High molecular weight homologues of gp91phox, the superoxide-generating subunit of phagocyte nicotinamide adenine dinucleotide phosphate (NADPH)-oxidase, have been identified in human (h) and Caenorhabditis elegans (Ce), and are termed Duox for “dual oxidase” because they have both a peroxidase homology domain and a gp91phox domain. A topology model predicts that the enzyme will utilize cytosolic NADPH to generate reactive oxygen, but the function of the ecto peroxidase domain was unknown. Ce-Duox1 is expressed in hypodermal cells underlying the cuticle of larval animals. To investigate function, RNA interference (RNAi) was carried out in C. elegans. RNAi animals showed complex phenotypes similar to those described previously in mutations in collagen biosynthesis that are known to affect the cuticle, an extracellular matrix. Electron micrographs showed gross abnormalities in the cuticle of RNAi animals. In cuticle, collagen and other proteins are cross-linked via di- and trityrosine linkages, and these linkages were absent in RNAi animals. The expressed peroxidase domains of both Ce-Duox1 and h-Duox showed peroxidase activity and catalyzed cross-linking of free tyrosine ethyl ester. Thus, Ce-Duox catalyzes the cross-linking of tyrosine residues involved in the stabilization of cuticular extracellular matrix.
The Caenorhabditis elegans gene unc-22 encodes a very large muscle protein, called twitchin, which consists of a protein kinase domain and several copies of two short motifs. The sequence of twitchin has unexpected similarities to the sequences of proteins of the immunoglobulin superfamily, cell adhesion molecules and vertebrate muscle proteins, including myosin light-chain kinase. These homologies, together with results from earlier genetic and molecular analyses, indicate that twitchin is involved in a novel mechanism of myosin regulation.
Abstract. Mutations in the Caenorhabditis elegans gene unc-89 result in nematodes having disorganized muscle structure in which thick filaments are not organized into A-bands, and there are no M-lines (Waterston, R.H., J.N. Thomson, and S. Brenner. 1980. Dev. Biol. 77:271-302 124:491-506). We propose that the intracellular protein UNC-89 responds to these signals, localizes, and then participates in assembling an M-line.
The Caenorhabditis elegans unc-60 gene encodes two functionally distinct isoforms of ADF/cofilin that are implicated in myofibril assembly. Here, we show that one of the gene products, UNC-60B, is specifically required for proper assembly of actin into myofibrils. We found that all homozygous viable unc-60 mutations resided in the unc-60B coding region, indicating that UNC-60B is responsible for the Unc-60 phenotype. Wild-type UNC-60B had F-actin binding, partial actin depolymerizing, and weak F-actin severing activities in vitro. However, mutations in UNC-60B caused various alterations in these activities. Three missense mutations resulted in weaker F-actin binding and actin depolymerizing activities and complete loss of severing activity. The r398 mutation truncated three residues from the COOH terminus and resulted in the loss of severing activity and greater actin depolymerizing activity. The s1307 mutation in a putative actin-binding helix caused greater activity in actin-depolymerizing and severing. Using a specific antibody for UNC-60B, we found varying protein levels of UNC-60B in mutant animals, and that UNC-60B was expressed in embryonic muscles. Regardless of these various molecular phenotypes, actin was not properly assembled into embryonic myofibrils in all unc-60 mutants to similar extents. We conclude that precise control of actin filament dynamics by UNC-60B is required for proper integration of actin into myofibrils.
