Comparative analysis of human chromosomal segments bearing nonallelic dispersed tRNAimet genes

Drosophila melanogaster tRNAVal3b genes and their allogenes

Drosophila tRNAVal3b genes have been analyzed with respect to their nucleotide sequence and in vitro transcription efficiency. Plasmid pDt78R contains a single tRNA gene derived from the major tRNAVal3b gene cluster at chromosome band 84D. Its sequence corresponds to that of the tRNAVal3b. Two other plasmids, pDt41R and pDt48, each contain a tRNAVal3b-like gene from the minor tRNAVal3b gene cluster at chromosome bands 90BC. They contain the expected CAC anticodon, but their sequence differs from the tRNA at four positions. In homologous cell-free extracts, the tRNAVal3b variant genes in pDt41R and pDt48 are transcribed an order of magnitude more efficiently than the tRNAVal3b gene in pDt78R. However, the variant genes do not appear to contribute significantly to the in vivo tRNA pool [Larsen et al.: Mol. Gen. Genet. 185 (1982) 390-396]. We propose the term allogenes to describe families of related DNA sequences that may code for variant forms of a standard tRNA isoaccepting species.

Structure and transcription of eukaryotic tRNA genes

The availability of cloned tRNA genes and a variety of eukaryotic in vitro transcription systems allowed rapid progress during the past few years in the characterization of signals in the DNA-controlling gene transcription and in the processing of the precurser RNAs formed. This will be the subject matter discussed in this review.

Nucleotide sequence and transcription of a gene encoding human tRNAGlyCCC

A phage lambda clone containing a 13.1-kb human DNA fragment was isolated and found to contain a tRNA gene encoding a glycine tRNA. The nucleotide sequence of the gene and its flanking regions has been determined. The gene does not have an intervening sequence nor does it encode the 3'-terminal CCA sequence found in mature tRNAs. Although this tRNA gene has an anticodon sequence of CCC, it has a striking homology (96%) with a human glycine tRNA which has an anticodon of GCC. As in other eukaryotic tRNA genes, the coding region contains a characteristic internal split promoter sequence, and the 3'-flanking region has a typical RNA polymerase III termination site of five consecutive T residues. There is no apparent sequence in the 5'-flanking region which could serve as a regulatory element. This gene is accurately transcribed in vitro by RNA polymerase III using a HeLa cell-free system. During the course of in vitro transcription, larger precursor tRNAGlyCCC transcripts are processed to yield a mature-sized tRNA product. A precursor-product relationship was established by comparing the ribonuclease A fingerprints of the precursor and product tRNA transcripts.

Structure and evolution of mammalian tRNA genes: sequence of a mouse tRNAiMet gene, the 5'-flanking region of which is homologous to a human gene

From a recombinant lambda phage, we have determined a 317-bp sequence containing a mouse tRNAiMet gene. The coding region is precisely homologous to mammalian tRNAiMet if post-transcriptional modifications (including addition of the 3'-terminal CCA) are not considered. The gene does not contain introns and has a typical RNA polymerase III termination site in the 3'-flanking region. It is transcribed by RNA polymerase III in the HeLa cell S-100 system in vitro. Notably, the 5'-flanking region of the mouse tRNAiMet gene shares a "patchwork" pattern of homology with one of the human tRNAiMet genes of Santos and Zasloff [Cell 23 (1981) 699-710]. The 5'-flanking regions of the two genes contain strings of nucleotides, 6 to 32 bp in length, the homology of which is 76-100%. These are separated by short strings of unrelated nucleotides. This is one of the first examples of tRNA genes containing homologous 5'-flanking regions isolated from distantly related mammals. We also report a novel method for constructing deletion mutants of sequences cloned in M13 vectors.

