Ternary Complex Formation Facilitates a Redox Mechanism for Iron Release from a Siderophore

While the naturally occurring reducing agents glutathione (GSH) and ascorbate (H₂A) alone are ineffective at reducing iron(III) sequestered by the siderophore ferrioxamine B, the addition of an iron(II) chelator, sulfonated bathophenanthroline (BPDS), facilitates reduction by either reducing agent. A mechanism is described in which a ternary complex is formed between ferrioxamine B and BPDS in a rapidly established pre-equilibrium step, which is followed by rate limiting reduction of the ternary complex by glutathione or ascorbate. Spectral, thermodynamic, and kinetic evidence are given for ternary complex formation. Ascorbate was found to be slightly more efficient at reducing the ternary complex than glutathione (k₄=2.1×10⁻³ M⁻¹ s⁻¹ and k₄=6.3×10⁻⁴ M⁻¹ s⁻¹, respectively) at pH 7. Reduction is followed by a rapid ligand exchange step where iron is released from ferrioxamine B to form tris-(BPDS)iron(II). The implications of these results for siderophore mediated iron transport and release are discussed.     

Coordination chemical studies on metalloenzymes. IX. Properties of the ternary complex between cobalt(II)-bovine carbonic anhydrase and bidentate ligands

The spectrum, thermodynamic parameters, and proton longitudinal relaxation time of the ternary complex between various bidentate ligands (2-pyridinecarboxylate, 2-quinolincarboxylate, 8-quinolinecarboxylate, and 2-pyridylacetate) and cobalt(II)-bovine carbonic anhydrase were measured to clarify the nature of the ternary complex. The formation constants of the ternary complexes of bidentate ligands are in the order of (2-pyridinecarboxylate ? 8-quinolinecarboxylate ? 2-quinolinecarboxylate ≈2-pyridylacetate). The degree of the shift of the band characteristic of five-coordinate species at 13-15 kcm^-1 (cm^-1 × 10^-3) and that of the higher energy band at 21–22 kcm^-1 decrease almost in the same order. These results are explained on the basis of the contribution of the bond formation between the nitrogen atom of the heterocyclic ring of ligands and cobalt ion. The formation constants of the ternary complex of bidentate ligands were compared to the stability constants of various ligands with a cobalt ion but there is no correlation in these values. The rate constant of break-up of the ternary complex was discussed on the coordination geometry of the ternary complex on the basis of the degree of the distortion.     

Active site-specifically reconstituted nickel(II) horse liver alcohol dehydrogenase: Optical spectra of binary and ternary complexes with coenzymes,coenzyme analogues,substrates, and inhibitors

Insertion of nickel ions into the empty catalytic site of horse liver alcohol dehydrogenase yields an active enzyme with 65% metal substitution and about 12% intrinsic activity. The electronic absorption spectrum is characterized by bands at 357 nm (2900 M^?1 cm^?1, 407 nm (3500 M^?1 cm^?1), 505 nm (300 M^?1 cm^?1), 570 nm (?130 M^?1 cm^?1), and 680 nm (?80 M^?1 cm^?1). The absorption and CD spectra are similar to those of nickel(II) azurin and nickel(II) aspartate transcarbamoylase and prove coordination of the nickel(II) ions to sulfur in a distorted tetrahedral coordination geometry. Changes of the spectra upon ligand binding at the metal or conformation changes of the protein induced by coenzyme, or both, indicate alterations of the metal geometry.The chromophoric substrate trans-4-(N, N-dimethylamino)-cinnamaldehyde forms a ternary complex with Ni(II) liver alcohol dehydrogenase and the coenzyme analogue 1,4,5,6-tetrahydronicotinamide-adenine-dinucleotide, stable between pH 6 and 10. The corresponding ternary complex with NADH is only stable at pH > 9.0. The spectral redshifts induced in the substrate are 11 nm larger than those found in the zinc enzyme. We suggest direct coordination of the substrate to the catalytic metal ion which acts as a Lewis acid in both substrate coordination and catalysis.     

Temperature dependent conformational changes at the active site of pyruvate kinase. A li nuclear magnetic resonance study.

