tRNATyr has an unusually short half-life in Trypanosoma brucei.

Following transcription, tRNAs undergo a series of processing and modification events to become functional adaptors in protein synthesis. Eukaryotes have also evolved intracellular transport systems whereby nucleus-encoded tRNAs may travel out and into the nucleus. In trypanosomes, nearly all tRNAs are also imported from the cytoplasm into the mitochondrion, which lacks tRNA genes. Differential subcellular localization of the cytoplasmic splicing machinery and a nuclear enzyme responsible for queuosine modification at the anticodon "wobble" position appear to be important quality control mechanisms for tRNATyr, the only intron-containing tRNA in T. brucei Since tRNA-guanine transglycosylase (TGT), the enzyme responsible for Q formation, cannot act on an intron-containing tRNA, retrograde nuclear transport is an essential step in maturation. Unlike maturation/processing pathways, the general mechanisms of tRNA stabilization and degradation in T. brucei are poorly understood. Using a combination of cellular and molecular approaches, we show that tRNATyr has an unusually short half-life. tRNATyr, and in addition tRNAAsp, also show the presence of slow-migrating bands during electrophoresis; we term these conformers: alt-tRNATyr and alt-tRNAAsp, respectively. Although we do not know the chemical or structural nature of these conformers, alt-tRNATyr has a short half-life resembling that of tRNATyr; the same is not true for alt-tRNAAsp We also show that RRP44, which is usually an exosome subunit in other organisms, is involved in tRNA degradation of the only intron-containing tRNA in T. brucei and is partly responsible for its unusually short half-life.

Crystal structure of Nanoarchaeum equitans tyrosyl-tRNA synthetase and its aminoacylation activity toward tRNATyr with an extra guanosine residue at the 5'-terminus.

tRNATyr of Nanoarchaeum equitans has a remarkable feature with an extra guanosine residue at the 5'-terminus. However, the N. equitans tRNATyr mutant without extra guanosine at the 5'-end was tyrosylated by tyrosyl-tRNA synthase (TyrRS). We solved the crystal structure of N. equitans TyrRS at 2.80 Å resolution. By comparing the present solved structure with the complex structures TyrRS with tRNATyr of Thermus thermophilus and Methanocaldococcus jannaschii, an arginine substitution mutant of N. equitans TyrRS at Ile200 (I200R), which is the putative closest candidate to the 5'-phosphate of C1 of N. equitans tRNATyr, was prepared. The I200R mutant tyrosylated not only wild-type tRNATyr but also the tRNA without the G-1 residue. Further tyrosylation analysis revealed that the second base of the anticodon (U35), discriminator base (A73), and C1:G72 base pair are strong recognition sites.

Role of disordered regions in transferring tyrosine to its cognate tRNA.

Aminoacyl tRNA synthetase (AARS) plays an important role in transferring each amino acid to its cognate tRNA. Specifically, tyrosyl tRNA synthetase (TyrRS) is involved in various functions including protection from DNA damage due to oxidative stress, protein synthesis and cell signaling and can be an attractive target for controlling the pathogens by early inhibition of translation. TyrRS has two disordered regions, which lack a stable 3D structure in solution, and are involved in tRNA synthetase catalysis and stability. One of the disordered regions undergoes disorder-to-order transition (DOT) upon complex formation with tRNA whereas the other remains disordered (DR). In this work, we have explored the importance of these disordered regions using molecular dynamics simulations of both free and RNA-complexed states. We observed that the DOT and DR regions of the first subunit acts as a flap and interact with the acceptor arm of the tRNA. The DOT-DR flap closes when tyrosine (TyrRSTyr) is present at the active site of the complex and opens in the presence of tyrosine monophosphate (TyrRSYMP). The DOT and DR regions of the second subunit interact with the anticodon stem as well as D-loop of the tRNA, which might be involved in stabilizing the complex. The anticodon loop of the tRNA binds to the structured region present in the C-terminal of the protein, which is observed to be flexible during simulations. Detailed energy calculations also show that TyrRSTyr complex has stronger binding energy between tRNA and protein compared to TyrRSYMP; on the contrary, the anticodon is strongly bound in TyrRSYMP. The results obtained in the present study provide additional insights for understanding catalysis and the involvement of disordered regions in Tyr transfer to cognate tRNA.

An evolving tale of two interacting RNAs-themes and variations of the T-box riboswitch mechanism.

