Your search keyword '"Kedersha N"' showing total 12 results

1. Molecular mechanisms of stress granule assembly and disassembly.

Author

Hofmann S, Kedersha N, Anderson P, and Ivanov P

Subjects

Cell Compartmentation genetics, Cell Membrane genetics, Cytoplasm genetics, Humans, Liquid Phase Microextraction, RNA, Messenger genetics, Cytoplasmic Granules genetics, Polyribosomes genetics, Ribonucleoproteins genetics, Stress, Physiological genetics

Abstract

Stress granules (SGs) are membrane-less ribonucleoprotein (RNP)-based cellular compartments that form in the cytoplasm of a cell upon exposure to various environmental stressors. SGs contain a large set of proteins, as well as mRNAs that have been stalled in translation as a result of stress-induced polysome disassembly. Despite the fact that SGs have been extensively studied for many years, their function is still not clear. They presumably help the cell to cope with the encountered stress, and facilitate the recovery process after stress removal upon which SGs disassemble. Aberrant formation of SGs and impaired SG disassembly majorly contribute to various pathological phenomena in cancer, viral infections, and neurodegeneration. The assembly of SGs is largely driven by liquid-liquid phase separation (LLPS), however, the molecular mechanisms behind that are not fully understood. Recent studies have proposed a novel mechanism for SG formation that involves the interplay of a large interaction network of mRNAs and proteins. Here, we review this novel concept of SG assembly, and discuss the current insights into SG disassembly., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2021

2. Relationship of GW/P-bodies with stress granules.

Author

Stoecklin G and Kedersha N

Subjects

Animals, Biological Transport, Cytoplasmic Granules metabolism, Fluorescent Antibody Technique, Gene Expression Regulation, Humans, MicroRNAs genetics, Microbodies metabolism, Protein Biosynthesis, RNA Stability, RNA, Messenger genetics, Ribonucleoproteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Stress, Physiological, Cytoplasmic Granules genetics, MicroRNAs metabolism, Microbodies genetics, RNA, Messenger metabolism, Ribonucleoproteins genetics

Abstract

Whereas P-bodies are intimately linked to the cytoplasmic RNA decay machinery, stress granules harbor stalled translation initiation complexes that accumulate upon stress-induced translation arrest. In this Chapter, we reflect on the relationship between P-bodies and stress granules. In mammalian cells, the two structures can be clearly distinguished from each other using specific protein or RNA markers, but they also share many proteins and mRNAs. While the formation of P-bodies and stress granules is coordinately triggered by stress, their assembly appears to be regulated independently by different pathways. Under certain types of stress, P-bodies frequently dock with stress granules, and overexpressing certain proteins that localize to both structures can cause P-body/stress granule fusion. Currently available data suggest that these self-assembling compartments are controlled by flux of mRNAs within the cytoplasm, and that their assembly mirrors the translation and degradation rates of their component mRNAs.

Published

2013

3. Stress granules.

Author

Anderson P and Kedersha N

Subjects

Animals, Cell Line, Humans, Cytoplasmic Granules metabolism, Ribonucleoproteins metabolism, Stress, Physiological

Published

2009

4. A functional RNAi screen links O-GlcNAc modification of ribosomal proteins to stress granule and processing body assembly.

Author

Ohn T, Kedersha N, Hickman T, Tisdale S, and Anderson P

Subjects

Animals, Arsenites pharmacology, Cell Line, Cytoplasmic Granules drug effects, Cytoplasmic Structures drug effects, Humans, Models, Biological, Polyribosomes drug effects, Polyribosomes metabolism, Ribosomal Proteins isolation & purification, Saccharomyces cerevisiae metabolism, Acetylglucosamine metabolism, Cytoplasmic Granules metabolism, Cytoplasmic Structures metabolism, Protein Processing, Post-Translational drug effects, RNA Interference drug effects, Ribonucleoproteins metabolism, Ribosomal Proteins metabolism

