The maintenance of neuromuscular function requires UBC-25 in Caenorhabditis elegans

Caenorhabditis elegans gene ubc-25 encodes a novel type of an E2 ubiquitin transferase domain (UBCc) protein, which is highly conserved in multicellular animals, but which is not present in the genomes of fungi or plants. To identify the cellular localization of UBC-25 during the development of C. elegans, we used a ubc-25::gfp reporter gene construct. These experiments showed that ubc-25 expression starts during embryogenesis and that it is restricted to neurons and muscle cells in all later stages of development as well as in adult animals. RNA interference with ubc-25 caused late-onset paralysis of most muscular functions such as locomotion, egg laying, and defecation. We therefore propose that ubc-25 in C. elegans is required for the maintenance (homeostasis) of neuromuscular functions by contributing to a tissue specific protein modification pathway, and we speculate that the adult onset phenotype results from the accumulation of target proteins which fail to be degraded.     

Caenorhabditis elegans mutants resistant to attachment of Yersinia biofilms

The detailed composition and structure of the Caenorhabditis elegans surface are unknown. Previous genetic studies used antibody or lectin binding to identify srf genes that play roles in surface determination. Infection by Microbacterium nematophilum identified bus (bacterially unswollen) genes that also affect surface characteristics. We report that biofilms produced by Yersinia pestis and Y. pseudotuberculosis, which bind the C. elegans surface predominantly on the head, can be used to identify additional surface-determining genes. A screen for C. elegans mutants with a biofilm absent on the head (Bah) phenotype identified three novel genes: bah-1, bah-2, and bah-3. The bah-1 and bah-2 mutants have slightly fragile cuticles but are neither Srf nor Bus, suggesting that they are specific for surface components involved in biofilm attachment. A bah-3 mutant has normal cuticle integrity, but shows a stage-specific Srf phenotype. The screen produced alleles of five known surface genes: srf-2, srf-3, bus-4, bus-12, and bus-17. For the X-linked bus-17, a paternal effect was observed in biofilm assays.     

The Caenorhabditis elegans ortholog of human PHF5a shows a muscle-specific expression domain and is essential for C. elegans morphogenetic development

We have recently described a novel human and murine multigene-family that is highly conserved during evolution and shows a PHD-finger-like domain present in the deduced protein sequences. Here, we describe the cloning and characterization of the Caenorhabditis elegans ortholog of human PHF5a. Transgenic phf-5::yfp-reporter techniques in C. elegans identified temporal C. elegans phf-5 expression being restricted to late C. elegans development. The phf-5::yfp expression starts within the morphogenetic phase of embryonic development and lasts to the stage of adult worms. Spatial phf-5 expression is muscle-specific with an expression in the developing pharynx, in body wall muscular structures, and in the anal muscles. By phf-5 RNAi we further demonstrated that PHF-5 is essential in the morphogenetic phase of C. elegans embryonic development as well as in young larvae. In contrast, phf-5 RNAi does not show an evident phenotype to adult worms. Taken together, this is the first report providing evidence for a tissue and stage-specific expression of a PHF5a ortholog, named phf-5, in C. elegans while our data further suggest an essential role of the encoded PHF-5 protein in morphogenetic development and muscle function.     

A novel bacterial pathogen, Microbacterium nematophilum, induces morphological change in the nematode C. elegans

The Dar (deformed anal region) phenotype, characterized by a distinctive swollen tail, was first detected in a variant strain of Caenorhabditis elegans which appeared spontaneously in 1986 during routine genetic crosses [1,2]. Dar isolates were initially analysed as morphological mutants, but we report here that two independent isolates carry an unusual bacterial infection different from those previously described [3], which is the cause of the Dar phenotype. The infectious agent is a new species of coryneform bacterium, named Microbacterium nematophilum n. sp., which fortuitously contaminated cultures of C. elegans. The bacteria adhere to the rectal and post-anal cuticle of susceptible nematodes, and induce substantial local swelling of the underlying hypodermal tissue. The swelling leads to constipation and slowed growth in the infected worms, but the infection is otherwise non-lethal. Certain mutants of C. elegans with altered surface antigenicity are resistant to infection. The induced deformation appears to be part of a survival strategy for the bacteria, as C. elegans are potentially their predators.     

Molecular cloning of lin-29, a heterochronic gene required for the differentiation of hypodermal cells and the cessation of molting in C.elegans.