T-box riboswitches are a widespread class of structured noncoding RNAs in Gram-positive bacteria that regulate the expression of amino acid-related genes. They form negative feedback loops to maintain steady supplies of aminoacyl-transfer RNAs (tRNAs) to the translating ribosomes. T-box riboswitches are located in the 5' leader regions of mRNAs that they regulate and directly bind to their cognate tRNA ligands. T-boxes further sense the aminoacylation state of the bound tRNAs and, based on this readout, regulate gene expression at the level of transcription or translation. T-box riboswitches consist of two conserved domains-a 5' Stem I domain that is involved in specific tRNA recognition and a 3' antiterminator/antisequestrator (or discriminator) domain that senses the amino acid on the 3' end of the bound tRNA. Interaction of the 3' end of an uncharged but not charged tRNA with a thermodynamically weak discriminator domain stabilizes it to promote transcription readthrough or translation initiation. Recent biochemical, biophysical, and structural studies have provided high-resolution insights into the mechanism of tRNA recognition by Stem I, several structural models of full-length T-box-tRNA complexes, mechanism of amino acid sensing by the antiterminator domain, as well as kinetic details of tRNA binding to the T-box riboswitches. In addition, translation-regulating T-box riboswitches have been recently characterized, which presented key differences from the canonical transcriptional T-boxes. Here, we review the recent developments in understanding the T-box riboswitch mechanism that have employed various complementary approaches. Further, the regulation of multiple essential genes by T-boxes makes them very attractive drug targets to combat drug resistance. The recent progress in understanding the biochemical, structural, and dynamic aspects of the T-box riboswitch mechanism will enable more precise and effective targeting with small molecules. © 2019 IUBMB Life, 2019 © 2019 IUBMB Life, 71(8):1167-1180, 2019.

The complete mitochondrial genome of Sarcoptes scabiei var. nyctereutis from the Japanese raccoon dog: Prediction and detection of two transfer RNAs (tRNA-A and tRNA-Y).

Sarcoptes scabiei (Acari: Sarcoptidae) causes a common contagious skin disease that affects many mammals. Here, the complete mitochondrial genome of a mite, S. scabiei var. nyctereutis, from Japanese wild raccoon dogs was analyzed. The 13,837bp circular genome contained 13 protein-coding genes, two rRNA genes, and 22 tRNA genes. For the first time, two tRNAs (alanine and tyrosine), that were thought to be absent in scabies mites from other animals, were predicted to have short, non-cloverleaf structures by in silico annotation and detected by RT-PCR, sequencing, and northern analysis. The mitochondrial genome structure of S. scabiei is similar to that of Psoroptes cuniculi and Dermatophagoides farinae. While small and unusual tRNA genes seem to be common among acariform mites, further experimental evidence for their presence is needed. Furthermore, through an analysis of the cox1 gene, we have provided new evidence to confirm the transmission of this mite between different animal hosts.

Long and branched polyamines are required for maintenance of the ribosome, tRNAHis and tRNATyr in Thermus thermophilus cells at high temperatures.

Thermus thermophilus is an extremely thermophilic eubacterium that produces various polyamines. Aminopropylagmatine ureohydrolase (SpeB) and SAM decarboxylase-like protein 1 (SpeD1) are involved in the biosynthesis of spermidine from arginine. Because long and branched polyamines in T. thermophilus are synthesized from spermidine, the speB and speD1 gene-deleted strains (ΔspeB and ΔspeD1, respectively) cannot synthesize long and branched polyamines. Although neither strain grew at high temperatures (>75°C) in minimal medium, both strains survived at 80°C when they were cultured at 70°C until the mid-log phase and then shifted to 80°C. We therefore prepared the ΔspeB and ΔspeD1 cells using this culture method. Microscopic analysis showed that both strains can survive for 10 h after the temperature shift. Although the modification levels of 2'-O-methylguanosine at position 18, N7 -methylguanosine at position 46, 5-methyluridine at position 54 and N1 -methyladenosine at position 58 in the class I tRNA from both strains were normal, amounts of tRNATyr , tRNAHis , rRNAs and 70S ribosomes were decreased after the temperature shift. Furthermore, in vivo protein synthesis in both strains was completely lost 10 h after the temperature shift. Thus, long and branched polyamines are required for at least the maintenance of 70S ribosome and some tRNA species at high temperatures.

