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[
BMC Genomics,
2007]
BACKGROUND: Armigeres subalbatus is a natural vector of the filarial worm Brugia pahangi, but it rapidly and proficiently kills Brugia malayi microfilariae by melanotic encapsulation. Because B. malayi and B. pahangi are morphologically and biologically similar, the Armigeres-Brugia system serves as a valuable model for studying the resistance mechanisms in mosquito vectors. We have initiated transcriptome profiling studies in Ar. subalbatus to identify molecular components involved in B. malayi refractoriness. RESULTS: These initial studies assessed the transcriptional response of Ar. subalbatus to B. malayi at 1, 3, 6, 12, 24, 48, and 72 hrs after an infective blood feed. In this investigation, we initiated the first holistic study conducted on the anti-filarial worm immune response in order to effectively explore the functional roles of immune-response genes following a natural exposure to the parasite. Studies assessing the transcriptional response revealed the involvement of unknown and conserved unknowns, cytoskeletal and structural components, and stress and immune responsive factors. The data show that the anti-filarial worm immune response by Ar. subalbatus to be a highly complex, tissue-specific process involving varied effector responses working in concert with blood cell-mediated melanization. CONCLUSION: This initial study provides a foundation and direction for future studies, which will more fully dissect the nature of the anti-filarial worm immune response in this mosquito-parasite system. The study also argues for continued studies with RNA generated from both hemocytes and whole bodies to fully expound the nature of the anti-filarial worm immune response.
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[
PLoS Negl Trop Dis,
2011]
BACKGROUND: Co-occurrence of malaria and filarial worm parasites has been reported, but little is known about the interaction between filarial worm and malaria parasites with the same Anopheles vector. Herein, we present data evaluating the interaction between Wuchereria bancrofti and Anopheles punctulatus in Papua New Guinea (PNG). Our field studies in PNG demonstrated that An. punctulatus utilizes the melanization immune response as a natural mechanism of filarial worm resistance against invading W. bancrofti microfilariae. We then conducted laboratory studies utilizing the mosquitoes Armigeres subalbatus and Aedes aegypti and the parasites Brugia malayi, Brugia pahangi, Dirofilaria immitis, and Plasmodium gallinaceum to evaluate the hypothesis that immune activation and/or development by filarial worms negatively impact Plasmodium development in co-infected mosquitoes. Ar. subalbatus used in this study are natural vectors of P. gallinaceum and B. pahangi and they are naturally refractory to B. malayi (melanization-based refractoriness). METHODOLOGY/PRINCIPAL FINDINGS: Mosquitoes were dissected and Plasmodium development was analyzed six days after blood feeding on either P. gallinaceum alone or after taking a bloodmeal containing both P. gallinaceum and B. malayi or a bloodmeal containing both P. gallinaceum and B. pahangi. There was a significant reduction in the prevalence and mean intensity of Plasmodium infections in two species of mosquito that had dual infections as compared to those mosquitoes that were infected with Plasmodium alone, and was independent of whether the mosquito had a melanization immune response to the filarial worm or not. However, there was no reduction in Plasmodium development when filarial worms were present in the bloodmeal (D. immitis) but midgut penetration was absent, suggesting that factors associated with penetration of the midgut by filarial worms likely are responsible for the observed reduction in malaria parasite infections. CONCLUSIONS/SIGNIFICANCE: These results could have an impact on vector infection and transmission dynamics in areas where Anopheles transmit both parasites, i.e., the elimination of filarial worms in a co-endemic locale could enhance malaria transmission.
