Human DNA sequences complementary to the small nuclear RNA U2

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.

A fragile site in the human U2 small nuclear RNA gene cluster is revealed by adenovirus type 12 infection

Using in situ hybridization, we found that the U2 small nuclear RNA gene cluster mapped very close to and was frequently disrupted by the gaps and breaks induced specifically in the human 17q21-q22 region by highly oncogenic adenovirus type 12 (Ad12). Restriction mapping revealed no structural alterations in the U2 gene locus as a result of Ad12 infection. Likewise, no Ad12-induced alterations in U2 RNA levels were detected. We estimate that the maximum size of the region specifically disrupted by this virus was less than 350 to 700 kilobases. A comparison of these data with similar data regarding biochemically induced fragile sites was made.

A fragile site in the human U2 small nuclear RNA gene cluster is revealed by adenovirus type 12 infection

Using in situ hybridization, we found that the U2 small nuclear RNA gene cluster mapped very close to and was frequently disrupted by the gaps and breaks induced specifically in the human 17q21-q22 region by highly oncogenic adenovirus type 12 (Ad12). Restriction mapping revealed no structural alterations in the U2 gene locus as a result of Ad12 infection. Likewise, no Ad12-induced alterations in U2 RNA levels were detected. We estimate that the maximum size of the region specifically disrupted by this virus was less than 350 to 700 kilobases. A comparison of these data with similar data regarding biochemically induced fragile sites was made.

The gene cluster for human U2 RNA is located on chromosome 17q21

The gene cluster for human U2 RNA has been mapped to chromosome 17q21 by in situ hybridization and hybridization analysis of DNA from mouse/human somatic cell hybrids.

Nonrandom integration of human U4 RNA pseudogenes

Four loci for human U4 RNA have been characterized by DNA sequence analysis. The results show that all four loci represent pseudogenes, which are flanked by direct repeats. Three of the pseudogenes, designated U4/5, U4/6, and U4/8, have very similar structures; they are all truncated and contain the first 67 to 68 nucleotides of the U4 RNA sequence. Their properties suggest that they were created by integration of truncated cDNA copies of the U4 RNA into new chromosomal sites. An interesting observation was that their flanking regions exhibit sequence homology. A purine-rich 5'-flanking sequence 12 to 13 nucleotides long is almost perfectly conserved in all three loci. Boxes of homology were also found on the 3' side when the U4/6 and U4/8 loci were compared. The U4/4 locus has a slightly different structure; the pseudogene matches the first 79 nucleotides of U4 RNA, but contains a greater number of mutations than the other pseudogenes. Taken together, the results suggest that a frequently occurring type of pseudogene for human U4 was created by a RNA-mediated mechanism and that the integration sites have features in common.

Nonrandom integration of human U4 RNA pseudogenes

Four loci for human U4 RNA have been characterized by DNA sequence analysis. The results show that all four loci represent pseudogenes, which are flanked by direct repeats. Three of the pseudogenes, designated U4/5, U4/6, and U4/8, have very similar structures; they are all truncated and contain the first 67 to 68 nucleotides of the U4 RNA sequence. Their properties suggest that they were created by integration of truncated cDNA copies of the U4 RNA into new chromosomal sites. An interesting observation was that their flanking regions exhibit sequence homology. A purine-rich 5'-flanking sequence 12 to 13 nucleotides long is almost perfectly conserved in all three loci. Boxes of homology were also found on the 3' side when the U4/6 and U4/8 loci were compared. The U4/4 locus has a slightly different structure; the pseudogene matches the first 79 nucleotides of U4 RNA, but contains a greater number of mutations than the other pseudogenes. Taken together, the results suggest that a frequently occurring type of pseudogene for human U4 was created by a RNA-mediated mechanism and that the integration sites have features in common.

