Tonic and acute nitric oxide signaling through soluble guanylate cyclase is mediated by nonheme nitric oxide, ATP, and GTP

Abstract: Nitric oxide (NO) affects many physiological systems by activating cGMP signaling cascades through soluble guanylate cyclase (sGC). In the accepted model, NO binds to the sGC heme, activating the enzyme. Here, we report that in the presence of physiological concentrations of ATP and GTP, NO dissociation from the sGC heme is Ϸ160 times slower than the rate of enzyme deactivation in vitro. Deactivated sGC still has NO bound to the heme, and full activation requires additional NO. We propose an activation model w… Show more

“…When the activity was probed ϳ4 min after exposure to NO, the sGC-NO complex was only a few -fold more active than the resting sGC (Fig. 4), consistent with previous findings that stoichiometric NO does not lead to full activation of sGC (21,22,26). This low activity was not due to sGC protein aggregation during preincubation with NO.…”

“…S1). Previous reports demonstrated that sGC-NO complexes formed over several minutes with excess NO donor (21,26) or with stoichiometric NO donor in the presence of GTP (21,22) have the high cGMPforming activity expected from fully activated sGC. Our measurements corroborated these observations and demonstrated that high cGMP-forming activity was retained for up to 260 s after the sGC-NO complex was formed with excess NO gas or with stoichiometric NO in the presence of GTP (Fig.…”

“…Effect of the GTP Substrate on the Dynamics of sGC/NO Interaction-A number of reports have indicated that the GTP substrate affects the stability (21,25) of the 5C sGC-NO complex. Thus, we monitored the effect of GTP on the kinetics of the 5C sGC-NO complex generated with stoichiometric NO.…”

“…The reaction rates determined in these studies are shown in blue, the number in red is the theoretical estimation of the minimal reaction rate, and the numbers in black are from the literature: *, values from Refs. 21 bacterium Rhodospirillum rubrum is coordinated by Cys-75 in the ferric form, but, upon reduction to the ferrous form, His-77 becomes the ligand (38,39). Similarly, ligand switching was described for the bacterial phosphodiesterase EcDOS (40) and the transcriptional regulator RcoM-2 from the bacterium Burkholderia xenovorans (41).…”

“…Accumulating experimental evidence suggests that a number of environmental factors affect the dynamics of formation of the sGC-NO complex and its activity. Several studies reported that the sGC-NO complex formed with a stoichiometric amount of NO has a much lower cGMP-forming activity in comparison with sGC-NO formed with excess NO (21,22). It was also reported that if sGC reacts with stoichiometric NO in the presence of GTP, the high cGMP-forming activity is restored (22).…”

Dynamic Ligand Exchange in Soluble Guanylyl Cyclase (sGC)

“…When the activity was probed ϳ4 min after exposure to NO, the sGC-NO complex was only a few -fold more active than the resting sGC (Fig. 4), consistent with previous findings that stoichiometric NO does not lead to full activation of sGC (21,22,26). This low activity was not due to sGC protein aggregation during preincubation with NO.…”

“…S1). Previous reports demonstrated that sGC-NO complexes formed over several minutes with excess NO donor (21,26) or with stoichiometric NO donor in the presence of GTP (21,22) have the high cGMPforming activity expected from fully activated sGC. Our measurements corroborated these observations and demonstrated that high cGMP-forming activity was retained for up to 260 s after the sGC-NO complex was formed with excess NO gas or with stoichiometric NO in the presence of GTP (Fig.…”

“…Effect of the GTP Substrate on the Dynamics of sGC/NO Interaction-A number of reports have indicated that the GTP substrate affects the stability (21,25) of the 5C sGC-NO complex. Thus, we monitored the effect of GTP on the kinetics of the 5C sGC-NO complex generated with stoichiometric NO.…”

“…The reaction rates determined in these studies are shown in blue, the number in red is the theoretical estimation of the minimal reaction rate, and the numbers in black are from the literature: *, values from Refs. 21 bacterium Rhodospirillum rubrum is coordinated by Cys-75 in the ferric form, but, upon reduction to the ferrous form, His-77 becomes the ligand (38,39). Similarly, ligand switching was described for the bacterial phosphodiesterase EcDOS (40) and the transcriptional regulator RcoM-2 from the bacterium Burkholderia xenovorans (41).…”

“…Accumulating experimental evidence suggests that a number of environmental factors affect the dynamics of formation of the sGC-NO complex and its activity. Several studies reported that the sGC-NO complex formed with a stoichiometric amount of NO has a much lower cGMP-forming activity in comparison with sGC-NO formed with excess NO (21,22). It was also reported that if sGC reacts with stoichiometric NO in the presence of GTP, the high cGMP-forming activity is restored (22).…”

Dynamic Ligand Exchange in Soluble Guanylyl Cyclase (sGC)

Nitric Oxide: Biological Targets

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