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[
European Worm Neurobiology Meeting,
2009]
Light-gated cation channels such as the blue light-activated depolarizing Channelrhodopsin-2 (ChR2), allow optical activation of individual neurons of live and behaving C. elegans at the millisecond time-scale in a non-invasive manner (Nagel et al., 2005, Zhang et al., 2007, Liewald et al., 2008). This optogenetics approach paves the way for further functional dissection of peptide signalling pathways or individual neuronal networks in a detail that is not possible in higher organisms. The huge advantage is that we can specifically stimulate the sensory input neurons, while other potentially contributing neurons are kept silent. The sensory PVD neurons that envelop the nematode with highly branched dendritic arbors are involved in harsh touch nociception. Expression and activation of ChR2 in PVD results in a forward escape movement and sometimes a reversal. These results are in line with the fact that the PVD neurons make synaptic contacts with the locomotory command interneurons PVC and AVA that regulate forward and backward movement, respectively. Using electrophysiology, we will assess the physiology of the PVD cells, as well as the downstream interneurons in response to photoactivation, while the involvement of different ion channels, receptors or neurotransmitters will be assessed by RNAi. We are also investigating the
flp-15 and
nlp-38 neuropeptidergic signalling pathways by optogenetics. Neuropeptide release can be triggered by photo-activating the respective neurons in an acute fashion while effects on behaviour can be observed at the same time. This way, we can correlate neuropeptide action with acute behavioural changes or effects, about which very limited knowledge is currently available in any system. References Liewald JF, Brauner M, Stephens GJ, Bouhours M, Schultheis C, Zhen M, and Gottschalk A (2008) Optogenetic analysis of synaptic function. Nat Methods, 5, 895-902. Nagel G, Brauner M, Liewald JF, Adeishvili N, Bamberg E, and Gottschalk A (2005) Light activation of channelrhodopsin-2 in excitable cells of Caenorhabditis elegans triggers rapid behavioral responses. Curr Biol, 15, 2279-2284. Zhang F, Wang LP, Brauner M, Liewald JF, Kay K, Watzke N, Wood PG, Bamberg E, Nagel G, Gottschalk A, and Deisseroth K (2007) Multimodal fast optical interrogation of neural circuitry. Nature, 446, 633-639.
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[
PLoS Negl Trop Dis,
2010]
BACKGROUND: Armigeres subalbatus is a natural vector of the filarial worm Brugia pahangi, but it kills Brugia malayi microfilariae by melanotic encapsulation. Because B. malayi and B. pahangi are morphologically and biologically similar, comparing Ar. subalbatus-B. pahangi susceptibility and Ar. subalbatus-B. malayi refractoriness could provide significant insight into recognition mechanisms required to mount an effective anti-filarial worm immune response in the mosquito, as well as provide considerable detail into the molecular components involved in vector competence. Previously, we assessed the transcriptional response of Ar. subalbatus to B. malayi, and now we report transcriptome profiling studies of Ar. subalbatus in relation to filarial worm infection to provide information on the molecular components involved in B. pahangi susceptibility. METHODOLOGY/PRINCIPAL FINDINGS: Utilizing microarrays, comparisons were made between mosquitoes exposed to B. pahangi, B. malayi, and uninfected bloodmeals. The time course chosen facilitated an examination of key events in the development of the parasite, beginning with the very start of filarial worm infection and spanning to well after parasites had developed to the infective stage in the mosquito. At 1, 3, 6, 12, 24 h post infection and 2-3, 5-6, 8-9, and 13-14 days post challenge there were 31, 75, 113, 76, 54, 5, 3, 13, and 2 detectable transcripts, respectively, with significant differences in transcript abundance (increase or decrease) as a result of parasite development. CONCLUSIONS/SIGNIFICANCE: Herein, we demonstrate that filarial worm susceptibility in a laboratory strain of the natural vector Ar. subalbatus involves many factors of both known and unknown function that most likely are associated with filarial worm penetration through the midgut, invasion into thoracic muscle cells, and maintenance of homeostasis in the hemolymph environment. The data show that there are distinct and separate transcriptional patterns associated with filarial worm susceptibility as compared to refractoriness, and that an infection response in Ar. subalbatus can differ significantly from that observed in Ae. aegypti, a common laboratory model.
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Liewald, Jana, Husson, Steven J, Schultheis, Christian, Schoofs, Liliane, Gottschalk, Alexander, Brauner, Martin, Erbguth, Karen, Schedletzky, Thorsten
[
International Worm Meeting,
2009]
Light-gated ion channels or pumps such as the blue light-activated depolarizing Channelrhodopsin (ChR2) and the yellow light-driven hyperpolarizing Halorhodopsin (HR) allow optical activation or inhibition in muscles and neurons of live and behaving C. elegans (Zhang et al., 2007). Furthermore, inward currents evoked by either ChR2 or HR, as well as muscle currents in response to activating ChR2 in motor neurons, can be directly measured by electrophysiology, while photo-evoked body contraction or elongation of the animal could be monitored at the behavioural level (Nagel et al., 2005; Liewald et al., 2008). These state-of-the-art technologies pave the way for further functional dissection of individual neuronal networks in a detail that is not possible in higher organisms. Doing so, we are investigating some defined neuropeptidergic signalling pathways. Neuropeptide release can be triggered by photo-activating the respective neurons in an acute fashion while effects on behaviour can be observed at the same time. This way, we can correlate neuropeptide action with acute behavioural changes or effects, about which very limited knowledge is currently available in any system. While higher organisms display millions of contributing neurons, only a handful of neurons take part in individual neuronal networks in C. elegans. This opens the possibility to study the contribution of each neuron to the function of a small network, for example involved in nociception. The huge advantage of our optogenetics tools is that we can specifically stimulate the sensory input neurons, while other potentially contributing neurons are kept silent. The involvement of different ion channels, receptors or neurotransmitters can be assessed by using different genetic backgrounds, while the physiological properties of each individual neuron will be monitored by electrophysiology. Liewald JF, Brauner M, Stephens GJ, Bouhours M, Schultheis C, Zhen M, and Gottschalk A (2008) Optogenetic analysis of synaptic function. Nat Methods, 5, 895-902. Nagel G, Brauner M, Liewald JF, Adeishvili N, Bamberg E, and Gottschalk A (2005) Light activation of channelrhodopsin-2 in excitable cells of Caenorhabditis elegans triggers rapid behavioral responses. Curr Biol, 15, 2279-2284. Zhang F, Wang LP, Brauner M, Liewald JF, Kay K, Watzke N, Wood PG, Bamberg E, Nagel G, Gottschalk A, and Deisseroth K (2007) Multimodal fast optical interrogation of neural circuitry. Nature, 446, 633-639.
