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.     

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.     

High resolution structures of p-aminobenzamidine- and benzamidine-VIIa/soluble tissue factor: unpredicted conformation of the 192-193 peptide bond and mapping of Ca2+, Mg2+, Na+, and Zn2+ sites in factor VIIa

Factor VIIa (FVIIa) consists of a gamma-carboxyglutamic acid (Gla) domain, two epidermal growth factor-like domains, and a protease domain. FVIIa binds seven Ca(2+) ions in the Gla, one in the EGF1, and one in the protease domain. However, blood contains both Ca(2+) and Mg(2+), and the Ca(2+) sites in FVIIa that could be specifically occupied by Mg(2+) are unknown. Furthermore, FVIIa contains a Na(+) and two Zn(2+) sites, but ligands for these cations are undefined. We obtained p-aminobenzamidine-VIIa/soluble tissue factor (sTF) crystals under conditions containing Ca(2+), Mg(2+), Na(+), and Zn(2+). The crystal diffracted to 1.8A resolution, and the final structure has an R-factor of 19.8%. In this structure, the Gla domain has four Ca(2+) and three bound Mg(2+). The EGF1 domain contains one Ca(2+) site, and the protease domain contains one Ca(2+), one Na(+), and two Zn(2+) sites. (45)Ca(2+) binding in the presence/absence of Mg(2+) to FVIIa, Gla-domainless FVIIa, and prothrombin fragment 1 supports the crystal data. Furthermore, unlike in other serine proteases, the amide N of Gly(193) in FVIIa points away from the oxyanion hole in this structure. Importantly, the oxyanion hole is also absent in the benzamidine-FVIIa/sTF structure at 1.87A resolution. However, soaking benzamidine-FVIIa/sTF crystals with d-Phe-Pro-Arg-chloromethyl ketone results in benzamidine displacement, d-Phe-Pro-Arg incorporation, and oxyanion hole formation by a flip of the 192-193 peptide bond in FVIIa. Thus, it is the substrate and not the TF binding that induces oxyanion hole formation and functional active site geometry in FVIIa. Absence of oxyanion hole is unusual and has biologic implications for FVIIa macromolecular substrate specificity and catalysis.     

Monovalent cation binding to cubic insulin crystals.

Two localized monovalent cation binding sites have been identified in cubic insulin from 2.8 A-resolution difference electron density maps comparing crystals in which the Na+ ions have been replaced by Tl+. One cation is buried in a closed cavity between insulin dimers and is stabilized by interaction with protein carbonyl dipoles in two juxtaposed alternate positions related by the crystal dyad. The second cation binding site, which also involves ligation with carbonyl dipoles, is competitively occupied by one position of two alternate His B10 side chain conformations. The cation occupancy in both sites depends on the net charge on the protein which was varied by equilibrating crystals in the pH range 7-10. Detailed structures of the cation binding sites were inferred from the refined 2-A resolution map of the sodium-insulin crystal at pH 9. At pH 9, the localized monovalent cations account for less than one of the three to four positive counterion charges necessary to neutralize the negative charge on each protein molecule. The majority of the monovalent counterions are too mobile to show up in the electron density maps calculated using data only at resolution higher than 10 A. Monovalent cations of ionic radius less than 1.5 A are required for crystal stability. Replacing Na+ with Cs+, Mg++, Ca++ or La+++ disrupts the lattice order, but crystals at pH 9 with 0.1 M Li+, K+, NH4+, Rb+ or Tl+ diffract to at least 2.8 A resolution.     

Cooperativity in low-affinity Mg2+ binding to tRNA

The Pb2+-catalyzed cleavage of tRNAPhe has been used to probe the effect of Na+ and Mg2+ binding to tRNA. Na+ is a noncompetitive inhibitor of the Pb2+-catalyzed cleavage. Millimolar Mg2+ is also a noncompetitive inhibitor. Analysis of the Mg2+ data show that at least two sites are involved in binding and that there is an interaction between the sites (cooperativity). Low-affinity Mg2+ binding is thus different from "weak" and "strong" Mg2+ binding to tRNA characterized previously. We postulate that the alterations induced by low-affinity Mg2+ binding in tRNA mimic to some extent those brought about in RNA by the interaction with a protein factor and that at appropriate [Mg2+] the whole structure of tRNA is able to respond in a concerted way to a signal from the environment such as aminoacylation or codon binding.     

Cleavage of tRNA by Fe(II)-bleomycin.

