The crystal structure of yeast phenylalanine tRNA at 2.0 A resolution: cleavage by Mg(2+) in 15-year old crystals

We have re-determined the crystal structure of yeast tRNA(Phe) to 2. 0 A resolution using 15 year old crystals. The accuracy of the new structure, due both to higher resolution data and formerly unavailable refinement methods, consolidates the previous structural information, but also reveals novel details. In particular, the water structure around the tightly bound Mg(2+) is now clearly resolved, and hence provides more accurate information on the geometry of the magnesium-binding sites and the role of water molecules in coordinating the metal ions to the tRNA. We have assigned a total of ten magnesium ions and identified a partly conserved geometry for high-affinity Mg(2+ )binding. In the electron density map there is also clear density for a spermine molecule binding in the major groove of the TPsiC arm and also contacting a symmetry-related tRNA molecule. Interestingly, we have also found that two specific regions of the tRNA in the crystals are partially cleaved. The sites of hydrolysis are within the D and anticodon loops in the vicinity of Mg(2+).     

Lead ion binding and RNA chain hydrolysis in phenylalanine tRNA

Crystalline complexes of yeast phenylalanine tRNA and Lead (II) ion were prepared by soaking pregrown orthorhombic crystals of tRNA in saturated lead chloride solutions. The locations of tightly bound lead ions on the tRNA were determined by difference Fourier methods. There are three major lead binding sites; two of these replace tightly bound magnesium ions in the native tRNA structure. Site I is located in the dihydrouridine loop of the molecule adjacent to phosphate P18 which is specifically cleaved by lead. This is evident from changes observed in the Pb-native difference electron density maps. A possible mechanism for lead ion hydrolysis of the polynucleotide chain is proposed.     

The effect of modification of tRNA nucleotide-37 on the tRNA interaction with the P- and A-site of the 70S ribosome Escherichia coli

A modified nucleotide on the 3'-side of the anticodon loop of tRNA is one of the most important structure element regulating codon-anticodone interaction on the ribosome owing to the stacking interaction with the stack of codon-anticodon bases. The presence and identity (pyrimidine, purine or modified purine) of this nucleotide has an essential influence on the energy of the stacking interaction on A- and P-sites of the ribosome. There is a significant influence of the 37-modification by itself on the P-site, whereas there is no such one on the A-site of the ribosome. Comparison of binding enthalpies of tRNA interactions on the P- or A-site of the ribosome with the binding enthalpies of the complex of two tRNAs with the complementary anticodones suggests that the ribosome by itself significantly endows in the thermodynamics of codon-anticodon complex formation. It happens by additional ribosomal interactions with the molecule of tRNA or indirectly by the stabilization of codon-anticodon conformation. In addition to the stacking, tRNA binding in the A and P sites is futher stabilized by the interactions involving some magnesium ions. The number of them involved in those interactions strongly depends on the nucleotide identity in the 37-position of tRNA anticodon loop.     

Lead Ion Binding and RNA Chain Hydrolysis in Phenylalanine tRNA

Abstract

Crystalline complexes of yeast phenylalanine tRNA and Lead (II) ion were prepared by soaking pregrown orthorhombic crystals of tRNA in saturated lead chloride solutions. The locations of tightly bound lead ions on the tRNA were determined by difference Fourier methods. There are three major lead binding sites; two of these replace tightly bound magnesium ions in the native tRNA structure. Site I is located in the dihydrouridine loop of the molecule adjacent to phosphate P18 which is specifically cleaved by lead. This is evident from changes observed in the Pb-native difference electron density maps. A possible mechanism for lead ion hydrolysis of the polynucleotide chain is proposed.     

Yeast phenylalanine transfer RNA: atomic coordinates and torsion angles.

The atomic coordinates of yeast phenylalanine transfer RNA (tRNA) as well as the torsion angles of the polynucleotide chain are presented as derived from an x-ray diffraction analysis of orthorhombic crystals. A comparison is made between the coordinates obtained from analysis of monoclinic crystals of the same material. It is concluded that the molecule has substantially the same form in the orthorhombic and the monoclinic lattices, except for differences found between residues at the 3' end of the polynucleotides chain. A number of observations are made concerning hydrogen bonding interactions which may account for many of the residues conserved in all tRNA sequences.     

