U1 small nuclear RNA genes are located on human chromosome 1 and are expressed in mouse-human hybrid cells

U1 snDNA clusters in grasshoppers: chromosomal dynamics and genomic organization

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

Genetic characterization of Plectorhinchus mediterraneus yields important clues about genome organization and evolution of multigene families

Background

Molecular and cytogenetic markers are of great use for to fish characterization, identification, phylogenetics and evolution. Multigene families have proven to be good markers for a better understanding of the variability, organization and evolution of fish species. Three different tandemly-repeated gene families (45S rDNA, 5S rDNA and U2 snDNA) have been studied in Plectorhinchus mediterraneus (Teleostei: Haemulidae), at both molecular and cytogenetic level, to elucidate the taxonomy and evolution of these multigene families, as well as for comparative purposes with other species of the family.

Results

Four different types of 5S rDNA were obtained; two of them showed a high homology with that of Raja asterias, and the putative implication of a horizontal transfer event and its consequences for the organization and evolution of the 5S rDNA have been discussed. The other two types do not resemble any other species, but in one of them a putative tRNA-derived SINE was observed for the first time, which could have implications in the evolution of the 5S rDNA. The ITS-1 sequence was more related to a species of another different genus than to that of the same genus, therefore a revision of the Hamulidae family systematic has been proposed. In the analysis of the U2 snDNA, we were able to corroborate that U2 snDNA and U5 snDNA were linked in the same tandem array, and this has interest for tracing evolutionary lines. The karyotype of the species was composed of 2n = 48 acrocentric chromosomes, and each of the three multigene families were located in different chromosome pairs, thus providing three different chromosomal markers.

Conclusions

Novel data can be extracted from the results: a putative event of horizontal transfer, a possible tRNA-derived SINE linked to one of the four 5S rDNA types characterized, and a linkage between U2 and U5 snDNA. In addition, a revision of the taxonomy of the Haemulidae family has been suggested, and three cytogenetic markers have been obtained. Some of these results have not been described before in any other fish species. New clues about the genome organization and evolution of the multigene families are offered in this study.

Analysis of inhibitory action of modified U1 snRNAs on target gene expression: discrimination of two RNA targets differing by a 1 bp mismatch

The modified U1 snRNA gene can suppress expression of a target transgene. In the present study, its potential utility to inhibit a dominant negative/gain of function mutation is explored. Using a green fluorescent protein (GFP) target gene, inhibition was achieved in all cells transduced with U1antiGFP directed at multiple sites within GFP. Using a chloramphenicol acetyltransferase (CAT) target gene, inhibition was not increased by increasing the hybridization domain from 10 to 16 bp or when a site in an upstream exon or intron was targeted. To determine if a U1 anti-target design could discriminate between two transcripts that differ by a 1-2 bp mismatch, GFPtpz and GFPsaph were chosen as targets because they share sequence homology except for three regions where a 1, 2 or 3 bp mismatch exists. The results demonstrated that U1antiGFP correctly reduced its cognate GFP expression by >90% and therefore U1 anti-target constructs are able to discriminate a 1 or 2 bp mismatch in their target mRNA. Thus, these U1 anti-target constructs may be effective in a strategy of somatic gene therapy for a dominant negative/gain of function mutation due to the discreteness of its discrimination. It may complement other anti-target strategies to reduce the cellular load of a mutant transcript.

Changes in the stem-loop at the 3' terminus of histone mRNA affects its nucleocytoplasmic transport and cytoplasmic regulation

The stem-loop structure at the 3' end of replication-dependent histone mRNA is required for efficient pre-mRNA processing, localization of histone mRNA to the polyribosomes, and regulation of histone mRNA degradation. A protein, the stem-loop binding protein (SLBP), binds the 3' end of histone mRNA and is thought to mediate some or all of these processes. A mutant histone mRNA with two nucleotide changes in the loop was constructed and found to be transported inefficiently to the cytoplasm. The mutant histone mRNA, unlike the wild-type histone mRNA, was not rapidly degraded when DNA synthesis is inhibited, and was not stabilized upon inhibition of protein synthesis. The stem-loop binding protein (SLBP) has between a 20-50 fold greater affinity for the wild type histone stem-loop structure than for the mutant stem-loop structure, suggesting that the alteration in the efficiency of transport and the normal degradation pathway in histone mRNA may be due to the reduced affinity of the mutant stem-loop for the SLBP.

