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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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[
International Worm Meeting,
2007]
The C. elegans post-embryonic mesodermal lineage arises from a single precursor cell, the M mesoblast, which will diversify to generate distinct dorsal and ventral cell types. The dorsal daughter of M gives rise to a subset of body wall muscles and two non-muscle coelomocytes, whereas the ventral daughter of M gives rise to two sex myoblasts in addition to a subset of body wall muscles. Mutations in the C. elegans Schnurri homolog
sma-9 cause ventralization of the M lineage. We have previously shown that SMA-9 antagonizes the Sma/Mab TGF-beta signaling pathway to promote dorsal M lineage fates (Foehr et al., 2006). Interestingly, loss-of-function mutations in the Notch receptor homolog
lin-12 cause dorsalization of the M lineage (Greenwald et al., 1983), an exact opposite phenotype of
sma-9 mutants. We have found that while LIN-12 protein is present in both the dorsal and ventral M lineage cells, the ligands for LIN-12, LAG-2 and APX-1, are asymmetrically localized in cells adjacent to ventral M-derived cells, and they function redundantly in promoting ventral M lineage fates. To investigate how LIN-12/Notch signaling interacts with SMA-9 and the Sma/Mab TGF-beta pathway in regulating M lineage patterning, we generated double and triple mutant combinations among
lin-12,
sma-9 and
dbl-1 (the ligand for the Sma/Mab TGF-beta pathway) and examined their M lineage phenotypes. Our results suggest that the LIN-12/Notch pathway and the Sma/Mab TGF-beta pathway function independently in regulating dorsoventral patterning of the M lineage, with LIN-12/Notch required for ventral M lineage fates, and SMA-9 antagonism of TGF-beta signaling required for dorsal M lineage fates. Our work provides a model for how combined Notch and TGF-beta signaling regulates the developmental potential of two equipotent cells along the dorsoventral axis.
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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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[
Development & Evolution Meeting,
2008]
The C. elegans postembryonic mesodermal lineage, the M lineage, is a powerful model system to study mesodermal patterning and cell fate specification at single cell resolution. The M lineage arises from a single pluripotent cell, the M mesoblast, during embryogenesis. In hermaphrodites, the M cell undergoes a series of postembryonic cell divisions to produce 18 cells: 14 body wall muscles (BWMs), 2 coelomocytes (CCs), and 2 sex myoblasts (SMs). We and others have previously identified a handful of transcription factors important for the proper development of this lineage. In order to identify additional transcription factors that play a role in the M lineage, we have generated a feeding RNAi library that targets a majority of the predicted transcription factors encoded in the C. elegans genome and conducted an RNAi screen using cell type-specific GFP reporters in the M lineage. From this screen, we identified a novel set of 32 transcription factors that, upon RNAi knockdown, give reproducible phenotypes in the M lineage. Among these 32 transcription factors, four are important for patterning and fate specification of the early M lineage, while the rest appear to play a role in fate decisions in the SM lineage. We have primarily focused on
let-381, which encodes a forkhead transcription factor that is essential for C. elegans development.
let-381(RNAi) causes a dorsal to ventral fate transformation in the M lineage. We have found that a
let-381::gfp translational fusion is expressed in the dorsal M lineage. Previous studies from our lab have shown that SMA-9, the Sma/Mab TGF-beta and LIN-12/Notch signaling pathways are involved in dorsal/ventral patterning of the M lineage. We are currently investigating the relationship between
let-381 and these pathways.
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[
International Worm Meeting,
2009]
Animals increase their pirouette frequency in response to removal from food stimulus for a period of 15 min. The AWC and ASK sensory neurons and the AIB interneurons stimulate pirouettes immediately after removal from food, while the AIY and AIA interneurons inhibit pirouettes (Wakabayashi et al 2004, Gray et al 2005). We have found that AWC sensory neurons become active in response to removal of stimulus, releasing two neurotransmitters (glutamate and a neuropeptide NLP-1). The released glutamate acts to activate AIB and inhibit AIY interneurons, promoting reversals (Chalasani et al 2007). In contrast to glutamate, AWC-released NLP-1 acts on AIA interneurons to suppress reversals, suggesting that reversal frequencies are regulated by at least two opposing signaling systems. AWC calcium responses are modulated in these neurotransmitter mutants, suggesting that feedback pathways affect AWC neuronal activity. References: Chalasani, S. H., Chronis, N., Tsunozaki, M., Gray, J. M., Ramot, D., Goodman, M. B., and Bargmann, C. I. (2007). Dissecting a circuit for olfactory behaviour in Caenorhabditis elegans. Nature 450, 63-70. Gray, J.M., Hill, J.J., and Bargmann, C.I. (2005). A circuit for navigation in Caenorhabditis elegans. Proc. Natl. Acad. Sci. 102, 3184-3191. Wakabayashi, T., Kitagawa, I., and Shingai, R. (2004). Neurons regulating the duration of forward locomotion in Caenorhabditis elegans. Neurosci. Res. 50, 103-111.
