Your search keyword '"Parker, R"' showing total 102 results

1. Are stress granules the RNA analogs of misfolded protein aggregates?

Author

Ripin N and Parker R

Subjects

Biomolecular Condensates metabolism, Eukaryota, Eukaryotic Cells metabolism, Eukaryotic Initiation Factor-4A chemistry, Eukaryotic Initiation Factor-4A genetics, Eukaryotic Initiation Factor-4A metabolism, Flocculation, Heat-Shock Proteins genetics, Heat-Shock Proteins metabolism, Molecular Chaperones genetics, Molecular Chaperones metabolism, Peptide Chain Initiation, Translational, Protein Aggregates, Protein Folding, RNA, Messenger genetics, RNA, Messenger metabolism, Ribonucleoproteins genetics, Ribonucleoproteins metabolism, Ribosomes genetics, Ribosomes metabolism, Stress Granules genetics, Stress Granules metabolism, Biomolecular Condensates chemistry, Heat-Shock Proteins chemistry, Molecular Chaperones chemistry, RNA, Messenger chemistry, Ribonucleoproteins chemistry, Stress Granules chemistry

Abstract

Ribonucleoprotein granules are ubiquitous features of eukaryotic cells. Several observations argue that the formation of at least some RNP granules can be considered analogous to the formation of unfolded protein aggregates. First, unfolded protein aggregates form from the exposure of promiscuous protein interaction surfaces, while some mRNP granules form, at least in part, by promiscuous intermolecular RNA-RNA interactions due to exposed RNA surfaces when mRNAs are not engaged with ribosomes. Second, analogous to the role of protein chaperones in preventing misfolded protein aggregation, cells contain abundant "RNA chaperones" to limit inappropriate RNA-RNA interactions and prevent mRNP granule formation. Third, analogous to the role of protein aggregates in diseases, situations where RNA aggregation exceeds the capacity of RNA chaperones to disaggregate RNAs may contribute to human disease. Understanding that RNP granules can be considered as promiscuous, reversible RNA aggregation events allow insight into their composition and how cells have evolved functions for RNP granules., (© 2022 Ripin and Parker; Published by Cold Spring Harbor Laboratory Press for the RNA Society.)

Published

2022

2. RNA partitioning into stress granules is based on the summation of multiple interactions.

Author

Matheny T, Van Treeck B, Huynh TN, and Parker R

Subjects

Adaptor Proteins, Signal Transducing genetics, Adaptor Proteins, Signal Transducing metabolism, Biological Transport, Cell Line, Tumor, DNA Helicases genetics, Fibroblasts cytology, Fibroblasts metabolism, Fragile X Mental Retardation Protein genetics, Fragile X Mental Retardation Protein metabolism, Genes, Reporter, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Humans, Luciferases genetics, Luciferases metabolism, Poly-ADP-Ribose Binding Proteins genetics, Protein Binding, Protein Interaction Mapping, RNA Helicases genetics, RNA Recognition Motif Proteins genetics, RNA, Long Noncoding genetics, RNA, Messenger genetics, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism, Ribonucleoproteins genetics, Stress, Physiological genetics, T-Cell Intracellular Antigen-1 genetics, T-Cell Intracellular Antigen-1 metabolism, Cytoplasmic Granules metabolism, DNA Helicases metabolism, Poly-ADP-Ribose Binding Proteins metabolism, RNA Helicases metabolism, RNA Recognition Motif Proteins metabolism, RNA, Long Noncoding metabolism, RNA, Messenger metabolism, Ribonucleoproteins metabolism, Transcriptome

Abstract

Stress granules (SGs) are stress-induced RNA-protein assemblies formed from a complex transcriptome of untranslating ribonucleoproteins (RNPs). Although RNAs can be either enriched or depleted from SGs, the rules that dictate RNA partitioning into SGs are unknown. We demonstrate that the SG-enriched NORAD RNA is sufficient to enrich a reporter RNA within SGs through the combined effects of multiple elements. Moreover, artificial tethering of G3BP1, TIA1, or FMRP can target mRNAs into SGs in a dose-dependent manner with numerous interactions required for efficient SG partitioning, which suggests individual protein interactions have small effects on the SG partitioning of mRNPs. This is supported by the observation that the SG transcriptome is largely unchanged in cell lines lacking the abundant SG RNA-binding proteins G3BP1 and G3BP2. We suggest the targeting of RNPs into SGs is due to a summation of potential RNA-protein, protein-protein, and RNA-RNA interactions with no single interaction dominating RNP recruitment into SGs., (© 2021 Matheny et al.; Published by Cold Spring Harbor Laboratory Press for the RNA Society.)

Published

2021

3. Coupling of translation quality control and mRNA targeting to stress granules.

Author

Moon SL, Morisaki T, Stasevich TJ, and Parker R

Subjects

Antigens, Neoplasm genetics, Antigens, Neoplasm metabolism, Arsenites pharmacology, Cytoplasmic Granules drug effects, Cytoplasmic Granules genetics, Gene Expression Regulation, Neoplastic, HeLa Cells, Humans, Kinetics, Neoplasms genetics, Nucleocytoplasmic Transport Proteins genetics, Nucleocytoplasmic Transport Proteins metabolism, Proteasome Endopeptidase Complex genetics, Proteasome Endopeptidase Complex metabolism, Protein Transport, Proteostasis, RNA, Messenger genetics, Ribosomes drug effects, Ribosomes genetics, Sodium Compounds pharmacology, Ubiquitin-Protein Ligases genetics, Ubiquitin-Protein Ligases metabolism, Valosin Containing Protein genetics, Valosin Containing Protein metabolism, Cytoplasmic Granules metabolism, Neoplasms metabolism, Protein Biosynthesis drug effects, RNA, Messenger metabolism, Ribosomes metabolism

Abstract

Stress granules are dynamic assemblies of proteins and nontranslating RNAs that form when translation is inhibited in response to diverse stresses. Defects in ubiquitin-proteasome system factors including valosin-containing protein (VCP) and the proteasome impact the kinetics of stress granule induction and dissolution as well as being implicated in neuropathogenesis. However, the impacts of dysregulated proteostasis on mRNA regulation and stress granules are not well understood. Using single mRNA imaging, we discovered ribosomes stall on some mRNAs during arsenite stress, and the release of transcripts from stalled ribosomes for their partitioning into stress granules requires the activities of VCP, components of the ribosome-associated quality control (RQC) complex, and the proteasome. This is an unexpected contribution of the RQC system in releasing mRNAs from translation under stress, thus identifying a new type of stress-activated RQC (saRQC) distinct from canonical RQC pathways in mRNA substrates, cellular context, and mRNA fate., (© 2020 Moon et al.)

Published

2020

4. The landscape of eukaryotic mRNPs.

Author

Khong A and Parker R

Subjects

Cell Nucleus genetics, Eukaryota genetics, Nucleic Acid Conformation, RNA, Messenger ultrastructure, RNA-Binding Proteins ultrastructure, Ribonucleoproteins biosynthesis, RNA, Messenger genetics, RNA-Binding Proteins genetics, Ribonucleoproteins genetics, Ribosomes genetics

Abstract

The proper regulation of mRNA processing, localization, translation, and degradation occurs on mRNPs. However, the global principles of mRNP organization are poorly understood. We utilize the limited, but existing, information available to present a speculative synthesis of mRNP organization with the following key points. First, mRNPs form a compacted structure due to the inherent folding of RNA. Second, the ribosome is the principal mechanism by which mRNA regions are partially decompacted. Third, mRNPs are 50%-80% protein by weight, consistent with proteins modulating mRNP organization, but also suggesting the majority of mRNA sequences are not directly interacting with RNA-binding proteins. Finally, the ratio of mRNA-binding proteins to mRNAs is higher in the nucleus to allow effective RNA processing and limit the potential for nuclear RNA based aggregation. This synthesis of mRNP understanding provides a model for mRNP biogenesis, structure, and regulation with multiple implications., (© 2020 Khong and Parker; Published by Cold Spring Harbor Laboratory Press for the RNA Society.)

