Xenopus laevis U1 snRNA genes: characterisation of transcriptionally active genes reveals major and minor repeated gene families

U1 snDNA chromosomal mapping in ten spittlebug species (Cercopidade, Auchenorrhyncha, Hemiptera)

Spittlebugs, which belong to the family Cercopidae (Auchenorrhyncha, Hemiptera), form a large group of xylem-feeding insects that are best known for causing damage to plantations and pasture grasses. The holocentric chromosomes of these insects remain poorly studied in regards to the organization of different classes of repetitive DNA. To improve chromosomal maps based on repetitive DNAs and to better understand the chromosomal organization and evolutionary dynamics of multigene families in spittlebugs, we physically mapped the U1 snRNA gene with fluorescence in situ hybridization (FISH) in 10 species of Cercopidae belonging to three different genera. All the U1 snDNA clusters were autosomal and located in interstitial position. In seven species, they were restricted to one autosome per haploid genome, while three species of the genus Mahanarva showed two clusters in two different autosomes. Although it was not possible to precisely define the ancestral location of this gene, it was possible to observe the presence of at least one cluster located in a small bivalent in all karyotypes. The karyotype stability observed in Cercopidae is also observed in respect to the distribution of U1 snDNA. Our data are discussed in light of possible mechanisms for U1 snDNA conservation and compared with the available data from other species.

U1 snDNA clusters in grasshoppers: chromosomal dynamics and genomic organization

The spliceosome, constituted by a protein set associated with small nuclear RNA (snRNA), is responsible for mRNA maturation through intron removal. Among snRNA genes, U1 is generally a conserved repetitive sequence. To unveil the chromosomal/genomic dynamics of this multigene family in grasshoppers, we mapped U1 genes by fluorescence in situ hybridization in 70 species belonging to the families Proscopiidae, Pyrgomorphidae, Ommexechidae, Romaleidae and Acrididae. Evident clusters were observed in all species, indicating that, at least, some U1 repeats are tandemly arrayed. High conservation was observed in the first four families, with most species carrying a single U1 cluster, frequently located in the third or fourth longest autosome. By contrast, extensive variation was observed among Acrididae, from a single chromosome pair carrying U1 to all chromosome pairs carrying it, with occasional occurrence of two or more clusters in the same chromosome. DNA sequence analysis in Eyprepocnemis plorans (species carrying U1 clusters on seven different chromosome pairs) and Locusta migratoria (carrying U1 in a single chromosome pair) supported the coexistence of functional and pseudogenic lineages. One of these pseudogenic lineages was truncated in the same nucleotide position in both species, suggesting that it was present in a common ancestor to both species. At least in E. plorans, this U1 snDNA pseudogenic lineage was associated with 5S rDNA and short interspersed elements (SINE)-like mobile elements. Given that we conclude in grasshoppers that the U1 snDNA had evolved under the birth-and-death model and that its intragenomic spread might be related with mobile elements.

Molecular characterization and chromosomal mapping of the 5S rRNA gene in Solea senegalensis: a new linkage to the U1, U2, and U5 small nuclear RNA genes

Some units of the 5S rDNA of Solea senegalensis were amplified by PCR and sequenced. Three main PCR products (227, 441, and 2166 bp) were identified. The 227- and 441-bp fragments were characterized by highly divergent nontranscribed spacer sequences (referred to as NTS-I and NTS-II) that were 109 and 324 bp long, respectively, yet their coding sequences were nearly identical. The 2166-bp 5S rDNA unit was composed of two 5S rRNA genes separated by NTS-I and followed by a 1721-bp spacer containing the U2, U5, and U1 small nuclear RNA genes (snRNAs). They were inverted and arranged in the transcriptional direction opposite that of the 5S rRNA gene. This simultaneous linkage of 3 different snRNAs had never been observed before. The PCR products were used as probes in fluorescence in situ hybridization experiments to locate the corresponding loci on the chromosomes of S. senegalensis. A major 5S rDNA chromosomal site was located along most of the short arm of a submetacentric pair, while a minor site was detected near the centromeric region of an acrocentric pair.

