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[
International Worm Meeting,
2019]
Skin-penetrating gastrointestinal parasitic nematodes are a worldwide health problem, with the bulk of infections found in low-resource countries. Although anthelmintic drugs are available, these drugs do not prevent reinfection and the rise of drug-resistant helminths is a growing concern in endemic areas. We are studying the interactions of skin-penetrating nematodes with bacteria, using the human-parasitic nematode Strongyloides stercoralis and the closely related rat-parasitic nematode Strongyloides ratti as model systems. S. stercoralis and S. ratti come into contact with bacteria at multiple stages of their life cycle: the free-living life stages develop on host feces and feed on fecal bacteria, the infective life stage encounters soil bacteria and host skin bacteria, and the parasitic life stages come into contact with host gut bacteria. However, remarkably little is known about how skin-penetrating nematodes interact with bacteria at any of these life stages. We are investigating the behavioral responses of free-living adults and infective larvae to a panel of ecologically relevant fecal, skin, gut, and environmental bacteria. We are also assessing the physiological responses of the free-living life stages to fecal bacteria. Preliminarily, we have found that S. stercoralis and S. ratti free-living adults appear to be more attracted to host fecal bacteria than soil bacteria. In contrast, S. stercoralis infective larvae are not attracted to fecal bacteria but are slightly attracted to the soil bacterium. Attraction of free-living adults to fecal bacteria may retain the adults on feces, while loss of attraction to fecal bacteria and attraction to soil bacteria at the infective stage may drive infective larvae off of host feces and into the soil to host seek. We have also found that growth on the bacterium Proteus mirabilis, which is found in feces as well as soil and water, decreases and delays S. stercoralis egg hatching when compared to hatching on other bacteria such as E. coli. Preliminarily, the egg hatching phenotype on P. mirabilis appears to stem from an effect of the bacteria on the young adult worms, rather than the laid eggs. We are now further investigating the mechanism by which P. mirabilis decreases egg hatching. Determining what bacterial interactions are important for the survival of these nematodes has the potential to uncover bacterial compounds that decrease parasite fitness, thus leading to new strategies for preventing infections.
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[
Indian J Exp Biol,
2015]
Advanced Glycation End products (AGE) generated in a non enzymatic protein glycation process are frequently associated with diabetes, aging and other chronic diseases. Here, we explored the protective effect of phlorotannins from brown algae Padina pavonica, Sargassum polycystum and Turbinaria ornata against AGEs formation. Phlorotannins were extracted from brown algae with methanol and its purity was analyzed by TLC and RP-HPLC-DAD. Twenty five grams of P. pavonica, S. polycystum, T. ornata yielded 27.6 +/- 0.8 g/ml, 37.7 g/ml and 37.1 +/- 0.74 g/ml of phloroglucinol equivalent of phlorotannins, respectively. Antioxidant potentials were examined through DPPH assay and their IC50 values were P. pavonica (30.12 +/- 0.99 g), S. polycystum (40.9 +/- 1.2 g) and T. ornata (22.9 +/- 1.3 g), which was comparatively lesser than the control ascorbic acid (46 +/- 0.2 g). Further, anti-AGE activity was examined in vitro by BSA-glucose assay with the extracted phlorotannins of brown algae (P. pavonica, 15.16 +/- 0.26 g/ml; S. polycystum, 35.245 +/- 2.3 g/ml; T. ornata, 22.7 +/- 0.3 g/ml), which revealed the required concentration to inhibit 50% of albumin glycation (IC50) were lower for extracts than controls (phloroglucinol, 222.33 +/- 4.9 g/ml; thiamine, 263 g/ml). Furthermore, brown algal extracts containing phlorotannins (100 l) exhibited protective effects against AGE formation in vivo in C. elegans with induced hyperglycemia.
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[
J Neurosci,
2003]
Thermotactic behavior in Caenorhabditis elegans is sensitive to both a worm's ambient temperature (T-amb) and its memory of the temperature of its cultivation (T-cult). The AFD neuron is part of a neural circuit that underlies thermotactic behavior. By monitoring the fluorescence of pH-sensitive green fluorescent protein localized to synaptic vesicles, we measured the rate of the synaptic release of AFD in worms cultivated at temperatures between 15 and 25degreesC, and subjected to fixed, ambient temperatures in the same range. We found that the rate of AFD synaptic release is high if either T-amb > T-cult or T-amb > T-cult, but AFD synaptic release is low if T-amb congruent to T-cult. This suggests that AFD encodes a direct comparison between T-amb and T-cult.
