The yeast tRNATyr gene intron is essential for correct modification of its tRNA product

PTA1, an essential gene of Saccharomyces cerevisiae affecting pre-tRNA processing

We have identified an essential Saccharomyces cerevisiae gene, PTA1, that affects pre-tRNA processing. PTA1 was initially defined by a UV-induced mutation, pta1-1, that causes the accumulation of all 10 end-trimmed, intron-containing pre-tRNAs and temperature-sensitive but osmotic-remedial growth. pta1-1 does not appear to be an allele of any other known gene affecting pre-tRNA processing. Extracts prepared from pta1-1 strains had normal pre-tRNA splicing endonuclease activity. pta1-1 was suppressed by the ochre suppressor tRNA gene SUP11, indicating that the pta1-1 mutation creates a termination codon within a protein reading frame. The PTA1 gene was isolated from a genomic library by complementation of the pta1-1 growth defect. Episome-borne PTA1 directs recombination to the pta1-1 locus. PTA1 has been mapped to the left arm of chromosome I near CDC24; the gene was sequenced and could encode a protein of 785 amino acids with a molecular weight of 88,417. No other protein sequences similar to that of the predicted PTA1 gene product have been identified within the EMBL or GenBank data base. Disruption of PTA1 near the carboxy terminus of the putative open reading frame was lethal. Possible functions of the PTA1 gene product are discussed.

PTA1, an essential gene of Saccharomyces cerevisiae affecting pre-tRNA processing

We have identified an essential Saccharomyces cerevisiae gene, PTA1, that affects pre-tRNA processing. PTA1 was initially defined by a UV-induced mutation, pta1-1, that causes the accumulation of all 10 end-trimmed, intron-containing pre-tRNAs and temperature-sensitive but osmotic-remedial growth. pta1-1 does not appear to be an allele of any other known gene affecting pre-tRNA processing. Extracts prepared from pta1-1 strains had normal pre-tRNA splicing endonuclease activity. pta1-1 was suppressed by the ochre suppressor tRNA gene SUP11, indicating that the pta1-1 mutation creates a termination codon within a protein reading frame. The PTA1 gene was isolated from a genomic library by complementation of the pta1-1 growth defect. Episome-borne PTA1 directs recombination to the pta1-1 locus. PTA1 has been mapped to the left arm of chromosome I near CDC24; the gene was sequenced and could encode a protein of 785 amino acids with a molecular weight of 88,417. No other protein sequences similar to that of the predicted PTA1 gene product have been identified within the EMBL or GenBank data base. Disruption of PTA1 near the carboxy terminus of the putative open reading frame was lethal. Possible functions of the PTA1 gene product are discussed.

Self-splicing introns in tRNA genes of widely divergent bacteria

The organization of eukaryotic genes into exons separated by introns has been considered as a primordial arrangement but because it does not exist in eubacterial genomes it may be that introns are relatively recent acquisitions. A self-splicing group I intron has been found in cyanobacteria at the same position of the same gene (that encoding leucyl transfer RNA, UAA anticodon) as a similar group I intron of chloroplasts, which indicates that this intron predates the invasion of eukaryotic cells by cyanobacterial endosymbionts. But it is not clear from this isolated example whether introns are more generally present in different genes or in more diverse branches of the eubacteria. Many mitochondria have intron-rich genomes and were probably derived from the alpha subgroup of the purple bacteria (or Proteobacteria), so ancient introns might also have been retained in these bacteria. We describe here the discovery of two small (237 and 205 nucleotides) self-splicing group I introns in members of two proteobacterial subgroups, Agrobacterium tumefaciens (alpha) and Azoarcus sp. (beta). The introns are inserted in genes for tRNA(Arg) and tRNA(Ile), respectively, after the third anticodon nucleotide. Their occurrence in different genes of phylogenetically diverse bacteria indicates that group I introns have a widespread distribution among eubacteria.

Inhibition of cell proliferation in Saccharomyces cerevisiae by expression of human NAD+ ADP-ribosyltransferase requires the DNA binding domain ("zinc fingers")

Constitutive expression of human nuclear NAD+: protein ADP-ribosyltransferase (polymerizing) [pADPRT; poly(ADP-ribose)polymerase; EC 2.4.2.30] as an active enzyme in Saccharomyces cerevisiae, under the control of the alcohol dehydrogenase promoter, was only possible with simultaneous inhibition of ADP-ribosylation by 3-methoxybenzamide. Induction of fully active pADPRT from the inducible galactose epimerase promoter resulted in inhibition of cell division and morphological changes reminiscent of cell cycle mutants. Expression of a pADPRT cDNA truncated at its 5' end had no influence on cell proliferation at all. Obviously the amino-terminal part of the DNA binding domain containing the first "zinc finger", which is essential for inducibility of pADPRT activity by DNA breaks, is also required for inhibition of cell growth on expression in yeast. Full-length as well as truncated pADPRT molecules were directed to the cell nucleus where the fully active enzyme produced large amounts of poly(ADP-ribose) by automodification. Since pADPRT turned out to be the only target for ADP-ribosylation in these cells, elevated levels of poly(ADP-ribose) were the most likely cause of inhibition of cell division, presumably resulting from interaction with chromosomal proteins.

The antiquity of group I introns

The recent discovery of self-splicing introns in cyanobacteria has given renewed interest to the question of whether introns may have been present in the ancestor of all living things. The properties of introns in genes of bacteria and bacteriophages are discussed in the context of their possible origin and biological function.

