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[
International Worm Meeting,
2015]
The IL2 neurons in C. elegans, are a set of 6 sensory neurons located posteriorly to the metacorpus. Throughout most of the animals' life cycle, the IL2s maintain themselves as cell bodies with a single dendrite extending to the nose and an axon extending into the nerve ring. When exposed to environmental stress, the animals will enter the dauer-larval stage in which they exhibit many morphological changes. Included amongst these changes is the remodeling of the IL2 neurons. During the molt into dauer, the IL2 neurons undergo an extensive arborization phenomenon, in which the neurons will show a three-fold increase in dendritic length. During this stage-specific arborization, the dorsal and ventral dendrites extend processes up to the midline, anteriorly and posteriorly along the midline and down the body walls, and the cell bodies also form additional dauer-specific primary dendrites from the cell body1. The mechanisms by which these neurons and their newly formed arbors are maintained is a question that we are currently addressing. A screen of IL2 branching phenotype candidates revealed DYF-7 as a gene of interest. DYF-7 encodes a transmembrane protein required to anchor dendritic tips during retrograde extension2. Though there were no obvious IL2 branching phenotypes associated with this mutant, we did observe dauer-specific defects in cell-body maintenance. In
dyf-7 dauer mutants, the cell bodies were observed to be unorganized and scattered throughout the anterior portion of the animal. However, cell-body maintenance assays of L1 larvae and young-adult animals that had not gone through dauer showed no statistical differences between mutant and wild-type animals. This suggests that DYF-7 is required for maintenance of cell body position during dauer formation. Ongoing experiments seek to determine the cause of this maintenance defect, and attempt to determine the role that DYF-7 plays in cell-body stabilization during dauer formation. In addition, we have begun exploring transmission electron microscopy as a tool to allow us to observe these neurons at the substructural level.1) Schroeder NE, Androwski RJ, Rashid A, Lee H, Lee J, et al. (2013) Dauer-specific dendrite arborization in C. elegans is regulated by KPC-1/Furin. Curr Biol 23: 1527-1535. doi: 10.1016/j.cub.2013.06.0582) Heiman MG, Shaham S (2009) DEX-1 and DYF-7 establish sensory dendrite length by anchoring dendritic tips during cell migration. Cell 137: 344-355 doi: 10.1016/j.cell.2009.01.05719344940.
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[
Biochim Biophys Acta,
2001]
Apparent Ca2+-binding constant (K-app) of Caenorhabditis elegans troponin C (CeTnC) was determined by a fluorescence titration method. The K-app of the N-domain Ca2+-binding site of CeTnC was 7.9 +/- 1.6 x 10(5) M-1 and that of the C-domain site was 1.2 +/- 0.6 x 10(6) M-1, respectively. Mg2+-dependence of the K-app showed that both Ca2+-binding sites did not bind competitively Mg2+. The Ca2+ dissociation rate constant (k(off)) of CeTnC was determined by the fluorescence stopped-flow method. The k(off) of the N-domain Ca2+-binding site of CeTnC was 703 +/- 208 s(-1) and that of the C-domain site was 286 +/- 33 s(-1), respectively. From these values we could calculate the Ca2+-binding rate constant (k(on)) as to be 5.6 +/- 2.8 x 10(8) M-1 s(-1) for the N-domain site and 3.4 +/- 2.1 x 10(8) M (1) s(-1) for the C-domain site, respectively. These results mean that all Ca2+-binding sites of CeTnC are low affinity, fast dissociating and Ca2+-specific sites. Evolutional function of TnC between vertebrate and invertebrate and biological functions of wild type and mutant CeTnCs are discussed.
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[
Nucleosides Nucleotides Nucleic Acids,
2007]
DcpS (scavenger decapping enzyme) from nematode C. elegans readily hydrolyzes both monomethyl- and trimethylguanosine cap analogues. The reaction was followed fluorimetrically. The marked increase of fluorescence intensity after the cleavage of pyrophosphate bond in dinucleotides was used to determine K(m) and V(max)values. Kinetic parameters were similar for both classes of substrates and only slightly dependent on pH. The hydrolysis was strongly inhibited by methylene cap analogues (m(7)Gp(CH(2))ppG and m(7)Gpp(CH(2))pG) and less potently by ARCA (m(7,3'' O)GpppG).