Published

2020

5. RNase L Reprograms Translation by Widespread mRNA Turnover Escaped by Antiviral mRNAs.

Author

Burke JM, Moon SL, Matheny T, and Parker R

Subjects

A549 Cells, Endoribonucleases genetics, HEK293 Cells, Humans, Interferon-beta genetics, RNA Stability, RNA, Double-Stranded genetics, RNA, Double-Stranded metabolism, RNA, Messenger genetics, eIF-2 Kinase genetics, Cellular Reprogramming, Endoribonucleases metabolism, Interferon-beta biosynthesis, Protein Biosynthesis, RNA, Messenger metabolism, eIF-2 Kinase metabolism

Abstract

In response to foreign and endogenous double-stranded RNA (dsRNA), protein kinase R (PKR) and ribonuclease L (RNase L) reprogram translation in mammalian cells. PKR inhibits translation initiation through eIF2α phosphorylation, which triggers stress granule (SG) formation and promotes translation of stress responsive mRNAs. The mechanisms of RNase L-driven translation repression, its contribution to SG assembly, and its regulation of dsRNA stress-induced mRNAs are unknown. We demonstrate that RNase L drives translational shut-off in response to dsRNA by promoting widespread turnover of mRNAs. This alters stress granule assembly and reprograms translation by allowing translation of mRNAs resistant to RNase L degradation, including numerous antiviral mRNAs such as interferon (IFN)-β. Individual cells differentially activate dsRNA responses revealing variation that can affect cellular outcomes. This identifies bulk mRNA degradation and the resistance of antiviral mRNAs as the mechanism by which RNase L reprograms translation in response to dsRNA., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

6. Multicolour single-molecule tracking of mRNA interactions with RNP granules.

Author

Moon SL, Morisaki T, Khong A, Lyon K, Parker R, and Stasevich TJ

Subjects

Cell Line, Tumor, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Humans, Kinetics, Luminescent Proteins genetics, Luminescent Proteins metabolism, Models, Biological, Protein Binding, RNA, Messenger genetics, Ribonucleoproteins genetics, Stress, Physiological, Time Factors, Red Fluorescent Protein, Cell Tracking methods, Cytoplasmic Granules metabolism, Protein Biosynthesis, RNA, Messenger metabolism, Ribonucleoproteins metabolism

Abstract

Ribonucleoprotein (RNP) granules are non-membrane-bound organelles that have critical roles in the stress response 1,2 , maternal messenger RNA storage 3 , synaptic plasticity 4 , tumour progression 5,6 and neurodegeneration 7-9 . However, the dynamics of their mRNA components within and near the granule surface remain poorly characterized, particularly in the context and timing of mRNAs exiting translation. Herein, we used multicolour single-molecule tracking to quantify the precise timing and kinetics of single mRNAs as they exit translation and enter RNP granules during stress. We observed single mRNAs interacting with stress granules and P-bodies, with mRNAs moving bidirectionally between them. Although translating mRNAs only interact with RNP granules dynamically, non-translating mRNAs can form stable, and sometimes rigid, associations with RNP granules with stability increasing with both mRNA length and granule size. Live and fixed cell imaging demonstrated that mRNAs can extend beyond the protein surface of a stress granule, which may facilitate interactions between RNP granules. Thus, the recruitment of mRNPs to RNP granules involves dynamic, stable and extended interactions affected by translation status, mRNA length and granule size that collectively regulate RNP granule dynamics.

Published

2019

7. TDP-43 and RNA form amyloid-like myo-granules in regenerating muscle.

Author

Vogler TO, Wheeler JR, Nguyen ED, Hughes MP, Britson KA, Lester E, Rao B, Betta ND, Whitney ON, Ewachiw TE, Gomes E, Shorter J, Lloyd TE, Eisenberg DS, Taylor JP, Johnson AM, Olwin BB, and Parker R

Subjects

Amyloid chemistry, Amyloid genetics, Amyotrophic Lateral Sclerosis metabolism, Amyotrophic Lateral Sclerosis pathology, Animals, Cytoplasm metabolism, DNA-Binding Proteins chemistry, Female, Humans, Male, Mice, Models, Biological, Muscle Fibers, Skeletal metabolism, Muscle, Skeletal metabolism, RNA, Messenger genetics, RNA-Binding Proteins chemistry, RNA-Binding Proteins metabolism, Sarcomeres metabolism, TDP-43 Proteinopathies pathology, Amyloid metabolism, DNA-Binding Proteins metabolism, Muscle, Skeletal physiology, RNA, Messenger metabolism, Regeneration, TDP-43 Proteinopathies metabolism

Abstract

A dominant histopathological feature in neuromuscular diseases, including amyotrophic lateral sclerosis and inclusion body myopathy, is cytoplasmic aggregation of the RNA-binding protein TDP-43. Although rare mutations in TARDBP-the gene that encodes TDP-43-that lead to protein misfolding often cause protein aggregation, most patients do not have any mutations in TARDBP. Therefore, aggregates of wild-type TDP-43 arise in most patients by an unknown mechanism. Here we show that TDP-43 is an essential protein for normal skeletal muscle formation that unexpectedly forms cytoplasmic, amyloid-like oligomeric assemblies, which we call myo-granules, during regeneration of skeletal muscle in mice and humans. Myo-granules bind to mRNAs that encode sarcomeric proteins and are cleared as myofibres mature. Although myo-granules occur during normal skeletal-muscle regeneration, myo-granules can seed TDP-43 amyloid fibrils in vitro and are increased in a mouse model of inclusion body myopathy. Therefore, increased assembly or decreased clearance of functionally normal myo-granules could be the source of cytoplasmic TDP-43 aggregates that commonly occur in neuromuscular disease.

Published

2018

8. An improved MS2 system for accurate reporting of the mRNA life cycle.

Author

Tutucci E, Vera M, Biswas J, Garcia J, Parker R, and Singer RH

Subjects

Binding Sites, Capsid Proteins genetics, Cytoplasm metabolism, Humans, In Situ Hybridization, Fluorescence, RNA, Fungal genetics, RNA, Messenger genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Single-Cell Analysis, Tumor Cells, Cultured, Capsid Proteins metabolism, RNA Stability, RNA, Fungal metabolism, RNA, Messenger metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

The MS2-MCP system enables researchers to image multiple steps of the mRNA life cycle with high temporal and spatial resolution. However, for short-lived mRNAs, the tight binding of the MS2 coat protein (MCP) to the MS2 binding sites (MBS) protects the RNA from being efficiently degraded, and this confounds the study of mRNA regulation. Here, we describe a reporter system (MBSV6) with reduced affinity for the MCP, which allows mRNA degradation while preserving single-molecule detection determined by single-molecule FISH (smFISH) or live imaging. Constitutive mRNAs (MDN1 and DOA1) and highly-regulated mRNAs (GAL1 and ASH1) endogenously tagged with MBSV6 in Saccharomyces cerevisiae degrade normally. As a result, short-lived mRNAs were imaged throughout their complete life cycle. The MBSV6 reporter revealed that, in contrast to previous findings, coordinated recruitment of mRNAs at specialized structures such as P-bodies during stress did not occur, and mRNA degradation was heterogeneously distributed in the cytoplasm.

Published

2018

9. The Stress Granule Transcriptome Reveals Principles of mRNA Accumulation in Stress Granules.

Author

Khong A, Matheny T, Jain S, Mitchell SF, Wheeler JR, and Parker R

Subjects

Cell Line, Tumor, Cytoplasmic Granules genetics, Humans, RNA, Fungal genetics, RNA, Messenger genetics, Saccharomyces cerevisiae genetics, Cytoplasmic Granules metabolism, RNA, Fungal metabolism, RNA, Messenger metabolism, Saccharomyces cerevisiae metabolism, Transcriptome physiology

Abstract

Stress granules are mRNA-protein assemblies formed from nontranslating mRNAs. Stress granules are important in the stress response and may contribute to some degenerative diseases. Here, we describe the stress granule transcriptome of yeast and mammalian cells through RNA-sequencing (RNA-seq) analysis of purified stress granule cores and single-molecule fluorescence in situ hybridization (smFISH) validation. While essentially every mRNA, and some noncoding RNAs (ncRNAs), can be targeted to stress granules, the targeting efficiency varies from <1% to >95%. mRNA accumulation in stress granules correlates with longer coding and UTR regions and poor translatability. Quantifying the RNA-seq analysis by smFISH reveals that only 10% of bulk mRNA molecules accumulate in mammalian stress granules and that only 185 genes have more than 50% of their mRNA molecules in stress granules. These results suggest that stress granules may not represent a specific biological program of messenger ribonucleoprotein (mRNP) assembly, but instead form by condensation of nontranslating mRNPs in proportion to their length and lack of association with ribosomes., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

10. The helicase, DDX3X, interacts with poly(A)-binding protein 1 (PABP1) and caprin-1 at the leading edge of migrating fibroblasts and is required for efficient cell spreading.

Author

Copsey AC, Cooper S, Parker R, Lineham E, Lapworth C, Jallad D, Sweet S, and Morley SJ

Subjects

Blotting, Western, CRISPR-Cas Systems, Cell Line, Cell Movement, Chromatography, Affinity, DEAD-box RNA Helicases genetics, Fluorescent Dyes chemistry, Humans, Immunoprecipitation, Lung cytology, Lung enzymology, Microscopy, Confocal, Microscopy, Fluorescence, Peptide Mapping, Protein Transport, Proteomics methods, Pseudopodia enzymology, Respiratory Mucosa cytology, Respiratory Mucosa enzymology, Cell Cycle Proteins metabolism, DEAD-box RNA Helicases metabolism, Lung metabolism, Poly(A)-Binding Protein I metabolism, Pseudopodia metabolism, RNA, Messenger metabolism, Respiratory Mucosa metabolism

Abstract

DDX3X, a helicase, can interact directly with mRNA and translation initiation factors, regulating the selective translation of mRNAs that contain a structured 5' untranslated region. This activity modulates the expression of mRNAs controlling cell cycle progression and mRNAs regulating actin dynamics, contributing to cell adhesion and motility. Previously, we have shown that ribosomes and translation initiation factors localise to the leading edge of migrating fibroblasts in loci enriched with actively translating ribosomes, thereby promoting steady-state levels of ArpC2 and Rac1 proteins at the leading edge of cells during spreading. As DDX3X can regulate Rac1 levels, cell motility and metastasis, we have examined DDX3X protein interactions and localisation using many complementary approaches. We now show that DDX3X can physically interact and co-localise with poly(A)-binding protein 1 and caprin-1 at the leading edge of spreading cells. Furthermore, as depletion of DDX3X leads to decreased cell motility, this provides a functional link between DDX3X, caprin-1 and initiation factors at the leading edge of migrating cells to promote cell migration and spreading., (© 2017 The Author(s).)

