-
[
International Worm Meeting,
2019]
The epithelial barriers of the lung and the intestine are lined with a mucosal layer, which serves as a first line of defense during infection. Caenorhabditis elegans, has long been used to study and understand conserved mechanisms of immunity at epithelial barriers. The nematode genome encodes predicted mucins and mucin-related proteins (enzymes). The roles of mucins during C. elegans infections are largely unknown, although microarray studies have shown that expression of five genes encoding mucin-like proteins is up-regulated upon infection with Pseudomonas aeruginosa. We screened predicted mucin and mucin-related genes for their roles in susceptibility or resistance to P. aeruginosa strain PA14 and S. enterica ser Typhimurium strain 1344. Inhibition of
mul-1 by RNAi enhanced the resistance of the animals to PA14 when compared to control RNAi animals (
mul-1 TD50= 81.59 hrs; control TD50= 49.36 hrs). Inhibition of
mul-1 by RNAi resulted in enhanced resistance to ST1344 infection as well (
mul-1 TD50= 106.4 hrs; control TD50= 92.2 hrs). Fewer S. enterica and P. aeruginosa bacteria accumulate in the
mul-1 RNAi worms compared to control. Both pathogens have been reported to use mucins as binding partners and to use O-linked glycans as carbon sources, but only S. enterica encodes the required enzyme to remove sialic acids to access the glycans (sialidase). C. elegans encodes a neuraminidase (F41C3.5) that can perform the same enzymatic reaction. Inhibition of F41C3.5 by RNAi resulted in enhanced resistance to PA14, but not S. enterica. Purified free glycans were supplemented in nematode growth media during killing assays and this reversed the
mul-1 enhanced resistance phenotype. We have shown that inhibition of
mul-1 results in reduced accumulation of bacteria and enhanced resistance to pathogens during infection, suggesting that
mul-1 plays in important role, possibly as a carbon source, for pathogens in the C. elegans intestine during infection.
-
[
East Coast Worm Meeting,
2000]
All organisms on earth evolved at unit gravity (1xG), and thus are probably adapted to function optimally at 1xG. Organisms exposed to increased G levels show changes in physiological processes that compensate for novel stresses, such as increased weight and density-driven sedimentation. These physiological adaptations illustrate the plasticity of organisms exposed to environmental conditions in which they could not possibly have evolved. Investigating the mechanism(s) behind these adaptations may uncover biological pathways that have not previously been identified. During laboratory procedures C. elegans are routinely subjected to transient accelerations of >1000xG, with no obvious ill effects. To establish whether C. elegans display altered physiological processes after exposure to low levels of increased G (2-10xG), we developed a centrifugation protocol using axenic liquid cultures of C. elegans and the short-arm centrifuge at NASA-Ames. After exposure to 5 or 10x G for 4 days, more than 90% of the C. elegans were immobile and did not display a 'tap-response'. Mobility and the tap-response were regained by two hours after the return to unit gravity. To determine whether maintenance at 10xG for 4 days produced alterations in steady-state mRNA levels, we performed whole-genome microarray analysis on mRNA from centrifuged C. elegans compared to parallel cultures of stationary controls. Only 40 highly-expressed genes out of 19,600 were upregulated or downregulated more than 3-fold. Two HSP70 genes were upregulated by 3-fold, indicating that the centrifuged cultures were under mild stress. Most of the genes are of unknown function, but a number show similarity to proteins possibly involved in signal transduction, including G-protein receptor subunits and transcription factors. One member of the ODR10 family of chemosensory receptors was upregulated 8-fold, and others were down-regulated more than 3-fold. These data indicate that C. elegans do respond to increases in G level, but further work will be required to establish how the genes that we have identified may be involved in the responses of C. elegans to increased G.
-
[
West Coast Worm Meeting,
2002]
To understand the evolution of developmental mechanisms, we are doing a comparative analysis of vulval patterning in C. elegans and C. briggsae. C. briggsae is closely related to C. elegans and has identical looking vulval morphology. However, recent studies have indicated subtle differences in the underlying mechanisms of development. The recent completion of C. briggsae genome sequence by the C. elegans Sequencing Consortium is extremely valuable in identifying the conserved genes between C. elegans and C. briggsae.