The U5/U6 snRNA genomic repeat of Taenia solium

The U6 and U5 snRNA (small nuclear ribonucleic acid) genes were identified in Taenia solium with the aim of characterizing their sequence and genomic structures. They are contained within a shared 1,009-nt tandem genomic repeat and present at approximately 3 copies per haploid genome. The U6 snRNA gene shares 92 and 95% sequence similarity with the U6 homologs from humans and Schistosoma mansoni, respectively. The U5 snRNA gene of T. solium is 70% similar to the human U5 sequence in the 5' stem and loop 1 domains. The U6 and U5 snRNA genes are on complementary genomic strands and separated by 458 nt at their "heads" and 306 nt at their "tails." The nucleotides upstream of the U6 gene lack a recognizable TATA box and proximal sequence elements (PSEs), and the putative gene promoter for U5 snRNA does not resemble vertebrate examples. There are short blocks of similarity between the sequences upstream of the U5 and U6 snRNA genes, and these may be sites of shared transcription factor binding at the respective RNA polymerase II and III promoters. It is possible that this unusual allied U5/U6 snRNA genomic repeat may help mediate coordinated regulation of expression of the 2 snRNAs.

5S ribosomal and U1 small nuclear RNA genes: A new linkage type in the genome of a crustacean that has three different tandemly repeated units containing 5S ribosomal DNA sequences

We investigated the 5S ribosomal RNA (rRNA) genes of the isopod crustacean Asellus aquaticus. Using PCR amplification, three different tandemly repeated units containing 5S rDNA were identified. Two of the three sequences were cloned and sequenced. One of them was 1842 bp and presented a 5S rRNA gene and a U1 small nuclear RNA (snRNA) gene. This type of linkage had never been observed before. The other repeat consisted of 477 bp and contained only an incomplete 5S rRNA gene lacking the first eight nucleotides and a spacer sequence. The third sequence was 6553 bp long and contained a 5S rRNA gene and the four core histone genes. The PCR products were used as probes in fluorescent in situ hybridization (FISH) experiments to locate them on chromosomes of A. aquaticus. The possible evolutionary origin of the three repeated units is discussed.Key words: Asellus, isopoda, crustacea, 5S rDNA, U1 snDNA.

Assembly of U7 small nuclear ribonucleoprotein particle and histone RNA 3' processing in Xenopus egg extracts

In animals, replication-dependent histone genes are expressed in dividing somatic cells during S phase to maintain chromatin condensation. Histone mRNA 3'-end formation is an essential regulatory step producing an mRNA with a hairpin structure at the 3'-end. This requires the interaction of the U7 small nuclear ribonucleoprotein particle (snRNP) with a purine-rich spacer element and of the hairpin-binding protein with the hairpin element, respectively, in the 3'-untranslated region of histone RNA. Here, we demonstrate that bona fide histone RNA 3' processing takes place in Xenopus egg extracts in a reaction dependent on the addition of synthetic U7 RNA that is assembled into a ribonucleoprotein particle by protein components available in the extract. In addition to reconstituted U7 snRNP, Xenopus hairpin-binding protein SLBP1 is necessary for efficient processing. Histone RNA 3' processing is not affected by addition of non-destructible cyclin B, which drives the egg extract into M phase, but SLBP1 is phosphorylated in this extract. SPH-1, the Xenopus homologue of human p80-coilin found in coiled bodies, is associated with U7 snRNPs. However, this does not depend on the U7 RNA being able to process histone RNA and also occurs with U1 snRNPs; therefore, association of SPH1 cannot be considered as a hallmark of a functional U7 snRNP.

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.

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.

Structure of the Echinococcus multilocularis U1 snRNA gene repeat

The gene encoding U1 snRNA in Echinococcus multilocularis has been cloned and sequenced. This gene is contained within a 1300-bp sequence which is tandemly repeated in the E. multilocularis genome. E. multilocularis U1 snRNA is 50-70% homologous to U1 snRNAs of other species. E. multilocularis U1 snRNA could assume a predicted secondary structure similar to that proposed for other U1 snRNAs, and appears shorter (157 bases) than the U1 snRNAs of higher eukaryotes (163-166 bases).

