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[
Worm Breeder's Gazette,
1994]
Vectorology I: New lacZ vectors ("building a better gene trap") Andrew Fire and SiQun Xu Carnegie Institution of Washington, Baltimore, Md 21210
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[
Dev Cell,
2014]
Reactive oxygen species (ROS) are generated as a response to cellular stress and regulate processes including cellular signaling and wound healing. In this issue of Developmental Cell, Xu and Chisholm (2014) demonstrate that mitochondrial ROS are required for proper wound healing in Caenorhabditis elegans through controlling the redox state of actin regulators.
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[
Dev Cell,
2001]
Genes that regulate apoptosis are well defined. In contrast, it has not been clear what genes are central to necrotic cell loss. In the September 27th issue of Neuron, Xu et al. (2001) report a critical role for genes that regulate storage and release of Ca2+ from the endoplasmic reticulum as important to necrotic-like cellular degeneration in Caenorhabditis elegans.
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[
International Worm Meeting,
2013]
The Q system (Potter et al., 2010) permits inducible gene expression in C. elegans (Wei et al., 2012) and is similar in principal to the widely used GAL4-UAS system. The QF transcriptional activator directs transcription via an upstream activating sequence (QUAS). But in addition, another protein, QS, can inhibit QF activation and QS repression can be relieved by a small molecule, quinic acid or QA. QA is non-toxic and can be fed to worms (Wei et al., 2012). This inducible system has the potential to control target genes in both space and time.
A chemically inducible method to control gene expression in specific cells at specific times would be tremendously useful for analyses of germline stem cells (GSCs) and their niche, the somatic distal tip cell (DTC). To this end, we are generating mosSCI insertion transgenes that rely on DTC-specific and GSC-specific regulatory sequences to drive QF expression. We are also generating a QUAS driven nuclear GFP (fused to H2B). Once we have the QF/QUAS pair working well for spatial regulation, we will add the QS/QA pair for temporal regulation. Preliminary experiments are promising and results will be shared at the meeting.
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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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[
MicroPubl Biol,
2016]
Pumps were stimulated with 10mM 5HT in M9 recorded as electropharyngeograms (EPGs) for 2 minutes in a NemaMetrix ScreenChip, and analyzed using NemAnalysis software (NemaMetrix). The null mutant strains
kqt-1(
aw3) and
kqt-3 (
aw1) were kindly donated by Dr. Aguan Wei (Wei et al., 2002) A) Pump frequency in
kqt-1(
aw3) animals was significantly lower than in N2s, while
kqt-3(
aw1) worms showed an increase in pump frequency (*p<0.05; ***p<0.01; 1-tailed Mann-Whitney U-test; n = 21-23 worms in each strain). B) Microfluidic EPG recordings show that pumping pattern in
kqt-1(
aw3) mutants is arrhythmic, with frequent drops in frequency. C) Overlay of first 50 pumps of recordings show that pump duration is higher in
kqt-1(
aw3) and
kqt-3(
aw1) animals than in N2s. Pumps are showed aligned on E spikes, which occur when the pharynx is fully contracted. D) Duration histogram illustrating the probability of occurrence of inter-pump interval (E to E duration) for each mutant strain. Histograms were binned to 4 ms width and normalized to reach an area underneath the curve equal to 1 (duration 100% likelihood to occur). In
kqt-1(
aw3)) animals, the time between two pumps is significantly increased compared to N2s (p < 0.01).
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[
International Worm Meeting,
2015]
C. elegans has been an effective model organism for identifying genes with important physiological functions, including in aging. However, to fully dissect gene function an effective spatial-temporal controlled gene expression system is needed. In C. elegans, several protocols have been put forward for this purpose, including driving temporal gene expression using heat shock inducible promoters (Bacaj et al. 2007), and achieving tissue-specific gene expression using site-specific recombination methods (Cre-loxP, FLP-FRT). However, none of these systems have been used for simultaneous temporal- and spatial control and it is uncertain how applicable they would be for aging studies (see Xu & Kim, 2011). While several chemicals (e.g., tetracycline, RU486) are utilized to induce gene expression in other systems, such protocols are not available in C. elegans. However, the Shen lab recently adapted the Q system to C. elegans, a system in which inducible gene expression is obtained by the chemical quinic acid (Wei et al. 2013). This binary system, originally discovered in the fungus Neurospora crassa, is comprised of the transcription factor QF and its repressor QS. In the presence of quinic acid, the QS repressor is released from binding with QF, allowing QF to activate the expression of transgenes. Temporal control is achieved through the timing of quinic acid supplementation, and spatial control by use of tissue-specific promoters that drive the expression of QS and QF (Wei et al. 2013). We are interested in applying the Q system for our research on genes with roles in aging. Towards this goal, we are focusing on three main aspects. First, we have tested the effects of quinic acid and the Q system on C. elegans lifespan and stress resistance and detected no apparent alterations on longevity or fitness, suggesting that the Q system is suitable for aging studies. Second, we are driving the elements of the Q system with tissue-specific promoters to test inducibility in major tissue types of adult animals. Preliminary results indicate that the Q system can be used to induce expression in selected tissues, including neurons and muscle. Third, we are creating a library of Gateway-compatible plasmids that contain the various elements of the Q system and tissue-specific promoters to expedite the generation of Q system transgenic strains for future gene-specific projects. We will present our current progress towards applying the Q system as a powerful tool for spatial- and temporal analysis of gene function in adult C. elegans. This work will also be discussed at the "Spatial and temporal analysis of gene function in C. elegans" workshop.
