Abstract
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 Caenorhabditis elegans 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 acetylcholine neurons to control Gq-dependent locomotion. Additionally, expression of activated LIN-45/Raf in 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 C. elegans.
Introduction
The heterotrimeric G protein Gq is a conserved regulator of neurotransmission in metazoans. Gq is highly expressed in neurons in mammals and in the nematode C. elegans (Wilkie et al. 1991; Lackner et al. 1999). In its canonical signaling pathway, Gq activates phospholipase Cβ (PLCβ) to cleave the membrane lipid phosphatidylinositol 4,5-bisphosphate (PIP2) into inositol trisphosphate (IP3) and diacylglycerol (DAG) (Rhee 2001). An increased DAG concentration at the synapse helps trigger synaptic vesicle release (Miller et al. 1999; Lackner et al. 1999).
In addition to activating PLCβ, Gq directly binds and activates the Rho guanine nucleotide exchange factor (GEF) Trio, which in turn activates the small GTPase Rho (Lutz et al. 2005, 2007; Williams et al. 2007). In mature C. elegans neurons, the Rho ortholog RHO-1 regulates synaptic activity through multiple G protein-dependent mechanisms. First, RHO-1 acts downstream of the G12-class G protein GPA-12 by binding to and inhibiting the diacylglycerol kinase DGK-1. Inhibition of DGK-1 allows DAG to accumulate at the synapse, thereby increasing synaptic vesicle release (McMullan et al. 2006; Hiley et al. 2006). Second, Gq-Rho signaling promotes neurotransmitter release by recruiting the sphingosine kinase SPHK-1 to presynaptic terminals (Chan et al. 2012). Third, Gq-Rho signaling positively regulates the NCA-1/NALCN cation channel to regulate locomotion (Topalidou et al. 2017a). Here we identify the extracellular signal-related kinase mitogen-activated protein kinase (ERK MAPK) pathway as a positive regulator of neuronal activity acting downstream of or in parallel to Gq and Rho in acetylcholine neurons.
ERK MAPK signaling acts extensively in animal development, cellular proliferation, and cancer signaling (Yoon and Seger 2006; Karnoub and Weinberg 2008; Sun et al. 2015). ERKs are highly expressed in mammalian neurons (Boulton et al. 1991; Ortiz et al. 1995) and act in both the nucleus and at the synapse to regulate synaptic activity and plasticity (Thomas and Huganir 2004; Sweatt 2004; Mao and Wang 2016b). In C. elegans, the ERK pathway is required for multiple developmental events including specification of the vulva (Sternberg 2005; Sundaram 2013), and also acts in several types of neurons to control behavior. ERK signaling is activated in response to odorants in the AWC sensory neuron to regulate chemotaxis to volatile odorants and in AIY interneurons to mediate odor adaptation (Hirotsu et al. 2000; Hirotsu and Iino 2005; Chen et al. 2011; Uozumi et al. 2012). ERK is also activated in the ASER sensory neuron to regulate chemotaxis to salt (Tomioka et al. 2006; Tomida et al. 2012). ERK signaling regulates foraging behavior by acting in the IL1, OLQ, and RMD neurons (Hamakawa et al. 2015). Finally, the ERK pathway has been shown to act in interneurons to regulate the nose touch response, a mechanosensory behavior (Hyde et al. 2011).
In the canonical ERK MAPK pathway, extracellular ligand binding activates transmembrane receptor tyrosine kinases (RTKs), and adaptor proteins recruit a GEF to activate the small GTPase Ras (LET-60 in C. elegans). Upon Ras activation, LIN-45/Raf translocates to the plasma membrane where it interacts with Ras and the scaffold protein KSR-1. KSR-1 facilitates the activation of LIN-45/Raf and the subsequent phosphorylation of the MAPK cascade consisting of LIN-45/Raf, MEK-2/MEK, and MPK-1/ERK (Sundaram 2013). In this study, we found that the ERK MAPK pathway consisting of KSR-1, LIN-45/Raf, MEK-2/MEK and MPK-1/ERK modulates Gq-Rho signaling in acetylcholine neurons, but that surprisingly LET-60/Ras may not be required.
