Protein-like proton exchange in a synthetic host cavity

Abstract: The mechanism of proton exchange in a metal-ligand enzyme active site mimic (compound 1) is described through amide hydrogendeuterium exchange kinetics. The type and ratio of cationic guest to host in solution affect the rate of isotope exchange, suggesting that the rate of exchange is driven by a host whose cavity is occupied by water. Rate constants for acid-, base-, and watermediated proton exchange vary by orders of magnitude depending on the guest, and differ by up to 200 million-fold relative to an alani… Show more

“…The assembly contains ah ighly anionic exterior surface, which confers solubility in water,a s well as affinity for the externali on association of cationic molecules. [24] Other catalyzed chemical transformations [25,26] and dramatic changes in the properties and reactivity of encapsulatedg uest molecules [27,28] have been achieved with rate accelerationso f up twentym illion, [29] thus leadingu st oa ssume that the transition state of these reactions is stabilized, similar to the case of enzymes. For example, host 1 catalyzes the Nazarov cyclizationo f1 ,3-pentadienols with rate accelerationso f1 0 6 ,a nd this result has been attributed to transition-state binding, as well as substrate conjugate stabilization.…”

“…These latter investigations led to the development of proton‐catalyzed hydrolysis reactions inside 1 , in which a protonated transition state is stabilized in the host interior . Other catalyzed chemical transformations and dramatic changes in the properties and reactivity of encapsulated guest molecules have been achieved with rate accelerations of up twenty million, thus leading us to assume that the transition state of these reactions is stabilized, similar to the case of enzymes.…”

Different and Often Opposing Forces Drive the Encapsulation and Multiple Exterior Binding of Charged Guests to a M₄L₆ Supramolecular Vessel in Water

“…The assembly contains ah ighly anionic exterior surface, which confers solubility in water,a s well as affinity for the externali on association of cationic molecules. [24] Other catalyzed chemical transformations [25,26] and dramatic changes in the properties and reactivity of encapsulatedg uest molecules [27,28] have been achieved with rate accelerationso f up twentym illion, [29] thus leadingu st oa ssume that the transition state of these reactions is stabilized, similar to the case of enzymes. For example, host 1 catalyzes the Nazarov cyclizationo f1 ,3-pentadienols with rate accelerationso f1 0 6 ,a nd this result has been attributed to transition-state binding, as well as substrate conjugate stabilization.…”

“…These latter investigations led to the development of proton‐catalyzed hydrolysis reactions inside 1 , in which a protonated transition state is stabilized in the host interior . Other catalyzed chemical transformations and dramatic changes in the properties and reactivity of encapsulated guest molecules have been achieved with rate accelerations of up twenty million, thus leading us to assume that the transition state of these reactions is stabilized, similar to the case of enzymes.…”

Different and Often Opposing Forces Drive the Encapsulation and Multiple Exterior Binding of Charged Guests to a M₄L₆ Supramolecular Vessel in Water

“…The Ga 4 L 6 12− tetrahedral assembly formulated by Raymond and coworkers represents an excellent example of a water-soluble supramolecular cage that has provided host interactions that promotes guest encapsulation. Using steric interactions and electrostatic charge to chemically position the substrate while shielding the reaction from solvent, this host has been shown to provide enhanced reaction rates that approach the performance of natural biocatalysts ( 4 – 10 ). Moreover, aqueous solvation of the substrate, host, and encapsulated solvent also play an important role in the whole catalytic cycle.…”

“…Moreover, aqueous solvation of the substrate, host, and encapsulated solvent also play an important role in the whole catalytic cycle. In particular, the driving forces that release water from the nanocage host to favor the direct binding with the substrate is thought to be a critical factor in successful catalysis, but is challenging to probe directly ( 7 , 8 , 11 – 14 ).…”

An isolated water droplet in the aqueous solution of a supramolecular tetrahedral cage

“…11−13 The metal−ligand framework of the host generates a large and hydrophobic interior cavity capable of encapsulating guest molecules of appropriate size 14 and a highly anionic exterior surface which promotes external association of cationic molecules, and renders the host water-soluble. 15 −17 The interior microenvironment of host 1, which differs dramatically from the bulk solvent environment, has been successfully used to modify the physical properties and reactivity of encapsulated guest molecules 18,19 and to catalyze chemical transformations 20−22 with rate accelerations of up 2 × 10 7 . 23 This catalytic activity is achieved by transition state stabilization in a manner similar to the commonly accepted mechanism of action for enzymatic catalysis.…”

Untangling the Diverse Interior and Multiple Exterior Guest Interactions of a Supramolecular Host by the Simultaneous Analysis of Complementary Observables