Gold(I) alkynyl complexes containing a flexible, biphenyl-derived bis(alkyne)

2,2′-Diethynylbiphenyl was prepared in a three step sequence from commercially available 2,2′-bis(bromomethyl)biphenyl and subsequently reacted with the phosphinegold(I) complexes [AuCl(P)] (P = PEt₃, PCy₃, P^tBu₃, PPh₃, PTA) in the presence of base to give the bis(alkynyl) gold(I) complexes [(P)Au(deb)Au(P)] in good yields as air-stable solids. The compounds were fully characterized spectroscopically and the solid state structures of 2,2′-diethynylbiphenyl as well as the PEt₃ complex were determined by X-ray diffraction. Both solution and solid-state luminescence spectra of the gold complexes were recorded.     

Bridged multiclusters derived from the face-capped octahedral [Re6 III(μ3-Se)8]2+ cluster core

The face-capped octahedral cluster cis-[Re₆(μ₃-Se)₈(PEt₃)₄(MeCN)₂](SbF₆)₂, site-differentiated with protecting PEt₃ and substitutionally labile MeCN ligands, reacts with bidentate ligands (L) 4,4′-bipyridyl, (E)-1,2-bis(4-pyridyl)ethene, and 1,2-bis(4-pyridyl)ethane to give the first examples of cluster-based molecular squares of the general formula cyclo-[Re₆(μ₃-Se)₈(PEt₃)₄L]₄(SbF₆)₈. The complexes were characterized by microanalysis, ¹H and ³¹P NMR, and time-of-flight electrospray ionization mass spectrometry. Cyclic voltammetry reveals in each case one quasi-reversible oxidation and, for two compounds, one reversible and one irreversible reduction process.     

Structure and solution behaviour of cyclooctadiene complexes of platinum(II)

The substitution behaviour of [PtCl(R)(COD)] (R⁻ = Me and Fc) complexes, by the stepwise addition of phosphine ligands, L (L = PPh₃, PEt₃ and P(NMe₂)₃), were investigated in situ by ¹H and ³¹P NMR spectroscopy. Addition of less than two equivalents of the phosphine ligand results in the formation of dimeric molecules with the general formula trans-[Pt(R)(μ-Cl)(L)]₂ for the sterically demanding systems where R⁻ = Me/L = P(NMe₂)₃ and R⁻ = Fc/L = PEt₃, PPh₃ and P(NMe₂)₃ while larger quantities resulted in cis- and trans mixtures of mononuclear complexes being formed. In the case of the relatively small steric demanding, strongly coordinating, PEt₃ ligand the trans-[PtCl(R)(PEt₃)₂] mononuclear complexes were exclusively observed in both cases. The crystal structures of the two substrates, [PtCl(R)(COD)] (R⁻ = Me or Fc), as well as the cis-[PtCl(Fc)(PPh₃)₂] substitution product are reported.     

Interaction of [RuCl2(PR3)3] (R = Ph, p-tolyl) with some Rh(III), Ir(III) and Pt(IV) tertiary phosphine complexes

Reactions of RuCl₂(PR₃)₃ [PR₃ = PPh₃ or P(p-tolyl)₃ with several monomeric phosphine complexes of rhodium(III), iridium(III) and platinum(IV) have been studied. The reactions with mer-MCl₃(P′R₃)₃ (M = Rh, P′R₃ = PEt₂Ph, PMe₂Ph, PMe₂Ph; M = Ir, P′R₃ = PBuPh₂, PMePh₂, PEt₂Ph) involves a phosphine ligand transfer between metal atoms to afford novel dark coloured heterobimetallic complexes containing a triple chloro-bridge. The reactions of RuCl₂(PR₃)₃ with PtCl₄(P′R₃)₂ (P′R₃ = PEt₂Ph, PBu₂Ph), however, do not give evidence for the formation of dinuclear complexes containing the (RuCl₃Pt) unit, but a reduction of Pt^IV to Pt^II occurs with transfer of phosphine ligands between the two metals. The formulation of these complexes has been established by ³¹P NMR spectroscopy.     

31P and 195Pt NMR studies on the clusters [Pt4(μ2-CO)5L4]. L = PEt3, PMe2Ph,PMePh2, PEt2But. The molecular structure of a monoclinic modification of [Pt4(μ2-CO)5(PMe2Ph)4].