Materials and Methods
C. elegans strains
All strains were cultured using standard methods and were maintained at 20°C. Table S1 contains all the strains used in this study.
Isolation and mapping of the ksr-1(ox314) and ksr-1(yak10) mutations
The ox314 and yak10 mutants were isolated from an ENU mutagenesis suppressor screen of the activated Gq mutant egl-30(tg26) (Ailion et al. 2014). We mapped the ox314 mutation by its activated Gq suppression phenotype using single nucleotide polymorphisms (SNPs) in the Hawaiian strain CB4856 as described (Davis et al. 2005).The ox314 mutation was mapped to an approximately 709 kb region in the middle of the X chromosome between SNPs on cosmids F45E1 and F53A9 (SNPs F45E1[1] and pkP6158). This region included 159 predicted protein-coding genes. A complementation test of ox314 and yak10 in the egl-30(tg26) background showed these to be alleles of the same gene. Whole genome sequencing (see below) identified these as mutations in ksr-1, and we confirmed this by performing a complementation test with the deletion allele ksr-1(ok786).
Whole genome sequencing
Strains EG4198 egl-30(tg26); ox314 and XZ1340 egl-30(tg26); yak10 were sequenced to identify candidate mutations. DNA was purified according to the Hobert Lab protocol (http://hobertlab.org/whole-genome-sequencing/). Ion Torrent sequencing was performed at the University of Utah DNA Sequencing Core Facility. Each data set contained roughly 18,400,000 reads of a mean read length of 160 bases, resulting in about 30X average coverage of the C. elegans genome. The sequencing data were processed on the Galaxy server at usegalaxy.org (Afgan et al. 2016). SNPs and indels were identified and annotated using the Unified Genotyper and SnpEff tools (DePristo et al. 2011; Cingolani et al. 2012). After filtering for mutations in open reading frames, we found each strain to have unique stop mutations in ksr-1, in the middle of the interval where we mapped ox314. ox314 is a G to A transition that causes a stop codon at amino acid K463, and yak10 is an A to T transversion that causes a stop codon at W254.
Locomotion assays
Track waveform and radial locomotion assays were performed on 10 cm nematode growth medium (NGM) plates seeded with 400 μl of OP50 E. coli culture and spread with sterile glass beads. Bacterial lawns were grown at 37°C for 16 hrs and the plates were stored at 4°C until needed. For track waveform measurements, five first day adult animals were placed on a plate and allowed to roam for 2-5 min. We then recorded each animal’s tracks following forward locomotion. Track pictures were taken at 40X on a Nikon SMZ18 microscope with the DS-L3 camera control system. Pictures of worm tracks were processed using ImageJ. Period and 2X amplitude were measured freehand using the line tool. For each worm, we calculated the average period/amplitude ratio of five individual track bends (Figure 1C). For assays with the temperature sensitive allele sos-1(cs41), all strains were grown at 20°C and shifted to the non-permissive temperature of 25°C for 24 hours before being assayed. For radial locomotion assays, ten to fifteen first day adult animals were picked to the center of a plate and were then allowed to move freely for 40 minutes. The positions of worms were marked and the distances of the worms from the starting point were measured. For all waveform and radial locomotion assays, the experimenter was blind to the genotypes of the strains assayed.
Microscopy
Photographs of moving worms were taken at 60X on a Nikon SMZ18 microscope with the DS-L3 camera control system. The worms were age-matched as first day adults grown at 20°C.
Constructs and transgenes
Plasmids were constructed using the three-slot multisite Gateway cloning system (Invitrogen). Plasmids and primers used are found in Tables S2 and S3. The ksr-1 and lin-45 cDNAs were amplified by PCR from worm cDNA library and cloned into [1-2] Gateway entry vectors. Activating Raf mutations T626E/T629D were introduced into the lin-45 cDNA vector by two sequential site-directed mutagenesis reactions (Q5 kit, NEB) with primers oBC094/095 and oBC096/097, respectively, and then confirmed by sequencing. The ksr-1 and activated lin-45 cDNAs were cloned into expression constructs under different neuronal promoters using the multisite Gateway system. Proper expression of ksr-1 and activated lin-45 was confirmed by including an operon GFP⸬H2B in the [2-3] slot of the expression constructs. The operon GFP template tbb-2 3’utr⸬gpd-2 operon⸬GFP⸬H2B:cye-1 3’utr (Frøkjær-Jensen et al. 2012) results in untagged proteins whose expression can be monitored by GFP expression.