Plant nonsense suppressor tRNA(Tyr) genes are expressed at very low levels in vitro due to inefficient splicing of the intron-containing pre-tRNAs

Oligonucleotide-directed mutagenesis was used to generate amber, ochre and opal suppressors from cloned Arabidopsis and Nicotiana tRNA(Tyr) genes. The nonsense suppressor tRNA(Tyr) genes were efficiently transcribed in HeLa and yeast nuclear extracts, however, intron excision from all mutant pre-tRNAs(Tyr) was severely impaired in the homologous wheat germ extract as well as in the yeast in vitro splicing system. The change of one nucleotide in the anticodon of suppressor pre-tRNAs leads to a distortion of the potential intron-anticodon interaction. In order to demonstrate that this caused the reduced splicing efficiency, we created a point mutation in the intron of Arabidopsis tRNA(Tyr) which affected the interaction with the wild-type anticodon. As expected, the resulting pre-tRNA was also inefficiently spliced. Another mutation in the intron, which restored the base-pairing between the amber anticodon and the intron of pre-tRNA(Tyr), resulted in an excellent substrate for wheat germ splicing endonuclease. This type of amber suppressor tRNA(Tyr) gene which yields high levels of mature tRNA(Tyr) should be useful for studying suppression in higher plants.

In vivo pre-tRNA processing in Saccharomyces cerevisiae

We have surveyed intron-containing RNAs of the yeast Saccharomyces cerevisiae by filter hybridization with pre-tRNA intron-specific oligonucleotide probes. We have classified various RNAs as pre-tRNAs, splicing intermediates, or excised intron products according to apparent size and structure. Linear, excised intron products were detected, and one example was isolated and sequenced directly. Additional probes designed to detect other precursor sequences were used to verify the identification of several intermediates. Pre-tRNA species with both 5' leader and 3' extension, with 3' extension only, and with mature ends were distinguished. From these results, we conclude that the processing reactions used to remove the 5' leader and 3' extension from the transcript are ordered 5' end trimming before 3' end trimming. Splicing intermediates containing the 5' exon plus the intron were detected. The splice site cleavage reactions are probably ordered 3' splice site cleavage before 5' splice site cleavage. Surprisingly, we also detected a splicing intermediate with the 5' leader and a spliced product with both 5' leader and 3' extension. Evidently, splicing and end trimming are not ordered relative to each other, splicing occurring either before or after end trimming.

Nuclear tRNA(Tyr) genes are highly amplified at a single chromosomal site in the genome of Arabidopsis thaliana

We have examined the organization of tRNA(Tyr) genes in three ecotypes of Arabidopsis thaliana, a plant with an extremely small genome of 7 x 10(7) bp. Three tRNA(Tyr) gene-containing EcoRI fragments of 1.5 kb and four fragments of 0.6, 1.7, 2.5 and 3.7 kb were cloned from A. thaliana cv. Columbia (Col-O) DNA and sequenced. All EcoRI fragments except those of 0.6 and 2.5 kb comprise an identical arrangement of two tRNA(Tyr) genes flanked by a tRNA(Ser) gene. The three tRNA genes have the same polarity and are separated by 250 and 370 bp, respectively. The tRNA(Tyr) genes encode the known cytoplasmic tRNA(G psi ATyr). Both genes contain a 12 bp long intervening sequence. Densitometric evaluation of the genomic blot reveals the presence of at least 20 copies, including a few multimers, of the 1.5 kb fragment in Col-O DNA, indicating a multiple amplification of this unit. Southern blots of EcoRI-digested DNA from the other two ecotypes, cv. Landsberg (La-O) and cv. Niederzenz (Nd-O) also show 1.5 kb units as the major hybridizing bands. Several lines of evidence support the idea of a strict tandem arrangement of this 1.5 kb unit: (i) Sequence analysis of the EcoRI inserts of 2.5 and 0.6 kb reveals the loss of an EcoRI site between 1.5 kb units and the introduction of a new EcoRI site in a 1.5 kb dimer. (ii) Complete digestion of Col-O DNA with restriction enzymes which cleave only once within the 1.5 kb unit also produces predominantly 1.5 kb fragments. (iii) Partial digestion with EcoRI shows that the 1.5 kb fragments indeed arise from the regular spacing of the restriction sites.(ABSTRACT TRUNCATED AT 250 WORDS)

In vivo pre-tRNA processing in Saccharomyces cerevisiae

We have surveyed intron-containing RNAs of the yeast Saccharomyces cerevisiae by filter hybridization with pre-tRNA intron-specific oligonucleotide probes. We have classified various RNAs as pre-tRNAs, splicing intermediates, or excised intron products according to apparent size and structure. Linear, excised intron products were detected, and one example was isolated and sequenced directly. Additional probes designed to detect other precursor sequences were used to verify the identification of several intermediates. Pre-tRNA species with both 5' leader and 3' extension, with 3' extension only, and with mature ends were distinguished. From these results, we conclude that the processing reactions used to remove the 5' leader and 3' extension from the transcript are ordered 5' end trimming before 3' end trimming. Splicing intermediates containing the 5' exon plus the intron were detected. The splice site cleavage reactions are probably ordered 3' splice site cleavage before 5' splice site cleavage. Surprisingly, we also detected a splicing intermediate with the 5' leader and a spliced product with both 5' leader and 3' extension. Evidently, splicing and end trimming are not ordered relative to each other, splicing occurring either before or after end trimming.

