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

Plasmodium falciparum Maf1 Confers Survival upon Amino Acid Starvation

The target of rapamycin complex 1 (TORC1) pathway is a highly conserved signaling pathway across eukaryotes that integrates nutrient and stress signals to regulate the cellular growth rate and the transition into and maintenance of dormancy. The majority of the pathway's components, including the central TOR kinase, have been lost in the apicomplexan lineage, and it is unknown how these organisms detect and respond to nutrient starvation in its absence. Plasmodium falciparum encodes a putative ortholog of the RNA polymerase (Pol) III repressor Maf1, which has been demonstrated to modulate Pol III transcription in a TOR-dependent manner in a number of organisms. Here, we investigate the role of P. falciparum Maf1 (PfMaf1) in regulating RNA Pol III expression under conditions of nutrient starvation and other stresses. Using a transposon insertion mutant with an altered Maf1 expression profile, we demonstrated that proper Maf1 expression is necessary for survival of the dormancy-like state induced by prolonged amino acid starvation and is needed for full recovery from other stresses that slow or stall the parasite cell cycle. This Maf1 mutant is defective in the downregulation of pre-tRNA synthesis under nutrient-limiting conditions, indicating that the function of Maf1 as a stress-responsive regulator of structural RNA transcription is conserved in P. falciparum Recent work has demonstrated that parasites carrying artemisinin-resistant K13 alleles display an enhanced ability to recover from drug-induced growth retardation. We show that one such artemisinin-resistant line displays greater regulation of pre-tRNA expression and higher survival upon prolonged amino acid starvation, suggesting that overlapping, PfMaf1-associated pathways may regulate growth recovery from both artemisinin treatment and amino acid starvation.IMPORTANCE Eukaryote organisms sense changes in their environment and integrate this information through signaling pathways to activate response programs to ensure survival. The TOR pathway is a well-studied signaling pathway found throughout eukaryotes that is known to integrate a variety of signals to regulate organismal growth in response to starvation and other stresses. The human malaria parasite Plasmodium falciparum appears to have lost the TOR pathway over the course of evolution, and it is unclear how the parasite modulates its growth in response to starvation and drug treatment. Here, we show that Maf1, a protein regulated by TOR in other eukaryotes, plays an important role in maintaining the parasite's viability in the face of starvation and other forms of stress. This suggests that PfMaf1 is a component of a yet-to-be-described nutrient and stress response pathway.

The essential function of the Trypanosoma brucei Trl1 homolog in procyclic cells is maturation of the intron-containing tRNATyr

Trypanosoma brucei, the etiologic agent of sleeping sickness, encodes a single intron-containing tRNA, tRNA(Tyr), and splicing is essential for its viability. In Archaea and Eukarya, tRNA splicing requires a series of enzymatic steps that begin with intron cleavage by a tRNA-splicing endonuclease and culminates with joining the resulting tRNA exons by a splicing tRNA ligase. Here we explored the function of TbTrl1, the T. brucei homolog of the yeast Trl1 tRNA ligase. We used a combination of RNA interference and molecular biology approaches to show that down-regulation of TbTrl1 expression leads to accumulation of intron-containing tRNA(Tyr) and a concomitant growth arrest at the G1 phase. These defects were efficiently rescued by expression of an "intronless" version of tRNA(Tyr) in the same RNAi cell line. Taken together, these experiments highlight the crucial importance of the TbTrl1 for tRNA(Tyr) maturation and viability, while revealing tRNA splicing as its only essential function.

Diversity and roles of (t)RNA ligases

The discovery of discontiguous tRNA genes triggered studies dissecting the process of tRNA splicing. As a result, we have gained detailed mechanistic knowledge on enzymatic removal of tRNA introns catalyzed by endonuclease and ligase proteins. In addition to the elucidation of tRNA processing, these studies facilitated the discovery of additional functions of RNA ligases such as RNA repair and non-conventional mRNA splicing events. Recently, the identification of a new type of RNA ligases in bacteria, archaea, and humans closed a long-standing gap in the field of tRNA processing. This review summarizes past and recent findings in the field of tRNA splicing with a focus on RNA ligation as it preferentially occurs in archaea and humans. In addition to providing an integrated view of the types and phyletic distribution of RNA ligase proteins known to date, this survey also aims at highlighting known and potential accessory biological functions of RNA ligases.

