Depletion of Saccharomyces cerevisiae tRNA(His) guanylyltransferase Thg1p leads to uncharged tRNAHis with additional m(5)C

The essential Saccharomyces cerevisiae tRNA(His) guanylyltransferase (Thg1p) is responsible for the unusual G(-1) addition to the 5' end of cytoplasmic tRNA(His). We report here that tRNA(His) from Thg1p-depleted cells is uncharged, although histidyl tRNA synthetase is active and the 3' end of the tRNA is intact, suggesting that G(-1) is a critical determinant for aminoacylation of tRNA(His) in vivo. Thg1p depletion leads to activation of the GCN4 pathway, most, but not all, of which is Gcn2p dependent, and to the accumulation of tRNA(His) in the nucleus. Surprisingly, tRNA(His) in Thg1p-depleted cells accumulates additional m(5)C modifications, which are delayed relative to the loss of G(-1) and aminoacylation. The additional modification is likely due to tRNA m(5)C methyltransferase Trm4p. We developed a new method to map m(5)C residues in RNA and localized the additional m(5)C to positions 48 and 50. This is the first documented example of the accumulation of additional modifications in a eukaryotic tRNA species.     

Identification of critical residues for G-1 addition and substrate recognition by tRNA(His) guanylyltransferase

The yeast tRNA(His) guanylyltransferase (Thg1) is an essential enzyme in yeast. Thg1 adds a single G residue to the 5' end of tRNA(His) (G(-1)), which serves as a crucial determinant for aminoacylation of tRNA(His). Thg1 is the only known gene product that catalyzes the 3'-5' addition of a single nucleotide via a normal phosphodiester bond, and since there is no identifiable sequence similarity between Thg1 and any other known enzyme family, the mechanism by which Thg1 catalyzes this unique reaction remains unclear. We have altered 29 highly conserved Thg1 residues to alanine, and using three assays to assess Thg1 catalytic activity and substrate specificity, we have demonstrated that the vast majority of these highly conserved residues (24/29) affect Thg1 function in some measurable way. We have identified 12 Thg1 residues that are critical for G(-1) addition, based on significantly decreased ability to add G(-1) to tRNA(His) in vitro and significant defects in complementation of a thg1Delta yeast strain. We have also identified a single Thg1 alteration (D68A) that causes a dramatic decrease in the rigorous specificity of Thg1 for tRNA(His). This single alteration enhances the k(cat)/K(M) for ppp-tRNA(Phe) by nearly 100-fold relative to that of wild-type Thg1. These results suggest that Thg1 substrate recognition is at least in part mediated by preventing recognition of incorrect substrates for nucleotide addition.     

Doing it in reverse: 3'-to-5' polymerization by the Thg1 superfamily

The tRNA(His) guanylyltransferase (Thg1) family of enzymes comprises members from all three domains of life (Eucarya, Bacteria, Archaea). Although the initial activity associated with Thg1 enzymes was a single 3'-to-5' nucleotide addition reaction that specifies tRNA(His) identity in eukaryotes, the discovery of a generalized base pair-dependent 3'-to-5' polymerase reaction greatly expanded the scope of Thg1 family-catalyzed reactions to include tRNA repair and editing activities in bacteria, archaea, and organelles. While the identification of the 3'-to-5' polymerase activity associated with Thg1 enzymes is relatively recent, the roots of this discovery and its likely physiological relevance were described ≈ 30 yr ago. Here we review recent advances toward understanding diverse Thg1 family enzyme functions and mechanisms. We also discuss possible evolutionary origins of Thg1 family-catalyzed 3'-to-5' addition activities and their implications for the currently observed phylogenetic distribution of Thg1-related enzymes in biology.     

tRNAHis guanylyltransferase adds G-1 to the 5' end of tRNAHis by recognition of the anticodon, one of several features unexpectedly shared with tRNA synthetases

