Matrices of paired substitutions show the effects of tRNA D/T loop sequence on Drosophila RNase P and 3'-tRNase processing

Structural basis for sequence-independent substrate selection by eukaryotic wobble base tRNA deaminase ADAT2/3

The essential deamination of adenosine A34 to inosine at the wobble base is the individual tRNA modification with the greatest effects on mRNA decoding, empowering a single tRNA to translate three different codons. To date, many aspects of how eukaryotic deaminases specifically select their multiple substrates remain unclear. Here, using cryo-EM, we present the structure of a eukaryotic ADAT2/3 deaminase bound to a full-length tRNA, revealing that the enzyme distorts the anticodon loop, but in contrast to the bacterial enzymes, selects its substrate via sequence-independent contacts of eukaryote-acquired flexible or intrinsically unfolded motifs distal from the conserved catalytic core. A gating mechanism for substrate entry to the active site is identified. Our multi-step tRNA recognition model yields insights into how RNA editing by A34 deamination evolved, shaped the genetic code, and directly impacts the eukaryotic proteome.

tRNA-like leader-trailer interaction promotes 3'-end maturation of MALAT1

Human metastasis-associated lung adenocarcinoma transcript 1 (MALAT1) is a nuclear long noncoding RNA (lncRNA) that is highly overexpressed in many cancer tissues and plays important roles in tumor progression and metastasis. The MALAT1 primary transcript contains evolutionarily conserved structural elements in its 3'-terminal region: a triple helix forming element called element for nuclear expression (ENE) and a downstream tRNA-like structure called mascRNA. Instead of being polyadenylated, mature MALAT1 is generated by recognition and processing of the mascRNA by RNase P. A genomically encoded A-rich tract at the new 3' end of MALAT1, which is generated upon RNase P cleavage, forms a triple helical structure with the upstream ENE. Triplex formation is vital for stabilization of the mature transcript and for subsequent accumulation and oncogenic activity of MALAT1. Here, we demonstrate that efficient 3'-end maturation of MALAT1 is dependent on an interaction between the A-rich tract and the mascRNA 3' trailer. Using mutational analyses of cell-based reporter accumulation, we show that an extended mascRNA acceptor stem and formation of a single bulged A 5' to the RNase P cleavage site are required for efficient maturation of the nascent MALAT1 3' end. Our results should benefit the development of therapeutic approaches to cancer through targeting MALAT1.

Adaptation of the Romanomermis culicivorax CCA-Adding Enzyme to Miniaturized Armless tRNA Substrates

The mitochondrial genome of the nematode Romanomermis culicivorax encodes for miniaturized hairpin-like tRNA molecules that lack D- as well as T-arms, strongly deviating from the consensus cloverleaf. The single tRNA nucleotidyltransferase of this organism is fully active on armless tRNAs, while the human counterpart is not able to add a complete CCA-end. Transplanting single regions of the Romanomermis enzyme into the human counterpart, we identified a beta-turn element of the catalytic core that-when inserted into the human enzyme-confers full CCA-adding activity on armless tRNAs. This region, originally identified to position the 3'-end of the tRNA primer in the catalytic core, dramatically increases the enzyme's substrate affinity. While conventional tRNA substrates bind to the enzyme by interactions with the T-arm, this is not possible in the case of armless tRNAs, and the strong contribution of the beta-turn compensates for an otherwise too weak interaction required for the addition of a complete CCA-terminus. This compensation demonstrates the remarkable evolutionary plasticity of the catalytic core elements of this enzyme to adapt to unconventional tRNA substrates.

Decoupling tRNA promoter and processing activities enables specific Pol-II Cas9 guide RNA expression

Spatial/temporal control of Cas9 guide RNA expression could considerably expand the utility of CRISPR-based technologies. Current approaches based on tRNA processing offer a promising strategy but suffer from high background. Here, to address this limitation, we present a screening platform which allows simultaneous measurements of the promoter strength, 5', and 3' processing efficiencies across a library of tRNA variants. This analysis reveals that the sequence determinants underlying these activities, while overlapping, are dissociable. Rational design based on the ensuing principles allowed us to engineer an improved tRNA scaffold that enables highly specific guide RNA production from a Pol-II promoter. When benchmarked against other reported systems this tRNA scaffold is superior to most alternatives, and is equivalent in function to an optimized version of the Csy4-based guide RNA release system. The results and methods described in this manuscript enable avenues of research both in genome engineering and basic tRNA biology.

Genome-wide identification and characterization of transfer RNA-derived small RNAs in Plasmodium falciparum

Background

Transfer RNA (tRNA)-derived fragments (tRFs) have been widely identified in nature, functioning in diverse biological and pathological situations. Yet, the presence of these small RNAs in Plasmodium spp. remains unknown. Systematic identification and characterization of tRFs is therefore highly needed to understand further their roles in Plasmodium parasites, particularly in the virulent Plasmodium falciparum parasite.

Results

Genome-wide small RNAs with sizes ranging from 18–30 nucleotides from P. falciparum were deep-sequenced via Illumina HiSeq 2000 technology. In-depth analysis revealed the presence of a vast number of small RNAs originating from tRNA-coding genes, responsible for 22.4% of the total reads as the second predominant group. Three P. falciparum-derived tRF types (ptRFs) were identified as 5'ptRFs, mid-ptRFs and 3'ptRFs. The majority (90%) of ptRFs were derived from tRNAs that coded eight amino acids: Pro, Phe, Asn, Gly, Cys, Gln, His and Ala. Stem-loop reverse transcription polymerase chain reaction further confirmed the presence of tRFs in the blood stages of P. falciparum. Four new motifs with an enriched G/C feature were determined at cleavage sites that might guide the generation of ptRFs.

