induced-fit theory, model proposing that the binding of a substrate or some other molecule to an enzyme causes a change in the shape of the enzyme so as to enhance or inhibit its activity. Induced-fit theory retains the key-lock idea of a fit of the substrate at the active site but postulates in addition that the substrate must do more than simply fit into the already preformed shape of an active site—it must cause a change in the shape of the enzyme that results in the proper alignment of the catalytic groups on its surface. This concept has been likened to the fit of a hand in a glove, the hand (substrate) inducing a change in the shape of the glove (enzyme). Although some enzymes appear to function according to the older key-lock hypothesis, most apparently function according to the induced-fit theory.
Typically, the substrate approaches the enzyme surface and induces a change in its shape that results in the correct alignment of the catalytic groups. In the case of the digestive enzyme carboxypeptidase, for example, the binding of the substrate causes a tyrosine molecule at the active site to move by as much as 15 angstroms. The catalytic groups at the active site react with the substrate to form products. The products separate from the enzyme surface, and the enzyme is able to repeat the sequence. Nonsubstrate molecules that are too bulky or too small alter the shape of the enzyme so that a misalignment of catalytic groups occurs; such molecules are not able to react even if they are attracted to the active site.
The induced-fit theory explains a number of anomalous properties of enzymes. An example is “noncompetitive inhibition,” in which a compound inhibits the reaction of an enzyme but does not prevent the binding of the substrate. In this case, the inhibitor compound attracts the binding group so that the catalytic group is too far away from the substrate to react. The site at which the inhibitor binds to the enzyme is not the active site and is called an allosteric site. The inhibitor changes the shape of the active site to prevent catalysis without preventing binding of the substrate.
An inhibitor also can distort the active site by affecting the essential binding group; as a result, the enzyme can no longer attract the substrate. A so-called activator molecule affects the active site so that a nonsubstrate molecule is properly aligned and hence can react with the enzyme. Such activators can affect both binding and catalytic groups at the active site.
Enzyme flexibility is extremely important because it provides a mechanism for regulating enzymatic activity. The orientation at the active site can be disrupted by the binding of an inhibitor at a site other than the active site. Moreover, the enzyme can be activated by molecules that induce a proper alignment of the active site for a substrate that alone cannot induce this alignment.