Genes and pseudogenes in a reiterated rat tRNA gene cluster

A 13.4 kb rat genomic DNA fragment containing two related tRNA gene clusters was isolated from a rat lambda recombinant and analyzed for gene arrangement and nucleotide sequence. One cluster was found to contain a tRNALeuCUG gene while the second contained a tRNALeuCUA pseudogene with multiple base substitutions. The tRNALeu gene was found to possess an intact coding region and a functional transcription termination signal at the 3' end as demonstrated by in vitro transcription and processing of precursors to mature size tRNA. The first tRNA gene cluster was found to contain in addition to tRNALeu, three other transcribable genes coding for tRNAAspGAC(U), tRNAGlyGGA(G) and tRNAGluGAG; the second cluster contained in addition to tRNALeu pseudogene, the tRNAAsp tRNAGly and tRNAGlu genes. Examination of flanking sequences of the corresponding tRNA genes in the two clusters shows no homology at the 5' ends and partial conservation of sequences at the 3'-end region. Genomic rat DNA blot hybridizations show that the tRNALeu gene is distributed together with the tRNAAsp, tRNAGly and tRNAGlu on a 10 fold repeat of 3.2 kb EcoRI fragment.

Mature methyl-deficient tRNA isolated from a mammary adenocarcinoma

A transplantable rat tumor, mammary adenocarcinoma 13762, accumulates tRNA which can be methylated in vitro by mammalian tRNA (adenine-1) methyltransferase. This unusual ability of the tumor RNA to serve as substrate for a homologous tRNA methylating enzyme is correlated with unusually low levels of the A 58-specific adenine-1 methyltransferase. The nature of the methyl-accepting RNA has been examined by separating tumor tRNA on two-dimensional polyacrylamide gels. Comparisons of ethidium bromide-stained gels of tumor vs. liver tRNA show no significant quantitative differences and no accumulation of novel tRNAs or precursor tRNAs in adenocarcinoma RNA. Two-dimensional separations of tumor RNA after in vitro [14C]methylation using purified adenine-1 methyltransferase indicate that about 25% of the tRNA species are strongly methyl-accepting RNAs. Identification of six of the tRNAs separated on two-dimensional gels has been carried out by hybridization of cloned tRNA genes to Northern blots. Three of these, tRNALys3 , tRNAGln and tRNAMeti , are among the adenocarcinoma methyl-accepting RNAs. The other three RNAs, all of which are leucine-specific tRNAs, show no methyl-accepting properties. Our results suggest that low levels of a tRNA methyltransferase in the adenocarcinoma cause selected species of tRNA to escape the normal A58 methylation, resulting in the appearance of several mature tRNAs which are deficient in 1-methyladenine. The methyl-accepting tRNAs from the tumor appear as ethidium bromide-stained spots of similar intensity to those seen for RNA from rat liver; therefore, methyladenine deficiency does not seem to impair processing of these tRNAs.

Nucleotide sequences of two regions of the human genome containing tRNAAsn genes

The primary structures of two human tRNAAsn genes and 600-700 nucleotides of their flanking regions have been determined from two separate isolates of a fetal DNA library in phage lambda vector. The tRNA gene from one clone differs from the major mammalian tRNAAsn by a single base substitution at position 47, with an A replacing a G, while the tRNAAsn gene from the second clone has base substitutions at positions 17 and 65, with a G replacing a C and a T replacing a C, respectively. The sequences of the noncoding 5'- and 3'-flanking regions of both clones are over 90% homologous. As with other mammalian tRNA genes, these two human tRNAAsn genes contain CTTTTPu, which might act as a transcription termination signal, 11 bp 3' to the structural gene. In vitro transcription experiments in a HeLa cell extract demonstrate that both cloned tRNAAsn genes can be transcribed and processed to mature-sized tRNAs.