Conclusions

To our knowledge, this is the first report of a genome-wide investigation of ptRFs from Plasmodium species. The identification of ptRFs reveals a complex small RNA system manipulated by the malaria parasite, and might promote research on the function of tRFs in the pathogenesis of Plasmodium infections.

Electronic supplementary material

The online version of this article (10.1186/s13071-019-3301-6) contains supplementary material, which is available to authorized users.

RNase MRP cleaves pre-tRNASer-Met in the tRNA maturation pathway

Ribonuclease mitochondrial RNA processing (RNase MRP) is a multifunctional ribonucleoprotein (RNP) complex that is involved in the maturation of various types of RNA including ribosomal RNA. RNase MRP consists of a potential catalytic RNA and several protein components, all of which are required for cell viability. We show here that the temperature-sensitive mutant of rmp1, the gene for a unique protein component of RNase MRP, accumulates the dimeric tRNA precursor, pre-tRNA^Ser-Met. To examine whether RNase MRP mediates tRNA maturation, we purified the RNase MRP holoenzyme from the fission yeast Schizosaccharomyces pombe and found that the enzyme directly and selectively cleaves pre-tRNA^Ser-Met, suggesting that RNase MRP participates in the maturation of specific tRNA in vivo. In addition, mass spectrometry–based ribonucleoproteomic analysis demonstrated that this RNase MRP consists of one RNA molecule and 11 protein components, including a previously unknown component Rpl701. Notably, limited nucleolysis of RNase MRP generated an active catalytic core consisting of partial mrp1 RNA fragments, which constitute “Domain 1” in the secondary structure of RNase MRP, and 8 proteins. Thus, the present study provides new insight into the structure and function of RNase MRP.

Tethered domains and flexible regions in tRNase Z(L), the long form of tRNase Z

tRNase Z, a member of the metallo-β-lactamase family, endonucleolytically removes the pre-tRNA 3′ trailer in a step central to tRNA maturation. The short form (tRNase Z^S) is the only one found in bacteria and archaebacteria and is also present in some eukaryotes. The homologous long form (tRNase Z^L), exclusively found in eukaryotes, consists of related amino- and carboxy-domains, suggesting that tRNase Z^L arose from a tandem duplication of tRNase Z^S followed by interdependent divergence of the domains. X-ray crystallographic structures of tRNase Z^S reveal a flexible arm (FA) extruded from the body of tRNase Z remote from the active site that binds tRNA far from the scissile bond. No tRNase Z^L structures have been solved; alternative biophysical studies are therefore needed to illuminate its functional characteristics. Structural analyses of tRNase Z^L performed by limited proteolysis, two dimensional gel electrophoresis and mass spectrometry establish stability of the amino and carboxy domains and flexibility of the FA and inter-domain tether, with implications for tRNase Z^L function.

Pathogenesis-related mutations in the T-loops of human mitochondrial tRNAs affect 3' end processing and tRNA structure

Numerous mutations in the mitochondrial genome are associated with maternally transmitted diseases and syndromes that affect muscle and other high energy-demand tissues. The mitochondrial genome encodes 13 polypeptides, 2 rRNAs and 22 interspersed tRNAs via long bidirectional polycistronic primary transcripts, requiring precise excision of the tRNAs. Despite making up only ~10% of the mitochondrial genome, tRNA genes harbor most of the pathogenesis-related mutations. tRNase Z endonucleolytically removes the pre-tRNA 3' trailer. The flexible arm of tRNase Z recognizes and binds the elbow (including the T-loop) of pre-tRNA. Pathogenesis-related T-loop mutations in mitochondrial tRNAs could thus affect tRNA structure, reduce tRNase Z binding and 3' processing, and consequently slow mitochondrial protein synthesis. Here we inspect the effects of pathogenesis-related mutations in the T-loops of mitochondrial tRNAs on pre-tRNA structure and tRNase Z processing. Increases in K(M) arising from 59A > G substitutions in mitochondrial tRNA(Gly) and tRNA(Ile) accompany changes in T-loop structure, suggesting impaired substrate binding to enzyme.

Filtering of deep sequencing data reveals the existence of abundant Dicer-dependent small RNAs derived from tRNAs

Deep sequencing technologies such as Illumina, SOLiD, and 454 platforms have become very powerful tools in discovering and quantifying small RNAs in diverse organisms. Sequencing small RNA fractions always identifies RNAs derived from abundant RNA species such as rRNAs, tRNAs, snRNA, and snoRNA, and they are widely considered to be random degradation products. We carried out bioinformatic analysis of deep sequenced HeLa RNA and after quality filtering, identified highly abundant small RNA fragments, derived from mature tRNAs that are likely produced by specific processing rather than from random degradation. Moreover, we showed that the processing of small RNAs derived from tRNA(Gln) is dependent on Dicer in vivo and that Dicer cleaves the tRNA in vitro.