Sequence, organization and transcriptional analysis of a gene encoding a U1 snRNA from the axolotl, Ambystoma mexicanum

AmU1, a DNA fragment containing a U1 small nuclear RNA (snRNA)-encoding gene, was isolated from the axolotl, Ambystoma mexicanum. Although this U1 snRNA, produced in axolotl oocytes, exhibits the lowest degree of sequence conservation among vertebrates, its secondary structure is maintained by a number of compensatory base changes. The proximal sequence element (PSE) is only weakly similar to that of the previously characterized Xenopus laevis PSE. Exchanging either the entire upstream regions with their X. laevis U1 (XlU1) homologues or only the PSE with the XlU1 PSE increases the transcription rate of the AmU1 gene to a level similar to that of the XlU1 gene. However, while allowing the AmU1 gene to be transcribed with high efficiency in X. laevis oocytes, the strict swapping of the 12-bp constituting the XlU1 PSE does not confer competitive ability to the AmU1 gene. We present evidence that the PSE is the major, but not the only element responsible for the low template activity of the AmU1 gene in X. laevis oocytes and our data suggest that other sequences, perhaps flanking the PSE, might also influence the binding of factor(s) participating in the assembly of the transcription complex.

Monomethylated cap structures facilitate RNA export from the nucleus

RNA export from the nucleus has been analyzed in Xenopus oocytes. U1 snRNAs made by RNA polymerase II were exported into the cytoplasm, while U1 snRNAs synthesized by RNA polymerase III, and therefore with a different cap structure, remained in the nucleus. Export of the polymerase II-transcribed RNAs was inhibited by the cap analog m7GpppG. Spliced mRNAs carrying monomethylguanosine cap structures were rapidly exported, while hypermethylated cap structures delayed mRNA export. The export of a mutant precursor mRNA unable to form detectable splicing complexes was also significantly delayed by incorporation of a hypermethylated cap structure. The results suggest that the m7GpppN cap structure is likely to be a signal for RNA export from the nucleus.

The trimethylguanosine cap structure of U1 snRNA is a component of a bipartite nuclear targeting signal

The ability of series of U1 snRNAs and U6 snRNAs to migrate into the nucleus of Xenopus oocytes after injection into the cytoplasm was analyzed. The U snRNAs were made either by injecting U snRNA genes into the nucleus of oocytes or, synthetically, by T7 RNA polymerase, incorporating a variety of cap structures. The results indicate that nuclear targeting of U1 snRNA requires both a trimethylguanosine cap structure and binding of at least one common U snRNP protein. Using synthetic U6 snRNAs, it is further demonstrated that the trimethylguanosine cap structure can act in nuclear targeting in the absence of the common U snRNP proteins. These results imply that U snRNP nuclear targeting signals are of a modular nature.

Major determinants of the specificity of interaction between small nuclear ribonucleoproteins U1A and U2B'' and their cognate RNAs

The basis of the specificity of interaction of U1 and U2 small nuclear (sn)RNAs and their cognate binding proteins, U1A and U2B'', has been examined. The U1A protein recognizes U1 snRNA on its own, whereas U2B'' binds specifically to U2 snRNA only in the presence of a second protein, U2A'. Exchange of two nucleotides between the two RNAs or of eight amino acids between the two proteins reverses binding specificity.

Functional analysis of mutant Xenopus U2 snRNAs

Methods for studying pre-mRNA splicing in Xenopus oocytes have been improved to allow simultaneous analysis of the splicing reaction and the formation of splicing complexes in vivo. The number, order of appearance, and dependence on intact U1 and U2 snRNPs of complexes formed in vivo on a pre-mRNA substrate are similar but not identical to those observed in vitro. The migration on native gels of the complexes formed in vivo and in vitro is, however, dissimilar. RNAase H-mediated inhibition of splicing caused by oligonucleotide microinjection can be overcome by coinjection of a gene encoding the U snRNA that is targeted for cleavage. Transcripts from the injected gene complement the defect in splicing by assembling into functionally active U snRNPs. Using this assay, mutant U2 snRNAs have been tested for their ability to function in splicing and in splicing complex formation. The results indicate that much of the U2 snRNA, including regions essential for detectable binding of the U2-specific proteins A' and B", is dispensable for splicing.