Abstract

Stress granules (SGs) and processing bodies (PBs) are microscopically visible ribonucleoprotein granules that cooperatively regulate the translation and decay of messenger RNA. Using an RNA-mediated interference-based screen, we identify 101 human genes required for SG assembly, 39 genes required for PB assembly, and 31 genes required for coordinate SG and PB assembly. Although 51 genes encode proteins involved in mRNA translation, splicing and transcription, most are not obviously associated with RNA metabolism. We find that several components of the hexosamine biosynthetic pathway, which reversibly modifies proteins with O-linked N-acetylglucosamine (O-GlcNAc) in response to stress, are required for SG and PB assembly. O-GlcNAc-modified proteins are prominent components of SGs but not PBs, and include RACK1 (receptor for activated C kinase 1), prohibitin-2, glyceraldehyde-3-phosphate dehydrogenase and numerous ribosomal proteins. Our results suggest that O-GlcNAc modification of the translational machinery is required for aggregation of untranslated messenger ribonucleoproteins into SGs. The lack of enzymes of the hexosamine biosynthetic pathway in budding yeast may contribute to differences between mammalian SGs and related yeast EGP (eIF4E, 4G and Pab1 containing) bodies.

Published

2008

5. Stress granules and processing bodies are dynamically linked sites of mRNP remodeling.

Author

Kedersha N, Stoecklin G, Ayodele M, Yacono P, Lykke-Andersen J, Fritzler MJ, Scheuner D, Kaufman RJ, Golan DE, and Anderson P

Subjects

Animals, COS Cells, Chlorocebus aethiops, Cytoplasmic Granules genetics, Cytoplasmic Granules ultrastructure, Eukaryotic Initiation Factor-2 genetics, HeLa Cells, Humans, Polyribosomes genetics, Polyribosomes metabolism, Protein Biosynthesis genetics, Protein Transport genetics, RNA Processing, Post-Transcriptional genetics, RNA, Messenger genetics, Ribonucleoproteins genetics, Stress, Physiological genetics, Transcription Factors genetics, Transcription Factors metabolism, Cytoplasmic Granules metabolism, Eukaryotic Initiation Factor-2 metabolism, RNA Stability genetics, RNA, Messenger metabolism, Ribonucleoproteins metabolism, Stress, Physiological metabolism

Abstract

Stress granules (SGs) are cytoplasmic aggregates of stalled translational preinitiation complexes that accumulate during stress. GW bodies/processing bodies (PBs) are distinct cytoplasmic sites of mRNA degradation. In this study, we show that SGs and PBs are spatially, compositionally, and functionally linked. SGs and PBs are induced by stress, but SG assembly requires eIF2alpha phosphorylation, whereas PB assembly does not. They are also dispersed by inhibitors of translational elongation and share several protein components, including Fas-activated serine/threonine phosphoprotein, XRN1, eIF4E, and tristetraprolin (TTP). In contrast, eIF3, G3BP, eIF4G, and PABP-1 are restricted to SGs, whereas DCP1a and 2 are confined to PBs. SGs and PBs also can harbor the same species of mRNA and physically associate with one another in vivo, an interaction that is promoted by the related mRNA decay factors TTP and BRF1. We propose that mRNA released from disassembled polysomes is sorted and remodeled at SGs, from which selected transcripts are delivered to PBs for degradation.

Published

2005

6. Evidence that vault ribonucleoprotein particles localize to the nuclear pore complex.

Author

Chugani DC, Rome LH, and Kedersha NL

Subjects

Animals, Cell Nucleus ultrastructure, Cells, Cultured, Dictyostelium ultrastructure, Fibroblasts ultrastructure, Fluorescent Antibody Technique, Immunoblotting, Immunohistochemistry, Liver ultrastructure, Male, Microscopy, Immunoelectron, Nuclear Envelope ultrastructure, Organelles ultrastructure, Rats, Rats, Sprague-Dawley, Nuclear Envelope chemistry, Organelles chemistry, Ribonucleoproteins analysis

Abstract

Vaults are cytoplasmic ribonucleoprotein organelles that are highly conserved among diverse eukaryotic species. Their mass (12.9 MDa), diameter (26-35 nm) and shape (two halves, each with eightfold radial symmetry) have recently been determined and are similar to those ascribed to the central plug (or transporter) of the nuclear pore complex (NPC). The size and eightfold symmetry of the vault particle make it conducive to interacting physically in a complementary manner with NPCs. The present study demonstrates that vaults specifically associate with nuclei by both immunoblotting and immunofluorescence. Immunogold EM confirmed that vaults associate with the nuclear envelope in tissue sections and with NPCs of isolated nuclei.

Published

1993

7. cDNA cloning and disruption of the major vault protein alpha gene (mvpA) in Dictyostelium discoideum.