Injections and chromosomal integrations
Worms carrying the activated lin-45 transgenes Punc-17⸬lin-45* and Punc-17H⸬lin-45* as extrachromosomal arrays were generated by injecting pBC37 or pBC44 at 20 ng/μL or 10 ng/ μL respectively along with co-injection markers pCFJ104 (Pmyo-3⸬mCherry) at 5 ng/μL, pCFJ90 (Pmyo-2⸬mCherry) at 2.5 ng/μL, and the carrier DNA Litmus 38i to a final concentration of 100 ng/μL DNA (Mello et al. 1991). MosSCI lines were generated as described (Frøkjær-Jensen et al. 2012) using an injection mix containing 10-15 ng/μL targeting vector, 50 ng/μL pCFJ601 (Peft-3⸬Mos1 transposase), negative selection markers pGH8 (Prab-3⸬mCherry) at 10 ng/μL, pCFJ104 (Pmyo-3⸬mCherry) at 5 ng/μL, pCFJ90 (Pmyo-2⸬mCherry) at 2.5 ng/μL, pMA122 (Phsp16.41⸬peel-1) at 10 ng/μL, and carrier DNA Litmus 38i to a final concentration of 100 ng/μL DNA.
Extrachromosomal arrays were integrated into the genome by exposure to 4000 rads of gamma irradiation. Irradiated young adult hermaphrodites were transferred to 10 cm OP50 plates (5 worms/plate) and grown to starvation. The plates were chunked and grown to starvation twice more to enrich for stably expressing lines. When nearly starved, 8 animals per plate were picked to individual plates. The progeny were then screened for 100% stable transmission, indicating integration into the genome. Integration was confirmed by mapping the transgene to a chromosome.
Aldicarb assays
35 mm aldicarb assay plates were poured with NGM supplemented with 1 mM aldicarb. The plates were seeded with 5 uL OP50 and dried at room temperature overnight. Animals were picked onto the OP50 lawn to begin the assay (time 0) and then kept at room temperature. Every 15 minutes, animals were scored for paralysis by lightly touching the nose of the animal with an eyebrow hair. Animals were scored as paralyzed if the worm displayed no locomotor response to three nose touches and had no pharyngeal pumping. Animals that left the OP50 lawn were picked back onto the food.
Statistical analysis
P values were determined using GraphPad Prism 5. Normally distributed data sets were analyzed with a one-way ANOVA and Bonferroni’s post hoc test when group size was unequal, or with Tukey’s post hoc test when group size was equal. Data sets with non-normal distribution (using the Shapiro-Wilk normality test) were analyzed with a Kruskal-Wallis test and Dunn’s post hoc test. Data sets with multiple independent variables were analyzed by two-way ANOVA and Bonferroni’s post hoc test.
Reagent and data availability
Strains and plasmids are listed in Tables S1 and S2 and are available upon request. Primers are listed in Table S3. The authors state that all data necessary for confirming the conclusions presented in the article are represented fully within the article and Supplemental Material.
Results
KSR-1 regulates locomotion downstream of Gq
In C. elegans, the heterotrimeric G protein Gq regulates synaptic vesicle release (Hu et al. 2015). Gq is a key regulator of neuromuscular activity, as loss-of-function mutants in egl-30 are nearly paralyzed (Brundage et al. 1996) whereas the gain-of-function mutant egl-30(tg26) has hyperactive locomotion with an exaggerated loopy waveform (Doi and Iwasaki 2002; Bastiani et al. 2003) (Figure 1A, C, D). To identify pathways required for Gq signaling, we performed a forward genetic screen in C. elegans for suppressors of the activated Gq mutant egl-30(tg26). Two suppressors identified in this screen, ox314 and yak10, showed similar suppression of the loopy waveform and hyperactivity of egl-30(tg26) animals (Figure 1D). When crossed away from the egl-30(tg26) background, both mutants moved with wild-type waveform (Figure 1D), but at a slightly slower rate. We mapped the ox314 allele near the center of the X chromosome (see Materials and Methods), and a complementation test showed that ox314 and yak10 are mutations in the same gene since they fail to complement in an egl-30(tg26) background.
