One of the challenges to understand the organization of the nervous system has been to determine how axon guidance molecules govern axon outgrowth. Through an unbiased genetic screen, we identified a conserved Wnt pathway which is crucial for anterior-posterior (A/P) outgrowth of neurites from RME head motor neurons in Caenorhabditis elegans. The pathway is composed of the Wnt ligand CWN-2, the Frizzled receptors CFZ-2 and MIG-1, the co-receptor CAM-1/Ror, and the downstream component Dishevelled/DSH-1. Among these, CWN-2 acts as a local attractive cue for neurite outgrowth, and its activity can be partially substituted with other Wnts, suggesting that spatial distribution plays a role in the functional specificity of Wnts. As a co-receptor, CAM-1 functions cell-autonomously in neurons and, together with CFZ-2 and MIG-1, transmits the Wnt signal to downstream effectors. Yeast two-hybrid screening identified DSH-1 as a binding partner for CAM-1, indicating that CAM-1 could facilitate CWN-2/Wnt signaling by its physical association with DSH-1. Our study reveals an important role of a Wnt-Frz/Ror-Dsh pathway in regulating neurite A/P outgrowth.
How do individual nerve fibers find their way along specific paths in a complex environment such as the developing central nervous system? A principal mechanism in axon guidance is binding of a receptor protein on the axon surface to a guidance molecule. However, it remains a mystery exactly how a limited number of guidance molecules can pilot the growth of billions of neurons. In this study, we used the nematode worm Caenorhabditis elegans to establish a system to follow the outgrowth of a single neurite. We then searched for genes affecting neurite development and uncovered a guidance molecule, CWN-2 (a member of the well-known Wnt family of signaling proteins), which attracts neurite growth. We also identified two Wnt receptors (CFZ-2 and MIG-1, from the Frizzled family), a co-receptor (CAM-1, from the Ror family), and an effector (DSH-1, from the Dsh family). Together these proteins convey the Wnt guidance signal into the neurite and influence its growth. In addition, our study reveals that the restricted spatial localization of the Wnt signal, together with the specific combination of Wnt receptors and effectors expressed in the neurite, are important for the complex function of guidance molecules.
Citation: Song S, Zhang B, Sun H, Li X, Xiang Y, Liu Z, et al. (2010) A Wnt-Frz/Ror-Dsh Pathway Regulates Neurite Outgrowth in Caenorhabditis elegans. PLoS Genet 6(8): e1001056. doi:10.1371/journal.pgen.1001056
Editor: Susan E. Mango, Harvard University, United States of America
Received: January 25, 2010; Accepted: July 8, 2010; Published: August 12, 2010
Copyright: © 2010 Song et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: Research reported here was supported by the National Natural Science Foundation of China (30830069) and the National Basic Research Program of China (grants 2007CB947200 and 2009CB919000). Both XH and MD are funded by the One Hundred Talent project from CAS. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
During development of the nervous system, an individual neuron needs to be guided to its proper target through interactions with environmental guidance cues. Studies during the past twenty years have demonstrated that the ligand-receptor guidance mechanisms essential for this process are broadly present throughout the animal kingdom including worms, flies, and mice , .
Based on the body axis, the guidance action can be subdivided into Dorsal-Ventral (D/V) guidance and Anterior-Posterior (A/P) guidance. The well-defined D/V guidance cues include Netrin, Slit, Semaphorin and Ephrin . It is generally accepted that through their receptors, these guidance signals trigger downstream events, which are less well characterized, and finally act on the cytoskeleton to modulate the extension and/or turning of the growth cone at the tip of axon .
Wnt signaling, first identified in regulating embryonic pattern formation, has recently been linked to neurite A/P guidance . Binding of Wnt to the extracellular CRD domain of the Frizzled receptor (Frz) activates Dishevelled (Dsh). Once Dsh is activated, downstream signaling can take three different paths . In the canonical pathway, when Wnt is present, Dsh acts through GSK3β and Axin to stabilize β-catenin, which then translocates from the cytoplasm to the nucleus, thus turning on gene transcription. In the calcium pathway, Dsh regulates calcium signaling including protein kinase C (PKC) and Ca2+/calmodulin-dependent protein kinase II (CaMKII), in events such as conversion extension during embryonic development. Dsh can also function through the small GTPases Rho/Rac, subsequently activating downstream JNK kinase to modulate the actin cytoskeleton in the establishment of planar cell polarity (also known as the PCP pathway). However, exactly how Wnt ligands and other components of the Wnt pathways regulate axon A/P guidance is not well understood.
In the spinal cord of mice, Wnt4 is present in the floor plate and attracts commissural axons through interaction with its receptor Frz3 . PKCζ, atypical protein kinase C, and phosphatidylinositol-3-kinases (PI3K) are required for Wnt-mediated axon A/P outgrowth . In mice, Wnt5 and Wnt1 gradients were found to be important for the repulsion of cortico-spinal axons through RyK . In Drosophila, Wnt5 repels anterior commissural growth cones that express Derailed (drl), an atypical RyK gene . These findings pinpoint the essential role of the Wnt pathway in A/P axon guidance, but also raise many more questions. Do all Wnts and their receptors contribute to A/P guidance? Since Wnt pathway components are widely present throughout the nervous system, how is specificity achieved for an individual neuron, or a subset of neurons, in A/P guidance? What is the difference between the Wnts and/or their receptors? Can they substitute each other functionally?
One way to answer these questions is to combine unbiased genetic screens and suitable molecular manipulations to systematically investigate the molecular mechanisms underlying axon A/P guidance. The Caenorhabditis elegans genome contains five Wnts, and some of them have been studied in great detail, including egl-20, lin-44 and mom-2 –. Besides embryonic/larval tissue patterning, several Wnts have been shown to function in nervous system development, including neuron migration, polarity, neurite extension, neurite pruning, synaptogenesis and, most recently, nerve ring organization –. However, the exact roles of Wnts and related components during axon A/P outgrowth are less well characterized.
Here we describe the usage of a pair of C. elegans head motor neurons to systematically investigate the regulatory machinery of neurite A/P outgrowth. From the genetic screen, we recovered a set of Wnt components and, specifically, we found that CWN-2/Wnt could function locally as an attractive cue and act on DSH-1 through the Frz receptors CFZ-2 and MIG-1, and the co-receptor CAM-1/Ror, to guide neurite outgrowth. In addition, the activity of CWN-2 can be partially substituted by expressing other Wnts locally, indicating that part of the functional specificity of Wnts is through tissue-specific gene expression. Together, our study reveals a specific Wnt-Frz/Ror-Dsh pathway regulating A/P neurite guidance in C. elegans.
A genetic program regulating the neurite growth of RMED/V neurons
The RME neurons are a set of four GABAergic motor neurons that innervate head muscles and regulate foraging movements . The members of this class have an unusual four-fold symmetry; cell bodies are situated mid-dorsally (RMED), mid-ventrally (RMEV), left laterally (RMEL) and right laterally (RMER). In addition to the processes round the nerve ring, RMED and RMEV each sends out an extra process, which runs down the dorsal and ventral cords respectively and then terminates around the middle of the body (Figure 1A). Previously, we reported that in the absence of transcription factor AHR-1, the RMEL and RMER cells adopt RMED or RMEV cell fates and send out posterior processes, indicating that the outgrowth of posterior processes is genetically programmed .
