Guanine complexes with dysprosium(III), thorium(IV) and uranium(IV) chlorides

By refluxing mixtures of guanine (guH) and DyCl₃, ThCl₄ or UCl₄ in ethanol-triethyl orthoformate, solid complexes of the Dy(guH)₂(gu)Cl₂ and M(gu)₂Cl₂ (M = Th, U) types were isolated. The insolubility of the new complexes in organic media, combined with the coordination number six suggested by the spectral evidence, favors polymeric configurations. Most likely structures involve a linear, chainlike, single-bridged polymeric backbone

The Dy³⁺ complex is probably a linear polymer, also containing terminal unidentate guanine ligands, whilst for M = Th⁴⁺, U⁴⁺ highly polymeric structures arising from cross-linking between linear polymeric

units seems most likely. IR evidence rules out participation of the O(6) oxygen of guanine in coordination, despite the hard acid character of the metal ions under study. Guanine apparently coordinates exclusively through ring nitrogens in the new metal complexes; N(9) and N(7). N(9) are, respectively, the most likely binding sites of terminal unidentate and bridging bidentate guanine. The chloro ligands present in the complexes seem to be exclusively terminal.     

Synthesis,spectral characterization,in vitro microbial and cytotoxic studies of lanthanum(III) and thorium(IV) complexes with 1,2,4-triazole Schiff bases

A series of metal complexes of La(III) and Th(IV) have been synthesized with newly derived biologically active ligands. These ligands were synthesized by the condensation of 3-substituted-4-amino-5-hydrazino-1,2,4-triazole with 8-formyl-7-hydroxy- 4-methylcoumarin. The structure of the complexes has been proposed by elemental analyses, spectroscopic data i.e. i.r., ¹H nmr, Uv-Vis, FAB-mass and thermal studies. The elemental analyses of the complexes conform to the stoichiometry of the type [La(L)·3H₂O]·2H₂O and [Th(L)(NO₃)·2H₂O]·2H₂O where (L = L^I-L^IV). All the complexes are soluble in DMF and DMSO and are non-electrolytes in DMF and DMSO. All these ligands and their complexes have also been screened for their antibacterial (Escherichia coli, Staphylococcus aureus, Staphylococcus pyogenes and Pseudomonas aeruginosa) and antifungal activities (Aspergillus niger, Aspergillus flavus and cladosporium) by the MIC method. The brine shrimp bioassay was also carried out to study their invitro cytotoxic properties.     

Chloride and tropolonato mixed complexes of uranium(IV) and thorium(IV)

The synthesis of some new chloride and tropolonato mixed complexes of the general composition MCl_4?nTrop_n·mL (M = U^IV, Th^IV; n = 1, 2, 3; m = $\text{1}\text{2}$, $\text{2}\text{3}$, 1, 2 and 3; L = DME, THF, LiCl and 18-crown-6) by the reaction of uranium and thorium tetrachlorides with M′Trop (M′ = Tl and Li) is described. The residual chloride atoms in UTropCl₃·THF undergo further substitution reactions involving TlCp, while UTrop₂Cl₂·THF shows a different behaviour toward TlCp, since Cp₃UCl as one of the main reaction products is obtained. Protolysis of Cp₂U(NEt₂)₂ by HTrop affords a mixture of CpUTrop₃ and Cp₂UTrop₂. Finally both UTropCl₃·THF and UCl₄ react directly with HTrop, the nature of the resulting products depending on the reaction solvent.     

Chloride and oxinate mixed complexes of uranium(IV) and thorium(IV)

Some new chloride and oxinate mixed complexes of general composition MCl_4?nOx_n (M = U(IV) and Th(IV); Ox = 8-hydroxyquinolinato; n = 1, 2) were synthesized by the reaction of uranium or thorium tetrachlorides with M′Ox (M′ = Na, K, Tl) or MgOx₂. By using the oxine the formation of the adducts MCl₄·2HOx occurs, without the substitution of the chloride ions. By suspending MCl₄·2HOx in the presence of a strong base (Proton Sponge) MCl₂Ox₂ was formed immediately. The reaction of UCl₂Ox₂ and TlCp did not afford Cp₂UOx₂, which can be easily prepared by reaction of Cp₂U(NEt₂)₂ and HOx.     