-
[
International Worm Meeting,
2013]
Embryo development requires precise coordination of mechanical forces and their failure can lead to diseases. During the morphogenesis of C. elegans embryo, the cooperation of epidermal acto-myosin network and muscle contractions is essential. The acto-myosin activity in the epidermis, which has been shown to be more important in lateral than in dorsal-ventral cells, squeeze the embryo and make it elongate [1]. Muscle contractions become active around 1.7-1.8 fold stage. They have been showed to induce a mechano-transduction pathway [2], which is important for elongation. However, it is unclear how the contractions along the anterior-posterior axis help to increase the length of the embryo. Our project aims to elucidate the mechanical role of muscle contractions and its coordination with acto-myosin forces. The experiments are designed following a working model where muscle contractions induce a change in the elasticity of the embryo. We are using a laser nano-dissection technique to investigate cortical tension and elasticity of epidermal cells before and after the onset of muscle contractions. In parallel, we are evaluating the relative changes of acto-myosin forces with a FRET sensor [3] inserted in HMP-1 - a component of the adherens junctions. I will present our observations and preliminary results of the epidermal cortex nano-dissection experiments and measures of acto-myosin forces exerted on adherens junctions. References 1.Gally C, Wissler F, Zahreddine H, Quintin S, Landmann F, Labouesse M. Myosin II regulation during C. elegans embryonic elongation: LET-502/ROCK, MRCK-1 and PAK-1, three kinases with different roles. Development. 2009 Sep;136(18):3109-19. Epub 2009 Aug 12. 2.Zhang H, Landmann F, Zahreddine H, Rodriguez D, Koch M, Labouesse M. A tension-induced mechanotransduction pathway promotes epithelial morphogenesis. Nature. 2011 Mar 3;471(7336):99-103. 3.Grashoff C, Hoffman B, Brenner M, Zhou R, Parsons M, Yang M, McLean M, Sligar S, Chen C, Ha T, Schwartz M. Measuring mechanical tension across vinculin reveals regulation of focal adhesion dynamics. Nature. 2010 July 8; 466(7303): 263-266.
-
[
International Worm Meeting,
2019]
C. inopinata is a newly discovered sibling species of C. elegans. Despite their phylogenetic closeness, they have many differences in morphology and ecology. For example, while C. elegans is hermaphroditic, C. inopinata is gonochoristic; C. inopinata is nearly twice as long as C. elegans. A comparative analysis of C. elegans and C. inopinata enables us to study how genomic changes cause these phenotypic differences. In this study, we focused on early embryogenesis of C. inopinata. First, by the microparticle bombardment method we made a C. inopinata line that express GFP::histone in whole body, and compared the early embryogenesis with C. elegans by DIC and fluorescent live imaging. We found that the position of pronuclei and polar bodies were different between these two species. In C. elegans, the female and male pronuclei first become visible in anterior and posterior sides, respectively, then they meet at the center of embryo. On the other hand, the initial position of pronuclei were more closely located in C. inopinata. Also, the polar bodies usually appear in the anterior side of embryo in C. elegans, but they appeared at random positions in C. inopinata. Therefore, we infer that C. inopinata may have a different polarity formation mechanism from that in C. elegans. We are also analyzing temperature dependency of embryogenesis in C. inopinata, whose optimal temperature is ~7 degree higher than that in C. elegans.
-
[
Development & Evolution Meeting,
2008]
Recently, seven new Caenorhabditis have been discovered, bringing the number of Caenorhabditis species in culture to 17, 10 of which are undescribed. To elucidate the relationships of the new species to the five species with sequenced genomes, we have used sequence data from two rRNA genes and several protein-coding genes for reconstructing the phylogenetic tree of Caenorhabditis. Four new species (spp. 5, 9, 10, 11) group within the so-called Elegans group of Caenorhabditis, with C. elegans being the first branch. Whereas none of them is likely to be the sister species of C. elegans, we now know of two close relatives of C. briggsae-C. sp. 5 and C. sp. 9. C. sp. 9 can hybridize with C. briggsae in the laboratory [see abstract by Woodruff et al.]. Of the remaining new species, C. sp. 7 branches off between C. elegans and C. japonica. This species is easier to cultivate than C. japonica and may be a better candidate for comparative experimental work. Two of the new species branch off before C. japonica as sister species of C. sp. 3 and C. drosophilae+C. sp. 2, respectively. Only one of the new species, C. sp. 11, is hermaphroditic. The position of C. sp. 11 in the phylogeny suggests that hermaphroditism evolved three times within the Elegans group. Two of the new species were isolated from rotting leaves and flowers, and five from rotting fruit. Rotting fruit is also the habitat in which C. elegans has been found to proliferate (Barriere and Felix, Genetics 2007) and from which C. briggsae, C. brenneri and C. remanei were repeatedly isolated. This suggests that the habitat of the stem species of Caenorhabditis after the divergence of the earliest branches (C. plicata, C. sonorae and C. sp. 1) was rotting fruit. The rate of discovery of new Caenorhabditis species has steadily increased since the description of C. elegans in 1899, with a leap in the last two years. There is no indication that we are even close to knowing all species in this genus.