(A) A GFP fluorescence image of an unc-30(ju54);juIs76 animal. juIs76 (Punc-25::GFP) highlights the RME GABAergic neurons in unc-30(ju54) mutant animals. The insert shows a schematic drawing of all four RME neurons. Anterior is to the left and dorsal is up. (B) RME neurons at different developmental stages, including a: comma stage; b: two-fold stage; c: three-fold stage, viewed with the juIs76 marker. a, b, and c are DIC images; a′, b′, and c′ are fluorescence images. RMED/V neurons start sending out their posterior processes during the late embryonic stage (c and c′), and continue to grow posteriorly during larval stages (d and e). (C) The relative length of RMED and REMV posterior neurites at different developmental stages. Relative neurite length is defined as the ratio of neurite length to body length. Error bars represent the standard error of the mean (SEM).
Using a GFP transgene (juIs76) driven by the GABAergic neuron-specific promoter Punc-25 , we were able to visualize the morphology of RME neurons in unc-30 mutant animals. unc-30 encodes a homeodomain protein that controls the specification of type D GABA neurons . In the absence of UNC-30, unc-25 expression in type D neurons is abolished ; however its expression remains unchanged in RME neurons (Figure 1A). Therefore, using the juIs76 marker in the unc-30 mutant background, we were able to follow the development of RME neurons in living animals. The RME cell bodies were first visualized around the bean/comma stage during embryogenesis (Figure 1B). By the L1 stage, the posterior extending processes could be identified unambiguously. We measured the relative length of the RMED/V posterior extending processes as the ratio to the body length and found that the relative length continues increasing and reaches a plateau in the adult stage (Figure 1C). We also noticed that individual variation in terms of the relative RMED/V lengths is rather small. By the adult stage, RMEV processes stop at a certain distance away from the vulva, at which time the length of the RMEV process is on average ∼35% of body length, while the RMED process is about ∼26% of body length (Figure 1C). Therefore, for rest of this paper, all phenotypes are scored at the young adult stage in unc-30 mutant background.
To uncover the genetic program that regulates RMED/V neurite outgrowth, we first tested whether classical axon guidance molecules are involved. When we introduced the GFP marker into unc-6 and slt-1 mutants , , we found that neither unc-6(ev400) nor slt-1(eh15) affects the growth of RMED/V A-P processes, indicating that the signals for RMED/V neurite growth are different from commissural axon guidance signals (Figure 2A and 2B). Since in wild type, neither the RMED nor the RMEV process can extend beyond the vulva, we asked whether the vulva serves as a physical boundary preventing neurite growth. When we examined the length of RMED/V processes in lin-11, a mutant with no vulva , we found there is no detectable deficit in the length of RMED/V neurites, suggesting that the vulva does not play a role in RME A/P growth (Figure 2A and 2B).
(A) RME neuron fluorescence images of animals with different genetic backgrounds. unc-30(ju54);juIs76 is treated as wild type (WT). RMED/V posterior neurite outgrowth is unaffected in the D/V guidance cue mutants unc-6(ev400) and slt-1(eh15) and the vulvaless mutant lin-11(n389). (B) Quantification analysis of mutant phenotypes shown in (A). The average relative neurite length in wild type is set as 100. Error bars represent SEM. (C) Phenotypes and list of the three classes of mutants isolated from the genetic screen. Most Class I mutant animals lack both RMED and RMEV processes. Class II mutants display both shortened and normal length of neurites. In Class III mutants, both RMED and RMEV processes are short. Asterisk indicates the end of the process.
To systemically dissect the guidance signals required for RMED/V neurons, we performed a genetic screen for mutants with altered RMED/V neurite length. This yielded a total of 18 mutants, the phenotypes of which can be divided into three classes (Figure 2C). Class I mutants (xd1, xd5, xd16, and xd22) lack both RMED and RMEV processes. Class II mutants (xd2, xd8, xd9, xd10, xd11, xd13, xd21, xd23, xd24, and xd26) exhibit a variable phenotype including lack of processes, short processes and processes of normal length. In Class III mutants (xd12, xd14, xd15, and xd25), both RMED and RMEV display short processes and the phenotype is almost 100% penetrant. To reveal the molecular mechanism underlying RMED/V neurite growth, several of the genes were cloned and the detailed functional analysis is reported in following sections.
cwn-2/Wnt regulates neurite A/P growth
In animals carrying the class I mutation xd1, both RMED and RMEV lose posterior neurites. In addition, there are short anterior processes growing out from RMED/V cells with low frequency. These phenotypes remain in aged animals, indicating that the deficiency is not due to the delayed neurite outgrowth. Genetic mapping, transgenic rescue and complementation analysis identified xd1 as an allele of cwn-2. cwn-2 encodes one of the five Wnts in C. elegans. Genomic DNA sequencing revealed a G to A mutation in xd1, resulting in replacement of a conserved cysteine by tyrosine (Figure 3A). The lack of RMED/V processes in cwn-2 mutants could be due to failure of neurite outgrowth or alternatively to a cell fate change, such as RMED/V cells adopting the RMEL/R cell fate. To distinguish these two possibilities, we examined lim-6 reporter expression pattern in cwn-2 mutants. In wild type, lim-6 is specifically expressed in RMEL/R cells but not in RMED/V cells . If RMED/V cells adopt the RMEL/R cell fate, lim-6 should be expressed in RMED/V. In fact, we found that lim-6 expression was still restricted to RMEL/R cells in cwn-2 mutants (data not shown). These data suggested that CWN-2/Wnt likely directly regulates RME neurite A/P growth with no significant alteration of cell fate. To test whether cwn-2 affects neurite A/P growth in other neurons, we examined the AVE neuron with a Popt-3::mCherry marker. Similar to RMEV, the AVE neuron has a posterior process along the ventral nerve cord, which terminates before the vulva region . We found that the posterior growth of the AVE neurite is not affected in cwn-2 mutants (data not shown), suggesting that cwn-2 specifically regulates RMED/V neurite posterior extension.
(A) xd1 is a C138Y missense mutation in the cwn-2 locus. Black boxes are exons and grey boxes are UTRs. (B) Phenotypic quantification of RMED neurite A/P outgrowth defect in Wnt pathway receptor and ligand mutants. The average relative neurite length in wild type (unc-30;juIs76) is set as 100. Error bars represent SEM. Note that mig-1(e1787);cfz-2(ok1201) double mutants mimic cwn-2(xd1). (C) Pcwn-2::mCherry expression pattern (Red) in different developmental stages. Green is RMED/V neurons highlighted by juIs76 marker. Top panels: fluorescence and bright field images of embryos with Pcwn-2::mCherry. In a 2-fold stage embryo, cwn-2 is mainly expressed in the intestine (arrow). The highest level of mCherry signal is observed in the posterior pharyngeal bulb and the pharyngeal-intestine valve before hatching (arrowhead). After L1 stage, Pcwn-2::mCherry is expressed in the pharynx, body wall muscles and some ventral cord neurons. Asterisks point to the tips of RMED/V neurites. (D) Quantification analysis of the rescue activity of the cwn-2 genomic fragment in cwn-2(xd1). The length of both RMED and RMEV were compared to wild-type controls (unc-30;juIs76). The extent of RMED and RMEV extension was classified into three categories: “WT” stands for wild-type length in both RMED and RMEV neurites; “no D, V” stands for absence of both RMED and RMEV neurites (Class I phenotype); and “short” indicates an intermediate phenotype between “WT” and “No D, V” (including shorter processes and absence of either RMED or RMEV process). Results from two independent transgenic lines are presented.
