Possibility of cytoplasmic pre-tRNA splicing: the yeast tRNA splicing endonuclease mainly localizes on the mitochondria

Pre-tRNA splicing has been believed to occur in the nucleus. In yeast, the tRNA splicing endonuclease that cleaves the exon-intron junctions of pre-tRNAs consists of Sen54p, Sen2p, Sen34p, and Sen15p and was thought to be an integral membrane protein of the inner nuclear envelope. Here we show that the majority of Sen2p, Sen54p, and the endonuclease activity are not localized in the nucleus, but on the mitochondrial surface. The endonuclease is peripherally associated with the cytosolic surface of the outer mitochondrial membrane. A Sen54p derivative artificially fixed on the mitochondria as an integral membrane protein can functionally replace the authentic Sen54p, whereas mutant proteins defective in mitochondrial localization are not fully active. sen2 mutant cells accumulate unspliced pre-tRNAs in the cytosol under the restrictive conditions, and this export of the pre-tRNAs partly depends on Los1p, yeast exportin-t. It is difficult to explain these results from the view of tRNA splicing in the nucleus. We rather propose a new possibility that tRNA splicing occurs on the mitochondrial surface in yeast.     

Three-dimensional structure determined for a subunit of human tRNA splicing endonuclease (Sen15) reveals a novel dimeric fold

Splicing of eukaryal intron-containing tRNAs requires the action of the heterotetrameric splicing endonuclease, which is composed of two catalytic subunits, Sen34 and Sen2, and two structural subunits, Sen15 and Sen54. Here we report the solution structure of the human tRNA splicing endonuclease subunit HsSen15. To facilitate the structure determination, we removed the disordered 35 N-terminal and 14 C-terminal residues of the full-length protein to produce HsSen15(36-157). The structure of HsSen15(36-157), the first for a subunit of a eukaryal splicing endonuclease, revealed that the protein possesses a novel homodimeric fold. Each monomer consists of three alpha-helices and a mixed antiparallel/parallel beta-sheet, arranged in a topology similar to that of the C-terminal domain of Methanocaldococcus jannaschii endonuclease. The dimeric interface is dominated by a beta-barrel structure, formed by face-to-face packing of two, three-stranded beta-sheets. Each of the beta-sheets results from reciprocal parallel pairing of one beta-strand from one subunit with two other beta-strands from the symmetric subunit. The structural model provides insights into the functional assembly of the human tRNA splicing endonuclease.     

Involvement of MEK-ERK signaling pathway in the inhibition of cell growth by troglitazone in human pancreatic cancer cells

Tif6p (eIF6) is necessary for 60S biogenesis, rRNA maturation and must be released from 60S to permit 80S assembly and translation. We characterized Tif6p interactors. Tif6p is mostly on 66S-60S pre-ribosomes, partly free. Tif6p complex(es) contain nucleo-ribosomal factors and Asc1p. Surprisingly, Tif6p particle contains the low-abundance endonuclease Sen34p. We analyzed Sen34p role on rRNA/tRNA synthesis, in vivo. Sen34p depletion impairs tRNA splicing and causes unexpected 80S accumulation. Accordingly, Sen34p overexpression causes 80S decrease and increased polysomes which suggest increased translational efficiency. With delayed kinetics, Sen34p depletion impairs rRNA processing. We conclude that Sen34p is absolutely required for tRNA splicing and that it is a rate-limiting element for efficient translation. Finally, we confirm that Tif6p accompanies 27S pre-rRNA maturation to 25S rRNA and we suggest that Sen34p endonuclease in Tif6p complex may affect also rRNA maturation.     

Molecular cloning and characterization of a nuclear gene encoding a putative subunit of tRNA splicing endonuclease from Arabidopsis thaliana.

tRNA splicing endonuclease is required to produce mature tRNAs from intron-containing tRNA precursors. To characterize the structural features of plant endonuclease, we have isolated a cDNA and a corresponding genomic DNA clone from libraries of Arabidopsis thaliana which encode a putative subunit of the endonuclease. The gene product has an apparent mass of 27 kDa and contains a homologous domain of approximately 130 amino acids at the C-terminal region commonly found in other eucaryal and archaeal counterparts. Southern hybridization analysis of Arabidopsis genomic DNA utilizing the cDNA clone as probe indicates the presence of at least two related genes.     

Inactivation of the yeast Sen1 protein affects the localization of nucleolar proteins

A mutation in the Saccharomyces cerevisiae SEN1 gene causes accumulation of end-matured, intron-containing pre-tRNAs. Cells containing the thermosensitive sen1-1 mutation exhibit reduced tRNA splicing endonuclease activity. However, Sen1p is not the catalytic subunit of this enzyme. We have used Sen1p-specific antibodies for cell fractionation studies and immunofluorescent microscopy and determined that Sentp is a low abundance protein of about 239 kDa. It localizes to the nucleus with a granular distribution. We verified that a region in SEN1 containing a putative nuclear localization signal sequence (NLS) is necessary for nuclear targeting. Furthermore, we found that inactivation of Sen1p by temperature shift of a strain carrying sen1-1 leads to mislocalization of two nucleolar proteins, Nopt and Ssb1 Possible mechanisms are discussed for several related nuclear functions of Sen1p, including tRNA splicing and the maintenance of a normal crescent-shaped nucleolus.     

