The endocytic pathway of eukaryotes is essential for the internalization and trafficking of macromolecules, fluid, membranes, and membrane proteins. One of the most enigmatic aspects of this process is endocytic recycling, the return of macromolecules (often receptors) and fluid from endosomes to the plasma membrane. We have previously shown that the EH-domain protein RME-1 is a critical regulator of endocytic recycling in worms and mammals. Here we identify the RAB-10 protein as a key regulator of endocytic recycling upstream of RME-1 in polarized epithelial cells of the Caenorhabditis elegans intestine. rab-10 null mutant intestinal cells accumulate abnormally abundant RAB-5-positive early endosomes, some of which are enlarged by more than 10-fold. Conversely most RME-1-positive recycling endosomes are lost in rab-10 mutants. The abnormal early endosomes in rab-10 mutants accumulate basolaterally recycling transmembrane cargo molecules and basolaterally recycling fluid, consistent with a block in basolateral transport. These results indicate a role for RAB-10 in basolateral recycling upstream of RME-1. We found that a functional GFP-RAB-10 reporter protein is localized to endosomes and Golgi in wild-type intestinal cells consistent with a direct role for RAB-10 in this transport pathway. INTRODUCTIONEndocytosis and endocytic trafficking controls the uptake and sorting of extracellular macromolecules as well as the components of the cell membrane itself, counterbalancing secretion and allowing a complex interplay between cells and their environment that is important for a myriad of cellular activities (Brodsky et al., 2001;Maxfield and McGraw, 2004). The steps involved in the uptake and trafficking of cargo within the endosomal system have been well described, but many of the components mediating these steps at the molecular level remain to be identified (Brodsky et al., 2001;Maxfield and McGraw, 2004). Many receptors and their associated ligands cluster into clathrincoated pits, whereas other types of cargo utilize clathrinindependent uptake mechanisms (Nichols, 2003;Gesbert et al., 2004). Plasma membrane invaginations pinch off into vesicles, uncoat, and then fuse with one another and with early endosomes. In early endosomes some ligand-receptor complexes dissociate because of the reduced pH of the endosomal lumen (Mukherjee et al., 1997). Many receptors then recycle to the plasma membrane (PM) either directly or indirectly via recycling endosomes (Mukherjee et al., 1997;Maxfield and McGraw, 2004). Many ligands do not recycle but instead are transported from early to late endosomes and eventually to lysosomes for degradation (Mukherjee et al., 1997). In polarized epithelial cells such as cultured Madin-Darby canine kidney (MDCK) cells, an additional layer of complexity in the endocytic pathway contributes to formation and/or maintenance of the specialized apical and basolateral domains (Nelson and Yeaman, 2001;Mostov et al., 2003;Hoekstra et al., 2004). Both the apical and basolateral membranes deliver cargo ...
The raison d'etre of the germline is to produce oocytes and sperm that pass genetic material and cytoplasmic constituents to the next generation. To achieve this goal, many developmental processes must be executed and coordinated. ERK, the terminal MAP kinase of a number of signaling pathways, controls many aspects of development. Here we present a comprehensive analysis of MPK-1 ERK in Caenorhabditis elegans germline development. MPK-1 functions in four developmental switches: progression through pachytene, oocyte meiotic maturation/ovulation, male germ cell fate specification, and a nonessential function of promoting the proliferative fate. MPK-1 also regulates multiple aspects of cell biology during oogenesis, including membrane organization and morphogenesis: organization of pachytene cells on the surface of the gonadal tube, oocyte organization and differentiation, oocyte growth control, and oocyte nuclear migration. MPK-1 activation is temporally/spatially dynamic and most processes appear to be controlled through sustained activation. MPK-1 thus may act not only in the control of individual processes but also in the coordination of contemporaneous processes and the integration of sequential processes. Knowledge of the dynamic activation and diverse functions of MPK-1 provides the foundation for identification of upstream signaling cascades responsible for region-specific activation and the downstream substrates that mediate the various processes. I N the generation of oocytes and sperm, perhaps the most complex cells in animals, the germline lineage undergoes a multifaceted developmental process that begins in embryogenesis and continues into adulthood. While the details of the steps can differ between species due to differences in reproductive biology, a core set of events occurs in animals: germ cell fate specification, incorporation into the gonad, sexual fate specification, proliferative expansion, and gamete production. Two interconnected differentiation programs define gamete production: (1) meiosis where chromosomes pair, recombine, and then segregate to give a reassorted haploid content and (2) gametogenesis where biosynthetic and morphogenetic processes generate the large nutrient and developmental information-rich oocyte and the small motile sperm. In aggregate, these processes are essential to pass genetic material from generation to generation and to form the totipotent zygote necessary for the development of a new individual. Disruption of germline development can lead to sterility, germline tumors, and birth defects. Thus an important goal is to define the pathways and gene products that control and execute the various steps of germline development.The MAP kinase extracellular signal-regulated kinase (ERK) functions in many aspects of animal development and homeostasis (Marshall 1995;Rubin et al. 1997;Schlessinger 2000;Sundaram 2006). ERK is the terminal regulator of signaling cascades such as canonical receptor tyrosine kinase signaling, which contains core members, including the RA...
