Nucleotide sequence and transcription of a human glycine tRNAGCC gene and nearby pseudogene

The tRNA(Ser)-isoacceptors and their genes in Nicotiana rustica: genome organization, expression in vitro and sequence analyses

The existence of six serine codons results in a complex pattern of tRNA(Ser) isoacceptors in organisms and organelles. According to the original wobble hypothesis, a minimum of three isoacceptors should be sufficient to read the six serine codons. We have isolated five cytoplasmic tRNAs(Ser) from leaves of Nicotiana rustica. Their nucleotide sequences identify them as four different isoacceptors with the anticodons cm5UGA, CGA, IGA and GCU. For tRNA(Ser) with IGA anticodon, two species have been detected which vary only by one nucleotide in the long extra arm. The first three isoacceptors recognize codons of the type UCN whereas the fourth isoacceptor reads the two serine codons AGC and AGU. The tRNA(Ser) sequences were used to design appropriate primers for the amplification of Nicotiana nuclear tRNA(Ser) genes by the polymerase chain reaction (PCR). A total number of eight tRNA(Ser) genes differing in the coding region were thus identified. Selected PCR DNA fragments were then employed as probes for the isolation of the corresponding genes from a nuclear DNA library of N. rustica. Sequence analyses revealed that five of the isolated seven clones contained tRNA(Ser) genes which are identical in sequence with the five cytoplasmic tRNAs(Ser) mentioned above. None of them contains an intervening sequence. This is the first time that all putative cellular tRNA(Ser) isoacceptors and their corresponding genes have been characterized in an eukaryotic organism. Most of the tRNA(Ser) genes are functional as deduced from in vitro transcription and processing studies. Two of the genes yield pre-tRNAs(Ser) which are not or poorly converted to mature tRNA in a plant extract. The approximate tRNA(Ser) gene number was estimated by hybridization of specific DNA probes to Eco RI-cleaved Nicotiana nuclear DNA. The overall hybridization pattern indicates that members of each particular tRNA(Ser) gene family do not appear to be clustered but distributed randomly throughout the Nicotiana genome.

An intron-containing tRNAArg gene within a large cluster of human tRNA genes

The insert within lambda Ht363, a recombinant selected from a bank of human genomic DNA cloned in lambda Ch4A, is described. Southern blot hybridization with a mixed tRNA[32P]pCp probe revealed the presence of four tRNA genes, which were shown to represent further copies of genes previously identified as a solitary tRNAGly gene and as a three gene cluster on two different recombinants. In vitro transcription of a fragment containing the three gene cluster revealed the presence of a further pol III gene, which was shown to be that for a tRNAArgTCT. This gene contains a 15 bp intron, the presence of which presumably prevented its detection on Southern blots by tRNA hybridisation. The gene is present in the previously reported cluster and occurs in higher copy number (> 7) in other arrangements in the genome. Most of the copies of the gene have related intron sequences.

A human DNA segment encompassing leucine and methionine tRNA pseudogenes localized on chromosome 6

A human genomic clone, designated LHtlm8, that strongly hybridized to a mammalian leucine tRNA(IAG) probe, was found to encompass a pair of tRNA pseudogenes that are transcribed in a homologous cell extract. A leucine tRNA(AAG) pseudogene (TRLP1) is 2.1-kb upstream and of opposite polarity to a methionine elongator tRNA(CAU) pseudogene (TRMEP1). TRLP1 has three nucleotide variations (97% identity) from its cognate leucine tRNA(IAG), while TRMEP1 has a 78% identity with its cognate tRNA. Similar to a number of other eukaryotic tRNA pseudogenes, presumptive precursor tRNA transcripts are generated from the two pseudogenes in vitro, but possibly due to their aberrant and unstable secondary and tertiary structures, no detectable mature tRNA products are observed. The two tRNA pseudogenes are encompassed within a 9.6-kb EcoRI fragment that has been assigned to the chromosomal locus, 6pter-q13, by Southern blot hybridization of human-rodent somatic cell hybrid DNAs with probes derived from the cloned tRNA pseudogenes and flanking sequences. A 4.4-kb EcoRI fragment also harbored in clone LHtlm8 was mapped to human chromosome 11, suggesting that the two EcoRI fragments were inadvertantly ligated together during construction of the genomic library.