Generation of a new adenovirus type 12-inducible fragile site by insertion of an artificial U2 locus in the human genome

Infection with adenovirus type 12 (Ad12) induces four fragile sites in the human genome (H.F. Stich, G.L. van Hoosier, and J.J. Trentin, Exp. Cell Res. 34:400-403, 1964; H. zur Hausen, J. Virol. 1:1174-1185, 1967). The major site, at 17q21-22, contains the U2 gene cluster, which is specifically disrupted by infection in at least a percentage of the cells (D.M. Durnam, J.C. Menninger, S.H. Chandler, P.P. Smith, and J.K. McDougall, Mol. Cell. Biol. 8:1863-1867, 1988). For direct assessment of whether the U2 locus is the target of the Ad12 effect, an artificial locus, constructed in vitro and consisting of tandem arrays of the U2 6-kbp monomer, was transfected into human cells. We report that integration of this artificial locus on the p arm of chromosome 13 creates a new Ad12-inducible fragile site.

Generation of a new adenovirus type 12-inducible fragile site by insertion of an artificial U2 locus in the human genome

Infection with adenovirus type 12 (Ad12) induces four fragile sites in the human genome (H.F. Stich, G.L. van Hoosier, and J.J. Trentin, Exp. Cell Res. 34:400-403, 1964; H. zur Hausen, J. Virol. 1:1174-1185, 1967). The major site, at 17q21-22, contains the U2 gene cluster, which is specifically disrupted by infection in at least a percentage of the cells (D.M. Durnam, J.C. Menninger, S.H. Chandler, P.P. Smith, and J.K. McDougall, Mol. Cell. Biol. 8:1863-1867, 1988). For direct assessment of whether the U2 locus is the target of the Ad12 effect, an artificial locus, constructed in vitro and consisting of tandem arrays of the U2 6-kbp monomer, was transfected into human cells. We report that integration of this artificial locus on the p arm of chromosome 13 creates a new Ad12-inducible fragile site.

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.

A VNTR immediately adjacent to the human pseudoautosomal telomere

The probe 29C1 detects a hypervariable locus 18kb from the telomere of the human X and Y chromosomes, in the pseudoautosomal region. Here we report that hypervariability of fragments containing this sequence in the human population arises by loss or gain of a 31 base pair GC rich repeat. Labelled 29C1 does not detect a DNA fingerprint at low stringency, though the consensus repeat sequence does show some similarity to previously reported minisatellites. Sequence within the repeat block has G and C rich strands, a feature associated with sequences at the telomeres of many higher organisms. The repeat block shows sequence characteristics normally associated with a low methylation island, though the locus is methylated and does not appear to be transcribed.

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.

Fragments of rDNA within the Chinese hamster genome

We report the isolation and partial characterization of distinct EcoRI fragments of the Chinese hamster genome which contain regions complementary to a 1-kb portion of the mature 18 S ribosomal RNA molecule. This previously undescribed 18 S rDNA-like region, which we have termed a "fragment of ribosomal DNA" (frDNA), has been shown by sequence analysis to correspond to a region extending 1 kb upstream from the 3' terminus of the mature 18 S rRNA. Within the five frDNA-containing clones described here, no other region of the ribosomal RNA cistron was detected, making it unlikely that these are polymorphic forms of the ribosomal DNA repeat. The 18 S rDNA-complementary region appears to be flanked by an imperfect direct repeat, which could have been the result of the retroinsertion of a fragment of ribosomal RNA. Directly adjacent to the 18 S rDNA-like region we have identified nonribosomal sequences which appear common to all of the frDNA-containing clones we examined. At least eight different-sized EcoRI fragments contain frDNAs and the abundance of the frDNAs appears to be of the order of 30 per genome. The occurrence of multiple copies of this ribosomal-nonribosomal chimera suggests that, once formed, the chimera was duplicated within the genome.

Evolution of homologous sequences on the human X and Y chromosomes, outside of the meiotic pairing segment

A sequence isolated from the long arm of the human Y chromosome detects a highly homologous locus on the X. This homology extends over at least 50 kb of DNA and is postulated to be the result of a transposition event between the X and Y chromosomes during recent human evolution, since homologous sequences are shown to be present on the X chromosome alone in the chimpanzee and gorilla.

A new moderately repetitive DNA sequence family of novel organization

In cloning adenovirus homologous sequences, from a human cosmid library, we identified a moderately repetitive DNA sequence family consisting of tandem arrays of 2.5 kb members. A member was sequenced and several non-adjacent, 15-20 bp G-C rich segments with homology to the left side of adenovirus were discovered. The copy number of 400 members is highly conserved among humans. Southern blots of partial digests of human DNA have verified the tandem array of the sequence family. The chromosomal location was defined by somatic cell genetics and in situ hybridization. Tandem arrays are found only on chromosomes 4 (4q31) and 19 (q13.1-q13.5). Homologous repetitive sequences are found in DNA of other primates but not in cat or mouse. Thus we have identified a new family of moderately repetitive DNA sequences, unique because of its organization in clustered tandem arrays, its length, its chromosomal location, and its lack of homology to other moderately repetitive sequence families.