Unusual noncanonical intron editing is important for tRNA splicing in Trypanosoma brucei.

In cells, tRNAs are synthesized as precursor molecules bearing extra sequences at their 5' and 3' ends. Some tRNAs also contain introns, which, in archaea and eukaryotes, are cleaved by an evolutionarily conserved endonuclease complex that generates fully functional mature tRNAs. In addition, tRNAs undergo numerous posttranscriptional nucleotide chemical modifications. In Trypanosoma brucei, the single intron-containing tRNA (tRNA(Tyr)GUA) is responsible for decoding all tyrosine codons; therefore, intron removal is essential for viability. Using molecular and biochemical approaches, we show the presence of several noncanonical editing events, within the intron of pre-tRNA(Tyr)GUA, involving guanosine-to-adenosine transitions (G to A) and an adenosine-to-uridine transversion (A to U). The RNA editing described here is required for proper processing of the intron, establishing the functional significance of noncanonical editing with implications for tRNA processing in the deeply divergent kinetoplastid lineage and eukaryotes in general.

Pleiotropic effects of a mitochondrial-nuclear incompatibility depend upon the accelerating effect of temperature in Drosophila.

Interactions between mitochondrial and nuclear gene products that underlie eukaryotic energy metabolism can cause the fitness effects of mutations in one genome to be conditional on variation in the other genome. In ectotherms, the effects of these interactions are likely to depend upon the thermal environment, because increasing temperature accelerates molecular rates. We find that temperature strongly modifies the pleiotropic phenotypic effects of an incompatible interaction between a Drosophila melanogaster polymorphism in the nuclear-encoded, mitochondrial tyrosyl-transfer (t)RNA synthetase and a D. simulans polymorphism in the mitochondrially encoded tRNA(Tyr). The incompatible mitochondrial-nuclear genotype extends development time, decreases larval survivorship, and reduces pupation height, indicative of decreased energetic performance. These deleterious effects are ameliorated when larvae develop at 16° and exacerbated at warmer temperatures, leading to complete sterility in both sexes at 28°. The incompatible genotype has a normal metabolic rate at 16° but a significantly elevated rate at 25°, consistent with the hypothesis that inefficient energy metabolism extends development in this genotype at warmer temperatures. Furthermore, the incompatibility decreases metabolic plasticity of larvae developed at 16°, indicating that cooler development temperatures do not completely mitigate the deleterious effects of this genetic interaction. Our results suggest that the epistatic fitness effects of metabolic mutations may generally be conditional on the thermal environment. The expression of epistatic interactions in some environments, but not others, weakens the efficacy of selection in removing deleterious epistatic variants from populations and may promote the accumulation of incompatibilities whose fitness effects will depend upon the environment in which hybrids occur.

Mechanism of eukaryotic RNA polymerase III transcription termination.

Gene expression in organisms involves many factors and is tightly controlled. Although much is known about the initial phase of transcription by RNA polymerase III (Pol III), the enzyme that synthesizes the majority of RNA molecules in eukaryotic cells, termination is poorly understood. Here, we show that the extensive structure of Pol III-synthesized transcripts dictates the release of elongation complexes at the end of genes. The poly-T termination signal, which does not cause termination in itself, causes catalytic inactivation and backtracking of Pol III, thus committing the enzyme to termination and transporting it to the nearest RNA secondary structure, which facilitates Pol III release. Similarity between termination mechanisms of Pol III and bacterial RNA polymerase suggests that hairpin-dependent termination may date back to the common ancestor of multisubunit RNA polymerases.

A simple system for expression of proteins containing 3-azidotyrosine at a pre-determined site in Escherichia coli.