We used whole genome sequencing to identify ox314 and yak10 as nonsense mutations in ksr-1 (Figure 1B, see Materials and Methods). KSR-1 is a scaffold protein that facilitates the localization and interactions required for the Ras-mitogen activated protein kinase (MAPK) cascade consisting of Raf, MEK and ERK (Kornfeld et al. 1995b; Sundaram and Han 1995; Nguyen et al. 2002; Zhang et al. 2013). The deletion allele ksr-1(ok786) also suppressed the loopy waveform of the activated Gq mutant identically which is funded by the NIH Office ofto ox314 and yak10. These results suggest that KSR-1 activity is required for regulation of locomotion rate and waveform by Gq.
The ERK MAPK cascade acts to promote Gq signaling
Because the loss of the MAPK scaffold ksr-1 suppresses the activated Gq mutant egl-30(tg26), we asked whether other components of the Ras-ERK pathway would also suppress. Since the core components of the Ras-ERK pathway are required for viability, we built double mutants of activated Gq with reduction-of-function mutations in genes at each step of the ERK cascade. Mutations in Raf (lin-45(sy96)), MEK (mek-2(n1989), mek-2(ku114)), and ERK (mpk-1(ga117), mpk-1(oz140)) all suppressed the loopy waveform of activated Gq animals similarly to ksr-1(ok786) (Figure 2A,B; Figure S1A,B). However, mutations in Ras (let-60(n2021)) and the upstream pathway activators EGF (lin-3(e1417)) and the EGFR (let-23(sy12)) did not suppress activated Gq (Figure 2C). Because let-60 is required for viability, most let-60 alleles including n2021 are partial loss-of-function (Beitel et al. 1990). We also analyzed the dominant negative D119N allele let-60(sy93) that disrupts Ras binding to guanine nucleotides and thus prevents Ras activation (Han and Sternberg 1991). We found that let-60(sy93) also did not suppress the loopy waveform of activated Gq (Figure 2D), supporting the possibility that ERK activation occurs through a Ras-independent mechanism.
Because partial loss-of-function mutations in the ERK MAPK pathway genes downstream of Ras showed clear suppression of activated Gq, we were surprised to find that partial loss-of-function mutations in Ras did not suppress. If LET-60/Ras is indeed not required, Gq might instead activate the ERK pathway via other Ras-subfamily proteins. To test this possibility, we made double mutants of activated Gq with putative null alleles of R-Ras/ras-1, M-Ras/ras-2, and Rap1/rap-1 and found that they also did not suppress activated Gq (Figure S2A). To further investigate whether this pathway acts independently of Ras, we tested mutations in GEFs that activate Ras. The temperature-sensitive RasGEF mutant sos-1(cs41) did not suppress activated Gq when shifted to the non-permissive temperature (Figure S2B). Additionally, a null mutation in the neuronal RasGEF rgef-1 also did not suppress activated Gq locomotion (Figure S2C), supporting the possibility that this pathway is Ras-independent. In genetic screens for vulval induction mutants, additional factors such as the PP2A subunit sur-6 (Sieburth et al. 1999) and ion transporter sur-7 (Yoder et al. 2004) were identified as positive regulators of Ras-ERK activity. However, the sur-6(sv30) and sur-7(ku119) mutations did not suppress activated Gq locomotion (data not shown). These data suggest either that only a low level of Ras activity is needed to properly activate ERK signaling downstream of Gq, or that ERK signaling acts independently of LET-60/Ras and other known C. elegans Ras family proteins to regulate locomotion downstream of Gq.