Oxydiacetato complexes of thorium(IV), the crystal structures of tetra-aquo bis(oxydiacetato)thorium(IV) hexahydrate and di(sodium nitrate) disodium tris(oxydiacetato)thorium(IV)

The crystal and molecular structures of Th(oda)₂(H₂O)₄·6H₂O (1) and Na₂[Th(oda)₃]·2NaNO₃ (2) (oda = oxydiacetate) have been determined from three-dimensional X-ray diffraction data and refined by least squares to R = 0.049 and Rw = 0.049 for 2265 independent reflections for (1) and to R = 0.024 and Rw = 0.023 for 2196 independent reflections for (2).Crystal parameters are as follows: (1), tetragonal, space group P4₁2₁2, a = 10.335(2), c = 20.709(5) Å and Z = 4; (2), monoclinic, space group C2/c, a = 17.096(5), b = 9.451(2), c = 16.245(4) Å, β = 107.8(1) and Z = 4.In both compounds the thorium atom lies on a crystallographic two-fold axis. The co-ordination number for thorium in (1) is 10 (bicapped square antiprism geometry), the compound is monomeric, the two oda ligands are tridentate to the metal, and four water molecules complete the coordination sphere; in thorium (2) the coordination number is 9 (tricapped trigonal prism geometry) with three oda ligands tridentate to the metal, the [Th(oda)₃]^2? and NO₃^? anions are held together through the sodium ions which are coordinated both to the oda carboxylic oxygens and to the nitrate oxygens.The ThO coordination distances are: in (1) 2.411(8), 2.414(9) for the carboxylic oxygens, 2.479(10) and 2.486(8) for water molecules and 2.697(9) for the etheric oxygen and in (2) 2.384(3), 2.402(4) and 2.402(4) for the carboxylic oxygens, 2.559(5) and 2.562(4) Å for the etheric oxygens.     

Oxomolybdenum(III, IV and V) complexes of thiofunctional ligands

Reaction of [MoO₂(acac)₂] with (S is a thioether, S′ a thiophenolate function) yielded the compound Li₇(thf)₁₇{MoO}₈ · 10thf · hexane, where {MoO}₈ represents one 1, three (2, linked, via the oxo group, to [Li(thf)₃]⁺) and two (3a, linked by two [Li(thf)₂]⁺).A mixed-valent variant of 3, (3b, with an additional[Li(thf)₃]⁺ attached to S′), was also identified. The compounds model features pertinent to oxo-transferases containing the molybdopterin cofactor.     

N,N-diisopropylcarboxylic acid amide complexes of thorium(IV) and uranium(IV) N-thiocyanates; the crystal structure of tetraisothiocyanato tetrakis(N,N-diisopropylacetamide-O)uranium(IV)

The complexes M(NCS)₄·xL (x = 2, M = U, L = Me₃CCON(Prⁱ)₂(dippva); x = 3, M = Th, L = Me₂CHCON(Prⁱ)₂(dipiba) and dippva, M = U, L = EtCON(Pr¹)₂(dippa), dipiba and dippva; x = 4, M = Th, L = MeCON(Prⁱ)₂(dipa), dippa and dipiba, M = U, L = dipa, dippa) and the solvates M(NCS)₄·4dipa·CH₂Cl₂ (M = Th, U) have been prepared. Their i.r. and u.v.-visible (M = U only) spectra are reported. The crystal and molecular structure of U(NCS)₄(dipa)₄· CH₂Cl₂ has been determined by the heavy-atom method from X-ray diffractometer data and refined by least squares to R 0.029 for 1135 independent reflections. The crystal is tetragonal, space group P$\text{4}$2₁c, with Z = 2, a = 15.663(4) and c = 10.512(3) Å. The coordination geometry about the 8-coordinate uranium atom is dodecahedral with the N atoms of the NCS groups occupying the dodecahedral A sites and the ‘dipa’ O atoms the B sites. The bonding distances of UO and UN are 2.363(8), and 2.444(11) Å respectively.     

