Functional, developmentally expressed genes for mouse U1a and U1b snRNAs contain both conserved and non-conserved transcription signals

The assembly of a spliceosomal small nuclear ribonucleoprotein particle

The U1, U2, U4, U5 and U6 small nuclear ribonucleoprotein particles (snRNPs) are essential elements of the spliceosome, the enzyme that catalyzes the excision of introns and the ligation of exons to form a mature mRNA. Since their discovery over a quarter century ago, the structure, assembly and function of spliceosomal snRNPs have been extensively studied. Accordingly, the functions of splicing snRNPs and the role of various nuclear organelles, such as Cajal bodies (CBs), in their nuclear maturation phase have already been excellently reviewed elsewhere. The aim of this review is, then, to briefly outline the structure of snRNPs and to synthesize new and exciting developments in the snRNP biogenesis pathways.

Control of mouse U1 snRNA gene expression during in vitro differentiation of mouse embryonic stem cells

Early in mouse development, two classes of U1 RNAs, mU1a and mU1b, are synthesized, but as development proceeds, transcription of the embryo-specific mU1b genes is selectively down-regulated to a barely detectable level. We show here that during in vitro differentiation of mouse embryonic stem (ES) cells, both exogenously introduced and endogenous U1b genes are subject to normal developmental regulation. Thus, ES cells represent a convenient isogenic system for studying the control of expression of developmentally regulated snRNA genes. Using this system, we have identified a region in the proximal 5'flanking region, located outside the PSE element, that is responsible for differential transcription of the mU1a and mU1b genes in both developing cells and transiently transfected NIH 3T3 cells.

Efficient expression of protein coding genes from the murine U1 small nuclear RNA promoters

Few promoters are active at high levels in all cells. Of these, the majority encode structural RNAs transcribed by RNA polymerases I or III and are not accessible for the expression of proteins. An exception are the small nuclear RNAs (snRNAs) transcribed by RNA polymerase II. Although snRNA biosynthesis is unique and thought not to be compatible with synthesis of functional mRNA, we have tested these promoters for their ability to express functional mRNAs. We have used the murine U1a and U1b snRNA gene promoters to express the Escherichia coli lacZ gene and the human alpha-globin gene from either episomal or integrated templates by transfection, or infection into a variety of mammalian cell types. Equivalent expression of beta-galactosidase was obtained from < 250 nucleotides of 5'-flanking sequence containing the complete promoter of either U1 snRNA gene or from the 750-nt cytomegalovirus promoter and enhancer regions. The mRNA was accurately initiated at the U1 start site, efficiently spliced and polyadenylylated, and localized to polyribosomes. Recombinant adenovirus containing the U1b-lacZ chimeric gene transduced and expressed beta-galactosidase efficiently in human 293 cells and airway epithelial cells in culture. Viral vectors containing U1 snRNA promoters may be an attractive alternative to vectors containing viral promoters for persistent high-level expression of therapeutic genes or proteins.

Control of mouse U1a and U1b snRNA gene expression by differential transcription

The expression of mouse embryonic U1 snRNA (mU1b) genes is subject to stage- and tissue-specific control, being restricted to early embryos and adult tissues that contain a high proportion of stem cells capable of further differentiation. To determine the mechanism of this control we have sought to distinguish between differential RNA stability and regulation of U1 gene promoter activity in several cell types. We demonstrate here that mU1b RNA can accumulate to high levels in permanently transfected mouse 3T3 and C127 fibroblast cells which normally do not express the endogenous U1b genes, and apparently can do so without significantly interfering with cell growth. Expression of transfected chimeric U1 genes in such cells is much more efficient when their promoters are derived from a constitutively expressed mU1a gene rather than from an mU1b gene. In transgenic mice, introduced U1 transgenes with an mU1b 5' flanking region are subject to normal tissue-specific control, indicating that U1b promoter activity is restricted to tissues that normally express U1b genes. Inactivation of the embryonic genes during normal differentiation is not associated with methylation of upstream CpG-rich sequences; however, in NIH 3T3 fibroblasts, the 5' flanking regions of endogenous mU1b genes are completely methylated, indicating that DNA methylation serves to imprint the inactive state of the mU1b genes in cultured cells. Based on these results, we propose that the developmental control of U1b gene expression is due to differential activity of mU1a and mU1b promoters rather than to differential stability of U1a and U1b RNAs.

