-
[
Curr Biol,
2005]
Aurora B kinases play important roles during mitosis in eukaryotic cells; new work in Caenorhabditis elegans has identified the Tousled kinase TLK-1 as a substrate activator of the model nematode''''s Aurora B kinase AIR-2 which acts to ensure proper chromosome segregation during
-
[
1986]
Wild-type body wall muscle cells of Caenorhabditis elegans produce at a constant ratio two myosin heavy chain isoforms, A and B, that form homodimeric myosins. Electron microscopy of negatively stained complexes of isoform-specific antibodies with isolated thick filaments shows that the surface of the 9.7 =B5m long filament is differentiated with respect to myosin content: a medial 1.8 =B5m zone contains myosin A and two polar 4.4 = =B5m zones contain myosin B. Biochemical and electron microscopic studies show that at 0.45 M KC1, pH 6.35, myosin B and paramyosin are solubilized. The medial all-myosin A region with novel core structures extending in a polar manner remain. These dissociation experiments suggest a sequential model for wild-type thick filament assembly in which myosins A and B would participate in the initiation and termination of assembly, respectively. Analysis of mutant thick filaments clarifies the relationship of the myosin isoforms. CB190 (
unc-54 I) thick filaments contain myosin A only and have normal length. CB1214 (
unc-15 I) mutants produce no paramyosin, and their thick filaments are composed of a medial myosin region
-
[
1986]
C. elegans body wall muscle thick filaments are assembled from two different types of myosin heavy chain, MHC A and MHC B. The structural gene for the MHC A protein has been identified from the reaction of bacterial fusion peptides with specific monoclonal antibodies. We have also shown that a mutation in the
sup-3 locus that enhances the accumulation of the MHC A protein is closely linked to the MHC A gene. A model of
sup-3 action is proposed.
-
[
Genetics,
2019]
The <b>T</b>arget <b>o</b>f <b>R</b>apamycin (TOR or mTOR) is a serine/threonine kinase that regulates growth, development, and behaviors by modulating protein synthesis, autophagy, and multiple other cellular processes in response to changes in nutrients and other cues. Over recent years, TOR has been studied intensively in mammalian cell culture and genetic systems because of its importance in growth, metabolism, cancer, and aging. Through its advantages for unbiased, and high-throughput, genetic and <i>in vivo</i> studies, <i>Caenorhabditis elegans</i> has made major contributions to our understanding of TOR biology. Genetic analyses in the worm have revealed unexpected aspects of TOR functions and regulation, and have the potential to further expand our understanding of how growth and metabolic regulation influence development. In the aging field, <i>C. elegans</i> has played a leading role in revealing the promise of TOR inhibition as a strategy for extending life span, and identifying mechanisms that function upstream and downstream of TOR to influence aging. Here, we review the state of the TOR field in <i>C. elegans</i>, and focus on what we have learned about its functions in development, metabolism, and aging. We discuss knowledge gaps, including the potential pitfalls in translating findings back and forth across organisms, but also describe how TOR is important for <i>C. elegans</i> biology, and how <i>C. elegans</i> work has developed paradigms of great importance for the broader TOR field.
-
[
Genome Biol,
2001]
SUMMARY: All G-protein-coupled receptors (GPCRs) share a common molecular architecture (with seven putative transmembrane segments) and a common signaling mechanism, in that they interact with G proteins (heterotrimeric GTPases) to regulate the synthesis of intracellular second messengers such as cyclic AMP, inositol phosphates, diacylglycerol and calcium ions. Historically, GPCRs have been classified into six families, which were thought to be unrelated; three of these are found in vertebrates. Recent work has identified several new GCPR families and suggested the possibility of a common evolutionary origin for all of them. Family B (the secretin-receptor family or ''family 2'') of the GPCRs is a small but structurally and functionally diverse group of proteins that includes receptors for polypeptide hormones, molecules thought to mediate intercellular interactions at the plasma membrane and a group of Drosophila proteins that regulate stress responses and longevity. Family-B GPCRs have been found in all animal species investigated, including mammals, Caenorhabditis elegans and Drosophila melanogaster, but not in plants, fungi or prokaryotes. In this article, I describe the structures and functions of family-B GPCRs and propose a simplified nomenclature for these proteins.