The first human genes for tRNA(ArgICG), tRNA(GlyUCC), and tRNA(ThrIGU) and more tRNA(Val) pseudogenes: expression and pre-tRNA maturation in HeLa cell-free extracts

A functional tRNA(Val) gene, which codes for the major tRNA(ValIAC) isoacceptor species, and three new tRNA(Val) pseudogenes have been isolated from human genomic DNA. Two tRNA(Val) pseudogenes and a tRNA(Val) variant gene were found to be associated with tRNA genes encoding tRNA(ArgICG), tRNA(GlyUCC), and tRNA(ThrIGU), respectively, on distinct DNA fragments. All tRNA genes, including the pseudogenes, are actively transcribed in HeLa nuclear extract. Pre-tRNAs of tRNA(Val), tRNA(Arg), tRNA(Thr), and tRNA(Gly) genes are correctly processed to mature-sized tRNAs, whereas the three tRNA(Val) pseudogenes yield stable pre-tRNAs in vitro. These findings reveal that, together with the three known pseudogenes, half of the members of the human tRNA(Val) gene family are pseudogenes, all of which are active in homologous nuclear extracts in vitro and presumably also in vivo.

Expression of variant nuclear Arabidopsis tRNA(Ser) genes and pre-tRNA maturation differ in HeLa, yeast and wheat germ extracts

We have recently identified a tRNA gene cluster in the Arabidopsis nuclear genome. One tRNA(Ser) (AGA) gene and two tRNA(Tyr) (GTA) genes occur in tandem arrangement on a 1.5 kb unit that is amplified about 20-fold at a single chromosomal site. Here we have studied the in vitro expression of seven individually cloned tRNA(Ser) genes (pAtS1 to pAtS7) derived from this cluster. Five out of the seven tRNA(Ser) genes contain point mutations in the coding region which have in part adverse effects on the expression of these genes in different cell-free systems: (i) C10 and A62 in plant tRNA(Ser) genes, which correspond to G10 and C62, respectively, in all known vertebrate tRNA genes, result in a reduced transcription efficiency in HeLa but not in yeast extract. This indicates that yeast RNA polymerase III tolerates nucleotide substitutions at positions 10 [5' internal control region (ICR)] and 62 (3' ICR), whereas the vertebrate RNA polymerase III requires a more stringent consensus sequence. (ii) Processing of a pre-tRNA(Ser) with a mismatch in the aminoacyl stem is impaired in HeLa, yeast and wheat germ extracts, however, a mismatch in the anticodon stem is deleterious for HeLa and wheat germ but not for yeast processing enzymes. The unexpectedly high number of potential tRNA(Ser) pseudogenes in the cluster - quite in contrast to the tRNA(Ser) genes which mainly code for functional tRNAs - suggested that tRNA(Ser) (AGA) genes also occur elsewhere in the genome. We present evidence that single copies of tRNA(Ser) (AGA) genes do indeed exist outside the tRNA gene cluster.

Transfer RNA genes from Dictyostelium discoideum are frequently associated with repetitive elements and contain consensus boxes in their 5' and 3'-flanking regions

A total of 68 different tRNA genes from the cellular slime mold Dictyostelium discoideum have been isolated and characterized. Although these tRNA genes show features common to typical nuclear tRNA genes from other organisms, several unique characteristics are apparent: (1) the 5'-proximal flanking region is very similar for most of the tRNA genes; (2) more than 80% of the tRNA genes contain an "ex-B motif" within their 3'-flanking region, which strongly resembles characteristics of the consensus sequence of a T-stem/T-loop region (B-box) of a tRNA gene; (3) probably more than 50% of the tRNA genes in certain D. discoideum strains are associated with a retrotransposon, termed DRE (Dictyostelium repetitive element), or with a transposon, termed Tdd-3 (Transposon Dictyostelium discoideum). DRE always occurs 50 (+/- 3) nucleotides upstream and Tdd-3 always occurs 100 (+/- 20) nucleotides downstream from the tRNA gene. D. discoideum tRNA genes are organized in multicopy gene families consisting of 5 to 20 individual genes. Members of a particular gene family are identical within the mature tRNA coding region while flanking sequences are idiosyncratic.

Localization of a DNA segment encompassing four tRNA genes to human chromosome 14q11 and its use as an anchor locus for linkage analysis

The chromosomal location of an 8.2-kb genomic fragment encompassing a cluster of four human tRNA genes has been determined by three complementary methods including Southern analysis of human/rodent somatic cell hybrids, in situ hybridization, and genetic linkage analysis. This tRNA cluster (TRP1, TRP2, and TRL1) is located near the T-cell receptor alpha (TCRA) locus at 14q11, and several RFLPs were detected at this site. These RFLPs and those at the TCRA and MYH7 (cardiac beta-MHC gene) loci have been used to type all informative members of the CEPH pedigrees. This has permitted ordering of these three gene loci and two anonymous probes (D14S26 and D14S25) in a 20-cM interval just below the centromere of chromosome 14. Based upon the chromosomal location and the polymorphisms at this site, one or more members of this gene cluster could serve as a useful anchor locus on chromosome 14.