Effect of changes in the flexible arm on tRNase Z processing kinetics

tRNAs are transcribed as precursors and processed in a series of reactions culminating in aminoacylation and translation. Central to tRNA maturation, the 3' end trailer can be endonucleolytically removed by tRNase Z. A flexible arm (FA) extruded from the body of tRNase Z consists of a structured alphaalphabetabeta hand that binds the elbow of pre-tRNA. Deleting the FA hand causes an almost 100-fold increase in Km with little change in kcat, establishing its contribution to substrate recognition/binding. Remarkably, a 40-residue Ala scan through the FA hand reveals a conserved leucine at the ascending stalk/hand boundary that causes practically the same increase in Km as the hand deletion, thus nearly eliminating its ability to bind substrate. Km also increases with substitutions in the GP (alpha4-alpha5) loop and at other conserved residues in the FA hand predicted to contact substrate based on the co-crystal structure. Substitutions that reduce kcat are clustered in the beta10-beta11 loop.

The mitochondrial genome of the screamer louse Bothriometopus (phthiraptera: ischnocera): effects of extensive gene rearrangements on the evolution of the genome

Mitochondrial (mt) genome rearrangement has generally been studied with respect to the phenomenon itself, focusing on their phylogenetic distribution and causal mechanisms. Rearrangements have additional significance through effects on substitution, transcription, and mRNA processing. Lice are an ideal group in which to study the interactions between rearrangements and these factors due to the heightened rearrangement rate within this group. The entire mt genome of the screamer louse Bothriometopus was sequenced and compared to previously sequenced louse genomes. The mt genome is 15,564 bp, circular, and all genes are encoded on the same strand. The gene arrangement differs radically from both other louse species and the ancestral insect. Nucleotide composition is A+T biased, but there is no skew which may be due to reversal of replication direction or a transcriptional effect. Bothriometopus has both tRNA duplication and concerted evolution which has not been observed previously. Eleven of the 13 protein-coding genes have 3' end stem-loop structures which may allow mRNA processing without flanking tRNAs and so facilitate gene rearrangements. There are five candidate control regions capable of forming stem-loop structures. Two are structurally more similar to the control regions of other insect species than those of other lice. Analyses of Bothriometopus demonstrate that louse mt genomes, in addition to being extensively rearranged, differ significantly from most insect species in nucleotide composition biases, tRNA evolution, protein-coding gene structures and putative signaling sites such as the control region. These may be either a cause or a consequence of gene rearrangements.

Active suppressor tRNAs with a double helix between the D- and T-loops

One of the most conserved elements of the tRNA structure is the reverse-Hoogsteen base-pair T54--A58 in the T-loop, which plays a major role in the maintenance of the standard L-shape conformation. Here, we present the results of in vivo selection of 51 active suppressor tRNA clones, none of which contains base-pair T54--A58. In 49 clones, we found two regions in the D and T-loops that are complementary to each other. This finding suggests the existence of an inter-loop double helix consisting of three base-pairs, which could have the same role as base-pair T54--A58 in the fixation of the juxtaposition of the two helical domains within the L-shape. From this point of view, the appearance of the inter-loop double helix represents a compensatory effect for the absence of base-pair T54--A58. The results shed new light on the role of different elements of the tRNA structure in the formation of the standard L-shape conformation and on the possibility of synonymous replacements of one arrangement by another in functional RNA molecules.

Nucleases of the metallo-beta-lactamase family and their role in DNA and RNA metabolism

Proteins of the metallo-beta-lactamase family with either demonstrated or predicted nuclease activity have been identified in a number of organisms ranging from bacteria to humans and has been shown to be important constituents of cellular metabolism. Nucleases of this family are believed to utilize a zinc-dependent mechanism in catalysis and function as 5' to 3' exonucleases and or endonucleases in such processes as 3' end processing of RNA precursors, DNA repair, V(D)J recombination, and telomere maintenance. Examples of metallo-beta-lactamase nucleases include CPSF-73, a known component of the cleavage/polyadenylation machinery, which functions as the endonuclease in 3' end formation of both polyadenylated and histone mRNAs, and Artemis that opens DNA hairpins during V(D)J recombination. Mutations in two metallo-beta-lactamase nucleases have been implicated in human diseases: tRNase Z required for 3' processing of tRNA precursors has been linked to the familial form of prostate cancer, whereas inactivation of Artemis causes severe combined immunodeficiency (SCID). There is also a group of as yet uncharacterized proteins of this family in bacteria and archaea that based on sequence similarity to CPSF-73 are predicted to function as nucleases in RNA metabolism. This article reviews the cellular roles of nucleases of the metallo-beta-lactamase family and the recent advances in studying these proteins.

When all's zed and done: the structure and function of RNase Z in prokaryotes

RNase Z is a widely distributed and often essential endoribonuclease that is responsible for the maturation of the 3'-end of a large family of transfer RNAs (tRNAs). Although it has been the subject of study for more than 25 years, interest in this enzyme intensified dramatically with the identification of the encoding gene in 2002. This led to the discovery of RNase Z in bacteria, in which the final step in the generation of the mature 3'-end of tRNAs had previously been assumed to be catalysed by exoribonucleases. It also led inevitably to structural studies, and the recent resolution of the structure of RNase Z in complex with tRNA has provided a detailed understanding of the molecular mechanisms of RNase Z substrate recognition and cleavage. The identification of the RNase Z gene also allowed the search for alternative substrates for this enzyme to begin in earnest. In this Review, we outline the important recent developments that have contributed to our understanding of this enzyme, particularly in prokaryotes.