Several clusters complexes of composition [Pt₄(μ₂-CO)₅L₄] have been synthesized and characterized, using ³¹P and ¹⁹⁵Pt NMR. L = PEt₃, PMe₂Ph, PMePh₂, PEt₂Bu^t. The molecular structure of a new monoclinic modification of the PMe₂Ph derivative has been determined: space group P2₁/n with a = 19.698(4), b = 10.9440(20), and c = 21.360(6) Å, β = 112.432(18)°, Z = 4. Using 4751 reflections measured at 290 ± 1 K on a four-circle diffractometer the structure has been refined to R = 0.0846. The molecule has no imposed symmetry, but the central Pt₄(CO)₅P₄ core has the approximate C₂v architecture established for the previously known orthorhombic modification. The Pt₄ unit is thus a highly distorted, edge-opened (3.3347 Å) tetrahedron, with five edge-bridging carbonyl and four terminal phosphine ligands. In contrast to the crystallographic results ³¹P and ¹⁹⁵Pt NMR spectra reveal equivalent ³¹P and ¹⁹⁵Pt spins, which can be interpreted in terms of a tetrahedral arrangement of platinum atoms. It is suggested that this equivalence arises from time-averaging of all possible isomeric edge-opened tetrahedra.     

The structure of the antitumor complex cis-(diammino) (1,1-cyclobutanedicarboxylato)-Pt(II): X ray and nmr studies

X-ray crystallography shows that Pt(NH₃)₂(CBDCA) is a square-planar complex with the dicarboxylate chelate ring in the boat conformation and a planar cyclobutane ring. ¹H and ¹³C nmr studies suggest that rapid chelate ring flipping occurs in solution. The value of ¹⁹⁵Pt nmr combined with ¹⁵N labeling as an informative new method of studying carboxylate coordination is illustrated. nmr results are also reported for the analogous ethylmalonate complex.     

Slow conformational exchange in DNA minihairpin loops: A conformationalstudy of the circular dumbbell d〈pCGC-TT-GCG-TT〉

In recent years various examples of highly stable two-residue hairpin loops (miniloops) in DNA have been encountered. As the detailed structure and stability of miniloops appear to be determined not only by the nature and sequence of the two bases in the loop, but also by the closing base pair, it is desirable to carry out in-depth studies of especially designed small model DNA compounds. Therefore, a circular DNA dumbbell-like molecule is tailored to consist of a stem of three Watson–Crick base pairs, flanked on each side by a minihairpin loop. The resulting circular DNA decanter 5′-d〈pCGC- TT-GCG- TT〉 -3′ ( I ) is studied in solution by means of nmr spectroscope. At a temperature of 269 K the molecule occurs in a 50/50 mixture of two dumbbell structures (denoted L2L2 and L2L4). L2L2 contains three Watson–Crick C-G base pairs and two two-residue loops (H2-family type) in opposite parts of the molecule. On raising the temperature from 269 to 314 K. The L2L4 conformer becomes increasingly dominant (95% at 314 K). This conformer has a partially disrupted closing G-C base pair in the 5′-GTTC-3′ loop with only one remaining solvent-accessible hydrogen bond between NH_α of the cytosine C(1) and O6 of the guanine G(8), whereas the opposite 5′-CTTG-3′ loop remains stable. The disruption of the C(1)-G(8) base pair in the L2L4 form is correlated with the presence of a syn orientation for the C(1) base at the 5′-3′ loop-stem junction in the 5′-GTTC-3′ loop. The two conformers. L2L2 and L2L4, occur in slow equilibrium (2–20 s^?1). Moderate line broadening of specific ¹H, ¹³C, and ³¹P resonances of residues C(1), G(8), T(9), and T(10) at low temperatures, due to chemical exchange between L2L2 and L2L4, show that the interconversion from an anti to syn conformer in residue C(1) has a small local effect on the structure of the dumbbell. T₁ relaxation measurements, chemical-shift considerations, and complete hand-shape calculations of the exchange process of the G(8) imino proton reveal a possibility for the existence of multiconformational slates in the anti–syn equilibrium. © 1995 John Wiley & Sons, Inc.     

Purification and properties of a lectin from the seeds of Croton tiglium with hemolytic activity toward rabbit red cells

The pH dependence of the chemical shift of the inorganic phosphate (P_i) inside mitochondria observable by ³¹P nmr has been examined and used for the measurement of the internal pH. The pH gradient and the P_i concentration gradient were in the simple relation expected for the neutral exchange process of H₂PO₄^? and OH^?. This P_i distribution across the mitochondrial membrane was not influenced by the cross-membrane electrical potential. Both the P_i, distribution and the pH titration curve of the internal P_i indicate that the activity of the internal P_i can be well represented by the concentration of P_i measured by ³¹P nmr peak intensity. The present results give a sound base for applying ³¹P nmr to study bioenergetics and cell metabolism.     