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[
Nature,
1998]
Experimental introduction of RNA into cells can be used in certain biological systems to interfere with the function of an endogenous gene. Such effects have been proposed to result from a simple antisense mechanism that depends on hybridization between the injected RNA and endogenous messenger RNA transcripts. RNA interference has been used in the nematode Caenorhabditis elegans to manipulate gene expression. Here we investigate the requirements for structure and delivery of the interfering RNA. To our surprise, we found that double-stranded RNA was substantially more effective at producing interference than was either strand individually. After injection into adult animals, purified single strands had at most a modest effect, whereas double-stranded mixtures caused potent and specific interference. The effects of this interference were evident in both the injected animals and their progeny. Only a few molecules of injected double-stranded RNA were required per affected cell, arguing against stochiometric interference with endogenous mRNA and suggesting that there could be a catalytic or amplification component in the interference process.AD - Carnegie Institution of Washington, Department of Embryology, Baltimore, Maryland 21210, USA. fire@mail1.ciwemb.eduFAU - Fire, AAU - Fire AFAU - Xu, SAU - Xu SFAU - Montgomery, M KAU - Montgomery MKFAU - Kostas, S AAU - Kostas SAFAU - Driver, S EAU - Driver SEFAU - Mello, C CAU - Mello CCLA - engPT - Journal ArticleCY - ENGLANDTA - NatureJID - 0410462RN - 0 (Calmodulin-Binding Proteins)RN - 0 (Helminth Proteins)RN - 0 (Muscle Proteins)RN - 0 (RNA, Antisense)RN - 0 (RNA, Double-Stranded)RN - 0 (twitchin)SB - IM
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[
International C. elegans Meeting,
1999]
We seek to explore the molecular mechanisms responsible for RNA-mediated genetic interference (RNAi). In nematodes, introduction of double-stranded RNA corresponding to a segment of an endogenous genetic locus can result in specific silencing of that locus, essentially producing a knock out phenotype [1]. To date, evidence indicates that this interference reflects a post-transcriptional mechanism, resulting in the loss of the endogenous transcript [2]. Only a few molecules of dsRNA are required per cell to mediate interference, suggesting either an amplification or catalytic aspect of the process [1]. To gain an understanding of the mechanism of RNAi, we are examining the fates of the two key players in this pathway, the endogenous target RNA and the dsRNA effector molecule. First, we are attempting to follow alterations in the endogenous transcripts after the introduction of dsRNA. As a start, we are trying to map possible cleavage events or potential chemical modifications through primer extension and RT PCR of the target transcript. In a complementary set of experiments, we are also examining potential changes in the dsRNA triggering molecule. Through the characterization of the target and effector RNA molecules, we hope to acquire some insight into the mechanism of RNA-triggered silencing. With this knowledge, in conjunction with genetic identification of components in the pathway, it may be possible to unravel the events and intermediates essential for RNAi. 1. Fire, Xu, Montgomery, Kostas, Driver, Mello. Nature 391, 806 2. Montgomery, Xu, and Fire. PNAS 95, 15502
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Sathaseevan, Anson, Meng, Jun, Zhen, Mei, Chang, Maggie M., Hung, Wesley L., Miller III, David M., Lu, Yangning, Wang, Ying, McWhirter, Rebecca, Luo, Linjiao
[
International Worm Meeting,
2019]
In C. elegans, there are two central pattern generators (CPGs) that contribute to forward movement - the head CPG that controls the head swing, through currently unidentified neurons, and the body CPGs, which resides in the B-type motor neurons (Xu et al., 2017). The frequency and amplitude of the head swing and body undulation are tightly coupled to allow smooth, sinusoidal forward movement. We show here that the descending interneurons, AVG and RIF, play a critical role in two aspects of forward movement: forward speed modulation and head-body coordination. While AVG is not essential for locomotion, the loss of AVG results in animals with reduced forward speed and an increased tendency to remain in a pausing/resting state. Conversely, optogenetic activation of AVG alone rapidly increases forward velocity. This effect requires gap junction-mediated activation of RIFL/R, which subsequently activates the premotor interneurons AVBL/R to increase activity of the forward movement-driving B motor neurons. When head swinging is inhibited, body undulation is decreased. Conversely, increased head swinging frequency leads to increased body undulation frequency to potentiate higher forward velocity. This suggests communication between the head and body CPGs. Our preliminary results suggest that AVG may also be required to coordinate the head and body CPGs. Activation of AVG was sufficient to drive body bends even when head swinging was inhibited. Increased head swinging is not able change body undulation when AVG is ablated. We propose that the descending interneuron circuit (AVG-RIF-AVB) permits generation of adaptive forward movement by modulating forward speed and linking the head and body CPGs. Xu, T. et. al. PNAS May 8, 2018 115 (19) E4493-E4502