Trio’s Rho-specific GEF domain is the missing Gα<sub>q</sub> effector in <i>C. elegans</i>

Williams, Stacey L.; Lutz, Susanne; Charlie, Nicole K.; Vettel, Christiane; Ailion, Michael; Coco, Cassandra; Tesmer, John J.G.; Jørgensen, Erik M.; Wieland, Thomas; Miller, Kenneth G.

doi:10.1101/gad.1592007

Cited by 83 publications

(156 citation statements)

References 69 publications

(106 reference statements)

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“…The C. elegans p38 MAPK module functions in the intestine for oxidative stress resistance (8) and immunity (28). In agreement with the reconstitution experiments, intestine-restricted knockdown of sek-1 by RNAi caused increased sensitivity to pathogens and arsenite (Table 1, rows [11][12][13][14][15][16][17][18][19][20]. Intestine-restricted egl-8 or egl-30 knockdown also resulted in increased sensitivity to pathogens and arsenite similar to egl-8 or egl-30 knockdown in the entire animal (Table 1, rows [11][12][13][14][15][16][17][18][19][20].…”

Section: Regulation Of Immunity and Oxidative Stress Resistance By Gqsupporting

confidence: 50%

“…egl-30 or egl-8 mutants have decreased DAG and decreased neuronal secretion (17). In addition to EGL-8, EGL-30 also signals independently through UNC-73 (Trio RhoGEF) to activate Rho signaling and influence growth, locomotion, and egg laying (18). Reduced neuronal signaling mediated by EGL-30 through activation of EGL-8 influences adult life span in an IISdependent manner (19).…”

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confidence: 99%

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Systemic and cell intrinsic roles of Gqα signaling in the regulation of innate immunity, oxidative stress, and longevity in Caenorhabditis elegans

Kawli

Wu²,

Tan³

2010

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

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Signal transduction pathways that regulate longevity, immunity, and stress resistance can profoundly affect organismal survival. We show that a signaling module formed by the G protein alpha subunit, Gqα, and one of its downstream signal transducer phospholipase C β (PLCβ) can differentially affect these processes. Loss of Gqα and PLCβ functions result in increased sensitivity to pathogens and oxidative stress but confer life span extension. Gqα and PLCβ modulate life span and immunity noncell autonomously by affecting the activity of insulin/IGF1 signaling (IIS). In addition, Gqα and PLCβ function cell autonomously within the intestine to affect the activity of the p38 MAPK pathway, an important component of Caenorhabditis elegans immune and oxidative stress response. p38 MAPK activity in the intestine is regulated by diacylglycerol levels, a product of PLCβ's hydrolytic activity. We provide genetic evidence that life span is largely determined by IIS, whereas p38 MAPK signaling is the primary regulator of oxidative stress in PLCβ mutants. Pathogen sensitivity of Gqα and PLCβ mutants is a summation of the beneficial effects of decreased IIS through reduced neuronal secretion and the detrimental effects of reduced activity of intestinal p38 MAPK. We propose a model whereby Gqα signaling differentially regulates pathogen sensitivity, oxidative stress, and longevity through cell autonomous and noncell autonomous effects on p38 MAPK and insulin/IGF1 signaling, respectively.insulin/IGF-1 signaling | p38 MAPK signaling | infection | aging A ppropriate responses to endogenous and exogenous threats at the organismal level are achieved by the coordination and integration of both cell-intrinsic and systemic signaling events. The conserved insulin/IGF1 signaling (IIS) pathway regulates life span, stress responses, and immunity. In Caenorhabditis elegans, activation of the insulin/IGF1-like receptor (IGFR) DAF-2 results in phosphorylation and retention of the forkhead transcription factor DAF-16 in the cytoplasm (1). Reduction in IGFR function results in increased life span and oxidative stress resistance in C. elegans (2, 3), Drosophila (4), and mice (5). Oxidative stress response is also regulated by the p38 MAPK cascade, which in C. elegans comprises of a three-tiered kinase cascade leading to phosphorylation by a MAPK kinase homolog SEK-1 and activation of the p38 MAPK homolog PMK-1 (6). Loss of either sek-1 or pmk-1 function results in increased sensitivity to oxidative stress (7). The p38 MAPK pathway affects oxidative stress resistance cell autonomously in part through regulation of the Nrf family transcription factor SKN-1 in the intestine (8, 9).IIS and p38 MAPK signaling contribute to C. elegans immunity. Diminished IIS confers pathogen resistance because of derepression of DAF-16 transcriptional activity and increased immuneeffector gene expression (10, 11), whereas diminished p38 MAPK signaling confers increased pathogen sensitivity (12); these pathways regulate distinct sets of immune-related genes (13-15). Re...

