its interaction with single-stranded DNA and with poly r(U) and poly r(G). We suggest that an important function of coilin is to form a transient complex with the U7 snRNP and accompany it to the CBs. In the case of CBs attached to chromosomes at the histone gene loci, the U7 snRNP is thus brought close to the actual site of histone pre-mRNA transcription.

Coiled bodies without coilin

Nuclei assembled in vitro in Xenopus egg extract contain coiled bodies that have components from three different RNA processing pathways: pre-mRNA splicing, pre-rRNA processing, and histone pre-mRNA 3'-end formation. In addition, they contain SPH-1, the Xenopus homologue of p80-coilin, a protein characteristic of coiled bodies. To determine whether coilin is an essential structural component of the coiled body, we removed it from the egg extract by immunoprecipitation. We showed that nuclei with bodies morphologically identical to coiled bodies (at the light microscope level) formed in such coilin-depleted extract. As expected, these bodies did not stain with antibodies against coilin. Moreover, they failed to stain with an antibody against the Sm proteins, although Sm proteins associated with snRNAs were still present in the extract. Staining of the coilin- and Sm-depleted coiled bodies was normal with antibodies against two nucleolar proteins, fibrillarin and nucleolin. Similar results were observed when Sm proteins were depleted from egg extract: staining of the coiled bodies with antibodies against the Sm proteins and coilin was markedly reduced but bright nucleolin and fibrillarin staining remained. These immunodepletion experiments demonstrate an interdependence between coilin and Sm snRNPs and suggest that neither is essential for assembly of nucleolar components in coiled bodies. We propose that coiled bodies are structurally heterogeneous organelles in which the components of the three RNA processing pathways may occur in separate compartments.

Structurally related but functionally distinct yeast Sm D core small nuclear ribonucleoprotein particle proteins

Spliceosome assembly during pre-mRNA splicing requires the correct positioning of the U1, U2, U4/U6, and U5 small nuclear ribonucleoprotein particles (snRNPs) on the precursor mRNA. The structure and integrity of these snRNPs are maintained in part by the association of the snRNAs with core snRNP (Sm) proteins. The Sm proteins also play a pivotal role in metazoan snRNP biogenesis. We have characterized a Saccharomyces cerevisiae gene, SMD3, that encodes the core snRNP protein Smd3. The Smd3 protein is required for pre-mRNA splicing in vivo. Depletion of this protein from yeast cells affects the levels of U snRNAs and their cap modification, indicating that Smd3 is required for snRNP biogenesis. Smd3 is structurally and functionally distinct from the previously described yeast core polypeptide Smd1. Although Smd3 and Smd1 are both associated with the spliceosomal snRNPs, overexpression of one cannot compensate for the loss of the other. Thus, these two proteins have distinct functions. A pool of Smd3 exists in the yeast cytoplasm. This is consistent with the possibility that snRNP assembly in S. cerevisiae, as in metazoans, is initiated in the cytoplasm from a pool of RNA-free core snRNP protein complexes.

Is the sphere organelle/coiled body a universal nuclear component?

We present evidence for the essential homology of four nuclear organelles that have previously been described under four different names: coiled bodies in mammalian somatic nuclei, prenucleolar bodies in nuclei assembled in vitro in Xenopus egg extract, sphere organelles in amphibian germinal vesicles (GVs), and Binnenkörper in insect GVs. Each of these organelles contains coilin or a coilin-related protein plus a variety of small nuclear ribonucleoproteins. We suggest that the sphere organelle/coiled body is a "universal" nuclear component in the sense that it is involved in common nuclear processes and hence will be found in one form or another in most eukaryotic cells. We postulate that it functions in the assembly and sorting of snRNP complexes for three RNA processing pathways: pre-mRNA splicing, rRNA processing, and histone pre-mRNA 3' end formation. Specifically, the sphere organelle/coiled body may be the initial site for assembly of processing complexes, which are then sorted to other places in the nucleus, where the actual RNA processing takes place.

