Formation of the conserved pseudouridine at position 55 in archaeal tRNA

Pseudouridine (Ψ) located at position 55 in tRNA is a nearly universally conserved RNA modification found in all three domains of life. This modification is catalyzed by TruB in bacteria and by Pus4 in eukaryotes, but so far the Ψ55 synthase has not been identified in archaea. In this work, we report the ability of two distinct pseudouridine synthases from the hyperthermophilic archaeon Pyrococcus furiosus to specifically modify U55 in tRNA in vitro. These enzymes are _pfuCbf5, a protein known to play a role in RNA-guided modification of rRNA, and _pfuPsuX, a previously uncharacterized enzyme that is not a member of the TruB/Pus4/Cbf5 family of pseudouridine synthases. _pfuPsuX is hereafter renamed _pfuPus10. Both enzymes specifically modify tRNA U55 in vitro but exhibit differences in substrate recognition. In addition, we find that in a heterologous in vivo system, _pfuPus10 efficiently complements an Escherichia coli strain deficient in the bacterial Ψ55 synthase TruB. These results indicate that it is probable that _pfuCbf5 or _pfuPus10 (or both) is responsible for the introduction of pseudouridine at U55 in tRNAs in archaea. While we cannot unequivocally assign the function from our results, both possibilities represent unexpected functions of these proteins as discussed herein.     

Deficiency of the tRNATyr:Ψ35-synthase aPus7 in Archaea of the Sulfolobales order might be rescued by the H/ACA sRNA-guided machinery

Up to now, Ψ formation in tRNAs was found to be catalysed by stand-alone enzymes. By computational analysis of archaeal genomes we detected putative H/ACA sRNAs, in four Sulfolobales species and in Aeropyrum pernix, that might guide Ψ35 formation in pre-tRNA^Tyr(GUA). This modification is achieved by Pus7p in eukarya. The validity of the computational predictions was verified by in vitro reconstitution of H/ACA sRNPs using the identified Sulfolobus solfataricus H/ACA sRNA. Comparison of Pus7-like enzymes encoded by archaeal genomes revealed amino acid substitutions in motifs IIIa and II in Sulfolobales and A. pernix Pus7-like enzymes. These conserved RNA:Ψ-synthase- motifs are essential for catalysis. As expected, the recombinant Pyrococcus abyssi aPus7 was fully active and acted at positions 35 and 13 and other positions in tRNAs, while the recombinant S. solfataricus aPus7 was only found to have a poor activity at position 13. We showed that the presence of an A residue 3′ to the target U residue is required for P. abyssi aPus7 activity, and that this is not the case for the reconstituted S. solfataricus H/ACA sRNP. In agreement with the possible formation of Ψ35 in tRNA^Tyr(GUA) by aPus7 in P. abyssi and by an H/ACA sRNP in S. solfataricus, the A36G mutation in the P. abyssi tRNA^Tyr(GUA) abolished Ψ35 formation when using P. abyssi extract, whereas the A36G substitution in the S. solfataricus pre-tRNA^Tyr did not affect Ψ35 formation in this RNA when using an S. solfataricus extract.     

Archaeal Pus10 proteins can produce both pseudouridine 54 and 55 in tRNA

Pus10, a recently identified pseudouridine (Ψ) synthase, does not belong to any of the five commonly identified families of Ψ synthases. Pyrococcus furiosus Pus10 has been shown to produce Ψ55 in tRNAs. However, in vitro studies have identified another mechanism for tRNA Ψ55 production in Archaea, which uses Cbf5 and other core proteins of the H/ACA ribonucleoprotein complex, in a guide RNA-independent manner. Pus10 homologs have been observed in nearly all sequenced archaeal genomes and in some higher eukaryotes, but not in yeast and bacteria. This coincides with the presence of Ψ54 in the tRNAs of Archaea and higher eukaryotes and its absence in yeast and bacteria. No tRNA Ψ54 synthase has been reported so far. Here, using recombinant Methanocaldococcus jannaschii and P. furiosus Pus10, we show that these proteins can function as synthase for both tRNA Ψ54 and Ψ55. The two modifications seem to occur independently. Salt concentration dependent variations in these activities of both proteins are observed. The Ψ54 synthase activity of M. jannaschii protein is robust, while the same activity of P. furiosus protein is weak. Probable reasons for these differences are discussed. Furthermore, unlike bacterial TruB and yeast Pus4, archaeal Pus10 does not require a U54•A58 reverse Hoogstein base pair and pyrimidine at position 56 to convert tRNA U55 to Ψ55. The homology of eukaryal Pus10 with archaeal Pus10 suggests that the former may also have a tRNA Ψ54 synthase activity.     

