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[
West Coast Worm Meeting,
2004]
In C. elegans epidermal intermediate filaments (IFs) and their associated structures, the trans-epidermal attachments, are essential for embryonic epidermal elongation (Woo et al 2004). The formation of muscle contractile units and trans-epidermal attachments are mutually dependent during epidermal elongation. To understand how the connection between epidermis and muscle is established and how the two tissues communicate during organogenesis, we performed a screen for epidermal elongation-defective mutants. One locus identified in this screen was defined by three lethal alleles and mapped to the cluster of LG II. Subsequent analysis showed that these mutations were allelic to
vab-13 and
ven-3 . By genetic mapping and allele sequencing we showed that all these mutations affect F10E7.4, which encodes the C. elegans member of the F-spondin family of secreted proteins. F-spondin has been shown to play roles in axon guidance, cell migration, and angiogenesis. Our genetic analysis shows that in C. elegans F-spondin is required for epidermal elongation and muscle attachment, as well as for proper positioning of neuronal processes. Using GFP reporters, we found that F-spondin is expressed in body muscle cells and is a secreted protein. Thus, F-spondin may function in embryogenesis in communication between muscle and epidermis. Immunostaining of F-spondin mutants suggest that F-spondin may indirectly affect the organization of epidermal actin microfilaments and trans-epidermal attachments . We are examining the expression patterns of muscle and basement membrane components in F-spondin mutants. To study the signaling pathways regulated by F-spondin, we are testing mutations in candidate receptor genes for genetic interactions with F-spondin mutations.
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[
C.elegans Neuronal Development Meeting,
2008]
Release of neurotransmitters from neurons is highly regulated. Several proteins play roles in this process, including UNC-13, and decreased release of neurotransmitters in
unc-13 mutants results in paralysis. We identified an F-box protein that interacts with UNC-13. F-box proteins participate in ubiquitin ligase complexes and in Drosophila, DUNC-13 is degraded via the ubiquitin proteasome pathway. This UNC-13/F-box interaction may therefore indicate that UNC-13 is tagged for proteasomal degradation with ubiquitin by the ligase complex in C. elegans. The C. elegans knockout consortium isolated a strain with a large deletion in the coding region of the gene that codes for the F-box protein. If the F-box protein is indeed involved in the degradation of UNC-13, this strain would be expected to have higher levels of UNC-13, which could result in changes in phenotypes. We characterized the F-box deletion mutant by assaying brood size, developmental rate, and body bends per minute. Aldicarb assays were used to determine whether a deletion in the gene coding for the F-box protein alters the response to inhibitors of acetylcholinesterase. We found that the deletion resulted in some changes in developmental rate and in aldicarb sensitivity. We are continuing to study strains with mutations in both the gene coding for the F-box protein and in
unc-13.
