Ruthenium(II) Complexes of a Xanthene-Spanned Dicarbene Ligand.

Octahedral ruthenium(II) complexes of a xanthene-di(N-heterocyclic carbene) ancillary ligand (XdC) have been prepared and structurally characterized. Examples catalyze the transfer hydrogenation of ketones {[Ru(CO)I2(C,O,C'-XdC)] (1) and [Ru(CO)(MeCN)2(C,O,C'-XdC)]2+ (22+)} and the selective electrochemical reduction of CO2 to CO {[Ru(N,N'-bpy)(CO)(C,O,C'-XdC)]2+ (32+) at 0.40 V overpotential in MeCN-H2O (1 M)}. The reaction of 1 with KBEt3H afforded isomers of [(C,C'-XdC)Ru(µ-H)(H)]2 dimers, which are stable to reductive elimination of the XdC ligand, thereby suggesting similar (XdC)Rh(coligand)(H)x species may be viable intermediates in catalyses. The electrochemical reduction of CO2 involves a double reduction of 32+ to 3••, which has been characterized by IR-SEC and DFT calculations. The DFT calculations suggest the Ru-Oxanth bond breaks in 3••, opening a metal site for CO2 binding with selectivity over protons enabled by the diffuse nature of the HOMO delocalized over the metal and the bipyridine and carbonyl coligands. The results point to the promise of metal complexes of flexible and hemilabile xanthene-(NHC)2 ancillary ligands in catalysis.

[Fp(CH4)]+, [η5-CpRu(CO)2(CH4)]+, and [η5-CpOs(CO)2(CH4)]+: A Complete Set of Group 8 Metal-Methane Complexes.

Here, we report the NMR spectroscopic analysis of the group 8 transition metal methane σ-complexes [η5-CpM(CO)2(CH4)][Al(OC(CF3)3)4] (M = Fe, Ru) at -90 °C in the weakly coordinating solvent 1,1,1,3,3,3-hexafluoropropane. The iron(II)-methane complex has a 1H resonance at δ -4.27, a 13C resonance at δ -53.0, and 1JC-H = 126 Hz for the bound methane fragment. The ruthenium(II)-methane complex has a 1H resonance at δ -2.10, a 13C resonance at δ -48.8, and a 1JC-H = 126 Hz for the bound methane fragment. DFT and ab initio calculations support these experimental observations and provide further detail on the structures of the [η5-CpM(CO)2(CH4)]+ (M = Fe, Ru) complexes of the Group 8 metals. Both the iron centered methane complex, [η5-CpFe(CO)2(CH4)][Al(OC(CF3)3)4], and the ruthenium centered methane complex, [η5-CpRu(CO)2(CH4)][Al(OC(CF3)3)4], are significantly less stable than the previously reported osmium-methane complex [η5-CpOs(CO)2(CH4)][Al(OC(CF3)3)4].

Binding methane to a metal centre.

The σ-alkane complexes of transition metals, which contain an essentially intact alkane molecule weakly bound to the metal, have been well established as crucial intermediates in the activation of the strong C-H σ-bonds found in alkanes. Methane, the simplest alkane, binds even more weakly than larger alkanes. Here we report an example of a long-lived methane complex formed by directly binding methane as an incoming ligand to a reactive organometallic complex. Photo-ejection of carbon monoxide from a cationic osmium-carbonyl complex dissolved in an inert hydrofluorocarbon solvent saturated with methane at -90 °C affords an osmium(II) complex, [η5-CpOs(CO)2(CH4)]+, containing methane bound to the metal centre. Nuclear magnetic resonance (NMR) spectroscopy confirms the identity of the σ-methane complex and shows that the four protons of the metal-bound methane are in rapid exchange with each other. The methane ligand has a characteristically shielded 1H NMR resonance (δ -2.16), and the highly shielded carbon resonance (δ -56.3) shows coupling to the four attached protons (1JC-H = 127 Hz). The methane complex has an effective half-life of about 13 hours at -90 °C.

