Molecular chaperoning function of Ric-8 is to fold nascent heterotrimeric G protein α subunits

We have shown that resistance to inhibitors of cholinesterase 8 (Ric-8) proteins regulate an early step of heterotrimeric G protein α (Gα) subunit biosynthesis. Here, mammalian and plant cell-free translation systems were used to study Ric-8A action during Gα subunit translation and protein folding. Gα translation rates and overall produced protein amounts were equivalent in mock and Ric-8A-immunodepleted rabbit reticulocyte lysate (RRL). GDP-AlF4(-)-bound Gαi, Gαq, Gα13, and Gαs produced in mock-depleted RRL had characteristic resistance to limited trypsinolysis, showing that these G proteins were folded properly. Gαi, Gαq, and Gα13, but not Gαs produced from Ric-8A-depleted RRL were not protected from trypsinization and therefore not folded correctly. Addition of recombinant Ric-8A to the Ric-8A-depleted RRL enhanced GDP-AlF4(-)-bound Gα subunit trypsin protection. Dramatic results were obtained in wheat germ extract (WGE) that has no endogenous Ric-8 component. WGE-translated Gαq was gel filtered and found to be an aggregate. Ric-8A supplementation of WGE allowed production of Gαq that gel filtered as a ∼100 kDa Ric-8A:Gαq heterodimer. Addition of GTPγS to Ric-8A-supplemented WGE Gαq translation resulted in dissociation of the Ric-8A:Gαq heterodimer and production of functional Gαq-GTPγS monomer. Excess Gβγ supplementation of WGE did not support functional Gαq production. The molecular chaperoning function of Ric-8 is to participate in the folding of nascent G protein α subunits

Ric-8A catalyzes guanine nucleotide exchange on G alphai1 bound to the GPR/GoLoco exchange inhibitor AGS3

Microtubule pulling forces that govern mitotic spindle movement of chromosomes are tightly regulated by G-proteins. A host of proteins, including Galpha subunits, Ric-8, AGS3, regulators of G-protein signalings, and scaffolding proteins, coordinate this vital cellular process. Ric-8A, acting as a guanine nucleotide exchange factor, catalyzes the release of GDP from various Galpha.GDP subunits and forms a stable nucleotide-free Ric-8A:Galpha complex. AGS3, a guanine nucleotide dissociation inhibitor (GDI), binds and stabilizes Galpha subunits in their GDP-bound state. Because Ric-8A and AGS3 may recognize and compete for Galpha.GDP in this pathway, we probed the interactions of a truncated AGS3 (AGS3-C; containing only the residues responsible for GDI activity), with Ric-8A:Galpha(il) and that of Ric-8A with the AGS3-C:Galpha(il).GDP complex. Pulldown assays, gel filtration, isothermal titration calorimetry, and rapid mixing stopped-flow fluorescence spectroscopy indicate that Ric-8A catalyzes the rapid release of GDP from AGS3-C:Galpha(i1).GDP. Thus, Ric-8A forms a transient ternary complex with AGS3-C:Galpha(i1).GDP. Subsequent dissociation of AGS3-C and GDP from Galpha(i1) yields a stable nucleotide free Ric-8A.Galpha(i1) complex that, in the presence of GTP, dissociates to yield Ric-8A and Galpha(i1).GTP. AGS3-C does not induce dissociation of the Ric-8A.Galpha(i1) complex, even when present at very high concentrations. The action of Ric-8A on AGS3:Galpha(i1).GDP ensures unidirectional activation of Galpha subunits that cannot be reversed by AGS3

The Nucleotide Exchange Factor Ric-8A is a Chaperone for the Conformationally Dynamic Nucleotide-Free State of G Alpha I1