-
[
International Worm Meeting,
2015]
Dosage compensation (DC) across Caenorhabditis species exemplifies an essential process that has undergone rapid co-evolution of protein-DNA interactions central to its mechanism. In C. elegans, recruitment elements on X (rex sites) recruit a condensin-like DC complex (DCC) to hermaphrodite X chromosomes to balance gene expression between the sexes. Recruitment assays in vivo showed that C. elegans rex sites do not recruit the DCC of C. briggsae, and vice versa. To understand how DC complexes and X chromosomes evolved to use different X targeting sequences, we compared DCC subunits and binding sites in C. elegans to those in three species of the C. briggsae clade (15-30 MYR diverged): C. briggsae, its close relative C. nigoni (C. sp. 9), and C. tropicalis (C. sp. 11). By raising antibodies and introducing endogenous tags with TALENs or CRISPR/Cas9, we showed that homologs of both SDC-2, the pivotal X targeting factor, and DPY-27, a DCC-specific condensin subunit, bind X chromosomes of XX animals. Although the DCC shares key components across these four species, the binding sites differ. First, ChIP-seq studies in C. briggsae and C. nigoni identified DCC binding sites that are homologous across these close relatives but differ from C. elegans sites in sequence and location. Second, C. elegans sites use motifs enriched on X (MEX and MEXII) to drive DCC binding, but these motifs are not in C. briggsae or C. nigoni DCC sites and are not X-enriched. Third, we found an X-enriched motif at DCC binding sites of C. briggsae and C. nigoni that is not X-enriched in C. elegans. An oligo with the C. briggsae motif recruits the DCC in C. briggsae, but a similar oligo lacking the motif fails to recruit, establishing the importance of the motif. Fourth, another motif was found in C. briggsae and C. nigoni that shares a few nucleotides with MEX, but its functional divergence was shown by C. elegans recruitment assays. Fifth, two endogenous C. briggsae X-chromosome regions with strong C. elegans MEX motifs fail to recruit the C. briggsae DCC, as assayed by ChIP-seq and recruitment assays. None of these DCC motifs is enriched on the C. tropicalis draft X sequence, supporting further binding site divergence within the C. briggsae clade. Ongoing ChIP-seq studies in C. tropicalis will help determine how C. elegans and C. briggsae clade motifs are evolutionarily related. Comparison of DCC targeting mechanisms across these four species allows us to characterize a rarely captured event: the recent co-evolution of a protein complex and its rapidly diverged target sequences across an entire X chromosome.
-
[
International Worm Meeting,
2009]
Recently, nine new Caenorhabditis have been discovered, bringing the number of Caenorhabditis species in culture to nineteen, eleven of which are undescribed. To elucidate the relationships of the new species to the five species with sequenced genomes, we have used sequence data from two rRNA genes and several protein-coding genes for reconstructing the phylogenetic tree of Caenorhabditis. Four new species (spp. 5, 9, 10 and 11) group within the so-called Elegans group of Caenorhabditis, with C. elegans being the first branch. Although none of them is the sister species of C. elegans, C. sp. 5 and C. sp. 9 are close relatives of C. briggsae. C. sp. 9 can hybridize with C. briggsae in the laboratory. Of the remaining new species, C. sp. 7 branches off between C. elegans and C. japonica. Three of these species, C. sp. 7, C. sp. 9 and C. sp. 11 have been chosen for genome sequencing. Four further new species branch off before C. japonica within a monophyletic clade which also comprises C. sp. 3 and C. drosophilae. Only one of the new species, C. sp. 11, is hermaphroditic. The position of C. sp. 11 in the phylogeny suggests that hermaphroditism evolved three times within the Elegans group. Two of the new species were isolated from rotting leaves and flowers, and seven from rotting fruit. Rotting fruit is also the habitat in which C. elegans has been found to proliferate (Barriere and Felix, Genetics 2007) and from which C. briggsae, C. brenneri and C. remanei were repeatedly isolated. This suggests that the habitat of the stem species of Caenorhabditis after the divergence of the earliest branches (C. plicata, C. sonorae and C. sp. 1) was rotting fruit. Other characters, like the shape of the stoma and the male tail, introns, susceptibility to RNAi and genome size are being evaluated in the context of the phylogeny. The rate of discovery of new Caenorhabditis species has steadily increased since the description of C. elegans in 1899, with a leap in the last few years. There is no indication that we are even close to knowing all species in this genus.