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[
East Coast Worm Meeting,
2004]
We are interested in understanding mesodermal patterning and fate specification by studying the C. elegans postembryonic mesodermal lineage, the M lineage. The M lineage is derived from a single precursor cell, the M mesoblast, and gives rise to six cell types: striated bodywall muscles (BWMs), nonmuscle coelomocytes (CCs), and four classes of non-striated sex muscles which are descendants of the sex myoblasts (SMs). We are studying the function of the
mls-2 (mesodermal lineage specification) gene in M lineage patterning and fate specification. The
mls-2(
cc615) mutation causes randomization of division planes in the M lineage, and subsequent fate transformation of CCs and BWMs to SMs. In addition,
cc615mutants have defects in SM migration and show some larval and adult lethality. We have cloned the wild type
mls-2 gene (C39E6.4).
mls-2 encodes a homeodomain protein that belongs to the HMX family of homeodomain proteins that are also present in sea urchin, Drosophila and vertebrates., We examined the expression pattern of
mls-2 using both functional
mls-2::gfp fusion construct and affinity purified anti-MLS-2 antibodies. We found that the MLS-2 protein is localized in nuclei of early M lineage cells and a subset of head neurons. Furthermore,
mls-2 expression in the M lineage and the head neurons appears to require distinct cis-acting elements. Overexpression of
mls-2 in the early M lineage where
mls-2 is normally expressed caused a variety of defects in the M lineage. Forced expression of
mls-2 in the later M lineage such as in SMs where
mls-2 is not normally expressed resulted in extra rounds of divisions of SMs. This suggests that
mls-2 may have multiple roles in the M lineage and that MLS-2 protein level is critical for the correct patterning of the M lineage. The M lineage defects of
mls-2(
cc615) are very similar to those of
mab-5,
hlh-1,
egl-27 and
egl-20 mutants. We are currently carrying out molecular and genetic epistasis experiments to investigate the relationship between
mls-2 and those factors.
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[
International Worm Meeting,
2007]
Heme serves as a cofactor for a number of proteins involved in key metabolic processes. In eukaryotes, heme synthesis occurs in the mitochondria by an evolutionarily conserved multi-step pathway. Hemes are hydrophobic and thus insoluble in the aqueous environment of the cell. Moreover, free heme is cytotoxic because of peroxidase activity. We therefore hypothesize that intracellular pathways exist for trafficking of heme from the site of synthesis in the mitochondria to various cellular destinations. However, identification of these heme transport pathways has been difficult because heme synthesis is regulated by multiple effectors and is tightly coordinated with apo-protein synthesis. We have previously shown that C. elegans and related helminths do not make heme albeit requiring exogenous heme for normal metabolic processes. Importantly, C. elegans show a biphasic response for heme; worms are growth-arrested at 1.5 <font face=symbol>m</font>M and at 800 <font face=symbol>m</font>M heme. These results suggest that although worms are obligate heme auxotrophs they are likely to have all the pathways for heme utilization beyond the point of heme synthesis. To identify pathways for heme transport in C. elegans, we exploited their biphasic response to heme by screening for mutants that could survive heme toxicity. We screened 300,000 haploid genomes and isolated 13 mutants at 800 <font face=symbol>m</font>M heme in liquid axenic medium. Based on the mutants growth profile in medium containing low and high heme, we categorized the mutants into three broad phenoclusters: class A, class B and class C. Class A mutants grew robustly under low and high (800 and 1000<font face=symbol>m</font>M) heme, Class B mutants grew exceptionally well under low heme, moderately well at 800 <font face=symbol>m</font>M heme, and not at all at 1000 <font face=symbol>m</font>M heme, and Class C mutants grow moderately well under high heme (800<font face=symbol>m</font>M), but exhibit normal growth under low heme. The mutants were further sub-clustered by using gallium protoporphyrin (GaPP), a toxic heme analog. Complementation analyses revealed that these 13 mutants fall into five complementation groups. Genetic mapping by recombination localized the mutants from each complementation group to chromosome III. We are now producing a high resolution map to define a genetic interval and pinpoint the exact nature of the molecular lesion in these mutants.