Generation of long read-through transcripts in vivo and in vitro by deletion of 3' termination and processing sequences in the human tRNAimet gene

The effects of 3' deletions of the coding and flanking regions of the human tRNAimet gene on its transcription and subsequent processing have been studied both in vitro and in vivo. We demonstrate that in the absence of the oligo T stop signal, polymerase III will read-through efficiently to the next available downstream stop signal. In mutations preserving the 3' terminal sequence of the coding region these read-through transcripts are efficiently processed, irrespective of their length and sequence by an endonucleolytic cleavage to yield both a mature tRNA and an intact trailer RNA. However, deletions involving the terminal regions up to +62 in the coding sequence produce an unprocessed co-transcript of tRNA and downstream sequences. Deletions further within the B promoter box abolish transcription. The use of these mutants as possible "portable" promoters is discussed.

Structure and evolution of a mouse tRNA gene cluster encoding tRNAAsp, tRNAGly and tRNAGlu and an unlinked, solitary gene encoding tRNAAsp

We have sequenced mouse tRNA genes from two recombinant lambda phage. An 1800 bp sequence from one phage contains 3 tRNA genes, potentially encoding tRNAAsp, tRNAGly, and tRNAGlu, separated by spacer sequences of 587 bp and 436 bp, respectively. The mouse tRNA gene cluster is homologous to a rat sequence (Sekiya et al., 1981, Nucleic Acids Res. 9, 2239-2250). The mouse and rat tRNAAsp and tRNAGly coding regions are identical. The tRNAGlu coding regions differ at two positions. The flanking sequences contain 3 non-homologous areas: a c. 100 bp insertion in the first mouse spacer, short tandemly repeated sequences in the second spacers and unrelated sequences at the 3' ends of the clusters. In contrast, most of the flanking regions are homologous, consisting of strings of consecutive, identical residues (5-17 bp) separated by single base differences and short insertions/deletions. The latter are often associated with short repeats. The homology of the flanking regions is c. 75%, similar to other murine genes. The second lambda clone contains a solitary mouse tRNAAsp gene. The coding region is identical to that of the clustered tRNAAsp gene. The 5' flanking regions of the two genes contain homologous areas (10-25 bp) separated by unrelated sequences. Overall, the flanking regions of the two mouse tRNAAsp genes are less homologous than those of the mouse and rat clusters.

tRNA transport from the nucleus in a eukaryotic cell: carrier-mediated translocation process

The mechanism by which a tRNA molecule is delivered from the nucleus of a cell to the cytoplasm has been studied in the Xenopus laevis oocyte utilizing nuclear microinjection and manual microdissection techniques. tRNA nuclear transport in this cell resembles a carrier-mediated translocation process rather than diffusion through a simple pore or channel. tRNA transport is saturable by tRNA, with a maximal rate measured to be about 190 X 10(7) molecules per min per nucleus (21 degrees C) in the mature oocyte. Competitive inhibition between two different tRNA species can be demonstrated, suggesting that many tRNA species share a common carrier system. tRNA nuclear transport is sharply dependent on temperature, with an optimal rate observed at 31 degrees C. A single G-to-U substitution at position 57 in the vertebrate tRNAMeti molecule reduces the transport rate of this tRNA by a factor of about 20, implicating this highly conserved region of the tRNA molecule (loop IV) as critical for recognition by the transport mechanism. On morphologic grounds I propose that ribosome-like components surrounding the nuclear pore may function as the tRNA translocation "motor." The tRNA nuclear transport mechanism represents a distinctly eukaryotic process and a site of potential control over cell growth and proliferation.

Characterization and nucleotide sequence of a chicken gene encoding an opal suppressor tRNA and its flanking DNA segments

A naturally occurring opal suppressor serine tRNA has been purified from chicken liver and used as a probe to isolate the corresponding gene from a library of chicken DNA in bacteriophage lambda. This minor tRNA is encoded by a single-copy gene that is not part of a tRNA gene cluster. DNA sequence analysis of the gene and its flanking DNA segments shows that the gene is encoded in an 87-base-pair segment without intervening sequences and specifies a tRNA that reads the termination codon UGA. This gene has additional nucleotides in the 5' internal promoter region but has a normal 3' internal promoter sequence and the usual termination signal.