Two promoter elements are necessary and sufficient for expression of the sea urchin U1 snRNA gene

The essential elements of the sea urchin L. variegatus U1 snRNA promoter were mapped by microinjection of a U1 maxigene into sea urchin zygotes. Two elements are required for expression: a distal sequence element (DSE) located between -318 and -300 and a proximal sequence element (PSE) centered at -55. Removal or alteration of other sequences conserved in different sea urchin snRNA U1 genes, including deletion of all sequence between -90 and -273, did not affect the expression. Sequences around the start site were not required for expression. Deletion of nucleotides between the PSE and the start site resulted in initiation inside the U1 coding region, suggesting that the PSE determines the start site of transcription. There is no obvious similarity between the sequences required for the sea urchin U1 snRNA expression and the sequences required for the expression of other sea urchin snRNAs.

Structure of the differentially expressed mouse U3A gene

Two markedly different forms of U3 RNA are present in mouse, the relative abundance of which largely depends upon the tissues. In all cases studied so far, the more abundant form is U3B, encoded by four previously characterized genes. We report here the isolation and analysis of the unique gene encoding the U3A variant, which completes the characterization of the mouse U3 multigene family. Comparisons with rat U3 genes indicate that the diversification of the A and B forms has predated the mouse/rat separation. The two forms of U3 RNA are submitted to similar, but not identical, primary and secondary structure constraints. As for the sequences flanking the RNA coding region, similar observations emerge for both types of genes: for each type, the 5' flanks are strongly conserved between mouse and rat, over at least the proximal 500 bp, whereas only about 30 bp of proximal 3' flanks are preserved, which include a signal for the formation of vertebrate U small nRNA 3' end. By contrast the 5' flanks of the two types of genes diverge extensively from each other, either in mouse or in rat, and could be involved in the differential expression of the two forms. Even over the few conserved motifs thought to be involved in the basic transcriptional control of vertebrate U small nRNA genes, the A and B forms of U3 genes exhibit specific differences maintained in the two rodent species.

Differential protein-DNA interactions at the promoter and enhancer regions of developmentally regulated U4 snRNA genes

In the chicken genome there are two closely-linked genes, U4B and U4X, that code for different sequence variants of U4 small nuclear RNA (snRNA). Both genes are expressed with nearly equal efficiency in the early embryo, but U4X gene expression is specifically down-regulated relative to U4B as development proceeds. At the present time, little is known about the mechanisms that regulate differential expression of snRNA genes. We have now identified a novel chicken factor, PPBF, that binds sequence-specifically in vitro to the proximal regulatory region of the U4X gene, but not to the proximal region of the U4B gene. PPBF is itself regulated during development and may therefore be a key factor involved in differentially regulating U4X gene transcription relative to U4B. The U4X and U4B enhancers contain distinct sequence variants of two essential motifs (octamer and SPH). The Oct-1 transcription factor binds with similar affinities to both the U4X and U4B octamer motifs. However, a second essential snRNA enhancer-binding protein, SBF, has a 20- to 30-fold lower affinity for the SPH motif in the U4X enhancer than for the homologous SPH motif in the U4B enhancer. A potential role therefore exists for SBF, as well as PPBF, in the preferential down-regulation of the U4X RNA gene during chicken development.