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[
International Worm Meeting,
2005]
We have developed a systematic approach for inferring cis-regulatory logic from whole-genome microarray expression data.[1] This approach identifies local DNA sequence elements and the combinatorial and positional constraints that determine their context-dependent role in transcriptional regulation. We use a Bayesian probabilistic framework that relates general DNA sequence features to mRNA expression patterns. By breaking the expression data into training and test sets of genes, we are able to evaluate the predictive accuracy of our inferred Bayesian network. Applied to S. cerevisiae, our inferred combinatorial regulatory rules correctly predict expression patterns for most of the genes. Applied to microarray data from C. elegans[2], we identify novel regulatory elements and combinatorial rules that control the phased temporal expression of transcription factors, histones, and germline specific genes during embryonic and larval development. While many of the DNA elements we find in S. cerevisiae are known transcription factor binding sites, the vast majority of the DNA elements we find in C. elegans and the inferred regulatory rules are novel, and provide focused mechanistic hypotheses for experimental validation. Successful DNA element detection is a limiting factor in our ability to infer predictive combinatorial rules, and the larger regulatory regions in C. elegans make this more challenging than in yeast. Here we extend our previous algorithm to explicitly use conservation of regulatory regions in C. briggsae to focus the search for DNA elements. In addition, we expand the range of regulatory programs we identify by applying to more diverse microarray datasets.[3] 1. Beer MA and Tavazoie S. Cell 117, 185-198 (2004). 2. Baugh LR, Hill AA, Slonim DK, Brown EL, and Hunter, CP. Development 130, 889-900 (2003); Hill AA, Hunter CP, Tsung BT, Tucker-Kellogg G, and Brown EL. Science 290, 809812 (2000). 3. Baugh LR, Hill AA, Claggett JM, Hill-Harfe K, Wen JC, Slonim DK, Brown EL, and Hunter, CP. Development 132, 1843-1854 (2005); Murphy CT, McCarroll SA, Bargmann CI, Fraser A, Kamath RS, Ahringer J, Li H, and Kenyon C. Nature 424 277-283 (2003); Reinke V, Smith HE, Nance J, Wang J, Van Doren C, Begley R, Jones SJ, Davis EB, Scherer S, Ward S, and Kim SK. Mol Cell 6 605-616 (2000).
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[
International Worm Meeting,
2005]
Actin has been shown to play key roles during early development in the C. elegans embryo (Schneider and Bowerman, 2003). However, it has been difficult to faithfully reproduce F-actin dynamics in vivo during early embryogenesis. To visualize F-actin we have generated a transgenic line that uses the F-actin binding domain of Drosophila moesin to decorate endogenous actin filaments with GFP (GFP::Moe). The GFP::Moe fusion line appears to be specific for filamentous actin and allows the visualization of F-actin dynamics in C. elegans in embryos. Preliminary evidence shows that F-actin is very dynamic in many cellular processes from prior to fertilization through the first mitotic cellular division. During fertilization a posterior actin cap forms and then dissipates. Prior to the first cell division F-actin becomes enriched in the anterior, similar to the anterior PAR proteins. As seen in
par-3 mutants (Kirby et. al., 1990), depleting the embryo of PAR-6 with RNAi prevents this enrichment, suggesting that PAR-6 and the other anterior PARs may be required for F-actin to accumulate in the anterior. We have also observed the presence of highly dynamic actin comets in the early embryo. Preliminary evidence suggests that these comets may be involved with endocytic processes. Using results from large-scale RNAi surveys, we are employing the GFP::Moe line to perform secondary screening of genes associated with pseudocleavage defects to further characterize this process. We will present our progress in using this GFP::Moe line to study genetic interactions involving actin dynamics in early development.
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[
International C. elegans Meeting,
2001]
The ubiuquitin-proteasome pathway is a key mechanism for substrate-specific degradation to control the abundance of a number of proteins. SCF complex, one of ubiquitin-protein ligases (E3s), regulates cell cycle progression, signal transduction, and many other biological systems. The SCF complex consists of invariable components, such as Skp1, Cul-1 and Rbx1, and variable components called F-box proteins that bind to Skp1 through the F-box motif. F-box proteins are substrate-specific adaptor subunits that recruit substrates to the SCF complex. Surprisingly, we found that the genome of Caenorhabditis elegans ( C. elegans ) contains at least 20 Skp1-like sequenses, whereas one or a few Skp1 is present in humans. Therefore, we studied C. elegans Skp1-like proteins (CeSkp1) that are likely to be variable components of SCF complex in addition to F-box proteins. At least, seven CeSkp1s were associated with C. elegans Cul-1 (CeCul-1) in yeast two-hybrid system as well as co-immunoprecipitation assay in mammalian cells, and these expression patterns were different in C. elegans . By RNA interference (RNAi), two of these CeSkp1s showed embyonic lethality and four showed the phenotype of slow growth. There were differences among CeSkp1s in ability to interact with F-box proteins. These results suggest that CeSkp1s, like F-box proteins, act as variable components of SCF complex in C. elegans .
