Rapid Interconversion Research Articles

Sulfonamide Basedβ-Carbonic Anhydrase Inhibitors: 2D QSAR Study

The carbonic anhydrases (CAs) (or carbonate dehydratases) form a family of metalloenzymes that catalyze the rapid interconversion of carbon dioxide and water to bicarbonate and protons (or vice versa), a reversible reaction that occurs rather slowly in the absence of a catalyst. Theβ-CAs have been characterized in a high number of human pathogens, such as the fungi/yeastsCandida albicans, Candida glabrata, Cryptococcus neoformans, andSaccharomyces cerevisiaeand the bacteriaHelicobacter pylori, Mycobacterium tuberculosis, Haemophilus influenzae, Brucella suis, andStreptococcus pneumonia. Theβ-CAs in microorganisms provide physiological concentration of carbon dioxide and bicarbonate (CO2/HCO3-) for their growth. Inhibition ofβ-CAs from the pathogenic microorganism is recently being explored as a novel pharmacological target to treat infections caused by the these organisms. The present study aimed to establish a relationship between theβ-CAs inhibitory activity for structurally related sulphonamide derivatives and the physicochemical descriptors in quantitative terms. The statistically validated two-dimensional quantitative structure activity relationship (2D QSAR) model was obtained through multiple linear regression (MLR) analysis method using Vlife molecular design suits (MDS). Five descriptors showing positive and negative correlation with theβ-CAs inhibitory activity have been included in the model. This validated 2D QSAR model may be used to design sulfonamide derivatives with better inhibitory properties.

Carbonic anhydrase: a key regulatory and detoxifying enzyme for Karst plants

Karstification is a rapid process during which calcidic stones/limestones undergo dissolution with the consequence of a desertification of karst regions. A slow-down of those dissolution processes of Ca-carbonate can be approached by a reforestation program using karst-resistant plants that can resist alkaline pH and higher bicarbonate (HCO₃⁻) concentrations in the soil. Carbonic anhydrases (CA) are enzymes that mediate a rapid and reversible interconversion of CO₂ and HCO₃⁻. In the present study, the steady-state expression of a CA gene, encoding for the plant carbonic anhydrase from the parsley Petroselinum crispum, is monitored. The studies were primarily been performed during germination of the seeds up to the 12/14-day-old embryos. The CA cDNA was cloned. Quantitative polymerase chain reaction (qPCR) analysis revealed that the gene expression level of the P. crispum CA is strongly and significantly affected at more alkaline pH in the growth medium (pH 8.3). This abolishing effect is counteracted both by addition of HCO₃⁻ and by addition of polyphosphate (polyP) to the culture medium. In response to polyP, the increased pH in the vacuoles of the growing plants is normalized. The effect of polyP let us to propose that this polymer acts as a buffer system that facilitates the adjustment of the pH in the cytoplasm. In addition, it is proposed that polyP has the potential to act, especially in the karst, as a fertilizer that allows the karstic plants to cope with the adverse pH and HCO₃⁻ condition in the soil.

Symmetry breaking in self-assembled M 4 L 6 cage complexes

Here we describe the phenomenon of symmetry breaking within a series of M4L6 container molecules. These containers were synthesized using planar rigid bis-bidentate ligands based on 2,6-substituted naphthalene, anthracene, or anthraquinone spacers and Fe(II) ions. The planarity of the ligand spacer favors a stereochemical configuration in which each cage contains two metal centers of opposite handedness to the other two, which would ordinarily result in an S4-symmetric, achiral configuration. Reduction of symmetry from S4 to C1 is achieved by the spatial offset between each ligand's pair of binding sites, which breaks the S4 symmetry axis. Using larger Cd(II) or Co(II) ions instead of Fe(II) resulted, in some cases, in the observation of dynamic motion of the symmetry-breaking ligands in solution. NMR spectra of these dynamic complexes thus reflected apparent S4 symmetry owing to rapid interconversion between energetically degenerate, enantiomeric C1-symmetric conformations.