Human genes for U2 small nuclear RNA map to a major adenovirus 12 modification site on chromosome 17

U2 RNA is one of the abundant, highly conserved species of small nuclear RNA (snRNA) molecules implicated in RNA processing. As is typical of mammalian snRNAs, human U1 and U2 are each encoded by a multigene family. In the human genome, defective copies of the genes (pseudogenes) far outnumber the authentic genes. The majority or all of the 35 to 100 bona fide U1 genes have at least 20 kilobases (kb) of nearly perfect 5' and 3' flanking homology in common with each other; these U1 genes are clustered loosely in chromosome band 1p36 (refs 5, 7) with intergenic distances exceeding 44 kb. In contrast, the 10 to 20 U2 genes are clustered tightly in a virtually perfect tandem array which has a strict 6-kb repeating unit. We report here the assignment, by in situ hybridization, of the U2 gene cluster to chromosome 17, bands q21-q22. Surprisingly, this region is one of three major adenovirus 12 modification sites which undergo chromosome decondensation ('uncoiling') in permissive human cells infected by highly oncogenic strains of adenovirus. The two other major modification sites, 1p36 and 1q21, coincide with the locations of U1 genes and class I U1 pseudogenes, respectively. We suggest that snRNA genes are the major targets of viral chromosome modification.

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.

Interaction of small nuclear ribonucleoproteins with simian virus 40 in CV-1 cells: is U2 snRNA involved in regulating replication?

The small nuclear RNAs (snRNAs) in African Green Monkey kidney cells (CV-1 cells) were examined by polyacrylamide gel electrophoresis. Methodology was developed to improve their extraction from enriched fractions. Cellular fractionation studies and subsequent analysis of these RNAs indicate that they are tightly associated with chromatin. Treatment of cells with alpha-amanitin totally suppressed transcription of U1, U2, U4, U5, and partially suppressed transcription of U6, suggesting that these snRNAs are transcribed by RNA polymerase II. Upon infection of the cells by simian virus 40 (SV40), overall transcription of these and other cellular RNAs was stimulated. Gel filtration and formaldehyde crosslinking studies indicated that the ribonucleoproteins (snRNPs) containing snRNAs are associated with the viral minichromosome. Nucleotide sequence comparisons show extensive sequence complementarity between the 5' end of U2 RNA, the replication origin of SV40, and a prokaryotic RNA (RNA I) that is involved in control of plasmid replication. The clustered homologies between these RNAs and the association of snRNAs with the SV40 chromosome suggest that snRNAs may be evolutionarily related to small RNAs from plasmids and are consistent with an hypothesis that U2 RNA may be involved in DNA replication.

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.

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.

Isolation and characterization of Drosophila melanogaster U2 small nuclear RNA genes

We describe here the organization of DNA sequences complementary to Drosophila melanogaster U2 small nuclear (sn) RNA. From a genomic library we isolated two recombinants containing two genes each. Genomic reconstruction experiments and Southern analysis revealed that D. melanogaster possesses only four to five U2 snRNA genes or very closely related sequences. The nucleotide sequence of one of the clones analysed shows 77% homology with rat U2 snRNA. A stretch of 12 nucleotides that has been implicated in heterogeneous nuclear RNA splicing is conserved between rat and Drosophila. The genomic organization of these genes is very similar in different melanogaster strains but diverges highly in different Drosophila species.

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

Six phage clones that contain sequences hybridizable with the small nuclear RNA U2 were isolated from a rat gene library. Of these clones, one which includes a candidate for a functional U2 RNA gene was selected and characterized. The sequence within the clone which hybridizes with rat U2 RNA was completely co-linear with that of the RNA. A T-A-T-A box was not found in the region of more than 400 base-pairs which lies upstream of the gene. However, several block homologies were found with the upstream sequences of a rat U1 RNA gene candidate cloned in our laboratory. An "identifier sequence", which was reported to be an element of gene regulation related to differentiation, was found downstream of the coding region at the same distance and with the same orientation as the identifier sequence located downstream of the U1 RNA gene candidate. We detected a presumed U2 RNA precursor elongated by about 11 nucleotides at the 3' end by S1 nuclease mapping using a fragment from the clone. A potential termination signal for transcription was found within the elongated region of the presumed precursor. Southern blot analysis suggests that families of U2 RNA genes that have conserved flanking sequences are present in the genomes of rat, mouse, man, calf and chicken.