We have investigated the action of the chemotherapeutic agent Fe(II)-bleomycin on yeast tRNA(Phe), an RNA of known three-dimensional structure. In the absence of Mg2+ ions, the RNA is cleaved preferentially at two major positions, A31 and G53, both of which are located at the terminal base pairs of hairpin loops, and coincide with the location of tight Mg2+ binding sites. A fragment of the tRNA (residues 47-76) containing the T stem-loop is also cleaved specifically at G53. Cleavage of both the intact tRNA and the tRNA fragment is abolished in the presence of physiological concentrations of Mg2+ (> 0.5 mM). Since Fe(II) is not displaced from bleomycin under these conditions, we infer that tight binding of Mg2+ to tRNA excludes productive interactions between Fe(II)-bleomycin and the RNA. These results also show that loss of cleavage is not due to Mg(2+)-dependent formation of tertiary interactions between the D and T loops. In contrast, cleavage of synthetic DNA analogs of the anticodon and T stem-loops is not detectably inhibited by Mg2+, even at concentrations as high as 50 mM. In addition, the site specificities observed in cleavage of RNA and DNA differ significantly. From these results, and from similar findings with other representative RNA molecules, we suggest that the cleavage of RNA by Fe(II)-bleomycin is unlikely to be important for its therapeutic action.     

Aminoglycoside binding displaces a divalent metal ion in a tRNA-neomycin B complex

Aminoglycosides bind to RNA and interfere with its function, and it has been suggested that aminoglycoside binding to RNA displaces essential divalent metal ions. Here we demonstrate that addition of various aminoglycosides inhibited Pb2+-induced cleavage of yeast tRNA(Phe). Cocrystallization of yeast tRNA(Phe) and an aminoglycoside, neomycin B, resulted in crystals that diffracted to 2.6 A and the structure of the complex was solved by molecular replacement. The structure shows that the neomycin B binding site overlaps with known divalent metal ion binding sites in yeast tRNA(Phe), providing direct evidence for the hypothesis that aminoglycosides displace metal ions. Additionally, the neomycin B binding site overlaps with major determinants for Escherichia coli phenylalanyl-tRNA-synthetase. Here we present data demonstrating that addition of neomycin B inhibited aminoacylation of E. coli tRNA(Phe) in the mid microM range. Given that aminoglycoside and metal ion binding sites overlap, we discuss that aminoglycosides can be considered as 'metal mimics'.     

Lead-catalysed specific cleavage of ribosomal RNAs.

Ribosomes have long been known to require divalent metal ions for their functional integrity. Pb2+-induced cleavage of the sugar-phosphate backbone has now been used to probe for metal binding sites in rRNA. Only three prominent Pb2+cleavages have been detected, with cleavage sites 5' of G240 in 16S rRNA and two sites 5' of A505 and C2347 in 23S rRNA. All cleavages occur in non-paired regions of the secondary structure models of the rRNAs and can be competed for by high concentrations of Mg2+, Mn2+, Ca2+ and Zn2+ ions, suggesting that lead is bound to general metal binding sites. Although Pb2+ cleavage is very efficient, ribosomes with fragmented RNAs are still functional in binding tRNA and in peptidyl transferase activity, indicating that the scissions do not significantly alter ribosomal structure. One of the lead cleavage sites (C2347 in 23S RNA) occurs in the vicinity of a region which is implicated in tRNA binding and peptidyl transferase activity. These results are discussed in the light of a recent model which proposes that peptide bond formation might be a metal-catalysed process.     

Strong magnesium binding sites in yeast phenylalanine transfer RNA.

To ascertain the sites that are available for strong binding between magnesium ions and phosphate groups in yeast phenylalanine transfer RNA, all distances below 5.5 A separating the phosphoryl oxygens (Op) of the 76 nucleotide residues have been computed from the latest atomic coordinates for the monoclinic form of the tRNA crystallized in the presence of magnesium chloride. The 5.5 A distance is chosen as the upper limit expected for Op....Op distances involved in strong magnesium-phosphate binding, on the basis of studies on a model magnesium phosphodiester hydrate, taking into account the quoted standard deviation in the tRNA atomic coordinates. It is concluded that there are four possible sites for strong magnesium binding in the tRNA molecule, in addition to the three sites previously reported. One of the hypothetical sites: m2G10-OL, U47-OR, could be involved in the first stage of melting of the tRNA molecule, and may be relevant to tertiary structure stabilization, since it links the dihydrouridine arm with the extra (V) loop.     

