Ras effector switching promotes divergent cell fates in C. elegans vulval patterning

The C. elegans vulva is patterned by epidermal growth factor (EGF) activation of Ras to control 1° fate, and 1° fate induces antagonistic Notch-dependent 2° fate. Furthermore, a spatial EGF gradient, in addition to inducing 1° fate, directly contributes to 2° fate via an unknown pathway. We find that in addition to its canonical effector, Raf, vulval Ras utilizes an exchange factor for the Ral small GTPase (RalGEF), such that Ras-RalGEF-Ral antagonizes Ras-Raf pro-1° fate activity. Consistent with its restricted expression pattern, Ral participates in EGF pro-2° activity. Thus, we have delineated a Ras effector-switching mechanism whereby position within the morphogen gradient dictates that Ras effector usage is switched to RalGEF from Raf to promote 2° instead of 1° fate. Our observations define the utility of Ras effector switching during normal development and may provide a possible mechanistic basis for cell and cancer-type differences in effector dependency and activation.     

Pattern formation during vulval development in C. elegans

Previous studies have shown that the development of the vulva of the C. elegans hermaphrodite involves six multipotential hypodermal cells as well as the gonadal anchor cell, which induces vulval formation. Our further examination of the interactions among these seven cells has led to the following model. Each hypodermal precursor cell becomes determined to adopt one of its three potential fates; each of these fates is to generate a particular cell lineage. In the absence of cellular interactions each precursor cell will generate the nonvulval cell lineage; an inductive signal from the anchor cell is required for a precursor cell to generate either of the two types of vulval cell lineages. The inductive signal is spatially graded, and the potency of the signal specifies which lineage is expressed by each of the tripotential precursor cells.     

Signal transduction during C. elegans vulval induction.

Nematode proteins related to the human epidermal growth factor receptor and Ras proteins act in a common pathway to control cell fates in response to an inductive signal. Analysis of these gene products during C. elegans vulval induction allows detailed study of their function in the context of a developing organism.     

The C. elegans Mi-2 chromatin-remodelling proteins function in vulval cell fate determination

The Mi-2 protein is the central component of the recently isolated NuRD nucleosome remodelling and histone deacetylase complex. Although the NuRD complex has been the subject of extensive biochemical analyses, little is known about its biological function. Here we show that the two C. elegans Mi-2 homologues, LET-418 and CHD-3, play essential roles during development. The two proteins possess both shared and unique functions during vulval cell fate determination, including antagonism of the Ras signalling pathway required for vulval cell fate induction and the proper execution of the 2 degrees cell fate of vulval precursor cells, a process under the control of LIN-12 Notch signalling.     

C. elegans PlexinA PLX-1 mediates a cell contact-dependent stop signal in vulval precursor cells

PLX-1 is a PlexinA transmembrane protein in Caenorhabditis elegans, and the transmembrane-type semaphorin, SMP-1, is a ligand for PLX-1. The SMP-1/PLX-1 system has been shown to be necessary for proper epidermal morphogenesis in the male tail and seam cells. Here, we show that the SMP-1/PLX-1 system also regulates vulval morphogenesis. In plx-1 and smp-1 mutants, hermaphrodites sometimes exhibit a protruding vulva or multiple vulva-like protrusions. Throughout the vulval development of plx-1 and smp-1 mutants, the arrangement of vulval cells is often disrupted. In the initial step of vulval morphogenesis, vulval precursor cells (VPCs) are generated normally but are subsequently arranged abnormally in mutants. Continuous observation revealed that plx-1 VPC fails to terminate longitudinal extension after making contact with neighbor VPCs. The arrangement defects of VPCs in plx-1 and smp-1 mutants are rescued by expressing the respective cDNA in VPCs. plx-1::egfp and smp-1::egfp transgenes are both expressed in all vulval cells, including VPCs, throughout vulval development. We propose that the SMP-1/PLX-1 system is responsible for a cell contact-mediated stop signal for VPC extension. Analyses using cell fate-specific markers showed that the arrangement defects of VPCs also affect cell fate specification and cell lineages, but in a relatively small fraction of plx-1 mutants.     

