Structure of transfer RNA molecules containing the long variable loop

A structure is proposed for the type II tRNA molecules containing the long variable loop and the tertiary base interactions here are compared with type I tRNAs having the short variable loop. The type II tRNAs are similar to the type I tRNAs in their tertiary base pairing interactions but differ from them generally by not having the tertiary base triples. The long variable loop, which is comprised of a helical stem and a loop at the end of it, emerges from the deep groove side of the dihydrouridine helix, and is tilted roughly 30° to the plane formed by the amino acid-pseudouridine and anticodon-dihydrouridine helices found in yeast tRNA^Phe. The fact that many of the type I tRNAs also lack the full compliment of base triples suggests that the tertiary base pairs may alone suffice to sustain the tRNA fold required for its biological function. The base triples and the variable loop appear to have little functional significance. The base type at position 9 is correlated with the number of base triples and G-C base pairs in the dihydrouridine stem.     

tRNA leucine identity and recognition sets

Transfer RNAs (tRNAs) are grouped into two classes based on the structure of their variable loop. In Escherichia coli, tRNAs from three isoaccepting groups are classified as type II. Leucine tRNAs comprise one such group. We used both in vivo and in vitro approaches to determine the nucleotides that are required for tRNA(Leu) function. In addition, to investigate the role of the tRNA fold, we compared the in vivo and in vitro characteristics of type I tRNA(Leu) variants with their type II counterparts.A minimum of six conserved tRNA(Leu) nucleotides were required to change the amino acid identity and recognition of a type II tRNA(Ser) amber suppressor from a serine to a leucine residue. Five of these nucleotides affect tRNA tertiary structure; the G15-C48 tertiary "Levitt base-pair" in tRNA(Ser) was changed to A15-U48; the number of nucleotides in the alpha and beta regions of the D-loop was changed to achieve the positioning of G18 and G19 that is found in all tRNA(Leu); a base was inserted at position 47n between the base-paired extra stem and the T-stem; in addition the G73 "discriminator" base of tRNA(Ser) was changed to A73. This minimally altered tRNA(Ser) exclusively inserted leucine residues and was an excellent in vitro substrate for LeuRS. In a parallel experiment, nucleotide substitutions were made in a glutamine-inserting type I tRNA (RNA(SerDelta); an amber suppressor in which the tRNA(Ser) type II extra-stem-loop is replaced by a consensus type I loop). This "type I" swap experiment was successful both in vivo and in vitro but required more nucleotide substitutions than did the type II swap. The type I and II swaps revealed differences in the contributions of the tRNA(Leu) acceptor stem base-pairs to tRNA(Leu) function: in the type I, but not the type II fold, leucine specificity was contingent on the presence of the tRNA(Leu) acceptor stem sequence. The type I and II tRNAs used in this study differed only in the sequence and structure of the variable loop. By altering this loop, and thereby possibly introducing subtle changes into the overall tRNA fold, it became possible to detect otherwise cryptic contributions of the acceptor stem sequence to recognition by LeuRS. Possible reasons for this effect are discussed.     

Nucleotides that contribute to the identity of Escherichia coli tRNA(Phe)

A series of sequence variants of amber suppressor genes of tRNA(Phe) were synthesized in vitro and cloned in Escherichia coli to examine the contributions of individual nucleotides to identity for amino acid acceptance. Three different but complementary types of tRNA variants were constructed. The first involved the substitution of base-pairs on the cloverleaf stem regions of the E. coli tRNA(Phe). The second type of variant involved total gene synthesis based on wild-type tRNA(Phe) sequences found in Bacillus subtilis and in Halobacterium volcanii. In the third type of variant, the identity of E. coli tRNALys was changed to that of tRNA(Phe). The nucleotides which are important for tRNA(Phe) identity in E. coli are located on the corner of the L-shaped tRNA molecule, where the dihydrouridine loop interacts with the T loop, and extend to the interior opening of the anticodon stem and the adjoining variable loop. The nucleotide sequence on the dihydrouridine stem region, which joins the corner and stem regions, was not successfully studied though it may contribute to tRNA(Phe) identity. The fourth nucleotide from the 3' end of tRNA(Phe) has some importance for identity.     

Transfer RNA splicing in Saccharomyces cerevisiae. Secondary and tertiary structures of the substrates

Secondary and tertiary structures of four yeast tRNA precursors that contain introns have been elucidated using limited digestion with a variety of single-strand- and double-strand-specific nucleases. The pre-tRNAs, representing the variety of intron sizes and potential structures, were: pre-tRNALeuCAA, pre-tRNALeuUAG, pre-tRNAIleUAU, and pre-tRNAPro-4UGG. Conventional tRNA cloverleaf structure is maintained in these precursors except that the anticodon loop is interrupted by the intron. The intron contains a sequence which is complementary to a portion of the anticodon loop and allows the formation of a double helix often extending the anticodon stem. The 5' and 3' splicing cleavage sites are located at either end of this helix and are single-stranded. The intron is the most sensitive region to nuclease cleavage, suggesting that it is on the surface of the molecule and available for interaction with the splicing endonuclease. Absence of Mg2+ or spermidine renders the dihydrouridine and T psi C loops of these precursors highly sensitive to nuclease digestion. These ionic effects mimic those observed for tRNAPhe and suggest that the tRNA portion of these precursors has native tRNA structure. We propose consensus secondary and tertiary structures which may be of significance to eventual understanding of the mechanism of yeast tRNA splicing.     