Identification and functional implications of pseudouridine RNA modification on small noncoding RNAs in the mammalian pathogen Trypanosoma brucei

Trypanosoma brucei, the parasite that causes sleeping sickness, cycles between an insect and a mammalian host. However, the effect of RNA modifications such as pseudouridinylation on its ability to survive in these two different host environments is unclear. Here, two genome-wide approaches were applied for mapping pseudouridinylation sites (Ψs) on small nucleolar RNA (snoRNA), 7SL RNA, vault RNA, and tRNAs from T. brucei. We show using HydraPsiSeq and RiboMeth-seq that the Ψ on C/D snoRNA guiding 2′-O-methylation increased the efficiency of the guided modification on its target, rRNA. We found differential levels of Ψs on these noncoding RNAs in the two life stages (insect host and mammalian host) of the parasite. Furthermore, tRNA isoform abundance and Ψ modifications were characterized in these two life stages demonstrating stage-specific regulation. We conclude that the differential Ψ modifications identified here may contribute to modulating the function of noncoding RNAs involved in rRNA processing, rRNA modification, protein synthesis, and protein translocation during cycling of the parasite between its two hosts.     

Degradation of ribosomal RNA precursors by the exosome

The yeast exosome is a complex of 3′→5′ exonucleases involved in RNA processing and degradation. All 11 known components of the exosome are required during 3′ end processing of the 5.8S rRNA. Here we report that depletion of each of the individual components inhibits the early pre-rRNA cleavages at sites A₀, A₁, A₂ and A₃, reducing the levels of the 32S, 20S, 27SA₂ and 27SA₃ pre-rRNAs. The levels of the 27SB pre-rRNAs were also reduced. Consequently, both the 18S and 25S rRNAs were depleted. Since none of these processing steps involves 3′→5′ exonuclease activities, the requirement for the exosome is probably indirect. Correct assembly of trans-acting factors with the pre-ribosomes may be monitored by a quality control system that inhibits pre-rRNA processing. The exosome itself degrades aberrant pre-rRNAs that arise from such inhibition. Exosome mutants stabilize truncated versions of the 23S, 21S and A₂-C₂ RNAs, none of which are observed in wild-type cells. The putative helicase Dob1p, which functions as a cofactor for the exosome in pre-rRNA processing, also functions in these pre-rRNA degradation activities.     

The Saccharomyces cerevisiae Pus2 protein encoded by YGL063w ORF is a mitochondrial tRNA:Psi27/28-synthase

The RNA:pseudouridine (Psi)-synthase family is one of the most complex families of RNA modification enzymes. Ten genes encoding putative RNA:Psi-synthases have been identified in S. cerevisiae. Most of the encoded enzymes have been characterized experimentally. Only the putative RNA:Psi-synthase Pus2p (encoded by the YGL063w ORF) had no identified substrate. Here, we analyzed Psi residues in cytoplasmic and mitochondrial tRNAs extracted from S. cerevisiae strains, carrying disruptions in the PUS1 and/or PUS2 ORFs. Our results demonstrate that Pus2p is a mitochondrial-specific tRNA:Psi-synthase acting at positions 27 and 28 in tRNAs. The importance of the Asp56 residue in the conserved ARTD motif of the Pus2p catalytic site is demonstrated in vivo. Interestingly, in spite of the absence of a characteristic N-terminal targeting signal, our data strongly suggest an efficient and rapid targeting of Pus2p in yeast mitochondria. In contradiction with the commonly held idea that a unique nuclear gene encodes the enzyme required for both cytoplasmic and mitochondrial tRNA modifications, here we show the existence of an enzyme specifically dedicated to mitochondrial tRNA modification (Pus2p), the corresponding modification in cytoplasmic tRNAs being catalyzed by another protein (Pus1p).     