Molecular dynamic simulations of diacridine binding to DNA: Indications that C6 diacridine can bisintercalate spanning two base pairs.

Dimers of 9-aminoacridine linked via the 9-amino group with polymethylene chains, termed diacridines, are known to bisintercalate into DNA when the linker comprises 6 or more methylene units. There are no literature reports of crystal or NMR solution structures for bisintercalated diacridine-DNA complexes, and the issue of the structure of the C6 ([CH2 ]n linker where n = 6) diacridine complex remains unresolved. Previously, based on simple geometric considerations, it was proposed that C6 diacridine could only span a single base pair, which requires that its bifunctional reaction violates the widely-observed "neighbor exclusion principle" where bound intercalators are separated by at least 2 base pairs. Here we have explored the structure of diacridine-DNA complexes using unrestrained molecular dynamics in explicit solvent using the parmbsc0 forcefield in AMBER14. We studied the C4 to C8 dimers, intercalated via both the minor and major DNA grooves, to a variety of nucleotide sequences. We find that C6, C7, and C8 diacridine are able to form 2 base pair bisintercalated complexes from either groove, whereas the C4 and C5 homologues cannot. We conclude that C6 diacridine does have the capacity to bisintercalate without violating neighbor exclusion, and that the previous proposed binding model needs revision.

Observation and Analysis of Large Dynamic Frequency Shifts in the 1H NMR Signals of H-D in Deuterium-Substituted Dihydrogen Complexes.

A dynamic frequency shift (DFS) in the 1H NMR resonance of the HD unit of the deuterium-labeled dihydrogen complex [Ru(D)(η2-HD)(P3P3iPr)][BPh4] [P3P3iPr = P(CH2CH2CH2PiPr2)3] has been observed and analyzed. To the best of our knowledge, this is the first demonstration of the DFS for a H-D pair. The observed DFS of the center line relative to the outside lines in the H-D triplet is large, up to ∼11 Hz, because of the short H-D distance encountered in dihydrogen complexes. Analysis of the DFS as a function of the temperature, combined with density-functional-theory-calculated or least-squares-fitted electric-field-gradient (EFG) parameters, suggests an H-D bond length of 0.92-0.94 Å. A DFS was also observed in trans-[Fe(η2-HD)(H)(dppe)2]+, suggesting the DFS will be commonplace in dihydrogen complexes if appropriate conditions are employed for its observation. Possible applications of the DFS as a probe of the bond lengths, EFGs, and molecular motion, particularly in inorganic systems, are discussed.

Structures and dynamics of DNA complexes of the desmethyl analog of the cytotoxin MLN944: Insights into activity when a methyl isn't futile.

Structure activity relationships for tricyclic-carboxamide topoisomerase II poisons indicate that cytotoxicity is enhanced by the presence of methyl, and other, groups in the position peri to the carboxamide. Linked dimers of phenazine-1-carboxamides are potent cytotoxins and one phenazine dimer, MLN944 (alternatively XR5944), has been in clinical trial. MLN944 is a template inhibitor of transcription, whereas corresponding monomers are not. Nevertheless, its cytotoxic potency is also diminished by removal of its peri methyl groups. Here, we describe NMR and molecular dynamic studies of the interaction of desmethyl MLN944 with d(ATGCAT)2 , d(TATGCATA)2 , and d(TACGCGTA)2 to investigate the influence of the nine-methyl group on the structure of MLN944 complexes. As with MLN944, the carboxamide group hydrogen bonds to the phenazine ring nitrogen, the ligand sandwiches the central GC base pairs in the major groove, and the protonated linker amines hydrogen bond primarily to the O6 atom of the guanines. Molecular dynamics studies reveal that the linker exists in multiple conformations, none of which produce an ideal set of hydrogen bonds. In distinction, however, the carboxamide-to-phenazine ring nitrogen hydrogen bond is weaker, the overall helix winding is less and the NMR resonances are broader in the desmethyl complexes. Exchange between free and complexed DNA, quantified using two-dimensional NOESY spectra, is faster for the desmethyl MLN944 complexes than for MLN944 complexes. Overall, the data suggest that desmethyl MLN944 DNA complexes are "looser" and more unwound at the binding site, leading to faster dissociation rates, which could account for the diminished efficacy of the desmethyl analog.