In vitro assembly of coiled bodies in Xenopus egg extract

When demembranated sperm nuclei are placed in a Xenopus egg extract, they become surrounded by a nuclear envelope and then swell to form morphologically typical pronuclei. Granules ranging from < 1.0 to approximately 3.0 microns in diameter appear within such nuclei. Bell et al. identified four nucleolar proteins in these "prenucleolar bodies" by immunofluorescent staining (fibrillarin, nucleolin, B23/NO38, 180-kDa nucleolar protein). By in situ hybridization we show that these bodies also contain U3 and U8 small nuclear RNAs (snRNAs), known to be involved in pre-rRNA processing. Moreover, they contain all the snRNAs involved in pre-mRNA splicing (U1, U2, U4, U5, and U6), as well as U7, which is required for histone pre-mRNA 3' end formation. In addition to the nucleolar antigens previously identified, we demonstrated staining with antibodies against the Sm epitope, trimethylguanosine, and coilin. Because the composition of these prenucleolar bodies is closer to that of coiled bodies than to nucleoli, we propose that they be referred to as coiled bodies. The existence of large coiled bodies in transcriptionally inactive pronuclei suggests that they may play a role in the import, assembly, and storage of RNA processing components but are not themselves sites of processing. In transcriptionally active nuclei coiled bodies could serve as sites for initial preassembly and distribution of snRNP complexes for the three major RNA processing pathways: pre-mRNA splicing, pre-rRNA processing, and histone pre-mRNA 3' end formation.

The zebrafish midblastula transition

The zebrafish midblastula transition (MBT) begins at cycle 10. It is characterized by cell cycle lengthening, loss of cell synchrony, activation of transcription and appearance of cell motility. Superceding a 15 minute oscillator that controls the first nine cycles, the nucleocytoplasmic ratio appears to govern the MBT. This timing mechanism operates cell autonomously: clones of labeled cells initiate cell cycle lengthening independently of neighbors but dependent on immediate lineal ancestors. Unequal divisions, when they occur, produce asymmetric cell cycle lengthening based on the volume of each daughter. During the several cycles after the MBT begins, cycle length is correlated with the reciprocal of the blastomere volume, suggesting a continuation of cell cycle regulation by the nucleocytoplasmic ratio during an interval that we term the ‘MBT period’.

Genes for Xenopus laevis U3 small nuclear RNA

Genomic Southern blots showed there are only 14 to 20 copies of U3 snRNA genes per somatic genome in Xenopus laevis, unlike the highly repetitive, tandem arrangement of other snRNA genes in this organism. Sequencing of two U3 snRNA genes from lambda clones of a genomic library revealed striking similarity upstream, but much more divergence downstream. Consensus motifs common to other U snRNA genes were also found: a distal sequence element (DSE, octamer motif at -222 to -215), a proximal sequence element (PSE, at -62 to -52) and a 3' Box (15 or 16 bp downstream of the U3 genes). The DSE of mammals also has an inverted CCAAT motif specific for U3 snRNA genes, and we find this is conserved in the amphibian U3 snRNA genes. The Xenopus inverted CCAAT motif is exactly one helical turn further upstream of the octamer motif than its mammalian counterpart, suggesting interaction of putative transcription factors bound to these motifs. Mutation of the inverted CCAAT motif and part of an adjacent Sp1 site greatly depresses transcription of the mutant U3 snRNA gene in Xenopus oocytes, implying a role in transcriptional efficiency. Electrophoretic mobility shift assays implicate transcription factor binding to this region.

Amphibian oocytes and sphere organelles: are the U snRNA genes amplified?

The sphere organelles (spheres) of Xenopus and other amphibian oocytes are known to contain small nuclear ribonucleoprotein particles (snRNPs) and have been suggested to play a role in snRNP complex assembly. Coupled with the similarities that exist between spheres and nucleoli and the quantitative and kinetic aspects of snRNA synthesis in the Xenopus oocyte, we have investigated whether or not the U snRNA encoding genes are amplified in Xenopus oogenesis, the spheres being possible sites for the location of such extrachromosomal gene copies. By applying a number of quantitative nucleic acid hybridization procedures to both total and fractionated oocyte and somatic DNA, employing both homologous and heterologous U snRNA gene probes and suitable amplification and non-amplification control probes, we show that the U snRNA genes do not undergo any major amplification in Xenopus oogenesis. Therefore, the analogy between the sphere organelles and nucleoli appears to be limited. The role of the spheres and their relationship to other snRNP containing structures, specifically B snurposomes, and the sphere organizer loci remains obscure.

Purification, primary structure, bacterial expression and subcellular distribution of an oocyte-specific protein in Xenopus

This study defines a novel Xenopus laevis protein (P100) that has recently been shown to be recognized by scleroderma patient sera. Using a combination of differential solubility in detergents, hydroxyapatite chromatography and one-dimensional PAGE, P100 was purified to apparent homogeneity and the amino acid sequence was obtained. An oligonucleotide derived from this sequence was used to clone P100 cDNA through a polymerase-chain-reaction cloning strategy. The entire P100 cDNA sequence was determined, identifying a novel 83,000-Da protein. Two alleles for P100 were transcribed in the oocyte, with only one predicted amino acid change between them. Bacterial expression of a clone containing the entire P100 coding region produced a protein that migrated at a mass 15% greater than that predicted from the amino acid sequence, indicating an aberrant electrophoretic mobility. The mRNA transcript for P100 was only expressed during the previtellogenic stages of oogenesis (stages I and II) and was absent from other Xenopus tissues. Similarly, the P100 protein was found only in Xenopus oocytes and was localized to the cytoplasm of these cells. P100 irreversibly bound single-stranded-DNA--cellulose but not double-stranded-DNA--cellulose. These data demonstrate the presence of a novel oocyte-specific protein in Xenopus.

