Hybrid Synthetic and Computational Study of an Optimized, Solvent-Free Approach to Curcuminoids.

A green and optimized protocol has been developed for the preparation of symmetric 1,7-bis(aryl)-1,6-heptadiene-3,5-diones and asymmetric 2-aryl-6-arylidenecyclohexanones with modified substrate scope and good functional group tolerance. Syntheses proceed smoothly under solvent-free conditions, providing moderate to excellent product yields with a minimal workup procedure. Control experiments, spectroscopic, and computational studies support a mechanism involving the boron-assisted in situ generation of imine intermediates. Crystal structures of three curcuminoids and isolated mechanistic intermediates are reported. The data provide insight for the further development of solvent-free protocols toward diverse curcumin derivatives in the fields of pharmaceutical and synthetic chemistries.

Reactions of Germylenes and Stannylenes with Halo(hydrocarbyl)- and Chloro(amino)phosphines: Oxidative Addition versus Ligand Transfer.

Oxidative addition (OA) is an important elementary step in chemistry, but it has been studied mainly in the context of transition-metal-catalyzed reactions and mainly with carbon-X substrates (X = halogen, H). Reports of main-group metal compounds undergoing OA are rare by comparison, and those involving phosphorus-halogen substrates are rarer still. Acyclic and cyclic diazagermylenes and -stannylenes react with chloro(hydrocarbyl)phosphines with the intermediacy of oxidative addition products. Stannylenes react faster than germylenes, and these reactions are first-order in both reactants and slowed by steric bulk. Kinetic data and the structures of intermediates and products had suggested an adduct/insertion mechanism for these reactions. To gain further insight into these transformations, the work presented herein was extended to chloro(hydrocarbyl)phosphines with varying organic substituents. These studies confirmed prior conclusions concerning the rate-diminishing effect of steric bulk, and the rate dependence on leaving groups also seems to suggest adduct/insertion or SN2 mechanisms. Importantly, these new data now also point to associative decomposition pathways. In the course of the investigation, it was discovered that aliphatic chloro(amino)phosphines react differently with the carbene analogues, giving oxidative addition products for germylenes but metathesis reactions for stannylenes.

Heavier carbene analogues and their derivatives as κ-El, κ2-El,N, and κ2-N,N' ligands: different reactivity patterns for acyclic and cyclic diamidogermylenes and -stannylenes.

Because of the increasing importance of N-heterocyclic carbenes in organometallic chemistry we investigated the ligand properties of structurally-related acyclic and cyclic heavier carbene analogues with transition metal chlorides. Acyclic {(Me(3)Si)(2)N}(2)El, El = Ge and Sn, react with CuCl with transfer of one (Me(3)Si)(2)N ligand to yield the known copper tetramer {(Me(3)Si)(2)NCu}(4). The cyclic Me(2)Si(µ-N(t)Bu)(2)Ge, by contrast, binds copper through germanium only, furnishing a tetranuclear ladder structure with both terminal and bridging germylenes. The tin homologue, however, inserts into the CuCl bond, and the ensuing {Me(2)Si(µ-N(t)Bu)(2)SnCl}(-) ions then coordinate one copper ion via their tin atoms while sandwiching the remaining three copper ions in an unprecedented κ(2)-N,N' fashion. Chemically-harder Cr(II)--created in a redox reaction of Me(2)Si(µ-N(t)Bu)(2)Sn with CrCl(3)(THF)(3)--is not coordinated by tin, but chelated by both nitrogen atoms of one {Me(2)Si(µ-N(t)Bu)(2)SnCl}(-) ion and more weakly through the tin-bound chloride.

Resolving the fluorescence response of Escherichia coli carbamoyl phosphate synthetase: mapping intra- and intersubunit conformational changes.

Carbamoyl phosphate synthetase (CPS) from Escherichia coli is potentially overlaid with a network of allosterism, interconnecting active sites, effector binding sites, and aggregate interfaces to control its mechanisms of catalytic synchronization, regulation, and oligomerization, respectively. To characterize these conformational changes, a tryptophan-free variant of CPS was genetically engineered by substituting six native tryptophans with tyrosines. Each tryptophan was then reinserted, singly, as a specific fluorescence probe of its corresponding microenvironment. The amino acid substitutions themselves result in little apparent disruption of the protein; variants maintain catalytic and allosteric functionality, and the fluorescence properties of each tryptophan, while unique, are additive to wild-type CPS. Whereas the collective, intrinsic fluorescence response of E. coli CPS is largely insensitive to ligand binding, changes of the individual probes in intensity, lifetime, anisotropy, and accessibility to acrylamide quenching highlight the dynamic interplay between several protein domains, as well as between subunits. W213 within the carboxy phosphate domain, for example, exhibits an almost 40% increase in intensity upon saturation with ATP; W437 of the oligomerization domain, in contrast, is essentially silent in its fluorescence to the binding of ligands. Nucleotide and bicarbonate association within the large subunit induces fluorescence changes in both W170 and W175 of the small subunit, indicative of the type of long-range interactions purportedly synchronizing the carboxy phosphate and amidotransferase domains of the enzyme to initiate catalysis. ATP and ADP engender different fluorescence responses in most tryptophans, perhaps reflecting coordinating, conformational changes accompanying the cycling of reactants and products during catalysis.