Studies on the ribothymidine content of specific rat and human tRNAs: a postulated role for 5-methyl cytosine in the regulation of ribothymidine biosynthesis.

Total mammalian tRNAs contain on the average less than one mole of ribothymidine per mole of tRNA. Mammalian tRNAs can be grouped into at least four classes, depending upon their ribothymidine content at position 23 from the 3′ terminus. Class A contains tRNA in which a nucleoside other than uridine replaces ribothymidine (tRNA_i^Met); Class B contains tRNA in which one mole of a modified uridine (rT, ψ, or 2′-O-methylribothymidine) is found per mole of tRNA (tRNA^Ser, tRNA^Trp, and tRNA^Lys, respectively). Class C contains tRNA in which there is a partial conversion of uridine to ribothymidine (tRNA^Phe, tRNA₁^Gly, tRNA₂^Gly); Class D contains tRNA which totally lacks ribothymidine (tRNA^Val). Only those tRNAs in Class C are acceptable substrates for $\text{E.}\text{coli}$ uridine methylase, under the conditions used in these studies. These observations cannot be adequately explained solely on the basis of the presence or absence of a specific “universal” nucleoside other than U or rT at position 23 from the 3′ terminus. However, correlations can be made between the ribothymidine and 5-methylcytosine content of eucaryotic tRNA. We postulate that the presence of one or more 5-methylcytosines in and adjacent to loop III (minor loop) in individual tRNAs act to regulate the amount of ribothymidine formed by uridine methylase. Several experiments are proposed as tests for this hypothesis.     

Complex formation between transfer RNAs with complementary anticodons: use of matrix bound tRNA

It is shown that yeast tRNA^Phe, chemically coupled by its oxidized 3′CpCpA end behaves exactly as free tRNA^Phe in its ability to form a specific complex with $\text{E. coli}$ tRNA₂^Glu having a complementary anticodon. The results support models of tRNA in which the 3′CpCpA_OH end and the anticodon are not closely associated in the tertiary structure, and provide a convenient tool of general use to characterize others pairs of tRNA having complementary anticodons, as well as for highly selective purification of certain tRNA species.     

Assignment of the low field proton nuclear magnetic resonance spectrum of yeast phenylalanine transfer RNA to specific base pairs

High-resolution proton nuclear magnetic resonance spectra at 220 and 300 MHz have been used to investigate the base-pairing structure of fragments of yeast tRNA^Phe, of chemically modified tRNA^Phe and of intact tRNA^Phe. To a very good approximation the positions of the fragment spectra are additive within 0·2 part per million, indicating that factors responsible for certain structural features in the intact molecule are already present in the smaller fragments (half molecules, hairpins and $\text{3}\text{4}$ molecules). A simple first-order ring-current shift theory taken in conjunction with the cloverleaf model for tRNA^Phe (RajBhandary et al., 1967) has been used to predict the low-field (? 15 to ?11 part per million) nuclear magnetic resonance spectra and make assignments of the resolved resonances to ring NH protons of specific base pairs. The general agreement between the predicted and observed spectra to within 0·2 part per million confirms in detail the cloverleaf model for the secondary structure of tRNA^Phe in solution. It is also established that ring-current shifts are the principal factor responsible for the wide range of shifts observed in the low-field spectra. As a result it is evident that the resonances are very sensitive to small changes in the secondary structure and in some cases changes in the interbase distance as small as 0·2 Å could easily be detected. It is also clear from the analysis that certain of the resonances are sensitive to the tertiary structure of the molecule and specific examples are discussed. As with our previous study, we find no evidence for any strong Watson-Crick type base pairs beyond those predicted by the cloverleaf structure.     

Study of the Mechanism of Interaction of Oligonucleotides with the 3′-Terminal Region of tRNA<Superscript>Phe</Superscript> by Computer Modeling

Three-dimensional atomic models of complexes between yeast tRNA^Phe and 10- or 15-mer oligonucleotides complementary to the 3′-terminal tRNA sequence have been constructed using computer modeling. It has been found that rapidly formed primary complexes appear when an oligonucleotide binds to the coaxial acceptor and T stems of the tRNA^Phe along the major groove, which results in the formation of a triplex. Long stems allow the formation of a sufficiently strong complex with the oligonucleotide, which delivers its 3′-terminal nucleotides to the vicinity of the T loop adjoining the stem. These nucleotides destabilize the loop structure and initiate conformational rearrangements involving local tRNA^Phe destruction and formation of the final tRNA^Phe-oligonucleotide complementary complex. The primary complex formation and the following tRNA^Phe destruction constitute the “molecular wedge” mechanism. An effective antisence oligonucleotide should consist of three segments—(1) complex initiator, (2) primary complex stabilizer, and (3) loop destructor—and be complementary to the (free end)/loop-stem-loop tRNA structural element.     