Published

2017

11. Analysis of the association between codon optimality and mRNA stability in Schizosaccharomyces pombe.

Author

Harigaya Y and Parker R

Subjects

Datasets as Topic, Evolution, Molecular, Gene Dosage, Kinetics, Nucleotide Motifs, RNA, Messenger chemistry, Transcription, Genetic, Codon, Genes, Fungal, RNA Stability, RNA, Messenger genetics, Schizosaccharomyces genetics

Abstract

Background: Recent experiments have shown that codon optimality is a major determinant of mRNA stability in Saccharomyces cerevisiae and that this phenomenon may be conserved in Escherichia coli and some metazoans, although work in Neurospora crassa is not consistent with this model., Results: We examined the association between codon optimality and mRNA stability in the fission yeast Schizosaccharomyces pombe. Our analysis revealed the following points. First, we observe a genome-wide association between codon optimality and mRNA stability also in S. pombe, suggesting evolutionary conservation of the phenomenon. Second, in both S. pombe and S. cerevisiae, mRNA synthesis rates are also correlated at the genome-wide analysis with codon optimality, suggesting that the long-appreciated association between codon optimality and mRNA abundance is due to regulation of both mRNA synthesis and degradation. However, when we examined correlation of codon optimality and either mRNA half-lives or synthesis rates controlling for mRNA abundance, codon optimality was still positively correlated with mRNA half-lives in S. cerevisiae, but the association was no longer significant for mRNA half-lives in S. pombe or for synthesis rates in either organism. This illustrates how only the pairwise analysis of multiple correlating variables may limit these types of analyses. Finally, in S. pombe, codon optimality is associated with known DNA/RNA sequence motifs that are associated with mRNA production/stability, suggesting these two features have been under similar selective pressures for optimal gene expression., Conclusions: Consistent with the emerging body of studies, this study suggests that the association between codon optimality and mRNA stability may be a broadly conserved phenomenon. It also suggests that the association can be explained at least in part by independent adaptations of codon optimality and other transcript features for elevated expression during evolution.

Published

2016

12. Distinct stages in stress granule assembly and disassembly.

Author

Wheeler JR, Matheny T, Jain S, Abrisch R, and Parker R

Subjects

Arsenites pharmacology, Cell Line, Tumor, Cell Survival drug effects, Cycloheximide pharmacology, Cytoplasmic Granules drug effects, Cytoplasmic Granules ultrastructure, Digitonin pharmacology, Glycols pharmacology, HeLa Cells, Humans, Intrinsically Disordered Proteins metabolism, Peptide Chain Initiation, Translational drug effects, RNA, Messenger metabolism, Ribonucleoproteins metabolism, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae ultrastructure, Sodium Compounds pharmacology, Stress, Physiological, Time Factors, Cytoplasmic Granules metabolism, Intrinsically Disordered Proteins genetics, RNA, Messenger genetics, Ribonucleoproteins genetics, Saccharomyces cerevisiae genetics

Abstract

Stress granules are non-membrane bound RNA-protein (RNP) assemblies that form when translation initiation is limited and contain a biphasic structure with stable core structures surrounded by a less concentrated shell. The order of assembly and disassembly of these two structures remains unknown. Time course analysis of granule assembly suggests that core formation is an early event in granule assembly. Stress granule disassembly is also a stepwise process with shell dissipation followed by core clearance. Perturbations that alter liquid-liquid phase separations (LLPS) driven by intrinsically disordered protein regions (IDR) of RNA binding proteins in vitro have the opposite effect on stress granule assembly in vivo. Taken together, these observations argue that stress granules assemble through a multistep process initiated by stable assembly of untranslated mRNPs into core structures, which could provide sufficient high local concentrations to allow for a localized LLPS driven by IDRs on RNA binding proteins., Competing Interests: The authors declare that no competing interests exist.

Published

2016

13. Ubiquitous accumulation of 3' mRNA decay fragments in Saccharomyces cerevisiae mRNAs with chromosomally integrated MS2 arrays.

Author

Garcia JF and Parker R

Subjects

Chromosomes, Fungal, RNA, Fungal genetics, RNA, Messenger genetics, Saccharomyces cerevisiae genetics

Abstract

The binding of MS2-GFP protein to arrays of MS2 sites in yeast mRNAs has been used extensively to visualize mRNA localization. We previously reported that arrays of MS2 sites bound by MS2 protein could inhibit Xrn1p and lead to the accumulation of 3' mRNA decay fragments. We suggest that these decay fragments have the potential to complicate mRNA localization studies, as stated in an earlier study., (© 2016 Garcia and Parker; Published by Cold Spring Harbor Laboratory Press for the RNA Society.)

Published

2016

14. Identification of Endogenous mRNA-Binding Proteins in Yeast Using Crosslinking and PolyA Enrichment.

Author

Mitchell SF and Parker R

Subjects

Fungal Proteins analysis, Mass Spectrometry methods, Poly A metabolism, RNA-Binding Proteins analysis, Ultraviolet Rays, Yeasts chemistry, Yeasts growth & development, Fungal Proteins metabolism, RNA, Messenger metabolism, RNA-Binding Proteins metabolism, Yeasts metabolism

Abstract

The maturation, localization, stability, and translation of messenger RNAs (mRNAs) are regulated by a wide variety of mRNA-binding proteins. Identification of the complete set of mRNA-binding proteins is a key step in understanding the regulation of gene expression. Herein, we describe a method for identifying yeast mRNA-binding proteins in a systematic manner using UV crosslinking, purification of polyA(+) mRNAs under denaturing conditions, and mass spectrometry to identify covalently bound proteins.

Published

2016

15. Coupling of Ribostasis and Proteostasis: Hsp70 Proteins in mRNA Metabolism.

Author

Walters RW and Parker R

Subjects

Animals, HSP40 Heat-Shock Proteins genetics, HSP40 Heat-Shock Proteins metabolism, HSP70 Heat-Shock Proteins genetics, Humans, Protein Folding, HSP70 Heat-Shock Proteins metabolism, RNA, Messenger metabolism

Abstract

A key aspect of the control of gene expression is the differential rates of mRNA translation and degradation, including alterations due to extracellular inputs. Surprisingly, multiple examples now argue that Hsp70 protein chaperones and their associated Hsp40 partners modulate both mRNA degradation and translation. Hsp70 proteins affect mRNA metabolism by various mechanisms including regulating nascent polypeptide chain folding, activating signal transduction pathways, promoting clearance of stress granules, and controlling mRNA degradation in an mRNA-specific manner. Taken together, these observations highlight the general principle that mRNA metabolism is coupled to the proteostatic state of the cell, often as assessed by the presence of unfolded or misfolded proteins., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015

16. MS2 coat proteins bound to yeast mRNAs block 5' to 3' degradation and trap mRNA decay products: implications for the localization of mRNAs by MS2-MCP system.

Author

Garcia JF and Parker R

Subjects

Capsid Proteins metabolism, Green Fluorescent Proteins metabolism, Protein Array Analysis, RNA Stability, RNA, Fungal chemistry, RNA, Messenger chemistry, Saccharomyces cerevisiae genetics, Capsid Proteins chemistry, RNA, Fungal metabolism, RNA, Messenger metabolism

Abstract

Arrays of MS2 binding sites are placed into mRNAs and are commonly used to visualize the localization of mRNAs in vivo by the expression of an MS2-GFP fusion protein. In Saccharomyces cerevisiae, we observed that arrays of MS2 binding sites inhibit 5' to 3' degradation of the mRNA in yeast cells and lead to the accumulation of a 3' mRNA fragment containing the MS2 binding sites. This accumulation can be dependent on the binding of the MS2 stem loops (MS2-SL) by MS2 coat proteins (MCPs). Since such decay fragments can still bind MCP-GFP, the localization of such mRNA fragments can complicate the interpretation of the localization of full-length mRNA in vivo., (© 2015 Garcia and Parker; Published by Cold Spring Harbor Laboratory Press for the RNA Society.)

Published

2015

17. In vivo cross-linking followed by polyA enrichment to identify yeast mRNA binding proteins.

Author

Mitchell SF and Parker R

Subjects

Fungal Proteins metabolism, Protein Binding, Poly A chemistry, RNA, Messenger metabolism, RNA-Binding Proteins metabolism

Abstract

mRNA binding proteins regulate gene expression by controlling the processing, localization, decay, and translation of messenger RNAs (mRNAs). To fully understand this process, it is necessary to identify the complete set of mRNA binding proteins. This work describes a method for the systematic identification of yeast mRNA binding proteins. This method applies in vivo UV cross-linking, affinity pull-down of polyA(+) mRNAs, and analysis by mass spectrometry to identify proteins that directly bind to mRNAs.

