Isolation and characterization of two linked mouse U1b small nuclear RNA genes

Regulation of expression of human RNA polymerase II-transcribed snRNA genes

In addition to protein-coding genes, RNA polymerase II (pol II) transcribes numerous genes for non-coding RNAs, including the small-nuclear (sn)RNA genes. snRNAs are an important class of non-coding RNAs, several of which are involved in pre-mRNA splicing. The molecular mechanisms underlying expression of human pol II-transcribed snRNA genes are less well characterized than for protein-coding genes and there are important differences in expression of these two gene types. Here, we review the DNA features and proteins required for efficient transcription of snRNA genes and co-transcriptional 3′ end formation of the transcripts.

Expression of histone-U1 snRNA chimeric genes: U1 promoters are compatible with histone 3' end formation

Chimeric genes which fuse the mouse histone H2a gene and the mouse U1b gene were constructed and introduced into CHO cells by cotransfection. In the UH genes, the U1b gene promoter and the start of the U1b gene were fused to the H2a gene in the 5' untranslated region. In the HU genes, the U1b 3' end was inserted into the 3' untranslated region of the H2a gene replacing the normal histone 3' end. Transcripts from the UH genes initiated at the start of the U1 gene and ended at the normal histone 3' end. Transcripts from the HU chimeric genes did not end at the U1 3' end but extended at least 80 nucleotides further and had heterogeneous 3' ends. Placing both a U1 snRNA promoter and a U1 snRNA 3' end around a histone coding region resulted in transcripts which initiate and terminate at the appropriate U1 ends. These results are consistent with previous reports that formation of the U1 3' ends require U1 promoters, but indicate that the histone 3' end can be formed on transcripts initiating at U1 promoters. The transcripts initiated at the U1 start site and ending at the histone 3' end are present on polyribosomes and show proper posttranscriptional regulation.

Variant U1 snRNAs are implicated in human pluripotent stem cell maintenance and neuromuscular disease

The U1 small nuclear (sn)RNA (U1) is a multifunctional ncRNA, known for its pivotal role in pre-mRNA splicing and regulation of RNA 3' end processing events. We recently demonstrated that a new class of human U1-like snRNAs, the variant (v)U1 snRNAs (vU1s), also participate in pre-mRNA processing events. In this study, we show that several human vU1 genes are specifically upregulated in stem cells and participate in the regulation of cell fate decisions. Significantly, ectopic expression of vU1 genes in human skin fibroblasts leads to increases in levels of key pluripotent stem cell mRNA markers, including NANOG and SOX2. These results reveal an important role for vU1s in the control of key regulatory networks orchestrating the transitions between stem cell maintenance and differentiation. Moreover, vU1 expression varies inversely with U1 expression during differentiation and cell re-programming and this pattern of expression is specifically de-regulated in iPSC-derived motor neurons from Spinal Muscular Atrophy (SMA) type 1 patient's. Accordingly, we suggest that an imbalance in the vU1/U1 ratio, rather than an overall reduction in Uridyl-rich (U)-snRNAs, may contribute to the specific neuromuscular disease phenotype associated with SMA.

Identification and characterization of U1 small nuclear RNA genes from two crustacean isopod species

Four different units containing three variants of the U1 snRNA gene have been identified in the genome of Asellus aquaticus and only one unit has been identified in the genome of Proasellus coxalis. All four identified U1 snRNA genes can be folded according to the proper secondary structure and possess the functionally useful conserved sequences. Moreover, in the 3 flanking regions, all genes present both the 3 box, a conserved sequence required for 3 processing of mature snRNA, and a polyadenylation signal which is unusual for these genes. The PCR products were used as probes in fluorescent in-situ hybridization (FISH) experiments to locate them on chromosomes of A. aquaticus and P. coxalis.