There are five Wnts (cwn-1, cwn-2, egl-20, lin-44, and mom-2) in the C. elegans genome. To test whether other Wnts are involved in RMED/V outgrowth, we examined mutants of cwn-1, egl-20, lin-44, and mom-2. None of these mutants exhibits defects in RME neurite A/P growth (Figure 3B and data not shown). We then generated lin-44;cwn-1 and lin-44;egl-20 double mutants and found that they do not display any detectable outgrowth defect either (data not shown). Although we can't exclude the possibility that other Wnts, in particular mom-2, which is maternally required for viability, may play a rather minor role, above data suggest that among all five Wnt ligands, cwn-2 likely plays a major role in RMED/V neurite outgrowth.
Wnt functions locally to attract neurite outgrowth
Of five Wnts, why is CWN-2 so important for RME A/P outgrowth? One explanation is that the spatial localization of CWN-2 determines its function specificity. We analyzed the expression pattern of all Wnts using a promoter::mCherry fusion assay. Consistent with previous reports , , , egl-20 and lin-44 are mainly expressed in the posterior and vulval region. mom-2 and cwn-1 have low levels of expression in the head region and high levels of expression in the posterior body (Figure S1). Pcwn-2::mCherry is visible in the intestine and part of the pharyngeal region during the embryonic stage. After hatching, cwn-2 is expressed in the anterior part of the worm, including pharynx, body wall muscle and ventral cord neurons (Figure 3C). cwn-2 promoter-driven cwn-2 can fully rescue the cwn-2 mutant defects, suggesting that the Pcwn-2::mCherry pattern may represent cwn-2 expression in vivo (Figure 3D and Figure S2).
We wondered whether other Wnts could substitute CWN-2 when expressed in the same position as CWN-2. We introduced cwn-1, mom-2, egl-20, or lin-44 cDNA driven by the cwn-2 promoter into cwn-2 null mutants and found that all of them could rescue the cwn-2 mutant phenotype to some degree (Figure 4A and Figure S3), suggesting the functional specificity of a particular Wnt could, at least, partially due to whether it is present locally and the enforced high level of other Wnts may overcome the intrinsic difference among Wnts.
(A) Quantification analysis showing that other Wnts when under control of the cwn-2 promoter can partially rescue cwn-2(xd1) mutant phenotype. Results from two independent transgenic lines are presented. The DNA injection concentration is 20 ng/µl. (B) CWN-2 expression, driven by different promoters, causes different levels of rescuing activity. Posterior extension and anterior growth of RMED and RMEV were evaluated separately. Schematic diagrams of the different posterior and anterior neurite phenotypes are shown at the top. The classification of the posterior phenotypes is the same as for the rescue assays in Figure 3. The color coding in the schematic drawing of the head (left) represents the expression patterns of different promoters. The expression level is relatively higher in the brown regions than in the red regions based on transcriptional mCherry assay. For the lin-11 and egl-17 promoters, the distance from the vulva (indicated by a red oval) to the head is not proportional. Expression of CWN-2 under control of the egl-17 promoter is able to trigger RMED anterior neurite extension (*). (C) Phenotype of anterior extension (arrows) in wild type, cwn-2(xd1) mutants and Pegl-17::CWN-2-rescued cwn-2(xd1) mutants.
Next, we asked whether CWN-2/Wnt play an attractive or repulsive role in guiding RMED/V neurite outgrowth. We utilized tissue-specific promoters to express cwn-2 in various places around the nerve ring region and examined the correlation between the direction of neurite outgrowth and the position of the cwn-2 gene product in cwn-2 mutant background (Figure 4B). Most transgenic lines express CWN-2 in a comparable level to wild type and Pcwn-2::CWN-2 transgenes by Q-RT-PCR (Figure S4). We firstly expressed cwn-2 in the whole pharynx using the myo-2 promoter. Similar to the cwn-2 promoter, myo-2 has a slightly higher expression level in the posterior region of the nerve ring than the anterior region. We found that the myo-2 promoter achieved full rescue activity. In contrast, when we expressed cwn-2 under control of the glc-2 promoter, which exhibits a higher level of expression in the anterior region of the nerve ring than the posterior region, we observed less rescuing activity. In addition, we found a considerably increased number of animals with RMED/V neurites that extended in the anterior direction. When cwn-2 is expressed only in the posterior region of the nerve ring with the hlh-17 promoter, the majority of cwn-2 mutants regain the wild-type-like RMED/V neurite growth pattern. Above data suggests that CWN-2 may act as an attractive cue to guide RMED/V A/P neurite growth. In consistence with this hypothesis, when we expressed CWN-2 more posteriorly towards the vulva region using the lin-11 promoter, we found that it also exhibited partial rescue activity. Interestingly, when cwn-2 is expressed under control of the egl-17 promoter, which drives expression in the vulva as well as dorsal M4 neurons in the pharynx , we found, in addition to weak rescuing activity, many more RMED neurons projecting neurites towards the anterior (Figure 4B). These data suggest that the presence of CWN-2 in the anterior dorsal region of the pharynx could redirect neurites to grow towards anterior (Figure 4B and 4C). Then could this rerouting phenotype be suppressed by CWN-2 from its normal source? We performed the same experiment in wild-type animals and found that the anterior outgrowth phenotype in the Pegl-17::CWN-2 expressing animals could be fully suppressed (Figure S2), suggesting that CWN-2 functions as an attractive cue and CWN-2 molecules from different locations could compete each other to direct neurite outgrowth.
If CWN-2 functions indeed as an attractive cue, one would expect that CWN-2 should present at the posterior region of RMED/V neurite tips during process extension. Therefore, we closely monitored the Pcwn-2::mCherry expression at different developmental stages. The mCherry signal first appeared in the intestine before the expression of Punc-25::GFP (Figure 3C) during embryogenesis. At late embryonic stage when RMED/V neurite start extending posteriorly, the highest expression of CWN-2 is found at posterior pharyngneal bulb and the pharyngeal-intestinal valve (Figure 3C). When animals are at L1 stage, the RMED/V neurites grow towards the posterior pharynx, where CWN-2 displays relatively higher expression level (Figure 3C). The expression pattern of CWN-2 at both embryonic and L1 stages correlates well with the attractant role of CWN-2 during neurite outgrowth. After L1 stage, the neurites continue their growth and pass the posterior pharynx; meanwhile CWN-2 is also found expressed in body muscles and some ventral cord neurons (Figure 3C). It is possible the continuous growth of RMED/V neurites in the later larval stage relies on other guidance cues. Alternatively, the temporary experience with CWN-2 attractant during embryonic and L1 stages could be sufficient to maintain the extension of RMED/V processes. While we can not rule out other mechanisms which may work together with CWN-2 to guide neurite growth, current evidences support a notion that CWN-2 acts as an attractive cue to regulate RMED/V neurite A/P outgrowth.
