Genetic Interactions Between UNC-17/VAChT and a Novel Transmembrane Protein in Caenorhabditis elegans

The unc-17 gene encodes the vesicular acetylcholine transporter (VAChT) in Caenorhabditis elegans. unc-17 reduction-of-function mutants are small, slow growing, and uncoordinated. Several independent unc-17 alleles are associated with a glycine-to-arginine substitution (G347R), which introduces a positive charge in the ninth transmembrane domain (TMD) of UNC-17. To identify proteins that interact with UNC-17/VAChT, we screened for mutations that suppress the uncoordinated phenotype of UNC-17(G347R) mutants. We identified several dominant allele-specific suppressors, including mutations in the sup-1 locus. The sup-1 gene encodes a single-pass transmembrane protein that is expressed in a subset of neurons and in body muscles. Two independent suppressor alleles of sup-1 are associated with a glycine-to-glutamic acid substitution (G84E), resulting in a negative charge in the SUP-1 TMD. A sup-1 null mutant has no obvious deficits in cholinergic neurotransmission and does not suppress unc-17 mutant phenotypes. Bimolecular fluorescence complementation (BiFC) analysis demonstrated close association of SUP-1 and UNC-17 in synapse-rich regions of the cholinergic nervous system, including the nerve ring and dorsal nerve cords. These observations suggest that UNC-17 and SUP-1 are in close proximity at synapses. We propose that electrostatic interactions between the UNC-17(G347R) and SUP-1(G84E) TMDs alter the conformation of the mutant UNC-17 protein, thereby restoring UNC-17 function; this is similar to the interaction between UNC-17/VAChT and synaptobrevin.     

Translational Control of the Oogenic Program by Components of OMA Ribonucleoprotein Particles in Caenorhabditis elegans

The oocytes of most sexually reproducing animals arrest in meiotic prophase I. Oocyte growth, which occurs during this period of arrest, enables oocytes to acquire the cytoplasmic components needed to produce healthy progeny and to gain competence to complete meiosis. In the nematode Caenorhabditis elegans, the major sperm protein hormone promotes meiotic resumption (also called meiotic maturation) and the cytoplasmic flows that drive oocyte growth. Prior work established that two related TIS11 zinc-finger RNA-binding proteins, OMA-1 and OMA-2, are redundantly required for normal oocyte growth and meiotic maturation. We affinity purified OMA-1 and identified associated mRNAs and proteins using genome-wide expression data and mass spectrometry, respectively. As a class, mRNAs enriched in OMA-1 ribonucleoprotein particles (OMA RNPs) have reproductive functions. Several of these mRNAs were tested and found to be targets of OMA-1/2-mediated translational repression, dependent on sequences in their 3′-untranslated regions (3′-UTRs). Consistent with a major role for OMA-1 and OMA-2 in regulating translation, OMA-1-associated proteins include translational repressors and activators, and some of these proteins bind directly to OMA-1 in yeast two-hybrid assays, including OMA-2. We show that the highly conserved TRIM-NHL protein LIN-41 is an OMA-1-associated protein, which also represses the translation of several OMA-1/2 target mRNAs. In the accompanying article in this issue, we show that LIN-41 prevents meiotic maturation and promotes oocyte growth in opposition to OMA-1/2. Taken together, these data support a model in which the conserved regulators of mRNA translation LIN-41 and OMA-1/2 coordinately control oocyte growth and the proper spatial and temporal execution of the meiotic maturation decision.     

Genetics of Lipid-Storage Management in Caenorhabditis elegans Embryos

Lipids play a pivotal role in embryogenesis as structural components of cellular membranes, as a source of energy, and as signaling molecules. On the basis of a collection of temperature-sensitive embryonic lethal mutants, a systematic database search, and a subsequent microscopic analysis of >300 interference RNA (RNAi)–treated/mutant worms, we identified a couple of evolutionary conserved genes associated with lipid storage in Caenorhabditis elegans embryos. The genes include cpl-1 (cathepsin L–like cysteine protease), ccz-1 (guanine nucleotide exchange factor subunit), and asm-3 (acid sphingomyelinase), which is closely related to the human Niemann-Pick disease–causing gene SMPD1. The respective mutant embryos accumulate enlarged droplets of neutral lipids (cpl-1) and yolk-containing lipid droplets (ccz-1) or have larger genuine lipid droplets (asm-3). The asm-3 mutant embryos additionally showed an enhanced resistance against C band ultraviolet (UV-C) light. Herein we propose that cpl-1, ccz-1, and asm-3 are genes required for the processing of lipid-containing droplets in C. elegans embryos. Owing to the high levels of conservation, the identified genes are also useful in studies of embryonic lipid storage in other organisms.     

