Molecular cloning and characterization of a gene for rat U2 small nuclear RNA

A 3'-terminal minihelix in the precursor of human spliceosomal U2 small nuclear RNA

U2 RNA is one of five small nuclear RNAs that participate in the majority of mRNA splicing. In addition to its role in mRNA splicing, the biosynthesis of U2 RNA and three of the other spliceosomal RNAs is itself an intriguing process involving nuclear export followed by 5'-cap hypermethylation, assembly with specific proteins, 3' end processing, and then nuclear import. Previous work has identified sequences near the 3' end of pre-U2 RNA that are required for accurate and efficient processing. In this study, we have investigated the structural basis of U2 RNA 3' end processing by chemical and enzymatic probing methods. Our results demonstrate that the 3' end of pre-U2 RNA is a minihelix with an estimated stabilization free energy of -6.9 kcal/mol. Parallel RNA structure mapping experiments with mutant pre-U2 RNAs revealed that the presence of this 3' minihelix is itself not required for in vitro 3'-processing of pre-U2 RNA, in support of earlier studies implicating internal regions of pre-U2 RNA. Other considerations raise the possibility that this distinctive structural motif at the 3' end of pre-U2 RNA plays a role in the cleavage of the precursor from its longer primary transcript or in its nucleocytoplasmic traffic.

3' processing of human pre-U2 small nuclear RNA: a base-pairing interaction between the 3' extension of the precursor and an internal region

The spliceosomal small nuclear RNAs U1, U2, U4, and U5 are transcribed by RNA polymerase II as precursors with extensions at their 3' ends. The 3' processing of these pre-snRNAs is not understood in detail. Two pathways of pre-U2 RNA 3' processing in vitro were revealed in the present investigation by using a series of human wild-type and mutant pre-U2 RNAs. Substrates with wild-type 3' ends were initially shortened by three or four nucleotides (which is the first step in vivo), and the correct mature 3' end was then rapidly generated. In contrast, certain mutant pre-U2 RNAs displayed an aberrant 3' processing pathway typified by the persistence of intermediates representing cleavage at each internucleoside bond in the precursor 3' extension. Comparison of the wild-type and mutant pre-U2 RNAs revealed a potential base-pairing interaction between nucleotides in the precursor 3' extension and a sequence located between the Sm domain and stem-loop III of U2 RNA. Substrate processing competition experiments using a highly purified pre-U2 RNA 3' processing activity suggested that only RNAs capable of this base-pairing interaction had high affinity for the pre-U2 RNA 3' processing enzyme. The importance of this postulated base-pairing interaction between the precursor 3' extension and the internal region between the Sm domain and stem-loop III was confirmed by the results obtained with a compensatory substitution that restores the base pairing, which displayed the normal 3' processing reaction. These results implicate a precursor-specific base-paired structure involving sequences on both sides of the mature cleavage site in the 3' processing of human U2 RNA.

U2 small nuclear RNA 3' end formation is directed by a critical internal structure distinct from the processing site

Mature U2 small nuclear RNA is generated by the removal of 11 to 12 nucleotides from the 3' end of the primary transcript. This pre-U2 RNA processing reaction takes place in the cytoplasm. In this study, the sequences and/or structures of pre-U2 RNA that are important for 3' processing have been examined in an in vitro system. The 7-methylguanosine cap, stem-loops I and II, the lariat branch site recognition sequence, the conserved Sm domain, and several other regions throughout the 5' end of U2 RNA have no apparent role in the 3' processing reaction. In fact, deletion of the entire first 104 nucleotides resulted in mini-pre-U2 RNAs which were efficiently processed. Similarly, deletion of the top two-thirds of stem-loop III or mutation of nucleotides in the loop of stem-loop IV had little effect on 3' processing. Most surprisingly, the precursor's 11- to 12-nucleotide 3' extension itself was of relatively little importance, since this sequence could be replaced with completely different sequences with only a minor effect on the 3' processing reaction. In contrast, we have defined a critical structure consisting of the bottom of stem III and the stem of stem-loop IV that is essential for 3' processing of pre-U2 RNA. Compensatory mutations which restore base pairing in this region resulted in normal 3' processing. Thus, although the U2 RNA processing activity recognizes the bottom of stem III and stem IV, the sequence of this critical region is much less important than its structure. These results, together with the surprising observation that the reaction is relatively indifferent to the sequence of the 11- to 12-nucleotide 3' extension itself, point to a 3' processing reaction of pre-U2 RNA that has sequence and structure requirements significantly different from those previously identified for pre-mRNA 3' processing.