CAM-1 may act as a receptor for CWN-2
From the genetic screen, we identified two alleles of cam-1, xd22 (class I) and xd13 (class II) (Figure 5A). cam-1 encodes the C. elegans homolog of the CRD domain-containing receptor tyrosine kinase Ror2 , . There are three isoforms of cam-1. cam-1a is the longest, while cam-1b lacks exon 1 and cam-1c lacks exons 1, 2, 3 and 4 (Figure 5B). In addition to the protein length, the transcription regulatory elements are different among these isoforms. Sequencing results showed that xd13 causes a glycine to glutamic acid change in the kinase domain while xd22 is a 607bp in-frame deletion, which deletes the start codon of the cam-1b isoform and part of the Ig domain (Figure 5B). When wild-type cam-1 transgene was introduced into null mutants, full rescue activity was observed, indicating that cam-1 is indeed required for RMED/V neurite growth (Figure 5C). A putative null allele of cam-1(gm122) results in a complete lack of RMED/V posterior neurites, mimicking the class I xd22 mutant phenotype (Figure 5A). Thus, xd22 is likely a null while xd13 is a partial loss-of-function mutation. Indeed, loss of the intracellular domain of CAM-1 (ks52 and gm105 allele, for instance) only causes partial loss of function (Figure 5B and 5D). Furthermore, CAM-1 without the intracellular kinase domain retains only partial rescuing activity, while in the absence of the extracellular CRD domains, CAM-1 loses its function completely (Figure S2 and data not shown). This suggests that kinase activity is important but not essential for CAM-1 function.
(A) RME neuron fluorescence images of animals with different genetic backgrounds. The cam-1 partial loss-of-function mutant xd13 shows a variable phenotype and the null mutant gm122 has a cwn-2 like phenotype. (B) Molecular lesions in the cam-1 mutants xd22, gm122, gm105, ks52 and xd13. The color-coded domain structure of cam-1 is shown. Ig, immunoglobulin domain; CRD, cysteine rich domain; Kr, kringle domain; TM, transmembrane domain; Kinase, kinase domain; S/T, serine and theronine-rich domain. Three cam-1 isoforms are indicated. (C) Quantification of the rescuing activity of cam-1 transgenes. (D) Quantification of the RMEV neurite A/P outgrowth defect in different mutants. cam-1 functions synergistically with cfz-2 and mig-1. The average relative neurite length in wild type is set as 100. Error bars represent SEM. (E) cam-1 is expressed in RME neurons (arrow).
In mammals, binding of Wnt5a to Ror protein stimulates its kinase activity . The extracellular domain of CAM-1 could physically interact with EGL-20/Wnt in vitro . However, it was initially suggested that CAM-1 did not act as a Wnt receptor in C. elegans but instead functioned as a Wnt or Frizzled antagonist during cell migration and other biological processes . Recently, CAM-1 was identified as a receptor for CWN-2 in regulating nerve ring organization . Thus, the effect of CAM-1 on RMED/V neurite growth could be explained by CAM-1 acting as a receptor for CWN-2, or, alternatively, CAM-1 may sequester other Wnts and therefore facilitate CWN-2 function indirectly. To distinguish between these two possibilities, we performed the following experiments. First, we tested whether CAM-1 is expressed in the CWN-2 responsive cells, which are the RMED and RMEV neurons. We identified cam-1-expressing cells by expressing GFP under the control of the cam-1a and cam-1b promoter. To visualize RME cells, Punc-25::mCherry was co-injected into worms. In the nerve ring region, unc-25 is only expressed in the four RME cells. It was evident that both Pcam-1a and Pcam-1b drove GFP expression in the nervous system. Specifically, Pcam-1a::GFP highlights RMED and RMEV cells, while Pcam-1b::GFP is present in all four RME cells (Figure 5E and data not shown).
Next, we asked whether cam-1 functions within cwn-2 responsive cells. When we expressed cam-1 in RME cells using the unc-25 promoter, we found that it could rescue the cam-1 mutant phenotype (Figure 5C). The rescue activity of Pcam-1a::CAM-1a is also consistent with the role of cam-1 in RMED and RMEV cells specifically. However, we noticed that expressing cam-1 in the whole nervous system using the snb-1 promoter achieved better rescue than expressing cam-1 in RME cells alone (Figure 5C). Therefore, to address whether CAM-1 activity is needed in non-CWN-2-responsive cells, we used the unc-86 or unc-4 promoter to express cam-1 in neurons excluding RME cells and found that neither promoter exhibits rescuing activity (Figure S5). Similarly, we used the hlh-17 promoter to express cam-1 in cephalic sheath glia cells, which are near the nerve ring, but this could not alleviate the mutant phenotype either (Figure S5). We also examined whether additional expression of cam-1 in non-RME cells could facilitate cam-1 function. Co-injecting Punc-4::CAM-1b could not enhance Punc-25::CAM-1b-YFP rescuing activity, indicating that cam-1 function is not required in non-RME cells (Figure S5). In addition, we found that the over-expression of cwn-2 could not suppress cam-1 null mutants (Figure S2), implying that the cam-1 may function downstream of cwn-2. Taken together, these data suggest that CAM-1 likely serves as a CWN-2 receptor on RMED/V cells to regulate RMED/V neurite growth.
cam-1 interacts with cfz-2 and mig-1 genetically
There are four Frz receptors (CFZ-2, LIN-17, MIG-1, and MOM-5) and one atypical receptor tyrosine kinase (Ryk) receptor (LIN-18) in C. elegans . Besides CAM-1, are any of these receptors involved in mediating the CWN-2 signal in RME neurite A/P outgrowth? Because none of the class I mutants turns out to be allelic to the Wnt receptors mentioned above, we reasoned that Wnt receptor mutants may display relatively weak (class II) phenotypes due to gene redundancy. Indeed, cfz-2 displays a variable phenotype, while mig-1 has a very mild defect in RMED/V neurite growth (Figure 3B). Moreover, the mig-1;cfz-2 double mutant phenotype mimics class I mutants, indicating that CFZ-2 and MIG-1 function redundantly as Wnt receptors in mediating the CWN-2 signal (Figure 3B). In contrast, the other three Wnt receptors, LIN-17, LIN-18 and MOM-5, appear not to play a role in RMED/V neurite outgrowth (Figure 3B and data not shown).
What is the relationship between Frz receptors (CFZ-2 and MIG-1) and CAM-1? Compared to cam-1 null mutants, null mutants of cfz-2 or mig-1 only display weak phenotypes and mig-1;cfz-2 double mutants exhibit a strong phenotype resembling cam-1 null mutants. This suggests that CAM-1 could act as the main receptor for CWN-2/Wnt, while CFZ-2 and MIG-1 are two co-receptors for CAM-1. Consistent with this idea, the double mutants cam-1(weak);cfz-2(null) and mig-1(null); cam-1(weak) all exhibit phenotypes resembling cam-1 full loss-of-function mutants (Figure 5D).