Distinct molecular signals for nuclear import of the nucleolar snRNA, U3

Export to the cytoplasm of U3 RNA transcribed from a rat U3 gene injected into the nucleus of Xenopus oocytes indicates that the biogenesis of U3 RNA, like that of the previously studied Sm-precipitable nucleoplasmic snRNAs (U1, U2, U4, and U5), includes a cytoplasmic phase. The regulation of import of the U3 snRNA into the nucleus has been analyzed by injection of synthetic human U3 transcripts into the cytoplasm of Xenopus oocytes. Binding of the major autoantigenic protein of the U3 snRNP, fibrillarin, and cap trimethylation can occur in the cytoplasm, but neither are required for import. The 3'-terminal 13 nucleotides are required for optimal import and cap trimethylation and participate in a phylogenetically conserved U3 structural element, a short 3'-terminal stem. An artificial construct containing the 3'-terminal 13 nucleotides, including the 3'-terminal stem, but only 56 nucleotides of the 217 nucleotides in U3, appears to be sufficient for import. The presence of the 3'-terminal stem in all snRNAs known to be imported suggests that it might be a universal element required for nuclear import.

Control of 4-8S RNA transcription at the midblastula transition in Xenopus laevis embryos

Transcription of Xenopus laevis U1 snRNA genes is subject to a precise program with respect both to the timing of activation at the midblastula transition (MBT) and to the relative levels of the two embryonic U1 RNAs (xU1b1 and b2) that are made. Here, we demonstrate that exogenous xU1b genes injected into developing X. laevis embryos come under the same controls as the endogenous genes. Injected U1 genes, unlike exogenous RNA polymerase III genes, remain quiescent until MBT and their activation at MBT requires protein synthesis during the early cleavage stages. Significantly, the onset of 4-8S RNA transcription occurs at the normal time, even when the DNA content of the embryo has been increased by injection of exogenous DNA or reduced through cleavage arrest, indicating that transcriptional activation at MBT is independent of the ratio of DNA (nucleus) to cytoplasm. In cleavage-arrested (coenocytic) embryos, the reduced level of DNA at MBT results both in a decrease in snRNA and tRNA synthesis (reflecting the lower gene dosage) and in a prolonged synthesis of large amounts of unusual RNA polymerase III transcripts, OAX RNAs. In normally cleaving embryos, small amounts of these unstable OAX RNAs (encoded by satellite I DNA) are synthesized only briefly at MBT. Our demonstration that RNA and DNA metabolism is aberrant in cleavage-arrested embryos requires reevaluation of previous experiments on transcriptional activation that utilized such coenocytic embryos.

Analysis of a gene cluster coding for the Xenopus laevis U7 snRNA

A cluster of Xenopus laevis U7 snRNA genes has been isolated and sequenced. The gene structure is more compact than, but otherwise comparable to, the major U snRNA genes since the distal sequence element (DSE) is located only 4 nt upstream of the PSE. The corresponding RNA is present in the oocyte and accumulates early in oogenesis.

Nuclear processing of the 3'-terminal nucleotides of pre-U1 RNA in Xenopus laevis oocytes

U1 small nuclear RNA is synthesized as a precursor with several extra nucleotides at its 3' end. We show that in Xenopus laevis oocytes, removal of the terminal two nucleotides occurs after the RNA has transited through the cytoplasm and returned to the nucleus. The activity is controlled by an inhibitor of processing, which we call TPI, for 3'-terminal processing inhibitor. This inhibitor is sensitive to both micrococcal nuclease and trypsin treatment, indicating that it is a nucleoprotein. TPI inhibits the 3' processing of pre-U1 RNAs that have 5' ends containing m7G caps but not mature m2,2,7G caps; this finding suggests that TPI interacts directly or indirectly with the 5' end of pre-U1 RNA. The inhibition of processing by TPI, almost complete at 19 degrees C, is reversibly inactivated at slightly higher temperatures. TPI activity is solely in the soluble fraction of oocyte nuclear extracts, in contrast to the 3'-terminal processing activity, which is present in both the particulate and soluble fractions. We propose that the differential processing of the 3'-terminal nucleotides of pre-U1 RNA after its return from the cytoplasm, but not before its exit from the nucleus, may be due to the association of TPI with the m7G cap on the newly synthesized pre-U1 RNA.