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Section: Regulation Of Immunity and Oxidative Stress Resistance By Gqsupporting

confidence: 50%

mentioning

confidence: 99%

Systemic and cell intrinsic roles of Gqα signaling in the regulation of innate immunity, oxidative stress, and longevity in Caenorhabditis elegans

Kawli

Wu²,

Tan³

2010

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

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“…egl-30(pe914) is a presumptive gain-offunction mutation because it caused hyperactive locomotion and constitutive egg-laying phenotypes (data not shown), which are typical phenotypes of egl-30(gf) alleles (Schade et al 2005;Williams et al 2007). pe914 is a missense mutation in linker I, a well-conserved domain of G q a across phylogeny ( Figure 4A).…”

Section: Resultsmentioning

confidence: 99%

“…Although activation of EGL-30 and addition of a DAG analog promote salt attraction, it is unknown whether EGL-30 is required for the production of DAG in ASER. GPA-12/G 12/13 a , RHO-1Rho (Mcmullan et al 2006), and UNC-73 Rho GEF (Williams et al 2007) also stimulate production of DAG. In motor neurons, EGL-30 activates phospholipase C-b EGL-8 phospholipase C-b, which results in production of DAG (Lackner et al 1999).…”

Section: Discussionmentioning

confidence: 99%

Reversal of Salt Preference Is Directed by the Insulin/PI3K and Gq/PKC Signaling inCaenorhabditis elegans

Adachi¹,

Kunitomo²,

Tomioka

et al. 2010

Genetics

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Animals search for foods and decide their behaviors according to previous experience. Caenorhabditis elegans detects chemicals with a limited number of sensory neurons, allowing us to dissect roles of each neuron for innate and learned behaviors. C. elegans is attracted to salt after exposure to the salt (NaCl) with food. In contrast, it learns to avoid the salt after exposure to the salt without food. In salt-attraction behavior, it is known that the ASE taste sensory neurons (ASEL and ASER) play a major role. However, little is known about mechanisms for learned salt avoidance. Here, through dissecting contributions of ASE neurons for salt chemotaxis, we show that both ASEL and ASER generate salt chemotaxis plasticity. In ASER, we have previously shown that the insulin/PI 3-kinase signaling acts for starvation-induced salt chemotaxis plasticity. This study shows that the PI 3-kinase signaling promotes aversive drive of ASER but not of ASEL. Furthermore, the G q signaling pathway composed of G q a EGL-30, diacylglycerol, and nPKC (novel protein kinase C) TTX-4 promotes attractive drive of ASER but not of ASEL. A putative salt receptor GCY-22 guanylyl cyclase is required in ASER for both salt attraction and avoidance. Our results suggest that ASEL and ASER use distinct molecular mechanisms to regulate salt chemotaxis plasticity.

