D. J. Black

Effects of Combined Phosphorylation at Ser-617 and Ser-1179 in Endothelial Nitric-oxide Synthase on EC50(Ca2+) Values for Calmodulin Binding and Enzyme Activation

We have investigated the possible biochemical basis for enhancements in NO production in endothelial cells that have been correlated with agonist- or shear stress-evoked phosphorylation at Ser-1179. We have found that a phosphomimetic substitution at Ser-1179 doubles maximal synthase activity, partially disinhibits cytochrome c reductase activity, and lowers the EC50(Ca2+) values for calmodulin binding and enzyme activation from the control values of 182 ± 2 and 422 ± 22 nm to 116 ± 2 and 300 ± 10 nm. These are similar to the effects of a phosphomimetic substitution at Ser-617 (Tran, Q. K., Leonard, J., Black, D. J., and Persechini, A. (2008) Biochemistry 47, 7557–7566). Although combining substitutions at Ser-617 and Ser-1179 has no additional effect on maximal synthase activity, cooperativity between the two substitutions completely disinhibits reductase activity and further reduces the EC50(Ca2+) values for calmodulin binding and enzyme activation to 77 ± 2 and 130 ± 5 nm. We have confirmed that specific Akt-catalyzed phosphorylation of Ser-617 and Ser-1179 and phosphomimetic substitutions at these positions have similar functional effects. Changes in the biochemical properties of eNOS produced by combined phosphorylation at Ser-617 and Ser-1179 are predicted to substantially increase synthase activity in cells at a typical basal free Ca2+ concentration of 50–100 nm.

Calmodulin-induced structural changes in endothelial nitric oxide synthase.

We have derived structures of intact calmodulin (CaM)‐free and CaM‐bound endothelial nitric oxide synthase (eNOS) by reconstruction from cryo‐electron micrographs. The CaM‐free reconstruction is well fitted by the oxygenase domain dimer, but the reductase domains are not visible, suggesting they are mobile and thus delocalized. Additional protein is visible in the CaM‐bound reconstruction, concentrated in volumes near two basic patches on each oxygenase domain. One of these corresponds with a presumptive docking site for the reductase domain FMN‐binding module. The other is proposed to correspond with a docking site for CaM. A model is suggested in which CaM binding and docking position the reductase domains near the oxygenase domains and promote docking of the FMN‐binding modules required for electron transfer.

Phosphorylation within an Autoinhibitory Domain in Endothelial Nitric Oxide Synthase Reduces the Ca2+ Concentrations Required for Calmodulin To Bind and Activate the Enzyme

We have investigated the effects of phosphorylation at Ser-617 and Ser-635 within an autoinhibitory domain (residues 595-639) in bovine endothelial nitric oxide synthase on enzyme activity and the Ca (2+) dependencies for calmodulin binding and enzyme activation. A phosphomimetic S617D substitution doubles the maximum calmodulin-dependent enzyme activity and decreases the EC 50(Ca (2+)) values for calmodulin binding and enzyme activation from the wild-type values of 180 +/- 2 and 397 +/- 23 nM to values of 109 +/- 2 and 258 +/- 11 nM, respectively. Deletion of the autoinhibitory domain also doubles the maximum calmodulin-dependent enzyme activity and decreases the EC 50(Ca (2+)) values for calmodulin binding and calmodulin-dependent enzyme activation to 65 +/- 4 and 118 +/- 4 nM, respectively. An S635D substitution has little or no effect on enzyme activity or EC 50(Ca (2+)) values, either alone or when combined with the S617D substitution. These results suggest that phosphorylation at Ser-617 partially reverses suppression by the autoinhibitory domain. Associated effects on the EC 50(Ca (2+)) values and maximum calmodulin-dependent enzyme activity are predicted to contribute equally to phosphorylation-dependent enhancement of NO production during a typical agonist-evoked Ca (2+) transient, while the reduction in EC 50(Ca (2+)) values is predicted to be the major contributor to enhancement at resting free Ca (2+) concentrations.

Fluorescence quenching studies of structure and dynamics in calmodulin–eNOS complexes

Activation of endothelial nitric oxide synthase (eNOS) by calmodulin (CaM) facilitates formation of a sequence of conformational states that is not well understood. Fluorescence decays of fluorescently labeled CaM bound to eNOS reveal four distinct conformational states and single‐molecule fluorescence trajectories show multiple fluorescence states with transitions between states occurring on time scales of milliseconds to seconds. A model is proposed relating fluorescence quenching states to enzyme conformations. Specifically, we propose that the most highly quenched state corresponds to CaM docked to an oxygenase domain of the enzyme. In single‐molecule trajectories, this state occurs with time lags consistent with the oxygenase activity of the enzyme.

Variations at the semiconserved glycine in the IQ domain consensus sequence have a major impact on Ca2+-dependent switching in calmodulin-IQ domain complexes.

We have replaced the semiconserved Gly in the IQ domain consensus sequence with Ala, Arg, or Met in a reference sequence and determined how this affects its complexes with calmodulin. The K(d) for the Ca(2+)-free reference complex is 2.4 +/- 0.3 microM. The Ala and Arg replacements increase this to 5.4 +/- 0.4 and 6.2 +/- 0.5 microM, while the Met increases it to 26.4 +/- 2.5 microM. When Ca(2+) is bound to both calmodulin lobes, the K(d) for the reference complex is not significantly affected, but the K(d) for the Ala variant decreases to 0.9 +/- 0.04 microM, and the values for the Arg and Met variants decrease to 0.4 +/- 0.03 microM. Using mutant calmodulins, we defined the effect of Ca(2+) binding to each lobe, with the C-terminal preceding the N-terminal (C-->N) or vice versa (N-->C). In the C-->N order the first step increases the reference K(d) approximately 5-fold, while it decreases the values for the variants approximately 2- to approximately 10-fold. The second step decreases the K(d) values for the all of the complexes approximately 5-fold, suggesting that the N-terminal lobe does not interact with the semiconserved position after the first step. In the N-->C order the first step increases the K(d) values for the reference complex and Met and Ala variants approximately 15- to approximately 200-fold but does not affect the value for the Arg variant. The second step decreases the K(d) values for the reference and Arg variant approximately 10- and approximately 15-fold and the Ala and Met variants approximately 2000-fold. Thus, both steps in the N-->C order are sensitive to variations at the semiconserved position, while only the first is in the C-->N order. Due to energy coupling, this order is followed under equilibrium conditions.