Increasing the distance between the snRNA promoter and the 3' box decreases the efficiency of snRNA 3'-end formation

Chimeric genes which contained the mouse U1b snRNA promoter, portions of the histone H2a or globin coding regions and the U1b 3'-end followed by a histone 3'-end were constructed. The distance between the U1 promoter and the U1 3' box was varied between 146 and 670 nt. The chimeric genes were introduced into CHO cells by stable transfection or into Xenopus oocytes by microinjection. The efficiency of utilization of the U1 3' box, as measured by the relative amounts of transcripts that ended at the U1 3' box and the histone 3'-end, was dependent on the distance between the promoter and 3'-end box. U1 3'-ends were formed with >90% efficiency on transcripts shorter than 200 nt, with 50-70% efficiency on transcripts of 280-400 nt and with only 10-20% efficiency on transcripts >500 nt. Essentially identical results were obtained after stable transfection of CHO cells or after injecting the genes into Xenopus oocytes. The distance between the U1 promoter and the U1 3' box must be <280 nt for efficient transcription termination at the U1 3' box, regardless of the sequence transcribed.

The histone mRNA 3' end is required for localization of histone mRNA to polyribosomes

The final step in mRNA biosynthesis is transport of the mRNA from the nucleus to the cytoplasm. Histone genes from which the 3' stem-loop has been deleted are transcribed to give RNAs with heterogeneous 3' ends. These RNAs are localized in the nucleus and are stable. Addition of the histone 3' processing signal either on short (< 250 nts) or long (> 1000 nts) transcripts restores 3' processing and transport of the mRNA to the cytoplasm. In addition chimeric histone-U1 snRNA genes which produced RNAs with either histone or U1 3' ends were analyzed. Transcripts which ended with U1 snRNA 3' ends were not efficiently localized to polyribosomes. However, transcripts containing the same sequences including the snRNA 3' end followed by the histone 3' end were present in the cytoplasm on polyribosomes. Taken together these results suggest that the histone 3' end is required for export of histone mRNA to the cytoplasm and association of the mRNA with polyribosomes.

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.

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.

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).

Regulation of histone mRNA in the unperturbed cell cycle: evidence suggesting control at two posttranscriptional steps

The levels of histone mRNA increase 35-fold as selectively detached mitotic CHO cells progress from mitosis through G1 and into S phase. Using an exogenous gene with a histone 3' end which is not sensitive to transcriptional or half-life regulation, we show that 3' processing is regulated as cells progress from G1 to S phase. The half-life of histone mRNA is similar in G1- and S-phase cells, as measured after inhibition of transcription by actinomycin D (dactinomycin) or indirectly after stabilization by the protein synthesis inhibitor cycloheximide. Taken together, these results suggest that the change in histone mRNA levels between G1- and S-phase cells must be due to an increase in the rate of biosynthesis, a combination of changes in transcription rate and processing efficiency. In G2 phase, there is a rapid 35-fold decrease in the histone mRNA concentration which our results suggest is due primarily to an altered stability of histone mRNA. These results are consistent with a model for cell cycle regulation of histone mRNA levels in which the effects on both RNA 3' processing and transcription, rather than alterations in mRNA stability, are the major mechanisms by which low histone mRNA levels are maintained during G1.

Regulation of histone mRNA in the unperturbed cell cycle: evidence suggesting control at two posttranscriptional steps

The levels of histone mRNA increase 35-fold as selectively detached mitotic CHO cells progress from mitosis through G1 and into S phase. Using an exogenous gene with a histone 3' end which is not sensitive to transcriptional or half-life regulation, we show that 3' processing is regulated as cells progress from G1 to S phase. The half-life of histone mRNA is similar in G1- and S-phase cells, as measured after inhibition of transcription by actinomycin D (dactinomycin) or indirectly after stabilization by the protein synthesis inhibitor cycloheximide. Taken together, these results suggest that the change in histone mRNA levels between G1- and S-phase cells must be due to an increase in the rate of biosynthesis, a combination of changes in transcription rate and processing efficiency. In G2 phase, there is a rapid 35-fold decrease in the histone mRNA concentration which our results suggest is due primarily to an altered stability of histone mRNA. These results are consistent with a model for cell cycle regulation of histone mRNA levels in which the effects on both RNA 3' processing and transcription, rather than alterations in mRNA stability, are the major mechanisms by which low histone mRNA levels are maintained during G1.

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.

