How do MgATP analogues differentially modify high-affinity and low-affinity ATP binding sites of Na+/K(+)-ATPase?

The exchange-inert tetra-ammino-chromium complex of ATP [Cr(NH3)4ATP], unlike the analogous cobalt complex Co(NH3)4ATP, inactivated Na+/K(+)-ATPase slowly by interacting with the high-affinity ATP binding site. The inactivation proceeded at 37 degrees C with an inactivation rate constant of 1.34 x 10(-3) min-1 and with a dissociation constant of 0.62 microM. To assess the potential role of the water ligands of metal in binding and inactivation, a kinetic analysis of the inactivation of Na+/K(+)-ATPase by Cr(NH3)4ATP, and its H2O-substituted derivatives Cr(NH3)3(H2O)ATP, Cr(NH3)2(H2O)2ATP and Cr(H2O)4ATP was carried out. The substitution of the H2O ligands with NH3 ligands increased the apparent binding affinity and decreased the inactivation rate constants of the enzyme by these complexes. Inactivation by Cr(H2O)4ATP was 29-fold faster than the inactivation by Cr(NH3)4ATP. These results suggested that substitution to Cr(III) occurs during the inactivation of the enzyme. Additionally hydrogen bonding between water ligands of metal and the enzyme's active-site residues does not seem to play a significant role in the inactivation of Na+/K(+)-ATPase by Cr(III)-ATP complexes. Inactivation of the enzyme by Rh(H2O)nATP occurred by binding of this analogue to the high-affinity ATP site with an apparent dissociation constant of 1.8 microM. The observed inactivation rate constant of 2.11 x 10(-3) min-1 became higher when Na+ or Mg2+ or both were present. The presence of K+ however, increased the dissociation constant without altering the inactivation rate constant. High concentrations of Na+ reactivated the Rh(H2O)nATP-inactivated enzyme. Co(NH3)4ATP inactivates Na+/K(+)-ATPase by binding to the low-affinity ATP binding site only at high concentrations. However, inactivation of the enzyme by Cr(III)-ATP or Rh(III)-ATP complexes was prevented when low concentrations of Co(NH3)4ATP were present. This indicates that, although Co(NH3)4ATP interacts with both ATP sites, inactivation occurs only through the low-affinity ATP site. Inactivation of Na+/K(+)-ATPase was faster by the delta isomer of Co(NH3)4ATP than by the delta isomer. Co(NH3)4ATP, but not Cr(H2O)4ATP or adenosine 5'-[beta,gamma-methylene]triphosphate competitively inhibited K(+)-activated p-nitrophenylphosphatase activity of Na+/K(+)-ATPase, which is assumed to be a partial reaction of the enzyme catalyzed by the low-affinity ATP binding site.     

The kinetic mechanism of yeast inorganic pyrophosphatase

The kinetic mechanism of yeast inorganic pyrophosphatase (PPase) was examined by carrying out initial velocity studies. Ca2+ and Rh(H2O)4(methylenediphosphonate) (Rh(H2O)4PCP) were used as dead-end inhibitors to study the order of binding of Cr(H2O)4PP to the substrate site and Mg2+ to the "low affinity" activator site on the enzyme. Competitive inhibition was observed for Ca2+ vs Mg2+ (Kis = 0.93 +/- 0.03 mM), for Rh(H2O)4PCP vs Cr(H2O)4PP (Kis = 0.25 +/- 0.07 mM), and for RH(H2O)4PCP vs Mg2+ (Kis = 0.38 +/- 0.03 mM). Uncompetitive inhibition was observed for Ca2+ vs Cr(H2O)4PP (Kii = 0.49 +/- 0.01). On the basis of these results a rapid equilibrium ordered mechanism in which Cr(H2O)4PP binding precedes Mg2+ ion binding is proposed. The inert substrate analog, Mg(imidodiphosphate) (MgPNP) was shown to induce Mg2+ inhibition of the PPase-catalyzed hydrolysis of MgPP. The Mg2+ inhibition observed was competitive vs MgPP and partial. These results suggest that Mg2+/MgPNP release from the enzyme occurs in preferred rather than strict order and that the Mg2+/MgPP-binding steps are at steady state. Zn2+, Co2+, and Mn2+ (but not Mg2+) displayed activator inhibition of the PPase-catalyzed hydrolysis of PPi (this study) and of Cr(H2O)4PP (W.B. Knight, S. Fitts, and D. Dunaway-Mariano, (1981) Biochemistry 20, 4079). These findings suggest that cofactor release from the low affinity cofactor site on the enzyme must precede product release and that Zn2+, Mn2+, and Co2+ (but not Mg2+) have high affinities for the cofactor sites on both the PPase.M.MPP and PPase.M.M(P)2 complexes. The role of the metal cofactor in determining PPase substrate specificity was briefly explored by testing the ability of the Mg2+ complex of tripolyphosphate (PPPi) (a substrate for the Zn2+-activated enzyme but not the Mg2+-activated enzyme) to induce Mg2+ inhibition of PPase-catalyzed hydrolysis of MgPP. MgPPP was shown to be as effective as MgPNP in inducing competitive Mg2+ inhibition (vs MgPP). This result suggests that the low affinity Mg2+ cofactor-binding site present in the enzyme-MgPP complex is maintained in the enzyme-MgPPP complex. Thus, failure of Mg2+ to bind to the enzyme-MgPPP complex was ruled out as a possible explanation for the failure of the Mg2+-activated enzyme to catalyze the hydrolysis of MgPPP.     