Residues in two homology blocks on the amino side of the tRNase Z His domain contribute unexpectedly to pre-tRNA 3' end processing

tRNase Z, which can endonucleolytically remove pre-tRNA 3'-end trailers, possesses the signature His domain (HxHxDH; Motif II) of the beta-lactamase family of metal-dependent hydrolases. Motif II combines with Motifs III-V on its carboxy side to coordinate two divalent metal ions, constituting the catalytic core. The PxKxRN loop and Motif I on the amino side of Motif II have been suggested to modulate tRNase Z activity, including the anti-determinant effect of CCA in mature tRNA. Ala walks through these two homology blocks reveal residues in which the substitutions unexpectedly reduce catalytic efficiency. While substitutions in Motif II can drastically affect k(cat) without affecting k(M), five- to 15-fold increases in k(M) are observed with substitutions in several conserved residues in the PxKxRN loop and Motif I. These increases in k(M) suggest a model for substrate binding. Expressed tRNase Z processes mature tRNA with CCA at the 3' end approximately 80 times less efficiently than a pre-tRNA possessing natural sequence of the 3'-end trailer, due to reduced k(cat) with no effect on k(M), showing the CCA anti-determinant to be a characteristic of this enzyme.

Accurate energies of hydrogen bonded nucleic acid base pairs and triplets in tRNA tertiary interactions

Tertiary interactions are crucial in maintaining the tRNA structure and functionality. We used a combined sequence analysis and quantum mechanics approach to calculate accurate energies of the most frequent tRNA tertiary base pairing interactions. Our analysis indicates that six out of the nine classical tertiary interactions are held in place mainly by H-bonds between the bases. In the remaining three cases other effects have to be considered. Tertiary base pairing interaction energies range from -8 to -38 kcal/mol in yeast tRNA(Phe) and are estimated to contribute roughly 25% of the overall tRNA base pairing interaction energy. Six analyzed posttranslational chemical modifications were shown to have minor effect on the geometry of the tertiary interactions. Modifications that introduce a positive charge strongly stabilize the corresponding tertiary interactions. Non-additive effects contribute to the stability of base triplets.

Naturally occurring mutations in human mitochondrial pre-tRNASer(UCN) can affect the transfer ribonuclease Z cleavage site, processing kinetics, and substrate secondary structure

tRNAs are transcribed as precursors with a 5' end leader and a 3' end trailer. The 5' end leader is processed by RNase P, and in most organisms in all three kingdoms, transfer ribonuclease (tRNase) Z can endonucleolytically remove the 3' end trailer. Long ((L)) and short ((S)) forms of the tRNase Z gene are present in the human genome. tRNase Z(L) processes a nuclear-encoded pre-tRNA approximately 1600-fold more efficiently than tRNase Z(S) and is predicted to have a strong mitochondrial transport signal. tRNase Z(L) could, thus, process both nuclear- and mitochondrially encoded pre-tRNAs. More than 150 pathogenesis-associated mutations have been found in the mitochondrial genome, most of them in the 22 mitochondrially encoded tRNAs. All the mutations investigated in human mitochondrial tRNA(Ser(UCN)) affect processing efficiency, and some affect the cleavage site and secondary structure. These changes could affect tRNase Z processing of mutant pre-tRNAs, perhaps contributing to mitochondrial disease.

Residues in the conserved His domain of fruit fly tRNase Z that function in catalysis are not involved in substrate recognition or binding

Transfer RNAs are transcribed as precursors with extensions at both the 5' and 3' ends. RNase P removes endonucleolytically the 5' end leader. tRNase Z can remove endonucleolytically the 3' end trailer as a necessary step in tRNA maturation. CCA is not transcriptionally encoded in the tRNAs of eukaryotes, archaebacteria and some bacteria and must be added by a CCA-adding enzyme after removal of the 3' end trailer. tRNase Z is a member of the beta-lactamase family of metal-dependent hydrolases, the signature sequence of which, the conserved histidine cluster (HxHxDH), is essential for activity. Starting with baculovirus-expressed fruit fly tRNase Z, we completed an 18 residue Ala scan of the His cluster to analyze the functional landscape of this critical region. Residues in and around the His cluster fall into three categories based on effects of the substitutions on processing efficiency: substitutions in eight residues have little effect, five substitutions reduce efficiency moderately (approximately 5-50-fold), while substitutions in five conserved residues, one serine, three histidine and one aspartate, severely reduce efficiency (approximately 500-5000-fold). Wild-type and mutant dissociation constants (Kd values), determined using gel shifts, displayed no substantial differences, and were of the same order as kM (2-20 nM). Lower processing efficiencies arising from substitutions in the His domain are almost entirely due to reduced kcat values; conserved, functionally important residues within the His cluster of tRNase Z are thus involved in catalysis, and substrate recognition and binding functions must reside elsewhere in the protein.