Seven coordinate complexes of metal(II) nitrates

ESR spectra at both X and Q band are reported for manganese(II) ions doped into the seven coordinate complexes M(L)₃(NO₃)₂ (M = Co, Ni, Zn or Cd; L = pyridine or substituted pyridine). The zero field splitting parameters D and λ (= E/D) are deduced. All complexes show considerable deviation from cubic symmetry, as can be expected for a seven coordinate structure. The distinctly lower D value of Ni(Mn)(pyridine)₃(NO₃)₂, as compared to the analogous cobalt and zinc complex, suggests a geometry tending towards an octahedral structure. The steric hindrance by the substituent reduces the D value.     

Biosorption of thorium (IV) by a Pseudomonas biomass

Lyophilized biomass of a Pseudomonas soilisolate adsorbed thorium (IV) (430 mg g^–1 dry wt) optimally at pH 4, with 91% of equilibrium loading being reached in 1 min. Equilibrium metal sorption showing conformity to Langmuir isotherm model suggested a monolayered thorium binding. Thorium binding remained unaffected or slightly affected (< 20% inhibition) in presence of equimolar (430 M) concentration of several interfering ions except Fe³⁺ (40% inhibition). More than 90% of loaded thorium could be recovered using 1 M CaCO₃, though mineral acids and Na₂CO₃ were also effective.     

High-coordinated lanthanum(III) complexes with new mono- and bidentate phosphoryl donors; spectroscopic and structural aspects

Monodentate and bidentate ligands PhNHP(O)(NC₄H₈O)₂ (1) and PhC(O)NHP(O)(NH(tert-C₄H₉))₂ (2) were used to prepare new 7, 9 and 10-coordinated lanthanum(III) complexes; La(1)₂Cl₃(H₂O)₂ (3), La(1)₂(NO₃)₃H₂O.La(1)₂(NO₃)₃CH₃CN (4) and La(2)₂(NO₃)₃ (5), respectively. Crystallization of compound 2 in CH₃OH:CH₃CN leads to one conformer in contrast to the crystallization result from CHCl₃:n-C₇H₁₆ (two conformers). Compound 4 contains two independent nine-coordinated La(III) complexes that are different in the solvated molecules (H₂O and CH₃CN). Some structural and electronic perturbations in coordinated ligand were occurred upon complexation, that are confirmed by increase of ²J_PH, ³J_PH and ⁶J_PH coupling constants from the free ligand 1 to complexes 3 and 4. The steric repulsions in the first coordination sphere of La³⁺ ion, metal-ligand (M-L) binding strength and PO stretching frequency are very influenced by changing the counter ion from Cl⁻ to . Comparing the X-ray crystallography data of free ligand 2 with bis-chelated complex 5, it is found that the phosphoryl group is more reactive than carbonyl counterpart. A blue shift of the ν(N-H) vibration is observed in line with the weakening of the hydrogen bond from N-H···O_Phosphoryl in 1 to N-H···Cl in 3. Three dimensional butterfly-shape structures are seen in the unit cell of complex 3, which are produced by O_Water-H···O_Morpholine hydrogen bonds.     