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.

Homologous subfamilies of human alphoid repetitive DNA on different nucleolus organizing chromosomes

The organization of alphoid repeated sequences on human nucleolus-organizing (NOR) chromosomes 13, 21, and 22 has been investigated. Analysis of hybridization of alphoid DNA probes to Southern transfers of restriction enzyme-digested DNA fragments from hybrid cells containing single human chromosomes shows that chromosomes 13 and 21 share one subfamily of alphoid repeats, whereas a different subfamily may be held in common by chromosomes 13 and 22. The sequences of cloned 680-base-pair EcoRI fragments of the alphoid DNA from chromosomes 13 and 21 show that the basic unit of this subfamily is indistinguishable on each chromosome. The sequence of cloned 1020-base-pair Xba I fragments from chromosome 22 is related to, but distinguishable from, that of the 680-base-pair EcoRI alphoid subfamily of chromosomes 13 and 21. These results suggest that, at some point after they originated and were homogenized, different subfamilies of alphoid sequences must have exchanged between chromosomes 13 and 21 and separately between chromosomes 13 and 22.

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.

Small nuclear RNAs from Saccharomyces cerevisiae: unexpected diversity in abundance, size, and molecular complexity

Previous work showed that the simple eukaryote Saccharomyces cerevisiae contains a group of RNAs with the general structural properties predicted for small nuclear RNAs (snRNAs), including possession of the characteristic trimethylguanosine 5'-terminal cap. It was also demonstrated that, unlike their metazoan counterparts, the yeast snRNAs are present in low abundance (200-500 molecules per haploid cell). We have now used antibody directed against the 5' cap to investigate the total set size of snRNAs in this organism. We present evidence that the number of distinct yeast snRNAs is on the order of several dozen, that the length of the capped RNAs can exceed 1000 nucleotides, and that the relative abundance of a subset of these RNAs is 1/5th to 1/20th that of the class of snRNAs described previously. These findings suggest that the six highly abundant species of snRNAs (U1-U6) typically reported in metazoans may represent a serious underestimation of the total diversity of snRNAs in eukaryotes.

Human U1 small nuclear RNA pseudogenes do not map to the site of the U1 genes in 1p36 but are clustered in 1q12-q22

Human U1 small nuclear RNA is encoded by approximately 30 gene copies. All of the U1 genes share several kilobases of essentially perfect flanking homology both upstream and downstream from the U1 coding region, but remarkably, for many U1 genes excellent flanking homology extends at least 24 kilobases upstream and 20 kilobases downstream. Class I U1 RNA pseudogenes are abundant in the human genome. These pseudogenes contain a complete but imperfect U1 coding region and possess extensive flanking homology to the true U1 genes. We mapped four class I pseudogenes by in situ hybridization to the long arm of chromosome 1, bands q12-q22, a region distinct from the site on the distal short arm of chromosome 1 to which the U1 genes have been previously mapped (Lund et al., Mol. Cell. Biol. 3:2211-2220, 1983; Naylor et al., Somat. Cell Mol. Genet. 10:307-313, 1984). We confirmed our in situ hybridization results by genomic blotting experiments with somatic cell hybrid lines with translocation products of human chromosome 1. These experiments provide further evidence that class I U1 pseudogenes and the true U1 genes are not interspersed. The results, along with those published elsewhere (Bernstein et al., Mol. Cell. Biol. 5:2159-2171, 1985), suggest that gene amplification may be responsible for the sequence homogeneity of the human U1 gene family.

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.

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.

The trypanosome spliced leader small RNA gene family: stage-specific modification of one of several similar dispersed genes

Diverse mRNAs of Trypanosoma brucei possess the same 5' terminal 35 nucleotides, termed the spliced leader (SL), which appears to be derived from a separate 135 nucleotide transcript. This small SL RNA is encoded within a 1.4 kb unit of DNA which is tandemly reiterated in the genome. In addition, there are at least 4 orphon elements containing SL sequences dispersed from the tandem array. Here we show that during the trypanosome life cycle one of the SL orphons undergoes a stage-specific modification that prevents cleavage of an EcoRV site and we further demonstrate that although only one orphon is modified, three of the SL orphons are flanked by very similar sequences. Each of these contains SL reiteration units including the non-transcribed spacer DNA, suggesting that they did not originate through an RNA intermediate. In addition no evidence of direct repeats at the junction of 1.4 kb and non-1.4 kb DNA was observed. Finally, a phylogenetic survey indicates that while many trypanosomatid species possess similarly organized SL-like sequences, only the SL orphons of closely related subspecies of the T. brucei - T. evansi complex share similar flanking regions.