The Mosaic of Rottlerin: The Sequel.

Rottlerin (1) is a potent protein kinase C δ inhibitor that possesses a wide range of biological activities. However, the potential of this molecule to be developed as a drug has been restricted by its limited availability. We report herein a gram scale quantity synthesis of rottlerin in a five-step synthetic route that can be completed within 2 days. The methodology was extended by the reaction of the key aminochromene intermediate (15) with various electron-rich arenes, forming novel unsymmetrical methylene-bridged compounds. The X-ray crystal structure revealed the boomerang shape of this kind of molecule for the first time. The direct transformation of rottlerin (1) into the natural product, isorottlerin (35), was observed for the first time, and we named this transformation the "isorottlerin change". In addition, the antibacterial activities of rottlerin (1) and new rottlerin analogues 32-34 were examined against Staphylococcus aureus. The compounds showed MIC values as low as 2.0 µM, which were comparable to the clinically used antibiotic gentamicin.

Antarctic Moss Biflavonoids Show High Antioxidant and Ultraviolet-Screening Activity.

Ceratodon purpureus is a cosmopolitan moss that survives some of the harshest places on Earth: from frozen Antarctica to hot South Australian deserts. In a study on the survival mechanisms of the species, nine compounds were isolated from Australian and Antarctic C. purpureus. This included five biflavonoids, with complete structural elucidation of 1 and 2 reported here for the first time, as well as an additional four known phenolic compounds. Dispersion-corrected DFT calculations suggested a rotational barrier, leading to atropisomerism, resulting in the presence of diastereomers for compound 2. All isolates absorbed strongly in the ultraviolet (UV) spectrum, e.g., biflavone 1 (UV-A, 315-400 nm), which displayed the strongest radical-scavenging activity, 13% more efficient than the standard rutin; p-coumaric acid and trans-ferulic acid showed the highest UV-B (280-315 nm) absorption. The more complex and abundant 1 and 2 presumably have dual roles as both UV-screening and antioxidant compounds. They are strongly bound to Antarctic moss cell walls as well as located inside the cells of moss from both locations. The combined high stability and photoprotective abilities of these isolates may account for the known resilience of this species to UV-B radiation and its survival in some of the toughest locations in the world.

Bridgehead isomer effects in bis(phosphido)-bridged diiron hexacarbonyl proton reduction electrocatalysts.

The influence of the substitution, orientation and structure of the phosphido bridges in [Fe2(CO)6(µ-PR2)2] electrocatalysts of proton reduction has been studied. The isomers e,a-[Fe2(CO)6{µ-P(Ar)H}2] (1a(Ar): Ar = Ph, 2'-methoxy-1,1'-binaphthyl (bn')), e,e-[Fe2(CO)6{µ-P(Ar)H}2] (1b(Ar): Ar = Ph, bn') were isolated from reactions of iron pentacarbonyl and the corresponding primary phosphine, syntheses that also afforded the phosphinidene-capped tri-iron clusters, [Fe3(CO)9(µ-CO)(µ3-Pbn')] (2) and [Fe3(CO)9(µ3-PAr)2] (3(Ar), Ar = Ph, bn'). A ferrocenyl (Fc)-substituted dimer [Fe2(CO)6{µ:µ'-1,2-(P(CH2Fc)CH2)2C6H4}] (4), in which the two phosphido bridges are linked by an o-xylyl group, was also prepared. The molecular structures of complexes 1a(Ph), 1b(Ph), 1b(bn'), 2 and 4 were established by X-ray crystallography. All complexes have been examined as electrocatalysts for proton reduction using p-toluene sulfonic acid in tetrahydrofuran. Cyclic voltammograms of the dimers with acid exhibit two catalysis waves for proton reduction. The first wave, which appears at the potential of the primary reduction, reaches maximum current (turnover) at moderate acid concentrations and is rapidly overtaken by the second wave, which appears at more negative potential. Both of these reductive waves show an initial first order dependence on acid. The electrochemistry and electrocatalyses of the [Fe2(CO)6(µ-PR2)2] dimers show subtle variations with the nature of the bridging phosphido group(s), including the orientation of bridgehead hydrogen atoms.