The Jaw of the Worm: GTPase-activating Protein EAT-17 Regulates Grinder Formation in Caenorhabditis elegans

Constitutive transport of cellular materials is essential for cell survival. Although multiple small GTPase Rab proteins are required for the process, few regulators of Rabs are known. Here we report that EAT-17, a novel GTPase-activating protein (GAP), regulates RAB-6.2 function in grinder formation in Caenorhabditis elegans. We identified EAT-17 as a novel RabGAP that interacts with RAB-6.2, a protein that presumably regulates vesicle trafficking between Golgi, the endoplasmic reticulum, and plasma membrane to form a functional grinder. EAT-17 has a canonical GAP domain that is critical for its function. RNA interference against 25 confirmed and/or predicted RABs in C. elegans shows that RNAi against rab-6.2 produces a phenotype identical to eat-17. A directed yeast two-hybrid screen using EAT-17 as bait and each of the 25 RAB proteins as prey identifies RAB-6.2 as the interacting partner of EAT-17, confirming that RAB-6.2 is a specific substrate of EAT-17. Additionally, deletion mutants of rab-6.2 show grinder defects identical to those of eat-17 loss-of-function mutants, and both RAB-6.2 and EAT-17 are expressed in the terminal bulb of the pharynx where the grinder is located. Collectively, these results suggest that EAT-17 is a specific GTPase-activating protein for RAB-6.2. Based on the conserved function of Rab6 in vesicular transport, we propose that EAT-17 regulates the turnover rate of RAB-6.2 activity in cargo trafficking for grinder formation.     

Asymmetric Neuroblast Divisions Producing Apoptotic Cells Require the Cytohesin GRP-1 in Caenorhabditis elegans

Cytohesins are Arf guanine nucleotide exchange factors (GEFs) that regulate membrane trafficking and actin cytoskeletal dynamics. We report here that GRP-1, the sole Caenorhabditis elegans cytohesin, controls the asymmetric divisions of certain neuroblasts that divide to produce a larger neuronal precursor or neuron and a smaller cell fated to die. In the Q neuroblast lineage, loss of GRP-1 led to the production of daughter cells that are more similar in size and to the transformation of the normally apoptotic daughter into its sister, resulting in the production of extra neurons. Genetic interactions suggest that GRP-1 functions with the previously described Arf GAP CNT-2 and two other Arf GEFs, EFA-6 and BRIS-1, to regulate the activity of Arf GTPases. In agreement with this model, we show that GRP-1’s GEF activity, mediated by its SEC7 domain, is necessary for the posterior Q cell (Q.p) neuroblast division and that both GRP-1 and CNT-2 function in the Q.posterior Q daughter cell (Q.p) to promote its asymmetry. Although functional GFP-tagged GRP-1 proteins localized to the nucleus, the extra cell defects were rescued by targeting the Arf GEF activity of GRP-1 to the plasma membrane, suggesting that GRP-1 acts at the plasma membrane. The detection of endogenous GRP-1 protein at cytokinesis remnants, or midbodies, is consistent with GRP-1 functioning at the plasma membrane and perhaps at the cytokinetic furrow to promote the asymmetry of the divisions that require its function.     

Caenorhabditis elegans PIG-1/MELK Acts in a Conserved PAR-4/LKB1 Polarity Pathway to Promote Asymmetric Neuroblast Divisions

Asymmetric cell divisions produce daughter cells with distinct sizes and fates, a process important for generating cell diversity during development. Many Caenorhabditis elegans neuroblasts, including the posterior daughter of the Q cell (Q.p), divide to produce a larger neuron or neuronal precursor and a smaller cell that dies. These size and fate asymmetries require the gene pig-1, which encodes a protein orthologous to vertebrate MELK and belongs to the AMPK-related family of kinases. Members of this family can be phosphorylated and activated by the tumor suppressor kinase LKB1, a conserved polarity regulator of epithelial cells and neurons. In this study, we present evidence that the C. elegans orthologs of LKB1 (PAR-4) and its partners STRAD (STRD-1) and MO25 (MOP-25.2) regulate the asymmetry of the Q.p neuroblast division. We show that PAR-4 and STRD-1 act in the Q lineage and function genetically in the same pathway as PIG-1. A conserved threonine residue (T169) in the PIG-1 activation loop is essential for PIG-1 activity, consistent with the model that PAR-4 (or another PAR-4-regulated kinase) phosphorylates and activates PIG-1. We also demonstrate that PIG-1 localizes to centrosomes during cell divisions of the Q lineage, but this localization does not depend on T169 or PAR-4. We propose that a PAR-4-STRD-1 complex stimulates PIG-1 kinase activity to promote asymmetric neuroblast divisions and the generation of daughter cells with distinct fates. Changes in cell fate may underlie many of the abnormal behaviors exhibited by cells after loss of PAR-4 or LKB1.     