A conserved Wnt pathway including DSH-1 functions within RMED/V to regulate neurite outgrowth
The above results indicate that CWN-2 activates its membrane receptors (CAM-1, CFZ-2 and MIG-1) on RME cells then triggers downstream events to regulate RME neurite A/P outgrowth. What are the downstream events? The xd5 mutation, which causes loss of both RMED and RMEV processes, turns out to be an allele of dsh-1 (Figure 6A). Dishevelled (Dsh) is a cytoplasmic multi-domain protein that is required for all known branches of the Wnt signaling pathway . There are two isoforms of dsh-1: dsh-1a and dsh-1b. Compared to DSH-1a, DSH-1b lacks the N-terminal DAX domain, which is essential for canonical Wnt signaling. The xd5 mutation is a 254bp deletion that affects both isoforms and results in a stop codon in the DEP domain (Figure 6B). Therefore, it is a putative null allele of dsh-1. In agreement with this, the null mutant of dsh-1(ok1445) displays the same phenotype as dsh-1(xd5) (Figure 5D). Moreover, using the unc-25 promoter to drive dsh-1a expression in RMED/V, we observed full rescuing activity, suggesting that dsh-1 function is required in RMED/V neurons (Figure 6C and Figure S2).
(A) Fluorescence images of RMED/V neurons in various Wnt mutant animals. cwn-2(xd1), dsh-1(xd5) and mig-1(e1787);cfz-2(ok1201) double mutant exhibit the same phenotype. (B) Molecular lesion in the dsh-1 mutant xd5. The domain structure of dsh-1 is shown. DAX: domain present in Dishevelled and axin; PDZ: PSD-95, Dlg, and ZO-1/2 domain; DEP: Dishevelled, Egl-10, and Pleckstrin domain. Two DSH-1 isoforms are indicated. xd5 causes a small deletion. (C) Quantification of the rescuing activity of dsh-1 transgenes. Expression of dsh-1 in RMED/V neurons can rescue dsh-1(xd5) mutant phenotype. (D) Quantification of the RMED neurite A/P outgrowth defect in different mutants, including components of the three different downstream pathways of Wnt and factors affecting the actin-microtubulin cytoskeleton.
What are the downstream signals after DSH-1? There are three proposed signal pathways: the canonical pathway, the calcium pathway and the PCP pathway. In the canonical Wnt pathway, DSH acts through β-catenin to regulate gene transcription. However, we found that none of the canonical pathway components including BAR-1, PRY-1, WRM-1 and the newly identified β-catenin SYS-1, appears to have a role in RMED/V neurite A/P growth (Figure 6D and data not shown). In addition, in the absence of the calcium pathway component CamKII (UNC-43), the growth of RMED/V neurites is indistinguishable from wild type (Figure 6D). We then tested whether the PCP pathway is involved. In the PCP pathway, DSH activates the Rho/Rac GTPases, thus regulating cytoskeleton organization. Although the absence of MIG-2/Rho or CED-10/Rac does cause RMED/V neurite outgrowth defects, rac-2, vang-1, or jnk-1 mutant does not display any visible phenotype. Therefore, whether PCP pathway is involved in RMED/V neurite outgrowth remains to be determined (Figure 6D). In addition, we found that mutants with deficits in cytoskeleton organization (such as unc-34/enable, unc-73/Rho-GEF, unc-76, and unc-14) also display shortened axon phenotype and the axon re-routing phenotype in cwn-2;Pegl-17::CWN-2 animals could be partially suppressed by these mutations, consistent with the general role of cytoskeleton re-arrangement during neurite outgrowth (Figure 6D and Figure S2).
Previous reports show that Wnt gradient formation requires the secretion machinery in Wnt-producing cells , . Similar to cwn-2 and dsh-1, mutants of mig-14 and vps-35, which act upstream to regulate the secretion of Wnts, display a class I phenotype (Figure 6D), suggesting that retromer complex and other secretion components are involved in RME neurite A/P outgrowth.
CAM-1 interacts with DSH-1 physically
To further explore how CAM-1 transmits CWN-2 signals to downstream components, we performed a yeast two-hybrid screen using the CAM-1 intracellular domain as bait. From the screen, we identified that the full length DSH-1 could bind to CAM-1 (Figure 7A). We further narrowed down the binding activity of DSH-1 to its PDZ and DEP domains, while the DAX domain is not required for CAM-1 binding (Figure 7A). Furthermore, we made truncated CAM-1 intracellular domain constructs and found that the kinase domain and the junction region between kinase and transmembrane domain are important for DSH-1 binding (Figure 7B). We also tested whether there is any physical interaction between DSH-1 and other Wnt receptors. The results demonstrated that neither CFZ-2 nor MIG-1 intracellular domain could bind DSH-1 in yeast two-hybrid assay (Figure 7C).
(A) The PDZ and DEP domains are important for the binding of DSH-1 to CAM-1 intracellular domain (ICD). Empty vector (Vector) was used as a control. (B) The kinase domain and the region before the kinase domain are crucial for DSH-1 interacting. (C) MIG-1 ICD and CFZ-2 ICD do not interact with CAM-1 or DSH-1.
The DAX domain of DSH has been shown to bind to Axin and is important for the canonical Wnt signaling pathway . Through alternative splicing, two DSH-1 isoforms (DSH-1a and DSH-1b) exist in C. elegans; DSH-1b lacks the DAX domain (Figure 6B). We found that Pdsh-1b::mCherry but not Pdsh-1a::mCherry is expressed in RME cells (data not shown). Moreover, DSH-1b alone significantly rescues the dsh-1 null phenotype, echoing previous findings that the canonical pathway may not be required for RME neurite A/P outgrowth (Figure 6C). To further address the biological relevance of CAM-1/DSH-1 binding, we made dsh-1;cam-1(null/weak) double mutants and found the double mutant phenotype is similar to dsh-1 single, in consistence with the notion that these two are likely in a same pathway (Figure 5D). Furthermore, cam-1(null) results into much strong phenotype than either cfz-2 or mig-1 and mig-1;cfz-2 double mimics cam-1(null), suggesting CAM-1 plays a key role in transmitting CWN-2 signal to DSH-1 during RMED/V neurite outgrowth.
Proper neurite A/P guidance is important for establishing accurate three-dimensional neuronal connections in the nervous system. However, the underlying mechanisms have not been explored in detail. Through an unbiased genetic screen, we have revealed a particular Wnt-Frz/Ror-Dsh pathway that regulates neurite A/P growth in C. elegans GABAergic RMED/V motor neurons.
In C. elegans, several Wnts are known to function in nervous system development. egl-20 is expressed in the posterior tail region and acts as a repellent cue to push HSN neuron migration forward . lin-44 participates in establishment of neuron cell polarity and this function is mediated by the Wnt receptor LIN-17 . In the absence of lin-44 and lin-17, the polarity of the PLM neuron is reversed. In addition, in cwn-1;egl-20 double mutants, the polarity of the ALM neuron is reversed, suggesting that the precise combination of different Wnt pathway components may contribute to the specific functions of Wnts. lin-44 and lin-17 could also regulate the extension of neurites along the A/P axis through a β-catenin-dependent pathway . Meanwhile, it has been reported that lin-44, egl-20, and lin-17 also inhibit ectopic synapse formation in DA9 neurons . Recently, CWN-2 has been linked to nerve ring organization, indicating that cwn-2 is likely involved in nervous system development . Our study provides additional evidence that CWN-2/Wnt and its downstream components are important for neural development.