Yeast tRNATrp genes with anticodons corresponding to UAA and UGA nonsense codons

Naturally occurring suppressor mutants derived from tRNATrp genes have never been identified in S. cerevisiae. Oligonucleotide-directed mutagenesis was used to generate potential ochre and opal suppressors from a cloned tRNATrp gene. In vitro transcription analyses show the ochre suppressor form of the gene, TRPO, accumulates precursors and tRNA in amounts comparable to the parent. The opal suppressor, TRPOP, accumulates 4-5 fold less tRNA. Both forms of the gene are processed and spliced in vitro to produce tRNAs with the expected base sequences. The altered genes were subcloned into yeast vectors and introduced into yeast strains carrying a variety of amber, ochre, and opal mutations. When introduced on a CEN vector, neither ochre nor opal suppressor forms show suppressor activity. Deletion of the CEN region from the clones increases the copy number to 10-20/cell. The opal suppressor form shows moderate suppressor activity when the gene is introduced on this vector, however, the ochre suppressor form exhibits no detectable biological activity regardless of gene copy number. Northern blot analyses of the steady state levels of tRNATrp in cells containing the high copy-number clones reveal 20-100% increases in the abundance of tRNATrp.

A bacterial amber suppressor in Saccharomyces cerevisiae is selectively recognized by a bacterial aminoacyl-tRNA synthetase

Little is known about the conservation of determinants for the identities of tRNAs between organisms. We showed previously that Escherichia coli tyrosine tRNA synthetase can charge the Saccharomyces cerevisiae mitochondrial tyrosine tRNA in vivo, even though there are substantial sequence differences between the yeast mitochondrial and bacterial tRNAs. The S. cerevisiae cytoplasmic tyrosine tRNA differs in sequence from both its yeast mitochondrial and E. coli counterparts. To test whether the yeast cytoplasmic tyrosyl-tRNA synthetase recognizes the E. coli tRNA, we expressed various amounts of an E. coli tyrosine tRNA amber suppressor in S. cerevisiae. The bacterial tRNA did not suppress any of three yeast amber alleles, suggesting that the yeast enzymes retain high specificity in vivo for their homologous tRNAs. Moreover, the nucleotides in the sequence of the E. coli suppressor that are not shared with the yeast cytoplasmic tyrosine tRNA do not create determinants which are efficiently recognized by other yeast charging enzymes. Therefore, at least some of the determinants that influence in vivo recognition of the tyrosine tRNA are specific to the cell compartment and organism. In contrast, expression of the cognate bacterial tyrosyl-tRNA synthetase together with the bacterial suppressor tRNA led to suppression of all three amber alleles. The bacterial enzyme recognized its substrate in vivo, even when the amount of bacterial tRNA was less than about 0.05% of that of the total cytoplasmic tRNA.

A bacterial amber suppressor in Saccharomyces cerevisiae is selectively recognized by a bacterial aminoacyl-tRNA synthetase

Little is known about the conservation of determinants for the identities of tRNAs between organisms. We showed previously that Escherichia coli tyrosine tRNA synthetase can charge the Saccharomyces cerevisiae mitochondrial tyrosine tRNA in vivo, even though there are substantial sequence differences between the yeast mitochondrial and bacterial tRNAs. The S. cerevisiae cytoplasmic tyrosine tRNA differs in sequence from both its yeast mitochondrial and E. coli counterparts. To test whether the yeast cytoplasmic tyrosyl-tRNA synthetase recognizes the E. coli tRNA, we expressed various amounts of an E. coli tyrosine tRNA amber suppressor in S. cerevisiae. The bacterial tRNA did not suppress any of three yeast amber alleles, suggesting that the yeast enzymes retain high specificity in vivo for their homologous tRNAs. Moreover, the nucleotides in the sequence of the E. coli suppressor that are not shared with the yeast cytoplasmic tyrosine tRNA do not create determinants which are efficiently recognized by other yeast charging enzymes. Therefore, at least some of the determinants that influence in vivo recognition of the tyrosine tRNA are specific to the cell compartment and organism. In contrast, expression of the cognate bacterial tyrosyl-tRNA synthetase together with the bacterial suppressor tRNA led to suppression of all three amber alleles. The bacterial enzyme recognized its substrate in vivo, even when the amount of bacterial tRNA was less than about 0.05% of that of the total cytoplasmic tRNA.

The intron of the yeast actin gene contains the promoter for an antisense RNA

Using Northern blot analysis we have detected an approximately 840 nucleotide-long RNA which is complementary to the 5' leader sequence and the first ten nucleotides of the coding sequence of the yeast actin (ACT1) messenger RNA. We have determined two transcription start sites for this actin antisense RNA (ASR1), both within the ACT1 intron, at about 80 and 90 nucleotides downstream from the 5' splice site. Analysis of a cDNA clone showed that this RNA species overlaps the entire trailer sequence and approximately 20 nucleotides of the coding sequence of the nearby yeast YPT1 gene.