Investigations of the metal ion-binding sites of yeast inorganic pyrophosphatase

Yeast inorganic pyrophosphatase was found to bind two Mn2+ per subunit in the absence of phosphate and three Mn2+ per subunit in the presence of phosphate. Kinetic studies of the pyrophosphatase-catalyzed hydrolysis of Cr(NH3)4PP and Cr(H2O)4PP were carried out with Mn2+ and with Mg2+ as activators. The results from these studies suggest that three divalent cations per pyrophosphatase active site are required for catalysis. NMR and EPR studies were conducted to evaluate the relative location of the metal ion binding sites on the enzyme. The two Mn2+ ions bound to the free enzyme are in close enough proximity to magnetically interact. Analysis of the NMR and EPR data in terms of a dipolar relaxation mechanism between Mn2+ ions provides an estimate of the distance between them of 10-14 A. When the diamagnetic substrate analog [Co(NH3)4PNP]- or intermediate analog [Co(NH3)4 (P)2]- are bound to pyrophosphatase, two Mn2+ ions still bind to the enzyme and their magnetic interaction increases. In the presence of these Co3+ complexes, the Mn2+--Mn2+ separation decreases to 7-9 A. Several NMR and EPR experiments were conducted at low Mn2+ to pyrophosphatase ratios (approximately 0.3), where only one Mn2+ ion binds per subunit, in the presence of Cr3+ or Co3+ complexes of PNP or PP. Analysis of the Mn2+--Cr3+ dipolar relaxation evident in proton NMR and EPR data provided for the calculation of Mn2+--Cr3+ distances. When the substrate analog CrPNP was present, the Mn2+--Cr3+ distance was congruent to 7 A whereas, when Cr(P)2 was bound to pyrophosphatase, the Mn2+--Cr3+ distance was congruent to 5 A. These results strongly support a model for the catalytic site of pyrophosphatase that involves three metal ion cofactors.     

Chromium(III)-mediated structural modification of glycoprotein: impact of the ligand and the oxidants

The interaction of three types of chromium(III) complexes, [Cr(salen) (H2O2]+, [Cr(en)3]3+, and [Cr(EDTA) (H2O)]- with AGP has been investigated. [Cr(salen) (H2O2]+, [Cr(en)3]3+ and [Cr(EDTA) (H2O]- bind to Human alpha1-acid glycoprotein with a protein:metal ratio of 1:8, 1:6, and 1:4, respectively. The binding constant, K(b) was estimated to be 1.37 +/- 0.12 x 10(5) M(-1), 1.089 +/- 0.05 x 10(5) M(-1) and 5.3 +/- 0.05 x 10(4) M(-1) for [Cr(salen) (H2O2]+, [Cr(en)3]3+, and [Cr(EDTA) (H2O)]-, respectively. [Cr(en)3]3+ has been found to induce structural transition of AGP from the native twisted beta sheet to a more compact alpha-helix. The complexes, [Cr(salen) (H2O2]+ and [Cr(EDTA) (H2O]-, in the presence of H2O2, have been found to bring about nonspecific cleavage of AGP, whereas [Cr(en)3]3+ does not bring about any protein damage. Treatment of [Cr(salen) (H2O)2]+-protein adduct with iodosyl benzene on the other hand led to site specific cleavage of the protein. These results clearly demonstrate that protein damage brought about by chromium(III) complexes depends on the nature of the coordinated ligand, nature of the metal complex, and the nature of the oxidant.     