Structural changes of yeast tRNA(Tyr) caused by the binding of divalent ions in the presence of spermine

The existence of specific sites in tRNA for the binding of divalent cations has been seriously questioned by electrostatic considerations [Leroy & Guéron (1979) Biopolymers, 16, 2429-2446]. However, our earlier studies of the binding of Mg2+ and Mn2+ to yeast tRNA(Tyr) have indicated that spermine creates new binding sites for divalent cations [Weygand-Durasevi? et al. (1977) Biochim. Biophys, Acta, 479, 332-344; N?thig-Laslo et al. (1981) Eur. J. Biochem. 117, 263-267]. We have now used yeast tRNA(Tyr), spin labeled at the hypermodified purine (i6A-37) in the anticodon loop, to study the effect of spermine on the binding of manganese ions. The presence of eight spermine molecules per tRNA(Tyr) at high ionic strength (0.2 M NaCl, 0.05 M triethanolamine.HCl) and at low temperature (7 degrees C) enhances the binding of manganese to tRNA(Tyr). This effect could not be explained by electrostatic binding. The initial binding of manganese to tRNA(Tyr) affects the motional properties of the spin label indicating a change of the conformation of the anticodon loop. From the absence of the paramagnetic effect of manganese on the ESR spectra of the spin label one can conclude that the first binding site for manganese is at a distance from i6A-37, influencing the spin label motion through a long-range effect. The enhancement of the binding of manganese to tRNA(Tyr) by spermine is lost upon destruction of its specific macromolecular structure and it does not occur in single stranded or in double-stranded polynucleotides. The observed effect can be explained by the binding of Mn2+ to new sites, created by the binding of spermine, which are specific for the macromolecular structure of tRNA.     

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.     

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.     

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+).     

Effect of europium(III) on the thermal denaturation and cleavage of transfer ribonucleic acids

The interaction of tRNA with Eu(III) has been studied by optical and gel electrophoretic tecfhniques. At low levels (less than six metals per tRNA), Eu(III) stabilizes yeast tRNA^Phe against thermal denaturation; however, at higher levels (about eight to ten Eu/tRNA) the tRNA is destabilized by Eu(III). This may have important implications regarding recent attempts to grow crystals of tRNA from solutions containing europium. Comparative studies of the effects of Mg(II) and Eu(III) on tRNA structure confirm that the first four Eu(III) ions are more strongly bound than Mg(II). At slightly elevated temperatures (50°C, pH 7) the binding of Eu(III) catalyzes the hydrolysis of the tRNA backbone. From an analysis of the fragments produced by the hydrolysis and of the variation in the rate of cleavage as a function of the metal per tRNA ratio, we conclude that (i) the addition of Eu(III) to the tRNA is sequential, (ii) the first Eu(III) is bound in close proximity to the two dihydrouridine residues, and (iii) the rate of hydrolysis depends on the number of Eu(III) free in solution. Metals bound at sites 2–4 are relatively much less active in promoting the cleavage but the metal bound at site 5 is again active. The initial cleavage products are shown to be identical with those obtained using magnesium, zinc, or lead.     

Structural details at active site of hen egg white lysozyme with di- and trivalent metal ions

Metal binding to lysozyme has received wide interest. In particular, it is interesting that Ni2+, Mn2+, Co2+, and Yb3+ chloride salts induce an increase in the solubility of the tetragonal form in crystals of hen egg white lysozyme at high salt concentration, but that Mg2+ and Ca2+ chloride salts do not. To investigate the interactions of the di- and trivalent metal ions with the active site of lysozyme and compare the effects of the di- and trivalent metal ions on molecular conformation of lysozyme based on the structural analysis, the crystal structures of hen egg white lysozyme grown at pH 4.6, in the presence of 0.5 M MgCl2, CaCl2, NiCl2, MnCl2, CoCl2, and YbCl3, have been determined by X-ray crystallography at 1.58 A resolution. The crystals grown in these salts have an identical space group, P4(3)2(1)2. The molecules show no conformational changes, irrespective of the salts used. Ni2+ and Co2+ binding to the Odelta atom of Asp52 in the active site at 1.98 and 2.02 A, respectively, and Yb3+ binding to both the Odelta atom of Asp52 and the Odelta1 atom of Asn46 at 2.25 A have been identified. The binding sites of Mn2+, Mg2+, and Ca2+ have not been found from different Fourier electron density maps. The Ni2+ and Co2+ ions bind to the Odelta atom of Asp52 at almost the same position, while the Yb3+ ion takes a different position from the Ni2+ and Co2+ ions. On the other hand, the anion Cl-, interacting with the Oeta atom of Tyr23 at a site of about 2.90 A, has also been determined for each crystal.     

The binding of polyamines and of ethidium bromide to tRNA.