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“…The live animal assays have been described in detail in previous studies: locomotion assays (Miller et al 1999;Reynolds et al 2005) and population growth rate assays (Williams et al 2007). …”

Section: Live Animal Assaysmentioning

confidence: 99%

An Organelle Gatekeeper Function forCaenorhabditis elegansUNC-16 (JIP3) at the Axon Initial Segment

et al. 2013

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Neurons must cope with extreme membrane trafficking demands to produce axons with organelle compositions that differ dramatically from those of the cell soma and dendrites; however, the mechanism by which they accomplish this is not understood. Here we use electron microscopy and quantitative imaging of tagged organelles to show that Caenorhabditis elegans axons lacking UNC-16 (JIP3/Sunday Driver) accumulate Golgi, endosomes, and lysosomes at levels up to 10-fold higher than wild type, while ER membranes are largely unaffected. Time lapse microscopy of tagged lysosomes in living animals and an analysis of lysosome distributions in various regions of unc-16 mutant axons revealed that UNC-16 inhibits organelles from escaping the axon initial segment (AIS) and moving to the distal synaptic part of the axon. Immunostaining of native UNC-16 in C. elegans neurons revealed a localized concentration of UNC-16 at the initial segment, although UNC-16 is also sparsely distributed in distal regions of axons, including the synaptic region. Organelles that escape the AIS in unc-16 mutants show bidirectional active transport within the axon commissure that occasionally deposits them in the synaptic region, where their mobility decreases and they accumulate. These results argue against the long-standing, untested hypothesis that JIP3/Sunday Driver promotes anterograde organelle transport in axons and instead suggest an organelle gatekeeper model in which UNC-16 (JIP3/Sunday Driver) selectively inhibits the escape of Golgi and endosomal organelles from the AIS. This is the first evidence for an organelle gatekeeper function at the AIS, which could provide a regulatory node for controlling axon organelle composition. NEURONS have a unique cell biology that presents daunting membrane trafficking challenges. For example, they must selectively transport two classes of regulated secretory vesicles (synaptic vesicles and dense core vesicles) long distances into axons, but only after the vesicles have completed their maturation process in the cell soma, during which they arise from, and interact with, other organelles in the soma. Neurons must also restrict, or even prevent, the flow of some organelles, such as Golgi, lysosomes, and endosomes, into the distal synaptic region of axons, which are relatively devoid of these organelles compared to cell somas.However, under special conditions, such as the need for axon repair or growth, neurons may require these organelles in axons. The potential hazards of excessive organelle transport into axons may include organelle traffic jams within narrow axons, reduced synaptic vesicle production as synaptic vesicle proteins are transported away from the cell soma before they are assembled into mature vesicles, and the disruption of membrane trafficking pathways in the synaptic region of axons caused by the inappropriate presence of cell soma organelles.A crucial regulatory domain for controlling axon composition is the region at or near the junction of the cell soma and axon, designated th...

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Trio’s Rho-specific GEF domain is the missing Gα_q effector in C. elegans

Cited by 83 publications

References 69 publications

Systemic and cell intrinsic roles of Gqα signaling in the regulation of innate immunity, oxidative stress, and longevity in Caenorhabditis elegans

Systemic and cell intrinsic roles of Gqα signaling in the regulation of innate immunity, oxidative stress, and longevity in Caenorhabditis elegans

Reversal of Salt Preference Is Directed by the Insulin/PI3K and Gq/PKC Signaling inCaenorhabditis elegans

An Organelle Gatekeeper Function forCaenorhabditis elegansUNC-16 (JIP3) at the Axon Initial Segment

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Trio’s Rho-specific GEF domain is the missing Gαq effector in C. elegans

Cited by 83 publications

References 69 publications

Systemic and cell intrinsic roles of Gqα signaling in the regulation of innate immunity, oxidative stress, and longevity in Caenorhabditis elegans

Systemic and cell intrinsic roles of Gqα signaling in the regulation of innate immunity, oxidative stress, and longevity in Caenorhabditis elegans

Reversal of Salt Preference Is Directed by the Insulin/PI3K and Gq/PKC Signaling inCaenorhabditis elegans

An Organelle Gatekeeper Function forCaenorhabditis elegansUNC-16 (JIP3) at the Axon Initial Segment

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Trio’s Rho-specific GEF domain is the missing Gα_q effector in C. elegans