The lin-29 gene product of C.elegans activates a temporal developmental switch for hypodermal cells. Loss-of-function lin-29 mutations result in worms that fail to execute a stage-specific pattern of hypodermal differentiation that includes exist from the cell cycle, repression of larval cuticle genes, activation of adult cuticle genes, and the cessation of molting. Combined genetic and physical mapping of restriction fragment length polymorphisms (RFLPs) was used to identify the lin-29 locus. A probe from the insertion site of a Tc1 (maP1), closely linked and to the left of lin-29 on the genetic map, was used to identify a large set of overlapping cosmid, lambda and yeast artificial chromosome (YAC) clones assembled as part of the C.elegans physical mapping project. Radiolabeled DNA from one YAC clone identified two distinct allele-specific alterations that cosegregated with the lin-29 mutant phenotype in lin-29 intragenic recombinants. lin-29 sequences were severely under-represented in all cosmid and lambda libraries tested, but were readily cloned in a YAC vector, suggesting that the lin-29 region contains sequences incompatible with standard prokaryotic cloning techniques.     

Novel gain-of-function alleles demonstrate a role for the heterochronic gene lin-41 in C. elegans male tail tip morphogenesis

To gain an understanding of the genes and mechanisms that govern morphogenesis and its evolution, we have analyzed mutations that disrupt this process in a simple model structure, the male tail tip of the rhabditid nematode C. elegans. During the evolution of rhabditid male tails, there have been several independent changes from tails with rounded tips ("peloderan", as in C. elegans) to those with pointed tips ("leptoderan"). Mutations which produce leptoderan (Lep) tails in C. elegans thus identify candidate genes and pathways in which evolutionary changes could have produced leptoderan tails from peloderan ancestors. Here we report that two novel, gain-of-function (gf) alleles of lin-41 have lesions predicted to affect the N-terminus of the RBCC-domain LIN-41 protein. Both gf alleles cause the tail tip of adult males to retain the pointed shape of the juvenile tails, producing a Lep phenotype that looks like the tails of leptoderan species. Consistent with its role in the heterochronic pathway, we find that lin-41 governs the timing and extent of male tail tip morphogenesis in a dose-dependent manner. Specifically, the Lep phenotype results from a heterochronic delay in the retraction and fusion of the tail tip cells during L4 morphogenesis, such that retraction is not completed before the adult molt. Conversely, we find that tail tip morphogenesis and cell fusions begin precociously at the L3 stage in the reduced-function lin-41 mutant, ma104, resulting in over-retracted male tails in the adult. Because modulated anti-LIN-41 RNAi knockdowns in the gf mutants restore wild-type phenotype, we suggest that the leptoderan phenotype of the gf alleles is due to a higher activity of otherwise normal LIN-41. Additionally, the gf allele is suppressed by the wild-type allele, suggesting that LIN-41 normally regulates itself, possibly by autoubiquitination. We speculate that small changes affecting LIN-41 could have been significant for male tail evolution.     

Aluminium exposure disrupts elemental homeostasis in Caenorhabditis elegans

Aluminium (Al) is highly abundant in the environment and can elicit a variety of toxic responses in biological systems. Here we characterize the effects of Al on Caenorhabditis elegans by identifying phenotypic abnormalities and disruption in whole-body metal homeostasis (metallostasis) following Al exposure in food. Widespread changes to the elemental content of adult nematodes were observed when chronically exposed to Al from the first larval stage (L1). Specifically, we saw increased barium, chromium, copper and iron content, and a reduction in calcium levels. Lifespan was decreased in worms exposed to low levels of Al, but unexpectedly increased when the Al concentration reached higher levels (4.8 mM). This bi-phasic phenotype was only observed when Al exposure occurred during development, as lifespan was unaffected by Al exposure during adulthood. Lower levels of Al slowed C. elegans developmental progression, and reduced hermaphrodite self-fertility and adult body size. Significant developmental delay was observed even when Al exposure was restricted to embryogenesis. Similar changes in Al have been noted in association with Al toxicity in humans and other mammals, suggesting that C. elegans may be of use as a model for understanding the mechanisms of Al toxicity in mammalian systems.     

An In Vivo C. elegans Model System for Screening EGFR-Inhibiting Anti-Cancer Drugs