The interaction of Li⁺, a weak activator of pyruvate kinase, with substrate and inhibitor complexes of the enzyme has been investigated by magnetic resonance techniques. Proton relaxation rate (PRR) titrations indicate that the dissociation constant of Li⁺ from the ternary enzyme-Mn(II)-phosphoenolpyruvate (P-enolpyruvate) complex is 15 mm at 5 °C and 17 mm at 30 °C. The electron paramagnetic resonance spectrum of the enzyme-Mn(II)-Li(I)-P-enolpyruvate complex is the superposition of spectra for two distinct species (Reed, G. H., and Cohn, M. (1973) J. Biol. Chem.248, 6436–6442). Low temperatures favor the form giving rise to the more nearly isotropic spectrum, whereas high temperatures favor the species giving rise to the anisotropic “K⁺-like” spectrum. ⁷Li nuclear magnetic resonance data are consistent with a model in which the two forms observed by epr correspond to differing Mn(II) to Li(I) distances. The form giving rise to the anisotropic spectrum is characterized by a Mn(II) to Li(I) distance of 4.7 Å, and in the more isotropic form this distance is approximately 9 Å. The 4.7 Å separation of the Mn(II) and Li(I) in the anisotropic form of the complex compares favorably with the 4.9 Å separation of Mn(II) and T1(I) (Reuben, J., and Kayne, F. J. (1971) J. Biol. Chem.246, 6227–6234) in the P-enolpyruvate complex, although T1⁺ is a much better activator of the pyruvate kinase reaction. Thus, a change in the distance between the monovalent and divalent cations does not account quantitatively for the lower activation by Li⁺, inasmuch as more than 50% of the enzyme-Mn(II)-Li(I)-P-enolpyruvate complex has the “active” conformation with respect to the separation of the cations and the epr spectrum of the complex. As reported previously (Reed, G. H., and Morgan, S. D. (1974) Biochemistry13, 3537–3541), the dissociation constant of oxalate and the epr spectrum for the ternary complex of pyruvate kinase with Mn(II) and oxalate are not influenced by the species of monovalent cation present. The nuclear relaxation rates of Li⁺ are increased in the presence of the ternary oxalate complex, although the separation of the Mn(II) and Li(I) appears to be much greater than for the “anisotropic” form of the P-enolpyruvate complex.     

Complexes of vitamin B6, part VII: Ternary complexes of cobalt(II), nickel(II), and copper(II) involving pyridoxamine and some amino acids

The stability constants of the ternary Cu(II), Ni(II), and Co(II) complexes containing pyridoxamine (PM) and as a second ligand (L) glycine, DL-alanine, DL-valine, and β-phenylalnine were determined by pH-metric titration in 0.50 M KNO₃ at 30°C. The corresponding constants of the equilibrium, log X, are greater than would be expected for purely statistical reasons (log X = 0.6), except for few complex cases of Co(II). It has been also concluded that amino acids compete more than pyridoxamine for Ni(II) and Co(II) through the formation of 1:2:1:0 species rather than 2:1:1:0 of PM⁻:L⁻:M²⁺:H⁺.     

A proton nuclear magnetic resonance study of the interaction of mercury with intact human erythrocytes

The binding of mercuric ion (Hg(II)) by small molecules in the intracellular region of intact human erythrocytes has been studied by ¹H-NMR spectroscopy. HgCl₂ added to intact erythrocytes in saline-glucose suspension is found to cross the membrane and reach an equilibrium distribution among the molecules of the erythrocyte within 4 min. In the intracellular region Hg(II) reacts with GSH and hemoglobin to form the ternary mixed-ligand complex GSH-Hg(II)-hemoglobin. The analogous complex with ergothioneine is formed after all the GSH is complexed. ¹H-NMR spectra show that the GSH-Hg(II)-hemoglobin complex also forms in simpler solutions containing HgCl₂, GSH and hemoglobin, whereas the complex Hg(GSH)₂ predominates in solutions of GSH and HgCl₂. The lifetime of the GSH in the GSH-Hg(II)-hemoglobin complex is shown to be less than 30 s, which provides direct evidence for the first time that Hg(II) complexes in biological systems are quite labile, even though their thermodynamic stability is large. The effectiveness of eight sulfhydryl-containing ligands, some of which have been used as antidotes for Hg(II) poisoning, for releasing GSH from its Hg(II) complex in hemolyzed erythrocytes was also studied. Dithiol ligands were found to be more effective than monothiols, with dithioerythritol the most effective of the dithiols.     

