A conserved aspartate of tRNA pseudouridine synthase is essential for activity and a probable nucleophilic catalyst.

tRNA pseudouridine synthase I catalyzes the conversion of uridine to pseudouridine at positions 38, 39, and/or 40 in the anticodon loop of many tRNAs. Pseudouridine synthase I was cloned behind a T7 promoter and expressed in Escherichia coli to about 20% of total soluble proteins. Fluorouracil-substituted tRNA caused a time-dependent inactivation of pseudouridine synthase I and formed a covalent complex with the enzyme that involved the FUMP at position 39. Asp60, conserved in all known and putative pseudouridine synthases, was mutated to amino acids with diverse side chains. All Asp60 mutants bound tRNA but were catalytically inactive and failed to form covalent complexes with fluorouracil-substituted tRNA. We conclude that the conserved Asp60 is essential for pseudouridine synthase activity and propose mechanisms which involve this residue in important catalytic roles.

Aminoacyl-tRNA synthetase and U54 methyltransferase recognize conformations of the yeast tRNA(Phe) anticodon and T stem/loop domain.

The enzyme-catalyzed posttranscriptional modification of tRNA and the contributions of modified nucleosides to tRNA structure and function can be investigated with chemically synthesized domains of the tRNA molecule. Heptadecamer RNAs with and without modified nucleosides and DNAs designed as analogs to the anticodon and T stem/loop domains of yeast tRNA(Phe) were produced by automated chemical synthesis. The unmodified T stem/loop domain of yeast tRNA(Phe) was a substrate for the E coli m5U54-tRNA methyltransferase activity, RUMT. Surprisingly, the DNA analog of the T stem/loop domain composed of d(A,U,G,C) was also a substrate. In addition, the DNA analog inhibited the methylation of unfractionated, undermodified E coli tRNA lacking the U54 methylation. RNA anticodon domains and DNA analogs differentially and specifically affected aminoacylation of the wild type yeast tRNA(Phe). Three differentially modified tRNA(Phe) anticodon domains with psi 39 alone, m1G37 and m5C40, or psi 39 with m1G37 and m5C40,stimulated phenylalanyl-tRNA synthetase (FRS) activity. However, one anticodon domain, with m5C40 as the only modified nucleoside and a closed loop conformation, inhibited FRS activity. Modified and unmodified DNA analogs of the anticodon, tDNA(PheAC), inhibited FRS activity. Analysis of the enzyme activity in the presence of the DNA analog characterized the DNA/enzyme interaction as either partial or allosteric inhibition. The disparity of action between the DNA and RNA hairpins provides new insight into the potential allosteric relationship of anticodon binding and open loop conformational requirements for active site function of FRS and other aaRSs. The comparison of the stimulatory and inhibitory properties of variously modified RNA domains and DNA analogs demonstrates that conformation, in addition to primary sequence, is important for tRNA-protein interaction. The enzyme recognition of various DNA analogs as substrate and/or inhibitors of activity demonstrates that conformational determinants are not restricted to ribose and the standard A-form RNA structure.

The pleiotypic response to amino acid deprivation is the result of interactions between components of the glycolysis and protein synthesis pathways.

Several diverse metabolic events become compromised when mammalian cells are made deficient in essential amino acids or when charging of their tRNA is blocked by amino acid analogs. This rapid general demise of cell function can be due to inhibition of phosphofructokinase (PFK) by uncharged tRNA. It has now been demonstrated that when tRNA is added to PFK in an assay dependent upon the reassociation of inactive, dissociated enzyme subunits, nanomolar concentrations cause complete inhibition. The model for control suggests that charged tRNA becomes associated with EF-1, which is specific for aminoacyl-tRNAs and is present in sufficiently high concentrations in cells to sequester that charged forms from an inhibitory role. Support for this model include: (1) the rapid onset of inhibition of glycolysis and glucose uptake upon amino acid deficiency; (2) the unique role of the product of PFK activity, fructose-1,6-diphosphate, in reactions of peptide chain initiation, particularly its role as a co-factor for purified eIF-2B, the GDP/GTP exchange factor; (3) the correlations of this interaction with the cellular and molecular lesions of insulin insufficiency; (4) the recognition that the anomalous role of high concentrations of cAMP as a stimulant of peptide chain initiation in energy depleted or gel-filtered cell lysates correlates with its stimulatory action on PFK as an analog for the positive effector, adenosine-5'-monophosphate; and (5) the role of fructose-1,6-diphosphate in the formation of glyceraldehyde-3-phosphate, a substrate for synthesis of ribose-5-phosphate via the non-oxidative portion of the pentose phosphate pathway, which, as a precursor of phosphoribosylpyrophosphate, is essential for nucleic acid synthesis.

Inhibition of the p66/p51 form of human immunodeficiency virus reverse transcriptase by tRNA(Lys).

Human immunodeficiency virus (HIV) reverse transcriptase (RT) uses host tRNA(Lys) partially annealed to the primer binding site (PBS) as primer for the initiation of cDNA synthesis. When assaying cDNA synthesis with a template-primer complex formed by an RNA fragment carrying the PBS site and bovine tRNA(Lys) we noticed that an excess of primer tRNA inhibited strongly the DNA polymerase activity of a recombinant HIV RT (p66-p51 heterodimeric form) produced in transformed yeast cells. The same inhibitory effect was observed with animal DNA polymerase alpha, while avian retrovirus RT was neither affected by tRNA(Lys) nor by its specific primer tRNA(Trp). Although the strongest inhibition was observed with tRNA(Lys), other tRNas like tRNA(Phe) and tRNA(Trp) inhibited also the HIV RT, whereas tRNAs specific for valine, proline and glycine had no effect on enzyme activity. Digestion of tRNA(Lys) with pancreatic RNase abolished the inhibition; on the other hand T1 RNase digestion had no effect on the inhibition suggesting a role of the anticodon region in this effect. The 12- and 14-mers corresponding to the anticodon regions of the three bovine tRNA(Lys) isoacceptors inhibited RT activity, indicating that at least an important part of the inhibitory effect could be ascribed to this tRNA region. A strong stimulation of DNA polymerase activity was observed when the effect of tRNA(Lys) was assayed on a recombinant HIV reverse transcriptase produced in a protease deficient yeast strain, which leads to the production of an active p66 enzyme. The same tRNAs that inhibited strongly the heterodimeric form stimulated the p66 form of HIV reverse transcriptase. The results suggest that although both enzymatic forms are able to interact with tRNA(Lys) the topography, as well as the functional implications of the interaction between the precursor and the mature form of HIV reverse transcriptase with the tRNA(Lys) primer, are different.

A new type of chemically modified tRNA as a tool for the study of tRNA-aminoacyl-tRNA synthetase interaction.

tRNA(Phe) in which the adenine and cytosine rings in the aminoacyl arm and in the anticodon loop were converted to alkylating derivatives by mild treatment with methyl chlorotetrolate was used to study the tRNA(Phe)-yeast phenylalanyl-tRNA(Phe) synthetase interaction. At neutral pH, modified tRNA inhibited the enzyme competitively. At pH 9 this binding is accompanied by irreversible inactivation of the enzyme due to alkylation of the alpha subunit of the synthetase. Such a derivatization of tRNA could probably be used to investigate the interaction of other tRNAs with their cognate synthetases.