The epidermal growth factor receptor (EGFR) is a well-established target for cancer treatment. EGFR tyrosine kinase (TK) inhibitors, such as gefinitib and erlotinib, have been developed as anti-cancer drugs. Although non-small cell lung carcinoma with an activating EGFR mutation, L858R, responds well to gefinitib and erlotinib, tumors with a doubly mutated EGFR, T790M-L858R, acquire resistance to these drugs. The C. elegans EGFR homolog LET-23 and its downstream signaling pathway have been studied extensively to provide insight into regulatory mechanisms conserved from C. elegans to humans. To develop an in vivo screening system for potential cancer drugs targeting specific EGFR mutants, we expressed three LET-23 chimeras in which the TK domain was replaced with either the human wild-type TK domain (LET-23::hEGFR-TK), a TK domain with the L858R mutation (LET-23::hEGFR-TK[L858R]), or a TK domain with the T790M-L858R mutations (LET-23::hEGFR-TK[T790M-L858R]) in C. elegans vulval cells using the let-23 promoter. The wild-type hEGFR-TK chimeric protein rescued the let-23 mutant phenotype, and the activating mutant hEGFR-TK chimeras induced a multivulva (Muv) phenotype in a wild-type C. elegans background. The anti-cancer drugs gefitinib and erlotinib suppressed the Muv phenotype in LET-23::hEGFR-TK[L858R]-expressing transgenic animals, but not in LET-23::hEGFR-TK[T790M-L858R] transgenic animals. As a pilot screen, 8,960 small chemicals were tested for Muv suppression, and AG1478 (an EGFR-TK inhibitor) and U0126 (a MEK inhibitor) were identified as potential inhibitors of EGFR-mediated biological function. In conclusion, transgenic C. elegans expressing chimeric LET-23::hEGFR-TK proteins are a model system that can be used in mutation-specific screens for new anti-cancer drugs.     

High-throughput isolation and mapping of C. elegans mutants susceptible to pathogen infection

We present a novel strategy that uses high-throughput methods of isolating and mapping C. elegans mutants susceptible to pathogen infection. We show that C. elegans mutants that exhibit an enhanced pathogen accumulation (epa) phenotype can be rapidly identified and isolated using a sorting system that allows automation of the analysis, sorting, and dispensing of C. elegans by measuring fluorescent bacteria inside the animals. Furthermore, we validate the use of Amplifluor as a new single nucleotide polymorphism (SNP) mapping technique in C. elegans. We show that a set of 9 SNPs allows the linkage of C. elegans mutants to a 5-8 megabase sub-chromosomal region.     

The Ref/Aly proteins are dispensable for mRNA export and development in Caenorhabditis elegans

The mRNA export pathway is highly conserved throughout evolution. We have used RNA interference (RNAi) to functionally characterize bona fide RNA export factors and components of the exon-exon junction complex (EJC) in Caenorhabditis elegans. RNAi of CeNXT1/p15, the binding partner of CeNXF1/TAP, caused early embryonic lethality, demonstrating an essential function of this gene during C. elegans development. Moreover, depletion of this protein resulted in nuclear accumulation of poly(A)(+) RNAs, supporting a direct role of NXT1/p15 in mRNA export in C. elegans. Previously, we have shown that RNAi of CeSRm160, a protein of the EJC complex, resulted in wild-type phenotype; in the present study, we demonstrate that RNAi of CeY14, another component of this complex, results in embryonic lethality. In contrast, depletion of the EJC component CeRNPS1 results in no discernible phenotype. Proteins of the REF/Aly family act as adaptor proteins mediating the recruitment of the mRNA export factor, NXF1/TAP, to mRNAs. The C. elegans genome encodes three members of the REF/Aly family. RNAi of individual Ref genes, or codepletion of two Ref genes in different combinations, resulted in wild-type phenotype. Simultaneous suppression of all three Ref genes did not compromise viability or progression through developmental stages in the affected progeny, and only caused a minor defect in larval mobility. Furthermore, no defects in mRNA export were observed upon simultaneous depletion of all three REF proteins. These results suggest the existence of multiple adaptor proteins that mediate mRNA export in C. elegans.     

PKN-1, a homologue of mammalian PKN, is involved in the regulation of muscle contraction and force transmission in C. elegans

To examine the in vivo functions of protein kinase N (PKN), one of the effectors of Rho small guanosine triphosphatases (GTPases), we used the nematode Caenorhabditis elegans as a genetic model system. We identified a C. elegans homologue (pkn-1) of mammalian PKN and confirmed direct binding to C. elegans Rho small GTPases. Using a green fluorescent protein reporter, we showed that pkn-1 is mainly expressed in various muscles and is localized at dense bodies and M lines. Overexpression of the PKN-1 kinase domain and loss-of-function mutations by genomic deletion of pkn-1 resulted in a loopy Unc phenotype, which has been reported in many mutants of neuronal genes. The results of mosaic analysis and body wall muscle-specific expression of the PKN-1 kinase domain suggests that this loopy phenotype is due to the expression of PKN-1 in body wall muscle. The genomic deletion of pkn-1 also showed a defect in force transmission. These results suggest that PKN-1 functions as a regulator of muscle contraction-relaxation and as a component of the force transmission mechanism.     

