Nucleotide sequences of mouse genomic loci including a gene or pseudogene for U6 (4.8S) nuclear RNA.

We have isolated four clones which hybridize with U6 (4.8S) nuclear RNA, a mammalian small nuclear RNA(nRNA), from DNA of BALB/C mouse liver. Their restriction maps are totally different from each other, indicating that they derived from different loci in the mouse genome. The nucleotide sequences around the hybridizing region in the three clones have been determined. One clone gives a gene that is co-linear with the U6 RNA. There is a sequence TATAAAT beginning 31 nucleotides upstream of the gene, which may suggest that the U6 RNA is transcribed by RNA polymerase II. The other two clones contain a pseudogene for the U6 RNA which has 7 or 9 nucleotide changes from the RNA. The pseudogenes are surrounded by radically different sequences from those surrounding the gene, and they are closely linked to a pseudogene for another snRNA, 4.5S-I RNA, or a part of highly repetitive an interspersed sequence B1.     

Structural analysis of gene loci for rat U1 small nuclear RNA.

Four phage clones which hybridize with U1 small nuclear RNA were obtained from a rat gene library. Two clones contain a presumed pseudogene. A third clone includes two gene candidates that are co-linear with the rat U1-RNA, 3.6kb apart and in the opposite orientation. The two genes are surrounded by identical sequences of 491bp upstream and 178bp downstream. The upstream sequences do not contain a TATA box, but share many block homologies with those for the human U1-RNA gene(1-3). A 101bp "identifier (ID) sequence", which was reported to be specifically expressed in rat brain (4), is inserted immediately after the shared sequence downstream of one of the genes. In the fourth clone, there are two putative pseudogenes, which have one or three nucleotide changes, 3kb apart and in the same orientation. Southern blot analysis of total rat DNA reveals about 50 U1-RNA genes/pseudogenes in the genome.     

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.     

Three pseudogenes for human U13 snRNA belong to class III.

The nucleotide sequences of three pseudogenes for the small nucleolar RNA, U13, were determined from three human DNA clones. The sequences are reported 50 bp 5' and 3' to each gene. These pseudogenes belong to class III because they contain dispersed mismatches when compared to the previously determined U13 RNA sequence, an adenine-rich region at the 3' end, and short imperfect repeats flanking the 5' end of the coding sequence and the 3' end of the adenine-rich region.     

A candidate gene for human U1 RNA.

Clones containing sequences complementary to the small nuclear RNA U1 were isolated from the human DNA library of Lawn et al. (1978). Three clones were studied by hybridization and restriction enzyme cleavage. The results showed that the inserts in all three clones were different and that each clone contains one single copy of a sequence which hybridizes to U1 RNA. The results revealed moreover that only one of the three clones contains all the cleavage sites which can be predicted from the known sequence of human U1 RNA, suggesting that the three clones comprise one candidate U1 gene and two pseudogenes. A fragment from the recombinant with the candidate U1 gene was subcloned in the pPR322 plasmid and part of its sequence was determined. The results showed that the subclone contains a sequence which matches that of the human U1 RNA perfectly. The sequence "TATAT" which often is found adjacent to RNA polymerase II start sites, was identified 33-37 base pairs upstream from the beginning of the U1 sequence. Two ten base pairs long, nearly perfect, direct repeats were also identified in the vicinity of the U1 sequence and an imperfect inverted repeat follows immediately after the U1 gene.     

Construction of a cDNA clone for a nuclear-coded subunit of cytochrome c oxidase from rat liver

A cDNA library for 6S-9S poly(A)-containing RNA from rat liver was constructed in E. coli. Initial screening of the clones was carried out using single stranded 32P-labeled cDNA prepared against poly(A)-containing RNA isolated from immunoadsorbed polyribosomes enriched for the nuclear-coded subunit messenger RNAs of cytochrome c oxidase. One of the clones, pCO89, was found to hybridize with the messenger RNA for subunit VIC. The DNA sequence of the insert in pCO89 was carried out and it has got extensive homology with the C-terminal 33 amino acids of subunit VIC from beef heart cytochrome c oxidase. In addition, the insert contained 146 bp, corresponding to a portion of the 3'-non-coding region. Northern blot analysis of rat liver RNA with the nick-translated insert of pCO89 revealed that the messenger RNA for subunit VI would contain around 510 bases.     

The importance of the light chain for the epitope specificity of human anti-U1 small nuclear RNA autoantibodies present in systemic lupus erythematosus patients.

Abs to U1 RNA are frequently found in patients suffering from systemic lupus erythematosus overlap syndromes and Ab titers correlate with disease activity. We describe the isolation of the first human anti-U1 RNA autoantibodies from a combinatorial IgG library made from the bone marrow of a systemic lupus erythematosus patient. With the use of phage display technology, two anti-U1 RNA single-chain variable fragment (scFv) Abs were selected. Both high affinity anti-U1 RNA Ab fragments (Kd approximately 1 nM) recognize stem II of U1 RNA and were derived from the same heavy chain gene (VH3-11) and the same lambda (3r) light chain gene although somatic mutations, predominantly present in the complementarity-determining regions, are different. Experiments, in which the heavy chain genes of both anti-U1 RNA scFvs were reshuffled with the original light chain repertoire of the patient resulted, after selection on stem loop II, in a large number of RNA-binding Ab fragments. All these stem loop II-specific RNA binding clones used a similar, but not identical, 3r lambda light chain. When scFvs were selected from the reshuffled libraries by stem loop IV, representing the other autoantigenic site of U1 RNA, most selected Ab clones did react with stem loop IV, but no longer with stem loop II. The stem loop IV-reactive Ab clones contained different, not 3r-related, light chains. These results point to a major role for the light chain in determining the sequence specificity of these disease-related anti-U1 RNA Abs. The possibility that secondary light chain rearrangements are involved in this autoimmune response is discussed.     