Nucleotide sequence and organization of full length human U4 RNA pseudogenes

Two loci encoding human U4 RNA, designated U4/7 and U4/14, have been isolated and sequenced. Both are pseudogenes in that their sequences do not match any identified human U4 RNA species perfectly. The U4/7 locus harbours a full-length pseudogene of 144 bp with eight base substitutions in the structural region. This pseudogene might be derived from a hitherto unidentified human U4 RNA gene. The second locus, U4/14, has a complex structure; the structural sequence of a U4 gene has apparently been integrated into an Alu sequence.

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.

Genetic analysis of the role of human U1 snRNA in mRNA splicing: I. Effect of mutations in the highly conserved stem-loop I of U1

The 5' splice site mutation known as hr440 can be suppressed efficiently in vivo by a compensatory base change in U1 small nuclear RNA (snRNA). We have now begun a second-site reversion analysis of this suppressor U1-4u snRNA (which has a C----U change at position 4) to identify U1 nucleotides that are essential for mRNA splicing. Point mutations in U1-4u that disrupt the structure of stem-loop I or alter phylogenetically conserved nucleotides within the loop cause loss of suppression. The level of suppressor activity observed for most mutants correlated with the abundance of the corresponding suppressor RNA, suggesting that mutations in stem-loop I cause loss of suppression by destabilizing U1 snRNA or the U1 snRNP (small nuclear ribonucleoprotein particle). We favor the interpretation that incompletely or improperly assembled U1 snRNPs are unstable, because two severe point mutations in stem-loop I were found to decrease the binding of U1 snRNP-specific proteins in vitro. In a separate set of experiments, we found that increasing the distance between stem-loop I and the 5' end of U1 snRNA also inhibited suppression but did not affect assembly or stability of the U1 snRNP. This suggests that the relationship between the 5' splice site and the body of the U1 snRNP is important for mRNA splicing.

Structure of an unusual sea urchin U1 RNA gene cluster

Genomic clones containing multiple copies of the Lytechinus variegatus U1 gene have been isolated from a gene library in the phage lambda EMBL3. These clones contain both types of U1 RNA gene repeats interspersed in the same 15-kb fragment. In addition, about 1/3 of the repeat units contain a 260-bp insert 460 bp prior to the first nucleotide of the U1 RNA sequence. The inserted sequence is abundant in the sea urchin genome as judged by Southern blots of genomic DNA. There are no repeated sequences flanking the insert. The insert occurs at the same position in the highly conserved 5'-flanking region at which a deletion has previously been reported.

A common octamer motif binding protein is involved in the transcription of U6 snRNA by RNA polymerase III and U2 snRNA by RNA polymerase II

The structure of a Xenopus U6 gene promoter has been investigated. Three regions in the 5'-flanking sequences of the gene that are important for U6 expression are defined. Deletion of the first, between positions -156 and -280 relative to the site of transcription initiation, reduces transcription to roughly 5% of its original level. Deletion of the second, between -60 and -77, abolishes transcription. These regions contain not only functional but also sequence homology to the previously defined distal and proximal sequence elements (DSE and PSE) of the Xenopus U2 promoter, although U2 is transcribed by RNA polymerase II and U6 by RNA polymerase III. Competition experiments show that at least the distal sequence elements of the two promoters bind to a common factor both in vivo and in vitro. Part of the sequence recognized by this factor is the octamer motif (ATG-CAAAT). A sequence similar to the common RNA polymerase II TATA box is also shown to have an effect, albeit minor, on U6 transcription. The U6 coding region contains a good match to the A box, part of all previously characterized RNA polymerase III promoters. Deletion of this region has no apparent effect on the efficiency or accuracy of U6 transcription.

