Caenorhabditis elegans as a model for innate immunity to pathogens

The amenability of the nematode Caenorhabditis elegans for genetic analysis and other experimentation provides a powerful tool for studying host-pathogen interactions. Our current understanding of how C. elegans responds to pathogen challenges is in its infancy, but the discovery that the worm has inducible defence responses, which to some extent parallel those of other organisms, demonstrates the potential of this model organism for the study of innate immunity. Most progress in dissecting the C. elegans antimicrobial response has focused around signal transduction pathways and the expression of genes activated by the worm in response to microbial infections.     

Using Caenorhabditis elegans as a model organism for evaluating extracellular signal-regulated kinase docking domain inhibitors

We have recently identified several novel ATP-independent inhibitors that target the extracellular signal-regulated kinase-2 (ERK2) protein and inhibit substrate phosphorylation. To further characterize these compounds, we describe the use of C. elegans as a model organism. C. elegans is recognized as a versatile and cost effective model for use in drug development. These studies take advantage of the well characterized process of vulva development and egg laying, which requires MPK-1, the homolog to human ERK2. It is shown that treatment of C. elegans eggs or larvae prior to vulva formation with a previously identified lead compound (76) caused up to 50% reduction in the number of eggs produced from the adult worm. In contrast, compound 76 had no effect on egg laying in young adult or adult worms with fully formed vulva. The reduction in egg laying by the test compound was not due to effects on C. elegans life span, general toxicity, or non-specific stress. However, compound 76 did show selective inhibition of phosphorylation of LIN-1, a MPK-1 substrate essential for vulva precursor cell formation. Moreover, compound 76 inhibited cell fusion necessary for vulva maturation and reduced the multivulva phenotype in LET-60 (Ras) mutant worms that have constitutive activation of MPK-1. These findings support the use of C. elegans as a model organism to evaluate the selectivity and specificity of novel ERK targeted compounds.     

Caenorhabditis elegans,a pluricellular model organism to screen new genes involved in mitochondrial genome maintenance

The inheritance of functional mitochondria depends on faithful replication and transmission of mitochondrial DNA (mtDNA). A large and heterogeneous group of human disorders is associated with mitochondrial genome quantitative and qualitative anomalies. Several nuclear genes have been shown to account for these severe OXPHOS disorders. However, in several cases, the disease-causing mutations still remain unknown.Caenorhabditis elegans has been largely used for studying various biological functions because this multicellular organism has short life cycle and is easy to grow in the laboratory. Mitochondrial functions are relatively well conserved between human and C. elegans, and heteroplasmy exists in this organism as in human. C. elegans therefore represents a useful tool for studying mtDNA maintenance. Suppression by RNA interference of genes involved in mtDNA replication such as polg-1, encoding the mitochondrial DNA polymerase, results in reduced mtDNA copy number but in a normal phenotype of the F1 worms. By combining RNAi of genes involved in mtDNA maintenance and EtBr exposure, we were able to reveal a strong and specific phenotype (developmental larval arrest) associated to a severe decrease of mtDNA copy number. Moreover, we tested and validated the screen efficiency for human orthologous genes encoding mitochondrial nucleoid proteins. This allowed us to identify several genes that seem to be closely related to mtDNA maintenance in C. elegans.This work reports a first step in the further development of a large-scale screening in C. elegans that should allow to identify new genes of mtDNA maintenance whose human orthologs will obviously constitute new candidate genes for patients with quantitative or qualitative mtDNA anomalies.     

小线虫,大发现:Caenorhabditis elegans在生命科学研究中的重要贡献

自20世纪60年代开始,秀丽线虫作为重要的模式生物在生命科学的发展过程中发挥着举足轻重的作用。线虫中的许多重大发现为人们理解复杂的细胞生命活动做出了极大的贡献。本文对秀丽线虫的研究历史、重要成果及研究前景作一简要综述。     

Caenorhabditis elegans: an emerging genetic model for the study of innate immunity

Invaluable insights into how animals, humans included, defend themselves against infection have been provided by more than a decade of genetic studies that have used fruitflies. In the past few years, attention has also turned to another simple animal model, the nematode worm Caenorhabditis elegans. What exactly have we learned from the work in Drosophila? And will research with C. elegans teach us anything new about our response to pathogen attack?     