One explanation for the observation that CWN-2 is essential for RMED/V neurite outgrowth while other Wnts are not, is that the specific functional requirement for CWN-2 is due to its intrinsic molecular features. However, in the absence of CWN-2, expression of cwn-1, egl-20, lin-44 or mom-2 in the nerve ring region partially rescued the neurite outgrowth defect of cwn-2 mutant animals. In addition, while other Wnts (cwn-1, egl-20, lin-44 and mom-2) are predominantly expressed in the posterior regions of the worm, cwn-2 expression remains high in the anterior region, indicating that positioning Wnts at different places along the body axis could contribute to the functional specificity of Wnts.
Wnts have been implicated in the establishment of neuronal polarity. The lack of posterior RMED/V neurites in cwn-2, dsh-1 and other mutants could result from loss of polarity instead of from outgrowth deficits. However, in cwn-2 mutants, the processes around the nerve ring appear normal, indicating that cell polarity is at least partially maintained. Moreover, placing CWN-2 at the anterior-most region of the nerve ring with the egl-17 promoter induces RMED neurites to grow forward, suggesting that CWN-2 likely functions in regulating neurite outgrowth. Consistent with this, ectopic expression of CWN-2 in a cwn-2 mutant background with various promoters points to an attractive role of CWN-2 in neurite outgrowth.
Previous studies in C. elegans revealed that CAM-1 may antagonize Wnt activity , . Furthermore, it has been shown that the extracellular domain (ECD) of CAM-1/Ror can bind Wnts in vitro. Thus it has been proposed that CAM-1 inhibits Wnt activity by sequestering Wnt ligands. In RMED/V motor neurons, however, CAM-1 apparently plays a positive role in mediating CWN-2/Wnt signals. First, cam-1 mutants exhibit a similar phenotype to cwn-2 single and mig-1;cfz-2 double mutants. Second, the partial loss-of-function allele of cam-1 synergistically enhances either the cfz-2 or mig-1 single mutant phenotype. Third, cam-1 is expressed in and can function within RMED/V to guide neurite outgrowth. Together, the above data indicate that CAM-1 acts as a receptor with CFZ-2 or MIG-1, thus facilitating CWN-2 signal transduction. In addition, we found that neither CAM-1 intracellular domain nor DSH-1 has binding activity to CFZ-2 or MIG-1 intracellular domain (Figure 7C), implying that CAM-1 may play a central role in transducing CWN-2 signal to DSH-1 during RMED/V outgrowth. However, the facts that lacking of CAM-1 intracellular domain does not cause phenotype as strong as dsh-1 null mutants and cam-1 without kinase domain contains partial rescuing activity indicate that extracellular domain of CAM-1 also play a role in signal transduction, such as clustering other co-receptors, like CFZ-2 or MIG-1. In support of the role of CAM-1 in facilitating Wnt signaling, recent studies demonstrated that Wnts and CAM-1 work together to promote axon stability as well as to stabilize nerve ring organization , . Why is CAM-1 needed in addition to both the CFZ-2 and MIG-1 receptors? Similar to Frz receptors, CAM-1/Ror has a CRD domain in the extra-cellular region, but unlike Frz receptors, CAM-1 only has a single transmembrane domain followed by a kinase domain. Although the kinase domain is not essential for CAM-1 activity, deletion or mutation of this domain compromised the Wnt signal, leading to a partial loss-of-function phenotype of cam-1. Thus, we suspect that different combinations of multiple Wnt receptors may contribute to the signal specificity of Wnt and to fine tuning of the Wnt signal. Although further investigation is required to test this speculation, a comparison can be made to the Netrin pathway: when UNC-40/DCC acts alone, it mediates Netrin-induced axon attraction, while with UNC-5, it leads axons away from the Netrin source , .
Out of three dsh genes, dsh-1 is the only one which when mutated displays a similar phenotype to cwn-2, suggesting that the CWN-2 signal is largely mediated by DSH-1. When it goes to the downstream of DSH-1, we believe that CWN-2 signals do not go through the canonical pathway but instead act on the actin/microtubule cytoskeleton, because unc-73/Trio, unc-34/enable, unc-14, and unc-76 mutant animals also display neurite outgrowth defects. Most importantly, mutants of two small GTPases (MIG-2/Rho and CED-10/Rac) exhibit class II mutant phenotypes, suggesting that they might act redundantly in regulating the cytoskeleton during neurite outgrowth. However, how Wnt signal is transduced from DSH-1 to the small GTPases, such as MIG-2/Rho and CED-10, is currently unknown. Cloning of other class I mutants may provide additional information.
Once axons grow out of the cell body, what kind of genetic program controls the length of those axons? Since ectopic expression of CWN-2 in the anterior nerve ring induces anterior neurite growth, we wondered whether elevating Wnt activity by over-expressing CWN-2 in wild-type animals could make RMED/V neurites grow longer. We tested other Wnts and found that none of them resulted in a neurite ‘over-shooting’ phenotype (data not shown). Therefore, the Wnt ligand level does not sufficient to determine the length of RMED/V posterior neurites. Through the screen, we identified a set of mutants with short or no posterior processes, but were unable to recover any mutants with neurites that were too long or incorrectly oriented (towards the anterior, for instance). One possible explanation is that genes regulating RMED/V neurite length or orientation choice are essential for viability. These mutants may be isolated in conditional screens. Another possibility is that genes controlling neurite length function redundantly. These genes may be identified through a gain-of-function analysis.
Given that four RME neurons with similar function are located in close proximity, why do RMED and RMEV extend neurites in response to CWN-2 while RMEL and RMER do not? Both CAM-1 and DSH-1 are expressed in all four RME neurons (Figure 5E and data not shown). Previously, we reported that in ahr-1 mutants, all four RME neurons send out posterior processes , and we found that this phenotype is dependent on cwn-2 (data not shown). AHR-1 is specifically expressed in RMEL/R but not RMED/V. Furthermore, ectopic expression of ahr-1 in RMED/V neurons can result in loss of posterior processes, implying that ahr-1 may act in potential Wnt-sensing neurons to antagonise the Wnt response. The targets of AHR-1 in the inhibition of Wnt signaling remain to be identified.
While the role of Wnts in regulating axon A/P guidance is well established, many questions remain. What is the specific combination of Wnt ligand, Wnt receptor, Dsh, and downstream signals in different circumstances? How does an individual neuron simultaneously sense the various guidance cues, including both D/V and A/P cues, present in the surrounding environment and thus decide which path it should take? How are the gradients of Wnt and other guidance cues established during development? How do they interact with each other? Answers to the above questions are certain to greatly advance our understanding of the principles of nervous system organization.
