Role of divalent metal ions in the hammerhead RNA cleavage reaction.

A hammerhead self-cleaving domain composed of two oligoribonucleotides was used to study the role of divalent metal ions in the cleavage reaction. Cleavage rates were measured as a function of MgCl2, MnCl2, and CaCl2 concentration in the absence or presence of spermine. In the presence of spermine, the rate vs metal ion concentration curves are broader, and lower concentrations of divalent ions are necessary for catalytic activity. This suggests that spermine can promote proper folding of the hammerhead and one or more divalent ions are required for the reaction. Six additional divalent ions were tested for their ability to support hammerhead cleavage. In the absence of spermine, rapid cleavage was observed with Co2+ while very slow cleavage occurred with Sr2+ and Ba2+. No detectable specific cleavage was observed with Cd2+, Zn2+, or Pb2+. However, in the presence of 0.5 mM spermine, rapid cleavage was observed with Zn2+ and Cd2+, and the rate with Sr2+ was increased, indicating that while these three ions could not promote proper folding of the hammerhead they were able to stimulate cleavage. These results suggest certain divalent ions either participate directly in the cleavage mechanism or are specifically involved in stabilizing the tertiary structure of the hammerhead. Additionally, an altered divalent metal ion specificity was observed when a unique phosphorothioate linkage was inserted at the cleavage site. The substitution of a sulfur for a nonbridging oxygen atom substantially reduced the affinity of an important Mg2+ ion necessary for efficient cleavage. In contrast, the reaction proceeds normally with Mn2+, presumably due to its ability to coordinate with both oxygen and sulfur.(ABSTRACT TRUNCATED AT 250 WORDS)     

Electrostatic effects in divalent ion binding to tRNA.

The binding of Mn²⁺ to yeast tRNA^Phe at 25°C is measured by esr, and found to depend strongly on the concentration of monovalent cations, showing the importance of electrostatic effects. In low sodium (<15mM/l.), the affinity is high and the Scatchard plots are distinctly curved. In high sodium (>50mM/l.), the affinity and the curvature are reduced. In a limited range of sodium concentrations (15–30mM/l.), the folding of tRNA which is induced by the divalent ions results in cooperative binding, leading to upwards convexity of the Scatchard plot. An electrostatic model is developed, based on a single type of binding site which we take to be the phosphates, with a binding constant for Mn²⁺ in the range of that found for ApA, 10 l./M. We compute the change in the binding constant due to the electrostatic potential of the distant charges (other phosphates and counterions), using a single set of parameters for all sodium concentrations. The model predicts that the plots in low sodium are curved, and a good fit to the experimental results is obtained: it is therefore not legitimate or necessary to interpret these results in terms of two types of binding sites. In high salt, the model gives plots that are only slightly curved, corresponding to weaker electrostatic effects. This shows that a search for sites with a special binding mode should be done in high salt. The computed plots are in good agreement with the data, except for slight differences concerning the first bound ions, which give a possible indication in favor of special binding. Given the observation of one special site for Mg²⁺ at 4°C in high sodium [Stein, A. & Crothers, D. M. (1976) Biochemistry 15 , 157–160] in E. coli tRNA^fMet, we have measured the binding of Mn²⁺ at lower temperature. At 12°C, in both yeast tRNA^Phe and E. coli tRNA^fMet, the plots clearly indicate special binding. A site found in high sodium is on a very different footing from the four to six so-called strong sites unduly derived from low-salt binding plots.     

Protein folding and tRNA biology

Polypeptides can fold into tertiary structures while they are synthesized by the ribosome. In addition to the amino acid sequence, protein folding is determined by several factors within the cell. Among others, the folding pathway of a nascent polypeptide can be affected by transient interactions with other proteins, ligands, or the ribosome, as well as by the translocation through membrane pores. Particularly, the translation machinery and the population of tRNA under different physiological or adaptive responses can dramatically affect protein folding. This review summarizes the scientific evidence describing the role of translation kinetics and tRNA populations on protein folding and addresses current efforts to better understand tRNA biology. It is organized into three main parts, which are focused on: (i) protein folding in the cellular context; (ii) tRNA biology and the complexity of the tRNA population; and (iii) available methods and technical challenges in the characterization of tRNA pools. In this manner, this work illustrates the ways by which functional properties of proteins may be modulated by cellular tRNA populations.     