Comparative analysis of nuclear tRNA genes of Nasonia vitripennis and other arthropods, and relationships to codon usage bias

Using bioinformatics methods, we identified a total of 221 and 199 tRNA genes in the nuclear genomes of Nasonia vitripennis and honey bee (Apis mellifera), respectively. We performed comparative analyses of Nasonia tRNA genes with honey bee and other selected insects to understand genomic distribution, sequence evolution and relationship of tRNA copy number with codon usage patterns. Many tRNA genes are located physically close to each other in the form of small clusters in the Nasonia genome. However, the number of clusters and the tRNA genes that form such clusters vary from species to species. In particular, the Ala-, Pro-, Tyr- and His-tRNA genes tend to accumulate in clusters in Nasonia but not in honey bee, whereas the bee contains a long cluster of 15 tRNA genes (of which 13 are Gln-tRNAs) that is absent in Nasonia. Though tRNA genes are highly conserved, contrasting patterns of nucleotide diversity are observed among the arm and loop regions of tRNAs between Nasonia and honey bee. Also, the sequence convergence between the reconstructed ancestral tRNAs and the present day tRNAs suggests a common ancestral origin of Nasonia and honey bee tRNAs. Furthermore, we also present evidence that the copy number of isoacceptor tRNAs (those having a different anticodon but charge the same amino acid) is correlated with codon usage patterns of highly expressed genes in Nasonia.

The Saccharomyces cerevisiae U2 snRNA:pseudouridine-synthase Pus7p is a novel multisite-multisubstrate RNA:Psi-synthase also acting on tRNAs

The Saccharomyces cerevisiae Pus7 protein was recently characterized as a novel RNA:pseudouridine (Psi)-synthase acting at position 35 in U2 snRNA. However, U2 snRNA was the only potential substrate tested for this enzyme. In this work, we demonstrated that although Pus7p is responsible for the formation of only one of the six Psi residues present in yeast UsnRNAs, it catalyzes U to Psi conversion at position 13 in cytoplasmic tRNAs and at position 35 in pre-tRNA(Tyr). Sites of RNA modification by Pus7p were identified by analysis of the in vivo RNA modification defects resulting from the absence of active Pus7p production and by in vitro tests using extracts from WT and genetically modified yeast cells. For demonstration of the direct implication of Pus7p in RNA modification, the activity of the WT and mutated Pus7p recombinant proteins was tested on in vitro produced tRNA and pre-tRNA transcripts. Mutation of an aspartic acid residue (D256) that is conserved in all Pus7 homologs abolishes the enzymatic activity both in vivo and in vitro. This suggests the direct involvement of D256 in catalysis. Target sites of Pus7p in RNAs share a common sequence Pu(G/C)UNPsiAPu (Pu = purine, N = any nucleotide), which is expected to be important for substrate recognition. Modification of tRNAs by Pus7p explains the presence of Pus7p homologs in archaea and some bacteria species, which do not have U2 snRNA, and in vertebrates, where Psi34 (equivalent to Psi35 in yeast) formation in U2 snRNA is an H/ACA snoRNA guided process. Our results increase the number of known RNA modification enzymes acting on different types of cellular RNAs.