Inhibition and inactivation of pyruvate phosphate dikinase with Cr(III) complexes of adenosine 5'-triphosphate and inorganic pyrophosphate

The exchange inert complexes beta,gamma-bidentate Cr(H2O)4ATP and P1,P2-bidentate Cr(H2O)4PP were found to bind to the Bacteriodes symbiosus pyruvate phosphate dikinase ATP and PP binding sites, respectively. The inactivation of the enzyme that was observed with these complexes was shown to involve covalent attachment of the entire complex to the enzyme via insertion of enzyme amino acid side chains into the coordination sphere of the Cr(III). Incubation of Cr(H2O)4ATP with other proteins also resulted in covalent attachment.     

Stereochemical probes of the argininosuccinate synthetase reaction

The stereochemical course of the argininosuccinate synthetase reaction has been determined. The SP isomer of [alpha-17O,alpha-18O,alpha beta-18O]ATP is cleaved to (SP)-[16O,17O,18O]AMP by the action of argininosuccinate synthetase in the presence of citrulline and aspartate. The overall stereochemical transformation is therefore net inversion, and thus the enzyme does not catalyze the formation of an adenylylated enzyme intermediate prior to the synthesis of citrulline adenylate. The RP isomer of adenosine 5'-O-(2-thiotriphosphate) (ATP beta S) is a substrate in the presence of Mg2+, but the SP isomer is a substrate when Cd2+ is used as the activating divalent cation. Therefore, the lambda screw sense configuration of the beta,gamma-bidentate metal--ATP complex is preferred by the enzyme as the actual substrate. No significant discrimination could be detected between the RP and SP isomers of adenosine 5'-O-(1-thiotriphosphate) (ATP alpha S) when Mg2+ or Mn2+ are used as the divalent cation. Argininosuccinate synthetase has been shown to require a free divalent cation for full activity in addition to the metal ion needed to complex the ATP used in the reaction.     

Studies of antibacterial activity of binuclear rhodium (II) complexes with heterocyclic nitrogen ligands

Binuclear rhodium (II) complexes, [Rh2(OOCPh)2(phen)2(H2O)2] (OOCPh)2 (1), [Rh2(OOCPh)2(bpy)2(H2O)2] (OOCPh)2 (2), [Rh2(OOCBu(n))2 (bpy)2(H2O)2] (OOCBu(n)2 (3), and [Rh2(OOCPr(n)2 (phen)2(H2O)2] (OOCPr(n)2 (4) (Phen = 1,10-phenanthroline and bpy = 2,2'-bipyridine), have been synthesized and characterized using NMR, IR and electronic spectra. Activity of these compounds against Gram-positive bacteria decreases in the order: 1?2?3 > 4. Complex 1 is active against many Staphylococcus strains resistant to commonly used antibiotics. The complexes 1-4 are much less active agents against Gram-negative bacteria.     

The preparation and characterization of Cr(III) and Co(III) complexes of GDP and GTP and their interactions with avian phosphoenolpyruvate carboxykinase

The exchange inert coordination complexes, Cr(H2O)4GDP, Cr(H2O)4GTP, Cr(NH3)4GDP, Cr(NH3)4GTP, Co(NH3)4GDP, and Co(NH3)4GTP have been synthesized and characterized. The lambda and delta coordination isomers of Cr(H2O)4GDP, Cr(NH3)4GDP, and the four Cr(H2O)4GTP isomers have been separated by reverse phase HPLC and characterized by their CD spectra. While the isomers of Co(NH3)4GTP have not been successfully separated, 31P NMR spectroscopy reveals the presence of the lambda and delta forms. The complexes, Cr(H2O)4GDP, Co(NH3)4GDP, Cr(H2O)4GTP, and Co(NH3)4GTP, are linear competitive inhibitors of avian phosphoenolpyruvate carboxykinase. The Ki values of 30 microM, 540 microM, 40 microM, and 12 microM, respectively, were determined for these complexes using Mn-IDP as the nucleotide substrate in the phosphoenolpyruvate carboxylation direction or Mn-ITP as nucleotide substrate for the oxalacetate decarboxylation reaction. The lambda and delta isomers of Cr(H2O)4 GDP show little specificity (a twofold maximum difference in Ki) for the enzyme. The isomeric forms of Cr(H2O)4 GTP demonstrate no observed stereoselectivity of interaction with the enzyme. All of the complexes tested, except for Cr(NH3)4GDP and Co(NH3)4GDP, which have larger Ki values, are good substrate analogs for P-enolpyruvate carboxykinase. When the substrate is Mn-GTP, fixed at 0.2 mM at pH 6.0, enzyme activity is stimulated two- to two and a half-fold by Cr(H2O)4GTP. A Dixon plot reveals that the stimulatory effect is saturated at 0.4 mM Cr(H2O)4GTP. The interaction of the enzyme with Cr(H2O)4GTP appears to produce a "memory" effect which is manifest with guanosine nucleotide substrates, but which is not observed with the alternative substrate Mn-ITP.     