KSR-1 and the ERK MAPK cascade modulate Rho signaling
Three classes of suppressor mutations were isolated in our forward genetic screen of activated Gq, as characterized by their molecular role and unique suppression phenotypes (Topalidou et al. 2017a; b). We grouped together a class of suppressor mutations including ox314, yak10, and the RhoGEF Trio (unc-73 in C. elegans) by their characteristic strong suppression of the loopy waveform of activated Gq (Topalidou et al. 2017a; b), suggesting that ksr-1 might act in the same pathway as unc-73.
We have shown that Gq regulates locomotion via the small GTPase Rho (RHO-1 in C. elegans) (Topalidou et al. 2017a). Transgenic expression of an activated RHO-1 mutant (G14V) in acetylcholine neurons (here called “rho-1(gf)”) causes worms to have a loopy waveform and impaired locomotion (McMullan et al. 2006) (Figure 3A). To examine whether ksr-1 acts in the Gq-Rho pathway we tested whether mutations in ksr-1 suppress the phenotypes of rho-1(gf) worms. We found that the ksr-1 alleles ok786, ox314, and yak10 all suppressed the loopy waveform of rho-1(gf) worms (Figure 3A). Because rho-1(gf) worms have a slow locomotion rate and loopy waveform, these mutants do not efficiently travel long distances. We used radial locomotion assays (see Materials and Methods) to quantify the locomotion phenotype of rho-1(gf) worms. rho-1(gf) ksr-1 double mutants had an increased radial distance traveled compared to rho-1(gf) alone (Figure 3B). These data suggest that KSR-1 acts downstream of or in parallel to the Gq-Rho pathway to regulate locomotion.
Since ksr-1 mutants suppress the exaggerated waveform of both activated Gq and activated Rho animals, we expected that loss of other ERK pathway components would also suppress activated Rho. We made double mutants of activated Rho (rho-1(gf)) with reduction-of-function alleles of the Ras-ERK pathway and found that mutations in Raf, MEK, and ERK suppressed the rho-1(gf) loopy waveform and decreased locomotion phenotypes (Figure 3A,C). However, the let-60(n2021) Ras mutation did not suppress the loopy waveform or radial locomotion defect of rho-1(gf) worms (Figure 3A,C). These data suggest that the ERK pathway acts downstream of or in parallel to the Gq-Rho pathway to regulate locomotion, possibly in a Ras-independent manner.
The ERK MAPK cascade acts in acetylcholine neurons to control locomotion
Members of the ERK pathway are expressed in neurons in C. elegans (Dent and Han 1998; Hunt-Newbury et al. 2007), and Gq and Rho act in acetylcholine neurons to promote synaptic release and regulate locomotion(Lackner et al. 1999; McMullan et al. 2006) To determine whether the ERK pathway also acts in neurons to modulate Gq signaling, we expressed the ksr-1 cDNA under promoters driving expression in specific types of neurons. Single-copy transgenic expression of ksr-1 under an acetylcholine neuron promoter (Punc-17) or under a head acetylcholine neuron promoter (Punc-17H) fully reversed the ksr-1 suppression of the loopy waveform of activated Gq worms (Figure 4). ksr-1 expression in ventral cord acetylcholine motor neurons (Punc-17β) or GABA neurons (Punc-47) did not significantly reverse the ksr-1 suppression of activated Gq (Figure 4). This suggests that ERK signaling primarily functions in the acetylcholine interneurons or motor neurons of the head to modulate Gq-dependent locomotion.
We have shown that the ERK pathway is necessary for Gq-dependent effects on locomotion. To determine whether ERK signaling is sufficient to modulate locomotion, we expressed an activated form of lin-45/Raf specifically in acetylcholine neurons. Raf kinase activity is regulated via conserved phosphorylation events, and phosphomimetic mutations T626E/T629D in the kinase activation loop of lin-45 are sufficient to confer constitutive Raf activity (Chong et al. 2001). We found that expression of activated Raf in acetylcholine neurons (Punc-17) causes a loopy waveform similar to activated Gq and Rho mutants and similar limited dispersal in radial locomotion assays (Figure 5A, B).