Materials and Methods
Strains and genetics
C. elegans were maintained on NGM plates under standard conditions . unc-30(ju54);juIs76 animals were treated with EMS and mutants with defective neurite outgrowth were isolated in the F2 generation. juIs76 is an integrated transgenic line of Punc-25::GFP for labeling GABA motor neurons. A total of 10,000 mutagenized haploid genomes were screened and 18 mutants were recovered. cwn-2(xd1) was mapped to chromosome IV because of its linkage to unc-30(ju54)IV. cam-1(xd13) was mapped to chromosome II around +0.08 and complementation tests were performed between cam-1(gm122), cam-1(xd22) and cam-1(xd13). Alleles used in this study were listed in the Text S1.
Molecular cloning and germline transformation
A cwn-2 genomic DNA fragment containing 5kb promoter, coding region and 0.8kb 3′-UTR was amplified from N2 genomic DNA to perform the rescue experiment. The 5kb cwn-2 promoter was cloned between the SphI and BamHI sites of pSL1190 and pPD95.77::mCherry to yield Pcwn-2-pSL1190 and Pcwn-2::mCherry-pPD95.77. cDNAs of egl-20, lin-44, mom-2 and cwn-1 were sub-cloned into Pcwn-2-pSL1190. To detect the expression patterns of Wnts, a fusion PCR approach was used to place mCherry downstream of various Wnt promoters. Fusion PCRs were also used to generate fragments for ectopic expression of cwn-2 under different promoters (myo-2, hlh-17, glc-2, egl-17 and lin-11) except elt-2. The expression patterns of these promoters were confirmed by mCherry reporters. To generate Punc-25::DSH-1a, Punc-25::DSH-1b, Punc-25::CAM-1b and Punc-25::CAM-1b-YFP constructs, full length dsh-1a, dsh-1b, and cam-1b cDNAs were cloned between the NheI and SacI/SalI sites after the unc-25 promoter in plasmid pSC325. To examine the cam-1 expression pattern, DNA sequences upstream of the cam-1 start codon were amplified using PCR and then cloned into appropriate vectors. Transgenic animals were made by standard microinjection procedures.
Image collection and phenotypic quantification
Except Figure 5E, all the RMED/V process images were taken from animals with an unc-30(ju54);juIs76 background. At least three transgenic lines for each construct were examined for rescue activity and/or expression patterns. Fluorescence images were taken with compound microscope and confocal microscope. The phenotypic quantification was acquired using NIS-Elements BR 3.0 software.
Yeast two-hybrid screen
The yeast transformation procedure was conducted using standard techniques. The intracellular domain (438aa) coding region of CAM-1b was fused with pBTM116 (LexA DNA binding domain, Leu selection) as the bait to screen a C. elegans mixed-stage cDNA library. Yeast strains bearing test plasmids were replicated onto -Leu-Trp-His plates containing 3-Amino-1,2,4-Triazole (3AT; 5 mM and 10 mM) to test potential interactions. Positive clones were analyzed by DNA sequencing. A prey plasmid harboring full length DSH-1a was isolated from the screen. The intracellular domains of MIG-1(46aa) and CFZ-2 (61aa) were cloned into pBTM116 as the same way of CAM-1b. Fusion PCR was used to generate CAM-1b ICD deletion pBTM116 constructs. A series of DSH-1a deletions constructs were made in an analogous manner to delete the DAX, PDZ and DEP domains.
The expression patterns of Wnt ligands in C. elegans. Top panels: fluorescence and bright field images of mCherry expressing embryos; middle and bottom panels: fluorescence and bright field images of adults (head to the left). (A and B) Pcwn-1::mCherry and Pmom-2::mCherry are robustly expressed in the tail and weakly expressed in the vulva and body wall muscles. (B and C) Pegl-20::mCherry and Plin-44::mCherry are mainly expressed in the tail during the embryonic and adult stages.
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Quantification of RMED/V neurite phenotypes in different mutants. The phenotype of RMED and RMEV were evaluated separately. Schematic diagrams of the different posterior and anterior neurite phenotypes are shown at the top. (A) The rescue activity of the cwn-2 genomic fragment in cwn-2(xd1). (B) The phenotype of anterior extension in Pegl-17::CWN-2-rescued cwn-2 mutants can be fully suppressed in wild type and partially suppressed in other mutants. (C) The rescue activity of the Punc-25::DSH-1 transgenes in dsh-1(xd5). (D) The rescuing activity of various cam-1 constructs. cam-1(gm122) can't be suppressed by Pcwn-2::CWN-2.
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Quantification of the rescue activity of other Wnts when driven by the cwn-2 promoter. The DNA concentrations for injection are 1 ng/µl except Pcwn-2::LIN-44 (2 ng/µl).
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The CWN-2 expression levels in different genetic backgrounds by quantitative RT-PCR.
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The rescuing activity of cam-1 transgene driven by hlh-17, unc-86, or unc-4 promoter.
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Alleles used in the study.
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We thank Dr. Yishi Jin for generous support and encouragement; CGC for stains; the C. elegans Gene Knockout Consortium for strains; Dr. Yuji Kohara for cDNAs; Dr. Kang Shen for strains and advice; and Ms Jingyan Zhang, Tian Yang, and Jianzhen Qin for the genetic screen.
Conceived and designed the experiments: SS BZ XH MD. Performed the experiments: SS BZ HS XH. Analyzed the data: SS BZ XL XH MD. Contributed reagents/materials/analysis tools: XL YX ZL. Wrote the paper: SS BZ XH MD.
- 1. Tessier-Lavigne M, Goodman CS (1996) The molecular biology of axon guidance. Science 274: 1123–1133.
- 2. Dickson BJ (2002) Molecular mechanisms of axon guidance. Science 298: 1959–1964.
- 3. Yu TW, Bargmann CI (2001) Dynamic regulation of axon guidance. Nat Neurosci 4: Suppl1169–1176.
- 4. Huber AB, Kolodkin AL, Ginty DD, Cloutier JF (2003) Signaling at the growth cone: ligand-receptor complexes and the control of axon growth and guidance. Annu Rev Neurosci 26: 509–563.
- 5. Zou Y (2004) Wnt signaling in axon guidance. Trends Neurosci 27: 528–532.
- 6. Montcouquiol M, Crenshaw EB 3rd, Kelley MW (2006) Noncanonical Wnt signaling and neural polarity. Annu Rev Neurosci 29: 363–386.
- 7. Lyuksyutova AI, Lu CC, Milanesio N, King LA, Guo N, et al. (2003) Anterior-posterior guidance of commissural axons by Wnt-frizzled signaling. Science 302: 1984–1988.
- 8. Wolf AM, Lyuksyutova AI, Fenstermaker AG, Shafer B, Lo CG, et al. (2008) Phosphatidylinositol-3-kinase-atypical protein kinase C signaling is required for Wnt attraction and anterior-posterior axon guidance. J Neurosci 28: 3456–3467.
- 9. Keeble TR, Halford MM, Seaman C, Kee N, Macheda M, et al. (2006) The Wnt receptor Ryk is required for Wnt5a-mediated axon guidance on the contralateral side of the corpus callosum. J Neurosci 26: 5840–5848.
- 10. Yoshikawa S, McKinnon RD, Kokel M, Thomas JB (2003) Wnt-mediated axon guidance via the Drosophila Derailed receptor. Nature 422: 583–588.
- 11. Eisenmann D (2005) Wnt signaling. In The C elegans Research Community WormBook.