Diphosphinoazine rhodium(III) and iridium(III) octahedral complexes

Rhodium(III) and iridium(III) octahedral complexes of general formula [MCl₃{R₂PCH₂C(Bu^t)NNC(Bu^t)CH₂PR₂}] (M = Rh, Ir; R = Ph, c-C₆H₁₁, Prⁱ, Bu^t; not all the combinations) were prepared either from the corresponding diphosphinoazines and RhCl₃ · 3H₂O or by the oxidation of previously reported bridging complexes [{MCl(1,2-η:5,6-η-CHCHCH₂CH₂CHCHCH₂CH₂)}₂{μ-R₂PCH₂C(Bu^t)NNC(Bu^t)CH₂PR₂}] with chlorine-containing solvents. Depending on the steric properties of the ligands, complexes with facial or meridional configuration were obtained. Crystal and molecular structures of three facial and two meridional complexes were determined by X-ray diffraction. Hemilability of ligand in the complex fac-[RhCl₃{(C₆H₁₁)₂PCH₂C(Bu^t)NNC(Bu^t)CH₂P(C₆H₁₁)₂}] consisting in reversible decoordination of the phosphine donor group in the six-membered ring was observed as the first step of isomerization between fac and mer isomers.     

Platinum(IV) isocyanide complexes

Neutral and cationic platinum(IV) isocyanide complexes of the type [PtCl₄(CNR)₂], [PtCl₄(CNR) (PMe₂Ph)], [PtCl₃(CNR)(PMe₂Ph)₂]⁺, [PtCl₂(CNR)₂ (PMe₂Ph)₂]²⁺, where R = methyl, t-butyl, cyclohexyl, p-tolyl, have been prepared by chlorine addition to the corresponding platinum(II) derivatives. The complexes [PtCl₂(CN)₂(CNR)₂] and [PtCl₂(CN)(CNR) (PMe₂Ph)₂]⁺ (R = t-butyl), are also reported. The cationic t-butylisocyanide derivatives are noteworthy in the way they readily lose the t-butyl cation at room temperature to give the corresponding cyano complexes. The compounds have been characterized by elemental analysis, molecular weights and conductivity measurements, and their i.r. and n.m.r. data are discussed in relation to structures and to the nature of the platinum-isocyanide bond.     

Redox potentials of Ti(IV) and Fe(III) complexes provide insights into titanium biodistribution mechanisms

Transferrin, the human iron transport protein, binds Ti(IV) even more tightly than it binds Fe(III). However, the fate of titanium bound to transferrin is not well understood. Here we present results which address the fate of titanium once bound to transferrin. We have determined the redox potentials for a series of Ti(IV) complexes and have used these data to develop a linear free energy relationship (LFER) correlating Ti(IV) ? Ti(III) redox processes with Fe(III) ? Fe(II) redox processes. This LFER enables us to compare the redox potentials of Fe(III) complexes and Ti(IV) complexes that mimic the active site of transferrin and allows us to predict the redox potential of titanium-transferrin. Using cyclic voltammetry and discontinuous metalloprotein spectroelectrochemistry (dSEC) in conjunction with the LFER, we report that the redox potential of titanium-transferrin is lower than − 600 mV (lower than that of iron-transferrin) and is predicted to be ca. − 900 mV vs. NHE (normal hydrogen electrode). We conclude that Ti(IV)/Ti(III) reduction in titanium-transferrin is not accessible by biological reducing agents. This observation is discussed in the context of current hypotheses concerning the role of reduction in transferrin mediated iron transport.     

The permeability and cytotoxicity of insulin-mimetic vanadium (III,IV,V)-dipicolinate complexes