To determine if Raf activation affects acetylcholine release, we assayed for sensitivity to the acetylcholinesterase inhibitor aldicarb. Mutants with reduced acetylcholine secretion are resistant to aldicarb, whereas mutants with increased acetylcholine secretion are hypersensitive to aldicarb (Mahoney et al. 2006). Activated Gq and Rho mutants have increased rates of paralysis when exposed to aldicarb (Lackner et al. 1999; McMullan et al. 2006). We found that expression of activated Raf in acetylcholine neurons also led to aldicarb hypersensitivity, similar to activated Gq and Rho mutants (Figure 5C). However, we found that a ksr-1 mutation does not suppress the aldicarb hypersensitivity of an activated Gq mutant, and the ksr-1 mutant on its own has similar aldicarb sensitivity to wild type (Figure 5D). These results suggest that the ERK pathway is not necessary for synaptic transmission, but is sufficient to stimulate synaptic transmission when constitutively activated.
Discussion
In this study we identified KSR-1 and the ERK MAPK cascade as downstream modulators of Gq-Rho signaling. We found that ERK signaling acts in the acetylcholine interneurons or motor neurons of the head to modulate Gq-dependent locomotion. We also found that activation of the MAPKKK Raf/LIN-45 in acetylcholine neurons causes increased sensitivity to the acetylcholinesterase inhibitor aldicarb, probably reflecting increased release of acetylcholine at neuromuscular synapses. Our data support the model that Gq-Rho activation of the ERK pathway may be independent of its canonical regulator, the small GTPase Ras/LET-60 (Figure 6).
The ERK signaling cascade has been well-studied for its regulation of cellular proliferation and differentiation (Sun et al. 2015), but also plays important roles in mature neurons and has been associated with synaptic plasticity and memory (Impey et al. 1999). In addition to activating transcription, ERKs regulate synaptic plasticity both presynaptically and postsynaptically by phosphorylating relevant substrates. ERKs phosphorylate the presynaptic proteins synapsin I and Munc18-1, and postsynaptic proteins such as scaffolds, Kv4.2 potassium channels, and Group I metabotropic glutamate receptors (Jovanovic et al. 2000; Thomas and Huganir 2004; Sweatt 2004; Kushner et al. 2005; Boggio et al. 2007; Vara et al. 2009; Mao and Wang 2016a; Schmitz et al. 2016). Our findings suggest that the ERK pathway controls Gq-dependent locomotion in C. elegans and that activated ERK promotes synaptic transmission.
In contrast to many developmental and neuronal roles of Ras-dependent ERK signaling in C. elegans, our data suggest that Raf-MEK-ERK signaling may modulate Gq-Rho output independently of Ras/LET-60. One caveat to the conclusion that the ERK pathway acts independently of Ras to control Gq-dependent locomotion is that the alleles of let-60/Ras tested here are not null (Han and Sternberg 1990, 1991; Han et al. 1990; Beitel et al. 1990). However, other than mpk-1(ga117), the alleles we used of lin-45, mek-2 and mpk-1 are also not null (Han et al. 1993; Kornfeld et al. 1995a; Wu et al. 1995; Lackner and Kim 1998; Hsu et al. 2002), yet were able to suppress an activated Gq mutant. Furthermore, the let-60/Ras alleles used here have stronger phenotypes in vulval development than the two weak mek-2/MEK alleles we used (n1989 and ku114) (Beitel et al. 1990; Kornfeld et al. 1995a; Wu et al. 1995) and the let-60(n2021)/Ras mutant has comparable phenotypes to the lin-45(sy96)/Raf and mpk-1(ga117)/ERK alleles for chemotaxis to odorants and the regulation of foraging behavior (Hirotsu et al. 2000; Hamakawa et al. 2015). Thus, either LET-60/Ras is not required to modulate Gq signaling, or ERK signaling in the locomotor circuit requires a lower threshold of Ras activity and the let-60 mutants we used have sufficient levels of active Ras to modulate Gq signaling, but not enough for vulval induction or other behaviors.