RNA synthesis and stability in UV-irradiated and nonirradiated mouse L cells

In mouse L cells, relatively low doses of UV light (e.g., about 35 J/m2) induced the rapid breakdown of the molecules of many RNA species transcribed shortly before irradiation. This included 28S, 18S, 5.8S, and 5S rRNA, U1, U2, U3, U4, and U5 small nuclear RNA, but not the main band of transfer RNAs or 7SL RNA. At higher UV doses, an RNA band that contains tRNAleu was also degraded rapidly after UV irradiation. RNA molecules synthesized long before irradiation (e.g., 22 h for small RNAs, 4 h for large rRNAs) were not affected. Our results suggest that the maturation and/or assembly into fully mature ribonucleoprotein particles of several small RNA species is not completed 4 h after transcription. The effect of UV radiation occurred in mouse L cells, but not in human HeLa or KB cells. In a previous report, L cells were transformed by DNA transfection with two mouse U1b RNA genes, named U1.1 and U1.2. We observed now that, in L cells transformed with the U1.2 gene, the ratio of radioactivity in the apparent U1b and U1a RNA precursors after 5 min of labeling was about 20 times higher than a) this ratio in briefly labeled L cells that had been transformed with the U1.1 gene, and b) the ratio of radioactive mature U1b and U1a RNA after 20 h of chase in L cells transformed with the U1.2 gene. These results suggest that very high levels of U1b RNA are transcribed from the exogenous U1.2 gene copies, followed by the rapid degradation of most of these transcripts.

Heterogeneity of human U1 snRNAs

I demonstrate that the U1 snRNAs of human cells are heterogeneous in sequence. Polyacrylamide gel and RNase T1 fingerprint analyses of U1 RNAs isolated from a variety of human cultured cells, including HeLa, 293, K562 and NT2/D1, show that minor variants of the human U1 RNA (hUla) comprise between 5% and 15% of the total U1 RNAs in these established cell lines. The patterns of variants are cell line specific, suggesting that expression of these minor species of hUla RNAs reflect polymorphisms of the hUla true genes rather than existence of an additional class of human embryonic U1 genes. Also, the hUla variants described here are not the products of previously identified human U1 Class I pseudogenes.

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%.

Three types of rat U1 small nuclear RNA genes with different flanking sequences are induced to express in vivo

There are about 50 copies of U1 RNA genes/pseudogenes in the rat genome. To date, we have isolated so far 25 phage clones carrying a U1 RNA gene/pseudogene from two rat genomic libraries. The 12 clones were selected by hybridization with the U1 RNA coding region under a stringent condition, and were mapped and sequenced. Here, we report three types of U1 RNA genes with different flanking sequences, all of which were shown to be induced to express in vivo by transfection with their polylinker-inserted maxi U1 RNA genes into cultured rat cells. Although these three classes of U1 RNA genes have few homologous flanking sequences, they provide both upstream and downstream of the genes two conserved blocks, which may possibly play an important role in U1 RNA expression.

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.

Synthesis of U1 RNA in isolated mouse cell nuclei: initiation and 3'-end formation

The transcription of U1 RNA genes was studied in isolated nuclei from mouse myeloma cells. Using a cloned U1b gene as a probe, we showed that isolated nuclei synthesize both U1b and U1a RNA. The U1 RNAs were initiated in vitro, as measured by incorporation of adenosine 5'-O-(2-thiotriphosphate) into U1 RNA. There was transcription of the 3'-flanking region but no transcription of regions directly 5' to the U1 genes. In addition to U1 RNAs of the correct length which were released from the nuclei, there were larger RNAs, presumably resulting from transcription into the 3'-flanking region, which were retained in the nuclei. Chase experiments showed that these longer transcripts were not precursors to mature U1 RNA, a finding consistent with the idea that 3'-end formation is coincident with transcription. During the chase, there was maturation of the 3' ends of U1a and U1b RNAs from slightly longer precursors. In addition to accurate transcription of U1 RNA, there was also synthesis of U2 and U3 RNA. All three of these RNAs were transcribed by RNA polymerase II, as measured by their sensitivity to alpha-amanitin.

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.