Two nonallelic tRNAiMet genes are located in the p23 leads to q12 region of human chromosome 6

Two nonallelic human tRNAiMet genes were assigned to chromosome 6 by filter hybridization of DNA from human-rodent somatic cell hybrids by using probes containing unique sequences from the regions flanking each tRNAiMet gene. These unique sequence probes thus allowed each tRNAiMet gene to be analyzed individually in cell hybrids. Both tRNAiMet genes segregated in the hybrid cells with the chromosome 6 enzyme markers, soluble malic enzyme and the mitochondrial form of superoxide dismutase, and also with a karyotypically normal chromosome 6. By using hybrid clones containing translocations that divide chromosome 6 into five segments, both tRNAiMet genes were assigned to the p23 leads to q12 region. These results raise the possibility that other tRNAiMet genes may be syntenic with the two described in this study and illustrate the utility of using unique flanking sequences to identify members of a multigene family.

Isolation and characterization of genomic mouse DNA clones containing sequences homologous to tRNAs and 5S rRNA

We have cloned and characterized three fragments of Balb/c mouse DNA which hybridize to mouse cell tRNAs. Fractionation of the tRNAs which hybridize to these clones reveals that two of the clones, lambda Mt-4A and lambda Mt-6A hybridize to only one or two tRNAs, while one clone, lambda Mt-4B, hybridizes to at least seven tRNAs. Two of the tRNAs were identified as tRNAProCCG and tRNAGlyGGA, and others have been identified as tRNAs which are selectively encapsidated into virions of murine leukemia virus and avian reticuloendotheliosis virus. The DNA sequences of putative genes for tRNAProCCG and tRNAGlyGGA, plus flanking regions, were determined. A clone of Balb/c mouse DNA which selectively hybridized to 5S rRNA was also isolated and partially characterized.

A human tRNAGlu gene of high transcriptional activity

A mixture of low molecular weight RNAs, in which only tRNAs were radiolabelled, was used as a hybridisation probe to select for tRNA-like sequences within a bank of human genomic DNA in lambda Charon 4A. A restriction enzyme digest of one of the selected lambda Charon 4A recombinants contained two fragments (2.4 Kb & 1.8 Kb) which hybridised tRNA and which, when subcloned into pAT153, were transcribed in Xenopus oocyte nuclei. Analysis of the subcloned 2.4 Kb fragment, which was of remarkably high transcriptional activity, revealed the presence of a single gene for tRNAGlu in the middle of the fragment. The sequence immediately preceding the gene has the potential for forming a tRNA-like structure.

Isolation and characterization of three cloned fragments of human DNA coding for tRNAs and small nuclear RNA U1

Employing a human fetal liver library in lambda Charon 4A phage vector, we have isolated and characterized three clones of human DNA containing genes for tRNAs. One clone contains at least three tRNA genes (tRNALys, tRNAGln and tRNALeu) within 2 kb of each other. The other two clones contain two different single genes for tRNAAsn. One of these latter two DNAs also contains a gene for U1 small nuclear RNA.

Genes for two small cytoplasmic Ro RNAs are adjacent and appear to be single-copy in the human genome

Anti-Ro autoantibodies precipitate several small cytoplasmic ribonucleoproteins from mammalian cells. The RNA components of these particles, designated hY1-hY5 in human cells and mY1 and mY2 in mouse cells, are about 100 nucleotides long. We have analyzed a genomic clone that appears to contain true RNA-coding regions for two of the human Ro RNAs, hY1 and hY3. These RNAs exhibit many sequence and secondary structure homologies, both with each other and with the recently sequenced hY5 RNA. The hY2 RNA is a slightly truncated form of hY1; several shorter versions of hY3 are also detected in cell extracts and immunoprecipitates. The human hY1 and hY3 genes cross-hybridize with the mouse Ro RNAs, mY1 and mY2, respectively; we show that the mouse Ro RNAs are exclusively contained in Ro particles. The genes for hY1 and hY3 are transcribed in vitro by RNA polymerase III. In contrast with all other mammalian class III genes described, they appear to be present as single copies in the human genome.