Carp growth hormone: molecular cloning and sequencing of cDNA

cDNA clones of the fish Cyprinus carpio growth hormone (GH) mRNA have been isolated from a cDNA library prepared from carp pituitary gland poly(A)+RNA. The nucleotide sequence of one of the carp GH cDNA clones containing an insert of 1164 nucleotides (nt) was determined. The cDNA sequence was found to encode a polypeptide of 210 amino acids (aa) including a signal peptide of 22 aa and to contain 5' and 3' untranslated regions of the mRNA of 36 and 498 nt, respectively. The carp GH presents a 63% amino acid sequence homology with the salmon GH, has structural features common with other GH polypeptides of mammalian or avian origin and contains domains of conserved sequence near the N- and C-terminal regions. Southern blot hybridization of carp genomic DNA with GH cDNA probes shows the presence of at least two GH-coding sequences in the fish genome.     

Characterization of unintegrated retroviral DNA with long terminal repeat-associated cell-derived inserts.

We have used a replication-competent shuttle vector based on the genome of Rous sarcoma virus to characterize genomic rearrangements that occur during retrovirus replication. The strategy involved cloning circular DNA that was generated during an acute infection. While analyzing a class of retroviral DNA clones that are greater than full length, we found several clones which had acquired nonviral inserts in positions adjacent to the long terminal repeats (LTRs). There appear to be two distinct mechanisms leading to the incorporation of cellular sequences into these clones. Three of the molecules contain a cell-derived insert at the circle junction site between two LTR units. Two of these molecules appear to be the results of abortive integration attempts, because of which, in each case, one of the LTRs is missing 2 bases at its junction with the cell-derived insert. In the third clone, pNO220, the cellular sequences are flanked by an inappropriately placed copy of the tRNA primer-binding site on one side and a partial copy of the U3 sequence as part of the LTR on the other side. A fourth molecule we characterized, pMD96, has a single LTR with a U5-bounded deletion of viral sequences spanning gag and pol, with cell-derived sequences inserted at the site of the deletion; its origin may be related mechanistically to pNO220. Sequence analysis indicates that all of the cellular inserts were derived from the cell line used for the acute infection rather than from sequences carried into the cell as part of the virus particle. Northern (RNA) analysis of cellular RNA demonstrated that the cell-derived sequences of two clones, pNO220 and pMD96, were expressed as polyadenylated RNA in uninfected cells. One mechanism for the joining of viral and cellular sequences suggested by the structures of pNO220 and pMD96 is recombination occurring during viral DNA synthesis, with cellular RNA serving as the template for the acquisition of cellular sequences.     

Structure of rodent helix-destabilizing protein revealed by cDNA cloning

A cDNA library of newborn rat brain poly(A+) RNA in lambda gt 11 was screened with a synthetic oligonucleotide probe corresponding to a five amino acid sequence in the N-terminal region of the calf helix-destabilizing protein, UP1. Six positive phage were isolated after testing 2 X 10(5) recombinants, and each phage was plaque purified. Four of these phage clones were positive with a second oligonucleotide probe corresponding to a 5 amino acid sequence in the C-terminal region of calf UP1; one of the clones positive with both probes was selected for detailed study. This phage, designated lambda HDP-182, contained a 1706-base pair cDNA insert corresponding to an mRNA with a poly(A) sequence at the 3' terminus and a single open reading frame starting 63 bases from the 5' terminus and extending 988 bases. The 3' untranslated region of the mRNA contained 718 bases, including an AAUAAA signal 21 bases from the poly(A) sequence and a 16-residue poly(U) sequence flanked on each side by oligonucleotide repeats. Primer extension analysis of newborn rat brain poly(A+) RNA suggested that the cDNA insert in lambda HDP-182 was full length except for about 35 nucleotide residues missing from the 5' end untranslated region, and Northern blot analysis revealed one relatively abundant mRNA species of approximately the same size as the cDNA insert. The 988-residue open reading frame in the cDNA predicted a 34,215-dalton protein of 320 amino acids. Residues 2 through 196 of this rat protein are identical to the 195-residue sequence of the calf helix-destabilizing protein, UP1. The 124-amino acid sequence in the C-terminal portion of the 34,215-dalton protein is not present in purified calf UP1. This 124-residue sequence has unusual amino acid content in that it is 11% asparagine, 15% serine, and 40% glycine and consists of 16 consecutive oligopeptide repeats. Computer-derived secondary structure predictions for the 34,215-dalton protein revealed two distinct domains consisting of residues 1 through approximately 196 and residues approximately 197 to 320, respectively.     

cDNA cloning and nucleotide sequence comparison of Chinese hamster metallothionein I and II mRNAs

Polyadenylated RNA was extracted from a cadmium resistant Chinese hamster (CHO) cell line, enriched for metal-induced, abundant RNA sequences and cloned as double-stranded cDNA in the plasmid pBR322. Two cDNA clones, pCHMT1 and pCHMT2, encoding two Chinese hamster isometallothioneins were identified, and the nucleotide sequence of each insert was determined. The two Chinese hamster metallothioneins show nucleotide sequence homologies of 80% in the protein coding region and approximately 35% in both the 5' and 3' untranslated regions. Interestingly, an 8 nucleotide sequence (TGTAAATA) has been conserved in sequence and position in the 3' untranslated regions of each metallothionein mRNA sequenced thus far. Estimated nucleotide substitution rates derived from interspecies comparisons were used to calculate a metallothionein gene duplication time of 45 to 120 million years ago.