Co-evolution of tRNA 3' trailer sequences with 3' processing enzymes in bacteria

Maturation of the tRNA 3' terminus is a complicated process in bacteria. Usually, it is initiated by an endonucleolytic cleavage carried out by RNase E and Z in different bacteria. In Escherichia coli, RNase E cleaves AU-rich sequences downstream of tRNA, producing processing intermediates with a few extra residues at the 3' end; these are then removed by exoribonuclease trimming to generate the mature 3' end. Here we show that essentially all E. coli tRNA precursors contain a potential RNase E cleavage site, the AU-rich sequence element (AUE), in the 3' trailer. This suggests that RNase E cleavage and exonucleolytic trimming is a general pathway for tRNA maturation in this organism. Remarkably, the AUE immediately downstream of each tRNA is selectively conserved in bacteria having RNase E and tRNA-specific exoribonucleases, suggesting that this pathway for tRNA processing is also commonly used in these bacteria. Two types of RNase E-like proteins are identified in actinobacteria and the alpha-subdivision of proteobacteria. The tRNA 3' proximal AUE is conserved in bacteria with only one type of E-like protein. Selective conservation of the AUE is usually not observed in bacteria without RNase E. These results demonstrate a novel example of co-evolution of RNA sequences with processing activities.

The T loop structure is dispensable for substrate recognition by tRNase ZL

tRNA 3'-processing endoribonucleases (tRNase Z, or 3'-tRNase; EC 3.1.26.11) are enzymes that remove 3'-trailers from pre-tRNAs. An about 12-base-pair stem, a T loop-like structure, and a 3'-trailer were considered to be the minimum requirements for recognition by the long form (tRNase ZL) of tRNase Z; tRNase ZL can recognize and cleave a micro-pre-tRNA or a hooker/target RNA complex that resembles a micro-pre-tRNA. We examined four hook RNAs containing systematically weakened T stems for directing target RNA cleavage by tRNase ZL. As expected, the cleavage efficiency decreased with the decrease in T stem stability, and to our surprise, even the hook RNA that forms no T stem-loop-directed slight cleavage of the target RNA, suggesting that the T stem-loop structure is important but dispensable for substrate recognition by tRNase ZL. To analyze the effect of the T loop on substrate recognition, we compared the cleavage reaction for a micro-pre-tRNA with that for a 12-base-pair double-stranded RNA, which is the same as the micro-pre-tRNA except for the lack of the T loop structure. The observed rate constant value for the double-stranded RNA was comparable with that for the micro-pre-tRNA, whereas the K(d) value for the complex with the double-stranded RNA was much higher than that for the complex with the micro-pre-tRNA. These results suggest that the T loop structure is not indispensable for the recognition, although the interaction between the T loop and the enzyme exists. Cleavage assays for such double-stranded RNA substrates of various lengths suggested that tRNase ZL can recognize and cleave double-stranded RNA substrates that are longer than 5 base pairs and shorter than 20 base pairs. We also showed that double-stranded RNA is not a substrate for the short form of tRNase Z.

Specific and non-specific purine trap in the T-loop of normal and suppressor tRNAs

To elucidate the general constraints imposed on the structure of the D and T-loops in functional tRNAs, active suppressor tRNAs were selected in vivo from a combinatorial tRNA gene library in which several nucleotide positions in these loops were randomized. Analysis of the nucleotide sequences of the selected clones demonstrates that most of them contain combination U54-A58 allowing the formation of the standard reverse-Hoogsteen base-pair 54-58 in the T-loop. With only one exception, all these clones fall into two groups, each characterized by a distinct sequence pattern. Analysis of these two groups has allowed us to suggest two different types of nucleotide arrangement in the DT region. The first type, the so-called specific purine trap, is found in 12 individual tRNA clones and represents a generalized version of the standard D-T loop interaction. It consists of purine 18 sandwiched between the reverse-Hoogsteen base-pair U54-A58 and purine 57. The identity of purine 18 is restricted by the specific base-pairing with nucleotide 55. Depending on whether nucleotide 55 is U or G, purine 18 should be, respectively, G or A. The second structural type, the so-called non-specific purine trap, corresponds to the nucleotide sequence pattern found in 16 individual tRNA clones and is described here for the first time. It consists of purine 18 sandwiched between two reverse-Hoogsteen base-pairs U54-A58 and A55-C57 and, unlike the specific purine trap, requires the T-loop to contain an extra eighth nucleotide. Since purine 18 does not form a base-pair in the non-specific purine trap, both purines, G18 and A18, fit to the structure equally well. The important role of both the specific and non-specific purine traps in the formation of the tRNA L-shape is discussed.

The N-terminal half-domain of the long form of tRNase Z is required for the RNase 65 activity

Transfer RNA (tRNA) 3' processing endoribonuclease (tRNase Z) is an enzyme responsible for the removal of a 3' trailer from pre-tRNA. There exists two types of tRNase Z: one is a short form (tRNase ZS) that consists of 300-400 amino acids, and the other is a long form (tRNase ZL) that contains 800-900 amino acids. Here we investigated whether the short and long forms have different preferences for various RNA substrates. We examined three recombinant tRNase ZSs from human, Escherichia coli and Thermotoga maritima, two recombinant tRNase ZLs from human and Saccharomyces cerevisiae, one tRNase ZL from pig liver, and the N- and C-terminal half regions of human tRNase ZL for cleavage of human micro-pre-tRNA(Arg) and the RNase 65 activity. All tRNase ZLs cleaved the micro-pre-tRNA and showed the RNase 65 activity, while all tRNase ZSs and both half regions of human tRNase ZL failed to do so with the exception of the C-terminal half, which barely cleaved the micro-pre-tRNA. We also show that only the long forms of tRNase Z can specifically cleave a target RNA under the direction of a new type of small guide RNA, hook RNA. These results indicate that indeed tRNase ZL and tRNase ZS have different substrate specificities and that the differences are attributed to the N-terminal half-domain of tRNase ZL. Furthermore, the optimal concentrations of NaCl, MgCl2 and MnCl2 differed between tRNase ZSs and tRNase ZLs, and the K(m) values implied that tRNase ZLs interact with pre-tRNA substrates more strongly than tRNase ZSs.