Interaction of purine nucleotides with inert paramagnetic Cr(III) probes evaluated by NMR relaxation effects. Molecular mechanics calculations on Cr(III) and Co(III) polyphosphate complexes

The 1H NMR relaxation effects produced by paramagnetic Cr(III) complexes on nucleoside 5'-mono- and -triphosphates in D2O solution at pH' = 3 were measured. The paramagnetic probes were [Cr(III)(H2O)6]3+, [Cr(III)(H2O)3(HATP)], [Cr(III)(H2O)3(HCTP)] and [Cr(III)(H2O)3(UTP)-, while the matrix nucleotides (0.1 M) were H2AMP, HIMP-, and H2ATP2-. For the aromatic base protons, the ratios of the transverse to longitudinal paramagnetic relaxation rates (R2p/R1p) for the [Cr(III)(H2O)6]3+/H2ATP2-, [Cr(III)(H2O)3(HATP)]/H2ATP2-, [Cr(III)(H2O)3(HCTP)]/H2ATP2 and [Cr(III)(H2O)3(UTP)]-/H2ATP2 systems were below 2.33 so the dipolar term predominates. For a given nucleotide, R1p for the purine H(8) signal was larger than for the H(2) signal with the [Cr(III)(H2O)6]3+ probe, while R1p for the H(2) signal was larger with all the other Cr(III) probes. Molecular mechanics computations on the [Cr(III)(H2O)4(HPP)(alpha,beta)], [Cr(III)(NH3)4(HPP)(alpha,beta)], [Co(III)(NH3)3(H2PPP)(alpha,beta,gamma)] and [Co(III)(NH3)4(HPP)(alpha,beta)] complexes gave calculated energy-minimized geometries in good agreement with those reported in crystal structures. The molecular mechanics force constants found were then used to calculate the geometry of the inner sphere [Cr(III)(H2O)6]3+ and [Cr(III)(H2O)3(HATP)(alpha,beta,gamma)] complexes as well as the structures of the outer sphere [Cr(III)(H2O)6]3(+)-(H2AMP) and [Cr(III)(H2O)6]-(HIMP)- species. The gas-phase structure of the [Cr(III)(H2O)3(HATP)(alpha,beta,gamma)] complex shows the existence of a hydrogen bond interaction between a water ligand and the adenine N(7)(O...N = 2.82 A). The structure is also stabilized by intramolecular hydrogen bonds involving the -O(2')H group and the adenine N(3) (O...N = 2.80 A) as well as phosphate oxygen atoms and a water molecule (O...O = 2.47 A). The metal center has an almost regular octahedral coordination geometry. The structures of the two outer-sphere species reveal that the phosphate group interacts strongly with the hexa-aquochromium probe. In both complexes, the nucleotides have a similar "anti" conformation around the N(9)-C(1') glycosidic bond. However, a very important difference characterizes the two structures. For the (HIMP)- complex, strong hydrogen bond interactions exist between one and two water ligands and the inosine N(7) and O(6) atoms, respectively (O...O = 2.63 A; O...N = 2.72, 2.70 A). For the H2AMP complex, the [Cr(III)(H2O)6]3+ cation does not interact with N(7) since it is far from the purine system. Hydrogen bonds occur between water ligands and phosphate oxygens. The Cr-H(8) and Cr-H(2) distances revealed by the energy-minimized geometries for the two outer sphere species were used to calculate the R1p values for the H(8) and H(2) signals for comparison with the observed R1p values: 0.92(c), 1.04(ob) (H(8)) and 0.06(c), 0.35(ob) (H(2)) for H2AMP; and 3.76(c), 4.53(ob) (H(8)) and 0.16(c), 0.77(ob) s-1 (H(2)) for HIMP-.(ABSTRACT TRUNCATED AT 400 WORDS)     