Plant pre-tRNA splicing enzymes are targeted to multiple cellular compartments

Splicing of precursor tRNAs in plants requires the concerted action of three enzymes: an endonuclease to cleave the intron at the two splice sites, an RNA ligase for joining the resulting tRNA halves and a 2'-phosphotransferase to remove the 2'-phosphate from the splice junction. Pre-tRNA splicing has been demonstrated to occur exclusively in the nucleus of vertebrates and in the cytoplasm of budding yeast cells, respectively. We have investigated the subcellular localization of plant splicing enzymes fused to GFP by their transient expression in Allium epidermal and Vicia guard cells. Our results show that all three classes of splicing enzymes derived from Arabidopsis and Oryza are localized in the nucleus, suggesting that plant pre-tRNA splicing takes place preferentially in the nucleus. Moreover, two of the splicing enzymes, i.e., tRNA ligase and 2'-phosphotransferase, contain chloroplast transit signals at their N-termini and are predominantly targeted to chloroplasts and proplastids, respectively. The putative transit sequences are effective also in the heterologous context fused directly to GFP. Chloroplast genomes do not encode intron-containing tRNA genes of the nuclear type and consequently tRNA ligase and 2'-phosphotransferase are not required for classical pre-tRNA splicing in these organelles but they may play a role in tRNA repair and/or splicing of atypical group II introns. Additionally, 2'-phosphotransferase-GFP fusion protein has been found to be associated with mitochondria, as confirmed by colocalization studies with MitoTracker Red. In vivo analyses with mutated constructs suggest that alternative initiation of translation is one way utilized by tRNA splicing enzymes for differential targeting.     

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.     

Identification of a human endonuclease complex reveals a link between tRNA splicing and pre-mRNA 3' end formation

tRNA splicing is a fundamental process required for cell growth and division. The first step in tRNA splicing is the removal of introns catalyzed in yeast by the tRNA splicing endonuclease. The enzyme responsible for intron removal in mammalian cells is unknown. We present the identification and characterization of the human tRNA splicing endonuclease. This enzyme consists of HsSen2, HsSen34, HsSen15, and HsSen54, homologs of the yeast tRNA endonuclease subunits. Additionally, we identified an alternatively spliced isoform of SEN2 that is part of a complex with unique RNA endonuclease activity. Surprisingly, both human endonuclease complexes are associated with pre-mRNA 3' end processing factors. Furthermore, siRNA-mediated depletion of SEN2 exhibited defects in maturation of both pre-tRNA and pre-mRNA. These findings demonstrate a link between pre-tRNA splicing and pre-mRNA 3' end formation, suggesting that the endonuclease subunits function in multiple RNA-processing events.     

Transfer RNA splicing in Saccharomyces cerevisiae: defining the substrates.

The primary sequences of all the tRNA precursors which contain intervening sequences and which accumulate in the Saccharomyces cerevisiae rnal mutant are presented. A combination of DNA and RNA sequence analysis has led to elucidation of the primary sequence of four hitherto uncharacterized precursors. The location of the intervening sequence has in all cases been unambiguously determined by analysis of the intermediates in the splicing reaction. Secondary structures based upon the tRNA cloverleaf are shown for all the tRNA precursors and discussed with respect to common recognition by the yeast splicing endonuclease.     

Identification of an entire set of tRNA molecules and characterization of cleavage sites of the intron-containing tRNA precursors in acidothermophilic crenarchaeon Sulfolobus tokodaii strain7

The acidothermophilic crenarchaeon, Sulfolobus tokodaii strain7, was isolated from a hot spring in Beppu, Kyushu, Japan. Whole genomic data of this microorganism indicated that among 46 putative tRNA genes identified, 24 were interrupted tRNA genes containing an intron. A sequence comparison between the cDNA sequences for unspliced and spliced tRNAs indicated that all predicted tRNAs were expressed and all intron portions were spliced in this microorganism. However, the actual cleavage site in the splicing process was not determined for 13 interrupted tRNAs because of the presence of the same nucleotides at both 5′ and 3′ border regions of each intron. The cleavage sites for all the introns, which were determined by an in vitro cleavage experiment with recombinant splicing endonuclease as well as cDNA sequencing of the spliced tRNAs, indicated that non-canonical BHB structure motifs were also recognized and processed by the splicing machinery in this organism. This is the first report to empirically determine the actual cleavage and splice sites of introns in the whole set of archaeal tRNA genes, and reassigns the exon-intron borders with a novel and more plausible non-canonical BHB structure.     

