-
[
Neuron,
1999]
We investigated the EGL-30 (Gqalpha) pathway in C. elegans by using genetic screens to identify genes that confer phenotypes similar to
egl-30 mutants. One such gene,
egl-8, encodes a phospholipase Cbeta that is present throughout the nervous system and near intestinal cell junctions. EGL-30 and EGL-8 appear to positively regulate synaptic transmission because reducing their function results in strong aldicarb resistance and slow locomotion rates. In contrast, GOA-1 (Goalpha) and DGK-1 (diacylglycerol kinase) appear to negatively regulate synaptic transmission, because reducing their function results in strong aldicarb hypersensitivity and hyperactive locomotion. A genetic analysis suggests that GOA-1 negatively regulates the EGL-30 pathway and that DGK-1 antagonizes the EGL-30 pathway.AD - Program in Molecular and Cell Biology, Oklahoma Medical Research Foundation, Oklahoma City 73104, USA.FAU - Miller, K GAU - Miller KGFAU - Emerson, M DAU - Emerson MDFAU - Rand, J BAU - Rand JBLA - engSI - GENBANK/AF179426ID - NS33187/NS/NINDSPT - Journal ArticleCY - UNITED STATESTA - NeuronJID - 8809320RN - 0 (Helminth Proteins)RN - 0 (Isoenzymes)RN - 0 (guanine nucleotide-binding protein Go)RN - EC 2.7.1.107 (Diacylglycerol Kinase)RN - EC 3.1.4.- (phospholipase C beta)RN - EC 3.1.4.3 (Phospholipase C)RN - EC 3.6.1.- (Heterotrimeric GTP-Binding Proteins)SB - IM
-
[
Science,
2001]
Caenorhabditis elegans oocytes, like those of most animals, arrest during meiotic prophase. Sperm promote the resumption of meiosis (maturation) and contraction of smooth muscle-like gonadal sheath cells, which are required for ovulation. We show that the major sperm cytoskeletal protein (MSP) is a bipartite signal for oocyte maturation and sheath contraction. MSP also functions in sperm locomotion, playing a role analogous to actin. Thus, during evolution, MSP has acquired extracellular signaling and intracellular cytoskeletal functions for reproduction. Proteins with MSP-like domains are found in plants, fungi, and other animals, suggesting that related signaling functions may exist in other phyla.AD - Department of Cell Biology, Mass Spectrometry Research Center, Vanderbilt University School of Medicine, Nashville, TN 37232, USA.FAU - Miller, M AAU - Miller MAFAU - Nguyen, V QAU - Nguyen VQFAU - Lee, M HAU - Lee MHFAU - Kosinski, MAU - Kosinski MFAU - Schedl, TAU - Schedl TFAU - Caprioli, R MAU - Caprioli RMFAU - Greenstein, DAU - Greenstein DLA - engID - CA09592/CA/NCIID - GM57173/GM/NIGMSID - GM58008/GM/NIGMSID - HD07043/HD/NICHDID - HD25614/HD/NICHDPT - Journal ArticleCY - United StatesTA - ScienceJID - 0404511RN - 0 (Carrier Proteins)RN - 0 (Helminth Proteins)RN - 0 (MAP Kinase Signaling System)RN - 0 (Membrane Proteins)RN - 0 (Recombinant Proteins)RN - 0 (VAP-33 protein)RN - 0 (major sperm protein, nematode)RN - EC 2.7.1.- (Mitogen-Activated Protein Kinases)SB - IM
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[
MicroPubl Biol,
2020]
Mechanistic target of rapamycin (mTOR), a serine/threonine protein kinase, regulates biological processes in response to changes in nutrients or metabolites (Reviewed in Liu and Sabatini, 2020). Inhibition of mTOR signaling delays aging and increases lifespan in multiple organisms by downregulating substrates, including S6 kinase (S6K) that phosphorylates ribosomal subunit 6 (Reviewed in Kennedy and Lamming, 2016). Genetic inhibition of RSKS-1, the Caenorhabditis elegans S6 kinase, extends lifespan via decreasing protein synthesis and upregulating longevity-promoting factors (Reviewed in Johnson et al., 2013; Lee et al. 2015). However, the longevity phenotypes of previously characterized loss-of-function
rsks-1 mutants are variable and greatly affected by environmental factors, such as temperatures (Seo et al., 2013; Miller et al., 2017). Here, we aimed at identifying
rsks-1 mutants whose lifespan phenotypes are robust and reproducible at 20C, the standard temperature for C. elegans lifespan assays.
-
[
Biochem Soc Trans,
2003]
Despite the central role of the 26 S proteasome in eukaryotic cells, many facets of its structural organization and functioning are still poorly understood. To learn more about the interactions between its different subunits, as well as its possible functional partners in cells, we performed, with Marc Vidal's laboratory (Dana-Farber Cancer Institute, Boston, MA, U.S.A.), a systematic two-hybrid analysis using Caenorhaditis elegans 26 S proteasome subunits as baits (Davy, Bello, Thierry-Mieg, Vaglio, Hitti, Doucette-Stamm, Thierry-Mieg, Reboul, Boulton, Walhout et al. (2001) EMBO Rep. 2, 821-828). A pair-wise matrix of all subunit combinations allowed us to detect numerous possible intra-complex interactions, among which some had already been reported by others and eight were novel. Interestingly, four new interactions were detected between two ATPases of the 19 S regulatory complex and three alpha-subunits of the 20 S proteolytic core. Possibly, these interactions participate in the association of these two complexes to form the 26 S proteasome. Proteasome subunit sequences were also used to screen a cDNA library to identify new interactors of the complex. Among the interactors found, most (58) have no clear connection to the proteasome, and could be either substrates or potential cofactors of this complex. Few interactors (7) could be directly or indirectly linked to proteolysis. The others (12) interacted with more than one proteasome subunit, forming 'interaction clusters' of
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[
Nature,
1994]
Platelet-activating factor (PAF) is involved in a variety of biological and pathological processes and PAF acetylhydrolase, which inactivates PAF by removing the acetyl group at the sn-2 position, is widely distributed in plasma and tissue cytosols. One isoform of PAF acetylhydrolase present in bovine brain cortex is a heterotrimer comprising subunits with relative molecular masses of 45K, 30K and 29K (ref. 4). We have now isolated the complementary DNA for the 45K subunit. Sequence analysis revealed a striking identity (99%) of the subunit with a protein encoded by the causative gene (LIS-1) for Miller-Dieker lissencephaly, a human brain malformation manifested by a smooth cerebral surface and abnormal neuronal migration. This indicates that the LIS-1 gene product is a human homologue of the 45K subunit of intracellular PAF acetylhydrolase. Our results raise the possibility that PAF and PAF acetylhydrolase are important in the formation of the brain cortex during differentiation and development.