Structure of the metal-nucleotide complex in the acetate kinase reaction. A study with gamma-32P-labeled phosphorothioate analogs of ATP

The synthesis of the gamma-32P-labeled diastereomers of adenosine 5'-O-(1-thiotriphosphate) (ATP alpha S) and the Sp isomer of adenosine 5'-O-(2-thiotriphosphate) (ATP beta S) by a modification of the Glynn and Chappell method (Glynn, I. M., and Chappell, J. T., (1964) Biochem. J. 90, 147-149) is described. These analogs were tested as substrates for acetate kinase in the presence of several divalent metal ions. Both isomers of ATP alpha S are substrates in the presence of Mg2+, Mn2+, Co2+, Zn2+, and Cd2+, the Sp isomer being preferred by a factor of between 4.8 (Mg2+) and 52.5 (Cd2+). Only the Rp isomer of ATP beta S is a substrate in the presence of Mg2+, and the Sp isomer becomes a better substrate in the presence of Mn2+, Co2+, and Zn2+; both isomers are equally good substrates in the presence of Cd2+. The change in specificity upon replacing Mg2+ by Cd2+ is greater than 1800 at beta-phosphorus and 10 at alpha phosphorus. These results provide a basis for proposing that the lambda screw sense configuration of the beta, gamma-bidentate MgATP complex is the substrate for acetate kinase. In the reverse reaction, both Sp and Rp isomers of ADP alpha S are substrates in the presence of all metal ions tested, the Sp isomer preferred by a factor between 12.3 (Mg2+) and 45.5 (Cd2+). In the presence of Mg2+, Mn2+, and Co2+, only the Rp isomer of ATP beta S is synthesized from prochiral ADP beta S, while a mixture of Rp and Sp isomers is synthesized in the presence of Zn2+ and Cd2+. These results are analogous to those for the forward reaction and suggest that the Mg.ADP complex which binds as a substrate in the reverse reaction, and is released as a product in the forward reaction, is the beta-monodentate. The classification of acetate kinase as an enzyme having a type I mechanism (Dunaway-Mariano, D. and Cleland, W. W. (1980) Biochemistry 19, 1506-1515) for kinases, is discussed.     

Investigation of substrate specificity of creatine kinase using chromium (III) and cobalt(III) complexes of adenosine 5'-diphosphate

The specificity for substrate binding to creatine kinase for metal-nucleotide complexes of the type Cr-(H2O)4-n(NH3)nADP (where n = 0, 3, or 4) and Co-(H2O)4-m(NH3)mADP (for m = 3 or 4) has been investigated over the pH range 5.5-7.8 with the delta-alpha, beta-bidentate diastereoisomers. These inert nucleotide complexes acted as competitive inhibitors vs. MgADP over this range. In addition, the pH dependence of the V, V/K, and Km values for MgADP has been determined. Metal-nucleotide binding to the enzyme is strongest below an approximate pK of 6.45 but again becomes pH independent above pH 7. This pK is not associated with the metal-nucleotide complex. Instead, we conclude that the pK of the acid-base catalyst (thought to be histidine) is about 6.45 in the absence of nucleotide but is raised to 7.2 in its presence. This perturbation of the pK may result from a protein conformational change that allows a hydrogen bond to form between the phosphorylated nitrogen of phosphocreatine and the acid-base catalyst. The pK of the water in Cr(H2O)(NH3)3ADP has been determined to be 6.6, and by comparison of the binding affinity of this complex with that of Cr(NH3)4ADP or Cr(H2O)4ADP, it can be deduced that the hydroxo species binds more strongly than the aquo complex. In general, chromium nucleotides are bound more strongly than cobalt complexes, and binding affinity increases as water replaces ammonia in the first coordination sphere of the metal. Both trends are a result of stronger hydrogen-bond interactions between the metal complex and protein.     