35-Cl nuclear magnetic resonance studies of anion-binding sites in proteins: lactate dehydrogenase.

³⁵Cl nmr relaxation rate measurements have been used to study anion-binding sites in pig heart lactate dehydrogenase. These studies reveal two types of sites, one is intimately associated with the active site, the other is not. The nonactive site has been ascribed to a subunit site in analogy with crystallographic results from the dogfish M₄ enzyme. The binding of either the reduced or the oxidized form of NAD results in an increase in the ³⁵Cl nmr relaxation rate by a factor of 1.8–2. The enhanced nmr relaxation rate of the binary lactate dehydrogenase-NAD complex is reduced on binding of the substrate inhibitor molecules oxamate or oxalate to a value less than that exhibited by lactate dehydrogenase alone. The enhancement of the nmr relaxation rate is attributed to a decrease in the dissociation constant of Cl for the enzyme. The K_p values for Cl binding to the active center site of lactate dehydrogenase is 0.85 m and for lactate dehydrogenase-NADH is 0.25 m. The ratio of these constants, 3.4, agrees well with the measured enhancement value 3.7. The effect of coenzyme analogs on the ³⁵Cl nmr relaxation rate has been examined. 3-Acetylpyridine NAD produces an enhancement of 4.3, thionicotinamide NAD of 2.3, whereas 3-pyridinealdehyde, adenosinediphosphoribose, and adenosine diphosphate do not affect the nmr relaxation state of Cl bound to lactate dehydrogenase.     

Reactions of alkyl and aryl sulfides with a monocarbon platinacarbaborane anion

The reaction of the monocarbon carbaborane complex Na[Pt(PEt₃)₂(η⁵-CB₁₀H₁₁)] with some diaryl- and dialkyl disulfides has been investigated. With Ph₂S₂, two new cage substituted products are formed, [Pt(SPh)(PEt₃)(η⁵-9-SPh-7-CB₁₀H₁₀)] (1) and [Pt(SPh)(PEt₃)(η⁵-8-SPh-11-SPh-7-CB₁₀H₉)] (2), whereas with S₂ the main product is the metal substituted complex, [Pt(SBu^t)(PEt₃)(η⁵-7-CB₁₀H₁₁)] (4). All three new molecules have been identified spectroscopically (¹H, ¹³C, ³¹P, ¹¹B NMR) and through single crystal X-ray diffraction.     

Structures of sulfur-rich dithiolate-gold(I) complexes and their oxidation

[NMe₄][Au(PEt₃)(C₃S₅)], [NMe₄][Au(PPh₃)(C₃S₅)], [NMe₄][Au(PEt₃)(C₈H₄S₈)], [N-methylpyridinium][Au(PPh₃)(C₈H₄S₈)], [(PEt₃)Au-C₃S₅-Au(PEt₃)], and [(PEt₃)Au-C₈H₄S₈-Au(PEt₃)] [C₃S₅²⁻=4,5-disulfanyl-1,3-dithiole-2-thionate(2−); C₈H₄S₈²⁻=2-{(4,5-ethylenedithio)-1,3-dithiole-2-ylidene}-1,3-dithiole-4,5-dithionate(2−)] were prepared. They exhibited first oxidation potentials due to the dithiolate ligand-centered oxidation at −0.30 to +0.21 V (vs. Ag/Ag⁺) in dichloromethane. They were reacted with iodine or 7,7,8,8-tetracyano-p-quinodimethane (TCNQ) to afford one-electron-oxidized species [Au(PEt₃)(C₈H₄S₈)] and [(L)Au-C₈H₄S₈-Au(L)](TCNQ)_1.0-1.1, (L=PEt₃ and PPh₃) and further-electron-oxidized species [Au(PEt₃)(S-S)]I_3.3-5.7, [Au(PPh₃)(S-S)]I_12-13, [(PEt₃)Au-(S-S)-Au(PEt₃)]I_3.3-5.5 (S-S=C₃S₅²⁻ and C₈H₄S₈²⁻) and [(PPh₃)Au-C₈H₄S₈-Au(PPh₃)]I₁₂. ESR spectra of the oxidized species suggest the C₃S₅ and C₈H₄S₈ ligand-centered oxidation. The oxidized C₈H₄S₈-complexes showed electrical conductivities of 10⁻⁴-10⁻² S cm⁻¹ measured for compacted pellets at room temperature. X-ray crystal structures of [NMe₄][Au(PPh₃)(C₃S₅)]CH₂Cl₂, [(PEt₃)Au-C₃S₅-Au(PEt₃)] and [(PEt₃)Au-C₈H₄S₈-Au(PEt₃)] were revealed.     