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.     

Inactivation and reactivation of phosphoprotein phosphatase of rabbit skeletal muscle. Role of ATP and divalent metal ions.

The regulatory mechanism of a phosphoprotein phosphatase (EC 3.1.3.16), which is considered to catalyze the dephosphorylation reaction of several phosphoproteins (glycogen synthetase-D (EC 2.4.1.11), phospho-form of phosphorylase b kinase (EC 2.7.1.38), phosphohistone and phosphorylase a (EC 2.4.1.1)), was studied with partially purified preparations from rabbit skeletal muscle. Time- and temperature-dependent inactivation and reactivation of phosphohistone phosphatase, as well as phosphorylase phosphatase (EC 3.1.3.17), were observed on pre0incubation of the enzyme(s) with ATP, and subsequent incubation with divalent metal ions (Mg2+, Mn2+, or Co2+) without any change of molecular size. Manganese, however, instantly restored the activity of the ATP-inactivated enzyme, and increased the maximal velocity of the enzyme while decreasing its affinity to phosphorylase a. However, the metal ion inhibited the reactivated enzyme competively with respect to phosphorylase a. It is suggested that phosphoprotein phosphatase(s) is a metalloenzyme, and that ATP results in a conformational change of the enzyme protein in such a way that a metal ion can be easily released due to the chelating effect of ATP, or incorporated (in the presence of excess metal ions) into the enzyme protein.     

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.     

Computer simulation of tRNA secondary structure folding

Computer simulation results of folding linear RNA moleculesinto secondaty structures are presented. The structure is formedby two interacting processes: the RNA molecular chain growth(beginning from an initial length, L_o), and the structuring(secondary structure sequential growth in the region of theexisting molecular chain, based on the local free energy minimizationby sequential addition of elementary substruc tures-stems).It was found that the final secondary structure formation isgreatly influenced by the ‘structuring period’ T(the ratio of the molecular chain growth rate to the structuringrate), and the direction of RNA synthesis. The computer simulationhas been performed for 219 and 906 tRNA genes from two publishedcatalogues, on the whale two-dimensional domain (T,L₀) parameters,by using four known free-energy models. Minimwn stem lengthand molecular chain growth direction have been also varied Thecalculated secondary structures have been compared to the naturaltRNA structures given in the catalogues, and the region of bestcoincidence for the model parameters has been determined. Ithas been proved that, on average, >86% of the paired basesof natural tRNA structures appear in the folding simulation.     

Interaction and conformational changes of chromatin with divalent ions.

We have investigated the interaction of divalent ions with chromatin towards a closer understanding of the role of metal ions in the cell nucleus. The first row transition metal ion chlorides MnCl2, CoCl2, NiCl2 and CuCl2 lead to precipitation of chicken erythrocyte chromatin at a significantly lower concentration than the alkali earth metal chlorides MgCl2, CaCl2 and BaCl2. A similar distinction can be made for the compaction of chromatin to the "30 nm" solenoid higher order structure which occurs at lower MeCl2 concentration in the first group but at the same MeCl2 concentration within each group. In other experiments in which mixed solutions of NaCl and of MgCl2 were examined, it is shown that increasing NaCl concentration leads to increasing solubility in the presence of MgCl2. Best compaction of chromatin was obtained at 40 mM NaCl and 0.8 mM MgCl2 at a value A260 approximately 0.8. Similar experiments were undertaken with mixtures of NaCl and MnCl2.     