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[
Development & Evolution Meeting,
2008]
We are using the C. elegans postembryonic mesodermal lineage, the M lineage, as a model to study mesodermal patterning and cell fate specification. The M lineage arises from a single pluripotent cell, the M mesoblast, during embryogenesis. In hermaphrodites, the M cell first undergoes a dorsal-ventral division and then a left-right division to produce four cells located in four quadrants of the L1 larva. These four cells subsequently undergo two to three more rounds of cell divisions along the anterior-posterior axis to produce 18 cells: 14 body wall muscles (BWMs), 2 coelomocytes (CCs), and 2 sex myoblasts (SMs). In particular, M.dlp and M.drp each give rise to an anterior CC and a posterior BWM. In an RNAi screen for transcription factors important for proper M lineage development, we identified the Six2 homeodomain factor
ceh-34 for its requirement in the proper specification of M-derived CC fates.
ceh-34(RNAi) results in a fate transformation of the anterior CC to its posterior sister cell, the BWM. We have generated translational
ceh-34::gfp fusions and found that in the M lineage,
ceh-34 is specifically expressed in the CC precursor cells. To understand the mechanisms underlying the asymmetric expression pattern of
ceh-34, we determined the roles of the Wnt/beta-catenin asymmetry pathway in the M lineage because this pathway has been shown to regulate other asymmetric cell fates along the anterior-posterior axis. We have found that during both of the anterior-posterior cell divisions in the early M lineage, the TCF homolog POP-1 is enriched in the anterior daughters while the beta-catenin homolog SYS-1 is enriched in the posterior daughters. Furthermore,
sys-1(
q544) loss-of-function mutants have extra M lineage-derived CCs, while
pop-1(RNAi) leads to a loss of M-derived CCs. We showed that
ceh-34(RNAi) is epistatic to
sys-1(
q544) mutations and that
ceh-34::gfp is ectopically expressed in the M lineage in
sys-1(RNAi) animals but reduced in
pop-1(RNAi) animals. These observations suggest that
ceh-34 functions downstream of
pop-1 and
sys-1 in the M lineage. We are currently testing if POP-1 and SYS-1 directly regulate the asymmetric expression of
ceh-34 in M lineage development.
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[
Development & Evolution Meeting,
2006]
mls-2 encodes a HMX homeodomain protein that plays critical roles in the C. elegans postembryonic mesodermal lineage, the M lineage.
mls-2 is expressed in the M lineage as well as a few other cell types, such as several pairs of head neurons including ASK and AIM. To uncover mechanisms involved in regulating the expression of
mls-2, we generated a series of promoter deletions and identified an M lineage enhancer (position -2221 to -2076) that is required for
mls-2 expression in the M lineage. We further identified several essential elements within this M enhancer. Among these elements are two putative Exd/Abd-B binding sites that are conserved in C. briggsae. We have found that
mls-2 expression in the M lineage is dependent on the C.elegans Exd/Pbx homolog CEH-20. We are currently testing whether CEH-20 directly binds to the
mls-2 promoter and whether CEH-20 regulates
mls-2 expression through acting together with the Abd-B class Hox proteins, EGL-5/PHP-3/NOB-1, and the Hth/Meis homolog, UNC-62.
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[
International Worm Meeting,
2015]
Parafilm M® is a thin thermoplastic used to seal a variety of containers in scientific laboratories. It is commonly used to seal Nematode Growth Media (NGM) culture plates to prevent microbial contamination and media dehydration. However, the effects on C. elegans of wrapping culture plates with Parafilm M® during experiments are unknown. Parafilm M® may limit gas exchange between the external and culture environment, potentially affecting the biology and life history of C. elegans, including its larval growth rate, viability, fecundity, lifespan, and behavior. In particular, wrapping culture plates with Parafilm M® may produce a hypoxic (low oxygen) environment compared to plates with no Parafilm M® (normoxic). Anoxic (no oxygen) and hypoxic conditions have been shown to change the metabolism, development, and longevity of C. elegans.Our research aims to determine the effects of wrapping NGM culture plates with Parafilm M® on C. elegans. We hypothesized that worms cultured on plates wrapped in Parafilm M® would exhibit a slower rate of larval growth and increased mortality compared to worms grown in normoxic conditions. Synchronized L1 worms were individually transferred to culture plates and incubated within an anoxic environment, hypoxic environment, normoxic environment, or wrapped one time with Parafilm M®. BD GasPaks™ were used to create anoxic and hypoxic environments, and normoxic culture conditions consisted of unsealed plates. Larval growth rate and mortality were measured 5 times over 48 hours. We found no significant difference in the growth rate between worms cultured in normoxic conditions and on plates wrapped with Parafilm M®. However, the growth rate between worms cultured on plates wrapped with Parafilm M® and worms in anoxic and hypoxic conditions was significantly higher. Mortality was significantly higher in worms cultured in anoxic conditions, but was not significantly different among the other three environmental conditions. Our data suggest that wrapping C. elegans culture plates one time with Parafilm M® does not affect the larval growth rate or viability. Future studies will focus on additional biological and life history metrics, such as fecundity and lifespan, to verify that wrapping with Parafilm M® has no unexpected effects on the outcomes of C. elegans studies.