Mapping and gene order of U1 small nuclear RNA, endogenous viral env sequence, amylase, and alcohol dehydrogenase-3 on mouse chromosome 3

Linkage was established between a number of genes that map on chromosome 3 by studying the distribution patterns of DNA polymorphisms and protein electrophoretic mobility polymorphisms in recombinant inbred (RI) strains of mice. This analysis resulted in the following suggested gene order between the newly assigned genes and previously mapped genes: gamma-fibrinogen (Fgg), Xmmv-22 of mink cell focus-inducing (MCF) virus, U1b small nuclear RNA gene cluster (Rnu-1b), amylase (Amy-1,2), cadmium resistance (cdm), alcohol dehydrogenase-3 (Adh-3), alcohol dehydrogenase-1 (Adh-1). In situ hybridization to chromosome spreads confirmed the assignment of the Ulb small nuclear RNA (snRNA) gene cluster and the gamma-fibrinogen gene to the center of chromosome 3.

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.

Accurate and efficient 3' processing of U2 small nuclear RNA precursor in a fractionated cytoplasmic extract

The small nuclear RNAs U1, U2, U4, and U5 are cofactors in mRNA splicing and, like the pre-mRNAs with which they interact, are transcribed by RNA polymerase II. Also like mRNAs, mature U1 and U2 RNAs are generated by 3' processing of their primary transcripts. In this study we have investigated the in vitro processing of an SP6-transcribed human U2 RNA precursor, the 3' end of which matches that of authentic human U2 RNA precursor molecules. Although the SP6-U2 RNA precursor was efficiently processed in an ammonium sulfate-fractionated HeLa cytoplasmic S100 extract, the product RNA was unstable. Further purification of the processing activity on glycerol gradients resolved a 7S activity that nonspecifically cleaved all RNAs tested and a 15S activity that efficiently processed the 3' end of pre-U2 RNA. The 15S activity did not process the 3' end of a tRNA precursor molecule. As demonstrated by RNase protection, the processed 3' end of the SP6-U2 RNA maps to the same nucleotides as does mature HeLa U2 RNA.

Synthesis of U1 RNA in isolated mouse cell nuclei: initiation and 3'-end formation

The transcription of U1 RNA genes was studied in isolated nuclei from mouse myeloma cells. Using a cloned U1b gene as a probe, we showed that isolated nuclei synthesize both U1b and U1a RNA. The U1 RNAs were initiated in vitro, as measured by incorporation of adenosine 5'-O-(2-thiotriphosphate) into U1 RNA. There was transcription of the 3'-flanking region but no transcription of regions directly 5' to the U1 genes. In addition to U1 RNAs of the correct length which were released from the nuclei, there were larger RNAs, presumably resulting from transcription into the 3'-flanking region, which were retained in the nuclei. Chase experiments showed that these longer transcripts were not precursors to mature U1 RNA, a finding consistent with the idea that 3'-end formation is coincident with transcription. During the chase, there was maturation of the 3' ends of U1a and U1b RNAs from slightly longer precursors. In addition to accurate transcription of U1 RNA, there was also synthesis of U2 and U3 RNA. All three of these RNAs were transcribed by RNA polymerase II, as measured by their sensitivity to alpha-amanitin.

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.

Accurate and efficient 3' processing of U2 small nuclear RNA precursor in a fractionated cytoplasmic extract

The small nuclear RNAs U1, U2, U4, and U5 are cofactors in mRNA splicing and, like the pre-mRNAs with which they interact, are transcribed by RNA polymerase II. Also like mRNAs, mature U1 and U2 RNAs are generated by 3' processing of their primary transcripts. In this study we have investigated the in vitro processing of an SP6-transcribed human U2 RNA precursor, the 3' end of which matches that of authentic human U2 RNA precursor molecules. Although the SP6-U2 RNA precursor was efficiently processed in an ammonium sulfate-fractionated HeLa cytoplasmic S100 extract, the product RNA was unstable. Further purification of the processing activity on glycerol gradients resolved a 7S activity that nonspecifically cleaved all RNAs tested and a 15S activity that efficiently processed the 3' end of pre-U2 RNA. The 15S activity did not process the 3' end of a tRNA precursor molecule. As demonstrated by RNase protection, the processed 3' end of the SP6-U2 RNA maps to the same nucleotides as does mature HeLa U2 RNA.