Calorimetric investigations of the helix-coil conversion of phenylalaninespecific transfer ribonucleic acid

The enthalpy of the helix-coil conversion of phenylalaninespecific transfer ribonucleic acid from brewer's yeast (tRNA^Phe_{brewer's yeast}) has been measured using both an LKB 10700-2 batch miciocalorimeter and an adiabatic differential scanning calorimeter. In the mixing calorimeter the conversion from coil to helix was induced by mixing a tRNA^Phe solution with a solution containing an excess of MgSO₄. We measured the enthalpy of this reaction stepwise in the temperature range from +9 to +60° C. For the enthalpy of folding of tRNA^Phe from coil to helix this method yielded the remarkably high value of ?310 $\text{kcal}\text{mole}$ of tRNA^Phe. With the differential scanning calorimeter in which the helix-coil conversion is simply induced by raising the temperature we found a value of +240 $\text{kcal}\text{mole}$ of tRNA^Phe at a Tm value of 76° C and a value of +200 $\text{kcal}\text{mole}$ of tRNA^Phe at a T_m value of 50° C. A comparison of the apparent van't Hoff enthalpies with the calorimetrically measured enthalpies shows, that the cooperativity of the system increases continually with rising melting temperatures - which are achieved by increasing Mg²⁺ concentrations - reaching a constant value at about 57° C. Above this temperature value the thermodynamic behaviour of the helix-coil conversion of tRNA^Phe may be approximately described by the model of an all-or-none process.     

Preparation and stability of the helical form of poly 2'-O-ethyluridylic acid

2′ (3′)-O-ethyl-CMP was prepared by alkylation of CMP with diethylsulphate in alkaline medium and deaminated to give 2′(3′)-O-ethyl-UMP, which was phosphorylated to 2′(3′)-O-ethyl-UDP. About 90% of the product consisted of the 2′ isomer. The 2′(3′)-O-ethyl-UDP was readily polymerized by $\text{E}$. $\text{coli}$ polynucleotide phosphorylase in the presence of Mn⁺⁺, but not Mg⁺⁺. The 3′-isomer did not seriously interfere with polymerization nor did it act as a chain terminator. The resulting poly 2′-O-ethyluridylic acid formed a helical structure with a stability much higher then that of poly (rU) or poly 2′-O-methyluridylic acid. It also complexed readily with poly (rA). Implications with regard to the role of the 2′-hydroxyl in nucleic acid conformation are discussed.     

Primary structure of E. coli alanine transfer RNA: relation to the yeast phenylalanyl tRNA synthetase recognition site

Nucleotide sequence comparison of tRNAs aminoacylated by yeast phenylalanyl tRNA synthetase (PRS) have lead to the proposal that the specific nucleotides of the dihydrouridine (diHU) stem region and adenosine at the fourth position from the 3′ end are involved in the PRS recognition site. Kinetic analysis and enzymatic methylation have shown that the size of the diHU loop and the methylation of guanine at position 10 from the 5′ end both directly affect the PRS aminoacylation kinetics. $\text{E. coli}$ tRNA₁^A1a, which is aminoacylated by PRS, should therefore have 1- the specific nucleotides of the diHU stem region and, 2- adenosine at position 4 from the 3′ end. The PRS aminoacylation kinetics of this tRNA indicates that this molecule 3- has a diHU loop of 8 nucleotides and 4- has an unmethylated guanine at position 10 from the 5′ end. We report here the complete sequence of $\text{E. coli}$ tRNA₁^A1a and confirmation of each of these four predictions.     

Interaction of polyamines with fragments and whole molecules of yeast phenylalanine-specific transfer RNA

Binding of the polyamines spermidine (∼-+3) and spermine (∼-+4) to yeast tRNA^phe has been investigated by equilibrium dialysis under the same conditions used to study Mn²⁺-tRNA^phe interactions (Schreier & Schimmel, 1974). The polyamines bind to tRNA^phe in a co-operative and a non-co-operative phase, which is analogous to the behavior found with Mn²⁺. In the co-operative phase, the empirical index of co-operativity is somewhat greater for the polyamines, however. Binding constants for both the co-operative and non-co-operative phases are similar for Mn²⁺ and spermidine, and are strongest for spermine. Estimates of the total number of ligand binding sites indicate that these numbers are inversely proportional to the charge on the ligand for all three ligands. The interaction of polyamines with four large fragments of tRNA^phe shows no evidence for co-operativity. These results, together with recent kinetic studies, collectively suggest that polyamine binding to the co-operative sites is associated with tertiary structure formation and that polyamine and divalent metal ion interactions with tRNA occur by phenomenologically similar mechanisms, in spite of their structural diversity.     