Caenorhabditis elegans as a model for intracellular pathogen infection

The genetically tractable nematode Caenorhabditis elegans is a convenient host for studies of pathogen infection. With the recent identification of two types of natural intracellular pathogens of C. elegans, this host now provides the opportunity to examine interactions and defence against intracellular pathogens in a whole‐animal model for infection. C. elegans is the natural host for a genus of microsporidia, which comprise a phylum of fungal‐related pathogens of widespread importance for agriculture and medicine. More recently, C. elegans has been shown to be a natural host for viruses related to the Nodaviridae family. Both microsporidian and viral pathogens infect the C. elegans intestine, which is composed of cells that share striking similarities to human intestinal epithelial cells. Because C. elegans nematodes are transparent, these infections provide a unique opportunity to visualize differentiated intestinal cells in vivo during the course of intracellular infection. Together, these two natural pathogens of C. elegans provide powerful systems in which to study microbial pathogenesis and host responses to intracellular infection.     

Caenorhabditis elegans is a model host for Salmonella typhimurium

The idea of using simple, genetically tractable host organisms to study the virulence mechanisms of pathogens dates back at least to the work of Darmon and Depraitère [1]. They proposed using the predatory amoeba Dictyostelium discoideum as a model host, an approach that has proved to be valid in the case of the intracellular pathogen Legionella pneumophila [2]. Research from the Ausubel laboratory has clearly established the nematode Caenorhabditis elegans as an attractive model host for the study of Pseudomonas aeruginosa pathogenesis [3]. P. aeruginosa is a bacterium that is capable of infecting plants, insects and mammals. Other pathogens with a similarly broad host range have also been shown to infect C. elegans [3,4]. Nevertheless, the need to determine the universality of C. elegans as a model host, especially with regards pathogens that have a naturally restricted host specificity, has rightly been expressed [5]. We report here that the enterobacterium Salmonella typhimurium, generally considered to be a highly adapted pathogen with a narrow range of target hosts [6], is capable of infecting and killing C. elegans. Furthermore, mutant strains that exhibit a reduced virulence in mammals were also attenuated for their virulence in C. elegans, showing that the nematode may constitute a useful model system for the study of this important human pathogen.     

Caenorhabditis elegans is a model host for Listeria monocytogenes

Here we report that Caenorhabditis elegans nematodes fed Listeria monocytogenes die over the course of several days, as a consequence of an accumulation of bacteria in the worm intestine. Mutant strains previously shown to be important for virulence in mammalian models were also found to be attenuated in their virulence in C. elegans. However, ActA, which is required for actin-based intracellular motility, appears to be dispensable during infection of C. elegans, indicating that L. monocytogenes remains extracellular in C. elegans.     

Caenorhabditis elegans as a model system for human diseases

1. Download : Download high-res image (88KB)
2. Download : Download full-size image

     

Caenorhabditis elegans as a model for lysosomal storage disorders

The nematode Caenorhabditis elegans is the simplest animal model available to study human disease. In this review, the worm homologues for the 58 human genes involved in lysosomal storage disorders and for 105 human genes associated with lysosomal function have been compiled. Most human genes had at least one worm homologue. In addition, the phenotypes of 147 mutants, in which these genes have been disrupted or knocked down, have been summarized and discussed. The phenotypic spectrum of worm models of lysosomal storage disorders varies from lethality to none obvious, with a large variety of intermediate phenotypes. The genetic power of C. elegans provides a means to identify genes involved in specific processes with relative ease. The overview of potential lysosomal phenotypes presented here might be used as a starting point for the phenotypic characterization of newly developed knock-out models or for the design of genetic screens selecting for loss or gain of suitable knock-out model phenotypes. Screens for genes involved in lysosomal biogenesis and function have been performed successfully resulting in the cup and glo mutants, but screens involving subtle phenotypes are likely to be difficult.     