Distribution of rRNA introns in the three-dimensional structure of the ribosome

More than 1200 introns have been documented at over 150 unique sites in the small and large subunit ribosomal RNA genes (as of February 2002). Nearly all of these introns are assigned to one of four main types: group I, group II, archaeal and spliceosomal. This sequence information has been organized into a relational database that is accessible through the Comparative RNA Web Site (http://www.rna.icmb.utexas.edu/) While the rRNA introns are distributed across the entire tree of life, the majority of introns occur within a few phylogenetic groups. We analyzed the distributions of rRNA introns within the three-dimensional structures of the 30S and 50S ribosomes. Most sites in rRNA genes that contain introns contain only one type of intron. While the intron insertion sites occur at many different coordinates, the majority are clustered near conserved residues that form tRNA binding sites and the subunit interface. Contrary to our expectations, many of these positions are not accessible to solvent in the mature ribosome. The correlation between the frequency of intron insertions and proximity of the insertion site to functionally important residues suggests an association between intron evolution and rRNA function.

A tobacco nuclear extract supporting transcription, processing, splicing and modification of plant intron-containing tRNA precursors

Nuclear tRNA genes are transcribed by RNA polymerase III (Pol III) and pre-tRNAs are processed into mature tRNAs via complex processes in the nucleus. We have developed an in vitro Pol III-dependent transcription system derived from tobacco cultured cells, which supports efficiently not only transcription of a variety of plant tRNA genes but also 5'-and 3'-end processing, nucleotide modification and splicing of intron-containing pre-tRNAs. The structures of in vitro transcripts have been confirmed by primer extension analysis and by RNase T1 fingerprinting. The optimal Mg2+ concentration differed for each step so that each reaction can be controlled by adjusting the Mg2+ concentration. At 1 mm Mg2+, only transcription occurs so that pre-tRNAs accumulate. The splicing reaction can be initiated by raising Mg2+ ions (> 5 mm) and enhanced by adding 1 mm hexamminecobalt chloride. Using the optimized system for the Nicotiana intron-containing tRNATyr gene, the precise initiation and termination sites of transcription and the splice sites were determined. The presence of 1 mm NAD+ in the reaction mixture leads to the removal of the 2' phosphate at the splice junction of tRNATyr, demonstrating the activity of a 2'-phosphotransferase in the tobacco nuclear extract. Many modified nucleosides such as m2G, m22G, m1A, phi27 and phi35 are introduced in either of the studied transcripts. As shown in other systems, the conversion of U35 to phi requires an intron-containing substrate.

Complete 5' and 3' end maturation of group II intron-containing tRNA precursors

Higher plant chloroplasts provide the only experimentally validated example of functional tRNA genes that are disrupted by group II introns. Here, precursor transcripts for tRNA(Gly)(UCC), tRNA(Val)(UAC), and tRNA(Ala)(UGC) were investigated for processing of 5' leader and 3' trailer sequences in vivo. Use of intron-specific primer pairs and inclusion of a barley chloroplast splicing mutant specifically allowed us to evaluate the potential effect of intervening sequences that disrupt tRNA secondary and tertiary structures. The data suggest that (1) neither integrity of the dihydrouridine nor the anticodon domain is required for the nucleotidyltransferase-mediated addition of 3'-terminal CCA; (2) interruption of these two structural elements by group II introns does not interfere with nucleotide-specific 5' maturation by RNase P; (3) processing intermediates of chloroplast tRNAs can be 3' polyadenylated; and (4) plastid DNA-encoded proteins are not required for 3' and 5' maturation of plastid tRNAs.

Identification of two catalytic subunits of tRNA splicing endonuclease from Arabidopsis thaliana

tRNA splicing endonuclease is essential for the correct removal of introns from precursor tRNA molecules of Archaea and Eucarya. The only well-characterized eucaryotic enzyme until now is the endonuclease from yeast (Saccharomyces cerevisiae). This protein has a heterotetrameric structure. Two of the four subunits, i.e. Sen34 and Sen44, contain the active sites for cleavage at the 3'- and 5'-splice sites, respectively. We have identified three novel genes from Arabidopsis thaliana, encoding putative subunits of tRNA splicing endonuclease. They are designated as AtSen1, AtSen2, and AtpsSen1. Both genes AtSen1 and AtSen2 seem to be functionally active, as deduced from corresponding cDNA sequences. Comparison of the amino acid sequences of the these two Arabidopsis proteins revealed 72% identity. However, AtpsSen1 is more similar to AtSen1, but is very likely a pseudogene, as concluded from extended stretches of deletions and the presence of in-frame stop codons. All putative proteins contain a conserved domain at their C-terminus common to counterparts from other organisms. Interestingly, they are more similar to the yeast catalytic subunit Sen44 than to Sen34. Southern analysis with various probes revealed that each gene is present as single copies in the nuclear genome. The evolutionary implications of these findings are discussed.