Vanadium (III,IV,V)-dipicolinate complexes with different redox properties were selected to investigate the structure-property relationship of insulin-mimetic vanadium complexes for membrane permeability and gastrointestinal (GI) stress-related toxicity using the Caco-2 cell monolayer model. The cytotoxicity of the vanadium complexes was assayed with 3-(4,5-dimethylthiazoyl-2-yl) 2,5-diphenyltetrazolium bromide (MTT) assays and the effect on monolayer integrity was measured by the trans-epithelial electric resistance (TEER). The three vanadium complexes exhibited intermediate membrane permeability (P(app) = 1.4-3.6x10(-6) cm/s) with low cellular accumulation level (<1%). The permeability of all compounds was independent of the concentration of vanadium complexes and excess picolinate ligands. Both V(III) and V(V)-dipicolinate complexes induced 3-4-fold greater reactive oxygen and nitrogen species (RONS) production than the V(IV)-dipicolinate complex; while the vanadium (III)-dipicolinate was 3-fold less damaging to tight junction of the Caco-2 cell monolayer. Despite the differences in apparent permeability, cellular accumulation, and capacity to induce reactive oxygen and nitrogen species (RONS) levels, the three vanadium complexes exhibited similar cytotoxicity (IC50 = 1.7-1.9 mM). An ion pair reagent, tetrabutylammonium, increased the membrane apparent permeability by 4-fold for vanadium (III and IV)-dipicolinate complexes and 16-fold for vanadium (V)-dipicolinate as measured by decrease in TEER values. In addition, the ion pair reagent prevented damage to monolayer integrity. The three vanadium (III,IV,V)-dipicolinate complexes may pass through caco-2 monolayer via a passive diffusion mechanism. Our results suggest that formation of ion pairs may influence compound permeation and significantly reduce the required dose, and hence the GI toxicity of vanadium-dipicolinate complexes.     

Alkylimido complexes of titanium(IV)

TiCl₄ reacts with t-butylamine in benzene to give [Ti(NCMe₃)Cl₂(NH₂CMe₃)₂]_x and t-butylamine hydrochloride. The IR spectrum indicates both c/s and trans metal dichlorides (300; and 308, 208 cm⁻¹). In the ¹³C NMR spectrum the t-butylimido quaternary carbon resonance occurs at 72.1 ppm. A dimeric structure incorporating symmetric t-butylimido bridges is proposed. TiCl₄ in benzene react under reflux with two equivalents of Me₃SiNHCMe₃ to give [Ti(NCMe₃)Cl₂(NH₂CMe₃)]_x and with iso-propylamine and ethylamine to give complexes of the form [Ti(NR)Cl₂(NH₂R)₂]_x. Broad bands below 800 cm⁻¹ in the IR spectra suggest polymeric MNM bridges. For [Ti(NCHMe₂)Cl₂(NH₂CHMe₂)]_x the iso-propylimido CH resonance in the ¹³C NMR spectrum occurs at 67 ppm. [Ti(NCMe₃)Cl₂(NH₂CMe₃)₂]₂ reacts with L=bipy or tmed to give [Ti(NCMe₃)Cl₂(L)]₂, and TiCl₄ reacts with two equivalents of Me₃SiNHCMe₃ in benzene and then tmed to give [Ti(NCMe₃)Cl₂(tmed)]₂. The ¹³C NMR spectrum shows the t-butylimido quaternary carbon resonance at 73.5 ppm and the tmed resonances are chemically equivalent. A dimeric μ-NCMe₃ bridging structure is proposed for the complex.     

Nature of cerium(III)- and lanthanum(III)-induced aggregation of human erythrocyte membrane proteins

To clarify the nature of the aggregation of membrane proteins (MP) induced by lanthanide cations (Lns), the interaction of cerium(III) (Ce3+) and lanthanum(III)(La3+) with erythrocyte membrane proteins was studied by means of SDS-PAGE, light scattering measurement, fluorescence, CD and FTIR spectra. The results showed that Ce3+ and La3+ induce protein aggregation not only by Lns non-covalent binding and cross-linking, but also by oxidative cross-linking through disulfide bond formation. As demonstrated by intrinsic fluorescence, CD and FTIR spectra studies, the aggregation was accompanied by the conformation changes with tryptophane residues exposing to more hydrophobic environment and the decreasing alpha-helix and beta-sheet contents. By stopped-flow studies, protein aggregation was shown to be a slow change, which is initiated by rapid Lns binding and then followed by subsequent conformational changes.     