Rapid Conformational Fluctuations of Disordered HIV-1 Fusion Peptide in Solution.

The conformationally flexible fusion peptide (FP) of HIV-1 is indispensible for viral infection of host cells, due to its ability to insert into and tightly couple with phospholipid membranes. There are conflicting reports on the membrane-associated structure of FP, and solution structure information is limited, yet such a structure is the target for a novel class of antiretroviral inhibitors. An ensemble of explicit solvent molecular dynamics simulations, initiated from a disordered HIV-1 FP (aggregate time of ∼30 μs), revealed that while the vast majority of conformations predominantly lack secondary structure, both spontaneous formation and rapid interconversion of local secondary structure elements occur, highlighting the structural plasticity of the peptide. Therefore, even at this rapid time scale, FP constitutes a diverse and flexible conformational ensemble in solution. Secondary structure clustering reveals that the most prominent ordered elements are α- and 3-10-helical subsets of membrane-bound conformations, while trace populations within 2 Å RMSD of all complete membrane-bound conformations are found to pre-exist in the solution ensemble. Since inhibitor bound conformations of FP are only rarely found, FP inhibitors could function by modulating the conformational ensemble and binding to nonfusogenic FP structures. A thermodynamic characterization of the most prominent ordered nonfusogenic structures could facilitate the future design of improved FP inhibitors.

P-Stilbazole Moieties As Artificial Base Pairs for Photo-Cross-Linking of DNA Duplex

In this study, we report a photo-cross-linking reaction between p-stilbazole moieties. p-Stilbazoles were introduced into base-paring positions of complementary DNA strands. The [2 + 2] photocycloaddition reaction occurred rapidly upon light irradiation at 340 nm. Consequently, duplex was cross-linked and highly stabilized after 3 min irradiation. The CD spectrum of the cross-linked duplex indicated that the B-form double-helical structure was not severely distorted. NMR analysis revealed only one conformation of the duplex prior to UV irradiation, whereas two diastereomers were detected after the photo-cross-linking reaction. Before UV irradiation, p-stilbazole can adopt two different stacking modes because of rotation around the single bond between the phenyl and vinyl groups; these conformations cannot be discriminated on the NMR time scale due to rapid interconversion. However, photo-cross-linking fixed the conformation and enabled discrimination both by NMR and HPLC. The artificial base pair of p-methylstilbazolium showed almost the same reactivity as p-stilbazole, indicating that positive charge does not affect the reactivity. When a natural nucleobase was present in the complementary strand opposite p-stilbazole, the duplex was significantly destabilized relative to the duplex with paired p-stilbazole moieties and no photoreaction occurred between p-stilbazole and the nucleobase. The p-stilbazole pair has potential as a "third base pair" for nanomaterials due to its high stability and superb orthogonality.

Theoretical evidence of multiple dye regeneration mechanisms in dye-sensitized solar cells

The multiple regeneration mechanisms in dye-sensitized solar cells (DSSC), with N3 (Ru(dcbpy)2(NCS)2) as dye and I−/I3− as redox shuttle, have been studied by DFT methods. Our results show that different reaction pathways are possible within the same dye and the actual mechanism is controlled by the initial geometry of the dyeI complex. By considering the rapid interconversion between different N3I geometries, the reaction mechanism where N3I dissociates into neutral dye and I radical is preferred to the mechanism where N3I reacts with a second iodide.