Only two of the four sites of interaction with nuclear factors within the Xenopus U2 gene promoter are necessary for efficient transcription

An analysis, performed by DNase I footprinting, of the interactions between factors present in Molt-4 nuclear extracts and a Xenopus U2 snRNA gene promoter is presented. Four distinct regions of sequence-specific DNA-factor interaction are found. Two of these correspond to the previously identified proximal and distal sequence elements (PSE and DSE) of the promoter. Both of these elements are important in U2 transcription, indicating a functional role for the observed interactions. The other two sites of interaction correspond to a sequence element conserved in many, but not all, vertebrate U snRNA gene promoters (the MSE) and to a region adjacent to the site of transcription initiation (the "cap site"). Site-directed mutants of these latter two elements are constructed which no longer bind nuclear factors. Transcriptional analysis in Xenopus oocytes reveals that these mutants are transcribed as efficiently as wild-type U2. Other possible roles for the two factors are discussed.

Structural and functional analysis of chicken U4 small nuclear RNA genes

Two distinct chicken U4 RNA genes have been cloned and characterized. They are closely linked within 465 base pairs of each other and have the same transcriptional orientation. The downstream U4 homology is a true gene, based on the criteria that it is colinear with chicken U4B RNA and is expressed when injected into Xenopus laevis oocytes. The upstream U4 homology, however, contains seven base substitutions relative to U4B RNA. This sequence may be a nonexpressed pseudogene, but the pattern of base substitutions suggests that it more probably encodes a variant yet functional U4 RNA product not yet characterized at the RNA level. In support of this, the two U4 genes have regions of homology with each other in their 5'-flanking DNA at two positions known to be essential for the efficient expression of vertebrate U1 and U2 small nuclear RNA genes. In the case of U1 and U2 RNA genes, the more distal region (located near position-200 with respect to the RNA cap site) is known to function as a transcriptional enhancer. Although this region is highly conserved in overall structure and sequence among U1 and U2 RNA genes, it is much less conserved in the chicken U4 RNA genes reported here. Interestingly, short sequence elements present in the -200 region of the U4 RNA genes are inverted (i.e., on the complementary strand) relative to their usual orientation upstream of U1 and U2 RNA genes. Thus, the -200 region of the U4 RNA genes may represent a natural evolutionary occurrence of an enhancer sequence inversion.

U1 precursors: variant 3' flanking sequences are transcribed in human cells

Using RNase protection and oligonucleotide hybridization experiments, we have shown that U1 precursors are derived by transcription of 3' flanking sequences. A labeled SP6 transcript of one of the true U1 genes (pD2) was able to protect a subset of the 3' flanking sequences present in HeLa cytoplasmic U1 RNA. However, not all U1 precursors were protected using this probe, suggesting that variant U1 precursor 3' tail sequences are expressed in HeLa cells. This conclusion has been confirmed by hybridization of HeLa RNA samples with specific oligonucleotide probes representing variant U1 3' flanking sequences. Interestingly, these variant tail sequences contain the putative Sm antigen binding site, A(U)3-6G. The conservation of this flanking sequence through evolution suggests a possible functional role for these precursor tails in ordering protein binding to U1 RNA.

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

Four genes that encode mouse U1a1, U1b2 and U1b6 snRNAs have been isolated from a mouse genomic DNA library. They all appear to be functional U1 genes since they are accurately transcribed into full length, capped snRNAs upon injection into Xenopus oocytes. A mouse pseudogene that is not transcribed in Xenopus oocytes was also isolated from the mouse genomic library. DNA sequence analysis of the 5' and 3' flanking regions of the functional genes revealed the presence of three highly conserved sequence elements that have been shown to be required for transcription initiation or 3' end formation in other U1 genes. Each of these U1 RNA genes also contains non-conserved sequences in the 5' flanking region that could function in their controlled expression during development.

