Abstract

Soluble guanylate cyclase (sGC) is the target of nitric oxide (NO) released by nitric-oxide synthase in endothelial cells, inducing an increase of cGMP synthesis in response. This heterodimeric protein possesses a regulatory subunit carrying a heme where NO binding occurs, while the second subunit harbors the catalytic site. The binding of NO and the subsequent breaking of the bond between the proximal histidine and the heme-Fe(2+) are assumed to induce conformational changes, which are the origin of the catalytic activation. At the molecular level, the activation and deactivation mechanisms are unknown, as is the dynamics of NO once in the heme pocket. Using ultrafast time-resolved absorption spectroscopy, we measured the kinetics of NO rebinding to sGC after photodissociation. The main spectral transient in the Soret band does not match the equilibrium difference spectrum of NO-liganded minus unliganded sGC, and the geminate rebinding was found to be monoexponential and ultrafast (tau = 7.5 ps), with a relative amplitude close to unity (0.97). These characteristics, so far not observed in other hemoproteins, indicate that NO encounters a high energy barrier for escaping from the heme pocket once the His-Fe(2+) bond has been cleaved; this bond does not reform before NO recombination. The deactivation of isolated sGC cannot occur by only simple diffusion of NO from the heme; therefore, several allosteric states may be inferred, including a desensitized one, to induce NO release. Thus, besides the structural change leading to activation, a consequence of the decoupling of the proximal histidine may also be to induce a change of the heme pocket distal geometry, which raises the energy barrier for NO escape, optimizing the efficiency of NO trapping. The non-single exponential character of the NO picosecond rebinding coexists only with the presence of the protein structure surrounding the heme, and the single exponential rate observed in sGC is very likely to be due to a closed conformation of the heme pocket. Our results emphasize the physiological importance of NO geminate recombination in hemoproteins like nitric-oxide synthase and sGC and show that the protein structure controls NO dynamics in a manner adapted to their function. This control of ligand dynamics provides a regulation at molecular level in the function of these enzymes.

Highlights

  • Ways in which cGMP1 acts as a second messenger in several types of cells

  • Besides the structural change leading to activation, a consequence of the decoupling of the proximal histidine may be to induce a change of the heme pocket distal geometry, which raises the energy barrier for nitric oxide (NO) escape, optimizing the efficiency of NO trapping

  • Our results emphasize the physiological importance of NO geminate recombination in hemoproteins like nitric-oxide synthase and Soluble guanylate cyclase (sGC) and show that the protein structure controls NO dynamics in a manner adapted to their function

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Summary

Introduction

Ways in which cGMP1 acts as a second messenger in several types of cells (for reviews, see Refs. 1– 4). Upon binding of NO to the heme, the His–Fe2ϩ bond is cleaved, as reflected by the change in Soret absorption position, leading to a fivecoordinate Fe2ϩ with NO on the distal side This event is thought to trigger the structural changes that occur in the regulatory ␤-subunit and propagate through the interface between subunits and lead to the activated conformation of sGC. The control of NO dynamics in the vicinity of the heme, including binding and release, may be involved in the physiological regulation of sGC activity To investigate these points, we measured the kinetics of NO rebinding after photodissociation by using time-resolved absorption spectroscopy in the picosecond range. This allows the probing of the dynamics of NO when sGC is in the activated state

Results
Discussion
Conclusion

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