Isolation and nucleotide sequence of a plant tRNA gene: petunia asparagine tRNA

A 14.3 kb petunia genomic DNA fragment was isolated and found to contain a single tRNA gene coding for asparagine tRNA. The nucleotide sequence of the asparagine tRNA gene and its flanking regions has been determined. This gene does not contain intervening sequences nor the 3'-end CCA sequence of the mature tRNA and presents a similar overall sequence homology (70%) to both E. coli and mammalian asparagine tRNA. As in other eukaryotic tRNA genes the 5'-flanking region does not seem to contain any special sequence that could function as a regulatory element and the 3'-end is followed by a short cluster of T that may function as the transcription termination site.

Sea urchin small nuclear RNA genes are organized in distinct tandemly repeating units

The genes coding for the two major small nuclear RNAs in the sea urchin are organized in independent tandem repeating units. The small nuclear RNAs, N1 and N2 were purified from gastrula embryos of Lytechinus variegatus. These RNAs are analogous to the U series of RNA in mammalian cells as judged by their identical 5' termini and the sequence homology of the N1 urchin RNA and U1 mouse RNA. These RNAs were polyadenylated with E. Coli adenylate transferase. A 32PO4 labeled copy of each RNA was made with RNA-dependent DNA polymerase. This copy was used to probe the gene organization of these RNAs by hybridizing to restriction enzyme digests of sperm DNA. Each of these RNAs is coded in a tandemly repeated cluster (at least 30 kb) with a repeat length of 1100-1400 bases. The N1 and N2 clusters are distinct. The N1 repeat has been cloned and the repeating organization confirmed with the cloned gene.

Nucleotide sequence of a segment of human DNA containing the three tRNA genes

A 1.65 kb segment of DNA from a human-lambda recombinant, selected for human tRNA genes, was subcloned in the plasmid pAT 153 for sequence determination. Three human tRNA genes were found; one, a tRNAlys gene which appears to specify a tRNA identical in sequence to the previously described tRNA3lys from rat liver (AAA,G); another a tRNAgln gene, the product of which would be expected to recognize only the codon CAG; and a third which would direct synthesis of a tRNAleu specific for CUA and G. Intervening sequences are not found in any of these genes. The three tRNA genes are separated by about 0.5 kb segments of DNA containing no apparent informational sequences. Examination of flanking sequences shows some similarities at the 5'-ends of the three genes, but less similarity to 5' flanking sequences of tRNA genes in other eucaryotes. All three tRNA genes direct synthesis of appropriate sized products in a HeLa cell lysate in vitro transcription system.

Isolation and nucleotide sequence of a mouse histidine tRNA gene

We have sequenced a 1307 base pair mouse genomic DNA fragment which contains a histidine tRNA gene. The sequence of the putative mouse histidine tRNA differs from the published sequence of sheep liver histidine tRNA by a single base change in the D-loop. It does not contain an unpaired 5' terminal G residue, as reported for Drosophila and sheep histidine tRNAs. The gene does not contain introns. The 3' flanking region contains a typical RNA polymerase III termination site of 6 consecutive T residues. 523 residues after the 3' end of the his tRNA coding region, the mouse DNA contains a sequence 72% homologous to part of the consensus sequence of the B1 (alu) family.

Characterization of a rat tRNA gene cluster containing the genes for tRNAAsp, tRNAGly and tRNAGlu, and pseudogenes

The putative genes for tRNAGAUAsp(C), tRNAGGAGly(G) and tRNAGAGGlu are in a cluster on the rat chromosome and are present exclusively in a 3.3 kb region cleaved with a restriction endonuclease EcoRI. The cluster reiterates about 10 times on the haploid DNA. Four lambda clones each containing an independent repeating unit were isolated from a rat gene library. The studies on the cloned DNA revealed that the length of the repeating unit including the 3.3 kb EcoRI fragment was at least 13.5 kb. Nucleotide sequence analysis of the 3.3 kb DNA in the isolated clones showed sequence variations among the repeating units and incomplete genes for tRNAGly and tRNAGlu within the clusters.