All eukaryotic tRNA(His) molecules are unique among tRNA species because they require addition of a guanine nucleotide at the -1 position by tRNA(His) guanylyltransferase, encoded in yeast by THG1. This G(-1) residue is both necessary and sufficient for aminoacylation of tRNA by histidyl-tRNA synthetase in vitro and is required for aminoacylation in vivo. Although Thg1 is presumed to be highly specific for tRNA(His) to prevent misacylation of tRNAs, the source of this specificity is unknown. We show here that Thg1 is >10,000-fold more selective for its cognate substrate tRNA(His) than for the noncognate substrate tRNA(Phe). We also demonstrate that the GUG anticodon of tRNA(His) is a crucial Thg1 identity element, since alteration of this anticodon in tRNA(His) completely abrogates Thg1 activity, and the simple introduction of this GUG anticodon to any of three noncognate tRNAs results in significant Thg1 activity. For tRNA(Phe), k(cat)/K(M) is improved by at least 200-fold. Thg1 is the only protein other than aminoacyl-tRNA synthetases that is known to use the anticodon as an identity element to discriminate among tRNA species while acting at a remote site on the tRNA, an unexpected link given the lack of any identifiable sequence similarity between these two families of proteins. Moreover, Thg1 and tRNA synthetases share two other features: They act in close proximity to one another at the top of the tRNA aminoacyl-acceptor stem, and the chemistry of their respective reactions is strikingly similar.     

A role for tRNA(His) guanylyltransferase (Thg1)-like proteins from Dictyostelium discoideum in mitochondrial 5'-tRNA editing

Genes with sequence similarity to the yeast tRNA(His) guanylyltransferase (Thg1) gene have been identified in all three domains of life, and Thg1 family enzymes are implicated in diverse processes, ranging from tRNA(His) maturation to 5'-end repair of tRNAs. All of these activities take advantage of the ability of Thg1 family enzymes to catalyze 3'-5' nucleotide addition reactions. Although many Thg1-containing organisms have a single Thg1-related gene, certain eukaryotic microbes possess multiple genes with sequence similarity to Thg1. Here we investigate the activities of four Thg1-like proteins (TLPs) encoded by the genome of the slime mold, Dictyostelium discoideum (a member of the eukaryotic supergroup Amoebozoa). We show that one of the four TLPs is a bona fide Thg1 ortholog, a cytoplasmic G(-1) addition enzyme likely to be responsible for tRNA(His) maturation in D. discoideum. Two other D. discoideum TLPs exhibit biochemical activities consistent with a role for these enzymes in mitochondrial 5'-tRNA editing, based on their ability to efficiently repair the 5' ends of mitochondrial tRNA editing substrates. Although 5'-tRNA editing was discovered nearly two decades ago, the identity of the protein(s) that catalyze this activity has remained elusive. This article provides the first identification of any purified protein that appears to play a role in the 5'-tRNA editing reaction. Moreover, the presence of multiple Thg1 family members in D. discoideum suggests that gene duplication and divergence during evolution has resulted in paralogous proteins that use 3'-5' nucleotide addition reactions for diverse biological functions in the same organism.     

Kinetic analysis of 3'-5' nucleotide addition catalyzed by eukaryotic tRNA(His) guanylyltransferase

The tRNA(His) guanylyltransferase (Thg1) catalyzes the incorporation of a single guanosine residue at the -1 position (G(-1)) of tRNA(His), using an unusual 3'-5' nucleotidyl transfer reaction. Thg1 and Thg1 orthologs known as Thg1-like proteins (TLPs), which catalyze tRNA repair and editing, are the only known enzymes that add nucleotides in the 3'-5' direction. Thg1 enzymes share no identifiable sequence similarity with any other known enzyme family that could be used to suggest the mechanism for catalysis of the unusual 3'-5' addition reaction. The high-resolution crystal structure of human Thg1 revealed remarkable structural similarity between canonical DNA/RNA polymerases and eukaryotic Thg1; nevertheless, questions regarding the molecular mechanism of 3'-5' nucleotide addition remain. Here, we use transient kinetics to measure the pseudo-first-order forward rate constants for the three steps of the G(-1) addition reaction catalyzed by yeast Thg1: adenylylation of the 5' end of the tRNA (k(aden)), nucleotidyl transfer (k(ntrans)), and removal of pyrophosphate from the G(-1)-containing tRNA (k(ppase)). This kinetic framework, in conjunction with the crystal structure of nucleotide-bound Thg1, suggests a likely role for two-metal ion chemistry in all three chemical steps of the G(-1) addition reaction. Furthermore, we have identified additional residues (K44 and N161) involved in adenylylation and three positively charged residues (R27, K96, and R133) that participate primarily in the nucleotidyl transfer step of the reaction. These data provide a foundation for understanding the mechanism of 3'-5' nucleotide addition in tRNA(His) maturation.     

