Structural and kinetic modeling of an activating helix switch in the rhodopsin-transducin interface

Scheerer, Patrick; Heck, M.; Goede, Andrean; Park, Jung Hee; Choe, Huhn; Ernst, Oliver P.; Hofmann, Klaus Peter; Hildebrand, Peter W.

doi:10.1073/pnas.0900072106

Cited by 49 publications

(54 citation statements)

References 53 publications

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“…IL2 of the receptor also collides with the ␣N-␤1 and ␣2-␤4 loops on the G␣ subunit. These collisions would be alleviated, at least in part, by rotation of the bulk of the heterotrimer with respect to the ␣C helix by ϳ60°(clockwise in this view), similar to that proposed previously (70). Collisions could also be avoided if the ␣C helix were kinked upon receptor binding, but current data suggest that an intact ␣C helix is required for functional receptor interactions (42,43).…”

Section: Structural Features Of Grks Responsible For Receptor Recognisupporting

confidence: 74%

Recognition in the Face of Diversity: Interactions of Heterotrimeric G proteins and G Protein-coupled Receptor (GPCR) Kinases with Activated GPCRs

Huang¹,

Tesmer

2011

Journal of Biological Chemistry

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Section: Structural Features Of Grks Responsible For Receptor Recognisupporting

confidence: 74%

Recognition in the Face of Diversity: Interactions of Heterotrimeric G proteins and G Protein-coupled Receptor (GPCR) Kinases with Activated GPCRs

Huang¹,

Tesmer

2011

Journal of Biological Chemistry

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“…The G αi C-terminal helix was fused with the highaffinity G α C-terminal peptide bound to opsin (for details, see SI Text and Figs. S5 and S6), which provided a convenient starting point for the model (19). The myristoylated N-terminal amphipathic helix was placed parallel to the membrane surface and the heterotrimer oriented such that both the myristoyl group and the nearby farnesylated C terminus of the Gγ-subunit can be inserted into the membrane; together these hydrophobic interactions cooperatively drive membrane binding of the intact heterotrimer (20).…”

Section: Resultsmentioning

confidence: 99%

Interaction of a G protein with an activated receptor opens the interdomain interface in the alpha subunit

Eps

Preininger

Alexander

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

147

149

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In G-protein signaling, an activated receptor catalyzes GDP/GTP exchange on the G α subunit of a heterotrimeric G protein. In an initial step, receptor interaction with G α acts to allosterically trigger GDP release from a binding site located between the nucleotide binding domain and a helical domain, but the molecular mechanism is unknown. In this study, site-directed spin labeling and double electron-electron resonance spectroscopy are employed to reveal a large-scale separation of the domains that provides a direct pathway for nucleotide escape. Cross-linking studies show that the domain separation is required for receptor enhancement of nucleotide exchange rates. The interdomain opening is coupled to receptor binding via the C-terminal helix of G α , the extension of which is a high-affinity receptor binding element.signal transduction | structural polymorphism T he α-subunit (G α ) of heterotrimeric G proteins (G αβγ ) mediates signal transduction in a variety of cell signaling pathways (1). Multiple conformational states of G α are involved in the signal transduction pathway shown in Fig. 1A. In the inactive state, the G α subunit contains a bound GDP [G α ðGDPÞ] and has a high affinity for G βγ . When activated by an appropriate signal, a membrane-bound G-protein coupled receptor (GPCR) binds the heterotrimer in a quaternary complex, leading to the dissociation of GDP and formation of an "empty complex" [G α ð0Þ βγ ], which subsequently binds GTP. The affinity of G α ðGTPÞ for G βγ is dramatically reduced relative to G α ðGDPÞ, resulting in functional dissociation of active G α ðGTPÞ from the membrane-bound complex. The active G α ðGTPÞ subsequently binds downstream effector proteins to trigger a variety of regulatory events, depending on the particular system. Thus, the GPCR acts to catalyze GDP/GTP exchange via an empty complex. Crystallographic (2-7), biochemical (8), and biophysical (9-11) studies have elucidated details of the conformational states of G α that correspond to the discrete steps indicated in Fig. 1A, but the mechanism by which receptor interaction leads to release of the bound GDP from G α and the structure of the empty complex remain a major target of research in the field.The G α subunit has two structural domains, namely a nucleotide binding domain and a helical domain that partially occludes the bound nucleotide (Fig. 1B). From the initial G α crystal structure in 1993, Noel et al. (2) recognized that nucleotide release would probably require an opening between the two domains in the empty complex, but in the intervening 18 years there has been little compelling experimental support for this idea. Nevertheless, some constraints on the general topology of the complex are known. For example, numerous studies indicate that the C terminus of G α is bound tightly to the receptor in the empty complex (9). In addition, the N-terminal helix of G α is associated with G βγ and with the membrane via N-terminal myristoylation (12,13). Together, these constraints fix the position of the nucleot...

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“…Correspondingly, activation is characterized by a spatial rearrangement of the TMHs relative to one another (Scheerer et al 2008, Schertler 2008. This structural rearrangement is supported by amino acids acting as 'micro-switches' (Ahuja & Smith 2009, Hofmann et al 2009, Nygaard et al 2009). …”

Section: How Do Gpcrs Function?mentioning

confidence: 99%

Oligomerization of GPCRs involved in endocrine regulation

Kleinau¹,

Müller²,

Biebermann³

2016

J Mol Endocrinol

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Structural and kinetic modeling of an activating helix switch in the rhodopsin-transducin interface

Cited by 49 publications

References 53 publications

Recognition in the Face of Diversity: Interactions of Heterotrimeric G proteins and G Protein-coupled Receptor (GPCR) Kinases with Activated GPCRs

Recognition in the Face of Diversity: Interactions of Heterotrimeric G proteins and G Protein-coupled Receptor (GPCR) Kinases with Activated GPCRs

Interaction of a G protein with an activated receptor opens the interdomain interface in the alpha subunit

Oligomerization of GPCRs involved in endocrine regulation

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