We developed an efficient method for introduction of 3-azidotyrosine (N(3)-Y) into proteins in Escherichia coli cells. We constructed a plasmid that is adaptable for the constitutive expression of both Methanosarcina acetivorans tyrosyl-tRNA synthetase (TyrRS) and tRNA(()(CUA)), and made an orthogonal tRNA((CUA)) that is recognized as a substrate only by the archaeal TyrRS. Random mutations were introduced into M. acetivorans TyrRS around the tyrosine binding pocket, and a TyrRS mutant recognizing N(3)-Y was selected. We then expressed rat calmodulin (CaM) containing N(3)-Y, using the CaM gene with an amber codon at position 80. Mass analyses confirmed production of CaM containing N(3)-Y, but a significant amount of CaM containing 3-aminotyrosine was also detected. To more efficiently express CaM containing N(3)-Y, we added an arabinose-inducible gene for the mutant TyrRS to the plasmid carrying the mutant TyrRS/tRNA(()(CUA)) gene. Although the yields of full-length CaM increased ~3-fold, the ratio of N(3)-Y introduction was not significantly improved. Following screening for a suitable host cell, we found that CaM expressed in E. coli SHuffle (K-12) had 97% N(3)-Y at the pre-determined site. Finally, we obtained up to 2 mg of CaM containing N(3)-Y per 100 ml of culture media, sufficient for use in various proteomics experiments, including photo-crosslinking.

Studies on crenarchaeal tyrosylation accuracy with mutational analyses of tyrosyl-tRNA synthetase and tyrosine tRNA from Aeropyrum pernix.

Aminoacyl-tRNA synthetases play a key role in the translation of genetic code into correct protein sequences. These enzymes recognize cognate amino acids and tRNAs from noncognate counterparts, and catalyze the formation of aminoacyl-tRNAs. While Although several tyrosyl-tRNA synthetases (TyrRSs) from various species have been structurally and functionally well characterized, the crenarchaeal TyrRS remains poorly understood. In this study, we performed mutational analyses on tyrosine tRNA (tRNA(Tyr)) and TyrRS from the crenarchaeon, Aeropyrum pernix, to investigate the molecular recognition mechanism. Kinetics for tyrosylation using in vitro transcript indicated that the discriminator base A73 and adjacent G72 in the acceptor stem are identity elements of tRNA(Tyr), whereas the C1 base and anticodon had modest roles as identity determinants. Intriguingly, in contrast to the identity element of eukaryotic/euryarchaeal TyrRSs, the first base-pair (C1-G72) of the acceptor stem was not essential in crenarchaeal TyrRS as a pair. Furthermore, A. pernix TyrRS mutants were constructed at positions Tyr39 and Asp172, which could form hydrogen bonds with the 4-hydroxyl group of l-tyrosine. The tyrosylation activities with the mutants resulted that Asp172 mutants completely abolished tyrosylation activity, whereas Tyr39 mutants had no effect on activity. Thus, crenarchaeal TyrRS appears to adopt different molecular recognition mechanism from other TyrRSs.

Conformation effects of base modification on the anticodon stem-loop of Bacillus subtilis tRNA(Tyr).

tRNA molecules contain 93 chemically unique nucleotide base modifications that expand the chemical and biophysical diversity of RNA and contribute to the overall fitness of the cell. Nucleotide modifications of tRNA confer fidelity and efficiency to translation and are important in tRNA-dependent RNA-mediated regulatory processes. The three-dimensional structure of the anticodon is crucial to tRNA-mRNA specificity, and the diverse modifications of nucleotide bases in the anticodon region modulate this specificity. We have determined the solution structures and thermodynamic properties of Bacillus subtilis tRNA(Tyr) anticodon arms containing the natural base modifications N(6)-dimethylallyl adenine (i(6)A(37)) and pseudouridine (ψ(39)). UV melting and differential scanning calorimetry indicate that the modifications stabilize the stem and may enhance base stacking in the loop. The i(6)A(37) modification disrupts the hydrogen bond network of the unmodified anticodon loop including a C(32)-A(38)(+) base pair and an A(37)-U(33) base-base interaction. Although the i(6)A(37) modification increases the dynamic nature of the loop nucleotides, metal ion coordination reestablishes conformational homogeneity. Interestingly, the i(6)A(37) modification and Mg(2+) are sufficient to promote the U-turn fold of the anticodon loop of Escherichia coli tRNA(Phe), but these elements do not result in this signature feature of the anticodon loop in tRNA(Tyr).

Solution structure of the K-turn and Specifier Loop domains from the Bacillus subtilis tyrS T-box leader RNA.