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[
Trends Mol Med,
2007]
Transforming growth factor beta1 (TGFbeta1), an important pleiotropic, immunoregulatory cytokine, uses distinct signaling mechanisms in lymphocytes to affect T-cell homeostasis, regulatory T (T(reg))-cell and effector-cell function and tumorigenesis. Defects in TGFbeta1 expression or its signaling in T cells correlate with the onset of several autoimmune diseases. TGFbeta1 prevents abnormal T-cell activation through the modulation of Ca(2+)-calcineurin signaling in a Caenorhabditis elegans Sma and Drosophila Mad proteins (SMAD)3 and SMAD4-independent manner; however, in T(reg) cells, its effects are mediated, at least in part, through SMAD signaling. TGFbeta1 also acts as a pro-inflammatory cytokine and induces interleukin (IL)-17-producing pathogenic T-helper cells (T(h) IL-17 cells) synergistically during an inflammatory response in which IL-6 is produced. Here, we will review TGFbeta1 and its signaling in T cells with an emphasis on the regulatory arm of immune tolerance.
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[
Genomics,
1995]
Recently, a novel family of genes with a region of homology to the mouse T locus, which is known to play a crucial, and conserved, role in vertebrate development, has been discovered. The region of homology has been named the T-box. The T-box domain of the prototypical T locus product is associated with sequence-specific DNA binding activity. In this report, we have characterized four members of the T-box gene family from the nematode Caenorhabditis elegans. All lie in close proximity to each other in the middle of chromosome III. Homology analysis among all completely sequenced T-box products indicates a larger size for the conserved T-box domain (166 to 203 residues) than previously reported. Phylogenetic analysis suggests that one C. elegans T-box gene may be a direct ortholog of the mouse Tbx2 and Drosophila omb genes. The accumulated data demonstrate the ancient nature of the T-box gene family and suggest the existence of at least three separate T-box-containing genes in a common early metazoan ancestor to nematodes and vertebrates.
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[
Glycobiology,
2006]
The common O-glycan core structure in animal glycoproteins is the core 1 disaccharide Galbeta1-3GalNAcalpha1-Ser/Thr, which is generated by addition of Gal to GalNAcalpha1-Ser/Thr by core 1 UDP-Gal:GalNAcalpha1-Ser/Thr beta1,3-galactosyltransferase (core 1 beta3-Gal-T or T-synthase, EC2.4.1.122)(2). Although O-glycans play important roles in vertebrates, much remains to be learned from model organisms such as the free-living nematode Caenorhabditis elegans, which offer many advantages in exploring O-glycan structure/function. Here we report the cloning and enzymatic characterization of T-synthase from C. elegans (Ce-T-synthase). A putative C. elegans gene for T-synthase, C38H2.2, was identified in GenBank by a BlastP search using the human T-synthase protein sequence. The full-length cDNA for Ce-T-synthase, which was generated by PCR using a C. elegans cDNA library as the template, contains 1,170 bp including the stop TAA. The cDNA encodes a protein of 389 amino acids with typical type-II membrane topology and a remarkable 42.7% identity to the human T-synthase. Ce-T-synthase has 7 Cys residues in the lumenal domain including 6 conserved Cys residues in all of the orthologs. The Ce-T-synthase has 4 potential N-glycosylation sequons, whereas the mammalian orthologs lack N-glycosylation sequons. Only one gene for Ce-T-synthase was identified in the genome-wide search and it contains 8 exons. Promoter analysis of the Ce-T-synthase using green fluorescent protein constructs show that the gene is expressed at all developmental stages and appears to be in all cells. Unexpectedly, only minimal activity was recovered in the recombinant, soluble Ce-T-synthase secreted from a wide variety of mammalian cell lines, whereas robust enzyme activity was recovered in the soluble Ce-T-synthase expressed in Hi-5 insect cells. Vertebrate T-synthase requires the molecular chaperone Cosmc, but our results show that Ce-T-synthase does not require Cosmc, and might require invertebrate-specific factors for formation of the optimally active enzyme. These results show that the Ce-T-synthase is a functional ortholog to the human T-synthase in generating core 1 O-glycans and opens new avenues to explore O-glycan function in this model organism.