U2 small nuclear RNA 3' end formation is directed by a critical internal structure distinct from the processing site

Mature U2 small nuclear RNA is generated by the removal of 11 to 12 nucleotides from the 3' end of the primary transcript. This pre-U2 RNA processing reaction takes place in the cytoplasm. In this study, the sequences and/or structures of pre-U2 RNA that are important for 3' processing have been examined in an in vitro system. The 7-methylguanosine cap, stem-loops I and II, the lariat branch site recognition sequence, the conserved Sm domain, and several other regions throughout the 5' end of U2 RNA have no apparent role in the 3' processing reaction. In fact, deletion of the entire first 104 nucleotides resulted in mini-pre-U2 RNAs which were efficiently processed. Similarly, deletion of the top two-thirds of stem-loop III or mutation of nucleotides in the loop of stem-loop IV had little effect on 3' processing. Most surprisingly, the precursor's 11- to 12-nucleotide 3' extension itself was of relatively little importance, since this sequence could be replaced with completely different sequences with only a minor effect on the 3' processing reaction. In contrast, we have defined a critical structure consisting of the bottom of stem III and the stem of stem-loop IV that is essential for 3' processing of pre-U2 RNA. Compensatory mutations which restore base pairing in this region resulted in normal 3' processing. Thus, although the U2 RNA processing activity recognizes the bottom of stem III and stem IV, the sequence of this critical region is much less important than its structure. These results, together with the surprising observation that the reaction is relatively indifferent to the sequence of the 11- to 12-nucleotide 3' extension itself, point to a 3' processing reaction of pre-U2 RNA that has sequence and structure requirements significantly different from those previously identified for pre-mRNA 3' processing.

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.

RNA processing and ribonucleoprotein assembly studied in vivo by RNA transfection

We present a method for studying RNA processing and ribonucleoprotein assembly in vivo, by using RNA synthesized in vitro. SP6-transcribed 32P-labeled U2 small nuclear RNA precursor molecules were introduced into cultured human 293 cells by calcium phosphate-mediated uptake, as in standard DNA transfection experiments. RNase protection mapping demonstrated that the introduced pre-U2 RNA underwent accurate 3' end processing. The introduced U2 RNA was assembled into ribonucleoprotein particles that reacted with an antibody specific for proteins known to be associated with the U2 small nuclear ribonucleoprotein particle. The 3' end-processed, ribonucleoprotein-assembled U2 RNA accumulated in the nuclear fraction. When pre-U2 RNA with a 7-methylguanosine group at the 5' end was introduced into cells, it underwent conversion to a 2,2,7-trimethylguanosine cap structure, a characteristic feature of the U-small nuclear RNAs. Pre-U2 RNA introduced with an adenosine cap (Ap-ppG) also underwent processing, small nuclear ribonucleoprotein assembly, and nuclear accumulation, establishing that a methylated guanosine cap structure is not required for these steps in U2 small nuclear ribonucleoprotein biosynthesis. Beyond its demonstrated usefulness in the study of small nuclear ribonucleoprotein biosynthesis, RNA transfection may be of general applicability to the investigation of eukaryotic RNA processing in vivo and may also offer opportunities for introducing therapeutically targeted RNAs (ribozymes or antisense RNA) into cells.

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.