Metabolome Response to Glucose in the β-Cell Line INS-1 832/13

Glucose-stimulated insulin secretion (GSIS) from pancreatic β-cells is triggered by metabolism of the sugar to increase ATP/ADP ratio that blocks the KATP channel leading to membrane depolarization and insulin exocytosis. Other metabolic pathways believed to augment insulin secretion have yet to be fully elucidated. To study metabolic changes during GSIS, liquid chromatography with mass spectrometry was used to determine levels of 87 metabolites temporally following a change in glucose from 3 to 10 mM glucose and in response to increasing concentrations of glucose in the INS-1 832/13 β-cell line. U-[(13)C]Glucose was used to probe flux in specific metabolic pathways. Results include a rapid increase in ATP/ADP, anaplerotic tricarboxylic acid cycle flux, and increases in the malonyl CoA pathway, support prevailing theories of GSIS. Novel findings include that aspartate used for anaplerosis does not derive from the glucose fuel added to stimulate insulin secretion, glucose flux into glycerol-3-phosphate, and esterification of long chain CoAs resulting in rapid consumption of long chain CoAs and de novo generation of phosphatidic acid and diacylglycerol. Further, novel metabolites with potential roles in GSIS such as 5-aminoimidazole-4-carboxamide ribotide (ZMP), GDP-mannose, and farnesyl pyrophosphate were found to be rapidly altered following glucose exposure.

A preformed binding interface in the unbound ensemble of an intrinsically disordered protein: evidence from molecular simulations.

Intrinsically disordered proteins play an important role in cellular signalling, mediated by their interactions with other biomolecules. A key question concerns the nature of their binding mechanism, and whether the bound structure is induced only by proximity to the binding partner. This is difficult to answer through experiment alone because of the very heterogeneous nature of the unbound ensemble, and the probable rapid interconversion of the various unbound structures. Here we report the most extensive set of simulations on NCBD to date: we use large-scale replica exchange molecular dynamics to explore the unbound state. An important feature of the study is the use of an atomistic force field that has been parametrised against experimental data for weakly structured peptides, together with an accurate explicit water model. Neither the force field nor the starting conformations are biased towards a particular structure. The regions of NCBD that have high helical propensity in the simulations correspond closely to helices in the ‘core’ unbound conformation determined by NMR, although no single member of the simulated unbound ensemble closely resembles the core conformation, or either of the two known bound conformations. We have validated the results against NMR spectroscopy and SAXS measurements, obtaining reasonable agreement. The two helices which most stabilise the binding of NCBD with ACTR are formed readily; the third helix, which is less important for binding but is involved in most of the intraprotein contacts of NCBD in the bound conformation, is formed more rarely, and tends not to coexist with the other helices. These results support a mechanism by which NCBD gains the advantages of disorder, while forming binding-competent structures in the unbound state. We obtain support for this mechanism from coarse-grained simulations of NCBD with, and without, its binding partner.

Lanthanide nitrate complexes with triethylphosphine oxide. Solid state and solution properties

Complexes between lanthanide nitrates and triethylphosphine oxide have been prepared and fall into two distinct categories. With the lighter lanthanides Ln(NO3)3(Et3PO)3 (Ln=La, Ce, Pr, Nd, Eu) are formed whilst for the heavier metals mixtures of Ln(NO3)3(Et3PO)3 and Ln(NO3)3(Et3PO)2 are isolated. The structures of Ln(NO3)3(Et3PO)3 (Ln=La, Ce, Eu) have been determined by single crystal X-ray crystallography and show that all the complexes are 9-coordinate and have a pseudo mer-octahedral arrangement if the bidentate nitrates are envisaged as monodentate ligands. The conductivity in dichloromethane and acetonitrile indicates that the complexes are non-conducting. NMR spectra in CD2Cl2 solution are consistent with a rapid interconversions of the inequivalent phosphorus environments. For the Yb and Lu complexes static structures can be assigned to peaks in the low temperature 31P NMR spectra which also show evidence of a pseudo fac-isomer and a 1:2 complex. The formation of mixtures of 1:2 and 1:3 complexes for the heavier lanthanides is discussed in terms of the balance between steric effects and the basicity of the phosphine oxide ligands.