3′-5′ tRNA guanylyltransferase in bacteria

The identity of the histidine specific transfer RNA (tRNA^His) is largely determined by a unique guanosine residue at position −1. In eukaryotes and archaea, the tRNA^His guanylyltransferase (Thg1) catalyzes 3′-5′ addition of G to the 5′-terminus of tRNA^His. Here, we show that Thg1 also occurs in bacteria. We demonstrate in vitro Thg1 activity for recombinant enzymes from the two bacteria Bacillus thuringiensis and Myxococcus xanthus and provide a closer investigation of several archaeal Thg1. The reaction mechanism of prokaryotic Thg1 differs from eukaryotic enzymes, as it does not require ATP. Complementation of a yeast thg1 knockout strain with bacterial Thg1 verified in vivo activity and suggests a relaxed recognition of the discriminator base in bacteria.     

Presence of a classical RRM-fold palm domain in Thg1-type 3'- 5'nucleic acid polymerases and the origin of the GGDEF and CRISPR polymerase domains

Background  

Almost all known nucleic acid polymerases catalyze 5'-3' polymerization by mediating the attack on an incoming nucleotide 5' triphosphate by the 3'OH from the growing polynucleotide chain in a template dependent or independent manner. The only known exception to this rule is the Thg1 RNA polymerase that catalyzes 3'-5' polymerization in vitro and also in vivo as a part of the maturation process of histidinyl tRNA. While the initial reaction catalyzed by Thg1 has been compared to adenylation catalyzed by the aminoacyl tRNA synthetases, the evolutionary relationships of Thg1 and the actual nature of the polymerase reaction catalyzed by it remain unclear.     

Structural Studies of a Bacterial tRNAHIS Guanylyltransferase (Thg1)-Like Protein,with Nucleotide in the Activation and Nucleotidyl Transfer Sites

All nucleotide polymerases and transferases catalyze nucleotide addition in a 5′ to 3′ direction. In contrast, tRNA^His guanylyltransferase (Thg1) enzymes catalyze the unusual reverse addition (3′ to 5′) of nucleotides to polynucleotide substrates. In eukaryotes, Thg1 enzymes use the 3′–5′ addition activity to add G₋₁ to the 5′-end of tRNA^His, a modification required for efficient aminoacylation of the tRNA by the histidyl-tRNA synthetase. Thg1-like proteins (TLPs) are found in Archaea, Bacteria, and mitochondria and are biochemically distinct from their eukaryotic Thg1 counterparts TLPs catalyze 5′-end repair of truncated tRNAs and act on a broad range of tRNA substrates instead of exhibiting strict specificity for tRNA^His. Taken together, these data suggest that TLPs function in distinct biological pathways from the tRNA^His maturation pathway, perhaps in tRNA quality control. Here we present the first crystal structure of a TLP, from the gram-positive soil bacterium Bacillus thuringiensis (BtTLP). The enzyme is a tetramer like human THG1, with which it shares substantial structural similarity. Catalysis of the 3′–5′ reaction with 5′-monophosphorylated tRNA necessitates first an activation step, generating a 5′-adenylylated intermediate prior to a second nucleotidyl transfer step, in which a nucleotide is transferred to the tRNA 5′-end. Consistent with earlier characterization of human THG1, we observed distinct binding sites for the nucleotides involved in these two steps of activation and nucleotidyl transfer. A BtTLP complex with GTP reveals new interactions with the GTP nucleotide in the activation site that were not evident from the previously solved structure. Moreover, the BtTLP-ATP structure allows direct observation of ATP in the activation site for the first time. The BtTLP structural data, combined with kinetic analysis of selected variants, provide new insight into the role of key residues in the activation step.     