Transcription analysis of a human U4C gene: involvement of transcription factors novel to snRNA gene expression

We have investigated the promoter requirements for in vivo transcription of a human U4C snRNA gene following transfection into HeLa cells. Two elements required for maximal U4C transcription were identified. The first, located upstream of -50, provides a basal level of transcription 2-3% of the full activity, and probably corresponds to the previously identified snRNA gene proximal element. The distal element, centered around -220, acts as a transcriptional enhancer and contains motifs for three previously recognized transcription factors: the octamer-binding protein, NF-A, which binds to motifs in the distal elements of other snRNA genes, and two factors not previously shown to be involved in snRNA gene transcription, cAMP response element binding protein (CREB) and AP-2. The octamer and putative AP-2 motifs are required for maximal transcription of the U4C gene. Specific binding of NF-A and CREB to the motifs in the distal element has been shown in vitro by DNase I and DMS methylation protection footprint competition analyses using HeLa nuclear extracts. The presence of a binding motif for the inducible factor CREB, together with the transcriptional requirement for the putative AP-2 motif, suggests a means by which expression of snRNA genes might be regulated.

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.

Newly synthesized small nuclear RNAs appear transiently in the cytoplasm

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

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.

A role for ID repetitive sequences in growth- and transformation-dependent regulation of gene expression in rat fibroblasts

A set of mRNAs tagged by repetitive sequences of the ID family were found to accumulate following growth-factor-induced transition of normal (FR3T3) rat fibroblasts from a quiescent to a proliferative state. The levels of the same transcripts were also increased following transformation by polyoma virus and by ras and myc oncogenes. The presence of the ID element appeared to be determinant, since a similar pattern of expression was observed for a construct where one element had been inserted in the 3' noncoding region of a rabbit beta-globin gene expressed under control of an SV40 promoter.

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.

Identification of proteins interacting with the enhancer of human U2 small nuclear RNA genes

Protein/DNA interactions in the human U2 RNA gene enhancer have been characterized by DNase I footprint and DMS methylation protection analyses. Nuclear factors present in both HeLa and B cell extracts have been shown to protect an approximately 70 bp region from DNase I digestion. DMS and DNase I footprint competition studies demonstrated that the entire footprint can be accounted for by interactions with two previously identified transcription factors. One of these recognizes the so called octanucleotide-motif ATGCAAAT (transcription factor IgNF-A) which has been shown to be essential for transcription. The other is the transcription factor Sp1 which binds to three target sequences located adjacent to the octameric motif. The Sp1 interactions appear to be required for full transcriptional activity. No differences in the DNase I footprint patterns or in the DMS methylation protections were observed when nuclear extracts from HeLa cells, two different B cell lines, or from the adenovirus-transformed 293 cell line were compared.

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.

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.

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.

Transcription boundaries of U1 small nuclear RNA

Transcription-proximal stages of U1 small nuclear RNA biosynthesis were studied by 32P labeling of nascent chains in isolated HeLa cell nuclei. Labeled RNA was hybridized to nitrocellulose-immobilized, single-stranded M13 DNA clones corresponding to regions within or flanking a human U1 RNA gene. Transcription of U1 RNA was inhibited by greater than 95% by alpha-amanitin at 1 microgram/ml, consistent with previous evidence that it is synthesized by RNA polymerase II. No hybridization to DNA immediately adjacent to the 5' end of mature U1 RNA (-6 to -105 nucleotides) was detected, indicating that, like all studied polymerase II initiation, transcription of U1 RNA starts at or very near the cap site. However, in contrast to previously described transcription units for mRNA, in which equimolar transcription occurs for hundreds or thousands of nucleotides beyond the mature 3' end of the mRNA, labeled U1 RNA hybridization dropped off sharply within a very short region (approximately 60 nucleotides) immediately downstream from the 3' end of mature U1 RNA. Also in contrast to pre-mRNA, which is assembled into ribonucleoprotein (RNP) particles while still nascent RNA chains, the U1 RNA transcribed in isolated nuclei did not form RNP complexes by the criterion of reaction with a monoclonal antibody for the small nuclear RNP Sm proteins. This suggests that, unlike pre-mRNA-RNP particle formation, U1 small nuclear RNP assembly does not occur until after the completion of transcription. These results show that, despite their common synthesis by RNA polymerase II, mRNA and U1 small nuclear RNA differ markedly both in their extents of 3' processing and their temporal patterns of RNP assembly.

