The Control of Gene Expression by Nuclear RNA Degradation in Saccharomyces Cerevisiae PDF Download
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Author: Kevin Richard Jones Roy
Publisher:
ISBN:
Category :
Languages : en
Pages : 164
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Book Description
Ribonucleases play critical roles in controlling the quantity and quality of gene expression through processing and degrading RNA. An important class of evolutionarily conserved ribonucleases is the RNase III family of enzymes, which are distinguished by their specificity for cleaving double-stranded RNA (dsRNA). RNase III enzymes perform diverse functions in RNA metabolism in all eukaryotes studied, yet numerous questions remain regarding their range of natural targets in vivo, how they achieve substrate specificity, and how their cleavage activity is regulated. The model eukaryote Saccharomyces cerevisiae harbors one RNase III homolog, Rnt1p, which is responsible for all known dsRNA cleavage activity in this organism. To better understand the substrate selectivity of Rnt1p, we examined how its double-stranded RNA binding domain (dsRBD) recognizes a non-canonical substrate containing an AAGU tetraloop sequence differing from the NGNN consensus sequence. Surprisingly, we found that upon engaging the RNA, the dsRBD induces a structural change in the AAGU loop so that it closely adopts the structure of the NGNN loop. This suggested that the structures of isolated RNAs in solution are not necessarily predictive of substrate specificity. We next characterized how structural dynamics in the dsRBD mediate specific binding. We found that in order to bind substrate dsRNA with high affinity, the dsRBD must undergo a significant conformational change involving the first alpha helix and beta strand of the dsRBD. Next we implemented computational RNA secondary structure screens to scan the genome for potential Rnt1p targets. We identified a characteristic Rnt1p stem-loop in the BDF2 mRNA, which is also subject to nuclear decay by the spliceosome through a first step splicing discard pathway. Cis acting mutations in BDF2 blocking Rnt1p or spliceosome-mediated decay (SMD) conferred distinct phenotypes for each pathway, revealing that salt stress hyper-activates Rnt1p cleavage while spliceosome-mediated decay controls BDF2 expression during DNA replication stress. To globally identify RNA targets of Rnt1p cleavage, we leveraged the fact that the 5 product of Rnt1p cleavage is oligo-adenylated by Trf4/5-Air2/1-Mtr4 polyadenylation (TRAMP) complex prior to degradation by the nuclear exosome, a 3 -to-5 exonuclease complex. We mapped TRAMP poly(A) tails genome-wide by high-throughput sequencing of 3 ends of polyadenylated RNA in yeast cells lacking a nuclear exosome component. This revealed a global profile of destabilized 3 ends arising from various nuclear RNA degradation mechanisms, including Rnt1p cleavage, transcription termination by the Nrd1p-Nab3p-Sen1p (NNS) pathway and roadblock transcription termination by Reb1p and TFIIIB DNA binding factors. While the NNS pathway was known to play a prominent role in limiting pervasive RNA polymerase II, we uncovered previously unappreciated roles for roadblocks and Rnt1p in controlling Pol II transcriptional output throughout the genome, revealing how cells use a multitude of nuclear mechanisms to regulate the levels of coding and cryptic transcripts.