Asymmetric Wnt Pathway Signaling Facilitates Stem Cell-Like Divisions via the Nonreceptor Tyrosine Kinase FRK-1 in Caenorhabditis elegans

Asymmetric cell division is critical during development, as it influences processes such as cell fate specification and cell migration. We have characterized FRK-1, a homolog of the mammalian Fer nonreceptor tyrosine kinase, and found it to be required for differentiation and maintenance of epithelial cell types, including the stem cell-like seam cells of the hypodermis. A genomic knockout of frk-1, allele ok760, results in severely uncoordinated larvae that arrest at the L1 stage and have an excess number of lateral hypodermal cells that appear to have lost asymmetry in the stem cell-like divisions of the seam cell lineage. frk-1(ok760) mutants show that there are excess lateral hypodermal cells that are abnormally shaped and smaller in size compared to wild type, a defect that could be rescued only in a manner dependent on the kinase activity of FRK-1. Additionally, we observed a significant change in the expression of heterochronic regulators in frk-1(ok760) mutants. However, frk-1(ok760) mutants do not express late, nonseam hypodermal GFP markers, suggesting the seam cells do not precociously differentiate as adult-hyp7 cells. Finally, our data also demonstrate a clear role for FRK-1 in seam cell proliferation, as eliminating FRK-1 during the L3–L4 transition results in supernumerary seam cell nuclei that are dependent on asymmetric Wnt signaling. Specifically, we observe aberrant POP-1 and WRM-1 localization that is dependent on the presence of FRK-1 and APR-1. Overall, our data suggest a requirement for FRK-1 in maintaining the identity and proliferation of seam cells primarily through an interaction with the asymmetric Wnt pathway.     

Systematic Analyses of rpm-1 Suppressors Reveal Roles for ESS-2 in mRNA Splicing in Caenorhabditis elegans

The PHR (Pam/Highwire/RPM-1) family of ubiquitin E3 ligases plays conserved roles in axon patterning and synaptic development. Genetic modifier analysis has greatly aided the discovery of the signal transduction cascades regulated by these proteins. In Caenorhabditis elegans, loss of function in rpm-1 causes axon overgrowth and aberrant presynaptic morphology, yet the mutant animals exhibit little behavioral deficits. Strikingly, rpm-1 mutations strongly synergize with loss of function in the presynaptic active zone assembly factors, syd-1 and syd-2, resulting in severe locomotor deficits. Here, we provide ultrastructural evidence that double mutants, between rpm-1 and syd-1 or syd-2, dramatically impair synapse formation. Taking advantage of the synthetic locomotor defects to select for genetic suppressors, previous studies have identified the DLK-1 MAP kinase cascade negatively regulated by RPM-1. We now report a comprehensive analysis of a large number of suppressor mutations of this screen. Our results highlight the functional specificity of the DLK-1 cascade in synaptogenesis. We also identified two previously uncharacterized genes. One encodes a novel protein, SUPR-1, that acts cell autonomously to antagonize RPM-1. The other affects a conserved protein ESS-2, the homolog of human ES2 or DGCR14. Loss of function in ess-2 suppresses rpm-1 only in the presence of a dlk-1 splice acceptor mutation. We show that ESS-2 acts to promote accurate mRNA splicing when the splice site is compromised. The human DGCR14/ES2 resides in a deleted chromosomal region implicated in DiGeorge syndrome, and its mutation has shown high probability as a risk factor for schizophrenia. Our findings provide the first functional evidence that this family of proteins regulate mRNA splicing in a context-specific manner.     