Structure and expression of a second sea urchin U1 RNA gene repeat

There are two tandemly repeated sets of U1 RNA genes in the sea urchin L. variegatus. Each of these genes is present in a 1.4 kb repeat defined by a HindIII site about 450 bases 5' to the gene. The sequences of a member of both repeating units (U1.1 and U1.2) has been determined. The repeats are nearly identical for 550 nucleotides 5' to the gene but show great divergence starting 30 nucleotides 3' to the gene, just after the CAAAGAAAGAAAA sequence thought to be required for 3' end formation. The other boundary between the conserved and non-conserved sequences is a polypyrimidine sequence (on the strand which codes for U1 RNA). Both of these repeats are expressed in blastula stage embryos, as judged by transcription of unique sequences 3' to the gene in nuclei isolated from blastula stage embryos. At least some of the two types of repeats are interspersed, since representatives of both repeat types on a single gamma phage isolated from a gene library. The sequence of the U1 RNA in L. variegatus eggs and embryos corresponds to the sequence of the U1 repeat.

Structural and functional analysis of chicken U4 small nuclear RNA genes

Two distinct chicken U4 RNA genes have been cloned and characterized. They are closely linked within 465 base pairs of each other and have the same transcriptional orientation. The downstream U4 homology is a true gene, based on the criteria that it is colinear with chicken U4B RNA and is expressed when injected into Xenopus laevis oocytes. The upstream U4 homology, however, contains seven base substitutions relative to U4B RNA. This sequence may be a nonexpressed pseudogene, but the pattern of base substitutions suggests that it more probably encodes a variant yet functional U4 RNA product not yet characterized at the RNA level. In support of this, the two U4 genes have regions of homology with each other in their 5'-flanking DNA at two positions known to be essential for the efficient expression of vertebrate U1 and U2 small nuclear RNA genes. In the case of U1 and U2 RNA genes, the more distal region (located near position-200 with respect to the RNA cap site) is known to function as a transcriptional enhancer. Although this region is highly conserved in overall structure and sequence among U1 and U2 RNA genes, it is much less conserved in the chicken U4 RNA genes reported here. Interestingly, short sequence elements present in the -200 region of the U4 RNA genes are inverted (i.e., on the complementary strand) relative to their usual orientation upstream of U1 and U2 RNA genes. Thus, the -200 region of the U4 RNA genes may represent a natural evolutionary occurrence of an enhancer sequence inversion.

Human U1 small nuclear RNA genes: extensive conservation of flanking sequences suggests cycles of gene amplification and transposition

The DNA immediately flanking the 164-base-pair U1 RNA coding region is highly conserved among the approximately 30 human U1 genes. The U1 multigene family also contains many U1 pseudogenes (designated class I) with striking although imperfect flanking homology to the true U1 genes. Using cosmid vectors, we now have cloned, characterized, and partially sequenced three 35-kilobase (kb) regions of the human genome spanning U1 homologies. Two clones contain one true U1 gene each, and the third bears two class I pseudogenes 9 kb apart in the opposite orientation. We show by genomic blotting and by direct DNA sequence determination that the conserved sequences surrounding U1 genes are much more extensive than previously estimated: nearly perfect sequence homology between many true U1 genes extends for at least 24 kb upstream and at least 20 kb downstream from the U1 coding region. In addition, the sequences of the two new pseudogenes provide evidence that class I U1 pseudogenes are more closely related to each other than to true genes. Finally, it is demonstrated elsewhere (Lindgren et al., Mol. Cell. Biol. 5:2190-2196, 1985) that both true U1 genes and class I U1 pseudogenes map to chromosome 1, but in separate clusters located far apart on opposite sides of the centromere. Taken together, these results suggest a model for the evolution of the U1 multigene family. We speculate that the contemporary family of true U1 genes was derived from a more ancient family of U1 genes (now class I U1 pseudogenes) by gene amplification and transposition. Gene amplification provides the simplest explanation for the clustering of both U1 genes and class I pseudogenes and for the conservation of at least 44 kb of DNA flanking the U1 coding region in a large fraction of the 30 true U1 genes.

