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[
International Worm Meeting,
2019]
The evolutionary arms race between pathogen and host has been a topic of inquiry for many years. Of particular interest, is that between microsporidia and their wide variety of hosts. Microsporidia are rapidly evolving, obligate intracellular fungal-like parasites with the smallest known eukaryotic genomes and remarkable host specificity. They have detrimental effects on many commercially and ecologically important species and have been associated with lethality in immunocompromised individuals, placing them on the NIH's list of priority pathogens. However, the mechanisms by which these parasites cause disease in their hosts is still widely unknown. Due to the lack of available tools to study microsporidia, the genetically tractable model organism Caenorhabditis elegans provides an excellent opportunity to study a nematode-infecting species of microsporidia, Nematocida parisii. To identify mechanisms by which C. elegans can prevent infection, we performed a forward genetic screen to identify mutant animals that had a Fitness Advantage With Nematocida (fawn). All three fawn isolates produce progeny at high levels and are less infected than wild-type animals. To identify the causative gene we performed whole genome sequencing and mapping using Molecular inversion probes (MIPs) and saw that all three fawn mutants contain different loss of function alleles in the same gene, T14E8.4, on the X chromosome. To understand how loss of this gene provides resistance against N. parisii, we tested infection on different stages of animals, determining that resistance is developmentally restricted to the first larval stage (L1) of growth. In addition, through a pulse infection assay we determined that these mutants are initially less infected than wild-type leading us to hypothesize that there may be an invasion defect, compromising the ability of N. parisii spores to invade their host. Work is currently underway to investigate the expression pattern of this gene, and uncover the molecular mechanism of how it is involved in microsporidia infection. Through this project, we expect to uncover novel strategies by which these fascinating parasites are able to successfully invade and propagate inside their hosts, and how hosts in turn are able to prevent infection.
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[
International Worm Meeting,
2007]
Hydrogen sulfide (H<sub>2</sub>S), which is naturally produced in animal cells, has been shown to effect physiological changes that improve the capacity of mammals to survive environmental changes. We have investigated the physiological response of C. elegans to H<sub>2</sub>S to begin to elucidate the molecular mechanisms of H<sub>2</sub>S action. We show that nematodes exposed to H<sub>2</sub>S are apparently healthy and do not exhibit phenotypes consistent with metabolic inhibition. However, we observed that animals exposed to H<sub>2</sub>S had increased thermotolerance and lifespan and survived subsequent exposure to otherwise lethal concentrations of H<sub>2</sub>S. Increased thermotolerance and lifespan is not observed in the
sir-2.1(
ok434) deletion mutant exposed to H<sub>2</sub>S. However, mutants in the insulin signaling pathway (both
daf-2 and
daf-16), animals with mitochondrial dysfunction (
isp-1 and
clk-1) and a genetic model of caloric restriction (
eat-2) all exhibit H<sub>2</sub>S-induced increased thermotolerance. These data suggest that H<sub>2</sub>S activates a pathway including SIR-2.1 that is separate from dietary restriction and insulin signaling that results in increased lifespan. Moreover, these studies suggest that SIR-2.1 activity may translate environmental change into physiological alterations that improve survival. It is interesting to consider the possibility that the mechanisms by which H<sub>2</sub>S increases thermotolerance and lifespan in nematodes are conserved, and that studies using C. elegans may help explain beneficial effects observed in mammals exposed to H<sub>2</sub>S.
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Zuckerman, B., Zelmanovich, V., Abergel, Z., Abergel, R., Gross, E., Smith, Y., Romero, L., Livshits, L.
[
International Worm Meeting,
2017]
Deprivation of oxygen (hypoxia) followed by reoxygenation (H/R stress) is a major component in several pathological conditions such as vascular inflammation, myocardial ischemia, and stroke. However how animals adapt and recover from H/R stress remains an open question. Previous studies showed that the neuroglobin GLB-5(Haw) is essential for the fast recovery of the nematode Caenorhabditis elegans (C. elegans) from H/R stress. Here, we characterize the changes in neuronal gene expression during the adaptation of worms to hypoxia and recovery from H/R stress. Our analysis shows that innate immunity genes are differentially expressed during both adaptation to hypoxia and recovery from reoxygenation stress. Moreover, we reveal that the prolyl hydroxylase EGL-9, a known regulator of both adaptation to hypoxia and the innate immune response, inhibits the fast recovery from H/R stress through its activity in the O2-sensing neurons AQR, PQR, and URX. Finally, we show that GLB-5(Haw) acts in AQR, PQR, and URX to increase the tolerance of worms to bacterial pathogenesis. Together, our studies suggest that innate immunity and recovery from H/R stress are regulated by overlapping signaling pathways.
