Accumulation of pre-tRNA splicing ''2/3'' intermediates in a Saccharomyces cerevisiae mutant.

In an effort to identify genes involved in the excision of tRNA introns in Saccharomyces cerevisiae, temperature-sensitive mutants were screened for intracellular accumulation of intron-containing tRNA precursors by RNA hybridization analysis. In one mutant, tRNA splicing intermediates consisting of the 5' exon covalently joined to the intron ('2/3' pre-tRNA molecules) were detected in addition to unspliced precursors. The mutant cleaves pre-tRNA(Phe) in vitro at the 3' exon/intron splice site, generating the 3' half molecule and 2/3 intermediate. The 5' half molecule and intron are not produced, indicating that cleavage at the 5' splice site is suppressed. This partial splicing activity co-purifies with tRNA endonuclease throughout several chromatographic steps. Surprisingly, the splicing defect does not appreciably affect cell growth at normal or elevated temperatures, but does confer a pseudo cold-sensitive phenotype of retarded growth at 15 degrees C. The mutant falls into the complementation group SEN2 previously defined by the isolation of mutants defective for tRNA splicing in vitro [Winey, M. and Culbertson, M.R. (1988) Genetics, 118, 609-617], although its phenotypes are distinct from those of the previous sen2 isolates. The distinguishing genetic and biochemical properties of this new allele, designated sen2-3, suggests the direct participation of the SEN2 gene product in tRNA endonuclease function.     

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.     

Intron sequence and structure requirements for tRNA splicing in Saccharomyces cerevisiae

Predicted single-stranded structure at the 3' splice site is a conserved feature among intervening sequences (IVSs) in eukaryotic nuclear tRNA precursors. The role of 3' splice site structure in splicing was examined through hexanucleotide insertions at a central intron position in the Saccharomyces cerevisiae tRNA gene. These insertions were designed to alter the structure at the splice site without changing its sequence. Endonuclease cleavage of pre-tRNA substrates was then measured in vitro, and suppressor activity was examined in vivo. A precursor with fully double-stranded structure at the 3' splice site was not cleaved by endonuclease. The introduction of one unpaired nucleotide at the 3' splice site was sufficient to restore cleavage, although at a reduced rate. We have also observed that guanosine at the antepenultimate position provides a second consensus feature among IVSs in tRNA precursors. Point mutations at this position were found to affect splicing although there was no specific requirement for guanosine. These and previous results suggest that elements of secondary and/or tertiary structure at the 3' end of IVSs are primary determinants in pre-tRNA splice site utilization whereas specific sequence requirements are limited.     

Ribonuclease PH plays a major role in the exonucleolytic maturation of CCA-containing tRNA precursors in Bacillus subtilis

In contrast to Escherichia coli, where all tRNAs have the CCA motif encoded by their genes, two classes of tRNA precursors exist in the Gram-positive bacterium Bacillus subtilis. Previous evidence had shown that ribonuclease Z (RNase Z) was responsible for the endonucleolytic maturation of the 3' end of those tRNAs lacking an encoded CCA motif, accounting for about one-third of its tRNAs. This suggested that a second pathway of tRNA maturation must exist for those precursors with an encoded CCA motif. In this paper, we examine the potential role of the four known exoribonucleases of B.subtilis, PNPase, RNase R, RNase PH and YhaM, in this alternative pathway. In the absence of RNase PH, precursors of CCA-containing tRNAs accumulate that are a few nucleotides longer than the mature tRNA species observed in wild-type strains or in the other single exonuclease mutants. Thus, RNase PH plays an important role in removing the last few nucleotides of the tRNA precursor in vivo. The presence of three or four exonuclease mutations in a single strain results in CCA-containing tRNA precursors of increasing size, suggesting that, as in E.coli, the exonucleolytic pathway consists of multiple redundant enzymes. Assays of purified RNase PH using in vitro-synthesized tRNA precursor substrates suggest that RNase PH is sensitive to the presence of a CCA motif. The division of labor between the endonucleolytic and exonucleolytic pathways observed in vivo can be explained by the inhibition of RNase Z by the CCA motif in CCA-containing tRNA precursors and by the inhibition of exonucleases by stable secondary structure in the 3' extensions of the majority of CCA-less tRNAs.     

Saccharomyces cerevisiae tRNA ligase. Purification of the protein and isolation of the structural gene

The tRNA ligase protein of Saccharomyces cerevisiae is one of the components required for splicing of yeast tRNA precursors in vitro. We have purified this protein to near homogeneity using an affinity elution chromatographic step. Purified tRNA ligase is a 90-kDa protein that, in addition to catalyzing the ligation of tRNA half-molecules in the coupled splicing reaction, will also ligate an artificial substrate. Using this artificial substrate, we provide evidence for the existence of a previously predicted activated intermediate in the ligation reaction. The amino acid sequence of the amino-terminal end of the protein was determined, and we have used this information to isolate the structural gene from a library of yeast DNA. We prove that this DNA encodes the tRNA ligase protein by DNA sequencing and by demonstrating overproduction of the protein.     