Effect of modification of tRNA nucleotide 37 on the tRNA interaction with the A and P sites of the Escherichia coli 70S ribosome

The modified nucleotide 3′ of the tRNA anticodon is an important structural element that regulates the codon-anticodon interaction in the ribosome by stacking with codon-anticodon bases. The presence and identity (pyrimidine, purine, or modified purine) of this nucleotide significantly affects the energy of stacking in the A and P sites of the ribosome. Modification of nucleotide 37 does not contribute to stacking in the A site of the 70S ribosome, while its effect is substantial in the P site. The enthalpies of tRNA interactions with the A and P sites in the ribosome are similar and considerably lower than the enthalpy of the interactions of two tRNAs with the cognate anticodons in solution, suggesting that the ribosome contributes to the enthalpy-related portion of the free energy of tRNA binding by directly forming additional interactions with tRNA or by indirectly stabilizing the conformation of the codon-anticodon complex. In addition to stacking, tRNA binding in the A and P sites is further stabilized by interactions that involve magnesium ions. The number of ions involved in the formation of the tRNA-ribosome complex depends on the identity of tRNA nucleotide 37.     

Specificity and mechanism of the cleavages induced in yeast tRNAPhe by magnesium ions

The specificity of magnesium ion-induced hydrolysis of yeast tRNAPhe in solution was studied as a function of the excess of Mg(II) ions and pH. The major cuts at phosphates 16 and 20 as well as minor cleavages at phosphates 17, 18, 21, 34 and 36 occur at all pH values in the range of 8.0-9.5, and at a molar excess of magnesium ions over the tRNA ranging from 125 to 5000. In yeast tRNA(Phe)-Y the efficiency of the anticodon and D-loop cleavages is considerably decreased while the differently modified Y-base of yellow lupin tRNA(Phe) lowers the specificity of the weak anticodon loop cleavages. The mechanism of the Mg(II)-induced cleavages is discussed on the basis of yeast tRNA(Phe) crystal structure data, and the two major D-loop cleavages are thought to be effected from two distinct magnesium binding sites. The possibility of probing the environments of magnesium binding sites in tRNAs by the induced cleavages is demonstrated, and the relevance of magnesium-induced tRNA cleavages to RNA catalysis is discussed.     

Biostructural chemistry of magnesium ion: characterization of the weak binding sites on tRNA(Phe)(yeast). Implications for conformational change and activity

The thermodynamics and kinetics of magnesium binding to tRNA(Phe)(yeast) have been studied directly by 25Mg NMR. In 0.17 M Na+(aq), tRNA(Phe) exists in its native conformation and the number of strong binding sites (Ka greater than or equal to 10(4)) was estimated to be 3-4 by titration experiments, in agreement with X-ray structural data for crystalline tRNA(Phe) (Jack et al., 1977). The set of weakly bound ions were in slow exchange and 25Mg NMR resonances were in the near-extreme-narrowing limit. The line shapes of the exchange-broadened magnesium resonance were indistinguishable from Lorentzian form. The number of weak magnesium binding sites was determined to be 50 +/- 8 in the native conformation and a total line-shape analysis of the exchange-broadened 25 Mg2+ NMR resonance gave an association constant Ka of (2.2 +/- 0.2) X 10(2) M-1, a quadrupolar coupling constant (chi B) of 0.84 MHz, an activation free energy (delta G*) of 12.8 +/- 0.2 kcal mol-1, and an off-rate (koff) of (2.5 +/- 0.4) X 10(3) s-1. In the absence of background Na+(aq), up to 12 +/- 2 magnesium ions bind cooperatively, and 73 +/- 10 additional weak binding sites were determined. The binding parameters in the nonnative conformation were Ka = (2.5 +/- 0.2) X 10(2) M-1, chi B = 0.64 MHz, delta G* = 13.1 +/- 0.2 kcal mol-1, and koff = (1.6 +/- 0.4) X 10(3) s-1. In comparison to Mg2+ binding to proteins (chi B typically ca. 1.1-1.6 MHz) the lower chi B values suggest a higher degree of symmetry for the ligand environment of Mg2+ bound to tRNA. A small number of specific weakly bound Mg2+ appear to be important for the change from a nonnative to a native conformation. Implications for interactions with the ribosome are discussed.     