Loci for human U1 RNA: structural and evolutionary implications

Three clones U1-1, U1-6, and U1-8 containing sequences related to human U1 RNA have been studied by sequence analysis. The results show that each of the three clones represents a distinct locus. The U1-6 locus is closely related to the HU1-1 locus, which is believed to represent a functional U1 gene. The U1-1 and U1-8 loci are pseudogenes by definition, since they contain sequences that are closely related to but not identical with the human U1 RNA sequence. The U1-6 locus contains the sequence T-A-T-A-T close to the 5'-end of the U1 sequence but it is unclear if this represents the promoter. When the U1-8 locus was compared to the U1-6 locus, it was observed that the 5'-flanking sequences, except in the immediate vicinity of the pseudogene, are as well-conserved as the U1-related sequence itself, at least up to position -220. The high degree of homology in the 5'-flanking region suggests that U1 genes have a much more strict sequence requirement with regard to 5'-flanking sequences than most other eukaryotic genes. The U1-6 and U1-8 loci contain the sequence T-A-T-G-T-A-G-A-T-G-A between positions -211 and -221. An identical sequence is present in the equivalent position in the HU1-1 locus, and may represent the promoter. The high degree of conservation in the postulated promoter region indicates that pseudogenes like U1-8 possibly could be expressed. A truncated U1-related sequence is present between 106 to 150 nucleotides upstream from the U1 gene/pseudogene in the U1-6, the U1-8 and the HU1-1 loci, suggesting that the U1 genes may have been clustered early in evolution. The U1-1 locus has a strikingly different structure from the U1-8 locus; the pseudogene itself is as closely related to the U1 RNA sequence as is the U1-8 pseudogene but the flanking sequences, both on the 5' and the 3' side, share no detectable homology with the corresponding regions in the U1-6 or U1-8 loci. It may therefore be postulated that small nuclear RNA pseudogenes are created by several different mechanisms.

Cross-reaction of snRNA and an Alu I-like sequence from rat with DNAs from different eucaryotic species

Sequence homologies to rat U1-snRNA and U2-snRNA were investigated in DNA from 23 eucaryotic species (3 lower eucaryotes, 4 plants, and 16 animals) using dot hybridization at various stringency conditions. Cross-hybridization among very distantly related species in e.g. plants-insects or mold-vertebrates is not the rule; there are, however, examples for stronger homologies like Rattus-Dictyostelium. Furthermore, DNA from all 23 species was analysed for sequence homologies with the repetitive DNA sequence B1 (an Alu I family equivalent) from rat. We observed a wide range of homologies covering some plants and insects, up to vertebrates. Hybridization at increasing stringency conditions revealed species with higher degree of homology to the rat B1 sequence: maize, chicken, and hamster.

Mouse DNA sequences complementary to small nuclear RNA U1

A mouse genomic library was screened for sequences complementary to U1 nuclear RNA. Out of the eight clones tested, none contained more than one copy of U1. Six of them were identical and one of those (clone 0U1-XIII) was further analyzed. This latter clone contained no other gene for discrete species of small size RNA in the 8 Kb EcoRI fragment encoding U1. A 248 bp Bg1II fragment from 0U1-XIII encompassing the full length of U1 as well as flanking regions on both sides has been subcloned and sequenced in M13 phage. Although the coding region was 96.5% homologous to rat U1a RNA, there is no direct evidence that this clone is a true gene. 3' and 5' flanking sequences of this as well as other published clones have been searched for homologies and the results of this search are discussed.