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.

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.

Human U2 small nuclear RNA genes contain an upstream enhancer

The human U1 and U2 snRNA genes lack an obvious TATA box, but are extremely powerful RNA polymerase II transcription units capable of accurately initiating at least one transcript per gene every 2-4 s. We have investigated the location of cis-acting regulatory elements within the flanking sequences of human U2 and U1 genes. By introducing marked human U2 genes into HeLa cells on SV40- and pUC13-based vectors, we found that transient expression of the marked U2 gene did not require the SV40 enhancer. The U2 promoter element responsible for SV40 enhancer-independent U2 expression was localized within the 5'-flanking sequence of the gene, and shown to stimulate transcription from the U2 basal promoter in an orientation- and position-independent fashion. In addition, the U2 element could be functionally replaced by either the SV40 enhancer or by distal sequences from the human U1 promoter. We conclude that the human U2 and U1 genes contain functionally equivalent enhancer elements. Moreover, since the human U2 enhancer sequences resemble the Xenopus U2 enhancer-like element, enhancers appear to be a general feature of vertebrate snRNA promoter structure.

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.

Molecular cloning and in vitro transcription of rat 4.5S RNAH genes

4.5S RNAH (4.5S RNA associated with poly A containing RNA) has extensive homology to major interspersed repeat B1 in rodent genomes. We developed a new cloning technique for screening genomic library that eliminates the signal produced by repeated sequences or pseudogenes and applied it to cloning of 4.5S RNAH genes. Six phage clones (2, 3, 6, 9, 10 and 15) which hybridize with 4.5S RNAH were isolated from a rat gene library by this method. The restriction fragments containing the 4.5S RNAH locus were subcloned into plasmids and sequenced. Clones 2, 3, 9 and 15 contained one to five base substitutions in the coding region for 4.5S RNAH and were probably pseudogenes. In clone 2, the 4.5S RNAH locus was linked directly with the identifier sequence. Clone 6 contained three copies of the 4.5S RNAH gene (6a, b and c) which were clustered in the same direction within 455 base pairs. 6b was linked directly with 6c and ubiquitous repetitive DNA sequences B2 were inserted immediately after 6a and 6c. These three sequences as well as the sequence in clone 10 were colinear with rat 4.5S RNAH. In an in vitro transcription system, only clone 10 gave intact 4.5S RNAH.

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.

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.

Transcription boundaries of U1 small nuclear RNA

Transcription-proximal stages of U1 small nuclear RNA biosynthesis were studied by 32P labeling of nascent chains in isolated HeLa cell nuclei. Labeled RNA was hybridized to nitrocellulose-immobilized, single-stranded M13 DNA clones corresponding to regions within or flanking a human U1 RNA gene. Transcription of U1 RNA was inhibited by greater than 95% by alpha-amanitin at 1 microgram/ml, consistent with previous evidence that it is synthesized by RNA polymerase II. No hybridization to DNA immediately adjacent to the 5' end of mature U1 RNA (-6 to -105 nucleotides) was detected, indicating that, like all studied polymerase II initiation, transcription of U1 RNA starts at or very near the cap site. However, in contrast to previously described transcription units for mRNA, in which equimolar transcription occurs for hundreds or thousands of nucleotides beyond the mature 3' end of the mRNA, labeled U1 RNA hybridization dropped off sharply within a very short region (approximately 60 nucleotides) immediately downstream from the 3' end of mature U1 RNA. Also in contrast to pre-mRNA, which is assembled into ribonucleoprotein (RNP) particles while still nascent RNA chains, the U1 RNA transcribed in isolated nuclei did not form RNP complexes by the criterion of reaction with a monoclonal antibody for the small nuclear RNP Sm proteins. This suggests that, unlike pre-mRNA-RNP particle formation, U1 small nuclear RNP assembly does not occur until after the completion of transcription. These results show that, despite their common synthesis by RNA polymerase II, mRNA and U1 small nuclear RNA differ markedly both in their extents of 3' processing and their temporal patterns of RNP assembly.