Genomic footprinting of a yeast tRNA gene reveals stable complexes over the 5'-flanking region

We have shown by genomic footprinting that the 5'-flanking region of the Saccharomyces cerevisiae tRNASUP53 gene is protected from DNase I digestion. The protected region has a 5' boundary at -40 (relative to the transcription initiation site) and extends into the coding region of the gene, with a 3' boundary at approximately +15. Although the DNase I protection over this region was much greater than at the A- and B-box internal promoters, point mutations within the A or B box that reduced transcription in vitro eliminated the upstream DNase I protection. This implies that formation of a stable complex over the 5'-flanking region is dependent on interaction of the gene with transcription factor IIIC but that stability of the complex may not require continued interaction with this factor. The DNase I protection under varied growth conditions further suggested that the upstream complex is composed of two or more components. The region over the transcription initiation site (approximately +15 to -10) was less protected in stationary-phase cultures, whereas the more upstream region (approximately -10 to -40) was protected in both exponential- and stationary-phase cultures.

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.

Transcription factor IIIB generates extended DNA interactions in RNA polymerase III transcription complexes on tRNA genes

Transcription complexes that assemble on tRNA genes in a crude Saccharomyces cerevisiae cell extract extend over the entire transcription unit and approximately 40 base pairs of contiguous 5'-flanking DNA. We show here that the interaction with 5'-flanking DNA is due to a protein that copurifies with transcription factor TFIIIB through several steps of purification and shares characteristic properties that are normally ascribed to TFIIIB: dependence on prior binding of TFIIIC and great stability once the TFIIIC-TFIIIB-DNA complex is formed. SUP4 gene (tRNATyr) DNA that was cut within the 5'-flanking sequence (either 31 or 28 base pairs upstream of the transcriptional start site) was no longer able to stably incorporate TFIIIB into a transcription complex. The TFIIIB-dependent 5'-flanking DNA protein interaction was predominantly not sequence specific. The extension of the transcription complex into this DNA segment does suggest two possible explanations for highly diverse effects of flanking-sequence substitutions on tRNA gene transcription: either (i) proteins that are capable of binding to these upstream DNA segments are also potentially capable of stimulating or interfering with the incorporation of TFIIIB into transcription complexes or (ii) 5'-flanking sequence influences the rate of assembly of TFIIIB into stable transcription complexes.

Genomic footprinting of a yeast tRNA gene reveals stable complexes over the 5'-flanking region

We have shown by genomic footprinting that the 5'-flanking region of the Saccharomyces cerevisiae tRNASUP53 gene is protected from DNase I digestion. The protected region has a 5' boundary at -40 (relative to the transcription initiation site) and extends into the coding region of the gene, with a 3' boundary at approximately +15. Although the DNase I protection over this region was much greater than at the A- and B-box internal promoters, point mutations within the A or B box that reduced transcription in vitro eliminated the upstream DNase I protection. This implies that formation of a stable complex over the 5'-flanking region is dependent on interaction of the gene with transcription factor IIIC but that stability of the complex may not require continued interaction with this factor. The DNase I protection under varied growth conditions further suggested that the upstream complex is composed of two or more components. The region over the transcription initiation site (approximately +15 to -10) was less protected in stationary-phase cultures, whereas the more upstream region (approximately -10 to -40) was protected in both exponential- and stationary-phase cultures.

Transcription factor IIIB generates extended DNA interactions in RNA polymerase III transcription complexes on tRNA genes

Transcription complexes that assemble on tRNA genes in a crude Saccharomyces cerevisiae cell extract extend over the entire transcription unit and approximately 40 base pairs of contiguous 5'-flanking DNA. We show here that the interaction with 5'-flanking DNA is due to a protein that copurifies with transcription factor TFIIIB through several steps of purification and shares characteristic properties that are normally ascribed to TFIIIB: dependence on prior binding of TFIIIC and great stability once the TFIIIC-TFIIIB-DNA complex is formed. SUP4 gene (tRNATyr) DNA that was cut within the 5'-flanking sequence (either 31 or 28 base pairs upstream of the transcriptional start site) was no longer able to stably incorporate TFIIIB into a transcription complex. The TFIIIB-dependent 5'-flanking DNA protein interaction was predominantly not sequence specific. The extension of the transcription complex into this DNA segment does suggest two possible explanations for highly diverse effects of flanking-sequence substitutions on tRNA gene transcription: either (i) proteins that are capable of binding to these upstream DNA segments are also potentially capable of stimulating or interfering with the incorporation of TFIIIB into transcription complexes or (ii) 5'-flanking sequence influences the rate of assembly of TFIIIB into stable transcription complexes.

tRNA(Tyr) genes of Drosophila melanogaster: expression of single-copy genes studied by S1 mapping

Six Drosophila melanogaster tRNA(Tyr) genes have been isolated and sequenced. They contained introns of different sequences and two size classes: 20 or 21 base pairs (bp) (five genes) and 113 bp (one gene). However, the sequences coding for the mature tRNA(Tyr) were identical in all six genes. The 113-bp intron-containing gene was a single-copy gene. Hence, its primary transcript could be traced by S1 mapping. The gene was turned on during embryogenesis and continually expressed to various degrees during the following developmental stages. Thus, S1 mapping is a feasible method to follow the transcriptional activity of individual genes with identical mature products, provided that their primary transcripts are unique. The six genes were organized in two clusters of three and two genes, respectively (each containing a 20- or a 21-bp intron; cytological localization, 85A), and a single-copy gene (113-bp intron; cytological localization, 28C). We show that four of the six tRNA(Tyr) genes characterized were localized in putative 5' control regions of developmentally controlled genes transcribed by polymerase II.