Splicing of arabidopsis tRNA(Met) precursors in tobacco cell and wheat germ extracts

Intron-containing tRNA genes are exceptional within nuclear plant genomes. It appears that merely two tRNA gene families coding for tRNA(GpsiA(Tyr)) and elongator tRNA(CmAU(Met)) contain intervening sequences. We have previously investigated the features required by wheat germ splicing endonuclease for efficient and accurate intron excision from Arabidopsis pre-tRNA(Tyr). Here we have studied the expression of an Arabidopsis elongator tRNA(Met) gene in two plant extracts of different origin. This gene was first transcribed either in HeLa or in tobacco cell nuclear extract and splicing of intron-containing tRNA(Met) precursors was then examined in wheat germ S23 extract and in the tobacco system. The results show that conversion of pre-tRNA(Met) to mature tRNA proceeds very efficiently in both plant extracts. In order to elucidate the potential role of specific nucleotides at the 3' and 5' splice sites and of a structured intron for pre-tRNA(Met) splicing in either extract, we have performed a systematic survey by mutational analyses. The results show that cytidine residues at intron-exon boundaries impair pre-tRNA(Met) splicing and that a highly structured intron is indispensable for pre-tRNA(Met) splicing. tRNA precursors with an extended anticodon stem of three to four base pairs are readily accepted as substrates by wheat and tobacco splicing endonuclease, whereas pre-tRNA molecules that can form an extended anticodon stem of only two putative base pairs are not spliced at all. An amber suppressor, generated from the intron-containing elongator tRNA(Met) gene, is efficiently processed and spliced in both plant extracts.

Characterization of nuclear tRNA(Tyr) introns: their evolution from red algae to higher plants

We have previously isolated numerous intron-containing nuclear tRNA(Tyr) genes derived from either monocotyledonous (Triticum) or dicotyledonous (Arabidopsis, Nicotiana) plants by screening the corresponding genomic phage libraries with a synthetic tRNA(Tyr)-specific oligonucleotide. Here we have characterized additional tRNA(Tyr) genes from phylogenetically divergent plant species representing red algae (Champia), brown algae (Cystophyllum), green algae (Ulva), stonewort (Chara), liverwort (Marchantia), moss (Polytrichum), fern (Rumohra) and gymnosperms (Ginkgo) using amplification of the coding sequences from the corresponding genomic DNAs by polymerase chain reaction (PCR). All novel tRNA(Tyr) genes contain intervening sequences of variable sequence and length ranging in size from 11 to 21 bp. However, two features are conserved in all plant pre-tRNA(Tyr) introns: they possess a uridine and less frequently an adenosine at the 5' boundary and can adopt similar intron secondary structures in which an extended anticodon helix of 4-5 bp is formed by base-pairing between nucleotides of the intron and the anticodon loop. In order to elucidate the potential role of the highly conserved uridine at the first intron position, we have replaced it by all other nucleosides in an Arabidopsis pre-tRNA(Tyr) and have studied in wheat germ extract its effect on splicing and on conversion of U to psi in the GpsiA anticodon. Furthermore, we discuss the putative acquisition of tRNA(Tyr) introns at an early step of evolution after the separation of Archaea and Eucarya.