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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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[
East Coast Worm Meeting,
2004]
egl-26 was identified in a genetic screen to uncover mutants with vulval morphology defects. In
egl-26 mutants the morphology of a single vulval toroid (vulF) is abnormal and a proper connection to the uterus is not made leading to the egg-laying defect. EGL-26 is a member of the NlpC/P60 superfamily of enzymes, which is characterized by a Histidine containing domain and a Cysteine containing domain (H-box and NC domain, respectively). EGL-26 along with other eukaryotic proteins belongs to a distinct subclass of NlpC/P60-related putative enzymes. The mammalian proteins lecithin: retinol acyltransferase or LRAT and H-ras revertant 107 or H-Rev107 are the most closely related to EGL-26. Both LRAT and H-Rev107 contain putative transmembrane domains in addition to the H-box and NC domains. Although EGL-26 contains no putative transmembrane domains, it is localized at the apical membrane of cells where it is expressed. Proper localization of LRAT within the retinal pigment epithelium is essential for its function. Significantly, an S-F substitution at amino acid 275 of EGL-26 found in the
egl-26 (
n481) allele causes mislocalization of an EGL-26::GFP fusion leading to general cytoplasmic expression as opposed to normal apical membrane localization. The corresponding Serine residue is conserved in both LRAT and H-Rev107. We are attempting to analyze the relationship between the mammalian proteins and EGL-26 by attempting a rescue of
egl-26 mutants by expression of either LRAT or H-Rev107 or both. We plan to test the importance of membrane localization by restoring membrane localization to EGL-26n481 via addition of alternative membrane localization signals.
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[
International Worm Meeting,
2013]
Entomopathogenic nematodes of the genus Heterorhabditis are insect killers that live in mutually beneficial symbiosis with pathogenic Photorhabdus bacteria. Photorhabdus is rapidly lethal to insects and to other nematodes, including C. elegans, but is required for Heterorhabditis growth in culture and for the insect-killing that defines the entomopathogenic lifestyle. The symbiosis between Heterorhabditis and Photorhabdus offers the potential to study the molecular genetic basis of their cooperative relationship. We developing tools to make such studies more feasible: we have been studying multiple nematodes of the genus Heterorhabditis and developing tools for the molecular genetic analysis of Heterorhabditis bacteriophora.
Many species of Heterorhabditis and variants of Photorhabdus have been isolated; some pairings show specificity in their ability to establish a symbiotic relationship. To better understand these interactions and other variations in the lifestyles of Heterorhabditis, we have sequenced H. indica, H. megidis, H. sonorensis, and H. zealandica; a H. bacteriophora genome sequence is available. A comparison of these closely related species may help us to identify mechanisms that regulate the response to bacterial interactions and to find variations that correlate with differences in lifestyle or bacterial compatibility.
In addition to genomics, we are developing H. bacteriophora as a laboratory organism. H. bacteriophora grows well on plates, has been reported to be susceptible to RNAi and transgenesis, and can develop as a selfing hermaphrodite, and so should be a powerful system for the molecular genetic study of the aspects of biology to which it is uniquely well suited, most prominently symbiosis. This potential is severely diminished by inconvenient sex determination: the self-progeny of hermaphrodites are mostly females with some males; at low density, their progeny are almost exclusively females. We have screened for and isolated a constitutively hermaphroditic mutant for use in molecular genetic studies of symbiosis. This mutant also offers the opportunity to explore the basis of hermaphrodite sex determination in H. bacteriophora.