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

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_qα 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.ANIMALS show various behaviors in response to environmental cues and modulate behaviors according to previous experience. To understand neuronal plasticity underlying learning, it is important to dissect neurons and molecules for sensing environmental stimuli, storing memory, and executing learned behaviors.The nematode Caenorhabditis elegans has only 302 neurons and functions of sensory neurons are well characterized (White et al. 1986; Bargmann 2006). C. elegans is attracted to odorants sensed by the AWC olfactory neurons or to salts sensed by the ASE gustatory neurons (Bargmann and Horvitz 1991; Bargmann et al. 1993). The ASE neuron class consists of a bilaterally symmetrical pair, ASE-left (ASEL) and ASE-right (ASER), which sense different sets of ions including Na⁺ and Cl⁻, respectively (Pierce-Shimomura et al. 2001; Suzuki et al. 2008; Ortiz et al. 2009). ASEL is activated by an increase in salt concentration, whereas ASER is activated by a decrease in salt concentration (Suzuki et al. 2008). In the ASE gustatory neurons, a cyclic GMP (cGMP) signaling pathway mediates sensory transduction (Komatsu et al. 1996; Suzuki et al. 2008; Ortiz et al. 2009). ASEL and ASER express different sets of receptor-type guanylyl cyclases (gcys) (Ortiz et al. 2006). Of these, gcy-22, which is specifically expressed in ASER, is important for attraction to ASER-sensed ions such as Cl⁻ (Ortiz et al. 2009).Preference for salts changes according to previous experience (known as gustatory plasticity or salt chemotaxis learning) (Saeki et al. 2001; Jansen et al. 2002; Tomioka et al. 2006). When worms are grown on a medium that contains sodium chloride (NaCl) and food (Escherichia coli), they show attraction to NaCl by using ASE neurons (Bargmann and Horvitz 1991; Suzuki et al. 2008). In contrast, after exposure to the salt under starvation conditions, they show reduced attraction to or even avoid the salt (Saeki et al. 2001; Jansen et al. 2002; Tomioka et al. 2006). In C. elegans, it was proposed that preference for a sensory cue is defined by the sensory neuron that detects the cue (Troemel et al. 1997). ASE neurons play a major role for salt attraction (Bargmann and Horvitz 1991; Suzuki et al. 2008; Ortiz et al. 2009). However, little is known about sensory neurons that drive the learned salt avoidance; it remains unclear whether ASE neurons act as salt receptors for the learned avoidance.We have previously shown that an insulin/PI 3-kinase signaling pathway is essential for salt chemotaxis learning (Tomioka et al. 2006). In C. elegans, the insulin-like signaling is composed of daf-2, age-1, and akt-1, which encode homologs of insulin receptor, PI 3-kinase, and protein kinase B, respectively (Morris et al. 1996; Kimura et al. 1997; Paradis and Ruvkun 1998). Mutants of daf-2, age-1, and akt-1 show attraction to salt even after starvation/NaCl conditioning (Tomioka et al. 2006).daf-18 encodes a homolog of phosphatase PTEN (phosphatase and tensin homolog deleted on chromosome ten), which dephosphorylates phosphatidylinositol (3,4,5)-triphosphate and counteracts the insulin/PI 3-kinase signaling (Ogg and Ruvkun 1998; Gil et al. 1999; Mihaylova et al. 1999; Rouault et al. 1999; Solari et al. 2005). Mutants of daf-18, in which the PI 3-kinase signaling is activated, show reduced attraction to NaCl even without conditioning. Since the insulin/PI 3-kinase signaling acts in ASER, we proposed that the insulin/PI 3-kinase signaling attenuates the attractive drive of ASER (Tomioka et al. 2006).In C. elegans, diacylglycerol (DAG) regulates functions of motor neurons and sensory neurons. egl-30, which encodes the α-subunit of heterotrimeric G-protein G_q, facilitates production of DAG and enhances locomotory movements (Brundage et al. 1996; Lackner et al. 1999). In the AWC olfactory neurons, a novel protein kinase C-ɛ/η (nPKC-ɛ/η) ortholog TTX-4 (also known as PKC-1), which is one of DAG targets, plays an essential role in attraction behavior to AWC-sensed odors (Okochi et al. 2005; Tsunozaki et al. 2008). GOA-1 G_oα regulates olfactory adaptation by antagonizing G_qα–DAG signaling (Matsuki et al. 2006).This study investigated the involvement of the ASE taste receptor neurons in the starvation-induced salt avoidance. We show that both ASEL and ASER contribute to salt chemotaxis learning. Activation of the PI 3-kinase signaling and the G_q/DAG/PKC signaling acted antagonistically in reversal of ASER function, whereas these signaling pathways did not have prominent effects on ASEL function. In ASER, GCY-22 was required for both salt attraction and avoidance. These results suggest that ASE neurons are important for bidirectional chemotaxis and also suggest that distinct molecular mechanisms regulate functions of ASEL and ASER in salt chemotaxis learning.     