Evaluation of Caenorhabditis elegans glycoproteins as protective immunogens against Haemonchus contortus challenge in sheep

High levels of protection can be attained against Haemonchus contortus challenge infection in sheep using native antigens isolated from the gut of the adult parasite. However, vaccination with recombinant forms of these antigens, or components thereof, has disappointingly failed to generate similar levels of protection, suggesting that appropriate nematode glycosylation may be a prerequisite for protection. The free-living nematode, Caenorhabditis elegans is closely related to H. contortus and has been shown to share similar glycan moieties. In order to investigate the potentially protective role of these glycan moieties, a complex set of glycoproteins was isolated from C. elegans using ConA-lectin chromatography and their efficacy as immunogens against H. contortus challenge infection evaluated in sheep. Despite the generation of a high titre systemic IgG antibody response to the C. elegans glycoproteins and the ability of these antibodies to bind to the microvillar surface of the gut of H. contortus, no protection against challenge infection was observed. Serum antibodies to the C. elegans glycoproteins cross-reacted with the H. contortus host-protective antigen, H-gal-GP, by ELISA, although the level of cross-reactivity was not of a magnitude considered protective. Qualitative differences were also determined between the glycan epitopes of the C. elegans ConA-binding proteins and those of H-gal-GP, suggesting the presence of H. contortus-specific patterns of glycosylation.     

siRNA-mediated knockdown of a splice variant of the PK-A catalytic subunit gene causes adult-onset paralysis in C. elegans

In C. elegans, the PK-A catalytic subunit is encoded by kin-1, which has six 5' exons (N'1-N'6), any one of which may be alternatively spliced onto exon-2. Here we describe a novel siRNA-based strategy to knockdown the expression levels of the N'3 and N'4 splice variants. We show that this technique can effectively knockdown expression of the targeted isoforms without affecting expression of the other kin-1 splice variants. We suggest that this strategy could be widely used in C. elegans to investigate the function of genes with alternative first exons. Moreover, we report a novel role for the N'3 kin-1 variant. Whereas knockdown of the N'4 variant results in no obvious phenotype, loss of the N'3 variant leads to paralysis and an egg-laying defect in the adult, suggesting a deficit in the function of the neuromuscular junction. The function of the N'3 variant is discussed in relation to the known function of PK-A in regulation of the release of neurotransmitters from many presynaptic termini.     

Phospholipase Cepsilon regulates ovulation in Caenorhabditis elegans

Phospholipase Cepsilon (PLCepsilon) is a novel class of phosphoinositide-specific PLC with unknown physiological functions. Here, we present the first genetic analysis of PLCepsilon in an intact organism, the nematode Caenorhabditis elegans. Ovulation in C. elegans is dependent on an inositol 1,4,5-trisphosphate (IP(3)) signaling pathway activated by the receptor tyrosine kinase LET-23. We generated deletion mutants of the gene, plc-1, encoding C. elegans PLCepsilon. We observed a novel ovulation phenotype whereby oocytes are trapped in the spermatheca due to delayed dilation of the spermatheca-uterine valve. The expression of plc-1 in the adult spermatheca is consistent with its involvement in regulation of ovulation. On the other hand, we failed to observe genetic interaction of plc-1 with let-23-mediated IP(3) signaling pathway genes, suggesting a complex mechanism for control of ovulation.     

Lipophilic regulator of a developmental switch in Caenorhabditis elegans

Abstract In Caenorhabditis elegans, the decision to develop into a reproductive adult or arrest as a dauer larva is influenced by multiple pathways including insulin-like and transforming growth factor beta (TGFbeta)-like signalling pathways. It has been proposed that lipophilic hormones act downstream of these pathways to regulate dauer formation. One likely target for such a hormone is DAF-12, an orphan nuclear hormone receptor that mediates these developmental decisions and also influences adult lifespan. In order to find lipophilic hormones we have generated lipophilic extracts from mass cultures of C. elegans and shown that they rescue the dauer constitutive phenotype of class 1 daf-2 insulin signalling mutants and the TGFbeta signalling mutant daf-7. These extracts are also able to rescue the lethal dauer phenotype of daf-9 mutants, which lack a P450 steroid hydroxylase thought to be involved in the synthesis of the DAF-12 ligand; extracts, however, have no effect on a DAF-12 ligand binding domain mutant that is predicted to be ligand insensitive. The production of this hormone appears to be DAF-9 dependent as extracts from a daf-9;daf-12 double mutant do not exhibit this activity. Preliminary fractionation of the lipophilic extracts shows that the activity is hydrophobic with some polar properties, consistent with a small lipophilic hormone. We propose that the dauer rescuing activity is a hormone synthesized by DAF-9 that acts through DAF-12.