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[
Int J Syst Evol Microbiol,
2007]
A yellow-pigmented, Gram-positive, aerobic, non-motile, non-spore-forming, irregular rod-shaped bacterium (strain TAN 31504(T)) was isolated from the bacteriophagous nematode Caenorhabditis elegans. Based on 16S rRNA gene sequence similarity, DNA G+C content of 69.5 mol%, 2,4-diaminobutyric acid in the cell-wall peptidoglycan, major menaquinone MK-11, abundance of anteiso- and iso-fatty acids, polar lipids diphosphatidylglycerol and phosphatidylglycerol and a number of shared biochemical characteristics, strain TAN 31504(T) was placed in the genus Leucobacter. DNA-DNA hybridization comparisons demonstrated a 91 % DNA-DNA relatedness between strain TAN 31504(T) and Leucobacter chromiireducens LMG 22506(T) indicating that these two strains belong to the same species, when the recommended threshold value of 70 % DNA-DNA relatedness for the definition of a bacterial species by the ad hoc committee on reconciliation of approaches to bacterial systematics is considered. Based on distinct differences in morphology, physiology, chemotaxonomic markers and various biochemical characteristics, it is proposed to split the species L. chromiireducens into two novel subspecies, Leucobacter chromiireducens subsp. chromiireducens subsp. nov. (type strain L-1(T)=CIP 108389(T)=LMG 22506(T)) and Leucobacter chromiireducens subsp. solipictus subsp. nov. (type strain TAN 31504(T)=DSM 18340(T)=ATCC BAA-1336(T)).
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[
Genome,
1997]
The T-box gene family consists of members that share a unique DNA binding domain. The best characterized T-box gene, Brachyury or T, encodes a transcription factor that plays an important role in early vertebrate development. Seven other recently described mouse T-box genes are also expressed during development. In the nematode Caenorhabditis elegans, four T-box genes have been characterized to date. In this study, we describe three new C. elegans T-box genes, named
Ce-tbx-11,
Ce-tbx-12, and
Ce-tbx-17.
Ce-tbx-11 and
Ce-tbx-17 were uncovered through the sequencing efforts of the C. elegans Genome Project.
Ce-tbx-12 was uncovered through degenerate PCR analysis of C. elegans genomic DNA.
Ce-tbx-11 and
Ce-tbx-17 are located in close proximity to the four other previously described T-box genes in the central region of chromosome III. In contrast,
Ce-tbx-12 maps alone to chromosome II. Phylogenetic analysis of all known T-box domain sequences provides evidence of an ancient origin for this gene family.
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[
Heredity,
2001]
In Drosophila elegans, partial sexual isolation has developed between the brown and black morphs, which are distributed allopatrically. The present study aims to understand how they discriminate between potential mates. Mating experiments show that the females of the two morphs differ in sexual signal(s) and the males discriminate using these differences. Body colouration is not used as a sexual cue in this species. Between the females of the two morphs, a large difference was observed in the percentages of 7-pentacosene and 9-pentacosene on the cuticle. Genetical analysis using recombinant inbred lines supported the possibility that the concentration of these pentacosenes plays a role in mate discrimination of these two morphs. However, males did not respond to killed females at all, suggesting that cuticular hydrocarbons of females are not the only cue for the induction of male courtship behaviour. It may be that unknown signals or substances are essential to induce male courtship and pentacosenes modulate the attractiveness of females, positively in the black morph and negatively in the brown morph. Drosophila elegans F1 offspring had intermediate characteristics in mate discrimination and hydrocarbon composition between the parental brown and black morph strains. The number of loci responsible for the differences in the concentration of pentacosenes and the male and female components in the mate recognition between these two morphs is suggested to be more than one.
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[
European Worm Meeting,
2002]
T-box genes are a group of developmentally important transcription factors united by a common DNA binding domain. T-box genes are present in all metazoan species so far analysed but are absent from yeast. There are 20 T-box genes in C. elegans, more than twice the number found in Drosophila. Many of the C. elegans T-box genes are highly diverged from those found in other species while others have clear orthologues present throughout the metazoan kingdom. One highly conserved T-box gene is
mab-9, a member of the
tbx20 sub-family1. This was the first C. elegans T-box gene to be identified by mutation and is required for cell fate specification during hindgut and male tail development, and aspects of nervous system function. One other conserved T-box gene has recently been reported to be important for a particular muscle cell fate specification2. We have inactivated the remaining C. elegans T-box genes by RNAi and have found obvious phenotypes only in very few cases. These phenotypes include embryonic lethality, L1 lethality, and a Dpy phenotype with weakly penetrant male tail defects, and will be described in detail. The remaining T-box genes give no obvious phenotype by RNAi. Phylogenetic analysis reveals that several pairs of T-box genes are very similar to eachother and are therefore likely to be the result of recent duplications. This might suggest functional redundancy. Double RNAi experiments have revealed this to be the case with at least two of the T-box gene pairs (see also poster by Pocock et al). Study of the expression patterns of the whole T-box family may suggest other potential redundancy relationships which can be explored by RNAi. Comparison of the C. elegans T-box genes with the set of T-box genes now defined for C. briggsae is being used as a tool for defining potentially important regulatory regions present in orthologous genes.