The tRNATyr-isoacceptors and their genes in the ciliate Tetrahymena thermophila: cytoplasmic tRNATyr has a QPsiA anticodon and is coded by multiple intron-containing genes

In the ciliated protozoa Tetrahymena thermophila introns have been detected in rRNA and mRNAs until now. We have isolated and sequenced seven tRNATyr genes from the T.thermophila nuclear genome. All of these genes contain introns of identical length and sequence. The 11 bp long intervening sequences are located 1 nt 3' to the anticodon as found in other eukaryotic nuclear tRNA genes. Tetrahymena tRNATyr genes are efficiently transcribed in HeLa cell nuclear extract. Moreover, processing and splicing occurred in HeLa as well as in wheat germ extracts, supporting the notion that Tetrahymena tRNATyr introns can be classified as authentic tRNA introns. We have also isolated cytoplasmic tRNATyr from Tetrahymena cells. This tRNATyr isoacceptor has a QPsiA anticodon and is not a UAG suppressor as shown in in vitro translation studies. Since UAG and UAA codons are used as glutamine codons in Tetrahymena macronuclear DNA, the presence of a strong natural UAG suppressor such as tRNATyr with GPsiA anticodon should cause misreading of the glutamine as tyrosine codons and the absence of the latter had thus been predicted. Furthermore we have studied the organization of tRNATyr genes in the genome of T.thermophila and have found two types of tRNATyr gene arrangement. A minimum of 12 tRNATyr genes are present as single copies in genomic DNA HindIII restriction fragments ranging in size from 0.6 to 7 kb. Additionally one cluster of tRNATyr genes consisting of six members has been detected in a 2.3 kb HindIII fragment.

Intron-dependent enzymatic formation of modified nucleosides in eukaryotic tRNAs: a review

In eukaryotic cells, especially in yeast, several genes encoding tRNAs contain introns. These are removed from pre-tRNAs during the maturation process by a tRNA-specific splicing machinery that is located within the nucleus at the nuclear envelope. Before and after the intron removal, several nucleoside modifications are added in a stepwise manner, but most of them are introduced prior to intron removal. Some of these early nucleoside modifications are catalyzed by intron-dependent enzymes while most of the others are catalyzed in an intron-independent manner. In the present paper, we review all known cases where the nucleoside modifications were shown to depend strictly on the presence of an intron. These are pseudouridines at anticodon positions 34, 35 and 36 and 5-methylcytosine at position 34 of several eukaryotic tRNAs. One common property of the corresponding intron-dependent modifying enzymes is that their activities are essentially dependent on the local specific architecture of the pre-tRNA molecule that comprises the anticodon stem and loop prolonged by the intron domain. Thus introns clearly serve as internal (cis-type) RNAs that guide nucleoside modifications by providing transient target sites in tRNA for selected nuclear modifying enzymes. This situation may be similar to the recently discovered (trans-type) snoRNA-guided process of ribose methylations of ribosomal RNAs within the nucleolus of eukaryotic cells.

The tRNATyr multigene family of Triticum aestivum: genome organization, sequence analyses and maturation of intron-containing pre-tRNAs in wheat germ extract

Southern analysis of Triticum DNA has revealed that nuclear tRNATyr genes are dispersed at a minimum of 16 loci in the genome. We have isolated six independent tRNATyr genes from a Triticum aestivum library in addition to three known members of the Triticum tRNATyr family. Four of the sequenced tRNATyr genes code for Triticum tRNA Tyr and two code for tRNA2Tyr. Three genes encode tRNAsTyr which carry one or two nucleotide substitutions as compared to the conventional genes. The nine Triticum tRNATyr genes possess highly conserved intron sequences ranging in size from 12 to 14 nucleotides. A common secondary intron structure with the 5' and 3' splice site loops separated by five base pairs can be formed by all pre-tRNAs Tyr which are efficiently spliced in the homologous wheat germ extract.