Chiral discrimination by ligand-exchange chromatography: A comparison between phenylalaninamide-based stationary and mobile phases

The copper(II) complexes of two new diastereomeric ligands, N²-(R)- and N²-(S)-2′-hydroxypropyl-(S)-phenylalaninamide [(R, S)-1 and (S, S)-1], have been used as additives to the eluent in high-performance liquid chromatography (HPLC) reversed phase for the chiral separation of DNS-amino acids. The aim was that of comparing the separation process obtained by the chiral eluent with that obtained by an analogous bonded stationary phase containing (S)-phenylalaninamide, previously studied [CSP-(S)-Phe-NH₂]. The affinity of the ternary complexes for the C₁₈ column was determined by adsorption experiments in HPLC. It was shown that the two systems (chiral eluent, chiral stationary phase) work according to different mechanisms. Ternary complex formation in solution was studied by fluorescence spectroscopy. It was shown that chiral separation with the Cu(II) complexes added to the eluent was determined by the relative affinities of the ternary complexes for the column-stationary phase rather than by their stabilities in solution. With CSP-(S)-Phe-NH₂ the separation is accounted for by the relative stabilities of the ternary complexes, which depends mainly on the “allowed” geometry of the complex and on the steric repulsion of the amino acid side chain with the spacer. © 1996 Wiley-Liss, Inc.     

Cu(II)-mediated phenol oxygenation: Chemical evidence implicates a unique role of the enzyme active site in promoting the chemically difficult tyrosine monooxygenation in TPQ cofactor biogenesis of copper amine oxidases

Cu(II)-mediated autoxidations of 4-tert-butylphenol under various conditions was studied, the data confirmed imidazole is the best ligand to promote phenol oxygenation. The same reaction of 2,4-di-tert-butylphenol proceeded much more quickly to lead nearly exclusively to oxidative coupling rather than oxygenation under high pressure O₂. These results suggested that Cu(II)-catalyzed phenol autoxidation by activating O₂ and phenol in terms of a phenoxy radical (ArO)–Cu(II)–superoxide ternary complex, whereas selectivity between oxygenation and coupling depends mainly on the electronic structure of ArO. It is appeared that CuAOs could achieve stoichiometric tyrosine monooxygenation by modulating the redox potential of Cu(II) and stabilizing the ternary complex through protein conformational adjustment.     

A mechanistic study of ferrioxamine B reduction by the biological reducing agent ascorbate in the presence of an iron(II) chelator

The iron overload drug desferal (desferrioxamine B) forms the stable iron complex ferrioxamine B. The reduction potential of ferrioxamine B (E^o = −482 mV versus NHE pH 7) prohibits its reduction by biological reducing agents such as ascorbate, but it was found that the iron(II) chelator 2,2′-bipyridine (bipy) facilitates this reduction. Evidence is given to support the formation of a ternary complex between iron, bipy, and desferrioxamine B as the key step in facilitating the reduction. The equilibrium constant for the formation of the ternary complex was found to be 8.9 × 10⁷ and ternary complex formation is explained in terms of a three step mechanism. The mechanism for the reduction of ferrioxamine B is discussed in terms of rapidly established pre-equilibria which include ternary complex formation, ascorbic acid deprotonation, and encounter complex formation between ascorbate and the ternary complex. These equilibria are followed by rate limiting reduction of the ternary complex. Bipy was found to be a similar facilitator to sulfonated bathophenanthroline for the reduction of ferrioxamine B by ascorbate.     

