Abstract
BackgroundThe soluble guanylyl cyclase (sGC) is a heterodimeric enzyme that, upon activation by nitric oxide, stimulates the production of the second messenger cGMP. Each sGC subunit harbor four domains three of which are used for heterodimerization: H-NOXA/H-NOBA domain, coiled-coil domain (CC), and catalytic guanylyl cyclase domain. The CC domain has previously been postulated to be part of a larger CC family termed the signaling helix (S-helix) family. Homodimers of sGC have also been observed but are not functionally active yet are likely transient awaiting their intended heterodimeric partner.ResultsTo investigate the structure of the CC S-helix region, we crystallized and determined the structure of the CC domain of the sGCβ1 subunit comprising residues 348-409. The crystal structure was refined to 2.15 Å resolution.ConclusionsThe CC structure of sGCβ1 revealed a tetrameric arrangement comprised of a dimer of CC dimers. Each monomer is comprised of a long a-helix, a turn near residue P399, and a short second a-helix. The CC structure also offers insights as to how sGC homodimers are not as stable as (functionally) active heterodimers via a possible role for inter-helix salt-bridge formation. The structure also yielded insights into the residues involved in dimerization. In addition, the CC region is also known to harbor a number of congenital and man-made mutations in both membrane and soluble guanylyl cyclases and those function-affecting mutations have been mapped onto the CC structure. This mutant analysis indicated an importance for not only certain dimerization residue positions, but also an important role for other faces of the CC dimer which might perhaps interact with adjacent domains. Our results also extend beyond guanylyl cyclases as the CC structure is, to our knowledge, the first S-helix structure and serves as a model for all S-helix containing family members.
Highlights
The soluble guanylyl cyclase is a heterodimeric enzyme that, upon activation by nitric oxide, stimulates the production of the second messenger cGMP
Results sGCb1 coiled-coil domain (CC) construct form oligomers in solution The N- and C-terminal boundaries of the Rattus norvegicus soluble guanylyl cyclase (sGC) 348-409 CC domain were chosen such that it starts after the PAS-like/heme-nitric-oxide-and-oxygen binding associate domain (H-NOXA) domain and ends before the cyclase domain
CC domains are known for their oligomerization behavior and we analyzed the inter-molecule interactions within the asymmetric unit which indicated a dimeric arrangement of the CC sGCb1 subunits
Summary
The soluble guanylyl cyclase (sGC) is a heterodimeric enzyme that, upon activation by nitric oxide, stimulates the production of the second messenger cGMP. Mammalian guanylyl cyclases are key signaling proteins that produce the second messenger cGMP thereby regulating a variety of different processes such as vasodilation, diuresis, vision, and bone growth [1] These cyclases are either membrane bound or are found as soluble forms. Considerable progress has been made on the structural characterization of domains of the receptors, or homologs thereof These domains include the GC-A receptor hormone-binding domain [3], homologous catalytic guanylyl cyclase domains [4,5], and domains that are homologous to sGC: ligand binding heme-nitricoxide-and-oxygen binding domains (H-NOX or termed H-NOB) [6,7,8,9], and the H-NOXA/H-NOBA/PAS domain [6,10]. One of the guanylyl cyclase domains that has yet to be structurally characterized is the CC domain and that is the focus of this study
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