Photochromic switching behaviour of donor-acceptor Stenhouse adducts in organic solvents.

We report photochromic donor-acceptor Stenhouse adducts (DASAs) capable of fully reversible photoisomerization with visible light in organic solvents including chloroform, acetonitrile and benzene. The rates of photoisomerization and thermal reversion can be tuned by altering the electronics of the donor adduct. X-Ray crystallography and photo-NMR experiments unambiguously establish molecular structures.

Diastereoselective Synthesis and Conformational Analysis of (2R)- and (2S)-Fluorostatines: An Approach Based on Organocatalytic Fluorination of a Chiral Aldehyde.

Stereoselectively fluorinated analogues of the amino acid statine have been efficiently synthesized. The key step is an organocatalytic electrophilic fluorination of a chiral ß-oxygenated aldehyde, which provided a test of both diastereoselectivity and chemoselectivity. The target statine analogues were found to adopt unique conformations influenced by the fluorine gauche effect, rendering them potentially valuable building blocks for incorporation into bioactive peptides.

Observation of Cationic Transition Metal-Alkane Complexes with Moderate Stability in Hydrofluorocarbon Solution.

In seeking to create more-stable transition metal-alkane complexes, we generated cationic alkane complexes of the type [(HEB)Re(CO)2(alkane)][Al(OR(f))4] (HEB = η(6)-hexaethylbenzene; alkane = cyclopentane (16) or pentane (17-19); OR(f) = perfluoro-tert-butoxy) via photolysis of the precursor complex [(HEB)Re(CO)3][Al(OR(f))4] (15) in the presence of the added alkane. The alkane complexes were generated in a hydrofluorocarbon (HFC) solvent, most often CF3CH2CF3, which is capable of simultaneously dissolving the ionic complex 15 and a small amount of alkane at low temperature (183 K). Use of the HFC solvent in tandem with the highly fluorinated, solubilizing, weakly coordinating [Al(OR(f))4](-) anion overcomes the technical difficulty of combining ionic species with alkanes in solution without the solvent molecules rapidly displacing the bound alkane ligand, as the alkanes bind in preference to the HFCs to the organometallic fragments employed in this study. The [(HEB)Re(CO)2(alkane)](+) complexes are more long-lived than the corresponding neutral alkane complexes [(HEB)W(CO)2(alkane)] and [CpRe(CO)2(alkane)] (Cp = η(5)-cyclopentadienyl), with samples of [CpRe(CO)2(cyclopentane)] decaying significantly more rapidly than [(HEB)Re(CO)2(alkane)](+) when present in the same solution. Intramolecular exchange of the methylene group bound to the metal within the cyclopentane ligand in 16 was observed at 212 K, with the 1,2 shifts appearing to be faster than 1,3 shifts.

The Mosaic of Rottlerin.

The first total synthesis of rottlerin is described. The methodology allows the development of potential novel protein kinase C δ (PKCδ) analogues for better treatment of various diseases. Kamalachalcone A and dimeric rottlerin were synthesized in a very practical and economical way using FeCl3 as a catalyst.

Improving Child Oral Health: Cost Analysis of a National Nursery Toothbrushing Programme.