Chromosomal assignment of a large tRNA gene cluster (tRNA(Leu), tRNA(Gln), tRNA(Lys), tRNA(Arg), tRNA(Gly)) to 17p13.1

A cluster of tRNA genes (tRNA(UAGLeu), tRNA(CUGGln), tRNA(UUULys), tRNA(UCUArg)) and an adjacent tRNA(GCCGly) have been assigned to human chromosome 17p12-p13.1 by in situ hybridization using a 4.2 kb human DNA fragment for tRNA(Leu), tRNA(Gln), tRNA(Lys), tRNA(Arg), and, for tRNA(Gly), 1.3 kb and 0.58 kb human DNA fragments containing these genes as probes. This localization was confirmed and refined to 17p13.100-p13.105 using a somatic cell hybrid mapping panel. Preliminary experiments with the biotinylated tRNA Leu, Gln, Lys, Arg probe and metaphase spreads from other great apes suggest the presence of a hybridization site on the long arm of gorilla (Gorilla gorilla) chromosome 19 and the short arm of orangutan (Pongo pygmaeus) chromosome 19 providing further support for homology between HSA17, GGO19 and PPY19.

Genes, variant genes and pseudogenes of the human tRNA(Val) gene family. Expression and pre-tRNA maturation in vitro

Nine different members of the human tRNA(Val) gene family have been cloned and characterized. Only four of the genes code for one of the known tRNA(Val) isoacceptors. The remaining five genes carry mutations, which in two cases even affect the normal three-dimensional tRNA structure. Each of the genes is transcribed by polymerase III in a HeLa cell nuclear extract, but their transcription efficiencies differ by up to an order of magnitude. Conserved sequences immediately flanking the structural genes that could serve as extragenic control elements were not detected. However, short sequences in the 5' flanking region of two genes show striking similarity with sequences upstream from two Drosophila melanogaster tRNA(Val) genes. Each of the human tRNA(Val) genes has multiple, i.e. two to four, transcription initiation sites. In most cases, transcription termination is caused by oligo(T) sequences downstream from the structural genes. However, the signal sequences ATCTT and CTTCTT also serve as effective polymerase III transcription terminators. The precursors derived from the four tRNA(Val) genes coding for known isoacceptors and those derived from two mutant genes are processed first at their 3' and subsequently at their 5' ends to yield mature tRNAs. The precursor derived from a third mutant gene is incompletely maturated at its 3' end, presumably as a consequence of base-pairing between 5' and 3' flanking sequences. Finally, precursors encoded by the genes that carry mutations affecting the tRNA tertiary structure are completely resistant to 5' and 3' processing.

Localization of three DNA segments encompassing tRNA genes to human chromosomes 1, 5, and 16: proposed mechanism and significance of tRNA gene dispersion

The chromosomal locations of three cloned human DNA fragments encompassing tRNA genes have been determined by Southern analysis of human-rodent somatic cell hybrid DNAs with subfragments from these cloned genes and flanking sequences used as hybridization probes. These three DNA segments have been assigned to human chromosomes 1, 5, and 16, and homologous sequences are probably located on chromosome 14 and a separate locus on chromosome 1. These studies, combined with previous results, indicate that tRNA genes and pseudogenes are dispersed on at least seven different human chromosomes and suggest that these sequences will probably be found on most, if not all, human chromosomes. Short (8-12 nucleotide) direct terminal repeats flank many of the dispersed tRNA genes. The presence of these flanking repeats, combined with the dispersion of tRNA genes throughout the human genome, suggests that many of these genes may have arisen by an RNA-mediated retroposition mechanism. The possible functional significance of this gene dispersion is considered.