- 12. Herman MA, Vassilieva LL, Horvitz HR, Shaw JE, Herman RK (1995) The C. elegans gene lin-44, which controls the polarity of certain asymmetric cell divisions, encodes a Wnt protein and acts cell nonautonomously. Cell 83: 101–110.
- 13. Whangbo J, Kenyon C (1999) A Wnt signaling system that specifies two patterns of cell migration in C. elegans. Mol Cell 4: 851–858.
- 14. Hayashi Y, Hirotsu T, Iwata R, Kage-Nakadai E, Kunitomo H, et al. (2009) A trophic role for Wnt-Ror kinase signaling during developmental pruning in Caenorhabditis elegans. Nat Neurosci 12: 981–987.
- 15. Hilliard MA, Bargmann CI (2006) Wnt signals and frizzled activity orient anterior-posterior axon outgrowth in C. elegans. Dev Cell 10: 379–390.
- 16. Kennerdell JR, Fetter RD, Bargmann CI (2009) Wnt-Ror signaling to SIA and SIB neurons directs anterior axon guidance and nerve ring placement in C. elegans. Development 136: 3801–3810.
- 17. Pan CL, Howell JE, Clark SG, Hilliard M, Cordes S, et al. (2006) Multiple Wnts and frizzled receptors regulate anteriorly directed cell and growth cone migrations in Caenorhabditis elegans. Dev Cell 10: 367–377.
- 18. Silhankova M, Korswagen HC (2007) Migration of neuronal cells along the anterior-posterior body axis of C. elegans: Wnts are in control. Curr Opin Genet Dev 17: 320–325.
- 19. Zinovyeva AY, Yamamoto Y, Sawa H, Forrester WC (2008) Complex network of Wnt signaling regulates neuronal migrations during Caenorhabditis elegans development. Genetics 179: 1357–1371.
- 20. Sulston JE, Schierenberg E, White JG, Thomson JN (1983) The embryonic cell lineage of the nematode Caenorhabditis elegans. Dev Biol 100: 64–119.
- 21. Huang X, Powell-Coffman JA, Jin Y (2004) The AHR-1 aryl hydrocarbon receptor and its co-factor the AHA-1 aryl hydrocarbon receptor nuclear translocator specify GABAergic neuron cell fate in C. elegans. Development 131: 819–828.
- 22. Huang X, Cheng HJ, Tessier-Lavigne M, Jin Y (2002) MAX-1, a novel PH/MyTH4/FERM domain cytoplasmic protein implicated in netrin-mediated axon repulsion. Neuron 34: 563–576.
- 23. Jin Y, Hoskins R, Horvitz HR (1994) Control of type-D GABAergic neuron differentiation by C. elegans UNC-30 homeodomain protein. Nature 372: 780–783.
- 24. Eastman C, Horvitz HR, Jin Y (1999) Coordinated transcriptional regulation of the UNC-25 glutamic acid decarboxylase and the UNC-47 GABA vesicular transporter by the Caenorhabditis elegans UNC-30 homeodomain protein. J Neurosci 19: 6225–6234.
- 25. Ishii N, Wadsworth WG, Stern BD, Culotti JG, Hedgecock EM (1992) UNC-6, a laminin-related protein, guides cell and pioneer axon migrations in C. elegans. Neuron 9: 873–881.
- 26. Hao JC, Yu TW, Fujisawa K, Culotti JG, Gengyo-Ando K, et al. (2001) C. elegans Slit acts in midline, dorsal-ventral, and anterior-posterior guidance via the SAX-3/Robo receptor. Neuron 32: 25–38.
- 27. Gupta BP, Wang M, Sternberg PW (2003) The C. elegans LIM homeobox gene lin-11 specifies multiple cell fates during vulval development. Development 130: 2589–2601.
- 28. Hobert O, Tessmar K, Ruvkun G (1999) The Caenorhabditis elegans lim-6 LIM homeobox gene regulates neurite outgrowth and function of particular GABAergic neurons. Development 126: 1547–1562.
- 29. White JG, Southgate E, Thomson JN, Brenner S (1976) The structure of the ventral nerve cord of Caenorhabditis elegans. Philos Trans R Soc Lond B Biol Sci 275: 327–348.
- 30. Inoue T, Oz HS, Wiland D, Gharib S, Deshpande R, et al. (2004) C. elegans LIN-18 is a Ryk ortholog and functions in parallel to LIN-17/Frizzled in Wnt signaling. Cell 118: 795–806.
- 31. Burdine RD, Branda CS, Stern MJ (1998) EGL-17(FGF) expression coordinates the attraction of the migrating sex myoblasts with vulval induction in C. elegans. Development 125: 1083–1093.
- 32. Forrester WC, Dell M, Perens E, Garriga G (1999) A C. elegans Ror receptor tyrosine kinase regulates cell motility and asymmetric cell division. Nature 400: 881–885.
- 33. Koga M, Take-uchi M, Tameishi T, Ohshima Y (1999) Control of DAF-7 TGF-(alpha) expression and neuronal process development by a receptor tyrosine kinase KIN-8 in Caenorhabditis elegans. Development 126: 5387–5398.
- 34. Liu Y, Shi J, Lu CC, Wang ZB, Lyuksyutova AI, et al. (2005) Ryk-mediated Wnt repulsion regulates posterior-directed growth of corticospinal tract. Nat Neurosci 8: 1151–1159.
- 35. Green JL, Inoue T, Sternberg PW (2007) The C. elegans ROR receptor tyrosine kinase, CAM-1, non-autonomously inhibits the Wnt pathway. Development 134: 4053–4062.
- 36. Forrester WC, Kim C, Garriga G (2004) The Caenorhabditis elegans Ror RTK CAM-1 inhibits EGL-20/Wnt signaling in cell migration. Genetics 168: 1951–1962.
- 37. Coudreuse DY, Roel G, Betist MC, Destree O, Korswagen HC (2006) Wnt gradient formation requires retromer function in Wnt-producing cells. Science 312: 921–924.
- 38. Prasad BC, Clark SG (2006) Wnt signaling establishes anteroposterior neuronal polarity and requires retromer in C. elegans. Development 133: 1757–1766.
- 39. Ikeda S, Kishida S, Yamamoto H, Murai H, Koyama S, et al. (1998) Axin, a negative regulator of the Wnt signaling pathway, forms a complex with GSK-3beta and beta-catenin and promotes GSK-3beta-dependent phosphorylation of beta-catenin. EMBO J 17: 1371–1384.
- 40. Maro GS, Klassen MP, Shen K (2009) A beta-catenin-dependent Wnt pathway mediates anteroposterior axon guidance in C. elegans motor neurons. PLoS One 4: e4690. doi:10.1371/journal.pone.0004690.
- 41. Klassen MP, Shen K (2007) Wnt signaling positions neuromuscular connectivity by inhibiting synapse formation in C. elegans. Cell 130: 704–716.
- 42. Hedgecock EM, Culotti JG, Hall DH (1990) The unc-5, unc-6, and unc-40 genes guide circumferential migrations of pioneer axons and mesodermal cells on the epidermis in C. elegans. Neuron 4: 61–85.
- 43. Brenner S (1974) The genetics of Caenorhabditis elegans. Genetics 77: 71–94.