Ligation of endogenous tRNA 3' half molecules to their corresponding 5' halves via 2'-phosphomonoester,3',5'-phosphodiester bonds in extracts of Chlamydomonas

tRNA preparations from Chlamydomonas and wheat germ contain small amounts of tRNA 5' halves and corresponding 3' halves. Incubation of cell-free extracts from the two sources with [γ-³²P]ATP yielded 5'-³²P-labeled tRNA 3' halves which were joined to their corresponding 5' counterparts to form mature tRNA containing 2'-phosphomonoester,3', 5'-phosphodiester bonds. tRNA 3' halves labelled with T4 kinase were purified, sequenced and also joined to their 5' counterparts. It is proposed that these tRNA halves may be intermediates of the tRNA splicing process, and that the RNA kinase and ligase activities observed here are part of the tRNA splicing complex.     

Transfer RNA intron processing in the halophilic archaebacteria

An in vitro assay system has been developed for the Halobacterium volcanii tRNA intron endonuclease using in vitro generated precursor RNAs. A partially purified enzyme preparation is capable of precise and accurate excision of the intron from the halobacterial tRNA(Trp) precursor. The cleavage reaction produces products having 5' hydroxyl and 2',3' cyclic phosphate termini. Processing of precursor molecules containing deletions within the exon regions indicates that the halobacterial endonuclease does not require intact mature tRNA structure in the substrate; this is in contrast to the eukaryotic endonuclease enzyme that has an absolute requirement for these structures. The large halobacterial tRNA(Trp) intron does not appear to be a primary site for recognition by the endonuclease, however, its removal affects cleavage efficiency. Through a comparison of the structural and sequence features of the halobacterial substrates and the precursors of other archaebacterial intron-containing precursors, a common element is proposed for the recognition of substrates by intron endonuclease.     

Human RNA 5'-kinase (hClp1) can function as a tRNA splicing enzyme in vivo

Yeast and human Clp1 proteins are homologous components of the mRNA 3′-cleavage-polyadenylation machinery. Recent studies highlighting an association of human Clp1 (hClp1) with tRNA splicing endonuclease and an intrinsic RNA-specific 5′-OH polynucleotide kinase activity of hClp1 have prompted speculation that Clp1 might play a catalytic role in tRNA splicing in animal cells. Here, we show that expression of hClp1 in budding yeast can complement conditional and lethal mutations in the essential 5′-OH RNA kinase module of yeast or plant tRNA ligases. The tRNA splicing activity of hClp1 in yeast is abolished by mutations in the kinase active site. In contrast, overexpression of yeast Clp1 (yClp1) cannot rescue kinase-defective tRNA ligase mutants, and, unlike hClp1, the purified recombinant yClp1 protein has no detectable RNA kinase activity in vitro. Mutations of the yClp1 ATP-binding site do not affect yeast viability. These findings, and the fact that hClp1 cannot complement growth of a yeast clp1Δ strain, indicate that yeast and human Clp1 proteins are not functional orthologs, despite their structural similarity. Although hClp1 can perform the 5′-end-healing step of a yeast-type tRNA splicing pathway in vivo, it is uncertain whether its kinase activity is necessary for tRNA splicing in human cells, given that other mammalian counterparts of yeast-type tRNA repair enzymes are nonessential in vivo.     

Mammalian 2',3' cyclic nucleotide phosphodiesterase (CNP) can function as a tRNA splicing enzyme in vivo

Yeast and plant tRNA splicing entails discrete healing and sealing steps catalyzed by a tRNA ligase that converts the 2',3' cyclic phosphate and 5'-OH termini of the broken tRNA exons to 3'-OH/2'-PO4 and 5'-PO4 ends, respectively, then joins the ends to yield a 2'-PO4, 3'-5' phosphodiester splice junction. The junction 2'-PO4 is removed by a tRNA phosphotransferase, Tpt1. Animal cells have two potential tRNA repair pathways: a yeast-like system plus a distinctive mechanism, also present in archaea, in which the 2',3' cyclic phosphate and 5'-OH termini are ligated directly. Here we report that a mammalian 2',3' cyclic nucleotide phosphodiesterase (CNP) can perform the essential 3' end-healing steps of tRNA splicing in yeast and thereby complement growth of strains bearing lethal or temperature-sensitive mutations in the tRNA ligase 3' end-healing domain. Although this is the first evidence of an RNA processing function in vivo for the mammalian CNP protein, it seems unlikely that the yeast-like pathway is responsible for animal tRNA splicing, insofar as neither CNP nor Tpt1 is essential in mice.     

tRNA 3' end maturation in archaea has eukaryotic features: the RNase Z from Haloferax volcanii

