24 research outputs found
Probing the Inverse Trans Influence in Americium and Lanthanide Tribromide Tris(tricyclohexylphosphine oxide)
The synthesis, characterization, and theoretical
analysis of meridional americium tribromide tris(tricyclohexylphosphine oxide),
mer-AmBr3(OPcy3)3 has been achieved and
is compared with its early lanthanide (La to Nd) analogs. The data show that homo trans ligands
show significantly shorter bonds than the cis or hetero trans ligands. This is
particularly pronounced in the americium compound. DFT along with
multiconfigurational CASSCF calculations show that the contraction of the bonds
relates qualitatively with overall covalency, i.e. americium shows the most
covalent interactions compared to lanthanides. . However, the involvement of
the 5p and 6p shells in bonding follows a different order, namely
cerium > neodymium ~ americium. This study provides further insight into the
mechanisms by which ITI operates in low-valent f-block complexes
Why p-OMe- and p-Cl-β-Methylphenethylamines Display Distinct Activities upon MAO-B Binding.
Despite their structural and chemical commonalities, p-chloro-β-methylphenethylamine and p-methoxy-β-methylphenethylamine display distinct inhibitory and substrate activities upon MAO-B binding. Density Functional Theory (DFT) quantum chemical calculations reveal that β-methylation and para-substitution underpin the observed activities sustained by calculated transition state energy barriers, attained conformations and key differences in their interactions in the enzyme's substrate binding site. Although both compounds meet substrate requirements, it is clear that β-methylation along with the physicochemical features of the para-substituents on the aromatic ring determine the activity of these compounds upon binding to the MAO B-isoform. While data for a larger set of compounds might lend generality to our conclusions, our experimental and theoretical results strongly suggest that the contrasting activities displayed depend on the conformations adopted by these compounds when they bind to the enzyme
Influence of protonation on substrate and inhibitor interactions at the active site of human monoamine oxidase-A
Although substrate conversion mediated by human monoaminooxidase (hMAO) has been associated with the deprotonated state of their amine moiety, data regarding the influence of protonation on substrate binding at the active site are scarce. Thus, in order to assess protonation influence, steered molecular dynamics (SMD) runs were carried out. These simulations revealed that the protonated form of the substrate serotonin (5-HT) exhibited stronger interactions at the protein surface compared to the neutral form. The latter displayed stronger interactions in the active site cavity. These observations support the possible role of the deprotonated form in substrate conversion. Multigrid docking studies carried out to rationalize the role of 5-HT protonation in other sites besides the active site indicated two energetically favored docking sites for the protonated form of 5-HT on the enzyme surface. These sites seem to be interconnected with the substrate/inhibitor cavity, as revealed by the
Altering the Spectroscopy, Electronic Structure, and Bonding of Organometallic Curium(III) Upon Coordination of 4,4-bipyridine
Structural and electronic characterization of (Cp\u273Cm)2(4,4\u27-bpy) (Cp\u27 = trimethylsilylcyclopentadienyl, 4,4\u27-bpy = 4,4\u27-bipyridine) is reported and provides a rare example of curium-carbon bonding. Cp\u273Cm displays unexpectedly low energy emission that is quenched upon coordination by 4,4\u27-bipyridine. Electronic structure calculations on Cp\u273Cm and (Cp\u273Cm)2(4,4\u27-bpy) rule out significant differences in the emissive state, rendering 4,4\u27-bipyridine as the primary quenching agent. Comparisons of (Cp\u273Cm)2(4,4\u27-bpy) with its samarium and gadolinium analogues reveal atypical bonding patterns and electronic features that offer insights into bonding between carbon with f-block metal ions
Teaching, training and learning for the agroecology transition : a french-brazilian perspective
International audienc
Molecular dynamics simulation of halogen bonding mimics experimental data for cathepsin L inhibition
ArtÃculo de publicación ISIA MD simulation protocol was developed to
model halogen bonding in protein–ligand complexes by
inclusion of a charged extra point to represent the anisotropic
distribution of charge on the halogen atom. This
protocol was then used to simulate the interactions of
cathepsin L with a series of halogenated and non-halogenated
inhibitors. Our results show that chloro, bromo and
iodo derivatives have progressively narrower distributions
of calculated geometries, which reflects the order of affinity
I[Br[Cl, in agreement with the IC50 values. Graphs for
the Cl, Br and I analogs show stable interactions between
the halogen atom and the Gly61 carbonyl oxygen of the
enzyme. The halogen-oxygen distance is close to or less
than the sum of the van der Waals radii; the C–X O angle
is about 170 ; and the X O=C angle approaches 120 , as
expected for halogen bond formation. In the case of the
iodo-substituted analogs, these effects are enhanced by
introduction of a fluorine atom on the inhibitors’ halogenbonding
phenyl ring, indicating that the electron withdrawing
group enlarges the r-hole, resulting in improved
halogen bonding properties.FONDECYT
Grant 111014
Altering the spectroscopy, electronic structure, and bonding of organometallic curium(III) upon coordination of 4,4′−bipyridine
Abstract Structural and electronic characterization of (Cp′3Cm)2(μ−4,4′−bpy) (Cp′ = trimethylsilylcyclopentadienyl, 4,4′−bpy = 4,4′−bipyridine) is reported and provides a rare example of curium−carbon bonding. Cp′3Cm displays unexpectedly low energy emission that is quenched upon coordination by 4,4′−bipyridine. Electronic structure calculations on Cp′3Cm and (Cp′3Cm)2(μ−4,4′−bpy) rule out significant differences in the emissive state, rendering 4,4′−bipyridine as the primary quenching agent. Comparisons of (Cp′3Cm)2(μ−4,4′−bpy) with its samarium and gadolinium analogues reveal atypical bonding patterns and electronic features that offer insights into bonding between carbon with f-block metal ions. Here we show the structural characterization of a curium−carbon bond, in addition to the unique electronic properties never before observed in a curium compound
Radium Revisited: Revitalization of the Coordination Chemistry of Nature’s Largest 2+ Cation
The crystallization, single-crystal structure, and Raman spectroscopy of Ra(NO3)2 have been investigated by experiment and theory, which represent the first, pure radium compound characterized by single crystal X-ray diffraction. The Ra2+ centers are bound by six chelating nitrate anions to form an anticuboctahedral geometry. The Raman spectrum acquired from a single crystal of Ra(NO3)2 generally occurs at a lower frequency than found in Ba(NO3)2 as expected. Computational studies on Ra(NO3)2 provide an estimation of the bond orders via Wiberg bond indices and indicate that Ra–O interactions are weak with values of 0.025 and 0.026 for Ra–O bonds. Inspection of natural bond orbitals and natural localized molecular orbitals suggest negligible orbital mixing. However, second-order perturbation interactions show that donation from the lone pairs of the nitrate oxygen atoms to the 7s orbitals of Ra2+ stabilize each Ra–O interaction by ca. 5 kcal mol−1