秀丽线虫:低氧应答研究的模式生物

低氧能够引起秀丽线虫发生相应的生理和行为学变化,并可保护机体免受缺氧损伤.秀丽线虫的低氧诱导因子(HIF-1)的恒定性调控通路和人类的相应通路之间具有高度保守性,因此秀丽线虫也已成为研究低氧应答调控通路进化保守性的重要工具之一.阐明秀丽线虫的低氧应答机制将为了解人类低氧相关疾病的发病机制提供有价值的线索.     

Reproductive fitness and dietary choice behavior of the genetic model organism Caenorhabditis elegans under semi-natural conditions

Laboratory breeding conditions of the model organism C. elegans do not correspond with the conditions in its natural soil habitat. To assess the consequences of the differences in environmental conditions, the effects of air composition, medium and bacterial food on reproductive fitness and/or dietary-choice behavior of C. elegans were investigated. The reproductive fitness of C. elegans was maximal under oxygen deficiency and not influenced by a high fractional share of carbon dioxide. In media approximating natural soil structure, reproductive fitness was much lower than in s tandard laboratory media. I n seminatural media, the reproductive fitness of C. elegans was low with the standard laboratory food bacterium E. coli (γ-Proteobacteria), but significantly higher with C. arvensicola (Bacteroidetes) and B. tropica (β-Proteobacteria) as food. Dietary-choice experiments in semi-natural media revealed a low preference of C. elegans for E. coli but significantly higher preferences for C. arvensicola and B. tropica (among other bacteria). Dietary-choice experiments under quasi-natural conditions, which were feasible by fluorescence in situ hybridization (FISH) of bacteria, showed a high preference of C. elegans for Cytophaga-Flexibacter-Bacteroides, Firmicutes, and β-Proteobacteria, but a low preference for γ-Proteobacteria. The results show that data on C. elegans under standard laboratory conditions have to be carefully interpreted with respect to their biological significance.     

Zebrafish (Danio rerio) as a model organism for investigating endocrine disruption

Endocrine-disrupting compounds (EDCs) are widespread in the aquatic environment and can cause alterations in development, physiological homeostasis and health of vertebrates. Zebrafish, Danio rerio, has been suggested as a model species to identify targets as well as modes of EDC action. In fact, zebrafish has been found useful in EDC screening, in EDC effects assessment and in studying targets and mechanisms of EDC action. Since many of the environmental EDCs interfere with the sex steroid system of vertebrates, most EDC studies with zebrafish addressed disruption of sexual differentiation and reproduction. However, other targets of EDCs action must not be overlooked. For using a species as a toxicological model, a good knowledge of the biological traits of this species is a pre-requisite for the rational design of test protocols and endpoints as well as for the interpretation and extrapolation of the toxicological findings. Due to the genomic resources available for zebrafish and the long experience with zebrafish in toxicity testing, it is easily possible to establish molecular endpoints for EDC effects assessment. Additionally, the zebrafish model offers a number of technical advantages including ease and cost of maintenance, rapid development, high fecundity, optical transparency of embryos supporting phenotypic screening, existence of many mutant strains, or amenability for both forward and reverse genetics. To date, the zebrafish has been mainly used to identify molecular targets of EDC action and to determine effect thresholds, while the potential of this model species to study immediate and delayed physiological consequences of molecular interactions has been instrumentalized only partly. One factor that may limit the exploitation of this potential is the still rather fragmentary knowledge of basic biological and endocrine traits of zebrafish. Information on species-specific features in endocrine processes and biological properties, however, need to be considered in establishing EDC test protocols using zebrafish, in extrapolating findings from zebrafish to other vertebrate species, and in understanding how EDC-induced gene expression changes translate into disease.     

Characterization of mediators of microbial virulence and innate immunity using the Caenorhabditis elegans host-pathogen model

The soil-borne nematode, Caenorhabditis elegans, is emerging as a versatile model in which to study host-pathogen interactions. The worm model has shown to be particularly effective in elucidating both microbial and animal genes involved in toxin-mediated killing. In addition, recent work on worm infection by a variety of bacterial pathogens has shown that a number of virulence regulatory genes mediate worm susceptibility. Many of these regulatory genes, including the PhoP/Q two-component regulators in Salmonella and LasR in Pseudomonas aeruginosa, have also been implicated in mammalian models suggesting that findings in the worm model will be relevant to other systems. In keeping with this concept, experiments aimed at identifying host innate immunity genes have also implicated pathways that have been suggested to play a role in plants and animals, such as the p38 MAP kinase pathway. Despite rapid forward progress using this model, much work remains to be done including the design of more sensitive methods to find effector molecules and further characterization of the exact interaction between invading pathogens and C. elegans' cellular components.     