Nuclear processing of the 3'-terminal nucleotides of pre-U1 RNA in Xenopus laevis oocytes

U1 small nuclear RNA is synthesized as a precursor with several extra nucleotides at its 3' end. We show that in Xenopus laevis oocytes, removal of the terminal two nucleotides occurs after the RNA has transited through the cytoplasm and returned to the nucleus. The activity is controlled by an inhibitor of processing, which we call TPI, for 3'-terminal processing inhibitor. This inhibitor is sensitive to both micrococcal nuclease and trypsin treatment, indicating that it is a nucleoprotein. TPI inhibits the 3' processing of pre-U1 RNAs that have 5' ends containing m7G caps but not mature m2,2,7G caps; this finding suggests that TPI interacts directly or indirectly with the 5' end of pre-U1 RNA. The inhibition of processing by TPI, almost complete at 19 degrees C, is reversibly inactivated at slightly higher temperatures. TPI activity is solely in the soluble fraction of oocyte nuclear extracts, in contrast to the 3'-terminal processing activity, which is present in both the particulate and soluble fractions. We propose that the differential processing of the 3'-terminal nucleotides of pre-U1 RNA after its return from the cytoplasm, but not before its exit from the nucleus, may be due to the association of TPI with the m7G cap on the newly synthesized pre-U1 RNA.

U2 small nuclear RNA localization and expression during bovine preimplantation development

This study describes the localization of the U2 small nuclear RNA (snRNA) and the major U snRNA group ribonucleoproteins (snRNPs) during bovine preimplantation development. In vitro maturation, fertilization, and oviductal epithelial cell coculture methods were employed to produce several developmental series totalling over 2,000 preimplantation-stage bovine oocytes and embryos. These oocytes and preimplantation embryos were processed for in situ hybridization, immunofluorescence and Northern blotting methods. The U2 snRNA and the major U group snRNPS were localized initially over the germinal vesicle (GV) of preovulatory oocytes but following GV breakdown were released throughout the ooplasm. They subsequently reassociated with both pronuclei during fertilization. From the two-cell to the blastocyst stages, the U2 snRNA and U snRNPs were localized to the interphase nucleus of each blastomere. The levels of U2 snRNA throughout bovine preimplantation development were determined by probing a Northern blot containing total RNA isolated from the following preimplantation bovine embryo stages: one to two cell, eight to 16 cell, early morula (greater than 32 cell), and late morula/early blastocysts. The levels of U2 snRNA remained constant between the one-cell and eight- to 16-cell bovine embryo stages but increased 4.4-fold between the eight- to 16-cell stage and the late morula/early blastocyst stages. The results suggest that a maternal pool of snRNAs is maintained in mammalian preimplantation embryos regardless of the duration of maternal control of development.

Small nuclear ribonucleoproteins and heterogeneous nuclear ribonucleoproteins in the amphibian germinal vesicle: loops, spheres, and snurposomes

We have examined the distribution of snRNPs in the germinal vesicle (GV) of frogs and salamanders by immunofluorescent staining and in situ nucleic acid hybridization. The major snRNAs involved in pre-mRNA splicing (U1, U2, U4, U5, and U6) occur together in nearly all loops of the lampbrush chromosomes, and in hundreds to thousands of small granules (1-4 microns diameter) suspended in the nucleoplasm. The loops and granules also contain several antigens that are regularly associated with snRNAs or spliceosomes (the Sm antigen, U1- and U2-specific antigens, and the splicing factor SC35). A second type of granule, often distinguishable by morphology, contains only U1 snRNA and associated antigens. We propose the term "snurposome" to describe the granules that contain snRNPs ("snurps"). Those that contain only U1 snRNA are A snurposomes, whereas those that contain all the splicing snRNAs are B snurposomes. GVs contain a third type of snRNP granule, which we call the C snurposome. C snurposomes range in size from less than 1 micron to giant structures greater than 20 microns in diameter. Usually, although not invariably, they have B snurposomes on their surface. They may also contain from one to hundreds of inclusions. Because of their remarkably spherical shape, C snurposomes with their associated B snurposomes have long been referred to as spheres or sphere organelles. Most spheres are free in the nucleoplasm, but a few are attached to chromosomes at specific chromosome loci, the sphere organizers (SOs). The relationship of sphere organelles to other snRNP-containing structures in the GV is obscure. We show by immunofluorescent staining that the lampbrush loops and B snurposomes also react with antibodies against heterogeneous nuclear ribonucleoproteins (hnRNPs). Transcription units on the loops are uniformly stained by anti-hnRNP and anti-snRNP antibodies, suggesting that nascent transcripts are associated with hnRNPs and snRNPs along their entire length, perhaps in the form of a unitary hnRNP/snRNP particle. That B snurposomes contain so many components involved in pre-mRNA packaging and processing suggests that they may serve as sites for assembly and storage of hnRNP/snRNP complexes destined for transport to the nascent transcripts on the lampbrush chromosome loops.