Author: Kevin Richard Jones Roy
Publisher:
ISBN:
Category :
Languages : en
Pages : 164
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Book Description
Ribonucleases play critical roles in controlling the quantity and quality of gene expression through processing and degrading RNA. An important class of evolutionarily conserved ribonucleases is the RNase III family of enzymes, which are distinguished by their specificity for cleaving double-stranded RNA (dsRNA). RNase III enzymes perform diverse functions in RNA metabolism in all eukaryotes studied, yet numerous questions remain regarding their range of natural targets in vivo, how they achieve substrate specificity, and how their cleavage activity is regulated. The model eukaryote Saccharomyces cerevisiae harbors one RNase III homolog, Rnt1p, which is responsible for all known dsRNA cleavage activity in this organism. To better understand the substrate selectivity of Rnt1p, we examined how its double-stranded RNA binding domain (dsRBD) recognizes a non-canonical substrate containing an AAGU tetraloop sequence differing from the NGNN consensus sequence. Surprisingly, we found that upon engaging the RNA, the dsRBD induces a structural change in the AAGU loop so that it closely adopts the structure of the NGNN loop. This suggested that the structures of isolated RNAs in solution are not necessarily predictive of substrate specificity. We next characterized how structural dynamics in the dsRBD mediate specific binding. We found that in order to bind substrate dsRNA with high affinity, the dsRBD must undergo a significant conformational change involving the first alpha helix and beta strand of the dsRBD. Next we implemented computational RNA secondary structure screens to scan the genome for potential Rnt1p targets. We identified a characteristic Rnt1p stem-loop in the BDF2 mRNA, which is also subject to nuclear decay by the spliceosome through a first step splicing discard pathway. Cis acting mutations in BDF2 blocking Rnt1p or spliceosome-mediated decay (SMD) conferred distinct phenotypes for each pathway, revealing that salt stress hyper-activates Rnt1p cleavage while spliceosome-mediated decay controls BDF2 expression during DNA replication stress. To globally identify RNA targets of Rnt1p cleavage, we leveraged the fact that the 5 product of Rnt1p cleavage is oligo-adenylated by Trf4/5-Air2/1-Mtr4 polyadenylation (TRAMP) complex prior to degradation by the nuclear exosome, a 3 -to-5 exonuclease complex. We mapped TRAMP poly(A) tails genome-wide by high-throughput sequencing of 3 ends of polyadenylated RNA in yeast cells lacking a nuclear exosome component. This revealed a global profile of destabilized 3 ends arising from various nuclear RNA degradation mechanisms, including Rnt1p cleavage, transcription termination by the Nrd1p-Nab3p-Sen1p (NNS) pathway and roadblock transcription termination by Reb1p and TFIIIB DNA binding factors. While the NNS pathway was known to play a prominent role in limiting pervasive RNA polymerase II, we uncovered previously unappreciated roles for roadblocks and Rnt1p in controlling Pol II transcriptional output throughout the genome, revealing how cells use a multitude of nuclear mechanisms to regulate the levels of coding and cryptic transcripts.
Author: Lynne E. Maquat
Publisher: Academic Press
ISBN: 0080923321
Category : Science
Languages : en
Pages : 463
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Book Description
Specific complexes of protein and RNA carry out many essential biological functions, including RNA processing, RNA turnover, and RNA folding, as well as the translation of genetic information from mRNA into protein sequences. Messenger RNA (mRNA) decay is now emerging as an important control point and a major contributor to gene expression. Continuing identification of the protein factors and cofactors and mRNA instability elements responsible for mRNA decay allow researchers to build a comprehensive picture of the highly orchestrated processes involved in mRNA decay and its regulation. - Covers the nonsense-mediated mRNA decay (NMD) or mRNA surveillance pathway - Expert researchers introduce the most advanced technologies and techniques - Offers step-by-step lab instructions, including necessary equipment and reagents
Author: Torben Heick Jensen
Publisher: Springer Science & Business Media
ISBN: 1441978410
Category : Medical
Languages : en
Pages : 161
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Book Description
The diversity of RNAs inside living cells is amazing. We have known of the more “classic” RNA species: mRNA, tRNA, rRNA, snRNA and snoRNA for some time now, but in a steady stream new types of molecules are being described as it is becoming clear that most of the genomic information of cells ends up in RNA. To deal with the enormous load of resulting RNA processing and degradation reactions, cells need adequate and efficient molecular machines. The RNA exosome is arising as a major facilitator to this effect. Structural and functional data gathered over the last decade have illustrated the biochemical importance of this multimeric complex and its many co-factors, revealing its enormous regulatory power. By gathering some of the most prominent researchers in the exosome field, it is the aim of this volume to introduce this fascinating protein complex as well as to give a timely and rich account of its many functions. The exosome was discovered more than a decade ago by Phil Mitchell and David Tollervey by its ability to trim the 3’end of yeast, S. cerevisiae, 5. 8S rRNA. In a historic account they laid out the events surrounding this identification and the subsequent birth of the research field. In the chapter by Kurt Januszyk and Christopher Lima the structural organization of eukaryotic exosomes and their evolutionary counterparts in bacteria and archaea are discussed in large part through presentation of structures.