Precursor molecules of both human 5S ribosomal RNA and transfer RNAs are bound by a cellular protein reactive with anti-La lupus antibodies

The small ribonucleoproteins recognized by anti-La autoantibodies contain a heterogeneous mixture of small RNAs from uninfected mammalian cells. The identity of many of these has now been established by the discovery of precursor forms of 5S rRNA and of certain tRNAs among La RNAs from HeLa cells. The small fraction of 5S rRNA molecules that exist as La ribonucleoproteins in vivo possess 1 or 2 additional U residues at their 3' ends. Such 5S molecules bound to the La protein have also been identified with in vitro nuclear transcription systems. Pulse-chase experiments performed both in vivo and in vitro support the idea that most newly synthesized 5S rRNA molecules are transiently associated with the La protein. Cell extracts contain a processing activity that converts longer in vitro-synthesized 5S RNA transcripts into molecules of mature size. The presence of in vivo tRNA precursors in the heterogeneous mixture of La RNAs is demonstrated by the identification of precursor forms of five different specific tRNAs (Meti, Asp, Gly, Glu, Asn). After in vitro transcription of a tRNA gene (tRNAiMet), only products the size of precursor molecules are precipitable by anti-La antibodies. The realization that virtually every known RNA polymerase III product associates at least initially with the La antigen suggests that this protein plays an essential role in the synthesis or maturation of all class III transcripts.

Isolation and structure of a yeast initiator tRNAmet gene

Sixteen bacterial clones containing yeast initiator tRNAmet genes have been isolated. The size of the BamHI fragments encoding these genes ranges from 4,000 to 23,000 base pairs. The nucleotide sequence of one member of this group has been determined. It has no intervening sequences.

Isolation and characterization of cloned rat DNA fragment carrying tRNA genes

A rat genomic library was screened for tRNA genes with an unfractionated rat liver tRNA probe. About 70 clones containing tRNA genes were detected per rat genome. The organization of tRNA genes in five clones was analyzed by restriction endonuclease digestion, RNA-DNA hybridization and in vitro transcription with nuclear extracts from Xenopus oocytes. Evidence is presented suggesting that tRNA genes are distributed in the rat genome in small clusters spanning 1 to 2 kb and interspersed with large regions (minimum 8 to 20 kb) of non tRNA-coding DNA. The tRNA gene clusters were found to contain the sequences for a variety of tRNA species. Genes for a single isoacceptor, were found in more than one clone. The detailed study of one clone shows the repetition of a cluster of four tRNA sequences at a distance of about 8 kb. The arrangement of tRNA genes in rat appears to follow the irregular pattern of tRNA gene organization previously reported in Drosophila and Xenopus.

The initiator tRNA genes of Drosophila melanogaster: evidence for a tRNA pseudogene

We have isolated four segments of Drosophila melanogaster DNA that hybridize to homologous initiator tRNAMet. Three of the cloned fragments contain initiator tRNA genes, each of which can be transcribed in vitro. The fourth clone, pPW568, contains an initiator tRNA pseudogene which is not transcribed in vitro by RNA polymerase III. The pseudogene is contained in a 1.15 kb DNA fragment. This fragment has the characteristics of dispersed repetitive DNA and hybridizes in situ to at least 30 sites in the Drosophila genome. The arrangement of the initiator tRNA genes we have isolated, is different to that of other Drosophila tRNA gene families. The initiator tRNA genes are not clustered nor intermingled with other tRNA genes. They occur as single copies within an approximately 415-bp repeat segment, which is separated from other initiator tRNA genes by a mean distance of 17 kb. In situ hybridization to polytene chromosomes localizes these genes to the 61D region of the Drosophila genome. Hybridization analysis of genomic DNA indicates the presence of 8-9 non-allelic initiator tRNA genes in Drosophila melanogaster.