A human tRNA gene cluster encoding the major and minor valine tRNAs and a lysine tRNA

A human genomic DNA clone hybridizing to mammalian valine tRNA(IAC) contained a cluster of three tRNA genes. Two valine tRNA genes with anticodons of AAC and CAC, encoding the major and minor cytoplasmic valine tRNA isoacceptors, respectively, and a lysine tRNA(CUU) gene were identified by Southern blot hybridization and DNA sequence analysis of a 7.1-kb region. At least nine Alu family members were interspersed throughout the 18.5-kb human DNA fragment, with three Alu elements in the intergenic region between the valine tRNA(AAC) gene and the lysine tRNA gene. Each of the five Alu family members in the sequenced region can be categorized into one of the four Alu subfamilies. The coding regions of all three tRNA genes contain characteristic internal split promoter sequences and typical RNA polymerase III termination signals in the 3'-flanking regions. The tRNA genes are accurately transcribed by RNA polymerase III in a HeLa cell extract, since the RNase T1 fingerprints of the mature-sized tRNA transcription products are consistent with the structural genes. The lysine tRNA(CUU) gene was transcribed only slightly more efficiently than the valine tRNA(CAC) gene in the homologous in vitro transcription system. Surprisingly, the valine tRNA(CAC) gene was transcribed about eightfold more efficiently than the valine tRNA(AAC) gene, implicating the presence of a modulatory element in the upstream region flanking the tRNA(CAC) gene.

A human tRNA gene heterocluster encoding threonine, proline and valine tRNAs

A cluster of three tRNA genes encoding a tRNA(UGUThr), a tRNA(UGGPro), and a tRNA(AACVal), and two Alu-elements occur in a 6.0-kb human DNA fragment. The tRNA(Thr) gene is 2.7-kb upstream from the tRNA(Pro) gene, which is separated by 367 bp from the tRNA(Val) gene. One Alu-element actually overlaps the tRNA(Val) gene and is of opposite polarity to all three tRNA genes. All three tRNA genes are accurately transcribed in a homologous HeLa cell extract, since the ribonuclease T1 fingerprints of the tRNA transcripts are consistent with the nucleotide sequences of the tRNAs. The upstream region flanking the tRNA(Thr) gene has two tracts of alternating purine/pyrimidine residues potentially capable of adopting the Z-DNA conformation, and presumptive binding sites for two RNA polymerase II transcription factors. The tRNA(Thr) gene apparently has a substantially higher in vitro transcriptional efficiency than the other two tRNA genes in this cluster, and a tRNA(GCCGly) gene from another human DNA segment. Deletion constructs of the tRNA(Thr) gene retaining 272, 168, and 33 bp of original 5'-flanking DNA had about the same in vitro transcriptional efficiency, whereas that of the construct with only 2 bp of 5'-flanking human DNA was drastically reduced. The tRNA(Thr) gene constructs with 272 and 168 bp of original 5'-flanking DNA apparently reduce the transcriptional efficiencies of the proline and glycine tRNA genes, implicating the upstream region from the tRNA(Thr) gene as being crucial for its high transcriptional efficiency.

Chromosomal assignment of a glutamic acid transfer RNA (tRNAGlu) gene to 1p36

A gene for tRNAGlu has been assigned to human chromosome 1p36 by in situ hybridisation using a [3H]-labelled or biotinylated 2.4-kb (human) DNA fragment containing a tRNAGlu gene as a probe. With the biotinylated DNA probe a secondary statistically significant site of hybridisation was observed at 1q21-22 which might represent a pseudogene or related sequence. In fibroblasts from gorilla (Gorilla gorilla) using biotin labelling, a single site of hybridisation occurred at 1qter which provides further support for homology of 1q in the higher apes and human 1p.

Two human genes encoding tRNA(GCCGly)

Two human DNA fragments of 16.7 and 15.5 kb have been selected from a human lambda Charon-4A library by hybridization to an unfractionated tRNA probe. Restriction mapping and Southern and Northern hybridization analyses revealed the presence of a single tRNA-hybridizing region in each of the human DNA fragments. Nucleotide sequence analysis has identified two identical members of the tRNA(GCCGly) gene family. These tRNA(GCCGly) genes encode all of the conserved and semiconserved nucleotides of the tDNA split promoter sequences. Neither gene contains introns or encodes the CCA sequence present on the 3' terminus of mature tRNA. One of these identical tRNA(GCCGly) genes was found to be expressed at a substantially greater efficiency than the other in a HeLa cell lysate in vitro transcription system. No similarity was detected in the nucleotide sequences flanking these genes other than the characteristic, 3' oligo[dT] transcription termination signals and a TCTTT sequence located 7 to 10 bp upstream. These data are consistent with the hypothesis that as yet unidentified tDNA flanking sequences may have an important role in modulating human tRNA gene expression.