Multiple studies have identified conserved genetic pathways and small molecules associated with extension of lifespan in diverse organisms. However, extending lifespan does not result in concomitant extension in healthspan, defined as the proportion of time that an animal remains healthy and free of age-related infirmities. Rather, mutations that extend lifespan often reduce healthspan and increase frailty. The question arises as to whether factors or mechanisms exist that uncouple these processes and extend healthspan and reduce frailty independent of lifespan. We show that indoles from commensal microbiota extend healthspan of diverse organisms, including Caenorhabditis elegans, Drosophila melanogaster, and mice, but have a negligible effect on maximal lifespan. Effects of indoles on healthspan in worms and flies depend upon the aryl hydrocarbon receptor (AHR), a conserved detector of xenobiotic small molecules. In C. elegans, indole induces a gene expression profile in aged animals reminiscent of that seen in the young, but which is distinct from that associated with normal aging. Moreover, in older animals, indole induces genes associated with oogenesis and, accordingly, extends fecundity and reproductive span. Together, these data suggest that small molecules related to indole and derived from commensal microbiota act in diverse phyla via conserved molecular pathways to promote healthy aging. These data raise the possibility of developing therapeutics based on microbiota-derived indole or its derivatives to extend healthspan and reduce frailty in humans.C. elegans | aging | frailty | aryl hydrocarbon receptor | microbiota R ecent advances in health care have contributed to a significant increase in life expectancy of individuals, especially in developed countries, which predict an expansion of geriatric populations by as much as 350-fold over the next 40 y (1). However, extension of lifespan is often accompanied by increased frailty, and attendant increases in global healthcare expenditures are expected to be both massive and unsustainable (2). Such data highlight the need to develop means to extend healthspan, which is broadly defined as the length of time that an individual remains healthy and free of age-related infirmities (3, 4).Healthspan has often been convolved with lifespan, and extended healthspan has been associated with slowed onset of normal age-related changes (e.g., sarcopenia). Thus, mutations that extend lifespan might be expected to likewise extend healthspan. Recent studies in Caenorhabditis elegans indicate that, relative to wild-type animals, mutations that extend lifespan do indeed extend the period of youthfulness, in which animals are motile and resistant to bacterial infection (healthspan), but also extend the period of decrepitude or frailty, where animals are relatively immobile (5, 6) Other studies in C. elegans that take into account multiple measures of health, each normalized to maximal lifespan, indicate that mutations or conditions that extend lifespan minimally impact or ev...
Pathogenic Escherichia coli, including enteropathogenic E. coli (EPEC), enterohaemorrhagic E. coli (EHEC), enteroinvasive E. coli (EIEC) and enterotoxigenic E. coli (ETEC) are major causes of food and water-borne disease. We have developed a genetically tractable model of pathogenic E. coli virulence based on our observation that these bacteria paralyse and kill the nematode Caenorhabditis elegans. Paralysis and killing of C. elegans by EPEC did not require direct contact, suggesting that a secreted toxin mediates the effect. Virulence against C. elegans required tryptophan and bacterial tryptophanase, the enzyme catalysing the production of indole and other molecules from tryptophan. Thus, lack of tryptophan in growth media or deletion of tryptophanase gene failed to paralyse or kill C. elegans. While known tryptophan metabolites failed to complement an EPEC tryptophanase mutant when presented extracellularly, complementation was achieved with the enzyme itself expressed either within the pathogen or within a cocultured K12 strains. Thus, an unknown metabolite of tryptophanase, derived from EPEC or from commensal non-pathogenic strains, appears to directly or indirectly regulate toxin production within EPEC. EPEC strains containing mutations in the locus of enterocyte effacement (LEE), a pathogenicity island required for virulence in humans, also displayed attenuated capacity to paralyse and kill nematodes. Furthermore, tryptophanase activity was required for full activation of the LEE1 promoter, and for efficient formation of actin-filled membranous protrusions (attaching and effacing lesions) that form on the surface of mammalian epithelial cells following attachment and which depends on LEE genes. Finally, several C. elegans genes, including hif-1 and egl-9, rendered C. elegans less susceptible to EPEC when mutated, suggesting their involvement in mediating toxin effects. Other genes including sek-1, mek-1, mev-1, pgp-1,3 and vhl-1, rendered C. elegans more susceptible to EPEC effects when mutated, suggesting their involvement in protecting the worms. Moreover we have found that C. elegans genes controlling lifespan (daf-2, age-1 and daf-16), also mediate susceptibility to EPEC. Together, these data suggest that this C. elegans/EPEC system will be valuable in elucidating novel factors relevant to human disease that regulate virulence in the pathogen or susceptibility to infection in the host.