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.

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.

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.

Nucleocytoplasmic RNA transport

A number of closely related post-transcriptional facets of RNA metabolism show nuclear compartmentation, including capping, methylation, splicing reactions, and packaging in ribonucleoprotein particles (RNP). These nuclear 'processing' events are followed by the translocation of the finished product across the nuclear envelope. Due to the inherent complexity of these interrelated events, in vitro systems have been designed to examine the processes separately, particularly so with regard to translocation. A few studies have utilized nuclear transplantation/microinjection techniques and specialized systems to show that RNA transport occurs as a regulated phenomenon. While isolated nuclei swell in aqueous media and dramatic loss of nuclear protein is associated with this swelling, loss of RNA is not substantial, and most studies on RNA translocation have employed isolated nuclei. The quantity of RNA transported from isolated nuclei is related to hydrolysis of high-energy phosphate bonds in nucleotide additives. The RNA is released predominantly in RNP: messenger-like RNA is released in RNP which have buoyant density and polypeptide composition similar to cytoplasmic messenger RNP, but which have distinctly different composition from those in heterogeneous nuclear RNP. Mature 18 and 28S ribosomal RNA is released in 40 and 60S RNP which represent mature ribosomal subunits. RNA transport proceeds with characteristics of an energy-requiring process, and proceeds independently of the presence or state of fluidity of nuclear membranes. The energy for transport appears to be utilized by a nucleoside triphosphatase (NTPase) which is distributed mainly within heterochromatin at the peripheral lamina. Photoaffinity labeling has identified the pertinent NTPase as a 46 kD polypeptide which is associated with nuclear envelope and matrix preparations. The NTPase does not appear to be modulated via direct phosphorylation or to reflect kinase-phosphatase activities. A large number of additives (including RNA and insulin) produce parallel effects upon RNA transport and nuclear envelope NTPase, strengthening the correlative relationship between these activities. Of particular interest has been the finding that carcinogens induce specific, long-lasting increases in nuclear envelope (and matrix) NTPase; this derangement may underlie the alterations in RNA transport associated with cancer and carcinogenesis.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Formation of the 3' end of U1 snRNA is directed by a conserved sequence located downstream of the coding region

U1 is a small non-polyadenylated nuclear RNA that is transcribed by RNA polymerase II and is known to play a role in mRNA splicing. The mature 3' end of U1 snRNA is formed in at least two steps. The first step generates precursors of U1 RNA with a few extra nucleotides at the 3' end; in the second step, these precursors are shortened to mature U1 RNA. Here, I have determined the sequences required for the first step. Human U1 genes with various deletions and substitutions near the 3' end of the coding region were constructed and introduced into HeLa cells by DNA transfection. The structure of the RNA synthesized during transient expression of the exogenous U1 gene was analyzed by S1 mapping. The results show that a 13 nucleotide sequence located downstream from the U1 coding region and conserved among U1, U2 and U3 genes of different species is the only sequence required to direct the first step in the formation of the 3' end of U1 snRNA.

Ribonucleoprotein organization of eukaryotic RNA. XXXII. U2 small nuclear RNA precursors and their accurate 3' processing in vitro as ribonucleoprotein particles