Phospholipids chiral at phosphorus. Absolute configuration of chiral thiophospholipids and stereospecificity of phospholipase D

Separate diastereomers of 1,2-dipalmitoyl-sn-glycero-3- thiophosphoethanolamine ( DPPsE ) were prepared in 97% diastereomeric purity and characterized by 31P, 13C, and 1H nuclear magnetic resonance (NMR). The isomers hydrolyzed by phospholipases A2 and C specifically were designated as isomer B (31P NMR delta 59.13 in CDCl3 + Et3N ) and isomer A (59.29 ppm), respectively, analogous to the isomers B and A of 1,2-dipalmitoyl-sn-glycero-3- thiophosphocholine ( DPPsC ) [ Bruzik , K., Jiang , R.-T., & Tsai, M.-D. (1983) Biochemistry 22, 2478-2486]. Phospholipase D from cabbage was shown to be specific to isomer A of DPPsC in transphosphatidylation . The product DPPsE was shown to be isomer A. The absolute configuration of chiral DPPsE at phosphorus was elucidated by bromine-mediated desulfurization in H2 18O to give chiral 1,2-dipalmitoyl-sn-glycero-3-[18O]phosphoethanolamine ( [18O]DPPE) followed by 31 P NMR analysis [ Bruzik , K., & Tsai, M.-D. (1984) J. Am. Chem. Soc. 106, 747-754]. The absolute configuration of chiral DPPsC was elucidated by desulfurization in H2 18O mediated by bromine or cyanogen bromide to give chiral 1,2-dipalmitoyl-sn-glycero-3-[18O]phosphocholine ( [18O]DPPC), which was then converted to [18O]DPPE by phospholipase D with retention of configuration [ Bruzik , K., & Tsai, M.-D. (1984) Biochemistry (preceding paper in this issue)]. The results indicate that isomer A of both DPPsE and DPPsC is SP whereas isomer B is RP.     

Crystal structure, solid state and solution characterisation of copper(II) coordination compounds of ethyl 5-methyl-4-imidazolecarboxylate (emizco)

The synthesis and characterisation of the following compounds derived from the biological relevant compound ethyl 5-methyl-4-imidazolecarboxylate (emizco) (1): [Cu(emizco)Cl2] (2), [Cu(emizco)2Cl2] (3), [Cu(emizco)2Br2] (4), [Cu(emizco)2(H2O)2](NO3)2 (5) and [Cu(emizco)4](NO3)2 (6), is presented. These compounds were characterised by IR and UV spectroscopic techniques, in addition the crystal structures of compounds 1-5 were determined. For complexes 2-5, emizco is coordinated as a bidentate ligand, through the oxygen atom of the carboxylate moiety and the nitrogen atom of the imidazolic ring. Different geometries are stabilised: compound 2 includes a pentacoordinated square pyramidal metal centre, while 3-5 are derived from octahedral geometry. Halide compounds 3 and 4 show a cis-octahedral arrangement, which is not very common on [CuN2O2X2] systems, while 5 stabilises the trans-octahedral isomer. Compound 6 displays a square planar geometry. Finally, hydrolysis of emizco to its corresponding carboxylic acid (mizco), allowed the preparation of another square planar complex 7, identified as [Cu(mizco)2] 0.5H2O. Solution studies of these compounds indicate that emizco is not substituted from the coordination sphere, remaining as a bidentate ligand. Halides are substituted by water molecules, changing from cis octahedral to the trans-[Cu(emizco)2(H2O)2]2+ isomer.     

Investigation of the role of the substrate metal ion in the yeast inorganic pyrophosphatase reaction

The substrate activities of a series of tripositive metal ion-pyrophosphate complexes with yeast inorganic pyrophosphatase were examined. While the Michaelis constants for these complexes were shown to be between one and two orders of magnitude greater than that of the natural substrate, [Mg(H2O)4PPi]2-, the turnover numbers were in general comparable to that of [Mg(H2O)4PPi]2-. These data suggest that the nature of the metal ion cofactor effects substrate binding but in most cases not catalysis. Thus, the role of the metal ion in catalysis is probably restricted to that of an electron sink.     

Apoptosis of lymphocytes induced by chromium(VI/V) is through ROS-mediated activation of Src-family kinases and caspase-3