SV40 T-antigen-binding sites within the 5'-flanking regions of human U1 and U2 genes

The 5' flanking regions of the genes (U1 and U2) encoding the human U1 and U2 small nuclear RNAs (snRNAs) each contain sequences that bind specifically to the simian virus (SV40) large tumor antigen (T.Ag). Substitution of these sites with sequences that lack T.Ag-binding sites did not block accumulation of U1 or U2 snRNA in a variety of cell types, but deletion of these regions resulted in the total loss of expression. Thus, these sequences may serve only a spacing function, and the T.Ag-binding sites appear not to be necessary for expression. However, coexpression of T.Ag markedly reduced expression of a U1 gene containing a high-affinity T.Ag-binding site (from the SV40 genome) in place of the U1 T.Ag-binding site. In contrast, coexpression of T.Ag enhanced synthesis of U2, but not U1, snRNA, independent of the presence of the T.Ag-binding sites. Thus, while the consensus T.Ag-binding sites within the U1 and U2 promoter regions do not appear to influence expression, the binding of SV40 T.Ag to a high-affinity site can lead to significant repression of a strong snRNA promoter, and T.Ag can enhance expression of another in the absence of a known binding site.

Differential expression of the mouse U1a and U1b SnRNA genes is not dependent on sequence differences in the octamer motif

The mouse U1b SnRNA gene is expressed in only a limited range of cell types, whereas the U1a SnRNA gene is expressed in all cells. These two genes differ in the sequence of the octamer motif, which plays a critical role in SnRNA gene regulation. We show that the U1b octamer binds the octamer-binding protein Oct-1 with higher affinity than does the U1a octamer in both U1b-expressing and -non-expressing cell lines and tissues. Moreover, the U1b octamer can direct a higher level of gene expression than the U1a octamer when linked to a heterologous promoter and introduced into a non-U1b-expressing cell line. Hence the tissue-specific expression of the U1b gene is not determined by the failure of its octamer motif to bind Oct-1 or the weak affinity of this binding.

U4B snRNA gene enhancer activity requires functional octamer and SPH motifs

Expression of the chicken U4B small nuclear RNA (snRNA) gene is stimulated by a transcriptional enhancer located approximately 190-227 base pairs upstream of the transcription start site. This enhancer is composed of at least two functional motifs: an octamer (binding site for Oct-1) and an SPH motif. We now report that these two motifs functionally cooperate to stimulate U4B snRNA gene expression, and both are required for the formation of a stable transcription complex. Expression in frog oocytes of 24 different point mutant constructions indicates that the functional SPH motif is at least 15 base pairs in length. It is a recognition site for a sequence specific DNA-binding protein, termed SBF, purified from chicken embryonic nuclear extracts. The ability of the mutant SPH motif constructions to be recognized by SBF in vitro correlates with their transcriptional activities, suggesting that SBF mediates the stimulatory effect of the U4B SPH motif. These results are similar to our recent findings on the chicken U1 gene enhancer, which also contains adjacent binding sites for Oct-1 and SBF. These studies, together with evolutionary considerations and sequence comparisons among snRNA gene enhancers, suggest that cooperativity between octamer and SPH motifs could be a widely-employed mechanism for generating vertebrate snRNA gene enhancer activity.

Drosophila melanogaster genes for U1 snRNA variants and their expression during development

We have cloned and characterized a complete set of seven U1-related sequences from Drosophila melanogaster. These sequences are located at the three cytogenetic loci 21D, 82E, and 95C. Three of these sequences have been previously studied: one U1 gene at 21D which encodes the prototype U1 sequence (U1a), one U1 gene at 82E which encodes a U1 variant with a single nucleotide substitution (U1b), and a pseudogene at 82E. The four previously uncharacterized genes are another U1b gene at 82E, two additional U1a genes at 95C, and a U1 gene at 95C which encodes a new variant (U1c) with a distinct single nucleotide change relative to U1a. Three blocks of 5' flanking sequence similarity are common to all six full length genes. Using specific primer extension assays, we have observed that the U1b RNA is expressed in Drosophila Kc cells and is associated with snRNP proteins, suggesting that the U1b-containing snRNP particles are able to participate in the process of pre-mRNA splicing. We have also examined the expression throughout Drosophila development of the two U1 variants relative to the prototype sequence. The U1c variant is undetectable by our methods, while the U1b variant exhibits a primarily embryonic pattern reminiscent of the expression of certain U1 variants in sea urchin, Xenopus, and mouse.