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[
International Worm Meeting,
2011]
Development and ageing are strongly interlinked with metabolism. Especially in C.elegans this relationships becomes apparent with the insulin like signalling pathway (IIS), mitochondrial activity and dietary restriction having a direct effect on lifespan. We recently showed (Fuchs et. al. 2010) that untargeted metabolic profiling (metabolomics | metabonomics) can be used to find a signature of long-life by comparing different longevity mutants and old worms.
By optimising tissue extraction protocols and incorporating chromatography mass spectrometry coupled approaches (GC-MS, LC-MS) we have refined our methodology to achieve a higher coverage of C.elegans metabolites (pathways) and increased sensitivity, aiming at single worm concentrations. We also use stable isotopes (13C, 15N) to label the C.elegans metabolome to help identify (novel) metabolites to increase coverage and trace the fate of dietary uptake.
By providing this array of new tools to the C.elegans (metabolomics) community, we hope to help improve the understanding of metabolism in this important model organism.
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[
Aging, Metabolism, Stress, Pathogenesis, and Small RNAs, Madison, WI,
2010]
Metabolomics (or metabolic profiling) is based on the simultaneous quantification of metabolites. This is arguably the most direct -omic measure of phenotype, which integrates the effects of regulation at different biological levels. Thus the approach can describe subtle differences between mutants which may otherwise have similar 'macro' phenotypes, such as longevity for instance. We have used both proton NMR spectroscopy and gas chromatography -- mass spectrometry to analyse the metabolome of ageing wild-type worms and long-lived mutants (Fuchs et al. BMC Biol. 2010 8:14). The most striking finding is that there were a number of common metabolic features even in worms with different reasons for lifespan extension (dauers,
daf-2 related mutants, and a translation disruption mutant). However it is not straightforward to relate individual metabolite differences to the underlying mechanisms. As an initial step we determined which metabolic changes were DAF-16-repressible in a
daf-2 mutant. In particular, the branched-chain amino acids (BCAAs) followed this pattern, as well as the hormone dopamine. Perhaps surprisingly, other longevity-associated metabolites, such as trehalose, did not. This profiling approach is inherently hypothesis-generating. Full understanding of the changes observed may depend on creation of metabolic models in the future, but these initial results demonstrate the potential value of metabolomics as a complement to existing ageing research.
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[
Arch Otolaryngol Head Neck Surg,
2006]
OBJECTIVE: The FBXO11 gene is the human homologue of the gene mutated in the novel deaf mouse mutant jeff (Jf), a single gene model of otitis media. We have evaluated single nucleotide polymorphisms (SNPs) in the FBXO11 gene for association with chronic otitis media with effusion/recurrent otitis media (COME/ROM). DESIGN: A total of 13 SNPs were genotyped across the 98.7 kilobases of genomic DNA encompassing FBXO11. Data were analyzed for single SNP association using generalized estimating equations, and haplotypes were evaluated using Pedigree Disequilibrium Test methods. PATIENTS: The Minnesota COME/ROM Family Study, a group of 142 families (619 subjects) with multiple affected individuals with COME/ROM. MAIN OUTCOME MEASURES: Genetic association of COME/ROM with polymorphisms in FBXO11. RESULTS: The FBXO11 SNPs are contained in a single linkage disequilibrium haplotype block. Ten of the 13 SNPs were sufficiently polymorphic in the sample to permit analysis. In univariate genetic analysis, 1 reference SNP (hereinafter rs) (
rs2134056) showed nominal evidence of association to COME/ROM (P = .02), and 2 SNPs approached significance (
rs2020911, P = .06;
rs3136367, P = .09). In multivariable analyses, including known risk factors for COME/ROM (sex, exposure to smoking, attending day care centers, no prior breastfeeding, and having allergies), the evidence of independent association was reduced for each SNP (eg,
rs2134056, from P = .02 to P = .08). In subsequent analyses using the Pedigree Disequilibrium Test, the association of FBXO11 SNP
rs2134056 (P = .06) with COME/ROM was confirmed. Incorporating multiple SNPs in 2- and 3-locus SNP haplotypes, those haplotypes containing
rs2134056 also exhibited evidence of association of FBXO11 and COME/ROM (P values ranging from .03 to .10). CONCLUSION: We have observed evidence consistent with an association between polymorphisms in FBXO11, the human homologue of the Jeff mouse model gene, and COME/ROM.