Predictive modeling of signaling crosstalk during C. elegans vulval development

Caenorhabditis elegans vulval development provides an important paradigm for studying the process of cell fate determination and pattern formation during animal development. Although many genes controlling vulval cell fate specification have been identified, how they orchestrate themselves to generate a robust and invariant pattern of cell fates is not yet completely understood. Here, we have developed a dynamic computational model incorporating the current mechanistic understanding of gene interactions during this patterning process. A key feature of our model is the inclusion of multiple modes of crosstalk between the epidermal growth factor receptor (EGFR) and LIN-12/Notch signaling pathways, which together determine the fates of the six vulval precursor cells (VPCs). Computational analysis, using the model-checking technique, provides new biological insights into the regulatory network governing VPC fate specification and predicts novel negative feedback loops. In addition, our analysis shows that most mutations affecting vulval development lead to stable fate patterns in spite of variations in synchronicity between VPCs. Computational searches for the basis of this robustness show that a sequential activation of the EGFR-mediated inductive signaling and LIN-12 / Notch-mediated lateral signaling pathways is key to achieve a stable cell fate pattern. We demonstrate experimentally a time-delay between the activation of the inductive and lateral signaling pathways in wild-type animals and the loss of sequential signaling in mutants showing unstable fate patterns; thus, validating two key predictions provided by our modeling work. The insights gained by our modeling study further substantiate the usefulness of executing and analyzing mechanistic models to investigate complex biological behaviors.     

The C. elegans LIM homeobox gene lin-11 specifies multiple cell fates during vulval development

LIM homeobox family members regulate a variety of cell fate choices during animal development. In C. elegans, mutations in the LIM homeobox gene lin-11 have previously been shown to alter the cell division pattern of a subset of the 2 degrees lineage vulval cells. We demonstrate multiple functions of lin-11 during vulval development. We examined the fate of vulval cells in lin-11 mutant animals using five cellular markers and found that lin-11 is necessary for the patterning of both 1 degrees and 2 degrees lineage cells. In the absence of lin-11 function, vulval cells fail to acquire correct identity and inappropriately fuse with each other. The expression pattern of lin-11 reveals dynamic changes during development. Using a temporally controlled overexpression system, we show that lin-11 is initially required in vulval cells for establishing the correct invagination pattern. This process involves asymmetric expression of lin-11 in the 2 degrees lineage cells. Using a conditional RNAi approach, we show that lin-11 regulates vulval morphogenesis. Finally, we show that LDB-1, a NLI/Ldb1/CLIM2 family member, interacts physically with LIN-11, and is necessary for vulval morphogenesis. Together, these findings demonstrate that temporal regulation of lin-11 is crucial for the wild-type vulval patterning.     

The Caenorhabditis elegans EGL-26 protein mediates vulval cell morphogenesis.

In screens for Caenorhabditis elegans mutants defective in vulval morphogenesis, we isolated multiple mutants in which the uterus and the vulva fail to make a functional connection, resulting in an egg-laying defective phenotype. Two of these connection of gonad defective (Cog) mutants carry alleles of the egl-26 gene. We demonstrate that vulval lineages in egl-26 mutant animals are normal, but one vulval cell, vulF, adopts an abnormal morphology. This results in formation of an abnormally thick layer of vulval tissue at the apex of the vulva and a physical blockage of the exit to the vulva from the uterus. egl-26 was cloned and is predicted to encode a novel protein. Mosaic analysis indicates that egl-26 activity is required in the primary vulval lineage for vulF morphogenesis. Expression of a functional translational fusion of EGL-26 to GFP was observed within the primary vulval lineage only in vulE, which neighbors vulF. EGL-26 is localized at the apical edge of the vulE cell. It is thus possible that vulE acts to instruct morphological changes in the neighboring cell, vulF, in an interaction mediated by EGL-26.     