Published

2015

18. Principles and properties of eukaryotic mRNPs.

Author

Mitchell SF and Parker R

Subjects

Active Transport, Cell Nucleus, Cell Nucleus metabolism, Gene Expression Regulation, Models, Genetic, RNA, Untranslated metabolism, RNA-Binding Proteins metabolism, Eukaryotic Cells metabolism, RNA, Messenger metabolism, Ribonucleoproteins chemistry, Ribonucleoproteins metabolism

Abstract

The proper processing, export, localization, translation, and degradation of mRNAs are necessary for regulation of gene expression. These processes are controlled by mRNA-specific regulatory proteins, noncoding RNAs, and core machineries common to most mRNAs. These factors bind the mRNA in large complexes known as messenger ribonucleoprotein particles (mRNPs). Herein, we review the components of mRNPs, how they assemble and rearrange, and how mRNP composition differentially affects mRNA biogenesis, function, and degradation. We also describe how properties of the mRNP "interactome" lead to emergent principles affecting the control of gene expression., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

19. Quality control: Is there quality control of localized mRNAs?

Author

Walters R and Parker R

Subjects

Animals, Endoplasmic Reticulum metabolism, Humans, Protein Biosynthesis, RNA Processing, Post-Transcriptional, RNA Stability, RNA Transport, RNA, Messenger genetics, RNA, Messenger metabolism

Abstract

In eukaryotic cells many mRNAs are localized to specific regions of the cytosol, thereby allowing the local production of proteins. The process of mRNA localization can be coordinated with mRNA turnover, which can also be spatially controlled to increase the degree of mRNA localization. The coordination of mRNA localization, translation repression during transport, and mRNA degradation suggests the hypothesis that an additional layer of mRNA quality control exists in cells to degrade mRNAs that fail to be appropriately localized.

Published

2014

20. The discovery and analysis of P Bodies.

Author

Jain S and Parker R

Subjects

Animals, Cytoplasmic Granules metabolism, Gene Expression Regulation, History, 20th Century, History, 21st Century, Humans, MicroRNAs genetics, MicroRNAs metabolism, Protein Biosynthesis, RNA Stability, RNA, Messenger metabolism, Ribonucleoproteins chemistry, Ribonucleoproteins metabolism, Yeasts metabolism, Cytoplasmic Granules genetics, Molecular Biology history, RNA, Messenger genetics, Ribonucleoproteins genetics, Yeasts genetics

Published

2013

21. Global analysis of yeast mRNPs.

Author

Mitchell SF, Jain S, She M, and Parker R

Subjects

Binding Sites, DEAD-box RNA Helicases metabolism, RNA Cap-Binding Proteins metabolism, RNA, Fungal metabolism, Saccharomyces cerevisiae growth & development, Stress, Physiological, Gene Expression Regulation, Fungal, RNA, Messenger metabolism, RNA-Binding Proteins metabolism, Ribonucleoproteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Proteins regulate gene expression by controlling mRNA biogenesis, localization, translation and decay. Identifying the composition, diversity and function of mRNA-protein complexes (mRNPs) is essential to understanding these processes. In a global survey of Saccharomyces cerevisiae mRNA-binding proteins, we identified 120 proteins that cross-link to mRNA, including 66 new mRNA-binding proteins. These include kinases, RNA-modification enzymes, metabolic enzymes and tRNA- and rRNA-metabolism factors. These proteins show dynamic subcellular localization during stress, including assembly into stress granules and processing bodies (P bodies). Cross-linking and immunoprecipitation (CLIP) analyses of the P-body components Pat1, Lsm1, Dhh1 and Sbp1 identified sites of interaction on specific mRNAs, revealing positional binding preferences and co-assembly preferences. When taken together, this work defines the major yeast mRNP proteins, reveals widespread changes in their subcellular location during stress and begins to define assembly rules for P-body mRNPs.

Published

2013

22. Structural basis of the PNRC2-mediated link between mrna surveillance and decapping.

Author

Lai T, Cho H, Liu Z, Bowler MW, Piao S, Parker R, Kim YK, and Song H

Subjects

Amino Acid Sequence, Amino Acid Substitution, Binding Sites, Binding, Competitive, Crystallography, X-Ray, Endoribonucleases genetics, Endoribonucleases metabolism, HEK293 Cells, Humans, Hydrogen Bonding, Hydrophobic and Hydrophilic Interactions, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Protein Binding, Protein Interaction Domains and Motifs, Protein Structure, Secondary, Protein Transport, RNA Helicases, RNA, Messenger genetics, RNA, Messenger metabolism, Receptors, Cytoplasmic and Nuclear genetics, Receptors, Cytoplasmic and Nuclear metabolism, Structural Homology, Protein, Trans-Activators genetics, Trans-Activators metabolism, Endoribonucleases chemistry, Nonsense Mediated mRNA Decay, RNA, Messenger chemistry, Receptors, Cytoplasmic and Nuclear chemistry, Trans-Activators chemistry

Abstract

Nonsense-mediated mRNA decay (NMD) is an important mRNA surveillance system, and human PNRC2 protein mediates the link between mRNA surveillance and decapping. However, the mechanism by which PNRC2 interacts with the mRNA surveillance machinery and stimulates NMD is unknown. Here, we present the crystal structure of Dcp1a in complex with PNRC2. The proline-rich region of PNRC2 is bound to the EVH1 domain of Dcp1a, while its NR-box mediates the interaction with the hyperphosphorylated Upf1. The mode of PNRC2 interaction with Dcp1a is distinct from those observed in other EVH1/proline-rich ligands interactions. Disruption of the interaction of PNRC2 with Dcp1a abolishes its P-body localization and ability to promote mRNA degradation when tethered to mRNAs. PNRC2 acts in synergy with Dcp1a to stimulate the decapping activity of Dcp2 by bridging the interaction between Dcp1a and Dcp2, suggesting that PNRC2 is a decapping coactivator in addition to its adaptor role in NMD., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012

23. P-bodies and stress granules: possible roles in the control of translation and mRNA degradation.

Author

Decker CJ and Parker R

Subjects

Cytoplasmic Granules metabolism, Gene Expression Regulation, Peptide Chain Initiation, Translational, Ribonucleoproteins metabolism, Ribonucleoproteins physiology, Models, Genetic, Protein Biosynthesis physiology, RNA Stability physiology, RNA, Messenger metabolism

Abstract

The control of translation and mRNA degradation is important in the regulation of eukaryotic gene expression. In general, translation and steps in the major pathway of mRNA decay are in competition with each other. mRNAs that are not engaged in translation can aggregate into cytoplasmic mRNP granules referred to as processing bodies (P-bodies) and stress granules, which are related to mRNP particles that control translation in early development and neurons. Analyses of P-bodies and stress granules suggest a dynamic process, referred to as the mRNA Cycle, wherein mRNPs can move between polysomes, P-bodies and stress granules although the functional roles of mRNP assembly into higher order structures remain poorly understood. In this article, we review what is known about the coupling of translation and mRNA degradation, the properties of P-bodies and stress granules, and how assembly of mRNPs into larger structures might influence cellular function.

Published

2012

24. Global analysis of mRNA decay intermediates in Saccharomyces cerevisiae.

Author

Harigaya Y and Parker R

Subjects

Base Sequence, Blotting, Northern, Endoribonucleases metabolism, Half-Life, Kinetics, Molecular Sequence Data, Oligonucleotides genetics, Plasmids genetics, RNA Caps metabolism, RNA Stability genetics, Reverse Transcriptase Polymerase Chain Reaction, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins metabolism, Sequence Alignment, Sequence Analysis, RNA, Endonucleases metabolism, RNA Stability physiology, RNA, Messenger metabolism, Saccharomyces cerevisiae physiology

Abstract

The general pathways of eukaryotic mRNA decay occur via deadenylation followed by 3' to 5' degradation or decapping, although some endonuclease sites have been identified in metazoan mRNAs. To determine the role of endonucleases in mRNA degradation in Saccharomyces cerevisiae, we mapped 5' monophosphate ends on mRNAs in wild-type and dcp2 xrn1 yeast cells, wherein mRNA endonuclease cleavage products are stabilized. This led to three important observations. First, only few mRNAs that undergo low-level endonucleolytic cleavage were observed, suggesting that endonucleases are not a major contributor to yeast mRNA decay. Second, independent of known decapping enzymes, we observed low levels of 5' monophosphates on some mRNAs, suggesting that an unknown mechanism can generate 5' exposed ends, although for all substrates tested, Dcp2 was the primary decapping enzyme. Finally, we identified debranched lariat intermediates from intron-containing genes, demonstrating a significant discard pathway for mRNAs during the second step of pre-mRNA splicing, which is a potential step to regulate gene expression.

Published

2012

25. RGG motif proteins: modulators of mRNA functional states.

Author

Rajyaguru P and Parker R

Subjects

Amino Acid Motifs, Eukaryotic Initiation Factor-4E metabolism, Eukaryotic Initiation Factor-4G metabolism, Nuclear Proteins metabolism, Protein Biosynthesis, Protein-Arginine N-Methyltransferases metabolism, RNA-Binding Proteins metabolism, Ribonucleoproteins metabolism, Saccharomyces cerevisiae metabolism, RNA, Messenger metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

A recent report demonstrates that a subset of RGG-motif proteins can bind translation initiation factor eIF4G and repress mRNA translation. This adds to the growing number of roles RGG-motif proteins play in modulating transcription, splicing, mRNA export and now translation. Herein, we review the nature and breadth of functions of RGG-motif proteins. In addition, the interaction of some RGG-motif proteins and other translation repressors with eIF4G highlights the role of eIF4G as a general modulator of mRNA function and not solely as a translation initiation factor.