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[
International Worm Meeting,
2003]
Accumulation of polyglutamine containing proteins into intracellular aggregates is associated with various CAG trinucleotide expansion disorders, including neurodegenerative diseases such as Huntingtons disease and spinocerebellar ataxias. The aggregation properties of polyglutamine proteins are directly related to the length of the polyglutamine stretch. With polyglutamine stretches above a threshold of approximately 30 glutamine residues, the aggregation rate increases with increasing numbers of glutamine residues. The length-dependent kinetics of aggregation recapitulates the length-dependent increase in cellular toxicity and age of onset of disease. Expression of polyglutamine stretches of 0, 24, 33, 35, 40, 44, and 82 glutamine residues as YFP-fusion proteins under control of the muscle specific
unc-54 promoter in C. elegans reconstitutes the length and age dependence of aggregation. 1 Whereas worms expressing YFP-fusions with polyglutamine stretches up to 24 (Q24) show a diffuse YFP staining in all muscle cells, Q82 animals show a punctate staining in most of the cells. Interestingly, all Q lengths show variability in aggregation within individual animals, depending on the cell and the age of the worm, which is influenced by the genetic background of the worms. For example, aggregation of Q82-YFP is greatly delayed in the aging mutant
age-11. This heterogeneity of aggregation suggests that genes exist that influence the formation of polyglutamine aggregates. We are using a genome-wide RNAi screen to identify genes involved in polyglutamine aggregation. In a candidate gene approach with RNAi against genes encoding molecular chaperones and molecules involved in proteins degradation, we have already identified genes that may play a role in aggregate formation. 1Morley JF, Brignull HR, Weyers JJ, Morimoto RI. Proc Natl Acad Sci U S A 2002 99(16):10417-22
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[
International Worm Meeting,
2007]
Neural circuits in C. elegans have been studied using light and electron microscopic techniques, focal laser ablations and, more recently, calcium imaging techniques. For a clearer functional understanding of these circuits, however, some knowledge of the rules of synaptic information transfer is required. How is the dynamic range of the post-synaptic neuron set? What are the mechanisms for synaptic integration and gain control? Questions such as these can best be answered by monitoring or controlling connected pre- and post-synaptic neurons simultaneously. We chose to focus on the synapses between the AFD/ASER and AIY neurons, since the functional relevance of these neurons has been established and there is anatomical evidence for synapses between them. Channelrhodopsin-2 (chR2) is a light activated cation channel with fast kinetics (order of milliseconds1). We express chR2 under a neuron-specific promoter2 in the presynaptic neuron, and use whole-cell patch-clamp recording techniques to monitor membrane voltage or currents in the postsynaptic neuron. We are first calibrating the response to light of chR2-expressing neurons. Currently, we are calibrating this light response in worms expressing chR2 in ASER. We have observed depolarizations of 10-30 mV in response to light (450-490 nm) in current clamp, and inward currents of 5-10 pA in voltage-clamp. We have also seen evidence of spontaneous synaptic activity, in the form of discrete synaptic events (potentials or currents) with different reversal potentials (some depolarizing, others Cl-dependent). We are beginning to characterize the ASER-AIY synapse, and will then move on to the AFD-AIY synapse. References 1. Boyden ES, Zhang F, Bamberg E, Nagel G, Deisseroth K. Millisecond-timescale, genetically targeted optical control of neural activity, Nat. Neurosci. 8 (2005), pp. 1263-1268. 2. Nagel G, Brauner M, Liewald JF, Adeishvili N, Bamberg E, Gottschalk A. Light activation of channelrhodopsin-2 in excitable cells of Caenorhabditis elegans triggers rapid behavioral responses. Curr. Biol. 15 (2005), pp. 2279-2284.