Sequences of four mouse histone H3 genes: implications for evolution of mouse histone genes

The sequences of four histone H3 genes coding for the replication variant proteins H3.1 and H3.2 have been determined. Three of these genes, two coding for H3.1 proteins and one for an H3.2 protein, are located on chromosome 13 and expressed at low levels. The fourth gene, encoding an H3.2 protein, is located on chromosome 3 and expressed at a high level. The coding regions of the three genes on chromosome 13 are more similar to each other than to the H3 gene on chromosome 3, and equally divergent from it, suggesting that either gene duplication or gene conversion has occurred since the genes were dispersed onto two chromosomes. A 14-base sequence including the CCAAT sequence and located 5' to the genes on chromosome 13 has been conserved. The histone H3 gene on chromosome 3 has multiple potential binding sites for the Sp1 transcription factor. The coding regions show greater than 95% conservation among the four genes. This is due to the strict pattern of codon usage and the presence of two long (greater than 60 base) regions of completely conserved nucleic acid sequence. These conserved regions in the coding sequence may have an important functional role at the mRNA or DNA level.

Isolation and characterization of a human U3 small nucleolar RNA gene

U3 RNA is an abundant, capped, small nucleolar RNA, implicated in the processing of preribosomal RNA. In this study, a DNA clone coding for U3 RNA (clone U3-1) was isolated from a human genomic library and characterized. The DNA sequence was identical to that of human U3 RNA isolated from HeLa cells. The flanking regions showed homology to the enhancer, promoter, and 3'-processing signal found in U1 and U2 snRNA genes. Further, the recently identified "U3 box" (GATTGGCTGCN10TATGTTAATTATGG) of rat U3 genes (Stroke and Weiner, (1985) J. Mol. Biol. 184, 183-193), was also found in the human U3 gene. This gene was transcribed in Xenopus oocytes; it is the first cloned true human U3 gene.

Synthesis of U1 RNA in a DNA-dependent system from sea urchin embryos

A soluble extract prepared from blastula nuclei of sea urchin (Lytechinus variegatus) embryos accurately transcribes cloned sea urchin DNA. This extract synthesizes U1 RNA using a cloned U1 RNA gene as a template. The U1 RNA is initiated accurately, and a portion of the transcripts has the correct 3' end as judged by gel electrophoresis. Longer transcripts also are formed that extend at least 280 bases 3' of the gene, and some extend as far as 800 bases 3' of the gene. A template containing 203 bases 5' of the gene gave as efficient transcription as did the whole U1 gene. Accurate 3' end formation was obtained with a template extending only 34 bases 3' of the gene, but efficient 3' end formation required sequences between 34 and 67 bases 3' of the gene.

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.

Analysis of a sea urchin gene cluster coding for the small nuclear U7 RNA, a rare RNA species implicated in the 3' editing of histone precursor mRNAs

A genomic 9.3-kilobase DNA fragment of the sea urchin Psammechinus miliaris, containing a cluster of five U7-RNA genes (or pseudogenes), has been isolated and analyzed by partial DNA sequencing. The U7-RNA coding sequences differ from one another by one or two nucleotides, one of the five gene sequences being identical to those of the cDNA U73 clone prepared earlier [Strub, K., Galli, G., Busslinger, M. & Birnstiel, M. L. (1984) EMBO J. 3, 2801-2807]. The spacer sequences separating the genes have, on the whole, a low degree of homology; hence, the five genes must have arisen by an ancient duplication event. The sequences preceding the coding portion contain three highly conserved sequence motifs but no "TATA box." The 3' flanking sequences include a highly conserved AAAGNNAGA sequence that is held in common with other U-RNA genes from both sea urchins and vertebrates. Our findings confirm our classification of the U7 RNA as a genuine, if sparsely represented, member of the U-RNA family.

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.