Increased levels of glycine tRNA associated with collagen synthesis

Analysis of codon usage for chick Type I collagen indicates that 89% of glycine codons are GGU/C. Since collagens are one-third glycine, chick Type I collagen synthesis should require large amounts of tRNAGly with the anticodon GCC. Earlier chromatographic studies of chick tRNA had indicated that connective tissues showed altered tRNAGly isoacceptor profiles [P. J. Christner and J. Rosenbloom (1976) Arch. Biochem. Biophys. 172, 399-409; H. J. Drabkin and L. N. Lukens (1978) J. Biol. Chem. 253, 6233-6241]. We have therefore used both two-dimensional gel electrophoresis and hybridization analysis to investigate whether collagen synthesis in chick connective tissues is associated with expression of a novel tRNAGly. Liver and calvaria tRNAs produced qualitatively similar patterns when separated on 2-D gels. Northern blots of 2-D-separated tRNAs from liver and calvaria, when hybridized to genes for vertebrate tRNAGly isoacceptors with GCC or UCC anticodons, showed hybridization to the same tRNAs in both tissues. Quantitation of tRNA species by dot blot hybridization indicated an increase in levels of the tRNAGly isoacceptor with anticodon GCC. Tissues synthesizing Type I collagen had a two- to threefold increase in this tRNA while tissues synthesizing Type II collagen showed a more modest increase. We conclude that elevated tRNAGly levels associated with collagen synthesis are due to increased amounts of the same isoacceptor which is the major tRNAGly in other tissues.

Analysis of a human gene cluster coding for tRNA(GAAPhe) and tRNA(UUULys)

A 13.8-kb fragment of human DNA isolated from a human lambda Charon-4A DNA library was found to contain four human tRNA genes. Nucleotide sequence analysis of approx. 3.7 kb of this segment of human DNA identified two lysine tRNA(UUU) genes identical in coding sequence to a previously reported human lysine tRNA gene [Roy et al., Nucl. Acids Res. 10 (1982) 7313-7322]. The other two tRNA genes were phenylalanine tRNA(GAA) genes, the first to be isolated from a mammalian source. These phenylalanine tRNA(GAA) genes were identical in sequence with the exception of a G/A polymorphism at coordinate 57. None of these tRNA genes contains introns. The tRNA(UUULys) and tRNA(GAAPhe) genes are organized in alternating order and are irregularly spaced, by intergenic regions of approx. 1.0, 2.6 and 5.0 kb, and randomly oriented. There was no evidence to indicate that any of these genes arose by gene duplication, since flanking sequence homology was limited to the putative RNA polymerase III termination signals in the 3'-flanking regions. A mature tRNA-sized product was identified following the transcription of each tRNA gene in a homologous in vitro transcription system. Interestingly, different levels of transcriptional activity of the three identical lysine tRNA genes were observed, suggesting modulation of tDNA expression by extragenic sequences. In addition, a minimum of eight regions of homology to Alu-type repetitive elements were detected in this human DNA fragment, one of which was located 53 bp upstream from a tRNA(GAAPhe) gene.

Nucleotide sequence and transcription of a human tRNA gene cluster with four genes

A bacteriophage lambda clone containing a 20-kb human DNA segment was isolated and found to harbor a cluster of four tRNA genes. An 8.2-kb HindIII subfragment encompassing the genes was cloned into pBR322 for restriction mapping and DNA sequence analysis. The genes were found to be arranged as two tandem pairs, separated by 3 kb. A proline tRNAAGG gene is separated from a leucine tRNAAAG gene by a 724-bp intergenic region in the first pair, and a second proline tRNAAGG gene is 316 bp from a threonine tRNAUGU gene in the second pair, with the leucine tRNA gene being of opposite polarity to the other three genes. A putative Alu-like element was found to occur within a 2.0-kb DNA fragment, at least 0.7 kb from the tRNA gene cluster. The coding sequences of the two proline tRNAAGG genes are identical. The coding regions of all four tRNA genes contain consensus internal split promoter sequences and do not have intervening sequences nor the CCA trinucleotide found in mature tRNAs. The 3'-flanking regions of these four tRNA genes have normal RNA polymerase III termination sites of at least four consecutive T nucleotides. No apparent homologies occur between the 5'-flanking regions of these genes. All four tRNA genes are accurately transcribed in an in vitro HeLa cell-free system, and the RNase T1 fingerprints of the mature-sized tRNA transcripts were found to be consistent with the DNA sequences of the genes.