Binding of spermidine to transfer ribonucleic acid

The binding of spermidine to yeast tRNAPhe and Escherichia coli tRNAGlu2 at low and high ionic strength was studied by equilibrium dialysis. Once corrected for the expected Donnan effect, the binding at low ionic strength obeys the simple relationship of equivalent binding sites, and cooperative binding of spermidine to tRNA could not be detected. At low ionic strength (0.013 M Na+ ion), tRNAPhe (yeast) has 13.9 +/- 2.3 strong spermidine binding sites per molecule with Kd = 1.39 X 10(-6) M and a few weak spermidine binding sites which were inaccessible to experimentation; tRNAGlu2 (E. coli) has 14.8 +/- 1.6 strong spermidine binding sites and 4.0 +/- 0.1 weak spermidine binding sites with Kd = 1.4 X 10(-6) M and Kd = 1.23 X 10(-4) M, respectively. At high ionic strength (0.12 M monovalent cation) and 0.01 M Mg2+, tRNAPhe (yeast) has approximately 13 strong spermidine binding sites with an apparent Kd = 3.4 X 10(-3) M while the dimeric complex tRNAPhe X tRNAGlu2 has 10.4 +/- 1.2 strong spermidine binding sites per monomer with an apparent Kd = 2.0 X 10(-3) M. In the presence of increasing Na+ ion or K+ ion concentration, spermidine binding data do not fit a model for competitive binding to tRNA by monovalent cations. Rather, analysis of binding data by the Debye-Hückel approximation results in a good fit of experimental data, indicating that monovalent cations form a counterion atmosphere about tRNA, thus decreasing electrostatic interactions. On the basis of equilibrium binding analyses, it is proposed that the binding of spermidine to tRNA occurs predominantly by electrostatic forces.     

Manganese(II) as a paramagnetic probe of the tertiary structure of transfer RNA.

The effect of manganese on both the low field (10--15 ppm) and the high field (o--3 ppm) NMR spectra of unfractionated tRNA and yeast tRNAPhe has been investigated. Trace amounts of Mn2+ cause selective broadening of resonances which are assigned to specific tertiary interactions. The order in which resonances broaden is the same as the order in which they are stabilized by the addition of magnesium, namely s4U8 - A14, U33 and A58 - T54. From this we conclude that three of the strong binding sites probably are the same for both Mn2+ and Mg2+, and that these sites are located close to the tertiary interactions which are stabilized by the strongly bound metals. The broadening data, taken in conjunction with published X-ray data on yeast tRNAPhe, permit us to suggest some plausible locations for the strong binding sites.     

Polyamine derivatives as selective RNaseA mimics

Site-selective scission of ribonucleic acids (RNAs) has attracted considerable interest, since RNA is an intermediate in gene expression and the genetic material of many pathogenic viruses. Polyamine-imidazole conjugates for site-selective RNA scission, without free imidazole, were synthesized and tested on yeast phenylalanine transfer RNA. These molecules catalyze RNA hydrolysis non-randomly. Within the polyamine chain, the location of the imidazole residue, the numbers of nitrogen atoms and their relative distances have notable influence on cleavage selectivity. A norspermine derivative reduces the cleavage sites to a unique location, in the anticodon loop of the tRNA, in the absence of complementary sequence. Experimental results are consistent with a cooperative participation of an ammonium group of the polyamine moiety, in addition to it’s binding to the negatively charged ribose-phosphate backbone, as proton source, and the imidazole moiety as a base. There is correlation between the location of the magnesium binding sites and the RNA cleavage sites, suggesting that the protonated nitrogens of the polycationic chain compete with some of the magnesium ions for RNA binding. Therefore, the cleavage pattern is specific of the RNA structure. These compounds cleave at physiological pH, representing novel reactive groups for antisense oligonucleotide derivatives or to enhance ribozyme activity.     

The affinity of magnesium binding sites in the Bacillus subtilis RNase P x pre-tRNA complex is enhanced by the protein subunit

The RNA subunit of bacterial ribonuclease P (RNase P) requires high concentrations of magnesium ions for efficient catalysis of tRNA 5'-maturation in vitro. The protein component of RNase P, required for cleavage of precursor tRNA in vivo, enhances pre-tRNA binding by directly contacting the 5'-leader sequence. Using a combination of transient kinetics and equilibrium binding measurements, we now demonstrate that the protein component of RNase P also facilitates catalysis by specifically increasing the affinities of magnesium ions bound to the RNase P x pre-tRNA(Asp) complex. The protein component does not alter the number or apparent affinity of magnesium ions that are either diffusely associated with the RNase P RNA polyanion or required for binding mature tRNA(Asp). Nor does the protein component alter the pH dependence of pre-tRNA(Asp) cleavage catalyzed by RNase P, providing further evidence that the protein component does not directly stabilize the catalytic transition state. However, the protein subunit does increase the affinities of at least four magnesium sites that stabilize pre-tRNA binding and, possibly, catalysis. Furthermore, this stabilizing effect is coupled to the P protein/5'-leader contact in the RNase P holoenzyme x pre-tRNA complex. These results suggest that the protein component enhances the magnesium affinity of the RNase P x pre-tRNA complex indirectly by binding and positioning pre-tRNA. Furthermore, RNase P is inhibited by cobalt hexammine (K(I) = 0.11 +/- 0.01 mM) while magnesium, manganese, cobalt, and zinc compete with cobalt hexammine to activate RNase P. These data are consistent with the hypothesis that catalysis by RNase P requires at least one metal-water ligand or one inner-sphere metal contact.     