In Gram-positive bacteria, the RNA transcripts of many amino acid biosynthetic and aminoacyl tRNA synthetase genes contain 5' untranslated regions, or leader RNAs, that function as riboswitches. These T-box riboswitches bind cognate tRNA molecules and regulate gene expression by a transcription attenuation mechanism. The Specifier Loop domain of the leader RNA contains nucleotides that pair with nucleotides in the tRNA anticodon loop and is flanked on one side by a kink-turn (K-turn), or GA, sequence motif. We have determined the solution NMR structure of the K-turn sequence element within the context of the Specifier Loop domain. The K-turn sequence motif has several noncanonical base pairs typical of K-turn structures but adopts an extended conformation. The Specifier Loop domain contains a loop E structural motif, and the single-strand Specifier nucleotides stack with their Watson-Crick edges displaced toward the minor groove. Mg(2+) leads to a significant bending of the helix axis at the base of the Specifier Loop domain, but does not alter the K-turn. Isothermal titration calorimetry indicates that the K-turn sequence causes a small enhancement of the interaction between the tRNA anticodon arm and the Specifier Loop domain. One possibility is that the K-turn structure is formed and stabilized when tRNA binds the T-box riboswitch and interacts with Stem I and the antiterminator helix. This motif in turn anchors the orientation of Stem I relative to the 3' half of the leader RNA, further stabilizing the tRNA-T box complex.

Dynamics of tRNAtyr probed with long-lifetime metal-ligand complexes.

The metal-ligand complexes, [Ru(bpy)(2)(dppz)](2+) (bpy = 2,2'-bipyridine, dppz = dipyrido[3,2-a:2',3'-c]phenazine) (RuBD) and [Ru(phen)(2)(dppz)](2+) (phen = 1,10-phenanthroline) (RuPD), display favorable photophysical properties including long lifetime, polarized emission, and very little background fluorescence. To check if RuBD and RuPD reflect the overall rotational mobility of small nucleic acid, we measured the intensity and anisotropy decays of RuBD and RuPD when intercalated into tRNA(tyr) using pBC SK(+) phagemid as a control. We used frequency-domain fluorometry with a blue light-emitting diode (LED) as the modulated light source. We observed shorter lifetimes for tRNA(tyr) than those for the pBC SK(+) phagemid for both probes, however, RuPD showed much larger decrease in the mean lifetime values (64%). The slow rotational correlation time of RuBD (31.3 ns) and the fast rotational correlation time of RuPD (26.0 ns) reflected the overall rotational mobility of tRNA(tyr). In addition, the steady-state anisotropy and time-resolved anisotropy decay data showed a clear difference between tRNA(tyr) and pBC SK(+) phagemid. This suggests the possibility of a homogeneous assay for identifying target nucleic acids and/or nucleic acid binding proteins.

The structure and mechanism of the Mycobacterium tuberculosis cyclodityrosine synthetase.

The Mycobacterium tuberculosis enzyme Rv2275 catalyzes the formation of cyclo(L-Tyr-L-Tyr) using two molecules of Tyr-tRNA(Tyr) as substrates. The three-dimensional (3D) structure of Rv2275 was determined to 2.0-Å resolution, revealing that Rv2275 is structurally related to the class Ic aminoacyl-tRNA synthetase family of enzymes. Mutagenesis and radioactive labeling suggests a covalent intermediate in which L-tyrosine is transferred from Tyr-tRNA(Tyr) to an active site serine (Ser88) by transesterification with Glu233 serving as a critical base, catalyzing dipeptide bond formation.

Preparation of an ochre suppressor tRNA recognizing exclusively UAA codon by using the molecular surgery technique.

In order to create an ochre suppressor tRNA which exclusively recognizes UAA codon, we replaced the G34 at the first position of yeast tRNA(Tyr)[GPsiA] anticodon with pseudouridine34 (Psi34) by using the molecular surgery technique. This tRNA(Tyr)[PsiPsiA] recognized only the UAA codon as expectedly, but tRNA(Tyr)[UPsiA] made as a control also behaved similarly. This result may suggest that U34 must be somehow modified to facilitate the wobble-pairing to G at the third position of codon.

Screening of amber suppressor tRNAs suitable to introduce nonnatural amino acids into proteins by real-time monitoring of cell-free translation.