Mechanistic insights into Cr(VI)-induced carcinogenicity and possible implication of Cr(V) species formed by the redox reactions of chromium-bearing species have attracted interest. We have previously demonstrated that when human peripheral blood lymphocytes are exposed to the Cr(V) complexes, viz., sodium bis(2-ethyl-2-hydroxybutyrato)oxochromate(V), Na[Cr(V)O(ehba)(2)] and sodium bis(2-hydroxy-2-methylbutyrato)oxochromate(V), Na[Cr(V)O(hmba)(2)], apoptosis and formation of reactive oxygen species (ROS) are observed. The molecular mechanisms involving cellular signaling pathways leading to apoptosis are addressed in the present study. Treatment of lymphocytes with Na[Cr(V)O(ehba)(2)] and K(2)Cr(2)O(7) leads to the activation of the Src-family protein tyrosine kinases namely, p56(lck), p59(fyn), and p56/53(lyn), which then activates caspase-3, both of which are under the partial influence of ROS. Inhibition of the Src-family tyrosine kinases activity by PP2 and of caspase-3 by Z-DEVD-FMK reverses apoptosis, thereby suggesting their importance. Antioxidants only partially reverse the apoptosis induced by Cr(VI/V), suggesting that pathways other than those induced by ROS cannot be ruled out. Although the complex, Na[Cr(V)O(ehba)(2)] is known to be relatively stable in aqueous solutions, previous studies have shown that the Cr(V) complex, Na[Cr(V)O(ehba)(2)] disproportionates to Cr(VI) and Cr(III) forms at pH 7.4 through complex mechanistic processes. Dynamics studies employing EPR data show that the Cr(V) state in Na[Cr(V)O(ehba)(2)] is relatively more stable in RPMI-1640 medium containing plasma. Formation of ROS during the reaction of redox partners with Na[Cr(V)O(ehba)(2)] is an early event and compares favorably in kinetic terms with the reported rate processes for disproportionation. This investigation presents evidence for the direct implication of Cr(V) in Cr(VI)-induced apoptosis of lymphocytes.     

Metal-ion interactions with sugars. Crystal structures and FT-IR studies of the LaCl3-ribopyranose and CeCl3-ribopyranose complexes

Single crystals of LaCl3.C5H10O5.5H2O (1) and CeCl3.C5H10O5.5H2O (2) were obtained from ethanol-water solutions and their structures determined by X-ray. The two complexes are isomorphous. Two configurations of complex 1 or complex 2, as a pair of isomers, were found in each single crystal in a disordered state. The ligand of one of the isomer is alpha-D-ribopyranose in the 4C1 conformation, the ligand of the other is beta-D-ribopyranose in the 1C4 conformation. For complex 1, the alpha:beta anomeric ratio is 51:49, and for complex 2, the ratio is 52:48. Both ligands of the two isomers provide three hydroxyl groups in ax-eq-ax orientation for coordination. The Ln3+ (Ln = La or Ce) ion is nine-coordinated with five Ln-O bonds from water molecules, three Ln-O bonds from hydroxyl groups of the D-ribopyranose, and one Ln-Cl bond from chloride ion. The hydroxyl groups, water molecules, and chloride ions form an extensive hydrogen-bond network. The IR spectral C-C, O-H, C-O, and C-O-H vibrations were observed to be shifted in both the two complexes and the IR results are in accord with those of X-ray diffraction.     

Investigation of the regiospecificity and stereospecificity of proton transfer in the yeast inorganic pyrophosphatase catalyzed reaction

The regiospecificity and stereospecificity of proton transfer in the yeast inorganic pyrophosphatase (PPase) catalyzed hydrolysis of P1,P2-bidentate Mg(H2O)4(PPi)2- were probed with exchange-inert metal complexes of imidodiphosphate (PNP) and thiopyrophosphate (PPS). PPase was unable to catalyze the hydrolysis of Mg(H2O)4PNP and P1,P2-bidentate Co(NH3)4PNP under conditions that resulted in rapid hydrolysis of the corresponding metal-PPi complexes. PPase was found to catalyze the hydrolysis of Mg(H2O)4PPS at 17% the rate of Mg(H2O)4PPi hydrolysis. The Km of Mg(H2O)4PPS was determined to be 300 microM, which is a value 10-fold greater than that observed for Mg(H2O)4PPi. P1,P2-Bidentate Cr(H2O)4PPS and Co(NH3)4PPS (prepared from PPS) were both found to be substrates for PPase. The enzyme specifically catalyzed the hydrolysis of the Rp enantiomers of these complexes and not the Sp enantiomers. These results are accommodated by a reaction mechanism involving enzyme-mediated proton transfer to the pro-R oxygen atom of the incipient phosphoryl leaving group of the bound P1,P2-bidentate Mg(H2O)4PPi2- complex.     