Biosynthetic precursors of U2 small nuclear RNA have been identified in cultured human cells by hybrid-selection of pulse-labeled RNA with cloned U2 DNA. These precursor molecules are one to approximately 16 nucleotides longer than mature U2 RNA and contain 2,2,7-trimethylguanosine "caps". The U2 RNA precursors are associated with proteins that react with a monoclonal antibody for antigens characteristic of small nuclear ribonucleoprotein particles. Like previously described precursors of U1 and U4 small nuclear RNAs, the pre-U2 RNAs are recovered in cytoplasmic fractions, although it is not known if this is their location in vivo. The precursors are processed to mature-size U2 RNA when cytoplasmic extracts are incubated in vitro at 37 degrees C. Mg2+ is required but ATP is not. The ribonucleoprotein structure of the pre-U2 RNA is maintained during the processing reaction in vitro, as are the 2,2,7-trimethylguanosine caps. The ribonucleoprotein organization is of major importance, as exogenous, protein-free U2 RNA precursors are degraded rapidly in the in vitro system. Two lines of evidence indicate that the conversion of U2 precursors to mature-size U2 RNA involves a 3' processing reaction. First, the reaction is unaffected by a large excess of mature U2 small nuclear RNP, whose 5' trimethylguanosine caps would be expected to compete for a 5' processing activity. Second, when pre-U2 RNA precursors are first stoichiometrically decorated with an antibody specific for 2,2,7-trimethylguanosine, the extent of subsequent processing in vitro is unaffected. These results provide the first demonstration of a eukaryotic RNA processing reaction in vitro occurring within a ribonucleoprotein particle.

A family of wheat embryo U2 snRNAs

Evidence is presented for the existence of small nuclear RNAs in a higher plant species. Based on subcellular fractionation experiments, wheat embryos contain at least four putative snRNAs, one of which co-migrates on SDS-polyacrylamide gels with a relatively abundant cytoplasmic RNA, W1. We purified W1 from ribosome-free high speed supernatant fractions for characterization studies. Electrophoresis under partially denaturing conditions resolves this RNA into several components which bear m3 (2, 2, 7) G-5' caps and strongly resemble vertebrate U2 snRNA on the basis of modified nucleotide content. Preliminary sequence analyses indicate that wheat embryos contain at least three U2-like RNAs which possess slightly different sequences near their 3' ends.

Drosophila melanogaster U1 snRNA genes

We have isolated and characterized a recombinant which contains a Drosophila melanogaster U1 small nuclear RNA (snRNA) gene colinear with the published snRNA sequence. Southern hybridizations of the fly genomic DNA, using as probe a plasmid containing only the coding region of the gene, shows that the fly contains at most three or four genes and very few related sequences for the small nuclear U1 RNA. These genes were localized by in situ hybridization at different chromosomal loci and show no spatial relationship to the U2 snRNA genes.

A complete and a truncated U1 snRNA gene of Drosophila melanogaster are found as inverted repeats at region 82E of the polytene chromosomes

A phage containing two sequences homologous to U1 snRNA was isolated from a Drosophila melanogaster genomic library, and identified with a previously cloned D. melanogaster U1 snRNA gene. DNA sequence analysis showed that complete and truncated U1 snRNA genes are present, both of which have base substitutions relative to U1 snRNA. These genes show conservation of 5' and 3' flanking regions relative to other U1 and U2 snRNA genes of Drosophila. Intramolecular renaturation experiments and electron microscope mapping demonstrates that the two U1 snRNA sequences are present as inverted repeats about 2.7kb apart, separated by a smaller pair of inverted repeats of an unrelated sequence. These U1 snRNA sequences were located by in situ hybridization at 82E, and related sequences were found at 21D and 95C on the polytene chromosome map. The results are discussed with reference to the origin and function of snRNAs.

DNA sequences complementary to human 7 SK RNA show structural similarities to the short mobile elements of the mammalian genome

A complementary DNA clone of 7 SK RNA from HeLa cells was used to study the genomic organization of 7 SK sequences in the human genome. Genomic hybridizations and genomic clones show that 7 SK is homologous to a family of disperse repeated sequences most of which lack the 3' end of the 7 SK RNA sequence. Only few of the genomic K sequences are homologous to both 3' and 5' 7 SK probes and presumably include the gene(s) for 7 SK RNA. The sequence of four genomic 7 SK clones confirms that they are in most cases pseudogenes. Although Alu sequences are frequently found near the 3' and 5' end of K DNA, the sequences immediately flanking the pseudogenes are different in all clones studied. However, direct repeats were found flanking directly the K DNA or the K-Alu unit, suggesting that the K sequences alone or in conjunction with Alu DNA might constitute a mobile element.