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[
International Worm Meeting,
2009]
Interactions between proteins are a key component of most or all biological processes. A key challenge in biology is to generate comprehensive and accurate maps (interactomes) of all possible protein interactions in an organism. This will require iterative rounds of interaction mapping using complementary technologies, as well as technological improvements to the approaches used. For example, we recently developed a novel yeast two-hybrid approach that adds a new level of detail to interaction maps by defining interaction domains(1). Currently, I am working to generate an interaction map of proteins involved in controlling cell polarity in C. elegans to improve our understanding of the molecular mechanisms that establish and maintain cell polarity in multicellular organisms. I will combine two fundamentally different interaction mapping techniques: the yeast two-hybrid system (Y2H) and affinity purification/mass spectrometry (AP/MS). This will provide more detail by identifying both direct interactions between pairs of proteins by Y2H, and the composition of protein complexes by AP/MS. Moreover, interactions missed by one technology may be detected by the other, leading to a more complete interaction map. I will integrate the physical interactions with phenotypic characterizations. To this end I will systematically characterize the interaction network in vivo using two distinct models of polarity: asymmetric division of the one-cell embryo, and stem-cell-like divisions of a multicellular epithelium (in collaboration with M. Wildwater and S. van den Heuvel). M. Boxem, Z. Maliga, N. Klitgord, N. Li, I. Lemmens, M. Mana, L. de Lichtervelde, J. D. Mul, D. van de Peut, M. Devos, N. Simonis, M. A. Yildirim, M. Cokol, H. L. Kao, A. S. de Smet, H. Wang, A. L. Schlaitz, T. Hao, S. Milstein, C. Fan, M. Tipsword, K. Drew, M. Galli, K. Rhrissorrakrai, D. Drechsel, D. Koller, F. P. Roth, L. M. Iakoucheva, A. K. Dunker, R. Bonneau, K. C. Gunsalus, D. E. Hill, F. Piano, J. Tavernier, S. van den Heuvel, A. A. Hyman, and M. Vidal, A protein domain-based interactome network for C. elegans early embryogenesis. Cell, 2008. 134(3): p. 534-545. .
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[
C. elegans: Development and Gene Expression, EMBL, Heidelberg, Germany,
2010]
Morphogenesis requires dynamic interaction between the adherens junctions and the actin cytoskeleton. This interaction is mediated by ?-catenin, which was proposed to be a stable bridge between the junctions and F-actin at the apical regions of polarized epithelial cells. However, ?-catenin cannot bind to F-actin and its adherens junction partner, ?-catenin, simultaneously, suggesting the bridge is dynamic and complex. ?-catenin was thought to inhibit Arp2/3-based branched actin at the junctions for normal maturation of adherens junctions. Our research suggests a new positive role for Arp2/3-dependent branched actin in junctional maturation and during embryonic cell movements of C. elegans . In this study we investigate how progressive WAVE/Scar and Arp2/3-depen dent accumulation of ?-catenin at the adherens junctions contributes to the accumulation of F-actin at apical regions of epithelial cells. We find that removing Arp2/3-dependent actin nucleation disrupts junctional maturation and results in altered levels of adherens junctional proteins in epithelial tissues. In particular, there is a drop in both ?-catenin and F-actin levels at the apical intestine, and altered organization of the apical intestine. Subcellular fractionation reveals that loss of Arp2/3-dependent actin nucleation reduces the amount of ?-catenin in the membrane-associated pool. These data demonstrate an essential role for Arp2/3 to dynamically remodel F-actin to support adherens junctions and polarized F-actin during cell migration and tissue morphogenesis.