Structure and Dynamics of Small Soluble Aβ(1–40) Oligomers Studied by Top-Down Hydrogen Exchange Mass Spectrometry

Aβ peptides can assemble into amyloid fibrils, which represent one of the hallmarks of Alzheimer's disease. Recent studies, however, have focused on the behavior of small soluble Aβ oligomers that possess a much greater neurotoxicity than mature fibrils. The structural characterization of these oligomers remains difficult because of their highly dynamic and polymorphic nature. This work explores the behavior of Aβ(1-40) in a slightly basic solution (pH 9.3) at a low salt concentration (10 mM ammonium acetate). These conditions lead to the formation of small oligomers, without any signs of fibrillation for several hours. The structure and dynamics of these oligomers were characterized by circular dichroism spectroscopy, size exclusion chromatography, and millisecond time-resolved hydrogen exchange mass spectrometry (MS). Our results reveal rapid interconversion between Aβ(1-40) oligomers and monomers. The mole fraction of monomeric molecules is on the order of 40%. Oligomers consist of ~4 Aβ(1-40) molecules on average, and the resulting assemblies have a predominantly β-sheet secondary structure. Hydrogen exchange proceeds in the EX1 regime. This feature allows the application of conformer-specific top-down MS. Electron capture dissociation is used for interrogating the deuteration behavior of the Aβ(1-40) oligomers. This approach provides a spatial resolution of ~2 residues. The backbone amide deuteration pattern uncovered in this way is consistent with a β-turn-β motif for L17-M35. The N-terminus is involved in hydrogen bonding, as well, whereas protection gradually tapers off for C-terminal residues 35-40. Our data are consistent with earlier proposals, according to which Aβ(1-40) oligomers adopt a β-barrel structure. In general terms, this study demonstrates how top-down MS with precursor ion selection can be employed for structural studies of specific protein conformers within a heterogeneous mix.

Ascorbate and dehydroascorbic acid as biomarkers of oxidative stress: validity of clinical data depends on vacutainer system used

Ascorbate and dehydroascorbic acid are frequently used as biomarkers of oxidative stress, but their lack of stability ex vivo and rapid postsampling interconversion continue to result in erroneous reference values. One problem is the large variety of vacutainer devices used for blood sampling purposes and the basic question of plasma vs serum as matrix. This study acquired blood samples by using 9 different and commonly used vacutainer systems followed by acidic stabilization and analysis by a well-validated method with the purpose of identifying acceptable means of collecting samples for proper ascorbate/dehydroascorbic acid analysis. In comparison, K(3)-EDTA vacutainers were superior in maintaining low ex vivo oxidation of vitamin C.

Ground-State Proton Transfer in Green Fluorescent Protein Measured by NMR

Proton transfer plays an important role in the optical properties of fluorescent proteins. Excited-state proton transfer (ESPT) is responsible for wtGFP's anomalously large Stokes shift and a number of FPs have found use as in vivo pH indicators. Unlike ESPT, ground-state proton transfer cannot be synchronously initiated (i.e. with an excitation pulse) and must be studied more indirectly. We report an NMR method in which GFP is labeled with a 13C at the position adjacent the phenol hydroxyl on the chromophore. This position is a highly specific and sensitive reporter of the ionization state as measured by direct-detect 13C-NMR. Through lineshape analysis and time-resolved NMR spectroscopy we obtain kinetic parameters for proton transfer. We find that GFPs having internal proton transfer and capable of ESPT show rapid interconversion of the protonated and deprotonated states (on the order of microseconds) while GFPs which must transfer protons externally to the solvent have much slower equilibration (on the order of milliseconds). Parallel measurements with less direct fluorescence correlation spectroscopy reveal interesting discrepancies perhaps suggestive of light-driven structural dynamics.