Self-splicing group I intron in cyanobacterial initiator methionine tRNA: evidence for lateral transfer of introns in bacteria.

A group I self-splicing intron has been found in the anticodon loop of tRNA(fMet) genes in three cyanobacterial genera: Dermocarpa, Scytonema and Synechocystis; it is absent in nine others. The Synechocystis intron is also interrupted by an open reading frame (ORF) of 150 codons. Of these three bacteria, only Scytonema also contains the group I intron that has previously been reported in tRNA(Leu) (UAA) genes in both cyanobacteria and chloroplasts. The presence of an ORF in the tRNA(fMet) intron, the sporadic distribution of the intron among cyanobacteria and the lack of correlation between relatedness of the intron sequences and the bacteria in which they reside, are all consistent with recent introduction of this intron by lateral transfer.     

Intron-dependent formation of pseudouridines in the anticodon of Saccharomyces cerevisiae minor tRNA(Ile).

We have isolated and sequenced the minor species of tRNA(Ile) from Saccharomyces cerevisiae. This tRNA contains two unusual pseudouridines (psi s) in the first and third positions of the anticodon. As shown earlier by others, this tRNA derives from two genes having an identical 60 nt intron. We used in vitro procedures to study the structural requirements for the conversion of the anticodon uridines to psi 34 and psi 36. We show here that psi 34/psi 36 modifications require the presence of the pre-tRNA(Ile) intron but are not dependent upon the particular base at any single position of the anticodon. The conversion of U34 to psi 34 occurs independently from psi 36 synthesis and vice versa. However, psi 34 is not formed when the middle and the third anticodon bases of pre-tRNA(Ile) are both substituted to yield ochre anticodon UUA. This ochre pre-tRNA(Ile) mutant has the central anticodon uridine modified to psi 35 as is the case for S.cerevisiae SUP6 tyrosine-inserting ochre suppressor tRNA. In contrast, neither the first nor the third anticodon pseudouridine is formed, when the ochre (UUA) anticodon in the pre-tRNA(Tyr) is substituted with the isoleucine UAU anticodon. A synthetic mini-substrate consisting of the anticodon stem and loop and the wild-type intron of pre-tRNA(Ile) is sufficient to fully modify the anticodon U34 and U36 into psi s. This is the first example of the tRNA intron sequence, rather than the whole tRNA or pre-tRNA domain, being the main determinant of nucleoside modification.     

Substrate structural requirements of Schizosaccharomyces pombe RNase P

RNase P from Schizosaccharomyces pombe has been purified over 2000-fold. The apparent Km for two S. pombe tRNA precursors derived from the supS1 and sup3-e tRNA(Ser) genes is 20 nM; the apparent Vmax is 2.5 nM/min (supS1) and 1.1 nM/min (sup3-e). Processing studies with precursors of other mutants show that the structures of the acceptor stem and anticodon/intron loop of tRNA are crucial for S. pombe RNase P action.     

SPLITS: a new program for predicting split and intron-containing tRNA genes at the genome level

In the archaea, some tRNA precursors contain intron(s) not only in the anticodon loop region but also in diverse sites of the gene (intron-containing tRNA or cis-spliced tRNA). The parasite Nanoarchaeum equitans, a member of the Nanoarchaeota kingdom, creates functional tRNA from separate genes, one encoding the 5'-half and the other the 3'-half (split tRNA or trans-spliced tRNA). Although recent genome projects have revealed a huge amount of nucleotide sequence data in the archaea, a comprehensive methodology for intron-containing and split tRNA searching is yet to be established. We therefore developed SPLITS, which is aimed at searching for any type of tRNA gene and is especially focused on intron-containing tRNAs or split tRNAs at the genome level. SPLITS initially predicts the bulge-helix-bulge splicing motif (a well-known, required structure in archaeal pre-tRNA introns) to determine and remove the intronic regions of tRNA genes. The intron-removed DNA sequences are automatically queried to tRNAscan-SE. SPLITS can predict known tRNAs with single introns located at unconventional sites on the genes (100%), tRNAs with double introns (85.7%), and known split tRNAs (100%). Our program will be very useful for identifying novel tRNA genes after completion of genome projects. The SPLITS source code is freely downloadable at http://splits.iab.keio.ac.jp/.     