Mutations of Arabidopsis thaliana pre-tRNA(Tyr) affecting pseudouridylation of U35

The structural and sequence requirements for the biosynthesis of tRNA(Tyr) pseudouridine (psi 35) have been studied. Nucleotide substitution at the 32nd position slightly reduced modification efficiency in the case of transition (C32 to U32) while transversion (C32 to G32) had no effect on the modification process in wheat germ extract. Insertion of one nucleotide into the anticodon stem caused a 2-fold reduction of modification efficiency. Mutants with a partially deleted 12 nt long intron of pre-tRNA(Tyr) exhibited different effects: deletion of 5 nt (7 nt long intron) gave only a reduction in pseudouridylation while deletion of 7 nt (5 nt long intron) almost completely abolished the reaction. The generated mini-substrate consisting of pre-tRNA(Tyr) anticodon stem and intron sequence was partially modified which proved that the crucial elements for recognition of psi 35 introduction had to present in this construct.

tRNA-m1G methyltransferase interactions: touching bases with structure

m1G methyltransferase of Escherichia coli is being examined with regard to how specific tRNA substrates are recognized. This enzyme appears to require the entire tRNA structure of optimal activity. Recognition may require specific base contacts as well as phosphate backbone structures embodied in the tRNA structure.

Pseudouridine and O2'-methylated nucleosides. Significance of their selective occurrence in rRNA domains that function in ribosome-catalyzed synthesis of the peptide bonds in proteins

Pseudouridine (5-ribosyluracil, psi) was the first of a host of modified nucleoside constituents detected in cellular RNA and it remains the most abundant, being broadly distributed in the RNA of archaebacteria, eubacteria and eukaryotes. Like some other modifications, psi is particularly abundant in more complex organisms, reaching 2-3% of the total nucleoside constituents in tRNA, snRNA and rRNA of multicellular plants and animals. Like all other modified nucleosides, psi arises by site-specific, enzymically catalyzed modification of a nucleoside residue in an RNA molecule. Unlike all other modified nucleosides, psi arises by isomerisation (not substitution) of a classical nucleoside, uridine (1-ribosyluracil). There have been suggestions that key processes such as ribosome assembly and peptidyl transfer may rely, more than is generally appreciated, on RNA modifications such as O2'-methylation and pseudouridylation, respectively. However, a persuasive case for the view that secondary modifications are of primary importance in ribosome function has not been convincingly made. Accordingly, we think it is timely to broaden what is generally meant by the 'catalytic properties of rRNA', and to ask, to what extent do modifications contribute to in vivo rates of ribosome assembly and ribosomal peptide-bond synthesis? The first part of this article sets forth the evidence that there is a conspicuous association between modified nucleosides and cellular RNAs that participate in group-transfer reactions. The second part reviews evidence in support of the view that the functions of psi and other modified nucleosides are likely of central importance for understanding the dynamics and stereostructural modeling at functionally significant sites in the ribosome.

Enzymatic formation of N2,N2-dimethylguanosine in eukaryotic tRNA: importance of the tRNA architecture

In eukaryotic tRNA, guanosine at position 26 in the junction between the D-stem and the anticodon stem is mostly modified to N2,N2-dimethylguanosine (m2(2)G26). Here we review the available information on the enzyme catalyzing the formation of this modified nucleoside, the SAM-dependent tRNA (m2(2)G26)-methyltransferase, and our attemps to identify the parameters in tRNA needed for efficient enzymatic dimethylation of guanosine-26. The required identity elements in yeast tRNA for dimethylation under in vitro conditions by the yeast tRNA(m2(2)G26)-methyltransferase (the TRM1 gene product) are comprised of two G-C base pairs at positions G10-C25 and C11-G24 in the D-stem together with a variable loop of at least five nucleotides. These positive determinants do not seem to act via base specific interactions with the methyltransferase; they instead ensure that G26 is presented to the enzyme in a favorable orientation, within the central 3D-core of the tRNA molecule. The anticodon stem and loop is not involved in such an interaction with the enzyme. In a heterologous in vivo system, consisting of yeast tRNAs microinjected into Xenopus laevis oocytes, the requirements for modification of G26 are less stringent than in the yeast homologous in vitro system. Indeed, G26 in several microinjected tRNAs becomes monomethylated, while in yeast extracts it stays unmethylated, even after extensive incubation. Thus either the X laevis tRNA(m2(2)G26)-methyltransferase has a more relaxed specificity than its yeast homolog, or there exist two distinct G26-methylating activities, one for G26-monomethylation, and one for dimethylation of G26.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

