99Mo metabolism in sheep after the intravenous injection of [99Mo] thiomolybdates

[99Mo]di-, tri-, and tetrathiomolybdate (5.4 to 62.5 mg of Mo) were given by intravenous injection to sheep maintained on a sulfur-supplemented (3 g of S/kg) diet. All the compounds were metabolized very rapidly over the first 15 min postinjection, but relatively slowly thereafter, with a t1/2 of about 30 hr for dithiomolybdate and 40 h for tri- and tetrathiomolybdate. The [99Mo] metabolites present in plasma were identified by Sephadex G-25 chromatography. The main fate of the compounds injected appeared to be stepwise transformation to molybdate and subsequent rapid urinary elimination. Over 90-100 hr more than 90% of the radioactivity was excreted in urine, compared to less than 5% in the feces. The trichloroacetic acid (TCA) solubility of plasma copper and the diamine oxidase activity of ceruloplasmin was depressed, particularly over the first 15 min postinjection and a more persistant TCA-insoluble Cu fraction was apparent.     

NMR study of the complexation of D-gulonic acid with tungsten(VI) and molybdenum(VI)

By using multinuclear (1H, 13C, 17O, 95Mo, 183W) magnetic resonance spectroscopy (1D and 2D), D-gulonic acid is found to form ten and seven complexes, respectively, with tungsten(VI) and molybdenum(VI), in aqueous solution, depending on pH and metal-ligand molar ratios. Two isomeric 1:2 (metal-ligand) complexes involving the carboxylate and the adjacent OH group are present in the pH range 2-9. At intermediate and high pH, molybdate forms a 2:1 tetradentate complex involving the four secondary hydroxyl groups, whereas tungstate forms one 2:1 terdentate species. At low and intermediate pH values, three 2:1 complexes are found for both metals, involving the carboxylate group and three secondary hydroxyl groups, as well as a 5:2 species involving the carboxylate group and all the secondary hydroxyl groups; the concentration of this species increases in time mainly at the expense of 2:1 and 1:2 complexes. Tungstate can also form two additional species, probably a 5:2 species involving the carboxylate group and all the hydroxyl groups, and a 2:1 pentadentate species involving the carboxylate group and all the secondary hydroxyl groups. In alkaline solutions, tungstate is able to form an additional 2:1 pentadentate complex involving all the hydroxyl groups.     

Insights into the nature of Mo(V) species in solution: Modeling catalytic cycles for molybdenum enzymes

The tris(pyrazolyl)borate and related tripodal N-donor ligands originally developed by Trofimenko stabilize mononuclear compounds containing Mo^VIO₂, Mo^VIO, Mo^VO, and Mo^IVO units and effectively inhibit their polynucleation in organic solvents. Dioxo-Mo(VI) complexes of the type LMoO₂(SPh), where L = hydrotris(3,5-dimethylpyrazol-1-yl)borate (Tp^∗), hydrotris(3-isopropylpyrazol-1-yl)borate (Tp^iPr), and hydrotris(3,5-dimethyl-1,2,4-triazol-1-yl)borate (Tz) and related derivatives are the only model systems that mimic the complete reaction sequence of sulfite oxidase, in which oxygen from water is ultimately incorporated into product. The quasi-reversible, one-electron reduction of Tp^∗MoO₂(SPh) in acetonitrile exhibits a positive potential shift upon addition of a hydroxylic proton donor, and the magnitude of the shift correlates with the acidity of the proton donor. These reductions produce two Mo(V) species, [Tp^∗Mo^VO₂(SPh)]⁻ and Tp^∗Mo^VO(OH)(SPh), that are related by protonation. Measurement of the relative amounts of these two Mo(V) species by EPR spectroscopy enabled the pK_a of the Mo^V(OH) unit in acetonitrile to be determined and showed it to be several pK_a units smaller than that for water in acetonitrile. Similar electrochemical-EPR experiments for Tp^iPrMoO₂(SPh) indicated that the pK_a for its Mo^V(OH) unit was ∼1.7 units smaller than that for Tp^∗Mo^VO(OH)(SPh). Density functional theory calculations also predict a smaller pK_a for Tp^iPrMo^VO(OH)(SPh) compared to Tp^∗Mo^VO(OH)(SPh). Analysis of these results indicates that coupled electron-proton transfer (CEPT) is thermodynamically favored over the indirect process of metal reduction followed by protonation. The crystal structure of Tp^iPrMoO₂(SPh) is also presented.     