Pseudouridine modification in the tRNA(Tyr) anticodon is dependent on the presence, but independent of the size and sequence, of the intron in eucaryotic tRNA(Tyr) genes

In Saccharomyces cerevisiae, pseudouridine formation in the middle position of the tRNA(Tyr) anticodon (psi 35) is dependent on the presence of the intron in the tRNA(Tyr) gene (Johnson and Abelson, Nature 302:681-687, 1983). Drosophila melanogaster tRNA(Tyr) genes contain introns of three size classes: 20 or 21 base pairs (bp) (six genes), 48 bp (one gene), and 113 bp (one gene). As in yeast, removal of the intron led to loss of psi 35 in the anticodon when transcription was assayed in Xenopus laevis oocytes. All Drosophila intron sizes supported psi 35 formation. The same results were obtained with the homologous X. laevis tRNA(Tyr) genes containing introns of 12 or 13 bp or with a deleted intron. The introns of yeast (Nishikura and DeRobertis, J. Mol. Biol. 145:405-420, 1981), D. melanogaster, and X. laevis tRNA(Tyr) wild-type genes, while they all supported psi 35 synthesis, did not share any consensus sequences. As discussed, these results, taken together, suggest that for appropriate function the psi 35 enzyme in the X. laevis oocyte needs the presence of an unqualified intron in the tRNA gene and a tRNA(Tyr)-like structure in the unprocessed tRNA precursor.

Introduction of an intervening sequence into a human serine suppressor tRNA gene: effects on gene expression in vitro and in vivo

The 13 nucleotide Xenopus laevis tyrosine tRNA gene intervening sequence was into a human serine suppressor tRNA gene which lacked an intron, by site-directed mutagenesis. Analysis of the products of in vitro transcription in a HeLa cell extract indicates that the intervening sequence is accurately removed to generate a mature sized RNA identical to that obtained from an intron-less gene. Analysis of the transcripts obtained in vitro and in vivo shows that the U in the CUA anticodon sequence is partially modified to psi. Total TRNA isolated from cells infected with recombinant SV40 viruses carrying the mutant tRNA genes is active in suppression of UAG codons in a reticulocyte cell-free system. Cotransfection of COS cells with the mutant tRNA genes and a mutant chloramphenicol acetyltransferase gene containing the termination codon UAG demonstrated that the tRNA functions as a UAG suppressor in vivo. Analysis of 32P-labeled RNA obtained from infected cells showed, however, that cells infected with the intron-containing gene accumulate less mature tRNA than cells infected with the intron-less tRNA genes.

Testing for intron function in the essential Saccharomyces cerevisiae tRNA(SerUCG) gene

The gene sup61+, which codes for the essential Saccharomyces cerevisiae tRNA(SerUCG), is the only single-copy tRNA gene in this organism know to contain an intron. To assess the role of this intron in tRNA gene expression, an intron-deleted sup61+ gene was constructed in vitro and introduced into the yeast genome. Isogenic intron- and intron+ strains were found to be indistinguishable by criteria that include growth rates, ability to undergo meiosis, levels of mature tRNA(SerUCG) transcribed in vivo, and the suppressor efficiency of amber- and ochre-specific alleles of this gene.

tRNA(Tyr) genes of Drosophila melanogaster: expression of single-copy genes studied by S1 mapping

Six Drosophila melanogaster tRNA(Tyr) genes have been isolated and sequenced. They contained introns of different sequences and two size classes: 20 or 21 base pairs (bp) (five genes) and 113 bp (one gene). However, the sequences coding for the mature tRNA(Tyr) were identical in all six genes. The 113-bp intron-containing gene was a single-copy gene. Hence, its primary transcript could be traced by S1 mapping. The gene was turned on during embryogenesis and continually expressed to various degrees during the following developmental stages. Thus, S1 mapping is a feasible method to follow the transcriptional activity of individual genes with identical mature products, provided that their primary transcripts are unique. The six genes were organized in two clusters of three and two genes, respectively (each containing a 20- or a 21-bp intron; cytological localization, 85A), and a single-copy gene (113-bp intron; cytological localization, 28C). We show that four of the six tRNA(Tyr) genes characterized were localized in putative 5' control regions of developmentally controlled genes transcribed by polymerase II.

Pseudouridine modification in the tRNA(Tyr) anticodon is dependent on the presence, but independent of the size and sequence, of the intron in eucaryotic tRNA(Tyr) genes

In Saccharomyces cerevisiae, pseudouridine formation in the middle position of the tRNA(Tyr) anticodon (psi 35) is dependent on the presence of the intron in the tRNA(Tyr) gene (Johnson and Abelson, Nature 302:681-687, 1983). Drosophila melanogaster tRNA(Tyr) genes contain introns of three size classes: 20 or 21 base pairs (bp) (six genes), 48 bp (one gene), and 113 bp (one gene). As in yeast, removal of the intron led to loss of psi 35 in the anticodon when transcription was assayed in Xenopus laevis oocytes. All Drosophila intron sizes supported psi 35 formation. The same results were obtained with the homologous X. laevis tRNA(Tyr) genes containing introns of 12 or 13 bp or with a deleted intron. The introns of yeast (Nishikura and DeRobertis, J. Mol. Biol. 145:405-420, 1981), D. melanogaster, and X. laevis tRNA(Tyr) wild-type genes, while they all supported psi 35 synthesis, did not share any consensus sequences. As discussed, these results, taken together, suggest that for appropriate function the psi 35 enzyme in the X. laevis oocyte needs the presence of an unqualified intron in the tRNA gene and a tRNA(Tyr)-like structure in the unprocessed tRNA precursor.