Author: Lynne E. Maquat
Publisher: Academic Press
ISBN: 0080922074
Category : Science
Languages : en
Pages : 661
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Book Description
Specific complexes of protein and RNA carry out many essential biological functions, including RNA processing, RNA turnover, RNA folding, as well as the translation of genetic information from mRNA into protein sequences. Messenger RNA (mRNA) decay is now emerging as an important control point and a major contributor to gene expression. Continuing identification of the protein factors and cofactors, and mRNA instability elements responsible for mRNA decay allow researchers to build a comprehensive picture of the highly orchestrated processes involved in mRNA decay and its regulation. - Covers the nonsense-mediated mRNA decay (NMD) or mRNA surveillance pathway - Expert researchers introduce the most advanced technologies and techniques to identify mRNA processing, transport, localization and turnover, which are central to the process of gene expression - Offers step-by-step lab instructions, including necessary equipment and reagents
Author: Defne Emel Egecioglu
Publisher:
ISBN:
Category :
Languages : en
Pages : 404
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Book Description
Author: Agnieszka Tudek
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
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Book Description
The RNA polymerase II (RNAPII) synthesizes protein-coding RNAs and many non-coding RNAs (ncRNAs) such as small nuclear/nucleolar (sn-/snoRNAs) and Cryptic Unstable Transcripts (CUTs). CUTs are ubiquitously transcribed including overlapping and antisense to genes, which can interfere with gene expression. Control of ncRNA expression is vital and also operates at the level of transcription termination and RNA degradation.In yeast Saccharomyces cerevisiae transcription of protein-coding genes is terminated by the Cleavage and Polyadenylation Factor (CPF), while short ncRNAs are generated by transcription termination dependent from the Nrd1p-Nab3p-Sen1p (NNS) complex. Transcription termination is regulated by phosphorylation of the carboxy-terminal domain (CTD) of the Rpb1p subunit of RNAPII, composed of repeats of the Y1S2P3T4S5P6S7 motif. Promoter-proximal high levels of serine 5 phosphorylated (Ser5P) CTD favors the function of the NNS pathway while the Ser2 phosphorylated mark (Ser2P), which is gradually introduced during transcription by Ctk1p, is recognized by components of the CPF pathway. The study of the mechanism of action of the NNS complex was the subject of my PhD work.NNS-dependent transcription termination is driven by the recognition of four nucleotide motifs in the nascent RNA by Nrd1p and Nab3p and the release of the RNAPII by the Sen1p helicase. Nrd1p interacts with the CTD-Ser5P via its CTD-interaction domain (CID). Thus a role of the CID in termination was anticipated but not demonstrated. In collaboration with the group of P. Cramer (Ludwig Maximilian University of Munich, Germany), we have shown that the Nrd1p CID domain is required for efficient transcription termination at most NNS-target genes and that it is important for the recruitment of Nrd1p to the RNAPII. This domain is also involved, directly or indirectly, in the interaction of the Sen1p helicase with Nrd1p and Nab3p. In the second project, in collaboration with F. Holstege group (University Medical Center Utrecht, Netherlands), we have shown that the CTD-Ser2P mark is important for efficient transcription termination by the NNS pathway but, surprisingly, it appears to play a minor role in termination of mRNA-coding genes by the CPF-complex.Shortly after NNS-dependent termination, the released ncRNAs are targeted by the nuclear exosome/Rrp6p nuclease complex and its cofactor the TRAMP which results in trimming of sn-/snoRNAs to a mature form and complete degradation of CUTs. The NNS complex co-purifies in vivo with the TRAMP/exosome, which is believed to facilitate subsequent degradation and processing. However, the molecular details of this interaction are unknown. We show that the CID is required and sufficient in vivo and in vitro for the interaction of Nrd1p with a motif present in the C-terminal region of Trf4p, which we called NIM (for Nrd1p-Interaction Motif). In collaboration with the group of R. Stefl (Masaryk University, Czech Republic), we obtained the NMR structure of the CID bound to the NIM and demonstrated that the CID binds in a similar manner to the CTD and the NIM. The CID interacts with the CTD and the NIM in a mutually exclusive manner and the former interaction is roughly 100 times stronger than the first. We propose that these alternative interactions represent two forms of the NNS complex, one functioning in termination and the other in degradation. Importantly, the NIM-CID interaction is likely to be functionally relevant since in vitro it results in the stimulation of the polyA polymerase activity of the Trf4p. We further show that Trf4p interacts directly with Rrp6p, which in vivo serves to recruit the TRAMP to the core exosome complex. This tight interplay between the NNS, TRAMP and exosome/Rrp6p complexes most likely accounts for the efficiency of RNA degradation in vivo.