The AP2 clathrin adaptor complex links protein cargo to the endocytic machinery but it is unclear how AP2 is activated on the plasma membrane. Here we demonstrate that the membrane-associated proteins FCHo and SGIP1 convert AP2 into an open, active conformation. We screened for Caenorhabditis elegans mutants that phenocopy the loss of AP2 subunits and found that AP2 remains inactive in fcho-1 mutants. A subsequent screen for bypass suppressors of fcho-1 nulls identified 71 compensatory mutations in all four AP2 subunits. Using a protease-sensitivity assay we show that these mutations restore the open conformation in vivo. The domain of FCHo that induces this rearrangement is not the F-BAR domain or the µ-homology domain, but rather is an uncharacterized 90 amino acid motif, found in both FCHo and SGIP proteins, that directly binds AP2. Thus, these proteins stabilize nascent endocytic pits by exposing membrane and cargo binding sites on AP2.DOI: http://dx.doi.org/10.7554/eLife.03648.001
ATP13A2 (PARK9) is a late endo-lysosomal transporter of unknown function that is genetically implicated in a spectrum of neurodegenerative disorders, including Kufor-Rakeb syndrome, a parkinsonism with dementia 1 and early-onset Parkinson's disease (PD) 2. ATP13A2 offers protection against genetic and environmental risk factors of PD, whereas loss of ATP13A2 compromises lysosomal function 3. The lysosomal transport function of ATP13A2 remained unclear, but here, we establish ATP13A2 as a lysosomal polyamine exporter with highest affinity for spermine. Polyamines stimulate the activity of purified ATP13A2, while disease mutants are functionally impaired to a degree that correlates with the disease phenotype. ATP13A2 promotes cellular polyamine uptake via endocytosis and transports polyamines into the cytosol, which highlights a role for endo-lysosomes in cellular polyamine uptake. At high concentrations, polyamines induce cell toxicity, which is exacerbated by ATP13A2 loss due to lysosomal dysfunction, lysosomal rupture and cathepsin B activation. This phenotype is recapitulated in neurons and nematodes with loss of ATP13A2 or its orthologues. Thus, defective lysosomal polyamine export is a new mechanism for lysosome-dependent cell death that may be implicated in neurodegeneration. Our findings further shed light on the molecular identity of the elusive mammalian polyamine transport system. ATP13A2 is a P5B-ATPase belonging to the family of P-type ATPases, which couple ATP hydrolysis to substrate transport while transiently forming a catalytic phospho-intermediate 4. ATP13A2 is generally described as a heavy metal transporter 5 , but Ca 2+ 6 and the polyamine spermidine (SPD) 7,8 were also proposed. To screen for the transported substrate(s) of ATP13A2, we measured ATPase activity in the presence of various candidate substrates in solubilized microsomal membrane fractions of SH-SY5Y cells that overexpress human ATP13A2 wild type (WT) (WT-OE) or comparable levels of the catalytically dead D508N mutant (D508N-OE) 9,10. ATPase activity of ATP13A2 WT was significantly stimulated by the polyamines SPD and spermine (SPM) (Fig. 1a), whereas SPM had no effect on the D508N mutant (Extended Data Fig. 1a). MnCl2, ZnCl2, FeCl3, CaCl2, diamines, monoamines and amino acids exerted no effect (Extended Data Fig. 1a-3 d). The polyamines SPM, N 1-acetylspermine and SPD were able to stimulate ATPase activity in a concentration-dependent manner (Fig. 1b, Extended Data Fig. 1e) with the highest apparent affinity for SPM (Extended Data Table 1). The catalytic auto-phosphorylation and/or dephosphorylation reactions of P-type ATPases occur in response to binding of the transported substrate 4. ATP13A2 forms a phospho-intermediate on the D508 residue in the absence of SPM supplementation 9,10 , whereas SPM leads to a dose-dependent reduction in ATP13A2 phospho-enzyme levels (Fig. 1c), which is not seen with ornithine (Extended Data Fig. 1f). The dephosphorylation rate following a chase with non-radioactive ATP increased in the presence of...
