Fig. 2.
Fig. 2. Comparison of proposed models of NADPH oxidase regulation by Rac GTPase. / In each of the proposed molecular models for NADPH oxidase regulation by Rac GTPase, the switch 1 region of Rac (not indicated) interacts with p67phox, the prenylated tail and polybasic domain of Rac (shown as a zigzag line) interact with the membrane, and the activation domain of p67phox (a crosshatched section) interacts with cytochrome b558. A role for p40phox remains unclear. In the model of Lambeth and colleagues (model A), Rac is thought to be recruited to the plasma membrane phospholipid bilayer via its prenylated C-terminus and polybasic domain. Indirect evidence supports the idea that the Rac insert domain (hatched section) may interact directly with cytochrome b558. Lambeth2 proposes the activation domain of p67phox is the sole regulator of the electron transfer step from NADPH to FAD. Rac and p47phox serve as adapters aiding in the interaction of p67phox with cytochrome b558. In model B proposed by Pick and colleagues,3738 Rac is thought to interact only with plasma membrane phospholipids via its C-terminal prenyl group and polybasic domain and does not interact physically with cytochrome b558. In this model, the insert domain is not involved in protein interactions or regulation of the NADPH oxidase. As in the model of Lambeth and colleagues, p67phox is the sole regulator of electron transfer by cytochrome b558, while Rac and p47phox serve only as adapters to position p67phox for interaction with cytochrome b558. Diebold and Bokoch35 propose a 2-step model (model C) for the regulation of NADPH oxidase by Rac. In step 1, Rac translocates to the membrane and interacts with the phospholipid bilayer via its prenylated/polybasic C-terminus. In addition, Rac, via its insert domain, interacts with cytochrome b558 and contributes to the regulation of electron flow from NADPH to FAD without interacting with p67phox. p67phox is still required for electron flow to occur in step1 and regulates electron flow via its activation domain. The interaction of the insert domain of Rac with cytochrome b558 may induce a conformational change in cytochrome b558 that modulates the interaction of p67phox and cytochrome b558. In step 2, the interaction between the switch I domain of Rac and the Rac-binding domain of p67phox, probably inducing a conformational change in p67phox, is required for electrons to continue to flow from FAD to the heme groups of cytochrome b558. (The step 1 reaction only is depicted in models A and B because this is thought to be the rate-limiting step in the overall electron transfer pathway to molecular oxygen. The step 2 reaction does take place in all 3 models depicted.) Portions of this figure have been used in Diebold and Bokoch.47

Comparison of proposed models of NADPH oxidase regulation by Rac GTPase.

In each of the proposed molecular models for NADPH oxidase regulation by Rac GTPase, the switch 1 region of Rac (not indicated) interacts with p67phox, the prenylated tail and polybasic domain of Rac (shown as a zigzag line) interact with the membrane, and the activation domain of p67phox (a crosshatched section) interacts with cytochrome b558. A role for p40phox remains unclear. In the model of Lambeth and colleagues (model A), Rac is thought to be recruited to the plasma membrane phospholipid bilayer via its prenylated C-terminus and polybasic domain. Indirect evidence supports the idea that the Rac insert domain (hatched section) may interact directly with cytochrome b558. Lambeth2 proposes the activation domain of p67phox is the sole regulator of the electron transfer step from NADPH to FAD. Rac and p47phox serve as adapters aiding in the interaction of p67phox with cytochrome b558. In model B proposed by Pick and colleagues,37,38 Rac is thought to interact only with plasma membrane phospholipids via its C-terminal prenyl group and polybasic domain and does not interact physically with cytochrome b558. In this model, the insert domain is not involved in protein interactions or regulation of the NADPH oxidase. As in the model of Lambeth and colleagues, p67phox is the sole regulator of electron transfer by cytochrome b558, while Rac and p47phox serve only as adapters to position p67phox for interaction with cytochrome b558. Diebold and Bokoch35 propose a 2-step model (model C) for the regulation of NADPH oxidase by Rac. In step 1, Rac translocates to the membrane and interacts with the phospholipid bilayer via its prenylated/polybasic C-terminus. In addition, Rac, via its insert domain, interacts with cytochrome b558 and contributes to the regulation of electron flow from NADPH to FAD without interacting with p67phox. p67phox is still required for electron flow to occur in step1 and regulates electron flow via its activation domain. The interaction of the insert domain of Rac with cytochrome b558 may induce a conformational change in cytochrome b558 that modulates the interaction of p67phox and cytochrome b558. In step 2, the interaction between the switch I domain of Rac and the Rac-binding domain of p67phox, probably inducing a conformational change in p67phox, is required for electrons to continue to flow from FAD to the heme groups of cytochrome b558. (The step 1 reaction only is depicted in models A and B because this is thought to be the rate-limiting step in the overall electron transfer pathway to molecular oxygen. The step 2 reaction does take place in all 3 models depicted.) Portions of this figure have been used in Diebold and Bokoch.47 

Close Modal
This Feature Is Available To Subscribers Only

or Create an Account

Close Modal
Close Modal