AGS3 Inhibits GDP Dissociation from Gα Subunits of the Gi Family and Rhodopsin-dependent Activation of Transducin

Natochin, Michael; Lester, Brad; Peterson, Yuri K.; Bernard, Michael L.; Lanier, Stephen M.; Artemyev, Nikolai O.

doi:10.1074/jbc.m006478200

Cited by 107 publications

(95 citation statements)

References 25 publications

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“…Signaling through the G␣ subunit and the G␤␥ complex of heterotrimeric G proteins is regulated predominately by the activation state of G␣; when G␣ is inactive, G␤␥ is inactive, because the inactive state of Gi␣ is stabilized by the G␤␥ complex (31). However, AGS3 can also stably maintain inactive Gi␣ (17,(32)(33)(34) and in this way can augment signaling through G␤␥ (15). Accordingly, the role of Gi␣ and G␤␥ (A) Virus expression of antisense was used to knock down AGS3 in the NAcore of 3-wk-EtOH-deprived rats (SC-AGS3: n ϭ 7; AS-AGS3: n ϭ 7) and in 24 h depr rats (SC-AGS3: n ϭ 6; AS-AGS3: n ϭ 6).…”

Section: Ags3 Knockdown Normalized Etoh-seeking To Pre-abstinence Levmentioning

confidence: 99%

Nucleus accumbens AGS3 expression drives ethanol seeking through Gβγ

Bowers

Hopf

Chou

et al. 2008

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

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Approximately 90% of alcoholics relapse within 4 years, in part because of an enhanced motivation to seek alcohol (EtOH). A novel G protein modulator (Gpsm1/AGS3) was up-regulated in the rat nucleus accumbens core (NAcore) but not in other limbic nuclei during abstinence from operant EtOH self-administration. Furthermore, NAcore AGS3 knockdown reduced EtOH seeking to preabstinence levels in a novel rat model of compulsive, human EtOH seeking. AGS3 can both inhibit G protein Gi␣-mediated signaling and stimulate G␤␥-mediated signaling. Accordingly, sequestration of G␤␥, but not Gi␣ knockdown, significantly reduced EtOH seeking to pre-abstinence levels. Thus, AGS3 and G␤␥ are hypothesized to gate the uncontrolled motivation to seek EtOH during abstinence. AGS3 up-regulation during abstinence may be a key determinant of the transition from social consumption to compulsionlike seeking during relapse.self-administration ͉ reinstatement ͉ alcohol deprivation effect ͉ Gi␣ ͉ G protein

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Section: Ags3 Knockdown Normalized Etoh-seeking To Pre-abstinence Levmentioning

confidence: 99%

Nucleus accumbens AGS3 expression drives ethanol seeking through Gβγ

Bowers

Hopf

Chou

et al. 2008

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

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“…The N-terminal part of AGS3 contains seven tetratricopeptide repeats [the TPR domain (2)], a mediator of protein-protein interaction, whereas the C-terminal part contains four G protein regulatory motifs [the GPR or GoLoco domain (3)], a modulator of G protein signaling. The GPR domain of AGS3 preferentially binds and stabilizes GDP-bound G␣i subunits (4)(5)(6). By acting as a GDP-dissociation inhibitor of the G␣i subunit, AGS3 blocks the reassociation of G␣i with the G␤␥ dimer, thus it inhibits the G␣i-dependent pathways but enhances the G␤␥-regulated signaling in a manner independent of receptor activation.…”