Mutant U2 snRNAs of Xenopus which can form an altered higher order RNA structure are unable to enter the nucleus

We studied the nuclear targeting of U snRNAs by microinjection of wild-type and mutant U2 small nuclear RNA transcripts into the cytoplasm of Xenopus oocytes. It has previously been shown that a mutant U2 RNA (delta C) which does not bind certain common U snRNP proteins, some of which carry epitopes recognized by anti-Sm antisera, does not enter the nucleus. We show here that several mutant U2 RNAs which bind to Sm antigens do not enter the nucleus, demonstrating that this RNA-protein interaction is insufficient to produce a nuclear targeting signal. Computer predictions of the secondary structures of the RNAs, derived from minimal energy calculations, show that those which are unable to enter the nucleus have the potential to form an additional secondary structure interaction due to base complementarity between sequences near to their 5' and 3' ends. The data suggest that this structural feature inhibits nuclear targeting.

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.

Properties of a distal regulatory element controlling transcription of the U2 small nuclear RNA

The upstream region of human U2 genes contains a distal transcriptional control element, previously mapped between nucleotide (nt) positions -198 and -258 (Westin et al., 1984b). In the present study we show that it resembles transcriptional enhancers in being active even from a distance of 1.4 kb. However, in contrast to most other enhancers it functions unidirectionally in Xenopus laevis oocytes. The distal control element was further mapped by construction of truncated templates for U2 RNA transcription. The results showed that templates, which extended to either of nt positions -214 and -218, were inactive. Templates comprising sequences to nt positions -225 or -226 displayed an intermediate level of activity whereas templates which extend to nt -258 were fully active. It has previously been shown that the human U2 enhancer contains binding sites for the so-called octamer binding protein and for transcription factor Sp1 [Janson et al., Nucl. Acids Res. 15 (1987) 4997-5016]. The partially active templates included one binding site for the octamer binding protein, whereas the fully active template included, in addition, two Sp1 binding sites, thus indicating that these transcription factors are of importance for U2 RNA transcription. The structure of the enhancer was also probed by inserting a pair of complementary synthetic oligodeoxynucleotides which represented the region between nt positions -235 and -215 into a truncated template which lacked the enhancer. The oligodeoxynucleotide enhanced transcription to approximately 50% of the level obtained with templates extending to position -258.

Formation of the 3' end on U snRNAs requires at least three sequence elements

The structural requirements for 3' end formation on the Xenopus laevis U1B snRNA gene have been studied. Three sequence elements are shown to be required. The first is a conserved sequence element found immediately 3' of all vertebrate U snRNA genes studied so far. The second is a gene internal sequence potentially capable of forming a stem-loop structure close to the 3' end of the RNA. The third element lies upstream of these, and may be part of the gene promoter. Experiments designed to investigate the mechanism of 3' end formation on primary U1B snRNA transcripts failed to find evidence for a processing event.

Cap trimethylation of U snRNA is cytoplasmic and dependent on U snRNP protein binding

Trimethyl capping of U2 snRNA has been studied using U2 genes with mutations located in either the 5' flanking or the coding region. A monomethyl (7-methylguanosine) cap is added to U2 cotranscriptionally, trimethylation being posttranscriptional. The immediate 5' flanking sequences have no influence on trimethylation; furthermore, trimethylation is not affected by changing the position and sequence of the cap site. The efficiency of trimethylation is reduced by deleting the Sm binding site from U2 RNA, but it is not altered by other mutations in the coding sequence. Insertion of artificial Sm binding sites either into a mutant U2 from which the natural binding site has been deleted or into SP6 transcripts generated in vitro allows these RNAs to become trimethylated. The trimethylase activity in Xenopus laevis oocytes is cytoplasmic.

Characterization and mapping of DNA sequence homologous to mouse U1a1 snRNA: localization on chromosome 11 near the Dlb-1 and Re loci

A phage clone which contained a functional U1a1 snRNA gene was isolated from a mouse genomic library. A single copy fragment was isolated from the 3' flanking region of the U1a1 gene and used as a hybridization probe for Southern blotted DNAs from recombinant inbred strains of mice, mouse-hamster hybrid cells, and the offspring from backcrosses between BALB/c mice and mice which were heterozygous for the Rex (Re) marker. The results of these experiments prove that the U1a1 gene is located on chromosome 11 near the Delb-1 and Re loci.