Heterotrimeric G protein alpha subunits are activated upon exchange of GDP for GTP at the nucleotide binding site of G alpha, catalyzed by guanine nucleotide exchange factors (GEFs). In addition to transmembrane G protein-coupled receptors (GPCRs), which act on G protein heterotrimers, members of the family cytosolic proteins typified by mammalian Ric-8A are GEFs for Gi/q/12/13-class G alpha subunits. Ric-8A binds to G alpha.GDP, resulting in the release of GDP. The Ric-8A complex with nucleotide-free G alpha i1 is stable, but dissociates upon binding of GTP to G alpha i1. To gain insight into the mechanism of Ric-8A-catalyzed GDP release from G alpha i1, experiments were conducted to characterize the physical state of nucleotide-free G alpha i1 (hereafter referred to as G alpha i1[]) in solution, both as a monomeric species, and in the complex with Ric-8A. We found that Ric-8A-bound, nucleotide-free G alpha i1 is more accessible to trypsinolysis than G alpha i1.GDP, but less so than G alpha i1[] alone. The TROSY-HSQC spectrum of [N-15]G alpha i1[] bound to Ric-8A shows considerable loss of peak intensity relative to that of [N-15]G alpha i1.GDP. Hydrogen-deuterium exchange in G alpha i1[] bound to Ric-8A is 1.5-fold more extensive than in G alpha i1.GDP. Differential scanning calorimetry shows that both Ric-8A and G alpha i1.GDP undergo cooperative, irreversible unfolding transitions at 47 degrees and 52 degrees, respectively, while nucleotide-free G alpha i1 shows a broad, weak transition near 35 degrees. The unfolding transition for Ric-8A: G alpha i1[] is complex, with a broad transition that peaks at 50 degrees, suggesting that both Ric-8A and G alpha i1[] are stabilized within the complex, relative to their respective free states. The C-terminus of G alpha i1 is shown to be a critical binding element for Ric-8A, as is also the case for GPCRs, suggesting that the two types of GEF might promote nucleotide exchange by similar mechanisms, by acting as chaperones for the unstable and dynamic nucleotide-free state of G alpha

Structure, Function, and Dynamics of the Gα Binding Domain of Ric-8A

Ric-8A is a 530-amino acid cytoplasmic molecular chaperone and guanine nucleotide exchange factor (GEF) for i, q, and 12/13 classes of heterortrimeric G protein alpha subunits (Gα). We report the 2.2-Å crystal structure of the Ric-8A Gα-binding domain with GEF activity, residues 1-452, and is phosphorylated at Ser435 and Thr440. Residues 1-429 adopt a superhelical fold comprised of Armadillo (ARM) and HEAT repeats, and the C terminus is disordered. One of the phosphorylated residues potentially binds to a basic cluster in an ARM motif. Amino acid sequence conservation and published hydrogen-deuterium exchange data indicate repeats 3 through 6 to be a putative Gα-binding surface. Normal mode modeling of small-angle X-ray scattering data indicates that phosphorylation induces relative rotation between repeats 1-4, 5-6, and 7-9. 2D H-N-TROSY spectra of [H,N]-labeled Gαi1 in the presence of R452 reveals chemical shift perturbations of the C terminus and Gαi1 residues involved in nucleotide binding

Protein kinase C ζ interacts with a novel binding region of Gαq to act as a functional effector

Heterotrimeric G proteins play an essential role in the initiation of G protein-coupled receptor (GPCR) signaling through specific interactions with a variety of cellular effectors. We have recently reported that GPCR activation promotes a direct interaction between Gαq and protein kinase C ζ (PKCζ), leading to the stimulation of the ERK5 pathway independent of the canonical effector PLCβ. We report herein that the activation-dependent Gαq/PKCζ complex involves the basic PB1-type II domain of PKCζ and a novel interaction module in Gαq different from the classical effector-binding site. Point mutations in this Gαq region completely abrogate ERK5 phosphorylation, indicating that Gαq/PKCζ association is required for the activation of the pathway. Indeed, PKCζ was demonstrated to directly bind ERK5 thus acting as a scaffold between Gαq and ERK5 upon GPCR activation. The inhibition of these protein complexes by G proteincoupled receptor kinase 2, a known Gαq modulator, led to a complete abrogation of ERK5 stimulation. Finally, we reveal thatGαq/ PKCζ complexes link Gαq to apoptotic cell death pathways. Our data suggest that the interaction between this novel region in Gαq and the effector PKCζ is a key event in Gαq signaling.Ministerio de Educación y Ciencia (SAF2011-23800, SAF2014-55511-R), Fundación Ramón Areces, The Cardiovascular Diseases Network of Ministerio Sanidad y Consumo-Instituto Carlos III (RD12/0042/0012), Comunidad de Madrid (S-2011/BMD-2332), and Instituto de Salud Carlos III (PI11/00126, PI14/00201) (to F. M. and C. R.). This work was also supported in part by the NIGMS, National Institutes of Health Grant R01-GM088242 (to G. T.), the Canadian Institutes of Health Research (CIHR) (MOP-GMX-231013) (to S. M.), an EMBO Short Fellowship (to G. S. F.), and Fondo Europeo de Desarrollo Regional (FEDER, European Union)Peer Reviewe