Nucleocytoplasmic transport and processing of small nuclear RNA precursors

We have analyzed the structures and locations of small nuclear RNA (snRNA) precursors at various stages in their synthesis and maturation. In the nuclei of pulse-labeled Xenopus laevis oocytes, we detected snRNAs that were longer than their mature forms at their 3' ends by up to 10 nucleotides. Analysis of the 5' caps of these RNAs and pulse-chase experiments showed that these nuclear snRNAs were precursors of the cytoplasmic pre-snRNAs that have been observed in the past. Synthesis of pre-snRNAs was not abolished by wheat germ agglutinin, which inhibits export of the pre-snRNAs from the nucleus, indicating that synthesis of these RNAs is not obligatorily coupled to their export. Newly synthesized U1 RNAs could be exported from the nucleus regardless of the length of the 3' extension, but pre-U1 RNAs that were elongated at their 3' ends by more than about 10 nucleotides were poor substrates for trimming in the cytoplasm. The structure at the 3' end was critical for subsequent transport of the RNA back to the nucleus. This requirement ensures that truncated and incompletely processed U1 RNAs are excluded from the nucleus.

Nucleocytoplasmic transport and processing of small nuclear RNA precursors

We have analyzed the structures and locations of small nuclear RNA (snRNA) precursors at various stages in their synthesis and maturation. In the nuclei of pulse-labeled Xenopus laevis oocytes, we detected snRNAs that were longer than their mature forms at their 3' ends by up to 10 nucleotides. Analysis of the 5' caps of these RNAs and pulse-chase experiments showed that these nuclear snRNAs were precursors of the cytoplasmic pre-snRNAs that have been observed in the past. Synthesis of pre-snRNAs was not abolished by wheat germ agglutinin, which inhibits export of the pre-snRNAs from the nucleus, indicating that synthesis of these RNAs is not obligatorily coupled to their export. Newly synthesized U1 RNAs could be exported from the nucleus regardless of the length of the 3' extension, but pre-U1 RNAs that were elongated at their 3' ends by more than about 10 nucleotides were poor substrates for trimming in the cytoplasm. The structure at the 3' end was critical for subsequent transport of the RNA back to the nucleus. This requirement ensures that truncated and incompletely processed U1 RNAs are excluded from the nucleus.

Changes in the patterns of RNA synthesis in early embryogenesis of Xenopus laevis

We analyzed the accumulation of newly-synthesized heterogeneous mRNA-like RNA, 4 S RNA, 5 S RNA, snRNAs and rRNA before and after the midblastula transition (MBT) in Xenopus laevis embryogenesis. Based on the kinetics of the labeling, we concluded that the pattern of RNA synthesis in Xenopus embryogenesis changes following at least three characteristically different phases. The first phase is the pre-MBT stage, which is characterized by the synthesis of heterogeneous mRNA-like RNA, accompanied by the synthesis of small amounts of 4 S RNA, 5 S RNA and snRNAs. The second phase is the MBT stage which is characterized by a large activation (about 50-fold increase on a per cell basis) of 4 S RNA synthesis. The third phase is the post-MBT stage which is characterized by the commencement and increase in rRNA synthesis. We assume that RNA polymerases II, III and I are activated in this order in early Xenopus embryogenesis.

Oligonucleotide-targeted degradation of U1 and U2 snRNAs reveals differential interactions of simian virus 40 pre-mRNAs with snRNPs

We have investigated the roles of U1 and U2 snRNP particles in SV40 pre-mRNA splicing by oligonucleotide-targeted degradation of U1 or U2 snRNAs in Xenopus laevis oocytes. Microinjection of oligonucleotides complementary to regions of U1 or U2 RNAs either in the presence or absence of SV40 DNA resulted in specific cleavage of the corresponding snRNA. Unexpectedly, degradation of U1 or U2 snRNA was far more extensive when the oligonucleotide was injected without, or prior to, introduction of viral DNA. In either co-injected or pre-injected oocytes, these oligonucleotides caused a dramatic reduction in the accumulation of spliced SV40 mRNA expressed from the viral late region, and a commensurate increase in unspliced late RNA. When pre-injected, two different U2 specific oligonucleotides also inhibited the formation of both large and small tumor antigen spliced early mRNAs. However, even when, by pre-injection of a U1 5' end-specific oligonucleotide, greater than 95% degradation of the U1 snRNA 5' ends occurred in oocytes, no reduction in early pre-mRNA splicing was observed. In contrast, the same U1 5' end oligonucleotide, when added to HeLa splicing extracts, substantially inhibited the splicing of SV40 early pre-mRNA, indicating that U1 mRNP is not totally dispensable for early splicing. These findings confirm and extend our earlier observations which suggested that different pre-mRNAs vary in their requirements for snRNPs.