Key elements in maintenance of the tRNA L-shape

Based on in vivo selection of effective suppressor tRNAs from two different combinatorial gene libraries in which several nucleotides in the D and T-loops were randomized, we show that the position of the reverse-Hoogsteen base-pair in the T-loop, normally formed between nucleotides 54-58, co-varies with the length of the D-domain. When the D-domain has the normal length, the position of the reverse-Hoogsteen base-pair in the T-loop is always such that it allocates two unpaired nucleotides 59-60 for the bulge that fills the space between the D and T-domains. However, when the D-domain becomes shorter, the position of the reverse-Hoogsteen base-pair changes in the way that more nucleotides are now allocated to the T-loop bulge, so that the total length of the D-domain and of the bulge remains the same. Such compensation guarantees that in all tRNAs, the D and T-domains are always juxtaposed in the standard way. It also demonstrates the major role of the two T-loop elements, the bulge and the reverse-Hoogsteen base-pair, in the formation of the canonical tRNA L-shape.

A pathogenesis-associated mutation in human mitochondrial tRNALeu(UUR) leads to reduced 3'-end processing and CCA addition

Point mutations in mitochondrial tRNAs can cause severe multisystemic disorders such as mitochondrial encephalomyopathy with lactic acidosis and stroke-like episodes (MELAS) and myoclonus epilepsy with ragged-red fibers (MERRF). Some of these mutations impair one or more steps of tRNA maturation and protein biosynthesis including 5'-end-processing, post-transcriptional base modification, structural stability, aminoacylation, and formation of tRNA-ribosomal complexes. tRNALeu(UUR), an etiologic hot spot for such diseases, harbors 20 of more than 90 disease-associated mutations described to date. Here, the pathogenesis-associated base substitutions A3243G, T3250C, T3271C, A3302G and C3303T within this tRNA were tested for their effects on endonucleolytic 3'-end processing and CCA addition at the tRNA 3'-terminus. Whereas mutations A3243G, A3302G and C3303T reduced the efficiency of 3'-end cleavage, only the C3303T substitution was a less efficient substrate for CCA addition. These results support the view that pathogenesis may be elicited through cumulative effects of tRNA mutations: a mutation can impede several pre-tRNA processing steps, with each such reduction contributing to the overall impairment of tRNA function.

A novel endonucleolytic mechanism to generate the CCA 3' termini of tRNA molecules in Thermotoga maritima

The tRNA 3'-terminal CCA sequence is essential for aminoacylation of the tRNAs and for translation on the ribosome. The tRNAs are transcribed as larger precursor molecules containing 5' and 3' extra sequences. In the tRNAs that do not have the encoded CCA, the 3' extra sequence after the discriminator nucleotide is usually cleaved off by the tRNA 3' processing endoribonuclease (3' tRNase, or RNase Z), and the 3'-terminal CCA residues are added thereto. Here we analyzed Thermotoga maritima 3' tRNase for enzymatic properties using various pre-tRNAs from T. maritima, in which all 46 tRNA genes encode CCA with only one exception. We found that the enzyme has the unprecedented activity that cleaves CCA-containing pre-tRNAs precisely after the CCA sequence, not after the discriminator. The assays for pre-tRNA variants suggest that the CA residues at nucleotides 75 and 76 are required for the enzyme to cleave pre-tRNAs after A at nucleotide 76 and that the cleavage occurs after nucleotide 75 if the sequence is not CA. Intriguingly, the pre-tRNA(Met) that is the only T. maritima pre-tRNA without the encoded CCA was cleaved after the discriminator. The kinetics data imply the existence of a CCA binding domain in T. maritima 3' tRNase. We also identified two amino acid residues critical for the cleavage site selection and several residues essential for the catalysis. Analysis of cleavage sites by 3' tRNases from another eubacteria Escherichia coli and two archaea Thermoplasma acidophilum and Pyrobaculum aerophilum corroborates the importance of the two amino acid residues for the cleavage site selection.

Endonucleolytic processing of CCA-less tRNA precursors by RNase Z in Bacillus subtilis

In contrast to Escherichia coli, where the 3' ends of tRNAs are primarily generated by exoribonucleases, maturation of the 3' end of tRNAs is catalysed by an endoribonuclease, known as RNase Z (or 3' tRNase), in many eukaryotic and archaeal systems. RNase Z cleaves tRNA precursors 3' to the discriminator base. Here we show that this activity, previously unsuspected in bacteria, is encoded by the yqjK gene of Bacillus subtilis. Decreased yqjK expression leads to an accumulation of a population of B.subtilis tRNAs in vivo, none of which have a CCA motif encoded in their genes, and YqjK cleaves tRNA precursors with the same specificity as plant RNase Z in vitro. We have thus renamed the gene rnz. A CCA motif downstream of the discriminator base inhibits RNase Z activity in vitro, with most of the inhibition due to the first C residue. Lastly, tRNAs with long 5' extensions are poor substrates for cleavage, suggesting that for some tRNAs, processing of the 5' end by RNase P may have to precede RNase Z cleavage.