Author

Vasu SK, Kedersha NL, and Rome LH

Subjects

Amino Acid Sequence, Animals, Base Sequence, Blotting, Southern, Cloning, Molecular, DNA, DNA, Fungal, Fungal Proteins ultrastructure, Genes, Fungal, Genes, Protozoan, Molecular Sequence Data, Protozoan Proteins ultrastructure, Ribonucleoproteins ultrastructure, Dictyostelium genetics, Fungal Proteins genetics, Protozoan Proteins genetics, Ribonucleoproteins genetics, Vault Ribonucleoprotein Particles

Abstract

Vaults are large cytoplasmic ribonucleoprotein particles found in nearly all eukaryotic cells. Dictyostelium vaults contain two major proteins, MVP alpha (94.2 kDa) and MVP beta (approximately 92 kDa). Using an anti-rat vault antibody, we screened a Dictyostelium cDNA expression library and isolated a 2.8-kilobase pair clone that contained a single full-length reading frame. The identity of the clone was established by the presence of a predicted 20-amino acid sequence identical to that found in a peptide sequenced from purified MVP alpha. We have disrupted the single copy gene using homologous recombination and have demonstrated a loss of MVP alpha. Although the cells still produce MVP beta, they do not contain characteristic vault particles, suggesting that MVP alpha is required for normal vault structure. These cells should be a valuable tool for elucidating the function of vaults.

Published

1993

8. Vault ribonucleoprotein particles from rat and bullfrog contain a related small RNA that is transcribed by RNA polymerase III.

Author

Kickhoefer VA, Searles RP, Kedersha NL, Garber ME, Johnson DL, and Rome LH

Subjects

Animals, Base Sequence, DNA genetics, DNA isolation & purification, Female, Genomic Library, Models, Structural, Molecular Sequence Data, Nucleic Acid Conformation, Oligodeoxyribonucleotides, Organ Specificity, RNA chemistry, RNA genetics, Rana catesbeiana, Rats, Restriction Mapping, Ribonucleoproteins chemistry, Liver metabolism, RNA metabolism, RNA Polymerase III metabolism, Ribonucleoproteins metabolism, Transcription, Genetic

Abstract

Vaults are large cytoplasmic ribonucleoprotein particles with a sedimentation value of about 150 S. These particles contain a unique small RNA (vault RNA (vRNA)). We have determined the sequence of the RNA associated with vaults purified from both rat and bullfrog. The rat vRNA is 141 bases in length, whereas the bullfrog vRNA is present as two highly related species of 89 and 94 bases. Despite the differences in length the predicted secondary structures of the three vRNAs are clearly related. All of the vRNAs contain sequences related to the internal promoter elements necessary for transcription by RNA polymerase III. The gene for the rat vRNA was isolated and sequenced from a rat genomic library, and its transcription by RNA polymerase III was verified using an in vitro transcription assay. The rat vRNA gene was efficiently transcribed in vitro, producing a single transcript of about 140 bases. Unlike most RNA polymerase III genes, the rat vRNA is present as a single copy gene and has a distinct tissue-specific expression pattern.

Published

1993

9. Vaults. III. Vault ribonucleoprotein particles open into flower-like structures with octagonal symmetry.

Author

Kedersha NL, Heuser JE, Chugani DC, and Rome LH

Subjects

Animals, Freeze Etching, Microscopy, Electron, Microscopy, Electron, Scanning, Models, Structural, Polyelectrolytes, Polymers metabolism, Rats, Ribonuclease, Pancreatic metabolism, Ribonucleoproteins metabolism, Trypsin metabolism, Liver ultrastructure, Polyamines, Ribonucleoproteins ultrastructure

Abstract

The structure of rat liver vault ribonucleoprotein particles was examined using several different staining techniques in conjunction with EM and digestion with hydrolytic enzymes. Quantitative scanning transmission EM demonstrates that each vault particle has a total mass of 12.9 +/- 1 MD and contains two centers of mass, suggesting that each vault particle is a dimer. Freeze-etch reveals that each vault opens into delicate flower-like structures, in which eight rectangular petals are joined to a central ring, each by a thin hook. Vaults examined by negative stain and conventional transmission EM (CTEM) also reveal the flower-like structure. Trypsin treatment of vaults resulted exclusively in cleavage of the major vault protein (p104) and concurrently alters their structure as revealed by negative stain/CTEM, consistent with a localization of p104 to the flower petals. We propose a structural model that predicts the stoichiometry of vault proteins and RNA, defines vault dimer-monomer interactions, and describes two possible modes for unfolding of vaults into flowers. These highly dynamic structural variations are likely to play a role in vault function.