Expression of a human U1 RNA gene introduced into mouse cells via bovine papillomavirus DNA vectors

We introduced a gene for human U1 small nuclear RNA, HU1-1, into mouse C127 cells via bovine papillomavirus (BPV) vectors. After transfection, up to 15% of the total U1 RNA in transformed cells was encoded by the introduced human genes. High levels of expression of the human gene were observed when the recombinant viral DNAs were maintained either as plasmids or after integration into high-molecular-weight DNA. As few as 400 and 35 base pairs of 5' and 3' flanking region sequences, respectively, were sufficient for transcription of human U1 RNA, and no increase in the level of expression was observed with HU1-1 DNA containing several kilobases of flanking region sequences. Several of the transformed cell lines contained the recombinant BPV DNA apparently integrated into the host genome. Integration or rearrangement or both of the U1-BPV DNA was promoted when the HU1-1 gene was positioned at the BamHI site downstream of the BPV transforming region. At least two variants of the U1-BPV DNAs were able to cause morphological transformation of cells despite the fact that these DNAs lacked a BPV transcriptional enhancer element.

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.

Human U1 small nuclear RNA pseudogenes do not map to the site of the U1 genes in 1p36 but are clustered in 1q12-q22

Human U1 small nuclear RNA is encoded by approximately 30 gene copies. All of the U1 genes share several kilobases of essentially perfect flanking homology both upstream and downstream from the U1 coding region, but remarkably, for many U1 genes excellent flanking homology extends at least 24 kilobases upstream and 20 kilobases downstream. Class I U1 RNA pseudogenes are abundant in the human genome. These pseudogenes contain a complete but imperfect U1 coding region and possess extensive flanking homology to the true U1 genes. We mapped four class I pseudogenes by in situ hybridization to the long arm of chromosome 1, bands q12-q22, a region distinct from the site on the distal short arm of chromosome 1 to which the U1 genes have been previously mapped (Lund et al., Mol. Cell. Biol. 3:2211-2220, 1983; Naylor et al., Somat. Cell Mol. Genet. 10:307-313, 1984). We confirmed our in situ hybridization results by genomic blotting experiments with somatic cell hybrid lines with translocation products of human chromosome 1. These experiments provide further evidence that class I U1 pseudogenes and the true U1 genes are not interspersed. The results, along with those published elsewhere (Bernstein et al., Mol. Cell. Biol. 5:2159-2171, 1985), suggest that gene amplification may be responsible for the sequence homogeneity of the human U1 gene family.

A cloned sequence, p82H, of the alphoid repeated DNA family found at the centromeres of all human chromosomes

Clone p82H is a human DNA sequence which hybridises in situ exclusively to the centromeric regions of all human chromosomes. It is composed of approximately 14 tandemly repeated variants of a basic 172 bp sequence, and is related to the alphoid family. The organisation of the family of cross-hybridising sequences, detected by the clone p82H, is described both in the human genome and on certain chromosomes, and its relationship to known sequence families is discussed.

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.

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.

Expression of a human U1 RNA gene introduced into mouse cells via bovine papillomavirus DNA vectors

We introduced a gene for human U1 small nuclear RNA, HU1-1, into mouse C127 cells via bovine papillomavirus (BPV) vectors. After transfection, up to 15% of the total U1 RNA in transformed cells was encoded by the introduced human genes. High levels of expression of the human gene were observed when the recombinant viral DNAs were maintained either as plasmids or after integration into high-molecular-weight DNA. As few as 400 and 35 base pairs of 5' and 3' flanking region sequences, respectively, were sufficient for transcription of human U1 RNA, and no increase in the level of expression was observed with HU1-1 DNA containing several kilobases of flanking region sequences. Several of the transformed cell lines contained the recombinant BPV DNA apparently integrated into the host genome. Integration or rearrangement or both of the U1-BPV DNA was promoted when the HU1-1 gene was positioned at the BamHI site downstream of the BPV transforming region. At least two variants of the U1-BPV DNAs were able to cause morphological transformation of cells despite the fact that these DNAs lacked a BPV transcriptional enhancer element.