All human tRNATyr genes contain introns as a prerequisite for pseudouridine biosynthesis in the anticodon

Two synthetic oligonucleotides, one specific for the 5' exon, the other spanning the splice junction, were used to show that (a) the human haploid genome contains at least 12 independent gene loci for tRNATyr, and (b) that all of them carry an intron. From one of the cloned human tRNATyr genes (pHtT1) the 20 bp intron was deleted to generate pHtT1 delta. Homologous in vitro transcription, fingerprint analyses of the products and elucidation of their nucleoside composition revealed that the pseudouridine (psi 35) in the center of the anticodon of tRNATyr was synthesized in the intron-containing precursor whereas this U to psi modification did not take place in precursors or mature tRNATyr derived from pHtT1 delta. On the basis of these results and of studies from other laboratories we suggest that the evolutionary pressure for maintaining introns in eukaryotic tRNAsTyr is this strict intron-requirement for psi 35 synthesis. Taking into account that all eukaryotic cytoplasmic tRNAsTyr contain a psi 35 we discuss here a special need for this modified nucleoside in stabilizing codon-anticodon interactions involving (a) classical base pairing upon translation of tyrosine codons and (b) unconventional interactions during UAG amber codon suppression by tRNATyrG psi A in eukaryotic cells.

Effects of tRNA-intron structure on cleavage of precursor tRNAs by RNase P from Saccharomyces cerevisiae

RNase P derived from S. cerevisiae nuclei was tested for its ability to cleave a variety of naturally occurring and selectively altered precursor-tRNA molecules to yield matured 5' termini. Precursors were synthesized in vitro in order to test which aspects of substrate structure are crucial to recognition and cleavage by RNase P. Base modifications in the precursor substrates are not required for cleavage by the enzyme, but deletion and substitution mutations affecting any portion of the precursor tertiary structure reduce cleavage. In particular, a number of alterations in the intervening sequence (IVS) reduce the susceptibility of the substrate to cleavage by RNase P. The significance of these results is discussed in reference to the contribution of the IVS to the structure of the precursor-tRNA.

Expression of a set of synthetic suppressor tRNA(Phe) genes in Saccharomyces cerevisiae

Synthetic ochre and amber tRNA suppressor genes derived from the yeast tRNA(PheGAA) sequence have been constructed. They were efficiently transcribed in vitro and expressed in vivo via a synthetic expression cassette. tRNA(PheUUA) and tRNA(PheUUA) delta IVS (IVS = intervening sequence) are relatively inefficient ochre suppressors. They are toxic to the cell when expressed on a multicopy plasmid, and they do not suppress at all when present as single copies. The intron does not seem to have any effect on suppression. In contrast, the amber suppressor tRNA(PheCUA) delta IVS is efficient when expressed from a single-copy plasmid, while its efficiency is reduced on a multicopy vector.

Development of a yeast system to assay mutational specificity

We have developed a system wherein DNA alterations occurring in a target gene in the yeast Saccharomyces cerevisiae can be determined by DNA sequencing. The target gene, SUP4-o, an ochre suppressor allele of a yeast tyrosine tRNA gene, has been inserted into a shuttle vector (YCpMP2) which is maintained in yeast at a copy number of one per cell Mutations in SUP4-o are selected by virtue of their inactivation of suppressor activity. Rapid DNA preparations from these mutants are used to transform an appropriate bacterial strain. Since YCpMP2 also carries the M13 phage replication origin, superinfection of bacterial cells containing the plasmid with wild-type M13 phage yields single stranded YCpMP2 DNA suitable for dideoxynucleotide chain termination sequencing. We have used this system to examine mutations arising spontaneously in the SUP4-o gene. The spontaneous mutants occurred at a frequency of 3.2 X 10(-6)/viable cell, corresponding to a rate of 2.7 X 10(-7) events/cell division. Following bacterial transformation, 16% of the recovered plasmids tested displayed altered gel mobility consistent with loss of significant portions of the plasmid. Hybridization analysis of total yeast DNA and use of purified YCpMP2 revealed that these very large deletions were not generated in yeast but were associated with bacterial transformation. Among the SUP4-o mutants analyzed by DNA sequencing, we identified each type of single base pair substitution (transitions and transversions), small deletions of varying length (1-32 base pairs) and more extensive deletions of undetermined size. These results demonstrate that the SUP4-o system can be used to detect various types of mutation at numerous sites in a single eukaryotic gene and to characterize the DNA sequence changes responsible for the mutations selected.