The binding of calcium to human fibronectin

The binding of calcium to human plasma fibronectin has been measured by equilibrium dialysis at 25° in 0.1 M NaCl 50mM Tris HCL, pH 7.4. Curve fitting of the binding data indicates that fibronectin has two strong calcium binding sites per chain (Mr 220,000), KD = 1.3 mM and approximately 12 weak sites, KD = 2.3 mM. No significant displacement of bound calcium by magnesium was observed at magnesium concentrations up to 1 mM. Calcium binding to a pair of tryptic fragments of fibronectin (Mr ? 160,000 and 180,000) that bind to gelatin has also been investigated. These fragments have a single class of calcium binding sites, with 2.2 sites per chain, KD = 1.1 mM. Negligible calcium binding to tryptic fragments derived from other regions of the fibronectin molecule was observed.     

Isoleucyl transfer ribonucleic acid synthetase. Competitive inhibition with respect to transfer ribonucleic acid by blue dextran.

The inhibitory effects of blue dextran and a small dye molecule derived from it (F3GA-OH) on the steady-state reaction catalyzed by Escherichia coli isoleucy-tRNA synthetase have been studied. Blue dextran gave uncompetitive inhibition with respect to Mg.ATP, mixed inhibition with respect to L-isoleucine, and competitive inhibition with respect to tRNA. The small dye molecule (F3GA-OH) was also competitive with respect to tRNA. These inhibition patterns were not consistent with the bi-uni-uni-bi Ping Pong mechanism generally accepted for aminoacyl-tRNA synthetases. They were consistent with a mechanism in which a second L-isoleucine is bound after isoleucyl-AMP synthesis and before transfer of the isoleucyl moiety to tRNA. Enzyme-bound L-isoleucine lowered the affinity of the enzyme for blue dextran approximately fivefold, a value comparable to the ninefold lowering of the enzyme's affinity for tRNA upon binding L-isoleucine. The affinity of the synthetase for F3GA-OH (K1 = 1.0 X 10(-7) M) is approximately fivefold higher than its affinity for blue dextran (K1 = 5.3 X 10(-7) M). These results indicate that blue dextran and its derivatives may be useful for kinetic and physical studies of polynucleotide binding sites on proteins as well as NAD and ATP sites.     

Thermodynamics of the Op18/stathmin-tubulin interaction

Op18/stathmin (stathmin) is an intrinsically disordered protein involved in the regulation of the microtubule filament system. One function of stathmin is to sequester tubulin dimers into assembly incompetent complexes, and recent studies revealed two tubulin binding sites per stathmin molecule. Using high sensitivity isothermal titration calorimetry, we document that at 10 degrees C and under the conditions of 80 mM PIPES, pH 6.8, 1 mM EGTA, 1 mM MgCl2, 1 mM GTP these two binding sites are of equal affinity with an equilibrium binding constant of K0 = 6.0 x 10(6) m(-1). The obtained large negative molar heat capacity change of deltaCp0 = -860 cal mol(-1) K(-1) (referring to tubulin) for the tubulin-stathmin binding equilibrium suggests that the hydrophobic effect is the major driving force of the binding reaction. Replacing GTP by GDP on beta-tubulin had no significant effect on the thermodynamic parameters of the tubulin-stathmin binding equilibrium. The proposed pH-sensitive dual function of stathmin was further evaluated by circular dichroism spectroscopy and nuclear magnetic resonance. At low temperatures, stathmin was found to be extensively helical but devoid of any stable tertiary structure. However, in complex with two tubulin subunits stathmin adopts a stable conformation. Both the stability and conformation of the individual proteins and complexes were not significantly affected by small changes in pH. A 4-fold decrease in affinity of stathmin for tubulin was revealed at pH 7.5 compared with pH 6.8. This decrease could be attributed to a weaker binding of the C terminus of stathmin. These findings do not support the view that stathmin works as a pH-sensitive protein.     

