Brantley David Coleman scite author profile

Trimeric G protein signaling is a fundamental mechanism of cellular communication in eukaryotes. The core of this mechanism consists of activation of G proteins by the guanine-nucleotide exchange factor (GEF) activity of G protein coupled receptors. However, the duration and amplitude of G protein-mediated signaling are controlled by a complex network of accessory proteins that appeared and diversified during evolution. Among them, nonreceptor proteins with GEF activity are the least characterized. We recently found that proteins of the ccdc88 family possess a Gα-binding and activating (GBA) motif that confers GEF activity and regulates mammalian cell behavior. A sequence similarity-based search revealed that ccdc88 genes are highly conserved across metazoa but the GBA motif is absent in most invertebrates. This prompted us to investigate whether the GBA motif is present in other nonreceptor proteins in invertebrates. An unbiased bioinformatics search in Caenorhabditis elegans identified GBAS-1 (GBA and SPK domain containing-1) as a GBA motif-containing protein with homologs only in closely related worm species. We demonstrate that GBAS-1 has GEF activity for the nematode G protein GOA-1 and that the two proteins are coexpressed in many cells of living worms. Furthermore, we show that GBAS-1 can activate mammalian Gα-subunits and provide structural insights into the evolutionarily conserved determinants of the GBA–G protein interface. These results demonstrate that the GBA motif is a functional GEF module conserved among highly divergent proteins across evolution, indicating that the GBA-Gα binding mode is strongly constrained under selective pressure to mediate receptor-independent G protein activation in metazoans.

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Modulation of Gq-Rho Signaling by the ERK MAPK Pathway Controls Locomotion in Caenorhabditis elegans

Coleman¹,

Topalidou²,

Ailion

2018

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The heterotrimeric G protein Gq regulates neuronal activity through distinct downstream effector pathways. In addition to the canonical Gq effector phospholipase Cβ, the small GTPase Rho was recently identified as a conserved effector of Gq. To identify additional molecules important for Gq signaling in neurons, we performed a forward genetic screen in the nematode for suppressors of the hyperactivity and exaggerated waveform of an activated Gq mutant. We isolated two mutations affecting the MAP kinase scaffold protein KSR-1 and found that KSR-1 modulates locomotion downstream of, or in parallel to, the Gq-Rho pathway. Through epistasis experiments, we found that the core ERK MAPK cascade is required for Gq-Rho regulation of locomotion, but that the canonical ERK activator LET-60/Ras may not be required. Through neuron-specific rescue experiments, we found that the ERK pathway functions in head acetylcholine neurons to control Gq-dependent locomotion. Additionally, expression of activated LIN-45/Raf in head acetylcholine neurons is sufficient to cause an exaggerated waveform phenotype and hypersensitivity to the acetylcholinesterase inhibitor aldicarb, similar to an activated Gq mutant. Taken together, our results suggest that the ERK MAPK pathway modulates the output of Gq-Rho signaling to control locomotion behavior in.

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Identification of a novel activator of GOA‐1, a trimeric G protein critical for early stages of C. elegans development

2013

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Classical activation of trimeric G proteins occurs via guanine nucleotide exchange factor (GEF) activity of GPCRs. However, it has become recently evident that a set of non‐receptor proteins can also activate G proteins. Among these non‐receptor GEFs, GIV is the first one that activates G proteins via a defined motif, i.e., the Gα‐Binding and Activating (GBA) motif. We investigated if a similar GBA motif capable of activating G proteins is present in other unrelated proteins. Our bioinformatics searches revealed a putative GBA sequence in an uncharacterized protein highly expressed in early stages of C. elegans development. Here we demonstrate that this protein, that we call ceGBA, binds directly to GOA‐1, a G protein critical for C. elegans development. By using a combination of site directed‐mutagenesis, homology modeling and biochemistry we demonstrate that ceGBA utilizes its GBA motif to bind to the switch II/α3 helix hydrophobic pocket of inactive GOA‐1 and subsequently activates the G protein by accelerating the rate of nucleotide exchange. These results not only suggest a novel receptor‐independent mechanism of GOA‐1 activation during organismal development but also demonstrate that the GBA motif is a functional module for G protein activation conserved among divergent proteins across evolution.

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Evolutionarily Divergent Proteins Utilize the G(alpha)‐Binding and Activating Motif as a Conserved Module for Trimeric G Protein Activation

et al. 2015

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