Complexes of magnesium(II) and other divalent metal ions with adenosine 5′-triphosphate and 2,2′-dipyridylamine in aqueous solution

Binary and ternary systems involving adenosine 5′-triphosphate (ATP), 2,2′-dipyridylamine (DPA) and magnesium, calcium, strontium, manganese, cobalt, copper, and zinc(II) metal ions have been investigated in aqueous media by potentiometric titrations. The analysis of the titration curves shows the existence of M(ATP)²⁻, M(ATP)(H)⁻, and M(ATP)₂(H)₂⁴⁻ species for alkaline-earth metal ions, while no ternary complex can be detected. For transition metal ions both binary and ternary species are found. Binary M(ATP)₂(H)₂⁴⁻ complexes are present in solutions containing manganese and cobalt(II) metal ions but these species cannot be revealed in the case of copper and zinc(II). Ternary complexes as M(ATP)(DPA)²⁻ and M(ATP)(DPA)(H)⁻ are common to all transition metals. Binuclear and hydroxo complexes as M₂(ATP)(OH)⁻ and M(ATP)(OH)³⁻ are found only for copper and zinc(II). A hypothesis on the possible role of the species M-ATP in 1:2 ratio in the dephosphorylation mechanism is advanced on the basis of a comparison between the equilibrium data in the solution phase and the solid state structures of the magnesium, calcium, and manganese(II)- ATP-DPA systems.     

Chelation of copper(II) by daunomycin and 5-iminodaunomycin and interaction of the complexes with mononucleotides: An ESR study

Coordination of copper(II) ions by daunomycin and 5-iminodaunomycin has been studied by electron spin resonance spectroscopy, at various values of pH and r, the anthracycline-to-Cu(II) molar ratio. At r = 1–5, polymeric complexes are formed in the case of daunomycin. At r = 5, a mononuclear complex is predominant and at r = 10, this is the only one formed with the ⁶³Cu and ⁶⁵Cu hyperfine interaction being clearly defined in the g_∥ region (g_∥ = 2.26, ⁶³A_∥ = 175; ⁶⁵A_∥ = 190 G). For 5-iminodaunomycin both chelation sites are involved in the coordination and a polymeric structure (in which exchange interactions between Cu(II) centers operate) is stable in the range r = 1–3. At r = 3, the triplet state of a dinuclear Cu(II) complex is observed and 5-iminodaunomycin behaves as both a bridging and a terminal ligand. For r = 5–10, the dinuclear complex coexists with the mononuclear one. In the presence of mononucleotides dGMP, dAMP, dCMP and thymidine, no ternary complex such as mononucleotide/Cu(II)/anthracycline was observed.     

Synthesis of Zn(II)-cloxacillin sodium complex and study of its interaction with calf thymus DNA

In this paper, a solid complex of cloxacillin sodium (CS) with Zn(II) was prepared by coprecipitation and characterized by UV, fluorescence, IR, and thermal spectra. Furthermore, the nature of the complex has been studied by ¹H-NMR and ¹³C-NMR spectroscopy. The influence of Zn(II) on the combination of CS and calf thymus DNA (CT DNA) was studied using fluorescence spectrophotometry, and the formation of binary CS-Zn(II) and CS-CT DNA complexes and ternary CS-Zn(II)-CT DNA complex was studied. The results show that the fluorescence intensity of CS can be quenched in the presence of Zn(II) or DNA. In the presence of Zn(II), the fluorescence quenching action of DNA on CS was strongly enhanced. Based on the fluorescence intensity, the formation constants of CS-Zn(II) and CS-CT DNA complexes were calculated, and the mechanism of interaction between CS, Zn(II), and DNA is discussed. Published in Russian in Biokhimiya, 2007, Vol. 72, No. 2, pp. 184–193.     

Ternary copper(II) complexes involving 2-(aminomethyl)-benzimidazole and some bio-relevant ligands. Equilibrium studies and kinetics of hydrolysis for glycine methyl ester under complex formation