Chromosomal assignments of the genes coding for human types II, III, and IV collagen: a dispersed gene family

The human type II collagen gene, COL2A1, has been assigned to chromosome 12, the type III gene, COL3A1, to chromosome 2, and one of the type IV genes, COL4A1, to chromosome 13. These assignments were made by using cloned genes as probes on Southern blots of DNA from a panel of mouse/human somatic cell hybrids. The two genes of type I collagen, COL1A1 and COL2A1, have been mapped previously to chromosomes 17 and 7, respectively. This family of conserved genes seems therefore to be dispersed throughout the genome.

Identification and chromosomal distribution of 5S rRNA genes in Neurospora crassa

The 5S rRNA genes of Neurospora crassa, unlike those of most organisms, are not tandemly arranged, and they are found imbedded in a variety of unique sequences. The 5S rRNA regions of most of the genes are of one type, alpha; however, several other "isotypes" (beta, gamma, delta, zeta, and eta) are also found. We asked whether Neurospora 5S rRNA genes are dispersed on a chromosomal scale and whether genes of different isotypes are spatially segregated. We identified, by DNA sequencing, 5S rRNA genes in 22 5S DNA clones, and we mapped these genes by conventional crosses by using restriction fragment length polymorphisms in their flanking sequences as genetic markers. The results show that the 5S rRNA genes are distributed on at least six of the seven chromosomes. Their location does not appear to be completely random. Some of them are closely linked. One of the chromosomes carries a disproportionate number of 5S rRNA genes of the most common structural type, alpha; another chromosome carries three of the four mapped beta 5S rRNA genes. None of the 5S rRNA genes studied maps close to the nucleolus organizer, the site of the genes that code for the three larger rRNAs.

The two embryonic U1 small nuclear RNAs of Xenopus laevis are encoded by a major family of tandemly repeated genes

We have identified a large family of U1 RNA genes in Xenopus laevis that encodes two distinct species of U1 RNA. These genes are expressed primarily at the onset of transcription in the 4,000-cell embryo (D. J. Forbes, M. W. Kirschner, D. Caput, J. E. Dahlberg, and E. Lund, Cell 38:681-689, 1984). The two types of embryonic U1 RNA genes are interspersed and are organized in large tandem arrays. The basic 1.9-kilobase repeating unit contains a single copy of each of the embryonic genes and is reiterated ca. 500-fold per haploid genome. This repetitive U1 DNA accounts for more than 90% of all U1 DNA in X. laevis. In addition to this major family, there exist several minor families of dispersed U1 RNA genes, which presumably encode the oocyte and somatic species of X. laevis U1 RNA. Although the embryonic genes are normally inactive in stage VI oocytes, they are expressed when cloned copies are injected into oocyte nuclei.

An estimate of unique DNA sequence heterozygosity in the human genome

Fifteen different restriction fragment length polymorphisms (RFLPs) were detected in the human genome using 19 cloned DNA segments, derived from flow-sorted metaphase chromosomes or total genomic DNA, as hybridization probes. Since these clones were selected at random with respect to their coding potential, their analysis permitted an unbiased estimate of single-copy DNA sequence heterozygosity in the human genome. Since our estimate (h = 0.0037) is an order of magnitude higher than previous estimates derived from protein data, most of the polymorphic variation present in the genome must occur in non-coding sequences. In addition, it was confirmed that enzymes containing the dinucleotide CpG in their recognition sequence detect more polymorphic variation than those that do not contain CpG.

The two embryonic U1 small nuclear RNAs of Xenopus laevis are encoded by a major family of tandemly repeated genes

We have identified a large family of U1 RNA genes in Xenopus laevis that encodes two distinct species of U1 RNA. These genes are expressed primarily at the onset of transcription in the 4,000-cell embryo (D. J. Forbes, M. W. Kirschner, D. Caput, J. E. Dahlberg, and E. Lund, Cell 38:681-689, 1984). The two types of embryonic U1 RNA genes are interspersed and are organized in large tandem arrays. The basic 1.9-kilobase repeating unit contains a single copy of each of the embryonic genes and is reiterated ca. 500-fold per haploid genome. This repetitive U1 DNA accounts for more than 90% of all U1 DNA in X. laevis. In addition to this major family, there exist several minor families of dispersed U1 RNA genes, which presumably encode the oocyte and somatic species of X. laevis U1 RNA. Although the embryonic genes are normally inactive in stage VI oocytes, they are expressed when cloned copies are injected into oocyte nuclei.

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.

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.

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.

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.