Incorporation of nonnatural amino acids into proteins is a useful technique to analyze protein structure and function. We have reported that amber suppressor tRNAs suitable for efficient and specific incorporation of nonnatural amino acids into proteins can be obtained by screening a wide variety of naturally occurring tRNAs in an E. coli. cell-free translation system. The amber suppressor activity of the tRNAs was evaluated by incorporation of a fluorescent nonnatural amino acid and fluorescent SDS-PAGE analysis of cell-free translation products, though the SDS-PAGE was troublesome and time-consuming. In this research, we developed an alternative method for the screening of amber suppressor tRNAs by real-time measurement of fluorescence resonance energy transfer (FRET) from GFP to BODIPY558-linked nonnatural amino acid, which was incorporated into the N-terminus of GFP by amber suppressor tRNAs. Using this method, we demonstrated that the screening of the amber suppressor activity of various prokaryotic Trp tRNAs was performed in a high-throughput manner.

Deficiency of the tRNATyr:Psi 35-synthase aPus7 in Archaea of the Sulfolobales order might be rescued by the H/ACA sRNA-guided machinery.

Up to now, Psi 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 Psi 35 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:Psi-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 Psi 35 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 Psi 35 formation when using P. abyssi extract, whereas the A36G substitution in the S. solfataricus pre-tRNA(Tyr) did not affect Psi 35 formation in this RNA when using an S. solfataricus extract.

Thermodynamic analysis reveals a temperature-dependent change in the catalytic mechanism of bacillus stearothermophilus tyrosyl-tRNA synthetase.

Catalysis of tRNA(Tyr) aminoacylation by tyrosyl-tRNA synthetase can be divided into two steps. In the first step, tyrosine is activated by ATP to form the tyrosyl-adenylate intermediate. In the second step, the tyrosyl moiety is transferred to the 3' end of tRNA. To investigate the roles that enthalpic and entropic contributions play in catalysis by Bacillus stearothermophilus tyrosyl-tRNA synthetase (TyrRS), the temperature dependence for the activation of tyrosine and subsequent transfer to tRNA(Tyr) has been determined using single turnover kinetic methods. A van't Hoff plot for binding of ATP to the TyrRS.Tyr complex reveals three distinct regions. Particularly striking is the change occurring at 25 degrees C, where the values of DeltaH(0) and DeltaS(0) go from -144 kJ/mol and -438 J/mol K below 25 degrees C to +137.9 kJ/mol and +507 J/mol K above 25 degrees C. Nonlinear Eyring and van't Hoff plots are also observed for formation of the TyrRS.[Tyr-ATP](double dagger) and TyrRS.Tyr-AMP complexes. Comparing the van't Hoff plots for the binding of ATP to tyrosyl-tRNA synthetase in the absence and presence of saturating tyrosine concentrations indicates that the temperature-dependent changes in DeltaH(0) and DeltaS(0) for the binding of ATP only occur when tyrosine is bound to the enzyme. Previous investigations revealed a similar synergistic interaction between the tyrosine and ATP substrates when the "KMSKS" signature sequence is deleted or replaced by a nonfunctional sequence. We propose that the temperature-dependent changes in DeltaH(0) and DeltaS(0) are because of the KMSKS signature sequence being conformationally constrained and unable to disrupt this synergistic interaction below 25 degrees C.

Studies on Methanocaldococcus jannaschii RNase P reveal insights into the roles of RNA and protein cofactors in RNase P catalysis.

Ribonuclease P (RNase P), a ribonucleoprotein (RNP) complex required for tRNA maturation, comprises one essential RNA (RPR) and protein subunits (RPPs) numbering one in bacteria, and at least four in archaea and nine in eukarya. While the bacterial RPR is catalytically active in vitro, only select euryarchaeal and eukaryal RPRs are weakly active despite secondary structure similarity and conservation of nucleotide identity in their putative catalytic core. Such a decreased archaeal/eukaryal RPR function might imply that their cognate RPPs provide the functional groups that make up the active site. However, substrate-binding defects might mask the ability of some of these RPRs, such as that from the archaeon Methanocaldococcus jannaschii (Mja), to catalyze precursor tRNA (ptRNA) processing. To test this hypothesis, we constructed a ptRNA-Mja RPR conjugate and found that indeed it self-cleaves efficiently (k(obs), 0.15 min(-1) at pH 5.5 and 55 degrees C). Moreover, one pair of Mja RPPs (POP5-RPP30) enhanced k(obs) for the RPR-catalyzed self-processing by approximately 100-fold while the other pair (RPP21-RPP29) had no effect; both binary RPP complexes significantly reduced the monovalent and divalent ionic requirement. Our results suggest a common RNA-mediated catalytic mechanism in all RNase P and help uncover parallels in RNase P catalysis hidden by plurality in its subunit make-up.