Investigation of the preferred Mg(II)-adenine-nucleotide complex at the active site of ectonucleotidases in intact vascular cells using phosphorothioate analogues of ADP and ATP

In the presence of Mg2+ the ecto-(nucleoside diphosphatase) on intact vascular endothelial or smooth muscle cells in culture selectively catabolizes the PS diastereoisomer of adenosine 5'-[alpha-thio]diphosphate, (PS)-ADP [alpha S], and the ecto-(nucleoside triphosphatase) selectively catabolizes the PS isomer of adenosine 5'-[beta-thio]triphosphate, (PR)-ATP[beta S], but exhibits no selectivity towards ATP[alpha S] isomers. In the presence of Cd2+ selectivity to ADP[alpha S] and to ATP[beta S] isomers is reversed; in the presence of Co2+, selectivity is lost. We conclude that each enzyme preferentially recognises the lambda (screw-sense) bidentate Mg(II)-nucleotide complex at its active site.     

Mechanistic information on the reaction of cis- and trans-[RuCl2(DMSO)4] with d(T2GGT2) derived from MALDI-TOF and HPLC studies

Reactions of trans and cis isomers of the Ru(II) complex [RuCl(2)(DMSO)(4)] with single-stranded hexanucleotide d(T(2)GGT(2)) were studied in aqueous solutions in the absence and presence of excess chloride by high performance liquid chromatography (HPLC) and matrix-assisted laser desorption/ionisation time of flight mass spectrometry (MALDI-TOF MS). Despite the different reactive species formed from the two isomers in aqueous solution, similar reaction products are obtained in their interaction with d(T(2)GGT(2)). Both [RuCl(2)(DMSO)(4)] isomers bind to the oligonucleotide in the bidentate mode to form thermodynamically stable bis-guanosine adducts, Ru(G-N7)(2). Significant differences were observed in the reaction rates, however the reaction with trans- [RuCl(2)(DMSO)(4)] is ca. 5-10 times faster in comparison to that observed for the cis analogue. This difference is interpreted in terms of different rate-limiting steps for the trans and cis complexes, respectively. It is suggested that the rate of the reaction with the trans isomer is controlled by dissociation of a Cl(-) ligand from the initially formed trans,cis,cis-[RuCl(2)(DMSO)(2)(H(2)O)(2)]. In the contrast, release of a dimethyl sulfoxide molecule from the reactive species cis,fac-[RuCl(2)(DMSO)(3)(H(2)O)] is likely to be rate limiting for the cis analogue. Significant influence of electrostatic interactions on the reaction rate was observed for the trans isomer. Mechanistic interpretation of the observed reactivity trends based on data obtained from UV-Vis spectroscopy, HPLC and MALDI-TOF MS studies is presented and discussed within the paper.     

Protein degradation by peroxide catalyzed by chromium (III): role of coordinated ligand

In order to understand the role of coordinated ligands in controlling the biotoxicity of chromium (III), interactions of three types of chromium (III) complexes viz. trans-diaquo [1,2 bis (salicyledeneamino) ethane chromium (III) perchlorate, [(Cr(salen)(H(2)O)(2)](ClO(4)); tris (ethylenediamine) chromium (III) chloride, [Cr(en)(3)]Cl(3), and monosodium ethylene diamine tetraacetato monoaquo chromiate (III), [Cr(EDTA)(H(2)O)]Na with BSA has been investigated. Spectroscopic and equilibrium dialysis studies show that the two cationic complexes Cr(salen)(H(2)O)(+)(2) and Cr(en)(3+)(3) bind to the protein with a protein-metal ratio of 1:8 and 1:4. The anionic complex Cr(EDTA)(H(2)O)(-) binds to the protein with a protein-metal ratio of 1:2. The binding constant K(b) as estimated from the fluorescence quenching studies has been found to be 7.6 +/- 0.4 x 10(3) M(-1), 3.1 +/- 0.2 x 10(2) M(-1), and 1.8 +/- 0.2 x 10(2) M(-1) for Cr(salen)(H(2)O)(+)(2), Cr(en)(3+)(3), and Cr(EDTA)(H(2)O)(-) respectively indicating that the thermodynamic stability of protein-chromium complex is Cr(salen)(H(2)O)(+)(2) > Cr(en)(3+)(3) approximately Cr(EDTA)(H(2)O)(-). The complexes Cr(salen)(H(2)O)(+)(2) and Cr(EDTA)(H(2)O)(-) in the presence of hydrogen peroxide have been found to bring about protein degradation, whereas Cr(en)(3+)(3) does not bring about any protein damage. This clearly shows that the nature of the chromium (III) complex plays a major role in the biotoxicity of chromium (III).