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J Cell Biol,
2019]
Wang studies lysosomal degradation pathways using <i>C. elegans</i> as a model system.
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Curr Biol,
2014]
Wang and Seydoux discuss the functional importance of P granules - the germline-specific RNA granules of C. elegans.
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Dev Cell,
2017]
In this issue of Developmental Cell, Dickinson etal. (2017) and Rodriguez etal. (2017), along with Wang etal. (2017) in Nature Cell Biology, show how PAR protein oligomerization can dynamically couple protein diffusion and transport by cortical flow to control kinase activity gradients and polarity in the C.elegans zygote.
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Dev Cell,
2017]
Reporting in Nature Cell Biology, Lin and Wang (2017) show that bacterial methyl metabolism impacts host mitochondrial dynamics and lipid storage in C.elegans. The authors propose a model whereby bacterial metabolic products regulate a nuclear hormone receptor that promotes lipid accumulation through expression of a secreted Hedgehog-like protein.
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Trends Genet,
2023]
Prenatal exposure to environmental agents can influence the fitness of not only the fetus, but also subsequent generations. In a recent study, Wang et al. demonstrated that feeding ursolic acid (UA), a plant-derived compound, to Caenorhabditis elegans mothers during their reproductive period prevented neurodegeneration in not only their offspring, but also the F2 progeny.
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MicroPubl Biol,
2022]
The Q system is a genetic tool developed to deliver spatiotemporal control over gene expression (Giles et al. 1991; Potter et al. 2010; Wei et al. 2012). Although it has already been adapted for use in C. elegans by Wei et al. in 2012, to date, the Q system has not been applied extensively in this nematode. In the relatively few available reports, it is mainly used to constitutively restrict gene expression in a spatial manner (e.g. Schild et al. 2014; Schild and Glauser 2015; Jee et al. 2016; Tolstenkov et al. 2018; Chiyoda et al. 2021), while but a handful of studies also explore the temporal aspect of the system (Matus et al. 2015; Yuan et al. 2016; Cottee et al. 2017; Hoang and Miller 2017). We aimed to apply this tool in the C. elegans nervous system to gain both spatial and temporal control over expression of a gene encoding a reporter protein that is targeted to the secretory pathway. Despite our efforts, we here report that in our hands, the Q system is not suitable for application in the neurons due to a lack of dynamic range.
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Neuron,
2016]
Transmembrane channel-like (TMC) proteins have been implicated in hair cell mechanotransduction, Drosophila proprioception, and sodium sensing in the nematode C.elegans. In this issue of Neuron, Wang etal. (2016) report that C.elegans TMC-1 mediates nociceptor responses to high pH, not sodium, allowing the nematode to avoid strongly alkaline environments in which most animals cannot survive.
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STAR Protoc,
2022]
Live imaging is an important tool to track dynamic processes such as neuronal patterning events. Here, we describe a protocol for time-lapse microscopy analysis using neuronal migration and dendritic growth as examples. This protocol can provide detailed information for understanding cellular dynamics during postembryonic development in Caenorhabditis elegans (C. elegans). For complete details on the use and execution of this protocol, please refer to Feng etal. (2020), Li etal. (2021), and Wang etal. (2021).
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Bioessays,
2003]
Cell size is an important determinant of body size. While the genetic mechanisms of cell size regulation have been well studied in yeast, this process has only recently been addressed in multicellular organisms. One recent report by Wang et al. (2002) shows that in the nematode C. elegans, the TGFbeta-like pathway acts in the hypodermis to regulate cell size and consequently body size.((1)) This finding is an exciting step in discovering the molecular mechanisms that control cell and body size.
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MicroPubl Biol,
2019]
Several techniques are available for spatiotemporal control of genome recombination and gene expression in the nematode Caenorhabditis elegans. Here we report a novel tool to combine the powerful FLP-Frt and GAL4-UAS systems to increase their versality and to offer additional levels of control.FLP is an enzyme that catalyzes recombination between two short Frt DNA sequences and is frequently used to excise genomic fragments flanked by Frt sites, thereby either activating or knocking out gene expression, depending on the experimental design (Hubbard, 2014). Recently, we generated multiple strains that stably express FLP in different somatic tissues from single-copy transgenes and demonstrated that they in most cases induce recombination in ~100% of the cells of the expected tissue (Munoz-Jimenez et al., 2017). We subsequently constructed a strain for germline recombination to permanently knock out Frt-flanked genes or exons (Macas-Len and Askjaer, 2018).The GAL4-UAS system is based on the Saccharomyces cerevisiae Gal4p transcription factor and its cognate DNA target called upstream activating sequence (UAS). Typically, this bipartite system includes a series of driver strains expressing GAL4 in specific tissues and one or several strains with an effector gene downstream of UAS repeats. Wang and colleagues from the Sternberg laboratory recently optimized the GAL4-UAS system for C. elegans (cGAL) and reported several tissue-specific cGAL drivers (Wang et al., 2017). Moreover, they have developed a split cGAL toolkit where the DNA binding and activation domains are expressed as individual polypeptides, thereby enabling further fine-tuning of spatiotemporal control: only when and where the two components are co-expressed they will activate the UAS::effector transgene (Wang et al., 2018).