Acetylcholinesterase from desert Cobra (Walterinnesia aegyptia) venom: Optimization and kinetics study

Acetylcholinesterase (AChE) was investigated inWalterinnesia aegyptia venom and characterized with respect to its kinetic properties. It was found that 4.0 ug of crude venom protein and an incubation time of 4.0 min were suitable conditions for linearity of AChE activity at 25°C. The optimum strength of the sodium phosphate buffer was 0.05 M, and the optimum pH was 7.75. The optimum temperature was 30°C. The activation energy and the heat of activation were observed to be 6510 and 5922 cal/mole. The AChE was specific for acetylthiocholine but it did not hydrolyse butyrylthiocholine. The optimum substrate concentration was 3.0 mM but at higher substrate concentrations, the AChE activity declined. The ASCh concentration ranges for different orders of the reactions were determined and kinetic parameters (K_m, V_max, k_cat, and k_sp) were established at each order of the reaction.Abbreviations AChE acetylcholinesterase - ASCh acetylthiocholine - K_m Michaelis-Menten constant - V_max the limiting maximal velocity - AChE_a acylated enzyme - k_cat turnover number - k_sp specificity constant     

The role of cyclopentadienyl versus indenyl in Mo(II) spirodiene complexes reactivity: A DFT mechanistic study

Spiro[2,4]hepta-4,6-diene and spiro[4,4]nona-1,3-diene react with [Mo(CO)₂Cp’(NCCH₃)₂][BF₄] (Cp’ = Cp, Ind; Ind = η⁵-C₉H₇) to afford the corresponding diene complex [Mo(diene)(CO)₂Cp′]⁺. When Cp’ = Ind, the reaction proceeded forward leading to ring opening in the case of the small spiro ring. Although this and another product resulting from migration of the side arm to the carbonyl were detected when Cp’ = Cp, they did not form from the diene complex. A DFT/PBE1PBE study was carried out and showed a kinetically controlled reaction pathway leading from the [Mo(diene)(CO)₂Ind]⁺ to the reaction product, with an activation barrier of 21.3 kcal mol⁻¹. The thermodynamic preferred species was the non-observed complex (insertion), and its formation required higher barriers. In the presence of Cp, all the barriers increased significantly, explaining the inertness of the initial diene complex. The interpretation of this behaviour is associated with the ease of the η⁵ → η³ haptotropic rearrangement of the indenyl, which helps to lower some relevant barriers. This route is not available for the Cp analogue.     

Syntheses, characterisation, infrared and Mo NMR spectroscopy of some coordinated oxo—molybdenum(VI) complexes

Adducts with MoO₄²⁻ tetrahedra coordinated to Cr(III) or Co(III) complexes have been synthesized and studied by IR and high resolution ⁹⁵Mo NMR spectroscopy. The ⁹⁵Mo chemical shifts of the adducts with cobalt(III) lie in the range −33.2 to + 49.4 ppm. This may be compared with an overall known chemical shift range in excess of 7000 ppm and implies a similarity in the molybdenum environment in all cases. For adducts with chelated cobalt(III) complexes several rather broad ⁹⁵Mo singnals are obtained with linewidths up to 260 Hz.     

Purification and characterization of the hemoglobin components of Adriatic sturgeon (Acipenser naccarii) blood

The oxygen binding properties of Acipenser naccarii hemoglobins have been investigated, and were found not to differ significantly from those shown by blood, intact erythrocytes and hemolysate in the presence of the physiological cofactors GTP and chloride ions. In particular, the oxygen equilibrium reveal a very low sensitivity of the hemolysate to the chloride ions and temperature while in the presence of organic phosphates their oxygen affinity decreased strongly. The electrophoretic analysis of the hemolysate of the sturgeon showed the presence of two hemoglobin components, each with a considerable globin multiplicity. The partial amino acid sequence of the a and P chain of the single hemoglobins was also established.     

