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Genes Dev,
1999]
A wide variety of extracellular stimuli induce signal transduction through receptors coupled to heterotrimeric G proteins, which consist of alpha, beta, and gamma subunits (Gilman 1987). The G alpha subunit has guanine nucleotide binding and GTP hydrolysis activities. Based on function and amino acid sequence homology, the Galpha, G alph i/o, G alpha q, and G alpha 12 (Simon et al. 1991; Hepler and Gilman 1992). As exemplified by the responsiveness of our five senses to environmental stimuli, signaling mediated by trimeric G proteins is often extremely rapid and transient. A key step in achieving such a raid response is the ability of the G alpha subunit to switch between it GDP- and GTP-bound forms. The nucleotide binding state of G alpha is regulated at both the GDP dissociation and GTP hydrolysis steps. Stimulation of receptors by agonists leads to a conformational change in the receptors which can function as a guanine nucleotide exchange factor to stimulate a rapid dissociation of GDP from the inactive G alpha. The nucleotide-free G alpha is then available to bind GTP, leading to the dissociation of G alpha from the G beta gamma heterodimer. Both the G alpha and G beat gamma subunits can interact with and regulate downstream effectors that include adenylyl cyclase, phospholipase C, and ion channels (Gilman 1987; Birnbaumer 1992).
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[
WormBook,
2006]
Heterotrimeric G proteins, composed of alpha , beta , and gamma subunits, are able to transduce signals from membrane receptors to a wide variety of intracellular effectors. In this role, G proteins effectively function as dimers since the signal is communicated either by the G alpha subunit or the stable G betagamma complex. When inactive, G alpha -GDP associates with G betagamma and the cytoplasmic portion of the receptor. Ligand activation of the receptor stimulates an exchange of GTP for GDP resulting in the active signaling molecules G alpha -GTP and free G betagamma , either of which can interact with effectors. Hydrolysis of GTP restores G alpha -GDP, which then reassociates with G betagamma and receptor to terminate signaling. The rate of G protein activation can be enhanced by the guanine-nucleotide exchange factor, RIC-8 , while the rate of GTP hydrolysis can be enhanced by RGS proteins such as EGL-10 and EAT-16 . Evidence for a receptor-independent G-protein-signaling pathway has been demonstrated in C. elegans early embryogenesis. In this pathway, the G alpha subunits GOA-1 and GPA-16 are apparently activated by the non-transmembrane proteins GPR-1 , GPR-2 , and RIC-8 , and negatively regulated by RGS-7 . The C. elegans genome encodes 21 G alpha , 2 G beta and 2 G gamma subunits. The alpha subunits include one ortholog of each mammalian G alpha family: GSA-1 (Gs), GOA-1 (Gi/o), EGL-30 (Gq) and GPA-12 (G12). The remaining C. elegans alpha subunits ( GPA-1 , GPA-2 , GPA-3 , GPA-4 , GPA-5 , GPA-6 , GPA-7 , GPA-8 , GPA-9 , GPA-10 , GPA-11 , GPA-13 , GPA-14 , GPA-15 , GPA-16 , GPA-17 and ODR-3 ) are most similar to the Gi/o family, but do not share sufficient homology to allow classification. The conserved G alpha subunits, with the exception of GPA-12 , are expressed broadly while 14 of the new G alpha genes are expressed in subsets of chemosensory neurons. Consistent with their expression patterns, the conserved C. elegans alpha subunits, GSA-1 , GOA-1 and EGL-30 are involved in diverse and fundamental aspects of development and behavior. GOA-1 acts redundantly with GPA-16 in positioning of the mitotic spindle in early embryos. EGL-30 and GSA-1 are required for viability starting from the first larval stage. In addition to their roles in development and behaviors such as egg laying and locomotion, the EGL-30 , GSA-1 and GOA-1 pathways interact in a network to regulate acetylcholine release by the ventral cord motor neurons. EGL-30 provides the core signals for vesicle release, GOA-1 negatively regulates the EGL-30 pathway, and GSA-1 modulates this pathway, perhaps by providing positional cues. Constitutively activated GPA-12 affects pharyngeal pumping. The G alpha subunits unique to C. elegans are primarily involved in chemosensation. The G beta subunit, GPB-1 , as well as the G gamma subunit, GPC-2 , appear to function along with the alpha subunits in the classic G protein heterotrimer. The remaining G beta subunit, GPB-2 , is thought to regulate the function of certain RGS proteins, while the remaining G gamma subunit, GPC-1 , has a restricted role in chemosensation. The functional difference for most G protein pathways in C. elegans, therefore, resides in the alpha subunit. Many cells in C. elegans express multiple G alpha subunits, and multiple G protein pathways are known to function in specific cell types. For example, Go, Gq and Gs-mediated signaling occurs in the ventral cord motor neurons. Similarly, certain amphid neurons use multiple G protein pathways to both positively and negatively regulate chemosensation. C. elegans thus provides a powerful model for the study of interactions between and regulation of G protein signaling.
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Prog Mol Biol Transl Sci,
2009]
The nematode worm, Caenorhabditis elegans, contains orthologs of most regulator of G protein signaling (RGS) protein subfamilies and all four G protein -subunit subfamilies found in mammals. Every C. elegans RGS and G gene has been knocked out, and the in vivo functions and G targets of a number of RGS proteins have been characterized in detail. This has revealed a complex relationship between the RGS and G proteins, in which multiple RGS proteins can regulate the same G protein, either by acting redundantly or by exerting control over signaling under different circumstances or in different cells. RGS proteins that are coexpressed can also show specificity for distinct G targets in vivo, and the determinants of such specificity can reside outside of the RGS domain. This review will discuss how analysis in C. elegans may aid us in achieving a full understanding of the physiological functions of RGS proteins.