Decreased CCA-addition in human mitochondrial tRNAs bearing a pathogenic A4317G or A10044G mutation

Pathogenic point mutations in mitochondrial tRNA genes are known to cause a variety of human mitochondrial diseases. Reports have associated an A4317G mutation in the mitochondrial tRNA(Ile) gene with fatal infantile cardiomyopathy and an A10044G mutation in the mitochondrial tRNA(Gly) gene with sudden infant death syndrome. Here we demonstrate that both mutations inhibit in vitro CCA-addition to the respective tRNA by the human mitochondrial CCA-adding enzyme. Structures of these two mutant tRNAs were examined by nuclease probing. In the case of the A4317G tRNA(Ile) mutant, structural rearrangement of the T-arm region, conferring an aberrantly stable T-arm structure and an increased T(m) value, was clearly observed. In the case of the A10044G tRNA(Gly) mutant, high nuclease sensitivity in both the T- and D-loops suggested a weakened interaction between the loops. These are the first reported instances of inefficient CCA-addition being one of the apparent molecular pathogeneses caused by pathogenic point mutations in human mitochondrial tRNA genes.

Recombinant RNase Z does not recognize CCA as part of the tRNA and its cleavage efficieny is influenced by acceptor stem length

One of the essential maturation steps to yield functional tRNA molecules is the removal of 3'-trailer sequences by RNase Z. After RNase Z cleavage the tRNA nucleotidyl transferase adds the CCA sequence to the tRNA 3'-terminus, thereby generating the mature tRNA. Here we investigated whether a terminal CCA triplet as 3'-trailer or embedded in a longer 3'-trailer influences cleavage site selection by RNase Z using three activities: a recombinant plant RNase Z, a recombinant archaeal RNase Z and an RNase Z active wheat extract. A trailer of only the CCA trinucleotide is left intact by the wheat extract RNase Z but is removed by the recombinant plant and archaeal enzymes. Thus the CCA triplet is not recognized by the RNase Z enzyme itself, but rather requires cofactors still present in the extract. In addition, we investigated the influence of acceptor stem length on cleavage by RNase Z using variants of wild-type tRNATyr. While the wild type and the variant with 8 base pairs in the acceptor stem were processed efficiently by all three activities, variants with shorter and longer acceptor stems were poor substrates or were not cleaved at all.

In vitro 3'-end endonucleolytic processing defect in a human mitochondrial tRNA(Ser(UCN)) precursor with the U7445C substitution, which causes non-syndromic deafness

Eukaryotic tRNAs are transcribed as precursors. A 5'-end leader and 3'-end trailer are endonucleolytically removed by RNase P and 3'-tRNase before 3'-end CCA addition, aminoacylation, nuclear export and translation. 3'-End -CC can be a 3'-tRNase anti-determinant with the ability to prevent mature tRNA from recycling through 3'-tRNase. Twenty-two tRNAs punctuate the two rRNAs and 13 mRNAs in long, bidirectional mitochondrial transcripts. Accurate mitochondrial gene expression thus depends on endonucleolytic excision of tRNAs. Various mitochondrial diseases and syndromes could arise from defective tRNA end processing. The U7445C substitution in the human mitochondrial L-strand transcript (U74C directly following the discriminator base of tRNA(Ser(UCN))) causes non-syndromic deafness. The sequence of the precursor (G/UCU) becomes G/CCU, resembling a 3'-tRNase anti-determinant. We demonstrate that a tRNA(Ser(UCN)) precursor with the U7445C substitution cannot be processed in vitro by 3'-tRNase from human mitochondria. A 3'-end processing defect in this tRNA precursor could thus be responsible for mitochondrial disease.

The plant tRNA 3' processing enzyme has a broad substrate spectrum

To elucidate the minimal substrate for the plant nuclear tRNA 3' processing enzyme, we synthesized a set of tRNA variants, which were subsequently incubated with the nuclear tRNA 3' processing enzyme. Our experiments show that the minimal substrate for the nuclear RNase Z consists of the acceptor stem and T arm. The broad substrate spectrum of the nuclear RNase Z raises the possibility that this enzyme might have additional functions in the nucleus besides tRNA 3' processing. Incubation of tRNA variants with the plant mitochondrial enzyme revealed that the organellar counterpart of the nuclear enzyme has a much narrower substrate spectrum. The mitochondrial RNase Z only tolerates deletion of anticodon and variable arms and only with a drastic reduction in cleavage efficiency, indicating that the mitochondrial activity can only cleave bona fide tRNA substrates efficiently. Both enzymes prefer precursors containing short 3' trailers over extended 3' additional sequences. Determination of cleavage sites showed that the cleavage site is not shifted in any of the tRNA variant precursors.

The effects of matrices of paired substitutions in mid-acceptor stem on Drosophila tRNA(His) structure and end-processing

End-maturation reactions, in which the 5' end leader and 3' end trailer of precursor tRNA are removed by RNase P and 3'-tRNase, respectively, are early, essential steps in eukaryotic precursor tRNA processing. End-processing enzymes may be expected to contact the acceptor stem of tRNA due to its proximity to both cleavage sites. We constructed matrices of pair-wise substitutions in mid-acceptor stem at nt 3/70 and 4/69 of Drosophila tRNA(His) and analyzed their ability to be processed by Drosophila RNase P and 3'-tRNase. In accord with our earlier study of D/T loop processing matrices, we find that tRNA end processing enzymes respond to sequence changes differently. More processing defects were observed with 3'-tRNase than with RNase P, and substitutions at 4/69 reduced processing more than those at 3/70. We evaluated tRNA folding using structure probing nucleases and investigated the contribution of K(M) and V(Max) to the processing efficiency of selected variants. In one substitution (C3A), mis-folding correlates with processing defects. In another (C69A), a disruption of structure appears to be transmitted laterally to both ends of the acceptor stem. Poor processing of C69A by RNase P is due entirely to a reduction in V(Max), but for 3'-tRNase, it is due to an increase in K(M).