Mapping Unstructured Regions and Synergistic Folding in Intrinsically Disordered Proteins with Amide H/D Exchange Mass Spectrometry

Mapping the structured and disordered regions and identifying disorder-to-order transitions are essential to understanding intrinsically disordered proteins (IDPs). One technique that can provide such information is H/D exchange coupled with mass spectrometry (H/D-MS). To explore the feasibility of H/D-MS for mapping disordered and ordered regions in IDPs, we undertook a systematic evaluation of an unstructured protein, a molten globular protein, and the well-folded complex of the two proteins. Most segments of the unstructured protein, ACTR (activator of thyroid and retinoid receptors, NCOA3_HUMAN, residues 1018-1088), exchange at rates consistent with its assignment as an unstructured protein, but there is slight protection in regions that become helical in the ACTR-CBP complex. The molten globular protein, CBP (the nuclear coactivator binding domain of the CREB binding protein, CBP_MOUSE, residues 2059-2117), is moderately protected from exchange, and the protection is nearly uniform across the length of the protein. The uniformity arises because of rapid interconversion between an ensemble of folded conformers and an ensemble of unstructured conformers. Rapid interconversion causes the H/D exchange kinetics to be dominated by exchange by molecules in unstructured conformations. For the folded ACTR-CBP complex, the exchange data provide a qualitatively accurate description of the complex. Our results provide a useful framework to use in the interpretation of H/D-MS data of intrinsically disordered proteins.

GlmS Riboswitch binding to the glucosamine-6-phosphate α-anomer shifts the pKa toward neutrality.

The glmS riboswitch regulates gene expression through a self-cleavage activity. The reaction is catalyzed with the assistance of the metabolite cofactor glucosamine-6-phosphate (GlcN6P), whose amino group is proposed to serve as the general acid during the reaction. This reaction is pH-dependent with a pK(a) that is lower than the observed pK(a) for the amine of GlcN6P in solution. GlcN6P, like other pyranose sugars, undergoes spontaneous and rapid interconversion between the α and β anomers at the C1 position. Here we demonstrate by NMR that the Bacillus anthracis glmS riboswitch selectively binds the α-anomer of GlcN6P with a maximum binding affinity of 0.36 mM and that binding is pH-dependent. We also report that the anomeric ratio between α and β is pH-dependent and the pK(a)s of the two amines differ by 0.5 pH units, α being the higher of the two (pK(a)=8.3). The pH dependence of binding reveals a pK(a) of 6.7, suggesting that the glmS RNA reduces the pK(a) of the GlcN6P amine by 1.6 units in the ground state. We reevaluated previously obtained kinetic data and found the reaction pK(a) is 6.9, within error of the binding data. The data support a model where the reaction pK(a) corresponds to that of the GlcN6P amine. This observation has broader relevance for considering how the microenvironment of an RNA, despite its anionic character, can reduce the pK(a)s of functional groups for use in catalysis.

Reexamination of the Rehm–Weller Data Set Reveals Electron Transfer Quenching That Follows a Sandros–Boltzmann Dependence on Free Energy

In a landmark publication over 40 years ago, Rehm and Weller (RW) showed that the electron transfer quenching constants for excited-state molecules in acetonitrile could be correlated with the excited-state energies and the redox potentials of the electron donors and acceptors. The correlation was interpreted in terms of electron transfer between the molecules in the encounter pair (A*/D ⇌ A(•-)/D(•+) for acceptor A and donor D) and expressed by a semiempirical formula relating the quenching constant, k(q), to the free energy of reaction, ΔG. We have reinvestigated the mechanism for many Rehm and Weller reactions in the endergonic or weakly exergonic regions. We find they are not simple electron transfer processes. Rather, they involve exciplexes as the dominant, kinetically and spectroscopically observable intermediate. Thus, the Rehm-Weller formula rests on an incorrect mechanism. We have remeasured k(q) for many of these reactions and also reevaluated the ΔG values using accurately determined redox potentials and revised excitation energies. We found significant discrepancies in both ΔG and k(q), including A*/D pairs at high endergonicity that did not exhibit any quenching. The revised data were found to obey the Sandros-Boltzmann (SB) equation k(q) = k(lim)/[1 + exp[(ΔG + s)/RT]]. This behavior is attributed to rapid interconversion among the encounter pairs and the exciplex (A*/D ⇌ exciplex ⇌ A(•-)/D(•+)). The quantity k(lim) represents approximately the diffusion-limited rate constant, and s the free energy difference between the radical ion encounter pair and the free radical ions (A(•-)/D(•+) vs A(•-) + D(•+)). The shift relative to ΔG for the overall reaction is positive, s = 0.06 eV, rather than the negative value of -0.06 eV assumed by RW. The positive value of s involves the poorer solvation of A(•-)/D(•+) relative to the free A(•-) + D(•+), which opposes the Coulombic stabilization of A(•-)/D(•+). The SB equation does not involve the microscopic rate constants for interconversion among the encounter pairs and the exciplex. Data that fit this equation contain no information about such rate constants except that they are faster than dissociation of the encounter pairs to (re-)form the corresponding free species (A* + D or A(•-) + D(•+)). All of the present conclusions agree with our recent results for quenching of excited cyanoaromatic acceptors by aromatic donors, with the two data sets showing indistinguishable dependencies of k(q) on ΔG.