The binding of spermidine and ethidium bromide to mixed tRNA and phenylalanine tRNA has been studied under equilibrium conditions. The numbers and classes of binding sites obtained have been compared to those found in complexes isolated by gel filtration a low ionic strength. The latter complexes contain 10-11 moles of either spermidine or ethidium per mole of tRNA; either cation is completely displaceable by the other. In ethidium complexes, the first 2-3 moles are bound in fluorescent binding sites; the remaining 7-8 molecules bind in non-fluorescent form. At least one of the binding sites for spermidine appears similar to a binding site for fluorescent ethidium. Similar results are found with E. coli formylmethionine tRNA. Spermine, in excess of 18-20 moles per mole tRNA, causes precipitation of the complex. Putrescine does not form isolable complexes with yeast tRNA and displaces ethidium less readily from preformed ethidium-tRNA complexes. Under equilibrium conditions, in the absence of Mg++, there are 16-17 moles of spermidine bound per mole of tRNA as determined by equilibrium dialysis. Of these, 2-3 bind with a Ksence of 9 mM Mg++, the total number of binding sites is decreased slightly and there appears to be only one class of sites with a Ka = 600 M(-1). Quantitatively similar results are obtained for the binding of spermidine to yeast phenylalanine tRNA. When the interaction between ethidium bromide and mixed tRNA is studied by equilibrium dialysis or spectrophotometric titration, two classes of binding sites are obtained: 2-3 molecules bind with an average Ka = 6.6 x 10(5) M(-1) and 14-15 molecules bind with an average Ka = 4.1 x 10(4) M(-1). Spermidine, spermine, and Mg++ compete effectively for both classes of ethidium sites and have the effect of reducing the apparent binding constants for ethidium. When the binding of ethidium is studied by fluorometry, there are 3-4 highly fluorescent sites per tRNA. These sites are also affected by spermidine, spermine and Mg++. Putrescine has little effect on any of the classes of binding sites. These data are consistent with those found under non-equilibrium conditions. They suggest that polyamines bind to fairly specific regions of tRNA and may be involved in the maintenance of certain structural features of tRNA.     

Crystallisation and preliminary analysis of glucose isomerase from Streptomyces albus

The glucose isomerase of Streptomyces albus has been crystallised from a dilute solution of magnesium chloride buffered at a pH of 6.8-7.0. The crystals are in the space group I222 with cell dimensions a = 93.9 A, b = 99.5 A and c = 102.9 A. There is one monomer of the tetrameric molecule per asymmetric unit of the crystal and the packing density is 2.93 A3.Da-1. The tetramer sits on the 222 symmetry point of the crystal. Native data have been recorded to a resolution of 1.9 A and the crystals diffract to about 1.5 A. The alpha-carbon coordinates of the Arthrobacter glucose isomerase and the backbone coordinates of the S. olivochromogenes enzyme determined by other groups have been oriented in the present cell. The structure is currently being refined. The binding of several metal ions to the two metal sites has been analysed.     

Metal substitution in transferrins: the crystal structure of human copper-lactoferrin at 2.1-A resolution.

The structural consequences of binding a metal other than iron to a transferrin have been examined by crystallographic analysis of human copper-lactoferrin, Cu2Lf. X-ray diffraction data were collected from crystals of Cu2Lf, using a diffractometer, to 2.6-A resolution, and oscillation photography on a synchrotron source, to 2.1-A resolution. The structure was refined crystallographically, by restrained least-squares methods, starting with a model based on the isomorphous diferric structure from which the ligands, metal ions, anions, and solvent molecules had been deleted. The final model, comprising 5321 protein atoms (691 residues), 2 Cu2+ ions, 2 (bi)carbonate ions, and 308 solvent molecules has good stereochemistry (rms deviation of bond lengths from standard values of 0.018 A) and gives a crystallographic R value of 0.196 for 43,525 reflections in the range 7.5-2.1-A resolution. The copper coordination is different in the two binding sites. In the N-terminal site, the geometry is square pyramidal, with equatorial bonds to Asp 60, Tyr 192, His 253, and a monodentate anion and a longer apical bond to Tyr 92. In the C-terminal site, the geometry is distorted octahedral, with bonds to Asp 395, Tyr 435, Tyr 528, and His 597 and an asymmetrically bidentate anion. The protein structure is the same as for the diferric protein, Fe2Lf, demonstrating that the closure of the protein domains over the metal is the same in each case irrespective of whether Fe3+ or Cu2+ is bound and that copper could be transported and delivered to cells equally well as iron. The differences in metal coordination are achieved by small movements of the metal ion and anion within each binding site, which do not affect the protein structure.