Published

1991

10. Vaults. II. Ribonucleoprotein structures are highly conserved among higher and lower eukaryotes.

Author

Kedersha NL, Miquel MC, Bittner D, and Rome LH

Subjects

Animals, Cell Line, Centrifugation, Density Gradient, Dictyostelium analysis, Dictyostelium growth & development, Fibroblasts ultrastructure, Humans, Microscopy, Electron, Molecular Weight, RNA isolation & purification, Ribonucleoproteins isolation & purification, Species Specificity, Ribonucleoproteins ultrastructure

Abstract

Vaults are cytoplasmic ribonucleoprotein structures that display a complex morphology reminiscent of the multiple arches which form cathedral vaults, hence their name. Previous studies on rat liver vaults (Kedersha, N. L., and L. H. Rome. 1986. J. Cell Biol. 103:699-709) have established that their composition is unlike that of any known class of RNA-containing particles in that they contain multiple copies of a unique small RNA and more than 50 copies of a single polypeptide of 104,000 Mr. We now report on the isolation of vaults from numerous species and show that vaults appear to be ubiquitous among eukaryotes, including mammals, amphibians (Rana catesbeiana and Xenopus laevis), avians (Gallus Gallus), and the lower eukaryote Dictyostelium discoideum. Electron microscopy reveals that vaults purified from these diverse species are similar both in their dimensions and morphology. The vaults from these various species are also similar in their polypeptide composition; each being composed of a major polypeptide with an approximate mass of 100 kD and several minor polypeptides with molecular masses similar to those seen in the rat. Antibodies raised against rat vaults recognize the major vault protein of all species including Dictyostelium. Vaults therefore appear to be strongly conserved and broadly distributed, suggesting that their function is essential to eukaryotic cells.

Published

1990

11. Vaults: large cytoplasmic RNP's that associate with cytoskeletal elements.

Author

Kedersha NL and Rome LH

Subjects

Animals, Cytoplasm analysis, Dictyostelium ultrastructure, Fungal Proteins metabolism, RNA Processing, Post-Transcriptional, RNA, Fungal metabolism, Rana catesbeiana, Rats, Species Specificity, Cytoskeleton metabolism, Fibroblasts ultrastructure, RNA metabolism, Ribonucleoproteins metabolism

Published

1990

12. Isolation and characterization of a novel ribonucleoprotein particle: large structures contain a single species of small RNA.

Author

Kedersha NL and Rome LH

Subjects

Animals, Organoids analysis, Particle Size, Rats, Rats, Inbred Strains, Ribonucleoproteins, Small Nuclear, Microsomes, Liver analysis, Organoids ultrastructure, RNA, Small Nuclear isolation & purification, Ribonucleoproteins isolation & purification

Abstract

Rat liver coated vesicle preparations were frequently found to contain small ovoid bodies, which resembled coated vesicles in morphology. We have purified these bodies to homogeneity using sucrose density gradients and preparative agarose gel electrophoresis. When negatively stained and viewed by electron microscopy, the purified structures display a very distinct and complex morphology, resembling the multiple arches which form cathedral vaults. They measure 35 X 65 nm and are therefore considerably larger than ribosomes. When subjected to SDS PAGE, these structures, which we refer to as vaults, appear to contain several minor and five major species: Mr 210,000, 192,000, 104,000, 54,000, and 37,000. One of these (Mr 104,000) greatly predominates, accounting for greater than 70% of the total Coomassie Brilliant Blue-staining protein. Another major species of Mr 37,000 has been identified as a species of small RNA of unusual base composition (adenosine 12.0%, guanosine 29.7%, uridine 30.9%, and 27.4% cytidine), which migrates as a single species in urea PAGE between the 5S and 5.8S ribosomal standards, containing approximately 140 bases. Although the RNA constitutes only 4.6% of the entire structure, the large size of the particle requires that each one contains approximately 9 molecules of this RNA. Antibodies prepared against the entire particle are largely specific for the major (Mr 104,000) polypeptide species. Although they do not directly react with the RNA constituent on Western blots, these antibodies immunoprecipitate a 32P-labeled RNA of identical size from metabolically-labeled rat hepatoma cells. Vaults are observed in partially purified fractions from human fibroblasts, murine 3T3 cells, glial cells, and rabbit alveolar macrophages. It therefore appears that these novel ribonucleoprotein structures are broadly distributed among different cell types. The function of vaults is at present unknown.

Published

1986