Mouse U14 snRNA is encoded in an intron of the mouse cognate hsc70 heat shock gene

Mouse U14 snRNA (previously designated mouse 4.5S hybRNA) is an evolutionarily conserved eukaryotic low molecular weight RNA capable of intermolecular hybridization with both homologous and heterologous 18S rRNA (1). A single genomic fragment of mouse DNA containing the U14 snRNA gene(s) has been isolated from a Charon 4A lambda phage mouse genomic library and sequenced. Results have surprisingly revealed the presence of three U14 snRNA-homologous regions positioned within introns 5, 6, and 8 of the mouse cognate hsc70 heat shock gene. Comparative analysis with the previously reported rat and human cognate hsc70 genes revealed a similar positioning of U14 snRNA-homologous sequences within introns 5, 6 and 8 of the respective rat and human genes. The U14 sequences contained in all three introns of all three organisms are highly homologous to each other and well conserved with respect to the diverging intron sequences flanking each U14-homologous sequence. Comparison of the mouse U14 snRNA sequence with the U14 DNA sequences contained in the three mouse hsc70 introns indicates that intron 5 is utilized for U14 snRNA synthesis in normally growing mouse ascites cells. Analysis of the determined mouse, rat, and human U14-homologous sequences and the upstream and downstream flanking regions did not reveal the presence of any previously defined RNA polymerase I, II, or III binding sites. This suggests that either higher eukaryotic U14 snRNA is transcribed from a unique transcriptional promoter sequence, or alternatively, is generated by intron processing of the hsc70 pre-mRNA transcript.

A structural analysis of P. polycephalum U1 RNA at the RNA and gene levels. Are there differentially expressed U1 RNA genes in P. polycephalum? U1 RNA evolution

U1 RNAs were isolated from P. polycephalum microplasmodia nuclei and sequenced. A P. polycephalum gene coding for U1 RNA was also isolated. The coding region of this gene differs at 3 positions compared to the isolated U1 RNA species. Both isolated RNAs and the gene encoded RNA can be folded according to the secondary structure model previously proposed for U1 RNA. Putative regulatory elements very similar to those required for efficient transcription of U RNA genes from vertebrates, in particular, the -200 distal enhancer element, are present in the flanking regions of this gene. The presence of several U1 RNA genes in P. polycephalum was confirmed by Southern blot analysis of genomic DNA. In contrast to yeast S. cerevisiae U1 RNA, P. polycephalum U1 RNAs have a length similar to that of U1 RNAs from higher eukaryotes. Nevertheless, P. polycephalum U1 RNAs probably differ from these RNAs in the 5'-terminal segment supposed to base-pair with the 5'-end of introns. The results are discussed taking into account phylogenetic evolution and functional role of U1 RNA.