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[
PLoS One,
2014]
Mycoplasma iowae is a well-established avian pathogen that can infect and damage many sites throughout the body. One potential mediator of cellular damage by mycoplasmas is the production of H2O2 via a glycerol catabolic pathway whose genes are widespread amongst many mycoplasma species. Previous sequencing of M. iowae serovar I strain 695 revealed the presence of not only genes for H2O2 production through glycerol catabolism but also the first documented mycoplasma gene for catalase, which degrades H2O2. To test the activity of M. iowae catalase in degrading H2O2, we studied catalase activity and H2O2 accumulation by both M. iowae serovar K strain DK-CPA, whose genome we sequenced, and strains of the H2O2-producing species Mycoplasma gallisepticum engineered to produce M. iowae catalase by transformation with the M. iowae putative catalase gene, katE. H2O2-mediated virulence by M. iowae serovar K and catalase-producing M. gallisepticum transformants were also analyzed using a Caenorhabditis elegans toxicity assay, which has never previously been used in conjunction with mycoplasmas. We found that M. iowae katE encodes an active catalase that, when expressed in M. gallisepticum, reduces both the amount of H2O2 produced and the amount of damage to C. elegans in the presence of glycerol. Therefore, the correlation between the presence of glycerol catabolism genes and the use of H2O2 as a virulence factor by mycoplasmas might not be absolute.
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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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[
Biochemistry,
2012]
Decapping scavenger (DcpS) enzymes catalyze the cleavage of a residual cap structure following 3' 5' mRNA decay. Some previous studies suggested that both m(7)GpppG and m(7)GDP were substrates for DcpS hydrolysis. Herein, we show that mononucleoside diphosphates, m(7)GDP (7-methylguanosine diphosphate) and m(3)(2,2,7)GDP (2,2,7-trimethylguanosine diphosphate), resulting from mRNA decapping by the Dcp1/2 complex in the 5' 3' mRNA decay, are not degraded by recombinant DcpS proteins (human, nematode, and yeast). Furthermore, whereas mononucleoside diphosphates (m(7)GDP and m(3)(2,2,7)GDP) are not hydrolyzed by DcpS, mononucleoside triphosphates (m(7)GTP and m(3)(2,2,7)GTP) are, demonstrating the importance of a triphosphate chain for DcpS hydrolytic activity. m(7)GTP and m(3)(2,2,7)GTP are cleaved at a slower rate than their corresponding dinucleotides (m(7)GpppG and m(3)(2,2,7)GpppG, respectively), indicating an involvement of the second nucleoside for efficient DcpS-mediated digestion. Although DcpS enzymes cannot hydrolyze m(7)GDP, they have a high binding affinity for m(7)GDP and m(7)GDP potently inhibits DcpS hydrolysis of m(7)GpppG, suggesting that m(7)GDP may function as an efficient DcpS inhibitor. Our data have important implications for the regulatory role of m(7)GDP in mRNA metabolic pathways due to its possible interactions with different cap-binding proteins, such as DcpS or eIF4E.
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[
Acta Biochim Pol,
2002]
Translation initiation factor eIF4E binds the m(7)G cap of eukaryotic mRNAs and mediates recruitment of mRNA to the ribosome during cap-dependent translation initiation. This event is the rate-limiting step of translation and a major target for translational control. In the nematode Caenorhabditis elegans, about 70% of genes express mRNAs with an unusual cap structure containing m(3)(2'2'7)G, which is poorly recognized by mammalian eIF4E. C. elegans expresses five isoforms of eIF4E (IFE-1, IFE-2, etc.). Three of these (IFE-3, IFE-4 and IFE-5) were investigated by means of spectroscopy and structural modelling based on mouse eIF4E bound to m(7) GDP. Intrinsic fluorescence quenching of Trp residues in the IFEs by iodide ions indicated structural differences between the apo and m(7)G cap bound proteins. Fluorescence quenching by selected cap analogues showed that only IFE-5 forms specific complexes with both m(7)G and m(3)(2,2,7)G-containing caps (K(as)2X10(6) M-1 to 7X10(6) M-1) wheras IFE-3 and IFE-4 discriminated strongly in favor of m(7)G-containing caps. These spectroscopic results quantitatively confirm earlier qualitative data derived from affinity chromatography. The dependence of K-as on pH indicated optimal cap binding of IFE-3, IFE-4 and IFE-5 at pH 7.2, lower by 0.4 pH units than that of eIF4E from human erythrocytes. These results provide insight into the molecular mechanism of recognition of structurally different caps by the highly homologous