Modulation of thapsigargin-induced calcium mobilisation by cyclic AMP-elevating agents in human lymphocytes is insensitive to the action of the protein kinase A inhibitor H-89

Ca2+ mobilisation from internal stores and from the extracellular medium is one of the primary events involved in lymphocyte activation and proliferation. Regulation of these processes by adenosine 3',5'-cyclic monophosphate (cAMP) and cAMP-dependent protein kinase (PKA) was studied in Fura2-loaded human peripheral blood lymphocytes. Cytosolic Ca2+ concentration ([Ca2+]i) was measured in single cells by the use of a ratio imaging fluorescence microscope and Ca2+ mobilisation was achieved by the use of the endoplasmic reticulum (ER) Ca2+ ATPase inhibitor, thapsigargin (Thg). Our results show that both activation and inhibition of PKA, with forskolin (FSK) and N-[2-(p-bromocinnamylamino)ethyl]-5-isoquinolinesulfonamide.2HCl (H-89), respectively, inhibited the Thg-induced Ca2+ entry. Furthermore, FSK also reduced the ability of Thg to release Ca2+ from internal stores. This reduction was inhibited by the adenylyl cyclase (AC) inhibitor 9-(tetrahydro-2-furanyl)-9-H-purin-6-amine (SQ22,536), but not by the PKA inhibitor H89, indicating that cAMP but not PKA is responsible for this effect. FSK effect was mimicked by dibutyryl cAMP (dbcAMP) and by inhibition of phosphodiesterases (PDEs) with rolipram (ROL) and milrinone (MIL). We also showed that a very high concentration of H-89 (100 microM) releases Ca2+ from an intracellular pool, although this action is probably independent of PKA inhibition. Neither 10 microM H-89 nor other cAMP/PKA-modulating drugs had any effect on the basal [Ca2+]i of human lymphocytes. We conclude that PKA may act as a fine modulator of capacitative Ca2+ entry, while cAMP has a PKA-independent interaction with the Ca2+ stores of human lymphocytes.     

Lack of end-product control of nitrite reductase level in pea roots

The effects of various ammonium salts and amino acids on nitrite reductase (NIR) induction in isolated pea roots cultured in media containing nitrate or nitrite and either exogenous sucrose or no sugar were investigated. Thg aim of these investigations was to determine if the NIR level is subject to end-product control. The results showed that even though some ammonium salts and casamino acids can depress NIR level under certain conditions this inhibition cannot be interpreted in terms of direct end-product inhibition of NIR synthesis because their effects were dependent on the character (anion) and toxicity of the respective ammonium salt, on the presence of exogenous sucrose in the induction medium, and on the inducer of NIR. NH₄HCO₃ inhibited NIR induction at those concentrations which were toxic to the roots, ammonium phosphates hampered NIR induction only in roots exposed to nitrite in media containing sucrose, while casamino acids slightly depressed NIR induction only in roots exposed to nitrate and exogenous sucrose. The results further show that the basal (noninduced) NIR level changes little even under strongly toxic conditions.     

A conserved domain of yeast RNA triphosphatase flanking the catalytic core regulates self-association and interaction with the guanylyltransferase component of the mRNA capping apparatus.

The 549-amino acid yeast RNA triphosphatase Cet1p catalyzes the first step in mRNA cap formation. Cet1p consists of three domains as follows: (i) a 230-amino acid N-terminal segment that is dispensable for catalysis in vitro and for Cet1p function in vivo; (ii) a protease-sensitive segment from residues 230 to 275 that is dispensable for catalysis but essential for Cet1p function in vivo; and (iii) a catalytic domain from residues 275 to 539. Sedimentation analysis indicates that purified Cet1(231-549)p is a homodimer. Cet1(231-549)p binds in vitro to the yeast RNA guanylyltransferase Ceg1p to form a 7.1 S complex that we surmise to be a trimer consisting of two molecules of Cet1(231-549)p and one molecule of Ceg1p. The more extensively truncated protein Cet1(276-549)p, which cannot support cell growth, sediments as a monomer and does not interact with Ceg1p. An intermediate deletion protein Cet1(246-549)p, which supports cell growth only when overexpressed, sediments principally as a discrete salt-stable 11.5 S homo-oligomeric complex. These data implicate the segment of Ceg1p from residues 230 to 275 in regulating self-association and in binding to Ceg1p. Genetic data support the existence of a Ceg1p-binding domain flanking the catalytic domain of Cet1p, to wit: (i) the ts growth phenotype of 2mu CET1(246-549) is suppressed by overexpression of Ceg1p; (ii) a ts alanine cluster mutation CET1(201-549)/K250A-W251A is suppressed by overexpression of Ceg1p; and (iii) 15 other cet-ts alleles with missense changes mapping elsewhere in the protein are not suppressed by Ceg1p overexpression. Finally, we show that the in vivo function of Cet1(275-549)p is completely restored by fusion to the guanylyltransferase domain of the mouse capping enzyme. We hypothesize that the need for Ceg1p binding by yeast RNA triphosphatase can by bypassed when the triphosphatase catalytic domain is delivered to the RNA polymerase II elongation complex by linkage in cis to the mammalian guanylyltransferase.     