Chromatin regulation and sumoylation in the inhibition of Ras-induced vulval development in C. elegans

Correction to: The EMBO Journal (2005) 24, 2613–2623. doi:10.1038/sj.emboj.7600726The authors have discovered an error in the above article.In our original paper, we inadvertently left out references for the ‘Essential gene'' column of Table 1New and previously studied synMuv genes     

The combined action of two intercellular signaling pathways specifies three cell fates during vulval induction in C. elegans

Each of the six C. elegans vulval precursor cells (VPCs) has three potential fates (1 degree, 2 degrees, or 3 degrees). The fate of each VPC depends on two types of signals: a graded inductive signal that acts at a distance and a short-range lateral signal among the VPCs. We describe interactions among mutations that cause different misspecifications of VPC fates. Particular combinations of mutations cause all six VPCs to have a single fate independent of their positions. Our results suggest that specification of the three VPC fates is accomplished by two binary decisions, each effected by one of the two signaling pathways. The gene lin-12 acts in the lateral signaling pathway and specifies 2 degrees. The "vulvaless" and "multivulva" genes act in the inductive signaling pathway and specify 1 degree independently of lin-12 and 2 degrees via lin-12. We describe a model for the regulatory circuitry underlying VPC determination that includes a role for lin-12 in both autocrine and paracrine VPC signaling.     

High sensitivity of C. elegans vulval precursor cells to the dose of posterior Wnts

Cell competence is a key developmental property. The Caenorhabditis elegans vulval competence group consists of P(3–8).p, six cells aligned along the antero-posterior axis in a wide central body region. The six cells are not equal in their competence: 1) P3.p quits the competence group in half of the individuals; 2) the posterior cells P7.p and P8.p are less competent than central vulval precursor cells. Competence to adopt a vulval fate is controlled by expression of the HOM-C gene lin-39, and maintained through Wnt signals that are secreted from the tail in a long-range gradient. Here we quantify the LIN-39 protein profile in vulval precursor cells of early L2 stage larvae, prior to P3.p fusion and inductive signaling. We show that LIN-39 levels are very low in P3.p and P4.p, peak in P5.p and progressively decrease until P8.p. This unexpectedly centered profile arises independently from the gonad. Posterior Wnt signaling reduces LIN-39 level in the posterior cells by activating the next-posterior HOM-C gene, mab-5. On the anterior side, P3.p and P4.p competence and division are sensitive to the already low LIN-39 and Wnt doses; most dramatically, each of the cwn-1/Wnt and egl-20/Wnt genes show haplo-insufficience for P3.p fate. In contrast to previous results, we find that these Wnts maintain P3.p and P4.p competence without affecting their LIN-39 level. The centered vulval competence profile is thus under the control of the posterior Wnts and of cross-regulation of three HOM-C genes and prepatterns the later induction of vulval fates.     

Distinct roles of the Pumilio and FBF translational repressors during C. elegans vulval development

The C. elegans PUF and FBF proteins regulate various aspects of germline development by selectively binding to the 3' untranslated region of their target mRNAs and repressing translation. Here, we show that puf-8, fbf-1 and fbf-2 also act in the soma where they negatively regulate vulvaI development. Loss-of-function mutations in puf-8 cause ectopic vulval differentiation when combined with mutations in negative regulators of the EGFR/RAS/MAPK pathway and suppress the vulvaless phenotype caused by mutations that reduce EGFR/RAS/MAPK signalling. PUF-8 acts cell-autonomously in the vulval cells to limit their temporal competence to respond to the extrinsic patterning signals. fbf-1 and fbf-2, however, redundantly inhibit primary vulval cell fate specification in two distinct pathways acting in the soma and in the germline. The FBFs thereby ensure that the inductive signal selects only one vulval precursor cell for the primary cell fate. Thus, translational repressors regulate various aspects of vulval cell fate specification, and they may play a conserved role in modulating signal transduction during animal development.