A developmental switch in sea urchin U1 RNA

The sequence of U1 RNA has been determined in the eggs and embryos of two sea urchins, Lytechinus variegatus and Strongylocentrotus purpuratus. In both species the sequence of the U1 RNA changes as the embryos progress through development. The sequence of the major U1 RNA in the eggs of the two species differs in two nucleotides, while the sequence of the U1 RNA present in the late embryos and somatic tissue is identical in the two species. The U1 RNA in eggs and early embryos is primarily derived from the tandemly repeated gene set, which is not expressed in somatic tissues.

Expression of the U1 RNA gene repeat during early sea urchin development: evidence for a switch in U1 RNA genes during development

The majority of the genes for U1 RNA are organized in tandemly repeated units in the sea urchin. To assess the level of expression of these genes in the sea urchin Lytechinus variegatus, we measured the transcription of sequences 3' to the gene. The tandemly repeated U1 genes are expressed in morula and continue to be expressed at high rates until 2 hr after hatching, at which time the rate of expression of all the U1 genes and the tandemly repeated U1 genes declines sharply. By the gastrula stage the synthesis of total U1 RNA has declined by a factor of 8. The major tandemly repeated genes are inactive by this time, although other U1 genes remain active. The sequence of U1 RNA synthesized late in embryonic development differs from the sequence of U1 RNA encoded by the tandemly repeated set of U1 RNA genes, indicating that there must be other U1 RNA genes that are active late in embryonic development.

Targeting of a chromosomal protein to the nucleus and to lampbrush chromosome loops

We have isolated a cDNA clone (SE5A) that encodes a protein on lampbrush chromosome loops of the newt Notophthalmus. In vitro-synthesized transcripts of this clone were injected into Xenopus oocytes, where they were efficiently translated. Most of the translated protein was imported into the oocyte nucleus, and some of it appeared on the chromosome loops. The translation product must contain information that permits its appropriate targeting first to the nucleus and then to the chromosome loops.

Assembly of functional U1 and U2 human-amphibian hybrid snRNPs in Xenopus laevis oocytes

Oligonucleotides complementary to regions of U1 and U2 small nuclear RNAs (snRNAs), when injected into Xenopus laevis oocytes, rapidly induced the specific degradation of U1 and U2 snRNAs, respectively, and then themselves were degraded. After such treatment, splicing of simian virus 40 (SV40) late pre-mRNA transcribed from microinjected viral DNA was blocked in oocytes. If before introduction of SV40 DNA into oocytes HeLa cell U1 or U2 snRNAs were injected and allowed to assemble into small nuclear ribonucleoprotein particle (snRNP)-like complexes, SV40 late RNA was as efficiently spliced as in oocytes that did not receive U1 or U2 oligonucleotides. This demonstrates that oocytes can form fully functional hybrid U1 and U2 snRNPs consisting of human snRNA and amphibian proteins.

Localization and expression of U1 RNA in early mouse embryo development

We have studied the accumulation and localization of U1 RNA during mouse embryo development by in situ hybridization with a U1 RNA probe and immunofluorescence microscopy using a mouse monoclonal antibody to U1 snRNP. There is a substantial amount of U1 RNA present in the oocyte that is present in both the germinal vesicle and the cytoplasm although the concentration is higher in the nuclear compartment. Following the germinal vesicle breakdown that accompanies ovulation and meiotic maturation, the U1 RNA is uniformly distributed throughout the unfertilized oocyte. In the fertilized egg, the silver grain density from in situ hybridization is higher over pronuclei and this enrichment is maintained at the two-cell and later stages. Similar results were obtained for the distribution of the U1 snRNP as assayed by immunofluorescence microscopy: U1 RNA is predominantly localized in all nuclei except polar body nuclei. The U1 RNA in the oocyte and two-cell embryo is predominantly (greater than 85%) U1a RNA. By the eight-cell stage there is a two to three-fold increase in the amount of total U1 RNA and the proportion of U1b RNA has increased to about 40%. The amount of U1 RNA continues to increase through the blastocyst stage and the proportion of the U1b RNA increases to 60%.