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Curr Biol,
1998]
In both vertebrates and invertebrates, olfactory perception is mediated by G-protein-coupled receptors. Recent work, in both mouse and Caenorhabditis elegans, sheds light on the role of specific G proteins in olfactory signal transduction, neuronal morphology and axon guidance.
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J Cell Biochem,
2012]
Signaling via heterotrimeric G-proteins is evoked by agonist-mediated stimulation of seven transmembrane spanning receptors (GPCRs). During the last decade it has become apparent that G subunits can be activated by receptor-independent mechanisms. Ric-8 belongs to a highly conserved protein family that regulates heterotrimeric G-protein function, acting as a non-canonical guanine nucleotide exchange factors (GEF) over a subset of G subunits. In this review we discuss the roles of Ric-8 in the regulation of diverse cell functions, emphasizing the contribution of its multiple domain protein structure in these diverse functions.
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J Dev Biol,
2018]
Many vital processes during C. elegans development, especially the establishment and maintenance of cell polarity in embryogenesis, are controlled by complex signaling pathways. G protein-coupled receptors (GPCRs), such as the four Frizzled family Wnt receptors, are linchpins in regulating and orchestrating several of these mechanisms. However, despite being GPCRs, which usually couple to G proteins, these receptors do not seem to activate classical heterotrimeric G protein-mediated signaling cascades. The view on signaling during embryogenesis is further complicated by the fact that heterotrimeric G proteins do play essential roles in cell polarity during embryogenesis, but their activity is modulated in a predominantly GPCR-independent manner via G protein regulators such as GEFs GAPs and GDIs. Further, the triggered downstream effectors are not typical. Only very few GPCR-dependent and G protein-mediated signaling pathways have been unambiguously defined in this context. This unusual and highly intriguing concept of separating GPCR function and G-protein activity, which is not restricted to embryogenesis in <i>C. elegans</i> but can also be found in other organisms, allows for essential and multi-faceted ways of regulating cellular communication and response. Although its relevance cannot be debated, its impact is still poorly discussed, and <i>C.</i><i>elegans</i> is an ideal model to understand the underlying principles.
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[
Exp Cell Res,
2014]
G4 DNA motifs, which can form stable secondary structures called G-quadruplexes, are ubiquitous in eukaryotic genomes, and have been shown to cause genomic instability. Specialized helicases that unwind G-quadruplexes in vitro have been identified, and they have been shown to prevent genetic instability in vivo. In the absence of these helicases, G-quadruplexes can persist and cause replication fork stalling and collapse. Translesion synthesis (TLS) and homologous recombination (HR) have been proposed to play a role in the repair of this damage, but recently it was found in the nematode Caenorhabditis elegans that G4-induced genome alterations are generated by an error-prone repair mechanism that is dependent on the A-family polymerase Theta (Pol ). Current data point towards a scenario where DNA replication blocked at G-quadruplexes causes DNA double strand breaks (DSBs), and where the choice of repair pathway that can act on these breaks dictates the nature of genomic alterations that are observed in various organisms.
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Curr Biol,
2000]
Recent studies have shed light on the role of G-protein signaling, and in particular the regulatory RGS proteins, in behavioral adaptations of the round worm Caenorhabditis elegans; similar signaling pathways underlie analogous physiology and behaviors in mammals.
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Front Endocrinol (Lausanne),
2020]
The <i>Caenorhabditis elegans</i> genome possesses homologs of about two-thirds of all human disease genes. Based on its physiological aging characteristics and superiority, the use of <i>C. elegans</i> as a model system for studies on aging, age-related diseases, mechanisms of longevity, and drug screening has been widely acknowledged in recent decades. Lifespan increasing mutations in <i>C. elegans</i> were found to delay aging by impinging several signaling pathways and related epigenetic modifications, including the insulin/IGF-1 signaling (IIS), AMP-activated protein kinase (AMPK), and mechanistic target of rapamycin (mTOR) pathways. Interestingly, dietary restriction (DR) has been shown to increase the lifespan of numerous metazoans and protect them from multiple age-related pathologies. However, the underlying molecular mechanisms are unclear. In recent decades, <i>C. elegans</i> has been used as a unique model system for high-throughput drug screening. Here, we review <i>C. elegans</i> mutants exhibiting increased in lifespan and age-dependent changes under DR, as well as the utility of <i>C. elegans</i> for drug screening. Thus, we provide evidence for the use of this model organism in research on the prevention of aging.
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Methods Enzymol,
2004]
Caenorhabditis elegans has close homologs or orthologs of most mammalian (RGS) and G proteins, and mutants for all the RGS and G-protein genes of C. elegans have been generated. C. elegans RGS proteins can be matched to the specific Galpha proteins they regulate in vivo by comparing the defects in animals lacking or transgenically overexpressing an RGS protein with defects in a specific Galpha mutant. Transgenic expression of mutated RGS proteins or subdomains in C. elegans has also been used to carry out structure?function studies of RGS proteins. We propose that similar strategies can be used to understand the function of RGS proteins from other organisms by expressing them in C. elegans. This article describes general considerations regarding such experiments and provides detailed protocols for quantitatively measuring G-protein signaling phenotypes in C. elegans.