Genes and pseudogenes for human U2 RNA. Implications for the mechanism of pseudogene formation

Three loci, designated U2/4, U2/6 and U2/7, which contain sequences related to human U2 RNA, have been studied. The U2/6 locus contains a tandem array of bona fide U2 genes. U2/4 and U2/7, in contrast, contain pseudogenes of whose sequences deviate significantly from that of mammalian U2 RNA. The two pseudogenes appear to have been created by different mechanisms. The sequences that flank the pseudogene in the U2/4 locus lack homology to the corresponding sequences in functional human U2 genes, except for 10 base-pairs immediately following the 3' end. The conserved 3'-flanking segment is homologous to those nucleotides that are present in a U2 RNA precursor. No direct repeats flank the pseudogene in the U2/4 locus. The observations thus suggest that a complementary DNA copy of the U2 RNA precursor was inserted into a blunt-ended chromosomal break to generate the U2/4 locus. The U2/7 locus, in contrast, revealed flanking sequence homology when compared to functional U2 genes, both on the 5' and 3' sides of the pseudogene. The homology was interrupted on both sides by repetitive sequences belonging to the Alu family. On the 5' side the homology continues beyond the Alu repeats whereas on the 3' side it ends precisely at the Alu repeat. This Alu repeat is inserted in a region where a homocopolymeric region of alternating C and T residues is located in functional U2 loci. The observed organization of the U2/7 locus suggests that a previously functional U2 locus was invaded by Alu repeats and subsequently accumulated base substitutions to become a pseudogene.

Three linked chicken U1 RNA genes have limited flanking DNA sequence homologies that reveal potential regulatory signals

We have isolated and characterized a cluster of three closely linked chicken U1 RNA genes from a lambda genomic library. These genes, which are completely collinear and homologous in sequence to chicken U1 RNA, are spaced about 1.8 kilobase pairs (kb) apart in the chicken genome. However, they are not tandemly repeated in that one of the genes has an inverse transcriptional orientation relative to the other two genes which are adjacent in the cluster. A comparison of sequences flanking the 5' ends of these genes reveals that homology is generally limited to a region around position -200 and to the region from -59 to -1. None of the genes possess a "TATA" box near the -25 position. The chicken sequences were compared to various mammalian snRNA genes and significant homology was observed around positions -200, -55 and -20. These data suggest that U1 RNA genes utilize an unusual RNA polymerase II promoter signal and that potential regulatory sequences are located as far as 200 bp upstream from the mature U1 RNA cap site.

Precursors of U4 small nuclear RNA

The processing and ribonucleoprotein assembly of U4 small nuclear RNA has been investigated in HeLa cells. After a 45-min pulse label with [3H]uridine, a set of apparently cytoplasmic RNAs was observed migrating just behind the gel electrophoretic position of mature U4 RNA. These molecules were estimated to be one to at least seven nucleotides longer than mature U4 RNA. They reacted with Sm autoimmune patient sera and a monoclonal Sm antibody, indicating their association with proteins characteristic of small nuclear ribonucleoprotein complexes. The same set of RNAs was identified by hybrid selection of pulse-labeled RNA with cloned U4 DNA, confirming that these are U4 RNA sequences. No larger nuclear precursors of these RNAs were detected. Pulse-chase experiments revealed a progressive decrease in the radioactivity of the U4 precursor RNAs coincident with an accumulation of labeled mature U4 RNA, confirming a precursor-product relationship.

