Rates of Uncatalyzed Peptide Bond Hydrolysis in Neutral Solution and the Transition State Affinities of Proteases

Radzicka, Anna; Wolfenden, Richard

doi:10.1021/ja954077c

Cited by 451 publications

(484 citation statements)

References 18 publications

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“…Wolfenden and co-workers have compiled and measured many of these, and they provide most of the data that allow calculation of the K tx À1 values plotted in Figure 21. [40] The average value of K tx À1 for enzymes of 10 16.0AE4.0 m À1 corresponds to an average free energy of binding of 22 kcal mol À1 , but can range up to 32 kcal mol À1 . [34b, 40] The value of k cat.…”

Section: Enzyme-substrate Complexesmentioning

confidence: 99%

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Binding Affinities of Host–Guest, Protein–Ligand, and Protein–Transition‐State Complexes

et al. 2003

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The affinities of hosts—ranging from small synthetic cavitands to large proteins—for organic molecules are well documented. The average association constants for the binding of organic molecules by cyclodextrins, synthetic hosts, and albumins in water, as well as of catalytic antibodies or enzymes for substrates are 103.5±2.5 M−1. Binding affinities are elevated to 108±2 M−1 for the complexation of transition states and biological antigens by antibodies or inhibitors by enzymes, and to 1016±4 M−1 for transition states with enzymes. The origins of the distributions of association constants observed for the broad range of host–guest systems are explored in this Review, and typical approaches to compute and analyze host–guest binding in solution are discussed. In many classes of complexes a rough correlation is found between the binding affinity and the surface area that is buried upon complexation. Enzymes transcend this effect and achieve transition‐state binding much greater than is expected from the surface areas.

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Section: Enzyme-substrate Complexesmentioning

confidence: 99%

“…Plot of the number of complexes formed between enzymes and transition states with values of Àlg K tx falling within a particular range (K a = 10 16.0AE4.0 m À1 ). [40] as K M K tx À1 . From our previous discussion, the average value of K M is 10 À3.7 m. Therefore, the average value of k cat.…”

Section: Enzyme-substrate Complexesmentioning

confidence: 99%

Binding Affinities of Host–Guest, Protein–Ligand, and Protein–Transition‐State Complexes

et al. 2003

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“…Its half-life is estimated at 350-600 years at 25 • C and neutral pH [5]. This remarkable kinetic stability is required for its function, but presents a challenge when there is a physiological need to break it.…”

Section: Introductionmentioning

confidence: 99%

Metal assisted peptide bond hydrolysis: Chemistry, biotechnology and toxicological implications

Wezynfeld

Frączyk

Bal

2016

Coordination Chemistry Reviews

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“…4 Similarly, enzymatic peptidases are able to cleave peptide bonds quite efficiently with rate accelerations of up to 10 10 -10 12 when compared to the background hydrolysis under physiological conditions. [5][6][7] Inspired by this enzyme-mediated reactivity, synthetic chemists have sought to both explain and emulate such reactivity in synthetic molecular assemblies. Despite the intense study of enzymatic selectivity and efficiency, a complete understanding of how enzymes are able to achieve such heightened reactivity remains elusive.…”

Section: Introductionmentioning

confidence: 99%

Spin Equilibria in Monomeric Manganocenes: Solid-State Magnetic and EXAFS Studies

et al. 2009

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A water-soluble self-assembled supramolecular host molecule catalyzes the hydrolysis of orthoformates in basic solution. Comparison of the rate constants of the catalyzed and uncatalyzed reactions for hydrolysis displays rate accelerations of up to 3900 for tri-n-propyl orthoformate. Kinetic analysis shows that the mechanism of hydrolysis with the supramolecular host obeys the Michaelis-Menten model.Mechanistic studies, including 13 C-labeling experiments, revealed that the resting state of the catalytic system is the neutral substrate encapsulated in the host. Activation parameters for the k cat step of the reaction revealed that upon encapsulation in the assembly, the entropy of activation becomes more negative in contrast to the uncatalyzed reaction. Furthermore, solvent isotope effects reveal a normal k(H 2 O)/k(D 2 O) = 1.6, confirming that proton transfer is occurring in the transition state and is rate limiting in the catalyzed reaction. In comparison to the uncatalyzed reaction, which operates by an A-1 mechanism in which the decomposition of the protonated substrate is rate limiting, the encapsulated reaction proceeds through an A-S E 2 mechanism in which proton transfer from protonated water to the substrate is rate limiting.

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Rates of Uncatalyzed Peptide Bond Hydrolysis in Neutral Solution and the Transition State Affinities of Proteases

Cited by 451 publications

References 18 publications

Binding Affinities of Host–Guest, Protein–Ligand, and Protein–Transition‐State Complexes

Binding Affinities of Host–Guest, Protein–Ligand, and Protein–Transition‐State Complexes

Metal assisted peptide bond hydrolysis: Chemistry, biotechnology and toxicological implications

Spin Equilibria in Monomeric Manganocenes: Solid-State Magnetic and EXAFS Studies

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