Synthesis and characterization of new cationic hydride complexes of rhodium(III)

New cationic hydride complexes of rhodium(III) with PR₃ and R-DAB ligands have been prepared and characterised. The tertiary phosphines employed were PPh₃, PMePh₂, PEt₃ and the R-DAB ligands, (RN:CR′CR′:NR), c-Hex-DAB, Ph-DAB, NH2-DAB-(CH₃,CH₃). Hexacoordinate-dihydride complexes, characterized by ¹H and ³¹P NMR, with stoichiometry [RhH₂(R-DAB)(PR₃)₂]X were obtained. Compounds with other stoichiometries (R-DAB/PR₃=1 or 2) are also possible. Preliminary studies of the catalytic activity in hydrogenation of olefins have been carried out.     

Interaction of polyamine macrocycles with Zn(II) and ATP in aqueous solution. Binary and ternary systems. A potentiometric,NMR and fluorescence emission study

ATP binding to ligands L1 and L3 and to their Zn(II) complexes has been examined by means of potentiometric and ¹H and ³¹P NMR measurements in aqueous solution. Their coordination features have been compared to those of ligand L2 and its Zn(II) complex. In all the three cases, the Zn(II) complexes proved to be better receptors than free ligands, due to the synergetic action of metal ion and ammonium functions in ATP binding. Among the three complexes, Zn(II) complex with L1 shows the highest equilibrium constant, which can be ascribed to the fact that, being coordinated by the dipyridine nitrogens outside the macrocyclic cavity, it is less saturated by ligand donors. The ³¹P NMR investigation showed that the nucleotide interacts via the P_γ and P_β phosphate groups with both free ligands and complexes, while the ¹H spectra revealed that the binding is reinforced by the presence of π–π interactions. Photophysical studies showed that the fluorescence emission intensity of the Zn(II) complexes is enhanced upon interaction with ATP.     

Structural Basis for the Binding Affinity of a Homologous Series of Synthetic Phenoxazone Drugs with DNA: NMR and Molecular Mechanics Analysis

Abstract

The molecular basis of the marked structure-activity relationship for a homologous series of DNA-binding phenoxazone drugs (ActII-ActIV) has been investigated by NMR spectroscopy and molecular mechanics. The spatial structures of the complexes between the drugs and a model deoxytetranucleotide, 5′-d(TpGpCpA), have been determined by molecular mechanics methods using homonuclear ¹H-¹H 2D-NOESY and heteronuclear ¹H-³¹P (HMBC) NMR spectroscopic data. Observed intermolecular NOE contacts and equilibrium binding studies confirm that the binding affinity of the synthetic phenoxazone derivatives with d(TGCA) decreases with an increase in the number of CH₂ groups in the dimethylami- noalkyl side chains, i.e., ActII > ActIII > ActIV, in agreement with the observed biological activity of these compounds. Molecular mechanics calculations of the spatial structures of the intercalated complexes of ActII-ActIV with d(TGCA) indicate that the different binding constants of the phenoxazone derivatives with the DNA oligomer are due to the different degrees of intercalation of the chromophore and the different steric arrangements of aminoalkyl side chains in the minor groove of the tetramer duplex; this results in different distances between the negatively-charged phosphates of the DNA duplex and the terminal positively-charged N(CH₃)₂ groups of the side chains.     

The X-Pro peptide bond as an nmr probe for conformational studies of flexible linear peptides

The equilibrium between the cis and trans forms of X-Pro peptide bonds can readily be measured in the ¹³C nmr spectra. In the present paper we investigate how observation of this equilibrium could be used as an nmr probe for conformational studies of flexible polypeptide chains. The experiments include studies by ¹³C nmr of a series of linear oligopeptides containing different X-L -Pro peptide bonds, with X = Gly, L -Ala, L -Leu, L -Phe, D -Ala, D -Leu, and D -Phe. Overall the study confirms that X-Pro peptide bonds can generally be useful as ¹³C nmr probes reporting the formation of nonrandom conformation in flexible polypeptide chains. It was found that the cis–trans equilibrium of X-Pro is greatly affected by the side chain of X and the configuration of the α-carbon atom of X. On the basis of these observations some general rules are suggested for a practical applications of the X-Pro nmr probes in conformational studies of polypeptide chains.     