Effect of 67Cu and 99Mo labeled tetrathiomolybdate on the distribution of 67Cu, Cu, and 99Mo in bile fractions in sheep

The effect of intravenous administration of 67Cu and 99Mo labeled tetrathiomolybdate (TTM) on the appearance of 67Cu, stable Cu, and 99Mo in gel chromatographic fractions of bile was examined in sheep fed either 5 or 35 mg Cu kg-1 DM. Peak excretory periods of biliary 67Cu, stable Cu, and 99Mo were observed at 30 min-1.25 hr, 2-3 hr, and 11-13 hr after 67Cu and after 99Mo labeled TTM. Sephadex G-75 gel filtration of bile samples collected at 1, 3, and 12 hr after 67Cu administration revealed two major protein peaks of molecular weights of greater than 80,000 (peak I) and 7,000 (peak II) containing both 67Cu and Cu. But the ratio of 67Cu in the two peaks varied with time of bile collection. The ratio of areas of peak I:II 1 hr after 67Cu administration was approximately 0.48; at 3 hr, 0.62, and at 12 hr 1.35. Tetrathiomolybdate administration increased both 67Cu and stable Cu in bile by severalfold and induced a major shift of Cu into the higher molecular weight protein fraction. The experiments confirm the effectiveness of TTM as a "decoppering" agent. Furthermore, TTM not only promoted bile Cu excretion, but it also increased the incorporation of Cu into the macromolecular fraction. This may limit enterohepatic circulation of biliary Cu and thereby cause an overall Cu depletion and a negative Cu balance.     

Multinuclear NMR study of the complexes of 6-phospho-D-gluconic acid with W(VI) and Mo(VI)

Multinuclear ((1)H, (13)C, (17)O, (31)P, (95)Mo, (183)W) magnetic resonance spectroscopy (1D and 2D) has been used to show that 6-phospho-d-gluconic acid forms three complexes with tungsten(VI) and six complexes with molybdenum(VI) in aqueous solution, depending on pH and concentration. Two isomeric 1:2 (metal-ligand) complexes are detected both with tungstate(VI) and molybdate(VI), having MO(2)(2+) centres and involving the carboxylate and the adjacent OH groups in addition to one 2:1 (metal-ligand) complex possessing a M(2)O(5)(2+) centre, with the ligand being coordinated by the carboxylate group and the three consecutive OH groups in positions 2, 3 and 4. Molybdate(VI) forms three additional species, which are not detected with tungstate. One of them is a 2:1 complex with a Mo(2)O(5)(2+) centre, with the ligand being tetradentate via O-3, O-4, O-5 and the phosphate group. The other two are 12:4 species, which can be seen as two 1:2 complexes bound together in a ring through two diphosphomolybdate moieties each derived from heptamolybdate by inclusion of two phosphate groups from the ligands.     

Nanopore detachment kinetics of poly(A) binding proteins from RNA molecules reveals the critical role of C-terminus interactions

The ubiquitous and abundant cytoplasmic poly(A) binding protein (PABP) is a highly conserved multifunctional protein, many copies of which bind to the poly(A) tail of eukaryotic mRNAs to promote translation initiation. The N-terminus of PABP is responsible for the high binding specificity and affinity to poly(A), whereas the C-terminus is known to stimulate PABP multimerization on poly(A). Here, we use single-molecule nanopore force spectroscopy to directly measure interactions between poly(A) and PABPs. Both electrical and biochemical results show that the C-C domain interaction between two consecutive PABPs promotes cooperative binding. Up to now, investigators have not been able to probe the detailed polarity configuration (i.e., the internal arrangement of two PABPs on a poly(A) streak in which the C-termini face toward or away from each other). Our nanopore force spectroscopy system is able to distinguish the cooperative binding conformation from the noncooperative one. The ～50% cooperative binding conformation of wild-type PABPs indicates that the C-C domain interaction doubles the cooperative binding probability. Moreover, the longer dissociation time of a cooperatively bound poly(A)/PABP complex as compared with a noncooperatively bound one indicates that the cooperative mode is the most stable conformation for PABPs binding onto the poly(A). However, ～50% of the poly(A)/PABP complexes exhibit a noncooperative binding conformation, which is in line with previous studies showing that the PABP C-terminal domain also interacts with additional protein cofactors.     

Thrombosis and atherosclerosis: regulatory role of interactions among blood components and endothelium

Complex interactions among constituents of blood and components of the vessel wall are involved in the pathogenesis of atherosclerosis and its subsequent thrombotic complications. Alterations in the endothelium are central both to the slowly progressive process of atherogenesis and to the acute events leading to thrombotic occlusion. Recent data, obtained by systematic evaluation of chronologic events that occur in diet-induced atherosclerosis, have extended our understanding of interactive processes among endothelium, monocytes, platelets, vascular smooth muscle cells, and humoral hemostatic elements in atherogenesis.     