Evidence that the NH2 terminus of vph1p, an integral subunit of the V0 sector of the yeast V-ATPase, interacts directly with the Vma1p and Vma13p subunits of the V1 sector

The vacuolar-type H(+)-ATPase (V-ATPase) is composed of a peripherally bound (V(1)) and a membrane-associated (V(0)) complex. V(1) ATP hydrolysis is thought to rotate a central stalk, which in turn, is hypothesized to drive V(0) proton translocation. Transduction of torque exerted by the rotating stalk on V(0) requires a fixed structural link (stator) between the complexes to prevent energy loss through futile rotation of V(1) relative to V(0); this work sought to identify stator components. The 95-kDa V-ATPase subunit, Vph1p, has a cytosolic NH(2) terminus (Nt-Vph1p) and a membrane-associated COOH terminus. Two-hybrid assays demonstrated that Nt-Vph1p interacts with the catalytic V(1) subunit, Vma1p. Co-immunoprecipitation of Vma1p with Nt-Vph1p confirmed the interaction. Expression of Nt-Vph1p in a Deltavph1 mutant was necessary to recruit Vma13p to V(1). Vma13p bound to Nt-Vph1p in vitro demonstrating direct interaction. Limited trypsin digests cleaves both Nt-Vph1p and Vma13p. The same tryptic treatment results in a loss of proton translocation while not reducing bafilomycin A(1)-sensitive ATP hydrolysis. Trypsin cleaved Vph1p at arginine 53. Elimination of the tryptic cleavage site by substitution of arginine 53 to serine partially protected vacuolar acidification from trypsin digestion. These results suggest that Vph1p may function as a component of a fixed structural link, or stator, coupling V(1) ATP hydrolysis to V(0) proton translocation.     

Accelerating the rate of disassembly of karyopherin.cargo complexes

Transport of macromolecules across the nuclear pore complex (NPC) occurs in seconds and involves assembly of a karyopherin.cargo complex and docking to the NPC, translocation of the complex across the NPC via interaction with nucleoporins (Nups), and dissociation of the complex in the nucleoplasm. To identify rate-limiting steps in the Kap95p.Kap60p-mediated nuclear import pathway of Saccharomyces cerevisiae, we reconstituted key intermediate complexes and measured their rates of dissociation and affinities of interaction. We found that a nuclear localization signal-containing protein (NLS-cargo) dissociates slowly from Kap60p monomers and Kap60p.Kap95p heterodimers with half-lives (t(12)) of 7 and 73 min, respectively; that Kap60p and Kap60p.NLS-cargo complexes dissociate slowly from Kap95p (t(12) = 36 and 73 min, respectively); and that Kap95p.Kap60p.NLS-cargo complexes and Kap95p.Kap60p heterodimers dissociate rapidly from the nucleoporin Nup1p (t(12) < or = 21 s) and other Nups. A search for factors that accelerate disassembly of the long-lived intermediates revealed that Nup1p and Nup2p accelerate 16- and 19-fold the rate of dissociation of NLS-cargo from Kap60p.Kap95p heterodimers; that Gsp1p-GTP accelerates > or = 447-fold the rate of dissociation of Kap60p.NLS-cargo from Kap95p; and that Nup2p and the Cse1p.Gsp1p-GTP complex independently accelerate > or = 22- and > or = 39-fold the rate of dissociation of NLS-cargo from Kap60p. We suggest that Nup1p, Nup2p, Cse1p, and Gsp1p accelerate disassembly of Kap95p.Kap60p.NLS-cargo complexes by triggering allosteric mechanisms within Kaps that cause rapid release of binding partners. In that way, Nup1p, Nup2p, Cse1p, and Gsp1p may function as karyopherin release factors (or KaRFs) in the nuclear basket structure of the S. cerevisiae NPC.