UAG readthrough during TMV RNA translation: isolation and sequence of two tRNAs with suppressor activity from tobacco plants

The hypothetical replicase or replicase subunit cistron in the 5'-proximal part of tobacco mosaic virus (TMV) RNA yields a major 126-K protein and a minor 183-K `readthrough' protein in vivo and in vitro. Two natural suppressor tRNAs were purified from uninfected tobacco plants on the basis of their ability to promote readthrough over the corresponding UAG termination codon in vitro. In a reticulocyte lysate the yield of 183-K readthrough protein increases from ˜10% in the absence of added tobacco plant tRNA up to ˜35% in the case of pure tRNA^Tyr added. Their amino acid acceptance and anticodon sequence (GψA) identifies the two natural suppressor tRNAs as the two normal major cytoplasmic tyrosine-specific tRNAs. tRNA^Tyr₁ has an A:U pair at the base of the TψC stem and an unmodified G₁₀, whereas tRNA^Tyr₂ contains a G:C pair in the corresponding location and m²G in position 10. This is the first case that, in a higher eukaryote, the complete structure is known of both the natural suppressor tRNAs and the corresponding viral RNA on which they exert their function. The corresponding codon-anticodon interaction, which is not in accordance with the wobble hypothesis, and the possible biological significance of the readthrough phenomenon is discussed.     

Insertional Editing of Mitochondrial tRNAs of Physarum polycephalum and Didymium nigripes

tRNAs encoded on the mitochondrial DNA of Physarum polycephalum and Didymium nigripes require insertional editing for their maturation. Editing consists of the specific insertion of a single cytidine or uridine relative to the mitochondrial DNA sequence encoding the tRNA. Editing sites are at 14 different locations in nine tRNAs. Cytidine insertion sites can be located in any of the four stems of the tRNA cloverleaf and usually create a G·C base pair. Uridine insertions have been identified in the T loop of tRNA^Lys from Didymium and tRNA^Glu from Physarum. In both tRNAs, the insertion creates the GUUC sequence, which is converted to GTΨC (Ψ = pseudouridine) in most tRNAs. This type of tRNA editing is different from other, previously described types of tRNA editing and resembles the mRNA and rRNA editing in Physarum and Didymium. Analogous tRNAs in Physarum and Didymium have editing sites at different locations, indicating that editing sites have been lost, gained, or both since the divergence of Physarum and Didymium. Although cDNAs derived from single tRNAs are generally fully edited, cDNAs derived from unprocessed polycistronic tRNA precursors often lack some of the editing site insertions. This enrichment of partially edited sequences in unprocessed tRNAs may indicate that editing is required for tRNA processing or at least that RNA editing occurs as an early event in tRNA synthesis.     

Mutation in PNPT1, which Encodes a Polyribonucleotide Nucleotidyltransferase,Impairs RNA Import into Mitochondria and Causes Respiratory-Chain Deficiency

Multiple-respiratory-chain deficiency represents an important cause of mitochondrial disorders. Hitherto, however, mutations in genes involved in mtDNA maintenance and translation machinery only account for a fraction of cases. Exome sequencing in two siblings, born to consanguineous parents, with severe encephalomyopathy, choreoathetotic movements, and combined respiratory-chain defects allowed us to identify a homozygous PNPT1 missense mutation (c.1160A>G) that encodes the mitochondrial polynucleotide phosphorylase (PNPase). Blue-native polyacrylamide gel electrophoresis showed that no PNPase complex could be detected in subject fibroblasts, confirming that the substitution encoded by c.1160A>G disrupts the trimerization of the protein. PNPase is predominantly localized in the mitochondrial intermembrane space and is implicated in RNA targeting to human mitochondria. Mammalian mitochondria import several small noncoding nuclear RNAs (5S rRNA, MRP RNA, some tRNAs, and miRNAs). By RNA hybridization experiments, we observed a significant decrease in 5S rRNA and MRP-related RNA import into mitochondria in fibroblasts of affected subject 1. Moreover, we found a reproducible decrease in the rate of mitochondrial translation in her fibroblasts. Finally, overexpression of the wild-type PNPT1 cDNA in fibroblasts of subject 1 induced an increase in 5S rRNA import in mitochondria and rescued the mitochondrial-translation deficiency. In conclusion, we report here abnormal RNA import into mitochondria as a cause of respiratory-chain deficiency.     

