AI Article Synopsis
- sGC is a heme protein that converts GTP to cyclic GMP, which serves as a crucial second messenger in cellular signaling, with nitric oxide greatly enhancing its activity.
- Carbon monoxide and activators like YC-1 and BAY also boost sGC activity, but the exact mechanism of this activation is still debated.
- Research indicates that YC-1 and BAY bind to the alpha subunit of sGC, causing conformational changes that promote its catalytic function, as supported by docking studies.
Article Abstract
Soluble guanylate cyclase (sGC), a heterodimeric heme protein, catalyses the conversion of GTP in to cyclic GMP, which acts as a second messenger in cellular signaling. Nitric oxide activates this enzyme several hundred folds over its basal level. Carbon monoxide, along with some activator molecules like YC-1 and BAY, also synergistically activate sGC. Mechanism of this synergistic activation is a matter of debate. Here we review the existing literature to identify the possible binding site for YC-1 and BAY on bovine lung sGC and its mechanism of activation. These two exogenous compounds bind sGC on alpha subunit inside a pocket and thus exert allosteric effect via subunit interface, which is relayed to the catalytic site. We used docking studies to further validate this hypothesis. We propose that the binding of YC-1/BAY inside the sensory domain of the alpha subunit modulates the interactions on the subunit interface resulting in rearrangements in the catalytic site into active conformation and this partly induces the cleavage of Fe-His bond.
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| http://dx.doi.org/10.1016/j.bbrc.2010.05.122 | DOI Listing |
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