The
intrinsic structural complexity of proteins makes it hard to
identify the contributions of each noncovalent interaction behind
the remarkable rate accelerations of enzymes. Coulombic forces are
evidently primary, but despite developments in artificial nanoreactor
design, a picture of the extent to which these can contribute has
not been forthcoming. Here we report on two supramolecular capsules
that possess structurally identical inner-spaces that differ in the
electrostatic potential (EP) field that envelops them: one positive
and one negative. This architecture means that only changes in the
EP field influence the chemical properties of encapsulated species.
We quantify these influences via acidity and rates of cyclization
measurements for encapsulated guests, and we confirm the primary role
of Coulombic forces with a simple mathematical model approximating
the capsules as Born spheres within a continuum dielectric. These
results reveal the reaction rate accelerations possible under Coulombic
control and highlight important design criteria for nanoreactors.
The interactions between nonpolar surfaces and polarizable anions lie in a gray area between the hydrophobic and Hofmeister effects. To assess the affinity of these interactions, NMR and ITC were used to probe the thermodynamics of eight anions binding to four different hosts whose pockets each consist primarily of hydrocarbon. Two classes of host were examined: cavitands and cyclodextrins. For all hosts, anion affinity was found to follow the Hofmeister series, with associations ranging from 1.6-5.7 kcal mol. Despite the fact that cavitand hosts 1 and 2 possess intrinsic negative electrostatic fields, it was determined that these more enveloping hosts generally bound anions more strongly. The observation that the four hosts each possess specific anion affinities that cannot be readily explained by their structures, points to the importance of counter cations and the solvation of the "empty" hosts, free guests, and host-guest complexes, in defining the affinity.
Octa-acid (OA) and tetra-endo-methyl octa-acid (TEMOA) are water-soluble, deep-cavity cavitands with nanometer-sized nonpolar pockets that readily bind complementary guests, such as n-alkanes. Experimentally, OA exhibits a progression of 1:1 to 2:2 to 2:1 host/guest complexes (X:Y where X is the number of hosts and Y is the number of guests) with increasing alkane chain length from methane to tetradecane. Differing from OA only by the addition of four methyl groups ringing the portal of the pocket, TEMOA exhibits a nonmonotonic progression of assembly states from 1:1 to 2:2 to 1:1 to 2:1 with increasing guest length. Here we present a systematic molecular simulation study to parse the molecular and thermodynamic determinants that distinguish the succession of assembly stoichiometries observed for these similar hosts. Potentials of mean force between hosts and guests, determined via umbrella sampling, are used to characterize association free energies. These free energies are subsequently used in a reaction network model to predict the equilibrium distributions of assemblies. Our models accurately reproduce the experimentally observed trends, showing that TEMOA's endo-methyl units constrict the opening of the binding pocket, limiting the conformations available to bound guests and disrupting the balance between monomeric complexes and dimeric capsules. The success of our simulations demonstrate their utility at interpreting the impact of even simple chemical modifications on supramolecular assembly and highlight their potential to aid bottom-up design.
Using molecular simulations, we examine the emergence of non-monotonic deep-cavity cavitand assembly patterns into monomeric and dimeric complexes with alkanes of increasing length.
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