In vivo processing of an intron-containing archael tRNA

In vitro studies on the processing of halobacterial tRNA introns have led to the proposal that archaeal and eukaryotic tRNA intron endonucleases have distinctly different requirements for the recognition of pre-tRNAs. Using a Haloferax volcanii in vivo expression vector we have examined the in vivo processing of modified forms of the halobacterial intron-containing tRNA(Trp) gene. As observed in vitro, changes in the exon-intron boundary structure of this pre-tRNA block processing. Intron sequences, other than those at the exon-intron boundaries, are not essential for processing in vivo. We also show that conversion of the tryptophan anticodon to an opal suppressor anticodon is tolerated when the exon-intron boundary structure is maintained.

The tRNA(Tyr) multigene family of Nicotiana rustica: genome organization, sequence analyses and expression in vitro

Tobacco tRNA(Tyr) genes are mainly organized as a dispersed multigene family as shown by hybridization with a tRNA(Tyr)-specific probe to Southern blots of Eco RI-digested DNA. A Nicotiana genomic library was prepared by Eco RI digestion of nuclear DNA, ligation of the fragments into the vector lambda gtWES.lambda B and in vitro packaging. The phage library was screened with a 5'-labelled synthetic oligonucleotide complementary to nucleotides 18 to 37 of cytoplasmic tobacco tRNA(Tyr). Eleven hybridizing Eco RI fragments ranging in size from 1.7 to 7.5 kb were isolated from recombinant lambda phage and subcloned into pUC19 plasmid. Four of the sequenced tRNA(Tyr) genes code for the known tobacco tRNA1(Tyr) (G psi A) and seven code for tRNA2(Tyr) (G psi A). The two tRNA species differ in one nucleotide pair at the basis of the T psi C stem. Only one tRNA(Tyr) gene (pNtY5) contains a point mutation (T54-->A54). Comparison of the intervening sequences reveals that they differ considerably in length and sequence. Maturation of intron-containing pre-tRNAs was studied in HeLa and wheat germ extracts. All pre-tRNAs(Tyr)--with one exception--are processed and spliced in both extracts. The tRNA(Tyr) gene encoded by pNtY5 is transcribed efficiently in HeLa extract but processing of the pre-tRNA is impaired.

Intron excision from tRNA precursors by plant splicing endonuclease requires unique features of the mature tRNA domain

It has been proposed that yeast and Xenopus splicing endonucleases initially recognize features in the mature tRNA domain common to all tRNA species and that the sequence and structure of the intron are only minor determinants of splice-site selection. In accordance with this postulation, we show that yeast endonuclease splices heterologous pre-tRNA(Tyr) species from vertebrates and plants which differ in their mature domains and intron secondary structures. In contrast, wheat germ splicing endonuclease displays a pronounced preference for homologous pre-tRNA species; an extensive study of heterologous substrates revealed that neither yeast pre-tRNA species specific for leucine, serine, phenylalanine and tyrosine nor human and Xenopus pre-tRNA(Tyr) species were spliced. In order to identify the elements essential for pre-tRNA splicing in plants, we constructed chimeric genes coding for tRNA precursors with a plant intron secondary structure and with mature tRNA(Tyr) domains from yeast and Xenopus, respectively. The chimeric pre-tRNA comprising the mature tRNA(Tyr) domain from Xenopus was spliced efficiently in wheat germ extract, whereas the chimeric construct containing the mature tRNA(Tyr) domain from yeast was not spliced at all. These data indicate that intron secondary structure contributes to the specificity of plant splicing endonuclease and that unique features of the mature tRNA domain play a dominant role in enzyme-substrate recognition. We further investigated the influence of specific nucleotides in the mature domain on splicing by generating a number of mutated pre-tRNA species. Our results suggest that nucleotides located in the D stem, i.e. in the center of the pre-tRNA molecule, are recognition points for plant splicing endonuclease.

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.

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.

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)