Probing autoinducer-2 based quorum sensing: the biological consequences of molecules unable to traverse equilibrium states.

Bacteria have developed a cell-to-cell communication system, termed quorum sensing (QS), which allows for the population-dependent coordination of their behavior via the exchange of chemical signals. Autoinducer-2 (AI-2), a class of QS signals derived from 4,5-dihydroxy-2,3-pentandione (DPD), has been revealed as a universal signaling molecule in a variety of bacterial species. In spite of considerable interest, the study of putative AI-2 based QS systems remains a challenging topic in part due to the rapid interconversion between the linear and cyclic forms of DPD. Herein, we report the design and development of efficient syntheses of carbocyclic analogues of DPD, which are locked in the cyclic form. The synthetic analogues were evaluated for the modulation of AI-2-based QS in Vibrio harveyi and Salmonella typhimurium. No agonists were uncovered in either V. harveyi or S. typhimurium assay, whereas weak to moderate antagonists were found against V. harveyi. On the basis of NMR analyses and DFT calculations, the heterocyclic oxygen atom within DPD appears necessary to promote hydration at the C3 position of cyclic DPD to afford the active tetrahydroxy species. These results also shed light on the interaction between the heterocyclic oxygen atom and receptor proteins as well as the importance of the linear form and dynamic equilibrium of DPD as crucial requirements for activation of AI-2 based QS circuits.

Isomer Population Analysis of Gaseous Ions From Infrared Multiple Photon Dissociation Kinetics

Infrared multiple photon dissociation (IRMPD) kinetics measured with tunable laser radiation from a free electron laser (FEL) are used to probe the relative populations of and interconversions between energetically competitive isomers of gas-phase ions at 298 K. On-resonance IRMPD kinetics of monoisomeric benzoate anion and anilinium (protonated aniline) are measured to determine the extent of overlap of the laser beam with the precursor ion population (∼93%). IRMPD kinetics indicating different photodissociation behavior for different isomers obtained at isomer-specific resonances are used to determine relative populations of salt bridge and charge-solvated isomers for ArgGly·Na(+), Ser·Cs(+), and Arg·Na(+). These values and Gibbs free energy differences obtained from them for thermal precursor populations are compared to values reported using other, less direct population probes. Rapid interconversion of two charge-solvated isomers occurs for ArgGly·Li(+), precluding population analysis for this ion. ArgGly·Na(+), ArgGly·Li(+), and Arg·Na(+) exhibit IRMPD induction periods lasting many seconds for some isomers at the laser photon energies and power used, indicating that IRMPD relative spectral intensities are time-dependent for these ions and that the relative band intensities in IRMPD spectra measured with short irradiation times may not provide meaningful information about relative isomer populations. These results constitute the first direct probe of ion isomer populations using IRMPD kinetics obtained with a FEL and illustrate a number of caveats in interpreting IRMPD spectra measured with just a single irradiation time. These results also indicate that more complete overlap of the laser beam with the ions will be highly advantageous in future instrument designs for IRMPD kinetics and spectroscopy experiments.