Genes for human U4 small nuclear RNA

A study of human genes coding for U4 small nuclear RNA is presented. It is known from previous studies that mammalian cells contain three major U4 RNA species, designated U4A, U4B, and U4C (Krol and Branlant, 1981). A clone was isolated from a human DNA library which contained two transcriptionally active genes for U4 RNA. U4 transcription was sensitive to low concentrations of alpha-amanitin, inferring that U4 RNA is a product of RNA polymerase II or RNA polymerase II-like activity. One of the two genes contains a coding region which matches the sequence of U4C RNA perfectly. The coding region of the second gene resembles U4B RNA although there are two differences between the sequence of this gene and the U4B RNA sequence, suggesting that it may encode a minor, hitherto undetected U4 RNA species. The 5'-flanking regions of the two U4 genes contain several almost perfectly conserved sequence motifs. One is located between positions -50 and -60. This motif is present in equivalent positions in the two U4 genes as well as in human U1 and U2 genes. A second motif, which is 19 nucleotides (nt) long and centered around nt position -140, is present in the two U4 genes but absent from U2 RNA genes. A third highly conserved region, located between nt positions -210 and -250, is a putative enhancer element. It includes one copy of the so-called octanucleotide motif, previously identified as adjacent to the early SV40 promoter and immunoglobulin promoters. Another highly conserved sequence motif, CTCTGTGA, is located approximately one helical turn upstream from the octanucleotide motif in both U2 and U4 genes. The human genome appears to contain a family of U4 RNA genes comprising at least 100 copies.

Differential control of U1 small nuclear RNA expression during mouse development

During normal mouse development the relative amounts of two types of U1 small nuclear RNA's (U1 RNA) change significantly. Fetal tissues have comparable levels of the two major types of mouse U1 RNA's, mU1a and mU1b, whereas most differentiated adult tissues contain only mU1a RNA's. Those adult tissues that also accumulate detectable amounts of embryonic (mU1b) RNA's (for example, testis, spleen, and thymus) contain a significant proportion of stem cells capable of further differentiation. Several strains of mice express minor sequence variants of U1 RNA's that are subject to the same developmental controls as the major types of adult and embryonic U1 RNA. The differential accumulation of embryonic U1 RNA's may influence the pattern of gene expression during early development and differentiation.

Sequences required for 3' end formation of human U2 small nuclear RNA

Xenopus oocytes injected with human U2 snRNA genes synthesize mature U2 as well as a U2 precursor with about 10 extra 3' nucleotides (human pre-U2 RNA). Formation of the pre-U2 3' end requires a downstream element located between position +16 and +37 in the U2 3'-flanking sequence. The distance between this element and the U2 coding region can be increased without affecting formation of the pre-U2 3' end. When the natural sequence surrounding the pre-U2 3' end is changed, novel 3' ends are still generated within a narrow range upstream from the element. The 3' terminal stem-loop of U2 snRNA is not required for pre-U2 3' end formation. A sequence within the 3' element (GTTTN0-3AAAPuNNAGA) is conserved among snRNA genes transcribed by RNA polymerase II. Our results suggest that the 3' ends of pre-U2 RNA and histone mRNA may be generated by related but distinct RNA processing mechanisms.

U1 small nuclear RNA genes are subject to dosage compensation in mouse cells

Multiple copies of a gene that encodes human U1 small nuclear RNA were introduced into mouse C127 cells with bovine papilloma virus as the vector. For some recombinant constructions, the human U1 gene copies were maintained extrachromosomally on the viral episome in an unrearranged fashion. The relative abundance of human and mouse U1 small nuclear RNA varied from one cell line to another, but in some lines human U1 RNA accounted for as much as one-third of the total U1. Regardless of the level of human U1 expression, the total amount of U1 RNA (both mouse and human) in each cell line was nearly the same relative to endogenous mouse 5S or U2 RNA. This result was obtained whether measurements were made of total cellular U1 or of only the U1 in small nuclear ribonucleoprotein particles that could be precipitated with antibody directed against the Sm antigen. The data suggest that the multigene families encoding mammalian U1 RNA are subject to some form of dosage compensation.

