Induced-fit binding

Hopfinger s 4D QSAR approach, and the methods VolSurl and GRIND developed by Cruciani. Vedani has proposed 5D QSAR, which considers hypotheses for changes that might occur in a conformation of a receptor due to ligand binding (induced fit) as a fifth dimension. ... 

Figure 7-5. Two-dimensional representation of Koshland s induced fit model of the active site of a lyase. Binding of the substrate A—B induces conformational changes In the enzyme that aligns catalytic residues which participate in catalysis and strains the bond between A and B, facilitating its cleavage.

C15-0139. According to the induced-fit model of enzyme activity, binding a reactant to the enz Tne causes a... 

Another difficulty is that a peptide may be able to bind to an existing neutralizing monoclonal antibody by an induced-fit mechanism that is somehow driven by the pre-existing structure of the antibody paratope. However, the same induced-fit process may not take place when the peptide is used as the immunogen and is confronted in the host by a large population of B cell receptors allowing a variety of other interactions. 

The use of the symbol E in 5.1 for the environment had a double objective. It stands there for general environments, and it also stands for the enzyme considered as a very specific environment to the chemical interconversion step [102, 172], In the theory discussed above catalysis is produced if the energy levels of the quantum precursor and successor states are shifted below the energy value corresponding to the same species in a reference surrounding medium. Both the catalytic environment E and the substrates S are molded into complementary surface states to form the complex between the active precursor complex Si and the enzyme structure adapted to it E-Si. In enzyme catalyzed reactions the special productive binding has been confussed with the possible mechanisms to attain it lock-key represents a static view while the induced fit concept... 

Wester, M.R., Johnson, E.F., Marques-Soares, C., Dijols, S., Dansette, P.M., Mansuy, D. and Stout, C.D. (2003) Structure of mammalian cytochrome P450 2C5 complexed with diclofenac at 2.1 A resolution evidence for an induced fit model of substrate binding. Biochemistry, 42, 9335-9345. 

Figure 6. Enzymes act as recycling catalysts in biochemical reactions. A substrate molecule binds (reversible) to the active site of an enzyme, forming an enzyme substrate complex. Upon binding, a series of conformational changes is induced that strengthens the binding (corresponding to the induced fit model of Koshland [148]) and leads to the formation of an enzyme product complex. To complete the cycle, the product is released, allowing the enzyme to bind further substrate molecules. (Adapted from Ref. 1). See color insert.

One of the important consequences of studying catalysis by mutant enzymes in comparison with wild-type enzymes is the possibility of identifying residues involved in catalysis that are not apparent from crystal structure determinations. This has been usefully applied (Fersht et al., 1988) to the tyrosine activation step in tyrosine tRNA synthetase (47) and (49). The residues Lys-82, Arg-86, Lys-230 and Lys-233 were replaced by alanine. Each mutation was studied in turn, and comparison with the wild-type enzyme revealed that each mutant was substantially less effective in catalysing formation of tyrosyl adenylate. Kinetic studies showed that these residues interact with the transition state for formation of tyrosyl adenylate and pyrophosphate from tyrosine and ATP and have relatively minor effects on the binding of tyrosine and tyrosyl adenylate. However, the crystal structures of the tyrosine-enzyme complex (Brick and Blow, 1987) and tyrosyl adenylate complex (Rubin and Blow, 1981) show that the residues Lys-82 and Arg-86 are on one side of the substrate-binding site and Lys-230 and Lys-233 are on the opposite side. It would be concluded from the crystal structures that not all four residues could be simultaneously involved in the catalytic process. Movement of one pair of residues close to the substrate moves the other pair of residues away. It is therefore concluded from the kinetic effects observed for the mutants that, in the wild-type enzyme, formation of the transition state for the reaction involves a conformational change to a structure which differs from the enzyme structure in the complex with tyrosine or tyrosine adenylate. The induced fit to the transition-state structure must allow interaction with all four residues simultaneously. 

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