-
[
International Worm Meeting,
2003]
Previous studies have shown that C. elegans ovo-related gene
lin-48 expresses in a small number of cells including the excretory duct cell. In the related species C. briggsae, the expression is conserved in all cells except the excretory duct. This
lin-48 expression difference affects excretory duct morphogenesis. In C. briggsae, as well as in C. elegans
lin-48(
sa496) mutants, the excretory duct is more anterior than in C. elegans wild type. This indicates that C. elegans
lin-48 (
Ce-lin-48) is involved in duct morphogenesis and positioning, but this gene function is absent in C. briggsae (1). We have made reporter transgenes composed of the
lin-48 regulatory sequences from C. elegans or C. briggsae driving expression of green fluorescent protein (GFP). Tests of these clones in each species showed that only the
Ce-lin-48 is expressed in excretory duct cell in C. elegans animal. These results indicate that there are differences in both cis-regulatory sequences and trans-acting proteins between the two species. By creating chimeric reporter transgenes including C. elegans and C. briggsae regulatory sequences, we have found that one difference between the two species is the presence of regulatory sequences in
Ce-lin-48 that respond to the bZip protein CES-2 (1). The
lin-48 gene expression differences between C. elegans and C. briggsae could result from loss of excretory duct expression in the C.briggsae lineage or acquired expression in the C. elegans lineage. To distinguish between these possibilities, we have analyzed three additional Caenorhabditis species (C. remanei, C. sp. CB5161 and C. sp. PS1010). We found these species have a duct morphology similar to C. briggsae indicating the C. elegans morphology is unique to this species. For comparison to C. elegans and C. briggsae, we have isolated the
lin-48 gene from C. remanei and C. sp. CB5161. Alignment of the
lin-48 regulatory sequences reveals that the sequences are more conserved among C. briggsae, C. remanei and C. sp. 5161. Several conserved domains are absent from C. elegans, whereas the previously identified CES-2 binding sites are absent from the other species. Currently, we are creating
lin-48::gfp reporter transgenes for each species to observe the gene expression patterns. Further experiments with these transgenes will allow us to test whether the differences between C. elegans and the other species result from a loss of repressor elements or gain of activator elements in the C. elegans gene. (1)X. Wang and H. M. Chamberlin (2002) Genes & Development 16: 2345-2349.
-
Kanzaki, Natsumi, Hoshi, Yuki, Kumagai, Ryohei, Sugimoto, Asako, Kikuchi, Taisei, Namai, Satoshi, Tsuyama, Kenji
[
International Worm Meeting,
2017]
Caenorhabditis sp. 34 is a sister species of C. elegans recently isolated from the syconia of the fig Ficus septica on Ishigaki Island, Japan (see abstract by T. Kikuchi, et al.). C. sp. 34 is gonochoric and shares typological key characters with other Elegans supergroup species, but strikingly, adults are nearly twice as long as C. elegans. The optimal culture temperature for C. sp. 34 is significantly higher (27 deg C) than that of C. elegans (20 deg C). Young adult males and females tend to form clumps, and Dauer larvae are rarely observed in laboratory culture conditions. Recently the C. sp. 34 genome assembly was produced into six chromosomes (see abstract by T. Kikuchi, et al.). The marked differences from C. elegans in morphology, behaviors and ecology, and the availability of the complete genome sequence make C. sp. 34 highly attractive for comparative and evolutionary studies. To make C. sp. 34 genetically tractable, we have been developing genetic and molecular techniques and tools. Stable transgenic lines of C. sp.34 could be obtained by microinjecting marker plasmids commonly used in C. elegans, although the efficiency was lower than that in C. elegans. Both soaking and feeding RNAi was as effective as in C. elegans. A panel of antibodies against C. elegans proteins successfully recognized expected structures in C. sp. 34 by immunofluorescence. Thus, many of the rich genetic and molecular resources for C. elegans can be directly used for C. sp. 34 studies. We well present some of the comparative analyses of gene functions regarding the body size, germ cell formation and sex determination.