Human genes for U2 small nuclear RNA are tandemly repeated

We found that the genes for human U2 small nuclear RNA (snRNA) are organized as a nearly perfect tandem array of 10 to 20 copies per haploid genome. Although the coding region for the mature form of U2 RNA was only 188 base pairs (bp) long, the basic repeating unit of the tandem array was 6 kilobase pairs in length. Comparison of DNA sequences immediately upstream from human U1 and U2 genes revealed two regions of strong homology: region I (15 bp long) lay upstream of region II (20 bp long) and was separated from it by about the same distance in U1 genes (25 bp) as in U2 genes (21 bp); however, region I and region II were located 174 bp further upstream from the 5' end of the snRNA coding sequence in U1 genes than in U2 genes. Homologs of region II were also found upstream of the snRNA coding region in a mouse U2 gene and two rat U1 genes. Murphy et al. (Cell 29:265-274, 1982) have found that sequences within region II may function as the equivalent of a TATA box for initiation by RNA polymerase II in vitro at a position 183 bp upstream from the 5' end of the human U1 snRNA coding region. In light of the data reported here, this result suggests that region II does indeed play a role in transcription but that its position relative to the actual initiation site can vary.

Clustered genes for human U2 RNA

Genes for the human small nuclear RNA U2 are present within 6.2-kilobase-pair-long tandem repeats. The haploid human genome contains approximately 20 such repeats, organized in one or a few very large clusters.

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

Xenopus laevis U1 snRNA genes are found in several different genomic arrangements. The major family of genes is organised in tandem repeats of 1.8 kb. The minor U1-family is much less abundant and is present on 1.2-kb HinfI restriction fragments. In addition there are genomic arrangements present in one or very few copies, which could represent the ends of repeating units. There is no evidence for the presence of U1 pseudogenes in Xenopus. A cluster of U1 snRNA genes consisting of a member of the minor class of U1 snRNA genes and two of the 'rarely represented' genes was cloned. All three genes were expressed upon microinjection into frog oocytes. A fragment containing 149 bp of 5' flanking sequence, the RNA coding sequence, and 27 bp of 3' flanking sequence was shown to be accurately transcribed into U1 snRNA. These oocyte transcripts are assembled into specific U1 snRNPs. Sequence comparison of the regions flanking Xenopus U1 and U2 snRNA genes showed the presence of two blocks of homology, which are also conserved in many other U snRNA genes. One of these blocks is found at position -60 to -50 before the coding sequence, and we discuss its possible role in the correct initiation of transcription. The other is 3' to the coding sequence and may be involved in the accurate production of mature 3' ends in the RNA.

Drosophila melanogaster U1 and U2 small nuclear RNA genes contain common flanking sequences

The flanking sequences of three U2 genes (or pseudogenes) and one U1 gene of Drosophila melanogaster have been determined. Comparison of the sequences reveals a remarkable homology between position -30 and -65 upstream from the structural genes, starting with a TATA box-like sequence. The 3' flanking regions are also conserved in all genes and contain a canonical A-A-T-A-A-A polyadenylation signal.

Human genes for U2 small nuclear RNA are tandemly repeated

We found that the genes for human U2 small nuclear RNA (snRNA) are organized as a nearly perfect tandem array of 10 to 20 copies per haploid genome. Although the coding region for the mature form of U2 RNA was only 188 base pairs (bp) long, the basic repeating unit of the tandem array was 6 kilobase pairs in length. Comparison of DNA sequences immediately upstream from human U1 and U2 genes revealed two regions of strong homology: region I (15 bp long) lay upstream of region II (20 bp long) and was separated from it by about the same distance in U1 genes (25 bp) as in U2 genes (21 bp); however, region I and region II were located 174 bp further upstream from the 5' end of the snRNA coding sequence in U1 genes than in U2 genes. Homologs of region II were also found upstream of the snRNA coding region in a mouse U2 gene and two rat U1 genes. Murphy et al. (Cell 29:265-274, 1982) have found that sequences within region II may function as the equivalent of a TATA box for initiation by RNA polymerase II in vitro at a position 183 bp upstream from the 5' end of the human U1 snRNA coding region. In light of the data reported here, this result suggests that region II does indeed play a role in transcription but that its position relative to the actual initiation site can vary.