Published

2012

26. The DEAD-box protein Ded1 modulates translation by the formation and resolution of an eIF4F-mRNA complex.

Author

Hilliker A, Gao Z, Jankowsky E, and Parker R

Subjects

Adenosine Triphosphate metabolism, Amino Acid Sequence, Cytoplasmic Granules metabolism, DEAD-box RNA Helicases chemistry, DEAD-box RNA Helicases metabolism, Eukaryotic Initiation Factor-4G metabolism, Gene Expression Regulation, Models, Genetic, Molecular Sequence Data, Ribonucleoproteins metabolism, Ribonucleoproteins physiology, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism, Sequence Alignment, DEAD-box RNA Helicases physiology, Eukaryotic Initiation Factor-4F metabolism, Protein Biosynthesis, RNA, Messenger metabolism, Saccharomyces cerevisiae Proteins physiology

Abstract

The translation, localization, and degradation of cytoplasmic mRNAs are controlled by the formation and rearrangement of their mRNPs. The conserved Ded1/DDX3 DEAD-box protein functions in an unknown manner to affect both translation initiation and repression. We demonstrate that Ded1 first functions by directly interacting with eIF4G to assemble a Ded1-mRNA-eIF4F complex, which accumulates in stress granules. After ATP hydrolysis by Ded1, the mRNP exits stress granules and completes translation initiation. Thus, Ded1 functions both as a repressor of translation, by assembling an mRNP stalled in translation initiation, and as an ATP-dependent activator of translation, by resolving the stalled mRNP. These results identify Ded1 as a translation initiation factor that assembles and remodels an intermediate complex in translation initiation., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011

27. Structure of the Dom34-Hbs1 complex and implications for no-go decay.

Author

Chen L, Muhlrad D, Hauryliuk V, Cheng Z, Lim MK, Shyp V, Parker R, and Song H

Subjects

Calorimetry, Crystallography, X-Ray, Endoribonucleases metabolism, Guanosine Triphosphate metabolism, Models, Molecular, Peptide Elongation Factor Tu chemistry, Protein Binding, Protein Biosynthesis, Protein Conformation, Protein Interaction Mapping, Protein Structure, Tertiary, RNA, Transfer chemistry, Recombinant Fusion Proteins chemistry, Schizosaccharomyces pombe Proteins, Structure-Activity Relationship, Transcription Factors genetics, Transcription Factors physiology, RNA Stability physiology, RNA, Fungal metabolism, RNA, Messenger metabolism, Schizosaccharomyces metabolism, Transcription Factors chemistry

Abstract

No-go decay (NGD) targets mRNAs with stalls in translation elongation for endonucleolytic cleavage in a process involving the Dom34 and Hbs1 proteins. The crystal structure of a Schizosaccharomyces pombe Dom34-Hbs1 complex reveals an overall shape similar to that of eRF1-eRF3-GTP and EF-Tu-tRNA-GDPNP. Similarly to eRF1 and GTP binding to eRF3, Dom34 and GTP bind to Hbs1 with strong cooperativity, and Dom34 acts as a GTP-dissociation inhibitor (GDI). A marked conformational change in Dom34 occurs upon binding to Hbs1, leading Dom34 to resemble a portion of a tRNA and to position a conserved basic region in a position expected to be near the peptidyl transferase center. These results support the idea that the Dom34-Hbs1 complex functions to terminate translation and thereby commit mRNAs to NGD. Consistent with this role, NGD at runs of arginine codons, which cause a strong block to elongation, is independent of the Dom34-Hbs1 complex.

Published

2010

28. Decapping activators in Saccharomyces cerevisiae act by multiple mechanisms.

Author

Nissan T, Rajyaguru P, She M, Song H, and Parker R

Subjects

Peptide Chain Initiation, Translational physiology, RNA, Fungal genetics, RNA, Messenger genetics, RNA-Binding Proteins genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, RNA Stability physiology, RNA, Fungal metabolism, RNA, Messenger metabolism, RNA-Binding Proteins metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Eukaryotic mRNA degradation often occurs in a process whereby translation initiation is inhibited and the mRNA is targeted for decapping. In yeast cells, Pat1, Scd6, Edc3, and Dhh1 all function to promote decapping by an unknown mechanism(s). We demonstrate that purified Scd6 and a region of Pat1 directly repress translation in vitro by limiting the formation of a stable 48S preinitiation complex. Moreover, while Pat1, Edc3, Dhh1, and Scd6 all bind the decapping enzyme, only Pat1 and Edc3 enhance its activity. We also identify numerous direct interactions between Pat1, Dcp1, Dcp2, Dhh1, Scd6, Edc3, Xrn1, and the Lsm1-7 complex. These observations identify three classes of decapping activators that function to directly repress translation initiation and/or stimulate Dcp1/2. Moreover, Pat1 is identified as critical in mRNA decay by first inhibiting translation initiation, then serving as a scaffold to recruit components of the decapping complex, and finally activating Dcp2., (Copyright © 2010 Elsevier Inc. All rights reserved.)

Published

2010

29. Dcp2 phosphorylation by Ste20 modulates stress granule assembly and mRNA decay in Saccharomyces cerevisiae.

Author

Yoon JH, Choi EJ, and Parker R

Subjects

Amino Acid Substitution, Catalytic Domain genetics, Cell Proliferation, Cytoplasm metabolism, DEAD-box RNA Helicases metabolism, Endoribonucleases genetics, Intracellular Signaling Peptides and Proteins genetics, Lipoproteins genetics, MAP Kinase Kinase Kinases, Pheromones genetics, Phosphorylation, Poly(A)-Binding Proteins genetics, Poly(A)-Binding Proteins metabolism, Protein Serine-Threonine Kinases genetics, RNA Stability, RNA, Fungal metabolism, Recombinant Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Serine metabolism, Up-Regulation physiology, Cytoplasmic Granules metabolism, Endoribonucleases metabolism, Gene Expression Regulation, Fungal physiology, Intracellular Signaling Peptides and Proteins metabolism, Protein Serine-Threonine Kinases metabolism, RNA, Messenger metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Stress, Physiological physiology

Abstract

Translation and messenger RNA (mRNA) degradation are important sites of gene regulation, particularly during stress where translation and mRNA degradation are reprogrammed to stabilize bulk mRNAs and to preferentially translate mRNAs required for the stress response. During stress, untranslating mRNAs accumulate both in processing bodies (P-bodies), which contain some translation repressors and the mRNA degradation machinery, and in stress granules, which contain mRNAs stalled in translation initiation. How signal transduction pathways impinge on proteins modulating P-body and stress granule formation and function is unknown. We show that during stress in Saccharomyces cerevisiae, Dcp2 is phosphorylated on serine 137 by the Ste20 kinase. Phosphorylation of Dcp2 affects the decay of some mRNAs and is required for Dcp2 accumulation in P-bodies and specific protein interactions of Dcp2 and for efficient formation of stress granules. These results demonstrate that Ste20 has an unexpected role in the modulation of mRNA decay and translation and that phosphorylation of Dcp2 is an important control point for mRNA decapping.

Published

2010

30. Polysomes, P bodies and stress granules: states and fates of eukaryotic mRNAs.

Author

Balagopal V and Parker R

Subjects

Humans, Protein Biosynthesis, RNA Stability, Ribonucleoproteins metabolism, Cytoplasmic Granules metabolism, Eukaryotic Cells metabolism, Polyribosomes metabolism, RNA Caps metabolism, RNA, Messenger metabolism

Abstract

The control of translation and mRNA degradation plays a key role in the regulation of eukaryotic gene expression. In the cytosol, mRNAs engaged in translation are distributed throughout the cytosol, while translationally inactive mRNAs can accumulate in P bodies, in complex with mRNA degradation and translation repression machinery, or in stress granules, which appear to be mRNAs stalled in translation initiation. Here we discuss how these different granules suggest a dynamic model for the metabolism of cytoplasmic mRNAs wherein they cycle between different mRNP states with different functional properties and subcellular locations.

Published

2009

31. Related mechanisms for mRNA and rRNA quality control.

Author

Swisher KD and Parker R

Subjects

Peptide Chain Initiation, Translational, Saccharomyces cerevisiae genetics, RNA Stability, RNA, Messenger genetics, RNA, Messenger metabolism, RNA, Ribosomal genetics, RNA, Ribosomal metabolism, Ribosomes metabolism

Abstract

In this issue of Molecular Cell, Cole et al. (2009) provide evidence that different defects in rRNA function are recognized by distinct RNA quality control systems, and suggest that a stalled ribosome can trigger either no-go decay of the mRNA or degradation of a nonfunctional 18S rRNA.

Published

2009

32. Analysis of cytoplasmic mRNA decay in Saccharomyces cerevisiae.

Author

Passos DO and Parker R

Subjects

RNA, Messenger analysis, RNA, Messenger genetics, Cytoplasm genetics, RNA Stability genetics, RNA, Messenger metabolism, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae genetics

Abstract

The yeast, Saccharomyces cerevisiae, is a model system for the study of eukaryotic mRNA degradation. In this organism, a variety of methods have been developed to measure mRNA decay rates, trap intermediates in the mRNA degradation process, and establish precursor-product relationships. In addition, the use of mutant strains lacking specific enzymes involved in mRNA destruction, or key regulatory proteins, allows one to determine the mechanisms by which individual mRNAs are degraded. In this chapter, we discuss methods for analyzing mRNA degradation in S. cerevisiae.