NMR analysis of bovine tRNATrp: conformation dependence of Mg2+ binding

NMR was used to study the solution structure of bovine tRNA(Trp) hyperexpressed in Escherichia coli. With the use of (15)N labeling and site-directed mutagenesis to assign overlapping resonances through the base pair replacement of U(71)A(2) by G(2)C(71), U(27)A(43) by G(27)C(43), and G(12)C(23) by U(12)A(23), the resonances of all 26 observable imino protons in the helical regions and in the tertiary interactions were assigned unambiguously by means of two-dimensional nuclear Overhauser effect spectroscopy and heteronuclear single quantum coherence methods. When the discriminator base A(73) and the G(12)C(23) base pair on the D stem, two identity elements on bovine tRNA(Trp) that are important for effective recognition by tryptophanyl-tRNA synthetase, were mutated to the ineffective forms of G(73) and U(12)A(23), respectively, NMR analysis revealed an important conformational change in the U(12)A(23) mutant but not in the G(73) mutant molecule. Thus A(73) appears to be directly recognized by tryptophanyl-tRNA synthetase, and G(12)C(23) represents an important structural determinant. Mg(2+) effects on the assigned resonances of imino protons allowed the identification of strong, medium, and weak Mg(2+) binding sites in tRNA(Trp). Strong Mg(2+) binding modes were associated with the residues G(7), s(4)U(8) (where s(4)U is 4-thiouridine), G(12), and U(52). The observations that G(42) was associated with strong Mg(2+) binding in only the U(12)A(23) mutant tRNA(Trp) but not the wild type or G(73) mutant tRNA(Trp) and that the G(7), s(4)U(8), G(24), and G(22) imino protons are associated with a two-site Mg(2+) binding mode in wild type and G(73) mutant but only a one-site mode in the U(12)A(23) mutant established the occurrence of conformational change in the U(12)A(23) mutant tRNA(Trp). These observations also established the dependence of Mg(2+) binding on tRNA conformation and the usefulness of Mg(2+) binding sites as conformational probes. The thermal titration of tRNA(Trp) in the presence and absence of 10 mm Mg(2+) indicated that overall tRNA(Trp) structure stability was increased by more than 15 degrees C by the presence of Mg(2+).     

Mg2+-induced tRNA folding

Mg(2+)-induced folding of yeast tRNA(Phe) was examined at low ionic strength in steady-state and kinetic experiments. By using fluorescent labels attached to tRNA, four conformational transitions were revealed when the Mg(2+) concentration was gradually increased. The last two transitions were not accompanied by changes in the number of base pairs. The observed transitions were attributed to Mg(2+) binding to four distinct types of sites. The first two types are strong sites with K(diss) of 4 and 16 microM. The sites of the third and fourth types are weak with a K(diss) of 2 and 20 mM. Accordingly, the Mg(2+)-binding sites previously classified as "strong" and "weak" can be further subdivided into two subtypes each. Fluorescent transition I is likely to correspond to Mg(2+) binding to a unique strong site selective for Mg(2+); binding to this site causes only minor A(260) change. The transition at 2 mM Mg(2+) is accompanied by substantial conformational changes revealed by probing with ribonucleases T1 and V1 and likely enhances stacking of the tRNA bases. Fast and slow kinetic phases of tRNA refolding were observed. Time-resolved monitoring of Mg(2+) binding to tRNA suggested that the slow kinetic phase was caused by a misfolded tRNA structure formed in the absence of Mg(2+). Our results suggest that, similarly to large RNAs, Mg(2+)-induced tRNA folding exhibits parallel folding pathways and the existence of kinetically trapped intermediates stabilized by Mg(2+). A multistep scheme for Mg(2+)-induced tRNA folding is discussed.     

Probing the environment of lanthanide binding sites in yeast tRNA(Phe) by specific metal-ion-promoted cleavages

Specific yeast tRNA(Phe) hydrolysis brought about by europium ions has been studied in detail using the 32P-end-labeled tRNA and polyacrylamide gel electrophoresis. The dependence of the induced cleavages on pH, temperature and concentration of the europium ions has been determined. Europium hydrolyzes yeast tRNA(Phe) in the D-loop at phosphates 16 and 18, and the anticodon loop of phosphates 34 and 36. The two D-loop cuts are thought to take place from two distinct europium binding sites, while the two anticodon loop cleavages from a single site. Eight other members of the lanthanide series and ytrium give basically the same pattern of cleavages as europium. The specific cleavages taking place in the anticodon loop occur in an intramolecular mode from the lanthanide binding site that has not been found in yeast tRNA(Phe) crystal structure. It appears from the comparison of the europium-promoted cuts with those generated by magnesium and lead that the former two ions give more similar but not identical cleavage patterns. The usefulness of the specific cleavages induced by lanthanides for probing their own and magnesium binding sites in tRNA is discussed.