The molecular basis for the differential translation of TMV RNA in tobacco protoplasts and wheat germ extracts

Translation of tobacco mosaic virus (TMV) RNA in tobacco protoplasts yields the 17.5-K coat protein, a 126-K protein and a 183-K protein which is generated by an efficient readthrough over the UAG termination codon at the end of the 126-K cistron. In wheat germ extracts, however, only the 5'-proximal 126-K cistron is translated whereas the 183-K readthrough protein is not synthesized. Purification and sequence analysis of the endogenous tyrosine tRNAs revealed that the uninfected tobacco plant contains two tRNAs^Tyr, both with GΨA anticodons which stimulate the UAG readthrough in vitro and presumably in vivo. In contrast, ˜85% of the tRNA^Tyr from wheat germ contains a QΨA anticodon and ˜15% has a GΨA anticodon. Otherwise the sequences of tRNAs^Tyr from wheat germ and tobacco are identical. UAG readthrough and hence synthesis of the 183-K protein is only stimulated by tRNA^Tyr_GΨA and not at all by tRNA^Tyr_QΨA. The tRNAs^Tyr from wheat leaves were also sequenced. This revealed that adult wheat contains tRNA^Tyr_GΨA only. This is very much in contrast to the situation in animals, where Q-containing tRNAs are characteristic for adult tissues whereas Q deficiency is typical for the neoplastic and embryonic state.     

Identification and characterization of the tRNA:Psi 31-synthase (Pus6p) of Saccharomyces cerevisiae.

To characterize the substrate specificity of the putative RNA:pseudouridine (Psi)-synthase encoded by the Saccharomyces cerevisiae open reading frame (ORF) YGR169c, the corresponding gene was deleted in yeast, and the consequences of the deletion on tRNA and small nuclear RNA modification were tested. The resulting DeltaYGR169c strain showed no detectable growth phenotype, and the only difference in Psi formation in stable cellular RNAs was the absence of Psi at position 31 in cytoplasmic and mitochondrial tRNAs. Complementation of the DeltaYGR169c strain by a plasmid bearing the wild-type YGR169c ORF restored Psi(31) formation in tRNA, whereas a point mutation of the enzyme active site (Asp(168)-->Ala) abolished tRNA:Psi(31)-synthase activity. Moreover, recombinant His(6)-tagged Ygr169 protein produced in Escherichia coli was capable of forming Psi(31) in vitro using tRNAs extracted from the DeltaYGR169c yeast cells as substrates. These results demonstrate that the protein encoded by the S. cerevisiae ORF YGR169c is the Psi-synthase responsible for modification of cytoplasmic and mitochondrial tRNAs at position 31. Because this is the sixth RNA:Psi-synthase characterized thus far in yeast, we propose to rename the corresponding gene PUS6 and the expressed protein Pus6p. Finally, the cellular localization of the green fluorescent protein-tagged Pus6p was studied by functional tests and direct fluorescence microscopy.     

Roles for TbDSS-1 in RNA surveillance and decay of maturation by-products from the 12S rRNA locus

The Trypanosoma brucei exoribonuclease, TbDSS-1, has been implicated in multiple aspects of mitochondrial RNA metabolism. Here, we investigate the role of TbDSS-1 in RNA processing and surveillance by analyzing 12S rRNA processing intermediates in TbDSS-1 RNAi cells. RNA fragments corresponding to leader sequence upstream of 12S rRNA accumulate upon TbDSS-1 depletion. The 5′ extremity of 12S rRNA is generated by endonucleolytic cleavage, and TbDSS-1 degrades resulting upstream maturation by-products. RNAs with 5′ ends at position −141 and 3′ ends adjacent to the mature 5′ end of 12S rRNA are common and invariably possess oligo(U) tails. 12S rRNAs with mature 3′ ends and unprocessed 5′ ends also accumulate in TbDSS-1 depleted cells, suggesting that these RNAs represent dead-end products normally destined for decay by TbDSS-1 in an RNA surveillance pathway. Together, these data indicate dual roles for TbDSS-1 in degradation of 12S rRNA maturation by-products and as part of a mitochondrial RNA surveillance pathway that eliminates stalled 12S processing intermediates. We further provide evidence that TbDSS-1 degrades RNAs originating upstream of the first gene on the minor strand of the mitochondrial maxicircle suggesting that TbDSS-1 also removes non-functional RNAs generated from other regions of the mitochondrial genome.     