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[
Dev Biol,
1999]
A TGFbeta-like signal is required for spicule development in Caenorhabditis elegans males. This signal appears to originate in the male-specific musculature and is required for the migrations of cells within the proctodeum. The migrations of these cells form cellular molds, the spicule traces, in which the cuticle of the spicules is secreted. Mutations in
daf-4,
sma-2,
sma-3, and
sma-4, which disrupt TGFbeta-like signaling, result in aberrant migrations and morphologically abnormal spicules.
daf-4, and hence the TGFbeta-like signal, is required prior to or during cell migrations. Therefore, the TGFbeta-like signal may act to prime the migrating cells or as a guidance cue. Mutations in
lin-31 result in identical cell migration and spicule morphology defects. Thus,
lin-31, which encodes a "winged helix" protein (Miller et al., Genes Dev. 7, 933-947, 1993), may be a component of this TGFbeta-like signaling pathway.
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[
J Cell Biol,
1985]
Myosin isoforms A and B are differentially localized to the central and polar regions, respectively, of thick filaments in body wall muscle cells of Caenorhabditis elegans (Miller, D.M. III, I. Ortiz, G.C. Berliner, and H.F. Epstein, 1983, Cell, 34: 477-490). Biochemical and electron microscope studies of KCl-dissociated filaments show that the myosin isoforms occupy a surface domain, paramyosin constitutes an intermediate domain, and a newly identified core structure exists. The diameters of the thick filaments vary significantly from 33.4 nm centrally to 14.0 nm near the ends. The latter value is comparable to the 15.2 nm diameter of the core structures. The internal density of the filament core appears solid medially and hollow at the poles. The differentiation of thick filament structure into supramolecular domains possessing specific substructures of characteristic stabilities suggests a sequential mode for thick filament assembly. In this model, the two myosin isoforms have distinct roles in assembly. The behavior of the myosins, including nucleation of assembly and determination of filament length, depend upon paramyosin and the core structure as well as their intrinsic molecular properties.
-
[
EMBO J,
1989]
Caenorhabditis elegans body wall muscle has two distinct myosin heavy chain isoforms, mhcA and mhcB. Mutations eliminating the major isoform, mhcB, have previously been shown to yield paralyzed, viable animals. In this paper we show that the minor isoform, mhcA, is essential for viability. We have utilized the known physical map position of the gene encoding mhcA to obtain two recessive lethal mutations that virtually eliminate accumulation of mhcA. The mutations are allelic, and the interactions of these alleles with mutations affecting other thick filament components are consistent with the hypothesis that the new mutations lie in the structural gene for mhcA. The homozygous mutant animals move very little and morphological analysis shows that thick filament assembly is severely impaired. Together with the location of mhcA in the center of the thick filament (Miller et al., 1983), the results suggest that mhcA has a unique role in initiating filament assembly. The homozygous mutations have an unexpected effect on morphogenesis that indicates an interaction between the muscle cells and the hypodermis during development. The resultant phenotype may be useful in the search for additional essential muscle genes.
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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.
-
[
MicroPubl Biol,
2021]
MEC-4 and UNC-8 are subunits of the DEG/ENaC family of voltage-independent Na+ channels in C. elegans (Driscoll and Chalfie 1991, Canessa, Horisberger et al. 1993, Waldmann, Champigny et al. 1996, Waldmann, Champigny et al. 1997, de Weille, Bassilana et al. 1998, Waldmann and Lazdunski 1998). While MEC-4 is expressed in body touch neurons where it mediates the transduction of gentle touch sensation (Driscoll and Chalfie 1991, O'Hagan, Chalfie et al. 2005), UNC-8 is primarily expressed in motoneurons where it is involved in synaptic remodeling during development (Tavernarakis, Shreffler et al. 1997, Miller-Fleming, Petersen et al. 2016). Both MEC-4 and UNC-8 can be hyperactivated by genetic mutations that hinder channel closing, called (d) mutations (Driscoll and Chalfie 1991, Shreffler, Magardino et al. 1995, Goodman, Ernstrom et al. 2002, Wang, Matthewman et al. 2013). C. elegans neurons and Xenopus oocytes expressing these hyperactive variants of MEC-4 and UNC-8 undergo cell death due to uncontrolled flux of ions into the cell. Cell death in Xenopus oocytes and in cultured C. elegans neurons can be prevented by incubation with the DEG/ENaC channel blocker amiloride (Goodman, Ernstrom et al. 2002, Suzuki, Kerr et al. 2003, Wang, Matthewman et al. 2013).