Published

2008

33. Analysis of P-body assembly in Saccharomyces cerevisiae.

Author

Teixeira D and Parker R

Subjects

DEAD-box RNA Helicases genetics, DEAD-box RNA Helicases metabolism, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Endoribonucleases genetics, Endoribonucleases metabolism, RNA Cap-Binding Proteins, RNA Caps metabolism, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism, Ribonucleases genetics, Ribonucleases metabolism, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Cytoplasmic Granules metabolism, Protein Biosynthesis, RNA, Messenger metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Recent experiments have defined cytoplasmic foci, referred to as processing bodies (P-bodies), that contain untranslating mRNAs in conjunction with proteins involved in translation repression and mRNA decapping and degradation. However, the order of protein assembly into P-bodies and the interactions that promote P-body assembly are unknown. To gain insight into how yeast P-bodies assemble, we examined the P-body accumulation of Dcp1p, Dcp2p, Edc3p, Dhh1p, Pat1p, Lsm1p, Xrn1p, Ccr4p, and Pop2p in deletion mutants lacking one or more P-body component. These experiments revealed that Dcp2p and Pat1p are required for recruitment of Dcp1p and of the Lsm1-7p complex to P-bodies, respectively. We also demonstrate that P-body assembly is redundant and no single known component of P-bodies is required for P-body assembly, although both Dcp2p and Pat1p contribute to P-body assembly. In addition, our results indicate that Pat1p can be a nuclear-cytoplasmic shuttling protein and acts early in P-body assembly. In contrast, the Lsm1-7p complex appears to primarily function in a rate limiting step after P-body assembly in triggering decapping. Taken together, these results provide insight both into the function of individual proteins involved in mRNA degradation and the mechanisms by which yeast P-bodies assemble.

Published

2007

34. Translation-independent inhibition of mRNA deadenylation during stress in Saccharomyces cerevisiae.

Author

Hilgers V, Teixeira D, and Parker R

Subjects

Kinetics, Lipoproteins genetics, Lipoproteins metabolism, Pheromones, Protein Biosynthesis, RNA Processing, Post-Transcriptional, RNA Stability, RNA, Fungal genetics, RNA, Messenger genetics, Ribonucleases antagonists & inhibitors, Ribonucleases metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, RNA, Fungal metabolism, RNA, Messenger metabolism, Saccharomyces cerevisiae metabolism

Abstract

Post-transcriptional control mechanisms play an important role in regulating gene expression during cellular responses to stress. For example, many stresses inhibit translation, and at least some stresses inhibit mRNA turnover in yeast and mammalian cells. We show that hyperosmolarity, heat shock, and glucose deprivation stabilize multiple mRNAs in yeast, primarily through inhibition of deadenylation. Although these stresses inhibit translation and promote the movement of mRNAs into P-bodies, we also observed inhibition of deadenylation in cycloheximide-treated cells as well as in a mutant strain where translation initiation is impaired. This argues that inhibition of poly(A)-shortening is independent of the translational state of the mRNAs and can occur when mRNAs are localized in polysomes or are not engaged in translation. Analysis of pan2Delta or ccr4Delta strains indicates that stress inhibits the function of both the Ccr4p/Pop2p/Notp and the Pan2p/Pan3p deadenylases. We suggest that under stress, simultaneous repression of translation and deadenylation allows cells to selectively translate mRNAs specific to the stress response, while retaining the majority of the cytoplasmic pool of mRNAs for later reuse and recovery from stress. Moreover, because various cellular stresses also inhibit deadenylation in mammalian cells, this mechanism is likely to be a conserved aspect of the stress response.

Published

2006

35. Targeting of aberrant mRNAs to cytoplasmic processing bodies.

Author

Sheth U and Parker R

Subjects

Adaptor Proteins, Signal Transducing, Codon, Nonsense, Models, Biological, RNA Helicases genetics, RNA Helicases metabolism, RNA Transport, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Trans-Activators genetics, Trans-Activators metabolism, Cytoplasmic Structures metabolism, RNA Stability, RNA, Fungal metabolism, RNA, Messenger metabolism, Saccharomyces cerevisiae metabolism

Abstract

In eukaryotes, a specialized pathway of mRNA degradation termed nonsense-mediated decay (NMD) functions in mRNA quality control by recognizing and degrading mRNAs with aberrant termination codons. We demonstrate that NMD in yeast targets premature termination codon (PTC)-containing mRNA to P-bodies. Upf1p is sufficient for targeting mRNAs to P-bodies, whereas Upf2p and Upf3p act, at least in part, downstream of P-body targeting to trigger decapping. The ATPase activity of Upf1p is required for NMD after the targeting of mRNAs to P-bodies. Moreover, Upf1p can target normal mRNAs to P-bodies but not promote their degradation. These observations lead us to propose a new model for NMD wherein two successive steps are used to distinguish normal and aberrant mRNAs.

Published

2006

36. Endonucleolytic cleavage of eukaryotic mRNAs with stalls in translation elongation.

Author

Doma MK and Parker R

Subjects

Cell Cycle Proteins physiology, Endoribonucleases, GTP-Binding Proteins physiology, Genes, Reporter, HSP70 Heat-Shock Proteins physiology, Peptide Elongation Factors physiology, Ribosomes metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae physiology, Saccharomyces cerevisiae Proteins physiology, Peptide Chain Elongation, Translational physiology, RNA Stability physiology, RNA, Fungal metabolism, RNA, Messenger metabolism

Abstract

A fundamental aspect of the biogenesis and function of eukaryotic messenger RNA is the quality control systems that recognize and degrade non-functional mRNAs. Eukaryotic mRNAs where translation termination occurs too soon (nonsense-mediated decay) or fails to occur (non-stop decay) are rapidly degraded. We show that yeast mRNAs with stalls in translation elongation are recognized and targeted for endonucleolytic cleavage, referred to as 'no-go decay'. The cleavage triggered by no-go decay is dependent on translation and involves Dom34p and Hbs1p. Dom34p and Hbs1p are similar to the translation termination factors eRF1 and eRF3 (refs 3, 4), indicating that these proteins might function in recognizing the stalled ribosome and triggering endonucleolytic cleavage. No-go decay provides a mechanism for clearing the cell of stalled translation elongation complexes, which could occur as a result of damaged mRNAs or ribosomes, or as a mechanism of post-transcriptional control.

Published

2006

37. Control of translation and mRNA degradation by miRNAs and siRNAs.

Author

Valencia-Sanchez MA, Liu J, Hannon GJ, and Parker R

Subjects

Animals, Eukaryotic Cells metabolism, Gene Expression, Protein Biosynthesis, RNA Processing, Post-Transcriptional, Transcription, Genetic, MicroRNAs genetics, MicroRNAs metabolism, RNA, Messenger metabolism, RNA, Small Interfering genetics, RNA, Small Interfering metabolism

Abstract

The control of translation and mRNA degradation is an important part of the regulation of gene expression. It is now clear that small RNA molecules are common and effective modulators of gene expression in many eukaryotic cells. These small RNAs that control gene expression can be either endogenous or exogenous micro RNAs (miRNAs) and short interfering RNAs (siRNAs) and can affect mRNA degradation and translation, as well as chromatin structure, thereby having impacts on transcription rates. In this review, we discuss possible mechanisms by which miRNAs control translation and mRNA degradation. An emerging theme is that miRNAs, and siRNAs to some extent, target mRNAs to the general eukaryotic machinery for mRNA degradation and translation control.

Published

2006

38. Movement of eukaryotic mRNAs between polysomes and cytoplasmic processing bodies.

Author

Brengues M, Teixeira D, and Parker R

Subjects

DEAD-box RNA Helicases, Endoribonucleases, Eukaryotic Initiation Factor-3 genetics, Eukaryotic Initiation Factor-3 metabolism, Glucose metabolism, RNA Caps metabolism, RNA Helicases metabolism, RNA-Binding Proteins metabolism, Recombinant Fusion Proteins metabolism, Resting Phase, Cell Cycle, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins biosynthesis, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Transcription, Genetic, Organelles metabolism, Polyribosomes metabolism, Protein Biosynthesis, RNA, Fungal metabolism, RNA, Messenger metabolism, Saccharomyces cerevisiae metabolism

Abstract

Eukaryotic cells contain nontranslating messenger RNA concentrated in P-bodies, which are sites where the mRNA can be decapped and degraded. We present evidence that mRNA molecules within yeast P-bodies can also return to translation. First, inhibiting delivery of new mRNAs to P-bodies leads to their disassembly independent of mRNA decay. Second, P-bodies decline in a translation initiation-dependent manner during stress recovery. Third, reporter mRNAs concentrate in P-bodies when translation initiation is blocked and resume translation and exit P-bodies when translation is restored. Fourth, stationary phase yeast have large P-bodies containing mRNAs that reenter translation when growth resumes. The reciprocal movement of mRNAs between polysomes and P-bodies is likely to be important in the control of mRNA translation and degradation. Moreover, the presence of related proteins in P-bodies and maternal mRNA storage granules suggests this mechanism is widely adapted for mRNA storage.