UNLABELLED: Dental caries is one of the most common diseases of childhood. The aim of this study was to compare the cost of providing the Scotland-wide nursery toothbrushing programme with associated National Health Service (NHS) cost savings from improvements in the dental health of five-year-old children: through avoided dental extractions, fillings and potential treatments for decay. METHODS: Estimated costs of the nursery toothbrushing programme in 2011/12 were requested from all Scottish Health Boards. Unit costs of a filled, extracted and decayed primary tooth were calculated using verifiable sources of information. Total costs associated with dental treatments were estimated for the period from 1999/00 to 2009/10. These costs were based on the unit costs above and using the data of the National Dental Inspection Programme and then extrapolated to the population level. Expected cost savings were calculated for each of the subsequent years in comparison with the 2001/02 dental treatment costs. Population standardised analysis of hypothetical cohorts of 1000 children per deprivation category was performed. RESULTS: The estimated cost of the nursery toothbrushing programme in Scotland was £1,762,621 per year. The estimated cost of dental treatments in the baseline year 2001/02 was £8,766,297, while in 2009/10 it was £4,035,200. In 2002/03 the costs of dental treatments increased by £213,380 (2.4%). In the following years the costs decreased dramatically with the estimated annual savings ranging from £1,217,255 in 2003/04 (13.9% of costs in 2001/02) to £4,731,097 in 2009/10 (54.0%). Population standardised analysis by deprivation groups showed that the largest decrease in modelled costs was for the most deprived cohort of children. CONCLUSIONS: The NHS costs associated with the dental treatments for five-year-old children decreased over time. In the eighth year of the toothbrushing programme the expected savings were more than two and a half times the costs of the programme implementation.

Bio-inspired transition metal-organic hydride conjugates for catalysis of transfer hydrogenation: experiment and theory.

Taking inspiration from yeast alcohol dehydrogenase (yADH), a benzimidazolium (BI(+) ) organic hydride-acceptor domain has been coupled with a 1,10-phenanthroline (phen) metal-binding domain to afford a novel multifunctional ligand (L(BI+) ) with hydride-carrier capacity (L(BI+) +H(-) ⇌L(BI) H). Complexes of the type [Cp*M(L(BI) )Cl][PF6 ]2 (M=Rh, Ir) have been made and fully characterised by cyclic voltammetry, UV/Vis spectroelectrochemistry, and, for the Ir(III) congener, X-ray crystallography. [Cp*Rh(L(BI) )Cl][PF6 ]2 catalyses the transfer hydrogenation of imines by formate ion in very goods yield under conditions where the corresponding [Cp*Ir(L(BI) )Cl][PF6 ] and [Cp*M(phen)Cl][PF6 ] (M=Rh, Ir) complexes are almost inert as catalysts. Possible alternatives for the catalysis pathway are canvassed, and the free energies of intermediates and transition states determined by DFT calculations. The DFT study supports a mechanism involving formate-driven RhH formation (90 kJ mol(-1) free-energy barrier), transfer of hydride between the Rh and BI(+) centres to generate a tethered benzimidazoline (BIH) hydride donor, binding of imine substrate at Rh, back-transfer of hydride from the BIH organic hydride donor to the Rh-activated imine substrate (89 kJ mol(-1) barrier), and exergonic protonation of the metal-bound amide by formic acid with release of amine product to close the catalytic cycle. Parallels with the mechanism of biological hydride transfer in yADH are discussed.

The solution structure of bis(phenazine-1-carboxamide)-DNA complexes: MLN 944 binding corrected and extended.

MLN 944 is a bisintercalating DNA-binding antitumor agent known to be a template inhibitor of transcription. Previous (1) H NMR studies of its d(ATGCAT)2 complex concluded that its phenazine chromophores are protonated. However, we find that this is not so, which has important consequences for the charged state of the ligand, for the orientation of its 1-carboxamide group in the complex, and for the details of the interaction of its protonated interchromophore linker with the DNA base pairs. Here, we report a corrected solution structure of the MLN 944-d(ATGCAT)2 complex, and extend the study to complexes with d(TATGCATA)2 , and d(TACGCGTA)2 , using a variety of (1) H and (31) P NMR methods and molecular dynamics simulations employing the AMBER 12 force field. We find that for all three complexes MLN 944 binds as a dication, in which the chromophores are uncharged, in the DNA major groove spanning the central 2 GC base pairs in a manner that maintains the dyad symmetry of the DNA. The carboxamide group lies in the plane of the chromophore, its NH making hydrogen bonding interactions with the phenazine N10 nitrogen, and the protonated linkers form hydrogen bonds with the O6 atom of guanine. The dynamics simulations reveal extensive solvent interactions involving the linker amines, the carboxamide group, and the DNA bases.