Kinase Suppressor of Ras (KSR) is a conserved protein that positively regulates Ras signaling and may function as a scaffold for Raf, MEK, and ERK. However, the precise role of KSR is not well understood, and some observations have suggested that KSR might act in a parallel pathway. In C. elegans, ksr-1 is only required for a specific Ras-mediated process (sex myoblast migration) and is a nonessential positive regulator of other Ras-mediated developmental events. We report the existence of a second C. elegans ksr gene, ksr-2, which is required for Ras-mediated signaling during germline meiotic progression and functions redundantly with ksr-1 during development of the excretory system, hermaphrodite vulva, and male spicules. Thus, while the ksr-1 and ksr-2 genes are individually required only for specific Ras-dependent processes, together these two genes appear necessary for most aspects of Ras-mediated signaling in C. elegans. The finding that ksr-2; ksr-1 double mutants have strong ras-like phenotypes and severely reduced or absent levels of diphosphorylated MPK-1 ERK strongly supports models where KSR acts to promote the activation or maintenance of the Raf/MEK/ERK kinase cascade.
. A bank of 892 autoimmune sera was screened by indirect immunofluorescence on mammalian cells . Six sera were identified that recognize an antigen(s) with a cell cycle-dependent localization pattern. In interphase cells, the antibodies stained the nucleus and in mitotic cells the spindle apparatus was recognized . Immunological criteria indicate that the antigen recognized by at least one of these sera corresponds to a previously identified protein called the nuclear mitotic apparatus protein (NuMA). A cDNA which partially encodes NuMA was cloned from a Xgtll human placental cDNA expression library, and overlapping cDNA clones that encode the entire gene were isolated . DNA sequence analysis of the clones has identified a long open reading frame capable of encoding a protein of 238 kD. Analysis of the predicted protein sequence suggests that NuMA con-HE eukaryotic nucleus is an organelle that partitions DNA and nuclear processes from the cytoplasm (for review see Gerace and Burke, 1988;Newport and Forbes, 1987). Morphological studies have shown that the nucleus is composed of structural and functional domains that are involved in the various aspects of nuclear function. The nucleolus, which is involved in ribosome biogenesis, and the nuclear membrane which regulates transport between the nucleus and the cytoplasm, are two well studied examples of defined structural domains within the nucleus (Gerace and Burke, 1988;Goessens, 1984). In addition, splicing regions (Wu et al., 1991) and novel subnuclear structures such as nuclear bodies and dots of unknown functions have been described (Ascoli and Maul, 1991; Xie, K., E. F. Lambie, and M . Snyder, manuscript submitted for publication) .These components are often distributed nonrandomly within the nucleus . For example, in Drosophila the nuclear envelope interacts with telomeres, centromeres, and specific chromosomal loci (Gruenbaum et al., 1984;Hochstrasser et al ., 1988), and in yeast the nucleolus and the spindle pole body (the yeast microtubule organizing center) are localized Eric J. Lambie's present address is
Highlights d Impairment of most, but not all, mitochondrial processes causes UPR mt d Conditions inducing UPR mt lead to a decrease in mitochondrial membrane potential d Decrease in mitochondrial membrane potential acts as a signal that triggers UPR mt d The MTS of ATFS-1 acts as a sensor for decreased mitochondrial membrane potential
Differential regulation of TRPM channels governs electrolyte homeostasis in the C. elegans intestine
The transient receptor potential (TRP) channels are implicated in various cellular processes, including sensory signal transduction and electrolyte homeostasis. We show here that the GTL-1 and GON-2 TRPM channels regulate electrolyte homeostasis in the C. elegans intestine. GON-2 is responsible for a large outwardly rectifying current of intestinal cells, and its activity is tightly regulated by intracellular Mg(2+) levels, while GTL-1 mainly contributes to appropriate Mg(2+) responsiveness of the outwardly rectifying current. We also used nickel cytotoxicity to study the function of these channels. Both GON-2 and GTL-1 are necessary for intestinal uptake of nickel, but GTL-1 is continuously active while GON-2 is inactivated at higher Mg(2+) levels. This type of differential regulation of intestinal electrolyte absorption ensures a constant supply of electrolytes through GTL-1, while occasional bursts of GON-2 activity allow rapid return to normal electrolyte concentrations following physiological perturbations.
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