Mutational analysis of the coordinate expression of the yeast tRNAArg-tRNAAsp gene tandem

tRNA genes occur in the yeast genome as highly dispersed and independent transcriptional units. The 5'-tRNAArg-tRNAAsp-3' gene tandem, separated by a 10-base-pair spacer sequence, thus represents a rare case of tight clustering. Previous in vitro studies did not reveal any primary transcript from the tRNAAsp gene, but rather a dimeric precursor containing both gene sequences plus spacer, which undergoes a series of maturation steps. This seems anomalous since the tRNAAsp gene contains the sequences necessary for its own transcription. We found that site-directed mutation of the highly conserved C at position 56 to a G in the tRNAArg gene suppresses all transcription and does not activate the tRNAAsp gene. Precise deletion of the entire tRNAArg gene gives a similar result. Rescue of tRNAAsp gene transcription is effected either by the precise deletion of both the tRNAArg gene and spacer or by the precise deletion of this gene with concomitant introduction of an artificial RNA polymerase III start site in the spacer. This artificial start site is ineffective if the tRNAArg gene is present upstream.

Effect of intron mutations on processing and function of Saccharomyces cerevisiae SUP53 tRNA in vitro and in vivo

The Saccharomyces cerevisiae leucine-inserting amber suppressor tRNA gene SUP53 (a tRNALeu3 allele) was used to investigate the relationship between precursor tRNA structure and mature tRNA function. This gene encodes a pre-tRNA which contains a 32-base intron. The mature tRNASUP53 contains a 5-methylcytosine modification of the anticodon wobble base. Mutations were made in the SUP53 intron. These mutant genes were transcribed in an S. cerevisiae nuclear extract preparation. In this extract, primary tRNA gene transcripts are end-processed and base modified after addition of cofactors. The base modifications made in vitro were examined, and the mutant pre-tRNAs were analyzed for their ability to serve as substrates for partially purified S. cerevisiae tRNA endonuclease and ligase. Finally, the suppressor function of these mutant tRNA genes was assayed after their integration into the S. cerevisiae genome. Mutant analysis showed that the totally intact precursor tRNA, rather than any specific sequence or structure of the intron, was necessary for efficient nonsense suppression by tRNASUP53. Less efficient suppressor activity correlated with the absence of the 5-methylcytosine modification. Most of the intron-altered precursor tRNAs were successfully spliced in vitro, indicating that modifications are not critical for recognition by the tRNA endonuclease and ligase.

Splicing of a yeast proline tRNA containing a novel suppressor mutation in the anticodon stem

The intron-containing proline tRNAUGG genes in Saccharomyces cerevisiae can mutate to suppress +1 frameshift mutations in proline codons via a G to U base substitution mutation at position 39. The mutation alters the 3' splice junction and disrupts the bottom base-pair of the anticodon stem which presumably allows the tRNA to read a four-base codon. In order to understand the mechanism of suppression and to study the splicing of suppressor pre-tRNA, we determined the sequences of the mature wild-type and mutant suppressor gene products in vivo and analyzed splicing of the corresponding pre-tRNAs in vitro. We show that a novel tRNA isolated from suppressor strains is the product of frameshift suppressor genes. Sequence analysis indicated that suppressor pre-tRNA is spliced at the same sites as wild-type pre-tRNA. The tRNA therefore contains a four-base anticodon stem and nine-base anticodon loop. Analysis of suppressor pre-tRNA in vitro revealed that endonuclease cleavage at the 3' splice junction occurred with reduced efficiency compared to wild-type. In addition, reduced accumulation of mature suppressor tRNA was observed in a combined cleavage and ligation reaction. These results suggest that cleavage at the 3' splice junction is inefficient but not abolished. The novel tRNA from suppressor strains was shown to be the functional agent of suppression by deleting the intron from a suppressor gene. The tRNA produced in vivo from this gene is identical to that of the product of an intron+ gene, indicating that the intron is not required for proper base modification. The product of the intron- gene is a more efficient suppressor than the product of an intron+ gene. One interpretation of this result is that inefficient splicing in vivo may be limiting the steady-state level of mature suppressor tRNA.

Mutational analysis of the coordinate expression of the yeast tRNAArg-tRNAAsp gene tandem

tRNA genes occur in the yeast genome as highly dispersed and independent transcriptional units. The 5'-tRNAArg-tRNAAsp-3' gene tandem, separated by a 10-base-pair spacer sequence, thus represents a rare case of tight clustering. Previous in vitro studies did not reveal any primary transcript from the tRNAAsp gene, but rather a dimeric precursor containing both gene sequences plus spacer, which undergoes a series of maturation steps. This seems anomalous since the tRNAAsp gene contains the sequences necessary for its own transcription. We found that site-directed mutation of the highly conserved C at position 56 to a G in the tRNAArg gene suppresses all transcription and does not activate the tRNAAsp gene. Precise deletion of the entire tRNAArg gene gives a similar result. Rescue of tRNAAsp gene transcription is effected either by the precise deletion of both the tRNAArg gene and spacer or by the precise deletion of this gene with concomitant introduction of an artificial RNA polymerase III start site in the spacer. This artificial start site is ineffective if the tRNAArg gene is present upstream.