Boron doping: B/H/C/O gas-phase chemistry; H atom density dependences on pressure and wire temperature; puzzles regarding the gas-surface mechanism

Experimental and modeling studies of the gas-phase chemistry occurring in dilute, hot filament (HF) activated B 2H 6/CH 4/H 2 gas mixtures appropriate for growth of boron-doped diamond are reported. The results of two-dimensional modeling of heat and mass transfer processes and the B/H/C chemistry prevailing in such HF activated gas mixtures (supplemented by reactions involving trace O 2 present as air impurity in the process gas mixture) are discussed and compared with measurements of B atom densities as functions of the hot wire temperature T w and distance from the wire. Most of the B 2H 6 molecules that diffuse from the cool, near-wall regions into the hot, near wire region are thermally decomposed (yielding two BH 3 molecules as primary products) and then converted into various ‘active’ B-containing species like B, BH and BH 2 — some of which are able to accommodate into the growing diamond film. H-shifting reactions BH x + H ↔ BH x − 1 + H 2 enable rapid inter-conversion between the various BH x ( x = 0–3) species and the BH x source is limited by diffusional transfer of B 2H 6. H atoms play several key roles — e.g. activating the process gas mixture, and driving inter-conversions between the various H x B y C z O z′ species. We show that the T w and gas pressure dependences of the H atom production rate (by H 2 dissociation on the HF surface) can be accommodated by a simple gas-surface reaction model.

Stereoselective Olefination of N‐Sulfonyl Imines with Stabilized Phosphonium Ylides for the Synthesis of Electron‐Deficient Alkenes

AbstractAn unprecedented protocol has been developed for thestereoselective synthesis of structurally diverse electron‐deficient alkenes in moderate to excellent yields from readily accessible N‐sulfonyl imines and stabilized phosphonium ylides. Significantly, the olefination reaction of N‐sulfonylimines with nitrile‐stabilized phosphonium ylides affords an array of α,β‐unsaturated nitriles with high Z selectivity, and the reactions with ester‐, amide‐, and ketone‐stabilized phosphonium ylides afford α,β‐unsaturated esters, amides, and ketones with high E selectivity, respectively. Spectroscopic analysis of the reaction mixtures and trapping of the intermediates allow plausible mechanisms to be proposed. Initialimine/ylide addition leads to the formation of betaines that cyclize to form 1,2‐azaphosphetanes that subsequently eliminate iminophosphoranes to yield alkenes. For the synthesis of electron‐deficient 1,2‐disubstituted alkenes, the presence of an electron‐withdrawing group in the betaine allows rapid interconversion between its two diastereomers through proton transfer. The Z/E selectivity for alkene synthesis is determined by the different rates at which the two betaine diastereomers form the corresponding 1,2‐azaphosphetane diastereomers. In contrast, the Z/E selectivity for the synthesis of electron‐deficient trisubstituted alkenes originates from the diastereoselective addition of stabilized phosphonium ylides to N‐sulfonyl imines.

Solvation of Ti(iv) in aqueous solution under ambient and supercritical conditions

We examine the structure of the hydrated Ti(IV) complex under both ambient and supercritical conditions using first-principles molecular dynamics. We find that an unanticipated fivefold coordination of Ti(IV) is favoured under ambient conditions, with rapid interconversions between square pyramidal and trigonal bipyramidal structures. At supercritical conditions the Ti coordination increases from five to six, adopting both octahedral and trigonal prismatic geometries. At 1000 K, the magnitude of the increase in the Ti to oxygen coordination number with increasing water density is similar to that of Li-O under comparable conditions. We present a detailed picture of the bonding in the hydrated Ti(IV) complex under both ambient and supercritical conditions.