Mixed-ligand tris chelated complexes of Mo(IV) and W(IV): A comparative study

Two hitherto unknown mixed-ligand tris chelated complexes containing 2-aminothiophenolate, [Et₄N]₂[M^IV(NH-(C₆H₄)-S)(mnt)₂] (M = Mo, 1a; W, 2a) and two mixed-ligand tris chelate complex containing N,N-diethyldithiocarbamate, [Et₄N]₂[M^IV(Et₂NS₂)(mnt)₂] (M = Mo, 1b; W, 2b) have been synthesized and characterized structurally. Although these complexes are supposed to be quite similar to the well-known symmetric tris chelate complexes of maleonitriledithiolate (mnt), [Et₄N]₂[M^IV(mnt)₃] (M = Mo, 1c; W, 2c), but display both trigonal prismatic and distorted trigonal prismatic geometry in their crystal structure indicating the possibility of an equilibrium between these two structural possibilities in solution. Unlike extreme stability of 1b, 2b, 1c and 2c, both 1a and 2a are highly unstable in solution. In contrast to one reversible reduction in case of 1b and 2b, 1a and 2a exhibited no possible reduction up to −1.2 V and two sequential oxidation steps which have been further investigated with EPR study. Differences in stability and electrochemical behavior of 1a, 1b, 2a and 2b have been correlated with theoretical calculations at DFT level in comparison with long known 1c and 2c.     

Immunochemical study of the blood group-active poly(glycosyl) ceramides isolated from human erythrocytes

An immunochemical study of two previously isolated I blood group-active glycolipids is described. It was found that anti-I autoantibodies may recognize different segments of the internal branch structures of oligosaccharide chains in the native erythrocyte antigen. The type of sugar present at the nonreducing terminal is less important but it does modify the reaction of antibodies with the glycolipid antigen. Anti-I alloantibodies need an N-acetyllactosamine sequence to be present at the nonreducing end of the branch oligosaccharide chain and substitution with fucose molecules at the non-reducing ends of the oligosaccharide chain diminishes the activity 10 times.     

Triphenylbismuth seven-coordinate complexes of molybdenum(II) and tungsten(II)

The seven-coordinate complexes [MI₂(CO)₃(NCMe)₂] (M = Mo and W) react with one equivalent of BiPh₃ in CH₂Cl₂ at room temperature to give the monoacetonitrile complexes [MI₂(CO)₃(NCMe)(BiPh₃)]. The molybdenum complex [MoI₂(CO)₃(NCMe)(BiPh₃)] after stirring in CH₂Cl₂ at room temperature for 5 h affords the iodide-bridged dimer [Mo(μ-I)I(CO)₃(BiPh₃)]₂, whereas the tungsten complex [WI₂(CO)₃(NCMe)(BiPh₃)] does not appear to dimerise even after stirring for 48 h in CH₂Cl₂ at room temperature. Reaction of [MI₂(CO)₃(NCMe)₂] with two equivalents of BiPh₃ gives the bistriphenylbismuth compounds [MI₂(CO)₃(BiPh₃)₂] in good yield. The new mixed ligand complexes [MI₂(CO)₃L(BiPh₃)] were prepared either by reaction of [MI₂(CO)₃(NCMe)(BiPh₃)]in situ with one equivalent of L(L = P(OPh)₃), or an in situ reaction of [MI₂(CO)₃(NCMe)L] (L = PPh₃ and SbPh₃; and L = AsPh₃ and PPh₂Cy (for M = Mo only) with an equimolar quantity of BiPh₃. Reaction of [MoI₂(CO)₃(NCMe)(BiPh₃)] with one equivalent of 2,2′-bipyridyl (bipy) in CH₂Cl₂ at room temperature afforded the cationic complexes [MoI(CO)₃(bipy)(BiPh₃)]I in good yield. The complex [WI₂(CO)₃(NCMe)(BiPh₃)] (prepared in situ) reacts with two equivalents of NaS₂CNMe₂·2H₂O to eventually give the non-triphenylbismuth containing product [W(CO)₃(S₂CNMe₂)₂] in high yield.