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[
Aging, Metabolism, Stress, Pathogenesis, and Small RNAs, Madison, WI,
2010]
Heterorhabditis bacteriophora is a species of insect-parasitic nematode that lives in mutually beneficial symbiosis with pathogenic Photorhabdus luminescens bacteria. P. luminescens bacteria are lethal to insects and to other nematodes, including the soil nematode Caenorhabditis elegans, but are required for H. bacteriophora growth. The symbiosis between H. bacteriophora and P. luminescens therefore offers the potential to study the molecular genetic basis of their cooperative relationship. We are interested in developing tools to make such studies more feasible; in particular, we propose to generate tools for genetic mapping in H. bacteriophora. We will test independent isolates of H. bacteriophora to ensure that the isolates are cross-fertile. We will then examine the abilities of these isolates to grow on and to become infected with different wild-type and mutant Photorhabdus bacteria. From these tests we will select an isolate on which we will use next-generation high-throughput sequencing technology for the purpose of refining the existing draft genome sequence and for the creation of a SNP map. We anticipate that this SNP map will enable us and the wider insect-parasitic nematode community to identify induced mutations and natural variations affecting the interactions between H. bacteriophora nematodes and pathogenic Photorhabdus bacteria.
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[
International Worm Meeting,
2013]
MicroRNAs (miRNAs) are small non-coding regulatory RNAs that regulate gene expression at the post-transcriptional level and are involved in a broad spectrum of biological processes. Rearrangements of inter- or intra-molecular RNA structures and conformational changes of ribonucleoprotein complexes in the multiple processes of the miRNA pathway have led to the involvement of RNA helicase activities but little is known so far. In eukaryotes, RNA helicases generally belong to the superfamily 2 (SF2) in helicase classification, especially the DExD/H-box helicase family. The DExD/H-box proteins have been shown in association with many cellular processes involving RNA. To better understand the possible roles of DExD/H-box RNA helicases in miRNA function, we employed RNAi screen to identify genetic interaction between C. elegans DExD/H-box RNA helicases and the
let-7 miRNA, which controls the timing of cell cycle exit and terminal differentiation. In addition to the RNA helicase
p72, a component of Drosha Microprocessor complex, and CGH-1 that has been reported to facilitate the function of miRNA-induced silencing complex (miRISC), we found several DExD/H-box RNA helicases, which are involved in ribosomal RNA processing, pre-mRNA splicing and mRNA surveillance, may also take part in miRNA biogenesis and/or function. (Support: National Science Council, Taiwan. NSC 100-2311-B-002-006-MY3).
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[
Development & Evolution Meeting,
2006]
Several Notch interactions occur in rapid succession during early C.elegans embryogenesis, each resulting in a distinct fate. We have previously shown that
ref-1, a gene distantly related to Drosophila E(spl), is a direct Notch target in all these interactions. We show here that
ref-1 expression is controlled by multiple, Notch-dependent enhancers that are specific for each interaction. We have identified a 150bp enhancer that is specific to Notch interactions in the endoderm, and found similar enhancers with the same activity in C.briggsae and C.remanei. The endoderm enhancer contains multiple, conserved binding sites for LAG-1/Su(H) and GATA transcription factors. We demonstrate that all LAG-1/Su(H) and GATA sites are required for full activity of this enhancer. We provide evidence that a GATA transcription factor called ELT-2 is a cooperative factor for Notch in the endoderm. Ectopic expression of ELT-2 in non-endodermal lineages caused activation of the endoderm enhancer only in Notch-signaled cells, suggesting that the presence of the cooperative factor dictates in which Notch interaction a Notch-dependent enhancer becomes responsive in vivo. Previous studies in Drosophila showed that synergy between Su(H) and the bHLH transcription factor Daughterless requires a specific configuration of Su(H) sites, known as a Su(H) paired site, SPS. The endoderm enhancer contains a putative SPS. However, we find that Notch-GATA synergy does not require a SPS, and instead requires a non-SPS configuration of oriented LAG-1/Su(H) sites. Thus, it appears that that each configuration couples Notch signaling with a specific class of transcription factor.
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[
European Worm Meeting,
2002]
Unique forms of the prolyl 4-hydroxylase (P4-H) complex modify the collagen rich cuticular ECM of C. elegans. ER localised P4-H enzyme complexes hydroxylate proline residues within the Gly-X-Y repeat regions of procollagen molecules. The nematode cuticle acts as an exoskeleton and is required for maintenance of worm body morphology. Mutations in collagens forming this cuticle, and the enzymes that process and modify procollagen, cause lethality and severe alterations to body shape as illustrated by the
sqt-3 and
bli-4 mutant phenotypes.