A Benchmark Ab Initio and DFT Study of the Structure and Binding of Methane in the σ-Alkane Complex CpRe(CO)2(CH4).

Ab initio molecular orbital theory and density functional theory (DFT) procedures have been used to study the binding of methane in CpRe(CO)2(CH4), the simplest σ-alkane complex in the experimentally widely studied CpRe(CO)2(alkane) family. We find the optimal Re···C, Re···H and C···H distances to be 2.60, 1.92, and 1.15 Å, respectively, on the composite-CCSD(T)/def2-QZVPP (CCSD(T)/def2-TZVP with supplement for the larger def2-QZVPP basis set at the second-order Møller-Plesset perturbation theory level) potential energy surface which has been mapped out at this level of theory. The enthalpy of binding at 298 K was determined to be 62.0 kJ mol(-1) at the composite-CCSD(T)/CBS//B3-PW91/aug-cc-pVTZ-PP level. Benchmarks on the various DFT procedures show that some functionals give good geometries but underestimate binding energies, while others yield poor geometries but give closer agreements with the composite-CCSD(T) binding energy. On the other hand, the ωB97X-D functional gives fair agreements with composite-CCSD(T) for both geometry optimization as well as binding energy. Thus, it appears to be a reliable, easily implemented, and cost-effective means for studying Re-alkane complexes. Good binding energies are also obtained with several common functionals when D3 dispersion corrections are applied. Selected dispersion-corrected DFT methods (B3PW91-D3, TPSSh-D3, and B98-D3) were found to be quite accurate for the calculation of binding energies of several other model metal-CH4 complexes containing a range of metal centers (Rh, Pd, W, Ir, Pt). We also note that, for single-point energy calculation of the Re-CH4 binding, the PWP-B95-D3 double-hybrid DFT procedure provides an excellent agreement with the benchmark energy at only a slightly higher computational requirement.

Stereodynamics in eight-coordination; a 2D NMR spectroscopic and computational study of the exchange process in ThCl4(Me2NCH2CH2NMe2)2.

The (13)C{(1)H} NMR spectrum of eight-coordinate ThCl(4)(tmed)(2), where tmed = Me(2)NCH(2)CH(2)NMe(2), shows that two isomers are present at 219.8 K in a ratio of ≈8:1 and inversion of the five-membered Th-tmed ring is slow at this temperature in both isomers. The 2D (13)C{(1)H} exchange spectroscopy (EXSY) spectrum shows that each of the two inequivalent methyl groups of the major isomer does not exchange directly with each other but that they both exchange with both of the two inequivalent methyl groups found in the minor isomer. This implies that interconversion of the two enantiomers of the major isomer proceeds by a stepwise process that involves the minor isomer. The interconversion of the isomers involves a ring-inversion process that may proceed with or without Th-N bond breaking, and the NMR spectra cannot distinguish between these two processes nor can density functional theory (DFT) calculations (B3PW91 and M06 with consideration of dispersion effects and solvent) because these two possibilities proceed by way of transition states of similar energies in this case.

Observation of a tungsten alkane σ-complex showing selective binding of methyl groups using FTIR and NMR spectroscopies.

The alkane σ-complex (HEB)W(CO)(2)(pentane) (HEB = η(6)-hexaethylbenzene) is produced from the UV photolysis of (HEB)W(CO)(3) in alkane solvents at low temperature. IR and (1)H and (13)C NMR spectroscopic data are reported, representing the first NMR data for a group 6 alkane complex. Only binding of the methyl functionality of the pentane ligand was observed in (HEB)W(CO)(2)(pentane). This contrasts with the previously reported binding of pentane to rhenium fragments, wherein both methylene and methyl groups were observed to bind, with a slight preference for binding of the former. The reason for the preference for binding through the methyl group is investigated, and the steric requirement for the pentane to adopt an unfavorable gauche conformation when bound via a methylene is identified as a contributing factor.