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[
Mid-west Worm Meeting,
2004]
P-granules are complexes of proteins and RNA found surrounding the nuclei of C. elegans germ cells and germ cell precursors. GLH (germline RNA helicase) proteins are components of the germline specific P-granules, which are necessary for fertility in C. elegans . PAN-1, a P-granule associated novel protein, was identified as a GLH-binding protein in yeast two hybrid assays. PAN-1 contains some conserved amino acids of N-terminal F-box motifs, as well as sixteen leucine-rich repeats and a weak FOG-2 homology (FTH) motif, each found in F-box proteins. F-box proteins, in the SCF (SKP-1, Cullin, F-box) complex, utilize ubiquitin-mediated substrate degradation. When
pan-1 is eliminated by RNA interference (RNAi), the larvae arrest between the L1 and L2 stages and can survive eight days at 20 0 C. A
pan-1(
gk142) deletion strain exhibits the same 'forever-young' phenotype. mRNA analysis and protein expression show that PAN-1 is not germline specific but is germline enhanced. Experiments are ongoing to separate potential germline and somatic functions of PAN-1. If PAN-1 belongs to the family of F-box proteins, it may be implicated in regulating GLH protein levels, as are two other GLH binding proteins, CSN-5 and KGB-1.
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[
European Worm Meeting,
1996]
The chromo domain is a phylogenetically conserved sequence motif which was identified as a region of homology between the repressor protein Pc and the heterochromatin constitutive protein HP1 of Drosophila. The specific function of the chromo domain is not yet understood, but it appears to be required for protein-protein interactions in chromatin-associated complexes. We have analzed a new chromobox-containing gene from C. elegans (
cec-1). It encodes a nuclear protein that is present in all somatic cells from the 60-100 cell stage on throughout development and in adult animals. No
cec-1 protein was detected in the cells of early embryos, in germ line cells and in their precursor cells Z2 and Z3. Maternally-produced
cec-1 mRNA, however, is included in the oocytes and is present in all the blastomeres of early embryos. Immunolocalization experiments revealed a homogeneous distribution of CEC-1 within interphase nuclei, while during mitosis CEC-1 seems to dissociate from the condensing chromosomes. The expression pattern of the
cec-1 gene suggests that it may represent a new regulatory gene in C. elegans.
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Van Damme, Sara, Schoofs, Liliane, Watteyne, Jan, De Fruyt, Nathan, Beets, Isabel, Fadda, Melissa
[
International Worm Meeting,
2021]
Neuropeptides are an evolutionarily conserved group of neuromodulators that regulate a wide range of adaptive behaviors, such as learning. Yet, unravelling the molecular and circuit mechanisms underlying this neuropeptidergic modulation is challenging due to the diversity of neuropeptide signaling pathways, and their 'wireless' extrasynaptic mode of action. Using reverse pharmacology, we have constructed a molecular map of the C. elegans neuropeptide-receptor network. Phylogenetic reconstruction of the evolutionary history of nematode neuropeptide systems across bilaterian animals revealed several nematode-specific diversifications of neuropeptide signaling in addition to evolutionarily ancient neuropeptide pathways. One of these ancient, conserved pathways is a neuropeptide Y/F (NPY/F)-like signaling system that is an important regulator of learning behavior both in Proto- and Deuterostomia. We found that NPY/F-like FLP-34 neuropeptides are required in serotonergic neurons for aversive olfactory associative learning, which is functionally similar to the role of NPY in vertebrate learning as well as to the role of NPF in invertebrate learning. NPY/F-like neuropeptides are released from serotonergic neurons and signal through the G protein-coupled receptor NPR-11 in the excitatory AIA interneurons to facilitate olfactory aversive learning. In addition, signaling through NPY/F-like receptor NPR-11 also affects learning in salt gustatory plasticity, a gustatory associative learning paradigm. NPY/F-like signaling is not the only neuropeptidergic signaling system affecting learning behavior; we discovered additional neuropeptides that appear to be important to the learning process as well, including peptides that are expressed in non-neuronal cells. Our current research focuses on unravelling the functions of such non-neuronal neuropeptide messengers in learning and other types of behavioral plasticity.