Formation equilibria of copper(II) complexes of 2-(aminomethyl)-benzimidazole (AMBI) and the ternary complexes Cu(AMBI)L (L = amino acid, amide, dicarboxylic acid or DNA constituents) have been investigated. Ternary complexes of amino acids or amides are formed by a simultaneous mechanism. Amino acids form the complex Cu(AMBI)L, whereas amides form two complex species Cu(AMBI)L and Cu(AMBI)(LH₋₁). The ternary complexes of copper(II) with AMBI and dicarboxylic acids or DNA units are formed by a stepwise mechanism, whereby binding of copper(II) to AMBI is followed by ligation of the dicarboxylic acids or DNA components. The values of Δ log K indicate that the ternary complexes containing aromatic amino acids are significantly more stable than the complexes containing alkyl- and hydroxyalkyl-substituted amino acids. This may be taken as an evidence for a stacking interaction between the aromatic moiety of AMBI and the aromatic side chains of the bio-active ligands. The solid complexes Cu(AMBI)L where L = 1,1-cyclobutanedicarboxylic acid (CBDCA) and malonic acid were separated and identified by elemental analysis and infrared spectroscopy and magnetic moment. The decomposition course and steps for the isolated complexes were analyzed and the kinetic parameters of the non-isothermal decomposition were calculated. The hydrolysis of glycine methyl ester (MeGly) is catalyzed by the Cu(AMBI)²⁺ complex. The kinetic data is fitted assuming that the hydrolysis reaction proceeds in two steps. The first step, involving coordination of the amino acid ester by the amino and carbonyl groups, is followed by rate-determining attack by OH⁻ ion. The second step involves the equilibrium formation of the hydroxo-complex Cu(AMBI)(MeGly)(OH) followed by intramolecular OH⁻ attack.     

The influence of anions and inhibitors on the catalytic metal ion in Co(II)-substituted horse liver alcohol dehydrogenase

¹H-NMR and electronic spectroscopic data are reported for the interaction of the effector molecule imidazole and the inhibitor molecule pyrazole with horse liver alcohol dehydrogenase whose catalytic zinc ions were replaced by Co(II). In addition ¹³C-NMR and optical data are given for the binding of acetate to this enzyme species. For the binary complex with imidazole an assignment of the protons of the metal-coordinated imidazole has been made and it was found that the rate of exchange of the effector molecule is slow on the NMR time scale. In the presence of NADH which is bound to the open conformation of the binary complex, the most pronounced change is a shift of the -CH₂ protons of the metal-coordinated cysteine residues which is attributed to hydrogen bonding interactions between the carboxamide group of the nicotinamide moiety with cysteine 46. The ¹H-NMR spectra of the binary complex of Co(II)-HLADH with pyrazole show resonances assigned to the protons in the 3-and 4-positions of the bound inhibitor, the NH proton resonance is not detectable. In the ternary complex with pyrazole and NAD⁺ only the resonances of the -CH₂ protons (beyond 150 ppm) are changed whereas the protons of histidine 67 and the bound inhibitor are unchanged. The data demonstrate that the coordination environment of the catalytic metal ion is changed very little when the protein changes from the open to the closed conformation. The only changes observed are the -CH₂ proton resonances of the metal-coordinating cysteines which are sensitive to local conformational changes within the ternary complex Co(II)-HLADH · Imidazole · NADH in the open conformation or global changes in the ternary complex Co(II)-HLADH · Pyrazole · NAD⁺ in the closed conformation. Acetate which can be regarded as a substrate model was shown to induce a similar change in the optical spectra of the Co(II) enzyme as all other anions observed so far. From the optical changes a dissociation constant of acetate at the catalytic metal site of 200±50 mM was calculated and from the changes of the ¹³C-NMR linewidth of ¹³C acetate direct bonding of the anion to the catalytic Co(II) ion can be demonstrated to occur under the conditions of rapid exchange. The implications of these data for the assessment of tetracoordination around the catalytic metal ion as well as the chemical nature of intermediates occurring along the catalytic pathway are discussed.This work has been performed with contribution of the project Projetto Strategico Biotechnologie CNR and with financial support from the Deutsche Forschungsgemeinschaft, NATO, Bundesminister für Forschung und Technologie, and the Universität des Saarlandes     

Coordination geometry for cadmium in the catalytic zinc site of horse liver alcohol dehydrogenase: studies by PAC spectroscopy