In vitro hyperprocessing of Drosophila tRNAs by the catalytic RNA of RNase P the cloverleaf structure of tRNA is not always stable?

We have previously reported that the catalytic RNA subunit of RNase P of Escherichia coli (M1 RNA) cleaves Drosophila initiator methionine tRNA (tRNA(Met)i) within the mature tRNA sequence to produce specific fragments. This cleavage was dependent on the occurrence of an altered conformation of the tRNA substrate. We call this further cleavage hyperprocessing. In the present paper, to search for another tRNA that can be hyperprocessed in vitro, we used total mature tRNAs from Drosophila as substrates for the in vitro M1 RNA reaction. We found that some tRNAs can be hyperprocessed by M1 RNA and that two such tRNAs are an alanine tRNA and a histidine tRNA. Using mutant substrates of these tRNAs, we also show that the hyperprocessing by M1 RNA is dependent on the occurrence of altered conformations of these tRNAs. The altered conformations were very similar to that of tRNA(Met)i. We show here that M1 RNA can be used as a powerful tool to detect the alternative conformation of tRNAs. The relationship between these hyperprocessing reactions and stability of the tRNA structure will also be discussed.

Minimum requirements for substrates of mammalian tRNA 3' processing endoribonuclease

Mammalian tRNA 3' processing endoribonuclease (3' tRNase) removes a 3' trailer after the discriminator nucleotide from precursor tRNA (pre-tRNA). To elucidate the minimum requirements for 3' tRNase substrates, we tested small pre-tRNA(Arg) substrates lacking the D and anticodon stem-loop domain for cleavage by purified pig 3' tRNase. A small pre-tRNA (R-ATW) composed of an acceptor stem, an extra loop, a T stem-loop domain, a discriminator nucleotide, and a 3' trailer was cleaved more efficiently than the full-length wild type. The catalytic efficiencies of three R-ATW derivatives, which were constructed to destroy the original T stem base pairs, were also higher than that of the full-length wild type. Pig 3' tRNase efficiently processed a "minihelix" (R-ATM5) that consists of a T stem-loop domain, an acceptor stem, a discriminator nucleotide, and a 3' trailer, while the enzyme never cleaved a "microhelix" that is composed of a T loop, an acceptor stem, a discriminator nucleotide, and a 3' trailer. Five R-ATM5 derivatives that have one to seven base substitutions in the T loop were all cleaved slightly more efficiently than the full-length wild type and slightly less efficiently than R-ATM5. A helix ("minihelixDelta1") one base pair smaller than minihelices was a good substrate, while small helices containing a continuous 10-base pair stem were poor substrates. The cleavage of these three small substrates occurred after the discriminator and one to three nucleotides downstream of the discriminator. From these results, we conclude that minimum substrates for efficient cleavage by mammalian 3' tRNase are minihelices or minihelicesDelta1, in which there seem to be no essential bases.

Selection of cleavage site by mammalian tRNA 3' processing endoribonuclease

Mammalian tRNA 3' processing endoribonuclease (3' tRNase) removes 3' trailers from pre-tRNAs by cleaving the RNA immediately downstream of the discriminator nucleotide. Although 3' tRNase can recognize and cleave any target RNA that forms a pre-tRNA-like complex with another RNA, in some cases cleavage occurs at multiple sites near the discriminator. We investigated what features of pre-tRNA determine the cleavage site using various pre-tRNAArg variants and purified pig enzyme. Because the T stem-loop and the acceptor stem plus a 3' trailer are sufficient for recognition by 3' tRNase, we constructed variants that had additions and/or deletions of base-pairs in the T stem and/or the acceptor stem. Pre-tRNAs lacking one and two acceptor stem base-pairs were cleaved one and two nucleotides and two and three nucleotides, respectively, downstream of the discriminator. On the other hand, pre-tRNA variants containing extra acceptor stem base-pairs were cleaved only after the discriminator. The cleavage site was shifted to one and two nucleotides downstream of the discriminator by deleting one base-pair from the T stem, but was not changed by additional base-pairs in the T stem. Pre-tRNA variants that contained an eight base-pair acceptor stem plus a six base-pair T stem, an eight base-pair acceptor stem plus a four base-pair T stem, or a six base-pair acceptor stem plus a six base-pair T stem were all cleaved after the original nucleotide. In general, pre-tRNA variants containing a total of more than 11 bp in the acceptor stem and the T stem were cleaved only after the discriminator, and pre-tRNA variants with a total of N bp (N is less than 12) were cleaved 12-N and 13-N nt downstream of the discriminator. Cleavage efficiency of the variants decreased depending on the degree of structural changes from the authentic pre-tRNA. This suggests that the numbers of base-pairs of both the acceptor stem and the T stem are important for recognition and cleavage by 3' tRNase.