2012
DOI: 10.1073/pnas.1202943109
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Differences in intradomain and interdomain motion confer distinct activation properties to structurally similar Gα proteins

Abstract: Proteins with similar crystal structures can have dissimilar rates of substrate binding and catalysis. Here we used molecular dynamics simulations and biochemical analysis to determine the role of intradomain and interdomain motions in conferring distinct activation rates to two Gα proteins, Gα i1 and GPA1. Despite high structural similarity, GPA1 can activate itself without a receptor, whereas Gα i1 cannot. We found that motions in these proteins vary greatly in type and frequency. Whereas motion is greatest … Show more

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Cited by 55 publications
(44 citation statements)
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“…More frequent RasD-HD domain separation has previously been suggested to underlie the self-activation of the G protein GPA1 from Arabidopsis thaliana (9). GPA1 is permanently activated, has enhanced nucleotide exchange rates, and displays enhanced domain opening in simulations relative to G␣ i .…”
Section: Discussionmentioning
confidence: 99%
See 1 more Smart Citation
“…More frequent RasD-HD domain separation has previously been suggested to underlie the self-activation of the G protein GPA1 from Arabidopsis thaliana (9). GPA1 is permanently activated, has enhanced nucleotide exchange rates, and displays enhanced domain opening in simulations relative to G␣ i .…”
Section: Discussionmentioning
confidence: 99%
“…This conformational change, which effectively exposes the otherwise buried nucleotide binding site, has been linked to GPCR-mediated nucleotide exchange (4). Evidence for domain opening has also been obtained from recent electron microscopy (5), double electron-electron resonance analysis (6), hydrogen-deuterium exchange mass spectrometry (7), biochemical analysis (8), and molecular dynamics (MD) simulations (3,9,10). In addition, the structure of Rasmussen and co-workers (7) together with mass spectrometry results also confirm that both N-terminal ␤1 strand and C-terminal ␣5 helix are major interaction sites for receptors.…”
Section: And Ref 3)mentioning
confidence: 99%
“…as a measure of dynamic motion, which is often linked to intrinsic domain motion. [57][58][59] As depicted in Supporting Fig. S8, the local per-residue flexibility is reduced upon δ-EVIA binding relative to the reference simulation with/without the toxin, especially in the linker region connecting the transmembrane segments of the voltage-sensor domain of Na V 1.7 and the toxin-sensitive chimera 4447.…”
Section: Accepted Manuscriptmentioning
confidence: 96%
“…The UD is adjacent to the A/B helix of the helical domain, a region whose dynamics were previously shown to promote the rapid, receptor-independent, nucleotide exchange activity of Arabidopsis thaliana G␣ (45). However, it is not known whether the UD regulates the enzymatic activity of S. cerevisiae Gpa1.…”
Section: Structural Contributions Of the Ubiquitination Domain Tomentioning
confidence: 99%
“…Functional Contributions of the Ubiquitination Domain to Gpa1 Activity-The ␣-helical domain is known to influence G protein nucleotide exchange activity (45). The UD is adjacent to the A/B helix of the helical domain, a region whose dynamics were previously shown to promote the rapid, receptor-independent, nucleotide exchange activity of Arabidopsis thaliana G␣ (45).…”
Section: Structural Contributions Of the Ubiquitination Domain Tomentioning
confidence: 99%