Structure of the G protein chaperone and guanine nucleotide exchange factor Ric-8A bound to Gαi1

Ric-8A is a cytosolic Guanine Nucleotide exchange Factor (GEF) that activates heterotrimeric G protein alpha subunits (Gα) and serves as an essential Gα chaperone. Mechanisms by which Ric-8A catalyzes these activities, which are stimulated by Casein Kinase II phosphorylation, are unknown. We report the structure of the nanobody-stabilized complex of nucleotide-free Gα bound to phosphorylated Ric-8A at near atomic resolution by cryo-electron microscopy and X-ray crystallography. The mechanism of Ric-8A GEF activity differs considerably from that employed by G protein-coupled receptors at the plasma membrane. Ric-8A engages a specific conformation of Gα at multiple interfaces to form a complex that is stabilized by phosphorylation within a Ric-8A segment that connects two Gα binding sites. The C-terminus of Gα is ejected from its beta sheet core, thereby dismantling the GDP binding site. Ric-8A binds to the exposed Gα beta sheet and switch II to stabilize the nucleotide-free state of Gα

Interdicting G q Activation in Airway Disease by Receptor-Dependent and Receptor-Independent Mechanisms

ABSTRACT Ga q bg heterotrimer (G q ), an important mediator in the pathology of airway disease, plays a central role in bronchoconstriction and airway remodeling, including airway smooth muscle growth and inflammation. Current therapeutic strategies to treat airway disease include the use of muscarinic and leukotriene receptor antagonists; however, these pharmaceuticals demonstrate a limited clinical efficacy as multiple G q -coupled receptor subtypes contribute to these pathologies. Thus, broadly inhibiting the activation of G q may be an advantageous therapeutic approach. Here, we investigated the effects of broadly inhibiting G q activation in vitro and ex vivo using receptor-dependent and receptor-independent strategies. P4pal-10 is a protease activated receptor 4-derived pepducin that exhibits efficacy toward multiple G q -coupled receptors. Mechanistic studies demonstrated that P4pal-10 selectively inhibits all G protein coupling to several G q -coupled receptors, including protease activated receptor 1, muscarinic acetylcholine M3, and histamine H1 receptors, while demonstrating no direct effect on G q . We also evaluated the ability of FR900359, also known as UBO-QIC, to directly inhibit G q activation. FR900359 inhibited spontaneous Ga q nucleotide exchange, while having little effect on Ga s bg, Ga i bg, or Ga 12/13 bg heterotrimer activity. Both P4pal-10 and FR900359 inhibited G qmediated intracellular signaling and primary human airway smooth muscle growth, whereas only FR900359 effectively interdicted agonist-promoted airway contraction in human precision cut lung slices. These studies serve as a proof of concept that the broad-based inhibition of G q activation may be a useful therapeutic approach to treat multiple common pathologies of airway disease

Genetic Determination and Linkage Mapping of Plasmodium falciparum Malaria Related Traits in Senegal

Plasmodium falciparum malaria episodes may vary considerably in their severity and clinical manifestations. There is good evidence that host genetic factors contribute to this variability. To date, most genetic studies aiming at the identification of these genes have used a case/control study design for severe malaria, exploring specific candidate genes. Here, we performed a family-based genetic study of falciparum malaria related phenotypes in two independent longitudinal survey cohorts, as a first step towards the identification of genes and mechanisms involved in the outcome of infection. We studied two Senegalese villages, Dielmo and Ndiop that differ in ethnicity, malaria transmission and endemicity. We performed genome-scan linkage analysis of several malaria-related phenotypes both during clinical attacks and asymptomatic infection. We show evidence for a strong genetic contribution to both the number of clinical falciparum malaria attacks and the asymptomatic parasite density. The asymptomatic parasite density showed linkage to chromosome 5q31 (LOD = 2.26, empirical p = 0.0014, Dielmo), confirming previous findings in other studies. Suggestive linkage values were also obtained at three additional chromosome regions: the number of clinical malaria attacks on chromosome 5p15 (LOD = 2.57, empirical p = 0.001, Dielmo) and 13q13 (LOD = 2.37, empirical p = 0.0014 Dielmo), and the maximum parasite density during asymptomatic infection on chromosome 12q21 (LOD = 3.1, empirical p<10−4, Ndiop). While regions of linkage show little overlap with genes known to be involved in severe malaria, the four regions appear to overlap with regions linked to asthma or atopy related traits, suggesting that common immune related pathways may be involved