Conformational Change of the L-Shaped tRNAPhe Molecule

Abstract

Fluorophore of proflavine was introduced onto the 3′-terminal ribose moiety of yeast tRNA^Phe. The distance between the fluorophore and the fluorescent Y base in the anticodon of yeast tRNA^Phe was measured by a singlet-singlet energy transfer. Conformational changes of tRNA^Phe with binding of tRNA^Glu ₂, which has the anticodon UUC complementary to the anticodon GAA of tRNA^Phe, were investigated. The distance obtained at the ionic strength of 100 mM K⁺ and 10 mM Mg²⁺ is very close to the distance from x-ray diffraction, while the distance obtained in the presence of tRNA^Glu ₂ is significantly smaller. Further, using a fluorescent probe of 4-bromomethl-7-methoxycoumarin introduced onto pseudouridine residue Ψ₅₅ in the TΨC loop of tRNA^Phe, Stern-Volmer quenching experiments for the probe with or without added tRNA^Glu ₂were carried out. The results showed greater access of the probe to the quencher with added tRNA^Glu ₂. These results suggest that both arms of the L-shaped tRNA structure tend to bend inside with binding of tRNA^Glu ₂ and some structural collapse occurs at the corner of the L-shaped structure.     

Anomalies in 5'-end [32P] labelling of transfer RNA and partial sequence of a tRNAGlu from Scenedesmus obliquus

A chloroplast tRNA_m^Met species from $\text{Scenedesmus}\text{obliquus}$ is very poorly 5′-end [${}^{32}\text{P}$] labelled using [γ-³²P]ATP and T4 polynucleotide kinase. In sequencing the tRNA using standard 5′-labelled methods a very minor contaminating tRNA is preferentially labelled. The partial tRNA sequence determined by this method has an anticodon (CUC) for tRNA^Glu.     

Studies of odd bases in yeast mitochondrial tRNA: Absence of the fluorescent “Y” base in mitochondrial DNA coded tRNAPhe, absence of 4-thiouridine

Reversed phase chromatography of mitochondrial [³H] Phe-tRNA from $\text{Saccharomyces cerevisiae}$ shows only one peak which elutes distinctly from cytoplasmic [¹⁴C] Phe-tRNA. Mitochondrial tRNA^Phe from this peak hybridizes specifically with ?⁺ and a ?^? mitochondrial DNA. Search for rare bases in mitochondrial tRNA shows the absence of the eukaryotic “Y” base and of the prokariotic s⁴U base.     

Properties of the 5'-terminus of tRNAHis: kinetics of polynucleotide kinase catalyzed exchange and effect of dephosphorylation on the aminoacylation reaction.

Bacteriophage T₄ induced polynucleotide kinase was found to be ineffective in transferring ³²P from [γ-³²P]ATP to the 5′-terminus of 5′-phosphorylated $\text{E. coli}$ tRNA^His using the ADP mediated exchange reaction. However, prior dephosphorylation with alkaline phosphatase allowed polynucleotide kinase catalyzed phosphorylation of tRNA^His. Contrary to reports for other tRNA species, alkaline phosphatase catalyzed 5′-terminus dephosphorylation destroys the amino acid accepting ability of tRNA^His. Aminoacylation competency of the tRNA^His is restored after phosphorylation with polynucleotide kinase.     

A difference in the affinity labeling of Ca2+, Mg2+-activated ATPases of normal and unc A strains of Escherichia coli by the 2',3'-dialdehyde derivative of adenosine 5'-diphosphate

The 2′,3′-dialdehyde of ADP, obtained by periodate oxidation of ADP, inhibited the hydrolytic activity of the purified Ca²⁺, Mg²⁺-activated ATPase of $\text{Escherichia}\text{coli}$. In the initial stages of the reaction inhibition was due to the reaction of 1 mol inhibitor/active site. When non-specific labelling of amino groups by the dialdehyde was lowered by the simultaneous presence of 15 mM ATP in the reaction mixture, 3 mol “ATP-protectable” binding sites/mol ATPase were found. “ATP-protectable” binding of the dialdehyde was not observed when the hydrolytically inactive ATPase of an $\text{unc A}$ mutant of $\text{E.}\text{coli}$ was used although binding of the inhibitor to non-protected amino groups still occurred. This suggests that the mutant ATPase is unable to bind ATP or that the amino groups with which the dialdehyde reacts in the native enzyme are absent or masked.     