13C nmr studies of aurothioglucose: Ligand exchange and redox disproportionation reactions

¹³C nmr studies of gold thioglucose, AuSTg, and solutions containing added β-1-D-thioglucose, TgSH, have been conducted at PD 7.4 and interpreted in terms of complexation and ligand exchange reactions that are consistent with the known preference of gold(I) for linear two-coordinate structures. The upper limit of the half-life for ligand exchange between 0.25 M Au(STg)₂^? and TgSH at pD 7.4 is 2.2 msec. The ¹³C nmr spectra of various thioglucose derivatives have been assigned. A novel oxidation reduction reaction was discovered that leads to the formation of metallic gold and a product tentatively identified as the sulfinic acid derivative of thioglucose. The presence of sulfinic acid in AuSTg was indicated by the infrared absorption at 1050 cm^?1. The same product was formed by slow hydrolysis of thioglucose disulfide. A mechanism for the formation of the sulfinic acid derivative from AuSTg is proposed.     

Ruthenium(II) tetraammines,a useful model to compare trans-effect and trans-influence of phosphanes

The substitution reaction

trans-[Ru(NH₃)₄P(III)pz]²⁺ + H₂O where P(III) = PEt₃, PBu₃, PPh₃, P(OBu)₃ and P(OPh)₃ has been studied at 25.0°C, μ = 0.10 NaCF₃COO, C_H⁺ = 1.0×10⁻³ M. Assuming the second order specific rate k₁ for the substitution of the water molecule on the coordination sphere for pz as indicative of a relative order of the trans-effect of P(III), the following increasing trans-effect order can be written: P(OPh)₃<PPh₃<P(OEt)₃< P(OBu)₃<PBu₃<PEt₃. The weakening of the Ru(II)pz bond expressed as 1/K_eq permits us to write the following order of increasing trans-influence: PEt₃<PBu₃<P(OBu)₃<P(OEt)₃∼ PPh₃<P(OPh)₃. The complex trans-[Ru(NH₃)₄- (PEt₃)(P(OEt)₃)](PF₆)₂ has been isolated and characterized by microanalysis, electronic and voltammetric spectra. The aquation of this complex provides additional support to the generalizations about the influence of π bonding on the trans-influence of phosphanes.     

The binding of metal ions to ATP: A proton and phosphorus nmr investigation of diamagnetic metal-ATP complexes

Phosphorus and proton nmr spectra were recorded for complexes of ATP with Mg(II), Ca(II), Sr(II), Zn(II), Cd(II), Sn(II), Pb(II), Hg(II), Ag(I), and Tl(I) ions. Each of these ions except Hg(II) affected the ³¹P nmr of ATP, usually by shifting all three resonances downfield and decreasing the ³¹P-³¹P coupling constants. Pb(II) exerted the greatest shifts, while Mg(II) caused the greatest change in coupling constants. Effects on the adenine proton resonances were generally small and attributable to base stacking, but a direct metal-adenine binding is likely for Zn(II), Cd(II), and Ag(I). Effects on the ribose proton resonance were small in all of the ATP complexes, but were much larger in Zn(II)ADP and Cd(II)ADP. Formation of metal-bis(nucleotide) complexes occurred with Sn(II), Zn(II), and Cd(II).     

Organogold(III) compounds as experimental anticancer agents: chemical and biological profiles

In the last few years gold(III) complexes have attracted growing attention in the medicinal chemistry community as candidate anticancer agents. In particular some organogold(III) compounds manifested quite attractive pharmacological behaviors in preclinical studies. Here we compare the chemical and biological properties of the novel organogold(III) complex [Au(bipy^dmb?H)(NH(CO)CH₃)][PF₆] (Aubipy^aa) with those of its parent compounds [Au(bipy^dmb?H)(OH)][PF₆] (Aubipy^c) and [Au₂(bipy^dmb?H)₂)(μ?O)][PF₆]₂ (Au2bipy^c), previously synthesized and characterized. The three study compounds were comparatively assessed for their antiproliferative actions against HCT-116 cancer cells, revealing moderate cytotoxic effects. Proapoptotic and cell cycle effects were also monitored. Afterward, to gain additional mechanistic insight, the three gold compounds were challenged against the model proteins HEWL, RNase A and cytochrome c and reactions investigated through UV–Vis and ESI–MS analysis. A peculiar and roughly invariant protein metalation profile emerges in the three cases consisting of protein binding of {Au(bipy^dmb?H)} moieties. The implications of these results are discussed in the frame of current knowledge on anticancer gold compounds.