Multiple functional motifs in the chicken U1 RNA gene enhancer

The DNA sequence requirements of chicken U1 RNA gene expression have been examined in an oocyte transcription system. An enhancer region, which was required for efficient U1 RNA gene expression, is contained within a region of conserved DNA sequences spanning nucleotide positions -230 to -183, upstream of the transcriptional initiation site. These DNA sequences can be divided into at least two distinct subregions or domains that acted synergistically to provide a greater than 20-fold stimulation of U1 RNA synthesis. The first domain contains the octamer sequence ATGCAAAT and was recognized by a DNA-binding factor present in HeLa cell extracts. The second domain (the SPH domain) consists of conserved sequences immediately downstream of the octamer and is an essential component of the enhancer. In the oocyte, the DNA sequences of the SPH domain were able to enhance gene expression at least 10-fold in the absence of the octamer domain. In contrast, the octamer domain, although required for full U1 RNA gene activity, was unable to stimulate expression in the absence of the adjacent downstream DNA sequences. These findings imply that sequences 3' of the octamer play a major role in the function of the chicken U1 RNA gene enhancer. This concept was supported by transcriptional competition studies in which a cloned chicken U4B RNA gene was used to compete for limiting transcription factors in oocytes. Multiple sequence motifs that can function in a variety of cis-linked configurations may be a general feature of vertebrate small nuclear RNA gene enhancers.

The embryonic and adult mouse U1 snRNA genes map to different chromosomal loci

The linkage relationships of mouse adult (mU1a) and embryonic (mU1b) U1 snRNA genes were determined by analysis of the strain distribution patterns of two polymorphic variant RNAs, mU1a2 and mU1b3, in several recombinant inbred strain systems. The locus for mU1b3 RNA maps to the U1 gene cluster, Rnu1b, located near the center of chromosome 3, whereas the locus for mU1a2 RNA, Rnu1a2, is located in the proximal region of chromosome 12, tightly linked to D12-1. Moreover, the lack of linkage between Rnu1a2 and the locus for mU1a1 genes on chromosome 11 demonstrates that the mouse genome contains at least three clusters of U1 snRNA genes.

Multiple functional motifs in the chicken U1 RNA gene enhancer

The DNA sequence requirements of chicken U1 RNA gene expression have been examined in an oocyte transcription system. An enhancer region, which was required for efficient U1 RNA gene expression, is contained within a region of conserved DNA sequences spanning nucleotide positions -230 to -183, upstream of the transcriptional initiation site. These DNA sequences can be divided into at least two distinct subregions or domains that acted synergistically to provide a greater than 20-fold stimulation of U1 RNA synthesis. The first domain contains the octamer sequence ATGCAAAT and was recognized by a DNA-binding factor present in HeLa cell extracts. The second domain (the SPH domain) consists of conserved sequences immediately downstream of the octamer and is an essential component of the enhancer. In the oocyte, the DNA sequences of the SPH domain were able to enhance gene expression at least 10-fold in the absence of the octamer domain. In contrast, the octamer domain, although required for full U1 RNA gene activity, was unable to stimulate expression in the absence of the adjacent downstream DNA sequences. These findings imply that sequences 3' of the octamer play a major role in the function of the chicken U1 RNA gene enhancer. This concept was supported by transcriptional competition studies in which a cloned chicken U4B RNA gene was used to compete for limiting transcription factors in oocytes. Multiple sequence motifs that can function in a variety of cis-linked configurations may be a general feature of vertebrate small nuclear RNA gene enhancers.

Transcriptional signals of a U4 small nuclear RNA gene

The signals controlling the expression of a chicken U4 small nuclear RNA (snRNA) gene have been studied by microinjection into Xenopus oocytes. At least two distinct regions in the 5'-flanking DNA contribute to U4B RNA gene expression. The proximal regulatory element, which is inactivated by a 5'-flanking DNA deletion to position -38, provides a basal level of U4B RNA synthesis. The distal regulatory region, centered near position -200, acts as a transcriptional enhancer. It provides a 4-5 fold stimulation of U4B RNA gene expression above the basal level, and, like mRNA enhancers, is composed of multiple functional motifs. One of these, the octamer sequence ATGCAAAG, has previously been recognized as an important element of U1 and U2 snRNA gene enhancers, as well as being involved in the expression of a number of mRNA genes. However, the octamer sequence is not sufficient for U4B enhancer activity. An additional element, an "Sph motif," is located 12 base pairs downstream of the octamer and is an essential component of the U4B enhancer. Transcriptional competition studies indicate that the U4B and U1 snRNA genes utilize a common set of transcription factors.