toca-1 Is in a Novel Pathway That Functions in Parallel with a SUN-KASH Nuclear Envelope Bridge to Move Nuclei in Caenorhabditis elegans

Moving the nucleus to an intracellular location is critical to many fundamental cell and developmental processes, including cell migration, differentiation, fertilization, and establishment of cellular polarity. Bridges of SUN and KASH proteins span the nuclear envelope and mediate many nuclear positioning events, but other pathways function independently through poorly characterized mechanisms. To identify and characterize novel mechanisms of nuclear migration, we conducted a nonbiased forward genetic screen for mutations that enhanced the nuclear migration defect of unc-84, which encodes a SUN protein. In Caenorhabditis elegans larvae, failure of hypodermal P-cell nuclear migration results in uncoordinated and egg-laying–defective animals. The process of P-cell nuclear migration in unc-84 null animals is temperature sensitive; at 25° migration fails in unc-84 mutants, but at 15° the migration occurs normally. We hypothesized that an additional pathway functions in parallel to the unc-84 pathway to move P-cell nuclei at 15°. In support of our hypothesis, forward genetic screens isolated eight emu (enhancer of the nuclear migration defect of unc-84) mutations that disrupt nuclear migration only in a null unc-84 background. The yc20 mutant was determined to carry a mutation in the toca-1 gene. TOCA-1 functions to move P-cell nuclei in a cell-autonomous manner. TOCA-1 is conserved in humans, where it functions to nucleate and organize actin during endocytosis. Therefore, we have uncovered a player in a previously unknown, likely actin-dependent, pathway that functions to move nuclei in parallel to SUN-KASH bridges. The other emu mutations potentially represent other components of this novel pathway.     

A Genome-Wide RNAi Screen for Enhancers of par Mutants Reveals New Contributors to Early Embryonic Polarity in Caenorhabditis elegans

The par genes of Caenorhabditis elegans are essential for establishment and maintenance of early embryo polarity and their homologs in other organisms are crucial polarity regulators in diverse cell types. Forward genetic screens and simple RNAi depletion screens have identified additional conserved regulators of polarity in C. elegans; genes with redundant functions, however, will be missed by these approaches. To identify such genes, we have performed a genome-wide RNAi screen for enhancers of lethality in conditional par-1 and par-4 mutants. We have identified 18 genes for which depletion is synthetically lethal with par-1 or par-4, or both, but produces little embryo lethality in wild type. Fifteen of the 18 genes identified in our screen are not previously known to function in C. elegans embryo polarity and 11 of them also increase lethality in a par-2 mutant. Among the strongest synthetic lethal genes, polarity defects are more apparent in par-2 early embryos than in par-1 or par-4, except for strd-1(RNAi), which enhances early polarity phenotypes in all three mutants. One strong enhancer of par-1 and par-2 lethality, F25B5.2, corresponds to nop-1, a regulator of actomyosin contractility for which the molecular identity was previously unknown. Other putative polarity enhancers identified in our screen encode cytoskeletal and membrane proteins, kinases, chaperones, and sumoylation and deubiquitylation proteins. Further studies of these genes should give mechanistic insight into pathways regulating establishment and maintenance of cell polarity.     

Functional Genomic Identification of Genes Required for Male Gonadal Differentiation in Caenorhabditis elegans