Localization of Two Recognition Sites in Yeast Valine tRNA I

AS a part of our research on the structure–function relationships of tRNA^val_I we have been mapping the regions that take part in the recognition of valyl tRNA ligase. Using the “dissected molecule” method¹, we have shown that associated molecules consisting of tRNA^Val_I fragments lacking nucleotides in the anticodon loop, the dihydrouridine loop (D) or the thymidine loop (T) retain their acceptor activity. By contrast, dissected molecules devoid of the pentanucleotide A₃₆CACGp (the sequence A₃₆C belongs to the anticodon T₃₅AC) or lacking any quarter (F_1–19, F_17–35 or F_36–57) are inactive^2–4. Here we report a study of the acceptor activity of other incomplete tRNA^val_I molecules. The principal inference is that the dinucleotides A₃₆Cp in the anticodon loop and 5′-terminal pG₁Gp in the CCA stem are at least parts of two different recognition sites of this tRNA.     

Control of pattern duplication in the retinotectal system of Xenopus. Induction of duplication in eye fragments by secondary cuts.

Following surgical ablation of the temporal (posterior) region of the eye-bud in stage 32 Xenopus frog embryos, the surviving nasal (anterior) fragment gradually rounds up to form a functional eye and orderly retinotectal map. Large nasal fragments ($\text{N}\text{-}\text{2}\text{3}$) assemble topographically normal maps, as does the majority of nasal “half-eye” fragments; small nasal fragments ($\text{N}\text{-}\text{1}\text{3}$), and a minority of nasal half-eye fragments, give a characteristic, mirror-symmetrical duplication map, similar (but not identical) to the “double-nasal” maps which develop when two nasal half-eyes are fused to form a frank NN double-eye. Ventral fragments and temporal fragments show similar size-dependent behavior, although their characteristic duplicate maps are topographically different from those of nasal fragments and more similar to the “double-ventral” and “double-temporal” maps of VV and TT recombinant eyes. Here we show that a simple surgical transection, applied either dorsally or ventrally to large nasal ($\text{N}\text{-}\text{2}\text{3}$) fragments so as to isolate a subregion of the tissue at the dorsum or venturm of the fragment, induces full or partial duplication of the nasal type in the majority of cases. The results refute the hypothesis that special properties at the eye-bud center, by their presence or absence in the fragment, control pattern duplication, and point instead toward interactions around the circumference of the eye-bud as a crucial parameter in determining positional information in the retina.     

Function of Y in codon-anticodon interaction of tRNA Phe

Molar association constants of binding oligonucleotides to the anticodon loops of (yeast) tRNA^Phe, (yeast) tRNA_HCl^Phe and (E. coli) tRNA_F^Met have been determined by equilibrium dialysis. From the temperature dependence of the molar association constants, ΔF, ΔH and ΔS of oligomer-anticodon loop interaction have been determined. The data indicate that the free energy change of codon-anticodon interaction is highly influenced by the presence of a modified purine (tRNA^Phe), of an unmodified purine (tRNA_F^Met) or its absence (tRNA_HCl^Phe). Excision of the modified purine Y in the anticodon loop of tRNA^Phe results in a conformational change of the anticodon loop, which is discussed on the basis of the corresponding changes in ΔF, ΔH and ΔS.     

Ca 2+ -dependent allosteric regulation of nicotinamide nucleotide transhydrogenase from Pseudomonas aeruginosa

Nicotinamide nucleotide transhydrogenase from $\text{Pseudomonas}\text{aeruginosa}$ exhibits allosteric properties and has been shown to be regulated by the prevailing $\text{[NADPH]}\text{[NADP}{}^{\mathrm{+}}\text{]}$ ratio or by 2′-AMP. The present data obtained with membrane fragments from $\text{P.}\text{aerug}$. show that Ca²⁺ strongly influences the concentration of 2′-AMP or NADPH required for half-maximal stimulation. Saturating concentrations of Ca²⁺ cause full activation of the enzyme; Mn²⁺, Mg²⁺ and K⁺ are considerably less efficient and antagonistic to Ca²⁺. Some implications of these findings for the regulatory mechanism and possible physiological function of the enzyme are considered.     

The influence of spermine on the structural dynamics of yeast tRNAPhe

A tRNA^Phe derivative carrying ethidium at position 37 in the anticodon loop has been used to study the effect of spermine on conformational transitions of the tRNA. As previously reported (Ehrenberg, M., Rigler, R. and Wintermeyer, W. (1979) Biochemistry 18, 4588–4599) in the tRNA derivative the ethidium is present in three states (T₁–T₃) characterized by different fluorescence decay rates. T-jump experiments show two transitions between the states, a fast one (relaxation time 10–100 ms) between T₁ and T₂, and a slow one (100–1000 ms) between T₂ and T₃. In the presence of spermine the fast transition shows a negative temperature coefficient indicating the existence of a preequilibrium with a negative reaction enthalpy. Spermine shifts the distribution of states towards T₃, as does Mg²⁺, but the final ratio $\text{[}\text{T}{}_2\text{]}\text{[}\text{T}{}_1\text{]}$ obtained with spermine is higher than with Mg²⁺, which we tentatively interpret to mean that spermine stabilizes one particular conformation of the anticodon loop.