Orientation-dependent transcriptional activator upstream of a human U2 snRNA gene

We examined the structure of the promoter for the human U2 snRNA gene, a strong RNA polymerase II transcription unit without an obvious TATA box. A set of 5' deletions was constructed and assayed for the ability to direct initiation of U2 snRNA after microinjection into Xenopus oocytes. Sequences between positions -295 and -218 contain an activator element which stimulates accurate initiation by 20- to 50-fold, although as few as 62 base pairs of 5' flanking sequence are sufficient to direct the accurate initiation of U2 RNA. When the activator was recloned in the proper orientation at either of two different upstream locations, the use of the normal U2 start site was stimulated. Inversion of the element destroyed the stimulation of accurate U2 initiation, but initiation at aberrant upstream start sites was enhanced by the element in both orientations. A 4-base-pair deletion that destroyed the activity of the element lies within a sequence (region III) which is highly conserved among U2 genes from different organisms. Mutations in the activator also affected the ability of the U2 template to compete with a wild-type U1 gene in coinjection experiments. We propose that the element enhances the efficiency of transcription in part by facilitating the association of a limiting factor with transcription complexes. Human U1 snRNA genes possess a region homologous to U2 region III, and we suggest that upstream activator elements may be a general feature of snRNA promoters.

Human U1 small nuclear RNA genes: extensive conservation of flanking sequences suggests cycles of gene amplification and transposition

The DNA immediately flanking the 164-base-pair U1 RNA coding region is highly conserved among the approximately 30 human U1 genes. The U1 multigene family also contains many U1 pseudogenes (designated class I) with striking although imperfect flanking homology to the true U1 genes. Using cosmid vectors, we now have cloned, characterized, and partially sequenced three 35-kilobase (kb) regions of the human genome spanning U1 homologies. Two clones contain one true U1 gene each, and the third bears two class I pseudogenes 9 kb apart in the opposite orientation. We show by genomic blotting and by direct DNA sequence determination that the conserved sequences surrounding U1 genes are much more extensive than previously estimated: nearly perfect sequence homology between many true U1 genes extends for at least 24 kb upstream and at least 20 kb downstream from the U1 coding region. In addition, the sequences of the two new pseudogenes provide evidence that class I U1 pseudogenes are more closely related to each other than to true genes. Finally, it is demonstrated elsewhere (Lindgren et al., Mol. Cell. Biol. 5:2190-2196, 1985) that both true U1 genes and class I U1 pseudogenes map to chromosome 1, but in separate clusters located far apart on opposite sides of the centromere. Taken together, these results suggest a model for the evolution of the U1 multigene family. We speculate that the contemporary family of true U1 genes was derived from a more ancient family of U1 genes (now class I U1 pseudogenes) by gene amplification and transposition. Gene amplification provides the simplest explanation for the clustering of both U1 genes and class I pseudogenes and for the conservation of at least 44 kb of DNA flanking the U1 coding region in a large fraction of the 30 true U1 genes.

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.

Synthesis of U1 RNA in isolated nuclei from sea urchin embryos: U1 RNA is initiated at the first nucleotide of the RNA

Nuclei from sea urchin blastula embryos synthesize a variety of small RNAs, one of which has identical mobility with sea urchin U1 RNA. This RNA is synthesized by RNA polymerase II and, in a hybridization-selection experiment, was selected by the cloned sea urchin U1 gene. The U1 RNA was initiated with ATP, but not GTP, in isolated nuclei with beta-S- and gamma-S-ribonucleotide triphosphates as substrates. The U1 RNA containing thiophosphate at the 5' end was not capped but accumulated as an uncapped transcript from which the thiophosphate could be removed with calf intestinal phosphatase.

Genes and pseudogenes for rat U3A and U3B small nuclear RNA

We report here the isolation and primary structure of two genes encoding rat U3 small nuclear RNA. One of the genes encodes U3B RNA; the other encodes an RNA which is almost identical to U3A RNA. Both genes are expressed after microinjection into the nuclei of Xenopus laevis oocytes and can direct the accumulation of mature U3 RNA as well as longer transcripts which may be the U3 precursors. We have also isolated and sequenced four other regions of the rat genome homologous to U3 RNA. One of these almost certainly represents a second U3B gene; the other three are pseudogenes which appear to have been generated by the reverse flow of genetic information from U3 RNA back into the genome. Using genomic blotting techniques, we show that the rat U3 genes are present in only a few copies per haploid genome and are probably not closely linked to one another.

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.