If Ras is not required, how instead might KSR-Raf-MEK-ERK signaling be activated? Normally, active Ras recruits Raf to the plasma membrane but it has been shown that artificial recruitment of Raf to the plasma membrane in the absence of Ras is sufficient to activate Raf signaling (Stokoe et al. 1994; Marais et al. 1995). Thus, another possible way to activate the ERK pathway would be for Raf to be recruited to the membrane by proteins other than Ras. The most obvious candidates for recruiting Raf are other members of the Ras family such as Rap1 or R-Ras that have a conserved effector-binding domain (Reiner and Lundquist 2016); it has been reported that Rap1 can mediate Ras-independent activation of Raf downstream of a Gq-coupled receptor (Guo et al. 2001). However, mutations in the worm orthologs of Rap1/RAP-1 and R-Ras/RAS-1 did not suppress the activated Gq mutant, indicating that these Ras-like proteins are not required, at least individually, to activate Raf in this pathway. It is possible that more than one of these Ras family members function redundantly to activate Raf, or that Raf is activated completely independently of Ras family proteins. There have been other reported cases of Ras-independent activation of the Raf-MEK-ERK pathway (Robbins et al. 1992; Honda et al. 1994; van Biesen et al. 1996; Ueda et al. 1996; Drosten et al. 2014), some of which involve G protein signaling and protein kinase C, though the precise mechanisms involved are unclear.
Gq, Rho, and ERK are also required for the C. elegans behavioral and immune response to infection by the bacterium M. nematophilum (Nicholas and Hodgkin 2004; McMullan et al. 2012). Interestingly, LET-60/Ras was reported to not be required for the immune response (Nicholas and Hodgkin 2004) or only partially required (McMullan et al. 2012). Additionally, LET-60/Ras was not required for the increased sensitivity to aldicarb caused by infection (McMullan et al. 2012), at least as assayed using the let-60(n2021) allele. Thus, the same neuronal Ras-independent ERK pathway we describe here appears to also modulate Gq signaling in the neuronal response to bacterial infection and possibly the innate immune response as well.
Our epistasis analysis suggests that ERK signaling acts genetically downstream of or in parallel to Gq-Rho signaling. How might Gq-Rho signaling lead to ERK activation? ERK activation could occur via a linear pathway downstream of Gq and Rho, or ERK could signal in parallel and converge downstream of Rho to affect neuronal activity (Figure 6). There is precedence for Gq activating ERK via a linear pathway. In the pharyngeal muscle of C. elegans, ERK activity is increased by Gq-dependent signaling through protein kinase C (You et al. 2006). In the AWC olfactory neuron, ERK activity is increased downstream of Gq signaling via the RasGEF RGEF-1 (Chen et al. 2011; Uozumi et al. 2012). Protein kinase C and RGEF-1 are both activated by DAG, probably produced by the canonical Gq-PLCβ pathway. By contrast, we found that ERK signaling regulates locomotion by modulating the output of the Gq-Rho pathway that acts in parallel to Gq-PLCβ, and does not depend on RGEF-1.
How might the ERK pathway modulate neuronal activity downstream of Gq-Rho signaling? Rho regulates neuronal activity and synaptic release through several mechanisms in C. elegans neurons, any of which could be targets of ERK signaling. One possible ERK effector is the NCA/NALCN cation channel that acts genetically downstream of Gq-Rho to regulate locomotion rate and waveform (Topalidou et al. 2017a; b). Though ERK has not been directly connected to NCA/NALCN, mammalian ERK regulates neuronal excitability by directly phosphorylating voltage-gated sodium and potassium channels (Schrader et al. 2006; Stamboulian et al. 2010) and by regulating channel expression (Yang et al. 2015). Given the many possible ways that ERK may regulate excitability or synaptic transmission, C. elegans genetics is well suited to determine relevant effectors of Gq-Rho-ERK signaling.
Acknowledgements
We thank Stephen Nurrish for the activated Rho worm strain; Jordan and Jill Hoyt for help with Galaxy analysis; Laura Taylor for help with irradiation of extrachromosomal arrays; Dana Miller for use of her Nikon SMZ18 microscope and camera. Some strains were provided by the CGC, which is funded by the NIH Office of Research Infrastructure Programs (P40 OD010440). This work was supported by an Ellison Medical Foundation New Scholar Award and by NIH grants R00 MH082109 and R56 NS100843 to M.A.