mentioning

confidence: 99%

A specific role of AGS3 in the surface expression of plasma membrane proteins

Groves

Gong

et al. 2007

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

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Activator of G protein signaling 3 (AGS3), originally identified in a functional screen for mammalian proteins that activate heterotrimeric G protein signaling, is known to be involved in drug-seeking behavior and is up-regulated during cocaine withdrawal in animal models. These observations indicate a potential role for AGS3 in the formation or maintenance of neural plasticity. We have found that the overexpression of AGS3 alters the surface-to-total ratios of a subset of heterologously expressed plasma membrane receptors and channels. Further analysis of the endocytic trafficking of one such protein by a biotin-based internalization assay suggests that overexpression of AGS3 moderately affects the internalization or recycling of surface proteins. Moreover, AGS3 overexpression and siRNA-mediated knockdown of AGS3 both result in the dispersal of two endogenously expressed trans-Golgi network (TGN)-associated cargo proteins without influencing those in the cis-or medial-Golgi compartments. Finally, adding a TGN-localization signal to a CD4-derived reporter renders the trafficking of fusion protein sensitive to AGS3. Taken together, our data support a model wherein AGS3 modulates the protein trafficking along the TGN/plasma membrane/endosome loop. drug addiction ͉ Golgi apparatus ͉ membrane trafficking ͉ receptors and channels

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“…1 AGS3 was identified as a receptor-independent activator of G-protein signaling in a yeastbased functional screen of mammalian cDNAs (2,3). AGS3-LONG is a 650-amino acid protein containing seven tetratricopeptide repeats and four G-protein regulatory (GPR) motifs that preferentially bind G␣ i (2,(7)(8)(9)(10)(11). The GPR motif is also found in Pcp2, G18.1b, LGN, and the GTPase-activating proteins RGS12, RGS14 (regulator of G-protein signaling), RAP1GAPI (partial GPR motif), and Rap1GAPII (3).…”

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confidence: 99%

AGS3 and Signal Integration by Gαs- and Gαi-coupled Receptors

Sato

Gettys

Lanier

2004

Journal of Biological Chemistry

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AGS3-LONG and AGS3-SHORT contain G-protein regulatory motifs that interact with and stabilize the GDPbound conformation of G␣ i > G␣ o . AGS3 and related proteins may influence signal strength or duration as well as the adaptation of the signaling system associated with sustained stimulation. To address these issues, we determined the effect of AGS3 on the integration of stimulatory (G␣ s -mediated vasoactive intestinal peptide receptor) and inhibitory (G␣ i -mediated ␣ 2 -adrenergic receptor (␣ 2 -AR)) signals to adenylyl cyclase in Chinese hamster ovary cells. AGS3-SHORT and AGS3-LONG did not alter the VIP-induced increase in cAMP or the inhibitory effect of ␣ 2 -AR activation. System adaptation was addressed by determining the influence of AGS3 on the sensitization of adenylyl cyclase that occurs following prolonged activation of a G␣ i -coupled receptor. Incubation of cells with the ␣ 2 -AR agonist UK14304 (1 M) for 18 h resulted in a ϳ1.8-fold increase in the vasoactive intestinal peptide-induced activation of adenylyl cyclase, and this was associated with a decrease in membrane-associated G␣ i3 . Both effects were blocked by AGS3-SHORT. AGS3-SHORT also decreased the rate of G␣ i3 decay. A mutant AGS3-SHORT incapable of binding G-protein was inactive. These data suggest that AGS3 and perhaps other G-protein regulatory motif-containing proteins increase the stability of G␣ i in the membrane, which influences the adaptation of the cell to prolonged activation of G␣ i -coupled receptors.The activation/deactivation cycle for heterotrimeric G-protein involves the exchange of GDP for GTP and the subsequent hydrolysis of GTP by G␣ subunits. These events are generally initiated by a G-protein-coupled receptor at the cell surface. However, increasing evidence indicates the existence of unexpected regulatory mechanisms for the G-protein activation/ deactivation cycle and a role for G-protein subunits in signaling events within the cell that do not involve a cell-surface receptor (1). These unexpected regulatory mechanisms include accessory proteins that accelerate GTPase activity, serve as novel binding partners for G␣ and G␤␥ subunits, and/or regulate guanine nucleotide exchange independent of a G-protein coupled receptor (1-6).

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AGS3 Inhibits GDP Dissociation from Gα Subunits of the Gi Family and Rhodopsin-dependent Activation of Transducin

Cited by 107 publications

References 25 publications

Nucleus accumbens AGS3 expression drives ethanol seeking through Gβγ

Nucleus accumbens AGS3 expression drives ethanol seeking through Gβγ

A specific role of AGS3 in the surface expression of plasma membrane proteins

AGS3 and Signal Integration by Gαs- and Gαi-coupled Receptors

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