Synthesis and characterisation of a series of 1,2-phenylenedioxoborylcyclopentadienyl-metal complexes [Ti(IV), Zr(IV), Hf(IV), La(III), Ce(III), Yb(III), Sn(II) and Fe(II)]

The preparation of a series of 1,2-phenylenedioxoborylcyclopentadienyl-metal complexes is described. These are of formula [M{η⁵-C₅H₄(BX)}Cl₃] [M = Ti and X = CAT (2a), CAT^t (2b) or CAT^tt (2c); X = CAT^tt and M = Zr (4a) or Hf (4b)], [M{η⁵-C₅H₄(BX)}₂Cl₂] [M = Zr, X = CAT (3a) or CAT^t (3c); or M = Hf, X = CAT (3b) or CAT^t (3d)], [M{(μ-η⁵-C₅H₃BCAT)₂ SiMe₂}Cl₂] [M = Zr (5a) or Hf (5b)], [M{η⁵-C₅H₃(BCAT)₂}Cl₃] [M = Zr (6a) or Hf (6b)], [M{η⁵-C₅H₄BCAT}₃(THF)] [M = La (7a), Ce (7b) or Yb (7c)], [Sn{η⁵-C₅ H₄(BCAT^t)}Cl](8) and [Fe{η⁵-C₅H₄(BCAT^t)}₂] (9). The abbreviations refer to BO₂C₆H₄-1,2 (BCAT) and the 4-Bu^t (BCAT^t) and the (BCAT^tt) analogues. The compounds 2a-9 have been characterised by microanalysis, multinuclear NMR and mass spectra. The single crystal X-ray structure of the lanthanum compound 7a is presented.     

Assignment of oxidation states in metal complexes. Cerium(III) or cerium(IV) and other questions

The use of the bond valence sum to assign correctly the oxidation state of a metal ion in a complex is discussed. Cerium complexes are used as examples since the oxidation state of Ce has been incorrectly assigned in a surprising number of publications. The recommended R₀ values for Ce(III)-O of 2.118 Å, Ce(IV)-O of 2.070 Å, Ce(III)-N of 2.251 Å, and for Ce(IV)-N of 2.202 Å were derived from analyses of homoleptic Ce-O, Ce-N, and heteroleptic Ce-O and -N complexes. These R₀ values can be used to assign correctly the oxidation state of Ce in complexes containing any combination of Ce-O or Ce-N bonds. An incorrect oxidation state assignment usually arises when the oxidation state of Ce or Pr in the product is assumed to be same as that of the starting Ce or Pr compound, but an oxidation or reduction has occurred. Problems with two related Sn complexes may have arisen because of a mix up in the starting materials.     

Mononuclear single helices of lanthanum(III) and europium(III). Metal dependent diastereomeric excess

Using the 1:2 condensate of benzildihydrazone and 2-acetylpyridine as a tetradentate N donor ligand L, LaL(NO₃)₃ (1) and EuL(NO₃)₃ (2), which are pale yellow in colour, are synthesized. While single crystals of 1 could not be obtained, 2 crystallises as a monodichloromethane solvate, 2·CH₂Cl₂ in the space group Cc with a = 11.7099(5) Å, b = 16.4872(5) Å, c = 17.9224(6) Å and β = 104.048(4)°. From the X-ray crystal structure, 2 is found to be a rare example of monohelical complex of Eu(III). Complex 1 is diamagnetic. The magnetic moment of 2 at room temperature is 3.32 BM. Comparing the FT-IR spectra of 1 and 2, it is concluded that 1 also is a mononuclear single helix. ¹H NMR reveals that both 1 and 2 are mixtures of two diastereomers. In the case of the La(III) complex (1), the diastereomeric excess is only 10% but in the Eu(III) complex 2 it is 80%. The occurrence of diastereomerism is explained by the chiralities of the helical motif and the type of pentakis chelates present in 1 and 2.