-
[
Results Probl Cell Differ,
2017]
Asymmetric cell division is a common mode of cell differentiation during the invariant lineage of the nematode, C. elegans. Beginning at the four-cell stage, and continuing throughout embryogenesis and larval development, mother cells are polarized by Wnt ligands, causing an asymmetric inheritance of key members of a Wnt/B-catenin signal transduction pathway termed the Wnt/B-catenin asymmetry pathway. The resulting daughter cells are distinct at birth with one daughter cell activating Wnt target gene expression via B-catenin activation of TCF, while the other daughter displays transcriptional repression of these target genes. Here, we seek to review the body of evidence underlying a unified model for Wnt-driven asymmetric cell division in C. elegans, identify global themes that occur during asymmetric cell division, as well as highlight tissue-specific variations. We also discuss outstanding questions that remain unanswered regarding this intriguing mode of asymmetric cell division.
-
[
Trends in Cell Biology,
1996]
Cellular microtubules assemble and disassemble at a variety of rates and frequencies, and these properties contribute directly to the cell-cycle-associated rearrangements of the microtubule cytoskeleton and to the molecular basis of mitosis. The kinetics of assembly/disassembly are governed, in part, by the hydrolysis of GTP bound to the B-tubulin nucleotide-binding site. The B-tubulin GTP-binding site, therefore, lies at the heart of microtubule assembly-disassembly kinetics, and the elucidation of its structure is central to an understanding of the cellular behaviour of microtubules. Unfortunately, the crystallographic structure of B-tubulin is not yet available. In this review, we describe the progress being made using mutagenesis and biochemical studies to understand the structure of this unusual GTP-binding site.
-
[
Cell Motility and the Cytoskeleton,
1995]
The tubilin family has been considered to have two members, the a- and B-tubulins, which interact to form the heterodimers which in turn assemble to form the eukaryotic microtubules. A third member, y-tubulin, was identified in 1989 and has since been shown to be specifically localized in Microtubule Organizing Centers and has been implicated in the nucleation of microtubules in vivo. Comparisons of individual a-, B-, and y-tubulin sequences within the three subfamilies yield homologies of 65-100% identity. By contrast, comparisons between the three subfamilies typically yield homologies of only about 30-40% identity. The Caenorhabditis and yeast genome projects have recently identified two putative y-tubulin sequences. Analysis of these sequences, however, shows that they are significantly different from those of bona fide y-tubulins...
-
[
Int J Parasitol,
2001]
Helminth parasites have large genomes (approximately 10(8) bp) which are likely to encode a spectrum of products able to block or divert the host immune response. We have employed three parallel approaches to identify the first generation of 'immune evasion genes' from parasites such as the filarial nematode Brugia malayi. The first strategy is a conventional route to characterise prominent surface or secreted antigens. In this way we have identified a 15-kDa protein, which is located on the surface of both L3 and adult B. malayi, and secreted by these parasites in vitro, as a member of the cystatin (cysteine protease inhibitor) family. This product, Bm-CPI-2, blocks conventional cysteine proteases such as papain, but also the aspariginyl endopeptidase involved in the Class II antigen processing pathway in human B cells. In parallel, we identified the major T cell-stimulating antigen from the microfilarial stage as a serpin (serine protease inhibitor), Bm-SPN-2. Microfilariae secrete this product which blocks two key proteases of the neutrophil, a key mediator of inflammation and innate immunity. The second route involves a priori hypotheses that helminth parasites encode homologues of mammalian cytokines such as TGF-beta which are members of broad, ancient metazoan gene families. We have identified two TGF-beta homologues in B. malayi, and shown that one form (Bm-TGH-2) is both secreted by adult parasites in vitro and able to bind to host TGF-beta receptors. Likewise, B. malayi expresses homologues of mammalian MIF, which are remarkably similar in both structure and function to the host protein, even though amino acid identity is only 28%. Finally, we deployed a third method of selecting critical genes, using an expression-based criterion to select abundant mRNAs taken from key points in parasite life histories. By this means, we have shown that the major transcript present in mosquito-borne infective larvae, Bm-ALT, is a credible vaccine candidate for use against lymphatic filariasis, while a second abundantly-expressed gene, Bm-VAL-1, is similar to a likely vaccine antigen being developed against hookworm parasites.
-
[
Annual Review of Genetics,
2000]
Mechanisms for repetition of DNA pose both opportunities and challenges to a functional genome: opportunities for increasing gene expression by amplification of useful sequences, and challenges of controlling amplification by unwanted sequences such as transposons and viruses. Experiments in numerous organisms have suggested the likely existence of a general mechanism for recognition of repeated character in DNA. This review focuses (a) on the nature of these recognition mechanisms, and (b) on types of chromatin modification and gene silencing that are used to control repeated DNA.