An uncapped RNA suggests a model for Caenorhabditis elegans polycistronic pre-mRNA processing

Polycistronic pre-mRNAs from Caenohabditis elegans operons are processed by internal cleavage and polyadenylation to create 3' ends of mature mRNAs. This is accompanied by trans-splicing with SL2 approximately 100 nucleotides downstream of the 3' end formation sites to create the 5' ends of downstream mRNAs. SL2 trans-splicing depends on a U-rich element (Ur), located approximately 70 nucleotides upstream of the trans-splice site in the intercistronic region (ICR), as well as a functional 3' end formation signal. Here we report the existence of a novel gene-length RNA, the Ur-RNA, starting just upstream of the Ur element. The expression of Ur-RNA is dependent on 3' end formation as well as on the presence of the Ur element, but does not require a trans-splice site. The Ur-RNA is not capped, and alteration of the location of the Ur element in either the 5' or 3' direction alters the location of the 5' end of the Ur-RNA. We propose that a 5' to 3' exonuclease degrades the precursor RNA following cleavage at the poly(A) site, stopping when it reaches the Ur element, presumably attributable to a bound protein. Part of the function of this protein can be performed by the MS2 coat protein. Recruitment of coat protein to the ICR in the absence of the Ur element results in accumulation of an RNA equivalent to Ur-RNA, and restores trans-splicing. Only SL1, however, is used. Therefore, coat protein is sufficient for blocking the exonuclease and thereby allowing formation of a substrate for trans-splicing, but it lacks the ability to recruit the SL2 snRNP. Our results also demonstrate that MS2 coat protein can be used as an in vivo block to an exonuclease, which should have utility in mRNA stability studies.     

Technical report: exploring the basis of congenital myasthenic syndromes in an undergraduate course, using the model organism, Caenorhabditis elegans

Mutations affecting acetylcholine receptors have been causally linked to the development of congenital myasthenic syndromes (CMS) in humans resulting from neuromuscular transmission defects. In an undergraduate Molecular Neurobiology course, the molecular basis of CMS was explored through study of a Caenorhabditis elegans model of the disease. The nicotinic acetylcholine receptor (nAChR), located on the postsynaptic muscle cell membrane, contains a pentameric ring structure comprised of five homologous subunits. In the nematode C. elegans, unc-63 encodes an α subunit of nAChR. UNC-63 is required for the function of nAChR at the neuromuscular junction. Mutations in unc-63 result in defects in locomotion and egg-laying and may be used as models for CMS. Here, we describe the responses of four unc-63 mutants to the cholinesterase inhibitor pyridostigmine bromide (range 0.9–15.6 mM in this study), a treatment for CMS that mitigates deficiencies in cholinergic transmission by elevating synaptic ACh levels. Our results show that 15.6 mM pyridostigmine bromide enhanced mobility in two alleles, depressed mobility in one allele and in N2, while having no effect on the fourth allele. This indicates that while pyridostigmine bromide may be effective at ameliorating symptoms of CMS in certain cases, it may not be a suitable treatment for all individuals due to the diverse etiology of this disease. Students in the Molecular Neurobiology course enhanced their experience in scientific research by conducting an experiment designed to increase understanding of genetic defects of neurological function.     

Commensals,probiotics and pathogens in the Caenorhabditis elegans model

Caenorhabditis elegans is a useful model host for a wide variety of microorganisms that have implications for human health. Recent surveys of mammalian and metazoan microbiota demonstrate the often profound effects of gut commensal bacteria on host lifespan, health and development. Work using C. elegans has revealed the surprising extent to which bacterial metabolism can interact with host pathways with examples from Escherichia coli folate metabolism and Bacillus subtilis nitric oxide synthesis. The C. elegans model has also shed light on the mechanisms by which probiotic bacteria influence lifespan.