Ferritin. Binding of beryllium and other divalent metal ions

Rat liver homogenates in 0.1 M Tris, pH 7.5, were heated to 80 degrees C, cooled immediately, and centrifuged at 24,000 X g, and 7Be2+ was added to the supernatant. Twenty-five per cent of the radioactivity was bound to a single protein. It was purified to homogeneity and identified to be ferritin as judged by different criteria. These were sucrose density gradient centrifugation, electrophoresis in polyacrylamide gel of the native or sodium dodecyl sulfate-treated protein, reactivity to antibodies, isoelectric focusing, and total amino acid composition. Comparative study of the ability of ferritin or apoferritin to bind Cd2+, Zn2+, Cu2+, and Be2+ was conducted by using a gel equilibrium technique, Centifree micropartition technique, and microcentrifuge desalting technique. Ferritin could be saturated with Cd2+ or Zn2+ or Cu2+ but not with Be2+ even after 800 g atoms of Be2+ were bound. None of the bound Be2+ was dialyzable at 4 degrees C in 0.05 Tris acetate buffer, pH 8.5, but at pH 6.5 over 80% of the bound metal ion was dialyzed after 72 h. By contrast, apoferritin bound similar amounts of all four metal ions, some of which were dialyzable. By spectrophotometric titrations at pH 6.5 of Be2+ with sulfosalicylic acid (SSA), BeKDSSA was calculated to be 5.0 X 10(-6) M and by competition of sulfosalicyclic acid and ferritin for Be2+ the BeKDferritin was calculated to be 6.8 X 10(-6) M.     

Winding of the DNA helix by divalent metal ions.

When supercoiled pBR322 DNA was relaxed at 0 or 22 degrees C by topoisomerase I in the presence of the divalent cations Ca2+, Mn2+ or Co2+, the resulting distributions of topoisomers observed at 22 degrees C had positive supercoils, up to an average delta Lk value of +8.6 (for Ca2+at 0 degrees C), corresponding to an overwinding of the helix by 0.7 degrees/bp. An increase of the divalent cation concentration in the reaction mixture above 50 mM completely reversed the effect. When such ions were present in agarose electrophoresis gels, they caused a relaxation of positively supercoiled DNA molecules, and thus allowed a separation of strongly positively supercoiled topoisomers. The effect of divalent cations on DNA adds a useful tool for the study of DNA topoisomers, for the generation as well as separation of positively supercoiled DNA molecules.     

Queuine-containing isoacceptor of tyrosine tRNA in Drosophila melanogaster. Alteration of levels by divalent cations

Dietary cadmium causes the queuine-containing, Q(+), isoacceptors to increase relative to the guanine-containing, Q(-), ones of tRNATyr, tRNAHis and tRNAAsp of Drosophila melanogaster. Of the other divalent cations examined, Sr2+, Ni2+, Cu2+, Zn2+ and Hg2+, only Hg2+ failed to cause an increase in Q(+)tRNATyr. For these results, all pre-adult stages of the organism were spent on media containing the divalent ions. Adult flies that had developed on a normal diet also responded to divalent ions; Hg2+ as well as Cd2+, Sr2+ and Zn2+ caused an increase in Q(+)tRNATyr in 4 days. Using adult flies, the rate of the response was measured; when placed on a Cd2+-containing diet, they formed significantly more Q(+)tRNATyr within 24 h as compared to adults on a normal diet. Whether the queuine is derived from the diet or from de novo synthesis is yet to be determined. Since the metal ions represent a range of values in the 'hard-soft' classification, different sites of reaction are expected, yet for Drosophila a common result is an alteration in the ratio of Q(+) and Q(-) isoacceptors of these tRNAs. The transition to Q(+)tRNA may be an early indication of the metabolic imbalances resulting from the presence of the divalent cation.     

Simultaneous stochastic sensing of divalent metal ions

Stochastic sensing is an emerging analytical technique that relies upon single-molecule detection. Transmembrane pores, into which binding sites for analytes have been placed by genetic engineering, have been developed as stochastic sensing elements. Reversible occupation of an engineered binding site modulates the ionic current passing through a pore in a transmembrane potential and thereby provides both the concentration of an analyte and, through a characteristic signature, its identity. Here, we show that the concentrations of two or more divalent metal ions in solution can be determined simultaneously with a single sensor element. Further, the sensor element can be permanently calibrated without a detailed understanding of the kinetics of interaction of the metal ions with the engineered pore.     