Active site substituted Cd(II) horse liver alcohol dehydrogenase has been studied by Perturbed Angular Correlation of Gamma rays Spectroscopy during turnover conditions for benzaldehyde and 4-trans-(N,N-dimethylamino)cinnamaldehyde. The ternary complex between alcohol dehydrogenase NAD⁺ and Cl^–, and the binary complex between alcohol dehydrogenase and orthophenanthroline have also been studied. The Nuclear Quadrupole Interaction parameters have been interpreted in terms of different coordination geometries for Cd(II) in the catalytic zinc site of the enzyme. Calculation of the nuclear quadrupole interaction for cadmium in the catalytic site of the enzyme with and without coenzyme, based upon the four coordinated geometries determined from X-ray diffraction, agrees with the experimentally determined values. The ternary complexes between enzyme, NAD⁺ and either Cl^– or trifluoroethanol and the binary complex between enzyme and orthophenanthroline have almost identical spectral parameters which are not consistent with a four coordinated geometry, but are consistent with a five coordinated geometry. The nonprotein ligands for the ternary complex with trifluoroethanol are suggested to be an alkoxide group and a water molecule. The Nuclear Quadrupole Interaction parameters for the productive ternary complex between enzyme, NADH and an aldehyde is consistent with the four coordinated geometry predicted from X-ray diffraction data having the carbonyl group of the aldehyde substituting the water molecule as ligand to the metal.Abbreviations LADH Horse liver alcohol dehydrogenase - H₄Zn₂LADH derivative of LADH free of zinc in the catalytic site - ¹¹¹CdZn₂LADH derivative of LADH with ¹¹¹Cd (carrier free) in the catalytic site - Cd₂Zn₂LADH derivative of LDH with 2 mole of Cd(II) per mole LADH in the catalytic site - PAC pertubed angular correlation of gamma rays - NQI Nuclear quadrupole interaction - AOM Angular overlap model - trifluoroethanol 2,2,2-trifluoroethanol - DACA trans-4-(N,N-dimethylamino)cinnamaldehyde - NAD⁺ and NADH oxidized and reduced nicotinamide adenine dinucleotide - NADH₂ reduced 1,4,5,6-tetrahydronicotinamide adenine dinucleotide The experimental work was carried out at the Niels Bohr Institute Risø, 4000 Roskilde and Blegdamsvej 19, 2100 Copenhagen, Denmark Offprint requests to: R. Bauer     

25Mg NMR study of Mg2+-ATP,ADP-creatine kinase complexes

²⁵Mg NMR spectroscopy was first applied to the ternary complexes consisting of Mg²⁺, ATP, ADP and creatine kinase. The ²⁵Mg NMR spectra of the Mg²⁺-ATP (or ADP) complex are remarkably broadened in the ternary Mg²⁺-ATP(or ADP)-creatine kinase complex in contrast with previous prediction. From temperature dependence of the spectra of the protein-bound ion, it is suggested that Mg²⁺ of the protein-bound Mg²⁺-ATP(or ADP) complex is not in the fast exchange regime. The ²⁵Mg NMR signal of the transition state analogue complex is narrower and less temperature-dependent than those of the ternary complex, suggesting that Mg²⁺ in the transition state analogue complex is in a more symmetrical environment or exchanges slower than that of the ternary complex.     

Ascorbic Acid Oxidation and DNA Scission Catalyzed by Iron and Copper Chelates

The asorbic acid (AH^?) auto-oxidation rates catalyzed by copper chelates of 1,10-phenanthroline (OP) or by iron chelates of bleomycin (BLM) are only slightly higher than the oxidation rates catalyzed by the metal ions. AH^? oxidation in the presence of DNA is accompanied by degradation of the DNA. The rates of DNA scission by the metal chelates are markedly higher than the rates induced by the free metal ions. AH^? oxidation is slowed down in the presence of DNA which forms ternary complexes with the chelates. The ternary complexes react slowly with AH^? but induce DNA double strand breaks more efficiently than the free metal chelates. With OP, DNA is degraded by the reaction of the ternary complex, DNA-(OP)₂Cu(I), withH₂O₂

AH^? oxidation in the presence of DNA was biphasic, showing a marked rate increase after DNA was cleaved. We suggest that this sigmoidal pattern of the oxidation curves reflects the low initial oxidative activity of the ternary complexes, accelerating as DNA is degraded.