Here, we report the first characterization and partial purification of an archaeal tRNA 3' processing activity, the RNase Z from Haloferax volcanii. The activity identified here is an endonuclease, which cleaves tRNA precursors 3' to the discriminator. Thus tRNA 3' processing in archaea resembles the eukaryotic 3' processing pathway. The archaeal RNase Z has a KCl optimum at 5mM, which is in contrast to the intracellular KCl concentration being as high as 4M KCl.The archaeal RNase Z does process 5' extended and intron-containing pretRNAs but with a much lower efficiency than 5' matured, intronless pretRNAs. At least in vitro there is thus no defined order for 5' and 3' processing and splicing. A heterologous precursor tRNA is cleaved efficiently by the archaeal RNase Z. Experiments with precursors containing mutated tRNAs revealed that removal of the anticodon arm reduces cleavage efficiency only slightly, while removal of D and T arm reduces processing effciency drastically, even down to complete inhibition. Comparison with its nuclear and mitochondrial homologs revealed that the substrate specificity of the archaeal RNase Z is narrower than that of the nuclear RNase Z but broader than that of the mitochondrial RNase Z.     

Splicing of yeast tRNA precursors: a two-stage reaction.

Soluble extracts of S. cerevisiae splice tRNA precursors which contain intervening sequences. The reaction goes to completion and requires ATP for the production of mature sequence tRNA. In the absence of ATP, half-tRNA molecules accumulate. Similar half-tRNA molecules appear as kinetic intermediates and accumulate if splicing is inhibited with pure, mature tRNA. Half-tRNA molecules have been purified. These half-tRNAs are efficiently ligated in an ATP-dependent reaction that is inhibited by added mature tRNA. The product of ligation is the expected mature sequence tRNA. The excised intervening sequence has also been identified. These results suggest an enzymatic mechanism for splicing which involves two independent steps.     

Intron sequences involved in lariat formation during pre-mRNA splicing

We have shown that lariat formation during in vitro splicing of several RNA precursors, from Drosophila to man, occurs at a unique and identifiable but weakly conserved site, 18 to 37 nucleotides proximal to the 3' splice site. Lariat formation within an artificial intron lacking a normal branch-point sequence occurs at a cryptic site a conserved distance (approximately 23 nucleotides) from the 3' splice site. Analysis of beta-thalassemia splicing mutations revealed that lariat formation in the first intron of the human beta-globin gene occurs at the same site in normal and mutant precursors, even though alternate 5' and 3' splice sites are utilized in the mutants. Remarkably, cleavage at the 5' splice site and lariat formation do not occur when the precursor contains a beta-thalassemia deletion removing the polypyrimidine stretch and AG dinucleotide at the 3' splice site. In contrast, a single base substitution in the AG dinucleotide blocks cleavage at the 3' splice site but not at the 5' site.     

Site selection by Xenopus laevis RNAase P

Investigation of the mechanism of cleavage site selection by Xenopus RNAase P reveals that the acceptor stem, a 7 bp helix common to all tRNA precursors, is required for cleavage. We propose that Xenopus RNAase P recognizes conserved features of the mature tRNA and that the cleavage site is selected by measuring the length of the acceptor stem. In support of this, we demonstrate that insertion of 2 bp in the acceptor stem of yeast pre-tRNA(3Leu) relocates the cleavage site 2 bases 3' to the original one. In addition, insertion of 1 bp in the acceptor stem of the end-matured yeast pre-tRNA(Phe) generates an RNAase P cleavage site: the enzyme produces a mature tRNA with the characteristic 7 bp stem and releases one 5' flanking nucleotide. Since it has previously been shown that cleavage sites of the splicing endonuclease are determined by the length of the anticodon stem, RNAase P and the splicing endonuclease apparently use different stems to determine their cutting sites.     

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.     

A conditional lethal yeast phosphotransferase (tpt1) mutant accumulates tRNAs with a 2'-phosphate and an undermodified base at the splice junction.

tRNA splicing is essential in yeast and humans and presumably all eukaryotes. The first two steps of yeast tRNA splicing, excision of the intron by endonuclease and joining of the exons by tRNA ligase, leave a splice junction bearing a 2'-phosphate. Biochemical analysis suggests that removal of this phosphate in yeast is catalyzed by a highly specific 2'-phosphotransferase that transfers the phosphate to NAD to form ADP-ribose 1"-2" cyclic phosphate. 2'-Phosphotransferase catalytic activity is encoded by a single essential gene, TPT1, in the yeast Saccharomyces cerevisiae. We show here that Tpt1 protein is responsible for the dephosphorylation step of tRNA splicing in vivo because, during nonpermissive growth, conditional lethal tpt1 mutants accumulate 2'-phosphorylated tRNAs from eight different tRNA species that are known to be spliced. We show also that several of these tRNAs are undermodified at the splice junction residue, which is always located at the hypermodified position one base 3' of the anticodon. This result is consistent with previous results indicating that modification of the hypermodified position occurs after intron excision in the tRNA processing pathway, and implies that modification normally follows the dephosphorylation step of tRNA splicing in vivo.