Author: Joe B. Harford
Publisher: John Wiley & Sons
ISBN: 9780471142065
Category : Science
Languages : en
Pages : 372
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Book Description
mRNA METABOLISM & POST-TRANSCRIPTIONAL GENE REGULATION Edited by Joe B. Harford and David R. Morris Gene expression is a process that begins with the transcription ofDNA to an RNA messenger (mRNA), which is then translated into aprotein. Historically, attention has been focused on the regulationof RNA synthesis (transcription); however, there is a growingrecognition of and appreciation for the importance of the manyregulatory mechanisms that take place after RNA synthesis has beencompleted. mRNA Metabolism and Post-Transcriptional Gene Regulation is thefirst comprehensive overview of the various modes of generegulation that exist post-transcriptionally. Collecting studies bysome of the top researchers in the field, this volume provides bothan up-to-date review of the complex "life" of an mRNA molecule andan introduction to current work on the diversity of mechanisms ofpost-transcriptional reactions. Topics covered include: * RNA structure * Mammalian RNA editing * RNA export from the nucleus * The fundamentals of translation initiation * Control of mRNA decay in plants * mRNA metabolism and cancer * Control of mRNA stability during herpes simplex virus infection * Regulation of mRNA expression in HIV-1 and other complexretroviruses * Nucleases * RNA localization A timely contribution to the understanding of genetic regulatorymechanisms, mRNA Metabolism and Post-Transcriptional GeneRegulation provides a basis from which potential therapeuticstrategies may be developed. This book will be of vital interest tocell and molecular biologists at all levels, from graduate studentsto senior investigators, clinical researchers, and professionals inthe pharmaceutical and biotechnology industries.
Author: John LaCava
Publisher: Springer Nature
ISBN: 1493998226
Category : Medical
Languages : en
Pages : 514
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Book Description
This volume provides a cross-section of RNA exosome research protocols, applied to a diversity of model organisms. Chapters guide readers through methods that e.g. delineate eukaryotic exosomes’ origins in prokaryotes, probe its RNA substrates, adapter complexes and macromolecular interaction of networks, and establish critical structural-function relationships. Written in the highly successful Methods in Molecular Biology series format, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Authoritative and cutting-edge, The Eukaryotic RNA Exosome: Methods and Protocols aims to ensure successful results in the further study of this vital field.
Author: Ron Milo
Publisher: Garland Science
ISBN: 1317230698
Category : Science
Languages : en
Pages : 400
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Book Description
A Top 25 CHOICE 2016 Title, and recipient of the CHOICE Outstanding Academic Title (OAT) Award. How much energy is released in ATP hydrolysis? How many mRNAs are in a cell? How genetically similar are two random people? What is faster, transcription or translation?Cell Biology by the Numbers explores these questions and dozens of others provid
Author: Witold Filipowicz
Publisher: Springer Science & Business Media
ISBN: 9400903537
Category : Science
Languages : en
Pages : 419
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Book Description
A recent volume of this series (Signals and Signal Transduction Pathways in Plants (K. Palme, ed.) Plant Molecular Biology 26, 1237-1679) described the relay races by which signals are transported in plants from the sites of stimuli to the gene expression machinery of the cell. Part of this machinery, the transcription apparatus, has been well studied in the last two decades, and many important mechanisms controlling gene expression at the transcriptional level have been elucidated. However, control of gene expression is by no means complete once the RNA has been produced. Important regulatory devices determine the maturation and usage of mRNA and the fate of its translation product. Post-transcriptional regulation is especially important for generating a fast response to environmental and intracellular signals. This book summarizes recent progress in the area of post-transcriptional regulation of gene expression in plants. 18 chapters of the book address problems of RNA processing and stability, regulation of translation, protein folding and degradation, as well as intracellular and cell-to-cell transport of proteins and nucleic acids. Several chapters are devoted to the processes taking place in plant organelles.