Effect of intron mutations on processing and function of Saccharomyces cerevisiae SUP53 tRNA in vitro and in vivo

The Saccharomyces cerevisiae leucine-inserting amber suppressor tRNA gene SUP53 (a tRNALeu3 allele) was used to investigate the relationship between precursor tRNA structure and mature tRNA function. This gene encodes a pre-tRNA which contains a 32-base intron. The mature tRNASUP53 contains a 5-methylcytosine modification of the anticodon wobble base. Mutations were made in the SUP53 intron. These mutant genes were transcribed in an S. cerevisiae nuclear extract preparation. In this extract, primary tRNA gene transcripts are end-processed and base modified after addition of cofactors. The base modifications made in vitro were examined, and the mutant pre-tRNAs were analyzed for their ability to serve as substrates for partially purified S. cerevisiae tRNA endonuclease and ligase. Finally, the suppressor function of these mutant tRNA genes was assayed after their integration into the S. cerevisiae genome. Mutant analysis showed that the totally intact precursor tRNA, rather than any specific sequence or structure of the intron, was necessary for efficient nonsense suppression by tRNASUP53. Less efficient suppressor activity correlated with the absence of the 5-methylcytosine modification. Most of the intron-altered precursor tRNAs were successfully spliced in vitro, indicating that modifications are not critical for recognition by the tRNA endonuclease and ligase.

Two human tyrosine tRNA genes contain introns

A human lambda-phage recombinant which contains at least four tRNA genes, has been isolated. Two DNA fragments were subcloned to give the recombinant plasmids pM6 and pM6128. Nucleotide sequence analysis showed that each plasmid contained a different tyrosine acceptor tRNA (tRNATyr) gene. Both tRNATyr genes are interrupted by 21-bp introns. These recombinant plasmids have been shown to direct the in vitro synthesis of tRNA-sized products in a HeLa cell transcription system.

Conserved sequences in both coding and 5' flanking regions of mammalian opal suppressor tRNA genes

The rabbit genome encodes an opal suppressor tRNA gene. The coding region is strictly conserved between the rabbit gene and the corresponding gene in the human genome. The rabbit opal suppressor gene contains the consensus sequence in the 3' internal control region but like the human and chicken genes, the rabbit 5' internal control region contains two additional nucleotides. The 5' flanking sequences of the rabbit and the human opal suppressor genes contain extensive regions of homology. A subset of these homologies is also present 5' to the chicken opal suppressor gene. Both the rabbit and the human genomes also encode a pseudogene. That of the rabbit lacks the 3' half of the coding region. Neither pseudogene has homologous regions to the 5' flanking regions of the genes. The presence of 5' homologies flanking only the transcribed genes and not the pseudogenes suggests that these regions may be regulatory control elements specifically involved in the expression of the eukaryotic opal suppressor gene. Moreover the strict conservation of coding sequences indicates functional importance for the opal suppressor tRNA genes.

5-Methyl-2-thiouridine in the tRNA of Candida tropicalis and its localization in lysine tRNA

35S incorporation studies showed that Candida tropicalis tRNA contained two thionucleosides, one of which was identified as 5-methyl-2-thiouridine. The other thionucleoside was alkali labile, and it appeared to be an ester. Pulse-chase experiments suggested that the two thionucleosides were structurally related. 5-Methyl-2-thiouridine was present in one of the lysine tRNAs. This is the first report of the presence of this nucleoside in a yeast tRNA.

Concerted evolution of tRNA genes: intergenic conversion among three unlinked serine tRNA genes in S. pombe

In many cases the multiple genes coding for one specific tRNA are dispersed throughout the genome. The members of such a gene family nevertheless maintain a common nucleotide sequence during evolution. A major mechanism contributing to this concerted evolution is intergenic conversion. Here we show that it occurs between three tRNA genes of related sequence residing on different chromosomes of Schizosaccharomyces pombe. Sequence analysis of converted genes indicates that blocks of a minimal length of 18-33 bp and of a maximal length of 190 bp can be transferred from one gene to the other. During meiosis the frequency of these transfers lies in the order of 10(-5) per progeny spore. Information transfer between any two members of the gene family occurs in both directions.

A test for intron function in the yeast actin gene

Many eukaryotic genes contain intervening sequences (IVS), but the rationale for their existence remains a mystery. Previous studies done in our laboratory demonstrated that the intron in a yeast tRNATyr gene, SUP6, does have a function. We used the same approach to determine the role of introns in nuclear genes encoding messenger RNAs. A single actin gene with one intron exists in Saccharomyces cerevisiae. The level of actin in yeast appears to be crucial to viability: either too much or too little actin inhibits growth. Therefore, small effects on synthesis of actin protein resulting from the removal of the actin gene intron would be expected to cause measurable changes in cell growth. In the present study, an intron-deleted actin gene was constructed in vitro and was used to replace the single resident actin gene in a haploid strain. Analysis of the cells carrying the intron-deleted actin gene shows that the intervening sequence is not essential for actin gene expression.

The nucleotide sequence of tyrosine tRNAQ* psi A from bovine liver

The nucleotide sequence of tyrosine tRNAQ* psi A from bovine liver was determined to be pC-C-U-U-C-m2G-A-U-A-m2G-C-U-C-A-G-D-D-G-G-acp3U-A-G-A -G-C-m22G-m22G -A-G-G-A-C-U-Q*-psi-A-m1G-A-psi m-C-C-U-U-A-G-m7G-D-m5C-G-C-U-G-G-T-psi-C-G-m1A -U-U-C-C-G-G-C-U-C-G-A-A-G-G-A-C-C-AOH. This tyrosine tRNA is 76 nucleotides in length, and contains two hypermodified nucleosides--3 -3(3-amino-3-carboxylpropyl)uridine (acp3U) and beta-D-galactosylqueuosine (Q*). The molecule also has a pseudouridine in the middle position of the anticodon, and is the first tRNA sequenced which has an adjacent pair of N2,N2-dimethylguanosine (m22G) residues.

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.