The identification of the sites of tRNA(Ser)(GCU) interaction in bovine liver with homologous aminoacyl-tRNA-synthetase by the chemical modification method]

Interaction of the bovine liver tRNA(GCUSer) having a long variable loop, with the cognate aminoacyl-tRNA synthetase has been studied by alkylation with ethylnitrosourea. It was shown that seryl-tRNA synthetase protects 3'-phosphates of nucleotides 12, 13 in D-stem and 45-47-, 47 G.-, 47 H-variable stem of tRNA(GCUreS) from alkylation. An anticodon loop of tRNA(GCUSer) did not interact with seryl-tRNA synthetase.     

Nested Evolution of a tRNALeu(UAA) Group I Intron by both Horizontal Intron Transfer and Recombination of the Entire tRNA Locus

The origin and evolution of bacterial introns are still controversial issues. Here we present data on the distribution and evolution of a recently discovered divergent tRNA(Leu)(UAA) intron. The intron shows a higher sequence affiliation with introns in tRNA(Ile)(CAU) and tRNA(Arg)(CCU) genes in alpha- and beta-proteobacteria, respectively, than with other cyanobacterial tRNA(Leu)(UAA) group I introns. The divergent tRNA(Leu)(UAA) intron is sporadically distributed both within the Nostoc and the Microcystis radiations. The complete tRNA gene, including flanking regions and intron from Microcystis aeruginosa strain NIVA-CYA 57, was sequenced in order to elucidate the evolutionary pattern of this intron. Phylogenetic reconstruction gave statistical evidence for different phylogenies for the intron and exon sequences, supporting an evolutionary model involving horizontal intron transfer. The distribution of the tRNA gene, its flanking regions, and the introns were addressed by Southern hybridization and PCR amplification. The tRNA gene, including the flanking regions, were absent in the intronless stains but present in the intron-containing strains. This suggests that the sporadic distribution of this intron within the Microcystis genus cannot be attributed to intron mobility but rather to an instability of the entire tRNA(Leu)(UAA) intron-containing genome region. Taken together, the complete data set for the evolution of this intron can best be explained by a model involving a nested evolution of the intron, i.e., wherein the intron has been transferred horizontally (probably through a single or a few events) to a tRNA(Leu)(UAA) gene which is located within a unstable genome region.     

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.     

Novel group I intron in the tRNA(Leu)(UAA) gene of a gamma-proteobacterium isolated from a deep subsurface environment

A group I intron has been found to interrupt the anticodon loop of the tRNA(Leu)(UAA) gene in a bacterium belonging to the gamma-subdivision of Proteobacteria and isolated from a deep subsurface environment. The subsurface isolate SMCC D0715 was identified as belonging to the genus Pseudomonas. The group I intron from this isolate is the first to be reported for gamma-proteobacteria, and the first instance of a tRNA(Leu)(UAA) group I intron to be found in a group of bacteria other than cyanobacteria. The 231-nucleotide (nt) intron's sequence has group I conserved elements and folds into a bona fide group I secondary structure with canonical base-paired segments P1 to P9 and a paired region, P10. The D0715 intron possesses the 11-nt motif CCUACG. UAUGG in its P8 region, a feature not common in bacterial introns. To date, phylogenetic analysis has shown that bacterial introns form two distinct families, and their complex distribution suggests that both lateral transfer and common ancestry have taken part in the evolutionary history of these elements.     

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.     

Determination of interacting segments of tRNA(Leu) from cow mammary glands with homologous aminoacyl-tRNA-synthetase by a chemical modification method

The interaction of the cow mammary gland tRNA(IAGLeu), having a long variable loop, with the cognate aminoacyl-tRNA synthetase has been studied by the alkylation with ethylnitrosourea. It was shown that leucyl-tRNA synthetase protects from alkylation 3'-phosphates of the nucleotides 12-13 in D-loop, 23-24 in D-stem and 37-43 in the anticodon arm of tRNA(IAGLeu). All regions of interaction with the aminoacyl-tRNA synthetase are located in the same plane of tRNA whereas the long variable loop is in another plane.     

Origin and evolution of group I introns in cyanobacterial tRNA genes.

Many tRNA(Leu)UAA genes from plastids contain a group I intron. An intron is also inserted in the same gene at the same position in cyanobacteria, the bacterial progenitors of plastids, suggesting an ancient bacterial origin for this intron. A group I intron has also been found in the tRNA(fMet) gene of some cyanobacteria but not in plastids, suggesting a more recent origin for this intron. In this study, we investigate the phylogenetic distributions of the two introns among cyanobacteria, from the earliest branching to the more derived species. The phylogenetic distribution of the tRNA(Leu)UAA intron follows the clustering of rRNA sequences, being either absent or present in clades of closely related species, with only one exception in the Pseudanabaena group. Our data support the notion that the tRNA(Leu)UAA intron was inherited by cyanobacteria and plastids through a common ancestor. Conversely, the tRNA(fMet) intron has a sporadic distribution, implying that many gains and losses occurred during cyanobacterial evolution. Interestingly, a phylogenetic tree inferred from intronic sequences clearly separates the different tRNA introns, suggesting that each family has its own evolutionary history.