Conformational change of pseudouridine 55 synthase upon its association with RNA substrate

Pseudouridine 55 synthase (Ψ55S) catalyzes isomerization of uridine (U) to pseudouridine (Ψ) at position 55 in transfer RNA. The crystal structures of Thermotoga maritima Ψ55S, and its complex with RNA, have been determined at 2.9 and 3.0 Å resolutions, respectively. Structural comparisons with other families of pseudouridine synthases (ΨS) indicate that Ψ55S may acquire its ability to recognize a stem–loop RNA substrate by two insertions of polypeptides into the ΨS core. The structure of apo-Ψ55S reveals that these two insertions interact with each other. However, association with RNA substrate induces substantial conformational change in one of the insertions, resulting in disruption of interaction between insertions and association of both insertions with the RNA substrate. Specific interactions between two insertions, as well as between the insertions and the RNA substrate, account for the molecular basis of the conformational change.     

Characterization of the cold stress-induced cyanobacterial DEAD-box protein CrhC as an RNA helicase

We have shown previously that CrhC is a unique member of the DEAD-box family of RNA helicases whose expression occurs specifically under conditions of cold stress. Here we show that recombinant His-tagged CrhC, purified from Escherichia coli, is an ATP-independent RNA binding protein possessing RNA-dependent ATPase activity which is stimulated most efficiently by rRNA and polysome preparations. RNA strand displacement assays indicate that CrhC possesses RNA unwinding activity that is adenosine nucleotide specific. Unwinding of partially duplexed RNA proceeds in the 5′→3′ but not the 3′→5′ direction using standard assay conditions. Immunoprecipitation and far-western analysis indicate that CrhC is a component of a multisubunit complex, interacting specifically with a 37 kDa polypeptide. We propose that CrhC unwinds cold-stabilized secondary structure in the 5′-UTR of RNA during cold stress.     

Apoptosis-like programmed cell death induces antisense ribosomal RNA (rRNA) fragmentation and rRNA degradation in Leishmania

Few natural antisense (as) RNAs have been reported as yet in the unicellular protozoan Leishmania. Here, we describe that Leishmania produces natural asRNAs complementary to all ribosomal RNA (rRNA) species. Interestingly, we show that drug-induced apoptosis-like programmed cell death triggers fragmentation of asRNA complementary to the large subunit gamma (LSU-γ) rRNA, one of the six 28S rRNA processed fragments in Leishmania. Heat and oxidative stress also induce fragmentation of asrRNA, but to a lesser extent. Extensive asrRNA cleavage correlates with rRNA breakdown and translation inhibition. Indeed, overexpression of asLSU-γ rRNA accelerates rRNA degradation upon induction of apoptosis. In addition, we provide mechanistic insight into the regulation of apoptosis-induced asrRNA fragmentation by a 67 kDa ATP-dependent RNA helicase of the DEAD-box subfamily. This helicase binds both sense (s)LSU-γ and asLSU-γ rRNAs, and appears to have a key role in protecting rRNA from degradation by preventing asrRNA cleavage and thus cell death. Remarkably, the asrRNA fragmentation process operates not only in trypanosomatid protozoa but also in mammals. Our findings uncover a novel mechanism of regulation involving asrRNA fragmentation and rRNA breakdown, that is triggered by apoptosis and conditions of reduced translation under stress, and seems to be evolutionary conserved.     

Fine mapping of the ribosomal RNA genes of HeLa cell mitochondrial DNA

A fine mapping study of the ribosomal RNA region of HeLa cell mitochondrial DNA has been carried out by using as an approach the protection by hybridized 12 S and 16 S rRNA of the complementary sequences in DNA against digestion with the single strand-specific Aspergillus nuclease S₁ or Escherichia coli exonuclease VII. No inserts have been detected in the main body of the 12 S and 16 S rRNA cistrons, in contrast to the situation described in the large mitochondrial ribosomal RNA gene of some strains of yeast and of Neurospora crassa. Furthermore, it has been possible to assign more precisely than previously the positions of the 5′ and 3′-ends of the 12 S rRNA and 16 S rRNA genes in the HpaII restriction map of HeLa cell mitochondrial DNA.