Using O₂^?produced by pulse radiolysis as a reductant, we found that AH^? oxidation with (OP)₂Cu(II) induced more DNA double strand breaks per single strand break than bipyridine-copper.

The site specific DNA damaging reactions indicated by these results are relevant to the mechanism of cytotoxic activities of bleomycin and similar antibiotics or cytotoxic agents.     

Protein synthesis in rabbit reticulocytes XXII+: a heat stable dialyzable factor (EIF-I*) modulates Met-tRNAf binding to EIF-1.

The peptide chain initiation factor EIF-1 forms a ternary complex, Met-tRNA_f·EIF-1·GTP in the absence of Mg⁺⁺ and the preformed complex is stable to Mg⁺⁺. However, with homogeneous preparations of EIF-1, addition of Mg⁺⁺ during the initial formation of the ternary complex strongly inhibits the complex formation.A heat stable dialyzable factor (EIF-1¹) which mostly remains associated with the high molecular weight protein complex, EIF-2 (TDF) during purification of the peptide chain initiation factors, has been purified using a phenol extraction procedure. EIF-1¹ restores the Met-tRNA_f binding activity of EIF-1 in the presence of 1 mM Mg⁺⁺; in the presence of EIF-1¹, Met-tRNA_f binding by EIF-1 shows a sharp Mg⁺⁺ optimum around 1 mM. EIF-1¹ is heat stable, alkali stable, dialyzable and pronase sensitive. The same EIF-1¹ preparation also strongly inhibits Met-tRNA_f binding to EIF-1 in the absence of Mg⁺⁺ and stimulates protein synthesis in a mRNA-dependent rabbit reticulocyte lysate system.     

Qualitative study of supramolecular assemblies of β-cyclodextrin and cholecalciferol and the cobalt (II), copper (II) and zinc (II) ions

A ¹³C NMR in DMSO-d₆ as solvent, diffuse reflectance spectra and X-ray powder diagram study of the inclusion of vitamin D in β-cyclodextrin and of the ternary assemblies with β-cyclodextrin, vitamin D and metal ions (e.g. Co(II), Cu(II) and Zn(II)) was carried out to determine the structure of these associations in which the molecular ratios (β-cyclodextrin:vitamin D:metal ions) were 5:1:1 or 10:1:1.     

Photochemical Properties of Camptothecin in the Presence of Copper(II) Ions: The Role of Radicals as Prospective Species in Photodynamic Therapy

Camptothecin (CPT) is an anticancer drug that inhibits topoisomerase I (Topo I) by forming a ternary DNA-CPT-Topo I complex. However, it has also been shown that UVA-irradiated CPT in the absence of Topo I produces significant DNA damage to cancer cells. In this work, we explored and identified free radicals generated in these processes. From the low-temperature EPR spectrum of Cu(II)-CPT complex, a proximity between Cu(II) ion and 20-hydroxy group of lactone E ring of CPT is proposed. Upon irradiation (λ = 365 nm) of the Cu(II)-CPT complex in de-oxygenated dimethylsulfoxide (DMSO), the EPR signal of Cu(II) measured in situ at room temperature shows formal first-order exponential decay with a formal half-life of 11 min. By the use of a specific Cu(I) chelating agent, neocuproine, it was shown that, during this process, Cu(II) is reduced to Cu(I). The loss in EPR signal intensity of the Cu(II)-CPT complex upon irradiation is accompanied by the appearance of a new EPR signal at g ≈ 2.0022. Application of the spin trap nitrosodurene (ND) revealed that the main radical product formed upon continuous irradiation of CPT in DMSO solutions is the hydroxyl radical (trapped in DMSO as the ^•CH₃ adduct) and superoxide radical. Application of 2,2,6,6-tetramethyl-4-piperidinol has revealed that irradiation of CPT in aerated DMSO solution also leads to formation of singlet oxygen (¹O₂). Our spectroscopic experiments indicate that CPT is a promising photosensitizer and that radicals and singlet oxygen generated upon illumination play a central role in DNA cleavage and in the induction of apoptosis in cancer cells.