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[
J Biol Chem,
2003]
The contributions to substrate binding and catalysis of 13 amino acid residues of the Caenorhabditis elegans diadenosine tetraphosphate pyrophosphohydrolase (Ap(4)A hydrolase) predicted from the crystal structure of an enzyme-inhibitor complex have been investigated by site-directed mutagenesis. Sixteen glutathione S-transferase-Ap(4)A hydrolase fusion proteins were expressed and their k(cat) and K-m values determined after removal of the glutathione S-transferase domain. As expected for a Nudix hydrolase, the wild type k(cat) of 23 s(-1) was reduced by 10(5)-, 10(3)-, and 30-fold, respectively, by replacement of the conserved P-phosphate-binding catalytic residues Glu(56), Glu(52), and Glu(103) by Gln. K-m values were not affected, indicating a lack of importance for substrate binding. In contrast, mutating His(31) to Val or Ala and Lys(83) to Met produced 10- and 16-fold increases in K. compared with the wild type value of 8.8 muM. These residues stabilize the P-1-phosphate. H31V and H31A had a normal kcat but K83M showed a 37-fold reduction in k(cat). Lys(36) also stabilizes the P-1-phosphate and a K36M mutant had a 10-fold reduced kcat but a relatively normal K-m. Thus both Lys(36) and Lys(83) may play a role in catalysis. The previously suggested roles of Tyr(27), His(38), Lys(79), and Lys(81) in stabilizing the P-2 and P-3-phosphates were not confirmed by mutagenesis, indicating the absence of phosphate-specific binding contacts in this region. Also, mutating both Tyr(76) and Tyr(121), which clamp one substrate adenosine moiety between them in the crystal structure, to Ala only increased K-m 4-fold. It is concluded that interactions with the P-1- and P-4-phosphates are minimum and sufficient requirements for substrate binding by this class of enzyme, indicating that
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[
International Worm Meeting,
2007]
Programmed cell death (or apoptosis) is an important feature of C. elegans development. Previous studies have identified pro-apoptotic genes
egl-1,
ced-3 and
ced-4 and anti-apoptotic genes
ced-9 and
icd-1 that control programmed cell death.. We have identified and characterized a novel pro-apoptotic gene
eif-3.K. Loss-of-function by mutation or RNAi inactivation in
eif-3.K resulted in a decrease of cell corpses, whereas heatshock-induced over-expression of
eif-3.K weakly but significantly increased cell corpses. Interestingly, the
eif-3.K mutation partially suppressed ectopic cell deaths caused by over-expression of
egl-1 or
ced-4. This result suggests that
eif-3.K may act downstream of or in parallel to
egl-1 and
ced-4 in the programmed cell death pathway. Using a cell-specific promoter to express
eif-3.k in touch neurons, we showed that
eif-3.K likely promoted cell death in a cell-autonomous manner. To further explore EIF-3.K function, we generated antibodies against bacterially expressed EIF-3.K protein. We found that EIF-3.K was ubiquitously expressed during embryogenesis and localized to the cytoplasm. As human
eif-3.K can functionally substitute C. elegans
eif-3.K in an
eif-3.K mutant, the function of
eif-3.K in apoptosis is likely conserved in evolution.
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[
J Infect Dis,
2015]
BACKGROUND: Elimination of onchocerciasis and lymphatic filariasis is targeted for 2020. Given the coincident Loa loa infections in Central Africa and the potential for drug resistance development, the need for new microfilaricides and macrofilaricides has never been greater. With the genomes of L. loa, Onchocerca volvulus, Wuchereria bancrofti, and Brugia malayi available, new drug targets have been identified. METHODS: The effects of the tyrosine kinase inhibitors imatinib, nilotinib, and dasatinib on B. malayi adult males, adult females, L3 larvae, and microfilariae were assessed using a wide dose range (0-100 M) in vitro. RESULTS: For microfilariae, median inhibitory concentrations (IC50 values) on day 6 were 6.06 M for imatinib, 3.72 M for dasatinib, and 81.35 M for nilotinib; for L3 larvae, 11.27 M, 13.64 M, and 70.98 M, respectively; for adult males, 41.6 M, 3.87 M, and 68.22 M, respectively; and for adult females, 42.89 M, 9.8 M, and >100 M, respectively. Three-dimensional modeling suggests how these tyrosine kinase inhibitors bind and inhibit filarial protein activity. CONCLUSIONS: Given the safety of imatinib in humans, plans are underway for pilot clinical trials to assess its efficacy in patients with filarial infections.