Site selection by the tRNA splicing endonuclease of Xenopus laevis

To investigate the mechanism by which the purified Xenopus tRNA splicing endonuclease recognizes its splice sites, we utilized yeast pre-tRNA(3Leu) and pre-tRNA(Phe) variants constructed by in vitro mutagenesis. We found that the endonuclease interacts with conserved features of the mature tRNA domain. In particular, U8 and C56 may be examples of contact points between protein and RNA. Given that there are no conserved sequences at the splice junctions, the specificity of cutting at both splice sites is determined by the length of the anticodon stem. Although in general, the sequence of the intron is unimportant for splicing, there are some structural requirements.     

Structural characterization of the catalytic subunit of a novel RNA splicing endonuclease

The RNA splicing endonuclease is responsible for recognition and excision of nuclear tRNA and all archaeal introns. Despite the conserved RNA cleavage chemistry and a similar enzyme assembly, currently known splicing endonuclease families have limited RNA specificity. Different from previously characterized splicing endonucleases in Archaea, the splicing endonuclease from archaeum Sulfolobus solfataricus was found to contain two different subunits and accept a broader range of substrates. Here, we report a crystal structure of the catalytic subunit of the S.solfataricus endonuclease at 3.1 angstroms resolution. The structure, together with analytical ultracentrifugation analysis, identifies the catalytic subunit as an inactive but stable homodimer, thus suggesting the possibility of two modes of functional assembly for the active enzyme.     

Isolation of yeast tRNALeu genes. DNA sequence of a cloned tRNALeu3 gene.

A library of cloned yeast DNA fragments generated by digestion of yeast DNA with the restriction endonuclease Bam HI has been screened by colony hybridization to total yeast [32P]tRNA. Four hundred colonies carrying yeast tRNA genes were isolated. By hybridization to 125I-tRNALeu3, we have isolated from this collection 14 colonies carrying fragments containing yeast tRNALeu genes. The size of the yeast Bam HI inserts ranged from 2.45 x 10(6) to 14 x 10(6) daltons. One of these fragments was mapped in detail by restriction endonuclease digestion and hybridization to 125I-tRNALeu3. The presence of a tRNALeu3 gene was confirmed by DNA sequence. The results indicate that the tRNALeu3 coding region is not co-linear with the tRNALeu3. An intervening tract of 33 base pairs interrupts the coding sequences 1 base pair past the anticodon coding region. The putative structure of a tRNALeu3 precursor is deduced in which the anticodon base pairs with residues from the intervening sequence.     

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.     

Two anthranilate synthase genes in Arabidopsis: defense-related regulation of the tryptophan pathway.

Arabidopsis thaliana has two genes, ASA1 and ASA2, encoding the alpha subunit of anthranilate synthase, the enzyme catalyzing the first reaction in the tryptophan biosynthetic pathway. As a branchpoint enzyme in aromatic amino acid biosynthesis, anthranilate synthase has an important regulatory role. The sequences of the plant genes are homologous to their microbial counterparts. Both predicted proteins have putative chloroplast transit peptides at their amino termini and conserved amino acids involved in feedback inhibition by tryptophan. ASA1 and ASA2 cDNAs complement anthranilate synthase alpha subunit mutations in the yeast Saccharomyces cerevisiae and in Escherichia coli, confirming that both genes encode functional anthranilate synthase proteins. The distributions of ASA1 and ASA2 mRNAs in various parts of Arabidopsis plants are overlapping but nonidentical, and ASA1 mRNA is approximately 10 times more abundant in whole plants. Whereas ASA2 is expressed at a constitutive basal level, ASA1 is induced by wounding and bacterial pathogen infiltration, suggesting a novel role for ASA1 in the production of tryptophan pathway metabolites as part of an Arabidopsis defense response. Regulation of key steps in aromatic amino acid biosynthesis in Arabidopsis appears to involve differential expression of duplicated genes.     

ZYGOTE-ARREST 3 that encodes the tRNA ligase is essential for zygote division in Arabidopsis

In sexual organisms, division of the zygote initiates a new life cycle. Although several genes involved in zygote division are known in plants, how the zygote is activated to start embryogenesis has remained elusive.Here, we showed that a mutation in ZYGOTE-ARREST 3(ZYG3) in Arabidopsis led to a tight zygote-lethal phenotype.Map-based cloning revealed that ZYG3 encodes the transfer RNA(tRNA) ligase AtRNL, which is a single-copy gene in the Arabidopsis genome. Expression analyses showed that AtRNL is expressed throughout zygotic embryogenesis, and in meristematic tissues. Using pAtRNL::cAtRNL-sYFP-complemented zyg3/zyg3 plants, we showed that AtRNL is localized exclusively in the cytoplasm, suggesting that tRNA splicing occurs primarily in the cytoplasm. Analyses using partially rescued embryos showed that mutation in AtRNL compromised splicing of intron-containing tRNA.Mutations of two tRNA endonuclease genes, SEN1 and SEN2, also led to a zygote-lethal phenotype. These results together suggest that tRNA splicing is critical for initiating zygote division in Arabidopsis.