Cytoplasmic assembly of snRNP particles from stored proteins and newly transcribed snRNA's in L929 mouse fibroblasts

Newly synthesized snRNAs appear transiently in the cytoplasm where they assemble into ribonucleoprotein particles, the snRNP particles, before returning permanently to the interphase nucleus. In this report, bona fide cytoplasmic fractions, prepared by cell enucleation, are used for a quantitative analysis of snRNP assembly in growing mouse fibroblasts. The half-lives and abundances of the snRNP precursors in the cytoplasm and the rates of snRNP assembly are calculated in L929 cells. With the exception of U6, the major snRNAs are stable RNA species; U1 is almost totally stable while U2 has a half-life of about two cell cycles. In contrast, the majority of newly synthesized U6 decays with a half-life of about 15 h. The relative abundances of the newly synthesized snRNA species U1, U2, U3, U4 and U6 in the cytoplasm are determined by Northern hybridization using cloned probes and are approximately 2% of their nuclear abundance. The half-lives of the two major snRNA precursors in the cytoplasm (U1 and U2) are approximately 20 min as determined by labeling to steady state. The relative abundance of the snRNP B protein in the cytoplasm is determined by Western blotting with the Sm class of autoantibodies and is approximately 25% of the nuclear abundance. Kinetic studies, using the Sm antiserum to immunoprecipitate the methionine-labeled snRNP proteins, suggest that the B protein has a half-life of 90 to 120 min in the cytoplasm. These data are discussed and suggest that there is a large pool of more stable snRNP proteins in the cytoplasm available for assembly with the less abundant but more rapidly turning-over snRNAs.

Newly synthesized small nuclear RNAs appear transiently in the cytoplasm

Newly synthesized small nuclear RNA (snRNA) species U1 and U2 are easily identified in cytoplasmic fractions prepared by standard aqueous cell fractionation. However, because the mature stable snRNA species leak from isolated nuclei during cell fractionation, the possibility exists that these newly synthesized species also leak from the nucleus. To overcome the problems of nuclear leakage, mouse L929 cells were fractionated by cell enucleation. Enucleation extrudes the nuclei from cytochalasin-treated cells and produces cytoplasts that, by several criteria, are a bona fide cytoplasmic fraction uncontaminated by nuclear material. All six of the major snRNAs are present in the cytoplasts (c-snRNAs) shortly after synthesis. The species are identified by immunoprecipitation with specific antisera against the ribonucleoproteins and by Northern blotting and hybrid selection using cloned probes. This confirms and extends similar studies that used non-aqueous cell fractionation and manual dissection to overcome nuclear leakage. Kinetic studies demonstrate that the c-snRNAs return to the interphase nucleus after approximately 20 minutes in the cytoplasm. The U2 precursor U2' is processed to mature-sized U2 in the cytoplast fractions before returning to the nucleus. The c-snRNAs occur in ribonucleoprotein particles with similar antigenicity to the mature nuclear particles within six minutes of transcription. This suggests that in mammalian cells, important steps in the assembly of these ribonucleoproteins occur in the cytoplasm.

Saccharomyces cerevisiae has a U1-like small nuclear RNA with unexpected properties

Previous experiments indicated that only a small subset of the approximately equal to 24 small nuclear RNAs (snRNAs) in Saccharomyces cerevisiae have binding sites for the Sm antigen, a hallmark of metazoan small nuclear ribonucleoproteins (snRNPs) involved in pre-messenger RNA splicing. Antibodies from human serum to Sm proteins were used to show that four snRNAs (snR7, snR14, snR19, and snR20) can be immunoprecipitated from yeast extracts. Three of these four, snR7, snR14, and snR20, have been shown to be analogs of mammalian U5, U4, and U2, respectively. Several regions of significant homology to U1 (164 nucleotides) have now been found in cloned and sequenced snR19 (568 nucleotides). These include ten out of ten matches to the 5' end of U1, the site known to interact with the 5' splice site of mammalian introns. Surprisingly, the precise conservation of this sequence precludes perfect complementarity between snR19 and the invariant yeast 5' junction (GTATGT), which differs from the mammalian consensus at the fourth position (GTPuAGT).

Cytoplasmic maturation of the snRNAs

The snRNAs are abundant and stable components of the interphase nucleus. Aqueous and non-aqueous cell fractionation demonstrate that the snRNAs appear transiently in the cytoplasm shortly after transcription, before returning permanently to the interphase nucleus. In pulse label and chase experiments, the newly synthesized snRNA species appear in the cytoplasm after 1 min of labeling and then return to the interphase nucleus after approximately 15 min in the cytoplasm. In order to study the maturation and intracellular transport of these particles, a battery of metabolic inhibitors and alterations in cell culture conditions were investigated for their ability to interfere with the return of the newly synthesized snRNAs to the nucleus. A wide range of inhibitors of the cytoskeleton did not interfere with this process. Only the inhibition of protein synthesis and exposure of cells to medium of at least twice the normal tonicity block the return of the snRNAs to the nucleus. Immunofluorescent staining of cells exposed to hypertonic medium identifies discrete foci in the cytoplasm that stain with the Sm antiserum, directed against proteins associated with the snRNAs. Using a detergent extraction procedure that preserves the cytoskeleton, the newly synthesized snRNAs in the cytoplasm fractionate as soluble complexes. These data are consistent with the hypothesis that the snRNAs partition into the interphase nucleus because of a preferential solubility and the existence of specific binding sites.