The Caenorhabditis elegans somatic gonad develops from a four-cell primordium into a mature organ that differs dramatically between the sexes in overall morphology (two arms in hermaphrodites and one in males) and in the cell types comprising it. Gonadal development in C. elegans is well studied, but regulation of sexual differentiation, especially later in gonadal development, remains poorly elucidated. To identify genes involved in this process, we performed a genome-wide RNAi screen using sex-specifically expressed gonadal GFP reporters. This screen identified several phenotypic classes, including ∼70 genes whose depletion feminized male gonadal cells. Among the genes required for male cell fate specification are Wnt/β-catenin pathway members, cell cycle regulators, and genes required for mitotic spindle function and cytokinesis. We find that a Wnt/β-catenin pathway independent of extracellular Wnt ligand is essential for asymmetric cell divisions and male differentiation during gonadal development in larvae. We also find that the cell cycle regulators cdk-1 and cyb-3 and the spindle/cytokinesis regulator zen-4 are required for Wnt/β-catenin pathway activity in the developing gonad. After sex is determined in the gonadal primordium the global sex determination pathway is dispensable for gonadal sexual fate, suggesting that male cell fates are promoted and maintained independently of the global pathway during this period.THE Caenorhabditis elegans gonad derives from a simple primordium of four cells that coalesces during embryogenesis and contains two somatic gonad precursors (SGPs), Z1 and Z4, flanking two germline precursors, Z2 and Z3 (Kimble and Hirsh 1979). The SGPs undergo very different developmental programs in each sex, involving sexually dimorphic cell lineages and migrations and sex-specific cellular differentiation. The result is a two-armed bilaterally symmetrical gonad in the adult hermaphrodite or a single-armed asymmetric gonad in the adult male. The high degree of sexual dimorphism of the mature organ and variety of cellular events that occur sex specifically during its development make the C. elegans gonad an outstanding model for sex-specific organogenesis.Development of the somatic gonad occurs in two phases. The early phase defines the gonadal axes and establishes the precursors of the major gonadal cell types. This takes place during the first larval stage (L1), beginning shortly after hatching with the first division of the SGPs. In both sexes SGP division is asymmetric in terms of both the sizes and the fates of the daughter cells, and establishes the proximal/distal axis of the gonad (Hirsh et al. 1976; Kimble and Hirsh 1979). The global sex determination pathway establishes the future sex of the gonad around the time of hatching (Klass et al. 1976; Nelson et al. 1978), and sexual dimorphism is already apparent when the SGPs divide: the size asymmetry of the SGP daughters is much more pronounced in males than hermaphrodites. In both sexes the asymmetry of the first SGP division requires a Wnt/β-catenin pathway. Mutations compromising this pathway cause a “symmetrical sisters” phenotype in which both daughters adopt the same fate (Miskowski et al. 2001; Siegfried and Kimble 2002; Phillips and Kimble 2009). Sex specificity is imposed on the SGPs by the global sex determining gene tra-1 (Hodgkin 1987) and the gonad-specific sex determining gene fkh-6 (Chang et al. 2004). These genes play opposing roles in SGP sex determination, with tra-1 feminizing and fkh-6 masculinizing the somatic gonad, and they also act redundantly to promote mitotic proliferation of the SGP lineage (Chang et al. 2004). SGP sex determination is linked to cell cycle progression by cyclin D, which is required to overcome repression of fkh-6 expression in the SGPs by E2F (Tilmann and Kimble 2005).The later phase of gonadal development involves the elongation of the gonad, together with cellular proliferation and differentiation, and lasts from L2 to adulthood. During L2 the somatic cells enlarge and leader cells (distal tip cells in the hermaphrodite, linker cell in the male) begin long-range migrations that extend the gonad. During L3, somatic gonad cell division resumes in both sexes, leading to the formation of differentiated somatic cell types by the end of L3 or beginning of L4. Gonadal morphogenesis is completed and gametogenesis begins during L4 (Kimble and Hirsh 1979).Although SGP division and much of hermaphrodite gonadal development have been well studied (Hubbard and Greenstein 2000), sexual cell fate specification in the somatic gonad is more poorly understood, particularly after the L1 stage. Despite the importance of fkh-6 in promoting male differentiation, it is expressed in males only during early L1 and null mutants have incomplete gonadal sex reversal. We have therefore performed a genome-wide RNAi screen to identify additional genes required after hatching for gonadal development in each sex. Among the advantages of this approach is the ability to identify gonadal regulators that also are essential for embryonic development. To our knowledge this is the first functional genomic study of gonadal sex differentiation.The screen identified many genes whose depletion disrupts gonadogenesis in each sex and nearly 70 genes whose depletion causes gonadal feminization in males. Prominent among this latter class were components of a Wnt/β-catenin pathway, cell cycle regulators, and genes involved in mitotic spindle function and cytokinesis. We find that Wnt/β-catenin activity continues in both sexes after SGP division and is required for male cell fate commitment in the gonad. We also find that the cyclin-dependent kinase cdk-1 and its cognate cyclin cyb-3 as well as the mitotic spindle regulator zen-4 are required for gonadal Wnt/β-catenin pathway activity, providing a potential new link between the cell cycle, asymmetric division, and sexual differentiation. The feminization caused by depletion of Wnt/β-catenin pathway components or cdk-1 is independent of the global sex determination pathway, suggesting that sexual fates in the male gonad remain plastic after the primary sex determination decision.