Many protein kinases are self-regulated by an intrasteric mechanism where part of the enzyme's structure directly inhibits the active site. This inhibitory structure is called a pseudosubstrate and specific regulators are required to remove it from the active site to allow substrates access. Removal of the pseudosubstrate sequence from members of the myosin light-chain kinase subfamily, including twitchin kinase, activates them but it is not known whether the pseudosubstrate sequence binds to the active site. Native twitchin is a 753K protein (6,839 residues) located in muscle A-bands of the nematode Caenorhabditis elegans and because of its size has not been easy to study. We have determined the crystal structure, refined to 2.8 A resolution, of a recombinant fragment (residues 5,890 to 6,262) of twitchin kinase that contains the catalytic core and a 60 residue carboxy-terminal tail. The C-terminal tail extends through the active site, wedged between the small and large lobes of the structure and making extensive contacts with the catalytic core which accounts for autoinhibition and provides direct support for the intrasteric mechanism of protein kinase regulation.
The Caenorhabditis elegans unc-60 gene encodes two actin depolymerizing factor/cofilin proteins which are implicated in the regulation of actin filament assembly in body wall muscle. We examined the interaction of recombinant UNC-60A and B proteins with actin and found that they differentially regulate actin filament dynamics. Co-pelleting assays with F-actin showed that UNC-60A depolymerized but did not remain bound to F-actin, whereas UNC-60B bound to but did not depolymerize F-actin. In the pH range of 6.8 -8.0, the apparent activities of UNC-60A and B did not change although UNC-60A showed greater actin-depolymerizing activity at higher pH. These activities were further confirmed by a light scattering assay and electron microscopy. The effects of these proteins on actin polymerization were quite different. UNC-60A inhibited polymerization in a concentration-dependent manner. On the other hand, UNC-60B strongly inhibited the nucleation process but accelerated the following elongation step. However, an excess amount of UNC-60B increased the amount of unpolymerized actin. These results indicate that UNC-60A depolymerizes actin filaments and inhibits actin polymerization, whereas UNC-60B strongly binds to F-actin without depolymerizing it and, through binding to Gactin, changes the rate of actin polymerization depending on the UNC-60B:actin ratio. These data suggest that the two UNC-60 isoforms play differential roles in regulating actin filament dynamics in vivo.Myofibrils are highly differentiated forms of actin cytoskeleton that are specialized for muscle contraction, but the mechanisms by which these complex and precise structures are assembled and maintained are largely unknown. Actin, a major component of thin filaments, has an inherent tendency to polymerize into filaments in vitro. However, the assembly of actin in developing muscle is regulated, and consequently, about 40% of actin is present in a monomeric form (1). In embryonic chicken skeletal muscle, proteins that bind to G-actin to prevent them from polymerization have been identified as profilin (2), actin depolymerizing factor (ADF) 1 (3), and cofilin (4).Quantitative analysis has shown that the concentrations of these three proteins are sufficient for sequestering most of G-actin at a late stage of embryonic muscle (5), suggesting that they are responsible for regulating actin filament assembly. ADF and cofilin are highly conserved proteins, are members of an ADF/cofilin family having 25-71% homology, and are found in diverse organisms. ADF/cofilin binds to both G-and F-actin at a stoichiometry of 1:1 and regulates the rate of actin polymerization (reviewed in Ref. 6). Recently, ADF/cofilin has been shown to affect the on/off rates at both ends of F-actin, which results in the enhancement of treadmilling (7). This function is necessary for the actin-based motility of Listeria monocytogenes (7, 8) and for actin turnover in cortical actin patches in yeast (9).A muscle-specific function for ADF/cofilin has been suggested by two examples. These are ...
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