An enhancer-like sequence within the Xenopus U2 gene promoter facilitates the formation of stable transcription complexes

Enhancers are eukaryotic promoter elements that increase transcriptional efficiency in a manner relatively independent of their position and orientation with respect to a nearby gene. There is growing evidence that enhancer action is mediated by transacting factors, but the mode of action of these factors is not yet known. We report here on the Xenopus U2 gene promoter, which contains two sequence elements. The distal sequence element increases promoter activity 20-fold by facilitating the formation of stable transcription complexes. A synthetic 14-base-pair (bp) oligonucleotide corresponding to part of the distal sequence element, which shows homology to an immunoglobulin gene promoter element and to both the simian virus 40 (SV40) and the immunoglobulin heavy-chain gene enhancers, stimulates transcription in an orientation-independent manner.

Transcription signals in embryonic Xenopus laevis U1 RNA genes

A genomic clone of the most abundant U1 RNA genes from Xenopus laevis was isolated from erythrocyte DNA and sequenced. Two different U1 RNA genes, U1A and U1B, are encoded in an HindIII 1.5-kb fragment and both are expressed after microinjection in Xenopus oocytes. Deletions and site-directed mutagenesis of the clones revealed two promoter elements in the U1B gene; one, located 250-220 nucleotides upstream from the 5' terminus of mature U1 RNA, functions as an activator, yielding a 10-fold promotion of transcription; the other, located 60-50 nucleotides upstream of the cap site, functions as an essential element for promotion of transcription. The U1A gene contained only the latter element in the cloned fragment. Homologous sequences can be identified in several U RNA genes of X. laevis.

The two embryonic U1 RNA genes of Xenopus laevis have both common and gene-specific transcription signals

We have cloned and sequenced the 1842-bp repeat DNA encoding the two Xenopus laevis embryonic U1 RNAs, xU1a and xU1b. Although these two U1 RNAs are almost identical in sequence and are coordinately expressed during early embryogenesis, the flanking sequences of their genes show very little homology. Both genes contain two short conserved sequences, centered around positions -55 and +19, that probably are essential for 5' and 3' end formation of U1 RNAs, respectively. Efficient transcription of either gene in stage VI oocytes requires gene-specific promoter elements, located upstream of position -220. In the xU1b gene, these required 5'-flanking sequences include an 18-bp palindrome that has potential for Z-DNA formation. When injected separately into stage VI oocytes, the xU1a and xU1b genes are equally well transcribed, but co-injection of the two genes, either as the full length repeat or as two separate subclones, results in preferential accumulation of xU1b RNA. This competitive advantage of the xU1b gene in injected oocytes apparently is the result of preferred binding of one or more transcription factors that are limiting in these oocytes.

Nuclear segregation of U2 snRNA requires binding of specific snRNP proteins

We analyzed the mechanism by which snRNAs are accumulated in the cell nucleus by introducing in vitro mutations into a cloned Xenopus U2 snRNA gene. The mutant genes were then expressed by microinjection into living oocytes. Using autoimmune antisera we localized the binding sites of snRNP proteins on the mutant U2 snRNAs. Sm antigen, a component shared by most U snRNPs, requires for binding a sequence containing AUUUUUG, a feature partly conserved in U1, U2, U4, and U5 snRNAs. A U2-specific protein defined by a second antiserum requires the two 3' loops of the U2 RNA molecule for binding. Mutant U2 transcripts unable to bind Sm antigen do not accumulate in the nucleus. Since Sm antigenic proteins are cytoplasmic and excluded from the oocyte nucleus when not bound to snRNA, we propose that a karyophilic domain may become exposed on formation of the RNA-protein complex.