Interaction of DNA with divalent metal ions

The interaction between the native DNA macromolecules and Ca2+, Mn2+, Cu2+ ions in solutions of low ionic strength (10(-3) M Na+) is studied using the methods of differential UV spectroscopy and CD spectroscopy. It is shown that the transition metal ions Mn2+ exercise binding to the nitrogen bases of DNA at concentrations approximately 5 x 10(-6) M and form chelates with guanine of N7-Me(2+)-O6 type. Only at high concentrations in solution (5 x 10(-3) M) do Ca2+ ions interact with the nitrogen bases of native DNA. In the process of binding to Ca2+ and Mn2+ the DNA conformation experiences some changes under which the secondary structure of the biopolymer is within the B-form family. The DNA transition to the new conformation is revealed by its binding to Cu2+ ions.     

Role of divalent metal ions in serum complement activity of the American alligator (Alligator mississippiensis)

Treatment of alligator serum with different concentrations of EDTA resulted in a concentration-dependent inhibition of serum-mediated sheep red blood cell (SRBC) hemolysis. This inhibition of serum-dependent hemolysis was observed for other chelators of divalent metal ions, such as phosphate and citrate. Treatment of alligator serum with 5 mM EDTA completely inhibited SRBC hemolysis, which could be totally restored by the addition of 5 mM Ca(2+) or Mg(2+), but not Cu(2+) or Ba(2+). These data indicate a specific need for Ca(2+) and/or Mg(2+) in the serum-mediated hemolysis of SRBCs. Kinetic analyses revealed that the addition of 30 mM EDTA 1 min after incubation of SRBCs with serum resulted in only 30% inhibition of hemolytic activity. However, addition of EDTA as early as 3 min post-incubation resulted in complete SRBC hemolysis. Pretreatment of serum with EDTA inhibited the hemolytic activity, but the activity could be restored in a time-dependent manner by the addition of Ca(2+)or Mg(2+). These data indicate that, as in human serum, the need for divalent metal ions occurs early in the alligator serum complement cascade.     

Effect of divalent metal ions on collagenase from Clostridium histolyticum.

The collagenase from Clostridium histolyticum (EC 3.4.24.3) degrades type IV collagen with Km 32 nM, indicating a high affinity for this substrate. Ferrous and ferric ions can inhibit Clostridium collagenase. Inhibition by Fe++ was of the mixed, non-competitive type, with Ki 90 microM. The inhibitory effect of Fe++ may be due to Zn++ displacement from the intrinsic functional center of this metalloprotease, since in the presence of excess amounts of Zn++ enzyme activity is retained. This inhibitory effect of Fe++ may be common for all types of collagenases, since this ion can also inhibit type IV collagenase purified from Walker 256 carcinoma, with IC50 80 microM. Cu++ can only partially inhibit Clostridium collagenase, while other divalent metal ions such as Cd++, Co++, Hg++, Mg++, Ni++ or Zn++ are devoid of any inhibitory effect on the enzyme.     

Interaction of anions and divalent metal ions with phosphoenolpyruvate carboxykinase.

The catalytic activity of phosphoenolpyruvate carboxykinase in rat liver cytosol is stimulated by incubating with Fe2+, Mn2+, Co2+, and Cd2+. When purified, the enzyme no longer responds to Fe2+, Co2+, or Cd2+ but retains a response to Mn2+. Low concentrations of SO4(2-) in the incubation medium with enzyme and divalent transition metal allow stimulation by Fe2+ and Co2+ and enhance the response to Mn2+. Under identical conditions, orthophosphate with Fe2+ is a potent inhibitor of the enzyme (half-maximal inhibition at 50 muM). A thiol is required in the incubation medium for the effects of Fe2+ plus sulfate or orthophosphate to be expressed. The magnitude of these effects depends on the thiol concentration. Dithiothreitol is more effective than GSH and activation by sulfate plus Fe2+ appears to require the reduced form of dithiothreitol. Sulfate ion is not considered to be the physiological Fe2+-activator of P-enolpyruvate carboxykinase in rat liver cytosol, as this function is fulfilled by a newly discovered liver protein. Knowledge concerning the interaction of Fe2+ and sulfate with the enzyme may be useful in examining their interaction between the enzyme, ferrous ion, and this activator protein.