Published

2005

39. General translational repression by activators of mRNA decapping.

Author

Coller J and Parker R

Subjects

DEAD-box RNA Helicases, DNA-Binding Proteins genetics, DNA-Binding Proteins pharmacology, Humans, Proto-Oncogene Proteins genetics, Proto-Oncogene Proteins physiology, RNA Helicases genetics, RNA Helicases pharmacology, RNA Nucleotidyltransferases genetics, RNA Nucleotidyltransferases physiology, RNA, Messenger drug effects, RNA-Binding Proteins genetics, RNA-Binding Proteins pharmacology, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins pharmacology, Time Factors, Cytoplasmic Granules metabolism, DNA-Binding Proteins physiology, Gene Silencing physiology, RNA Helicases physiology, RNA Stability physiology, RNA, Messenger metabolism, RNA-Binding Proteins physiology, Saccharomyces cerevisiae Proteins physiology

Abstract

Translation and mRNA degradation are affected by a key transition where eukaryotic mRNAs exit translation and assemble an mRNP state that accumulates into processing bodies (P bodies), cytoplasmic sites of mRNA degradation containing non-translating mRNAs, and mRNA degradation machinery. We identify the decapping activators Dhh1p and Pat1p as functioning as translational repressors and facilitators of P body formation. Strains lacking both Dhh1p and Pat1p show strong defects in mRNA decapping and P body formation and are blocked in translational repression. Contrastingly, overexpression of Dhh1p or Pat1p causes translational repression, P body formation, and arrests cell growth. Dhh1p, and its human homolog, RCK/p54, repress translation in vitro, and Dhh1p function is bypassed in vivo by inhibition of translational initiation. These results identify a broadly acting mechanism of translational repression that targets mRNAs for decapping and functions in translational control. We propose this mechanism is competitively balanced with translation, and shifting this balance is an important basis of translational control.

Published

2005

40. MicroRNA-dependent localization of targeted mRNAs to mammalian P-bodies.

Author

Liu J, Valencia-Sanchez MA, Hannon GJ, and Parker R

Subjects

3' Untranslated Regions genetics, 3' Untranslated Regions metabolism, Argonaute Proteins, Caenorhabditis elegans Proteins genetics, Cell Line, Cell Line, Tumor, Endoribonucleases metabolism, Eukaryotic Initiation Factor-2, Gene Expression Regulation, HeLa Cells, Humans, Immunoprecipitation, MicroRNAs genetics, Microscopy, Fluorescence, Mutation physiology, Peptide Initiation Factors genetics, Peptide Initiation Factors metabolism, Protein Binding, RNA Transport, RNA, Messenger genetics, RNA, Small Interfering genetics, RNA, Small Interfering metabolism, RNA-Induced Silencing Complex metabolism, Receptors, CXCR4 genetics, Trans-Activators metabolism, Transfection, Cytoplasmic Structures metabolism, MicroRNAs metabolism, RNA, Messenger metabolism

Abstract

Small RNAs, including small interfering RNAs (siRNAs) and microRNAs (miRNAs) can silence target genes through several different effector mechanisms. Whereas siRNA-directed mRNA cleavage is increasingly understood, the mechanisms by which miRNAs repress protein synthesis are obscure. Recent studies have revealed the existence of specific cytoplasmic foci, referred to herein as processing bodies (P-bodies), which contain untranslated mRNAs and can serve as sites of mRNA degradation. Here we demonstrate that Argonaute proteins--the signature components of the RNA interference (RNAi) effector complex, RISC--localize to mammalian P-bodies. Moreover, reporter mRNAs that are targeted for translational repression by endogenous or exogenous miRNAs become concentrated in P-bodies in a miRNA-dependent manner. These results provide a link between miRNA function and mammalian P-bodies and suggest that translation repression by RISC delivers mRNAs to P-bodies, either as a cause or as a consequence of inhibiting protein synthesis.

Published

2005

41. Mutations in the Saccharomyces cerevisiae LSM1 gene that affect mRNA decapping and 3' end protection.

Author

Tharun S, Muhlrad D, Chowdhury A, and Parker R

Subjects

Base Sequence, Humans, Microscopy, Confocal, Molecular Sequence Data, Mutation, Protein Structure, Tertiary, RNA Cap-Binding Proteins, RNA-Binding Proteins physiology, Saccharomyces cerevisiae physiology, Saccharomyces cerevisiae Proteins physiology, Temperature, RNA Caps metabolism, RNA, Messenger metabolism, RNA-Binding Proteins genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics

Abstract

The decapping of eukaryotic mRNAs is a key step in their degradation. The heteroheptameric Lsm1p-7p complex is a general activator of decapping and also functions in protecting the 3' ends of deadenylated mRNAs from a 3'-trimming reaction. Lsm1p is the unique member of the Lsm1p-7p complex, distinguishing that complex from the functionally different Lsm2p-8p complex. To understand the function of Lsm1p, we constructed a series of deletion and point mutations of the LSM1 gene and examined their effects on phenotype. These studies revealed the following: (i) Mutations affecting the predicted RNA-binding and inter-subunit interaction residues of Lsm1p led to impairment of mRNA decay, suggesting that the integrity of the Lsm1p-7p complex and the ability of the Lsm1p-7p complex to interact with mRNA are important for mRNA decay function; (ii) mutations affecting the predicted RNA contact residues did not affect the localization of the Lsm1p-7p complex to the P-bodies; (iii) mRNA 3'-end protection could be indicative of the binding of the Lsm1p-7p complex to the mRNA prior to activation of decapping, since all the mutants defective in mRNA 3' end protection were also blocked in mRNA decay; and (iv) in addition to the Sm domain, the C-terminal domain of Lsm1p is also important for mRNA decay function.

Published

2005

42. Crystal structures of human DcpS in ligand-free and m7GDP-bound forms suggest a dynamic mechanism for scavenger mRNA decapping.

Author

Chen N, Walsh MA, Liu Y, Parker R, and Song H

Subjects

Apoproteins chemistry, Apoproteins metabolism, Crystallography, X-Ray, Dimerization, Endoribonucleases genetics, Humans, Ligands, Models, Molecular, Mutation genetics, Pliability, Protein Structure, Tertiary, RNA Cap Analogs metabolism, Solvents, Static Electricity, Structure-Activity Relationship, Substrate Specificity, Tyrosine genetics, Tyrosine metabolism, Endoribonucleases chemistry, Endoribonucleases metabolism, Guanosine Diphosphate analogs & derivatives, Guanosine Diphosphate metabolism, RNA Caps metabolism, RNA, Messenger metabolism

Abstract

Eukaryotic cells utilize DcpS, a scavenger decapping enzyme, to degrade the residual cap structure following 3'-5' mRNA decay, thereby preventing the premature decapping of the capped long mRNA and misincorporation of methylated nucleotides in nucleic acids. We report the structures of DcpS in ligand-free form and in a complex with m7GDP. apo-DcpS is a symmetric dimer, strikingly different from the asymmetric dimer observed in the structures of DcpS with bound cap analogues. In contrast, and similar to the m7GpppG-DcpS complex, DcpS with bound m7GDP is an asymmetric dimer in which the closed state appears to be the substrate-bound complex, whereas the open state mimics the product-bound complex. Comparisons of these structures revealed conformational changes of both the N-terminal swapped-dimeric domain and the cap-binding pocket upon cap binding. Moreover, Tyr273 in the cap-binding pocket displays remarkable conformational changes upon cap binding. Mutagenesis and biochemical analysis suggest that Tyr273 seems to play an important role in cap binding and product release. Examination of the crystallographic B-factors indicates that the N-terminal domain in apo-DcpS is inherently flexible, and in a dynamic state ready for substrate binding and product release.

Published

2005

43. Processing bodies require RNA for assembly and contain nontranslating mRNAs.

Author

Teixeira D, Sheth U, Valencia-Sanchez MA, Brengues M, and Parker R

Subjects

Cytoplasmic Granules genetics, DEAD-box RNA Helicases, Endoribonucleases, Genotype, Glucose deficiency, Green Fluorescent Proteins, Microscopy, Confocal, Osmotic Pressure, Protein Biosynthesis, RNA Helicases metabolism, RNA, Messenger genetics, RNA-Binding Proteins metabolism, Saccharomyces cerevisiae Proteins metabolism, Yeasts genetics, Yeasts growth & development, Cytoplasmic Granules metabolism, RNA Stability, RNA, Messenger metabolism, Yeasts metabolism

Abstract

Recent experiments have defined cytoplasmic foci, referred to as processing bodies (P-bodies), wherein mRNA decay factors are concentrated and where mRNA decay can occur. However, the physical nature of P-bodies, their relationship to translation, and possible roles of P-bodies in cellular responses remain unclear. We describe four properties of yeast P-bodies that indicate that P-bodies are dynamic structures that contain nontranslating mRNAs and function during cellular responses to stress. First, in vivo and in vitro analysis indicates that P-bodies are dependent on RNA for their formation. Second, the number and size of P-bodies vary in response to glucose deprivation, osmotic stress, exposure to ultraviolet light, and the stage of cell growth. Third, P-bodies vary with the status of the cellular translation machinery. Inhibition of translation initiation by mutations, or cellular stress, results in increased P-bodies. In contrast, inhibition of translation elongation, thereby trapping the mRNA in polysomes, leads to dissociation of P-bodies. Fourth, multiple translation factors and ribosomal proteins are lacking from P-bodies. These results suggest additional biological roles of P-bodies in addition to being sites of mRNA degradation.