The transcription of Xenopus laevis embryonic U1 snRNA genes changes when oocytes mature into eggs

X. laevis stage VI oocytes respond differently from unfertilized eggs when injected with the genes for X. laevis embryonic U1 RNAs, xU1b1, and xU1b2. Upon maturation of oocytes into eggs, the efficiency of transcription decreases greatly and the ratio of xU1b1 to xU1b2 RNA transcription changes. Moreover, DNA replication is now required for transcription. Because of differences in the 5'-flanking regions of the two xU1b genes, xU1b2 RNA transcription predominates after injection into oocytes; in contrast, xU1b1 RNA transcription predominates after injection into unfertilized eggs. Our results also indicate that in oocytes a factor that interacts with sequences close to the coding region is limiting, whereas in eggs a factor that recognizes far-upstream sequences required for enhancer activity is limiting. Qualitatively, expression of the embryonic xU1b genes injected into eggs closely resembles that of the endogenous genes during early embryogenesis.

Differential accumulation of U1 and U4 small nuclear RNAs during Xenopus development

We showed previously that those U1 small nuclear RNA (snRNA) genes of Xenopus laevis which are transcribed very actively in early embryos are quiescent in mature (stage VI) oocytes (Forbes et al. 1984). Although that study demonstrated that differential control of snRNA genes occurred, it did not describe snRNA accumulation during development. Using high-resolution polyacrylamide gels in combination with Northern blot hybridization and RNA sequence analyses, we show here that Xenopus has at least three classes of U1 and U4 snRNAs that are distinguishable by their differential expression of oocytes, embryos, tadpoles, and frogs. Adult snRNAs appear to be synthesized constitutively throughout Xenopus development and comprise the major species in tissues from large tadpoles and frogs. Embryonic snRNAs are the principal species accumulating during the two periods of rapid snRNA synthesis, i.e., in previtellogenic oocytes and early embryos. Tadpole RNAs are minor species that are most prominent in young feeding tadpoles. Transcription of both embryonic and adult snRNA genes is activated at the midblastula transition (MBT), but expression of the embryonic genes is switched off selectively within a few days after MBT. Although the precise timing of this inactivation differs significantly for U1 and U4 genes, the overall pattern of differential expression is common to U1 and U2 snRNA genes. Because of sequence differences between the snRNAs accumulating at various stages, the resulting populations of snRNPs could have different splice-site specificities leading to altered patterns of pre-mRNA splicing during development.

The events of the midblastula transition in Xenopus are regulated by changes in the cell cycle

The midblastula transition (MBT) in Xenopus can be initiated prematurely by blocking the fundamental cell-cycle oscillator with cycloheximide, in which case motility and transcription are quickly initiated. Using various inhibitors of specific events of the cell cycle that do not inhibit the autonomous oscillator, we have shown that transcription is activated when DNA synthesis is interrupted and motility is activated when cell cleavage is inhibited. Furthermore, very low levels of transcription are found to occur before the MBT. These results demonstrate that the pre-MBT egg is fully competent for transcription and motility and suggest that different features of the rapid early cell cycle normally suppress these events.

Nuclear reconstitution in vitro: stages of assembly around protein-free DNA

We have developed a cell-free system derived from Xenopus eggs that reconstitutes nuclear structure around an added protein-free substrate (bacteriophage lambda DNA). Assembled nuclei are morphologically indistinguishable from normal eukaryotic nuclei: they are surrounded by a double membrane containing nuclear pores and are lined with a peripheral nuclear lamina. Nuclear assembly involves discrete intermediate steps, including nucleosome assembly, scaffold assembly, and nuclear membrane and lamina assembly, indicating that during reconstitution nuclear organization is assembled one level at a time. Topoisomerase II inhibitors block nuclear assembly. Lamin proteins and membrane vesicles bind to chromatin late in assembly, suggesting that these components do not interact with chromatin that is formed early in assembly. Reconstituted nuclei replicate their DNA; replication begins only after envelope formation has initiated, indicating that envelope attachment may be important for regulating replication.