Published

2005

44. The yeast EDC1 mRNA undergoes deadenylation-independent decapping stimulated by Not2p, Not4p, and Not5p.

Author

Muhlrad D and Parker R

Subjects

3' Untranslated Regions, Base Sequence, Cell Cycle Proteins metabolism, DNA, Fungal genetics, Molecular Sequence Data, RNA Caps chemistry, RNA, Fungal chemistry, RNA, Messenger chemistry, RNA-Binding Proteins, Repressor Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Transcription Factors metabolism, RNA Caps genetics, RNA Caps metabolism, RNA, Fungal genetics, RNA, Fungal metabolism, RNA, Messenger genetics, RNA, Messenger metabolism, Saccharomyces cerevisiae Proteins genetics

Abstract

A major mechanism of eukaryotic mRNA degradation initiates with deadenylation followed by decapping and 5' to 3' degradation. We demonstrate that the yeast EDC1 mRNA, which encodes a protein that enhances decapping, has unique properties and is both protected from deadenylation and undergoes deadenylation-independent decapping. The 3' UTR of the EDC1 mRNA is sufficient for both protection from deadenylation and deadenylation-independent decapping and an extended poly(U) tract within the 3' UTR is required. These observations highlight the diverse forms of decapping regulation and identify a feedback loop that can compensate for decreases in activity of the decapping enzyme. Surprisingly, the decapping of the EDC1 mRNA is slowed by the loss of Not2p, Not4p, and Not5p, which interact with the Ccr4p/Pop2p deadenylase complex. This indicates that the Not proteins can affect decapping, which suggests a possible link between the mRNA deadenylation and decapping machinery.

Published

2005

45. The yeast Apq12 protein affects nucleocytoplasmic mRNA transport.

Author

Baker KE, Coller J, and Parker R

Subjects

Cytoplasm genetics, Cytoplasm metabolism, Green Fluorescent Proteins, Luminescent Proteins genetics, Luminescent Proteins metabolism, Mutation, Poly A metabolism, RNA, Messenger genetics, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Sequence Deletion, Active Transport, Cell Nucleus, Cell Nucleus metabolism, Membrane Proteins metabolism, RNA, Fungal physiology, RNA, Messenger metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

An important step in mRNA biogenesis is the export of mRNA from the nucleus to the cytoplasm. In this work, we provide evidence that the previously uncharacterized gene APQ12 functions in nucleocytoplasmic mRNA transport in Saccharomyces cerevisiae. First, apq12delta strains manifest 3' hyperadenylated mRNA similar to other previously characterized RNA export mutants. Second, bulk poly(A)+ RNA is retained in the nucleus in apq12delta cells. Third, an Apq12p-GFP chimeric protein is localized to the nuclear periphery. Fourth, mRNA in apq12delta cells is stabilized, consistent with a defect in the rate of nuclear export. Interestingly, apq12delta mutants are severely compromised for growth and display atypical cell morphology. Because this aberrant cell morphology is not seen with other viable export mutants, Apq12p must have either an additional cellular function, or preferentially impinge on the export of mRNAs regulating cell growth. Together, these findings support a role for APQ12 in nucleocytoplasmic transport of mRNA.

Published

2004

46. Nonsense-mediated mRNA decay: terminating erroneous gene expression.

Author

Baker KE and Parker R

Subjects

3' Untranslated Regions, Animals, Codon, Nonsense, Codon, Terminator, Humans, Protein Biosynthesis genetics, RNA-Binding Proteins genetics, Gene Expression, RNA Stability, RNA, Messenger genetics, Transcription, Genetic

Abstract

Nonsense-mediated mRNA decay is a surveillance pathway that reduces errors in gene expression by eliminating aberrant mRNAs that encode incomplete polypeptides. Recent experiments suggest a working model whereby premature and normal translation termination events are distinct as a consequence of the spatial relationship between the termination codon and mRNA binding proteins, a relationship partially established by nuclear pre-mRNA processing. Aberrant termination then leads to both translational repression and an increased susceptibility of the mRNA to multiple ribonucleases.

Published

2004

47. Identification of Edc3p as an enhancer of mRNA decapping in Saccharomyces cerevisiae.

Author

Kshirsagar M and Parker R

Subjects

Amino Acid Sequence, Animals, Cytoplasm metabolism, Humans, Mice, Molecular Sequence Data, Protein Structure, Tertiary, RNA Stability genetics, RNA Stability physiology, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Sequence Analysis, Protein, RNA, Messenger metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics

Abstract

The major pathway of mRNA decay in yeast initiates with deadenylation, followed by mRNA decapping and 5'-3' exonuclease digestion. An in silico approach was used to identify new proteins involved in the mRNA decay pathway. One such protein, Edc3p, was identified as a conserved protein of unknown function having extensive two-hybrid interactions with several proteins involved in mRNA decapping and 5'-3' degradation including Dcp1p, Dcp2p, Dhh1p, Lsm1p, and the 5'-3' exonuclease, Xrn1p. We show that Edc3p can stimulate mRNA decapping of both unstable and stable mRNAs in yeast when the decapping enzyme is compromised by temperature-sensitive alleles of either the DCP1 or the DCP2 genes. In these cases, deletion of EDC3 caused a synergistic mRNA-decapping defect at the permissive temperatures. The edc3Delta had no effect when combined with the lsm1Delta, dhh1Delta, or pat1Delta mutations, which appear to affect an early step in the decapping pathway. This suggests that Edc3p specifically affects the function of the decapping enzyme per se. Consistent with a functional role in decapping, GFP-tagged Edc3p localizes to cytoplasmic foci involved in mRNA decapping referred to as P-bodies. These results identify Edc3p as a new protein involved in the decapping reaction.

Published

2004

48. The enzymes and control of eukaryotic mRNA turnover.

Author

Parker R and Song H

Subjects

Adenosine Monophosphate metabolism, Exonucleases metabolism, Polyribonucleotide Nucleotidyltransferase metabolism, RNA, Messenger metabolism

Abstract

The degradation of eukaryotic mRNAs plays important roles in the modulation of gene expression, quality control of mRNA biogenesis and antiviral defenses. In the past five years, many of the enzymes involved in this process have been identified and mechanisms that modulate their activities have begun to be identified. In this review, we describe the enzymes of mRNA degradation and their properties. We highlight that there are a variety of enzymes with different specificities, suggesting that individual nucleases act on distinct subpopulations of transcripts within the cell. In several cases, translation factors that bind mRNA inhibit these nucleases. In addition, recent work has begun to identify distinct mRNP complexes that recruit the nucleases to transcripts through different mRNA-interacting proteins. These properties and complexes suggest multiple mechanisms by which mRNA degradation could be regulated.

Published

2004

49. Cytoplasmic degradation of splice-defective pre-mRNAs and intermediates.

Author

Hilleren PJ and Parker R

Subjects

Endonucleases metabolism, Exons, Fungal Proteins genetics, Genes, Reporter, Introns, Models, Biological, Nucleic Acid Conformation, Spliceosomes metabolism, Cytoplasm metabolism, Fungal Proteins metabolism, RNA Splicing, RNA, Messenger metabolism

Abstract

Specific systems of nuclear RNA degradation appear to target and degrade aberrant pre-mRNA molecules. In this work we report on a Dbr1p-dependent RNA decay pathway that limits the accumulation of splice-defective lariat intermediates stalled at the second step of splicing. In this pathway, splice-defective lariat intermediates are debranched by Dbr1p and subsequently degraded 5' to 3' primarily by the cytoplasmic exonuclease, Xrn1p. When debranching is blocked, these splicing intermediates can be degraded in a 3' to 5' direction in a manner dependent on Ski2p, a cofactor for the cytoplasmic exosome. In that Xrn1p and Ski2p are cytoplasmic and Dbr1p localizes to both the nucleus and the cytoplasm, these data suggest that this decay pathway occurs within the cytoplasm. Furthermore, the finding that lariat intermediates accumulate in the dbr1Delta strain suggests that this pathway also functions as an inherent quality control mechanism for the process of pre-mRNA splicing.

Published

2003

50. Computational modeling and experimental analysis of nonsense-mediated decay in yeast.

Author

Cao D and Parker R

Subjects

Adenine metabolism, Base Sequence genetics, Codon, Nonsense metabolism, Models, Biological, Codon, Nonsense genetics, Eukaryotic Cells metabolism, Gene Expression Regulation, Fungal genetics, Genes, Regulator genetics, RNA, Messenger genetics, RNA, Messenger metabolism, Yeasts genetics, Yeasts metabolism

Abstract

A conserved mRNA surveillance system, referred to as nonsense-mediated decay (NMD), exists in eukaryotic cells to degrade mRNAs containing nonsense codons. This process is important in checking that mRNAs have been properly synthesized and functions, at least in part, to increase the fidelity of gene expression by degrading aberrant mRNAs that, if translated, would produce truncated proteins. Using computational modeling and experimental analysis, we define the alterations in mRNA turnover triggered by NMD in yeast. We demonstrate that the nonsense-containing transcripts are efficiently recognized, targeted for deadenylation-independent decapping, and show NMD triggered accelerated deadenylation regardless of the position of the nonsense codon. We also show that 5' nonsense codons trigger faster rates of decapping than 3' nonsense codons, thereby providing a mechanistic basis for the polar effect of NMD. Finally, we construct a computational model that accurately describes the process of NMD and serves as an explanatory and predictive tool.

Published

2003