Regulation of RNA Synthesis and Decay Via the C-terminal Domain of Pol II PDF Download
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Author: Sandra Chang Tseng
Publisher:
ISBN:
Category :
Languages : en
Pages : 213
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Book Description
RNA expression can be thought of as a sum of the products of RNA synthesis and decay: on the one hand, cells are transcribing the genes required for a given situation, while on the other, RNA degradation machinery is constantly acting on normal as well as aberrantly synthesized RNA. The kinases which phosphorylate the C-terminal domain (CTD) of RNA Polymerase II (Pol II) are canonically associated with being on the additive scale of the balancing act between RNA synthesis and decay. One such kinase, and the focus of my thesis, Kin28/CDK7 activates and promotes transcription by phosphorylating serine residues on the CTD. I begin my thesis with an introduction into our current understanding of how transcription is regulated via post-translational modification of the CTD, and also present the open questions, which this thesis seeks to address, on the role of Kin28/CDK7 in mediating gene expression (Chapter 1). In Chapter 2, I describe the development of a chemical genetic approach to covalently inhibit Kin28 in budding yeast. The strategy and lessons learned therein can be generally applied to covalently inhibit kinases in other model organisms. Combined with transcriptomic sequencing, I show that Kin28 is required for synthesis of nearly all annotated yeast mRNAs, and demonstrate that previously conflicting views on the matter can be explained by the phenomenon known as "RNA buffering," which is the stabilization of the steady-state level of RNAs during insults to transcription or decay. Also discussed in this chapter is our novel discovery that Kin28 plays a role in advancing Pol II from the initiation into the elongation phase of transcription. In Chapter 3, I investigate determinants of RNA buffering in a Kin28-inhibited regime, and reveal that the relative binding of the RNA binding proteins Nab2 and Ski2 can predict mRNA stability. Furthermore, I show inhibition of Kin28 rapidly induces the formation P bodies and perturbs translation. From my analyses, I present a compendium of the mRNAs that are unstable, buffered, translated, and or poorly translated in situations of transcriptional crisis, a state I show is distinct from that of the canonical stress response. In Chapter 4, I study RNA buffering from the "other side" of the gene expression equation by exploring the combined effect of deleting a component of the RNA decay machinery (rai1::URA3) and inhibition of Kin28. Despite being on opposite sides of the scale of gene expression, both defects in decay (rai1::URA3) and synthesis (inhibition of Kin28) result in similar outcomes, such as the formation of P bodies and defects to translation, suggesting translation as a key regulatory node for the crosstalk between RNA synthesis and decay. Finally, in Chapter 5, I comment on the potential of Kin28/CDK7-based therapies for the treatment of disease, and how studies in yeast can inform on the mechanism of action of such therapies. Appendix I describes my efforts into characterizing the role of CTD methylation on gene expression. In sum, this work has significantly contributed to our understanding of the myriad ways Kin28/CDK7 functions in regulating gene expression beyond its canonical roles in promoting RNA synthesis.
Author: Sandra Chang Tseng
Publisher:
ISBN:
Category :
Languages : en
Pages : 213
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Book Description
RNA expression can be thought of as a sum of the products of RNA synthesis and decay: on the one hand, cells are transcribing the genes required for a given situation, while on the other, RNA degradation machinery is constantly acting on normal as well as aberrantly synthesized RNA. The kinases which phosphorylate the C-terminal domain (CTD) of RNA Polymerase II (Pol II) are canonically associated with being on the additive scale of the balancing act between RNA synthesis and decay. One such kinase, and the focus of my thesis, Kin28/CDK7 activates and promotes transcription by phosphorylating serine residues on the CTD. I begin my thesis with an introduction into our current understanding of how transcription is regulated via post-translational modification of the CTD, and also present the open questions, which this thesis seeks to address, on the role of Kin28/CDK7 in mediating gene expression (Chapter 1). In Chapter 2, I describe the development of a chemical genetic approach to covalently inhibit Kin28 in budding yeast. The strategy and lessons learned therein can be generally applied to covalently inhibit kinases in other model organisms. Combined with transcriptomic sequencing, I show that Kin28 is required for synthesis of nearly all annotated yeast mRNAs, and demonstrate that previously conflicting views on the matter can be explained by the phenomenon known as "RNA buffering," which is the stabilization of the steady-state level of RNAs during insults to transcription or decay. Also discussed in this chapter is our novel discovery that Kin28 plays a role in advancing Pol II from the initiation into the elongation phase of transcription. In Chapter 3, I investigate determinants of RNA buffering in a Kin28-inhibited regime, and reveal that the relative binding of the RNA binding proteins Nab2 and Ski2 can predict mRNA stability. Furthermore, I show inhibition of Kin28 rapidly induces the formation P bodies and perturbs translation. From my analyses, I present a compendium of the mRNAs that are unstable, buffered, translated, and or poorly translated in situations of transcriptional crisis, a state I show is distinct from that of the canonical stress response. In Chapter 4, I study RNA buffering from the "other side" of the gene expression equation by exploring the combined effect of deleting a component of the RNA decay machinery (rai1::URA3) and inhibition of Kin28. Despite being on opposite sides of the scale of gene expression, both defects in decay (rai1::URA3) and synthesis (inhibition of Kin28) result in similar outcomes, such as the formation of P bodies and defects to translation, suggesting translation as a key regulatory node for the crosstalk between RNA synthesis and decay. Finally, in Chapter 5, I comment on the potential of Kin28/CDK7-based therapies for the treatment of disease, and how studies in yeast can inform on the mechanism of action of such therapies. Appendix I describes my efforts into characterizing the role of CTD methylation on gene expression. In sum, this work has significantly contributed to our understanding of the myriad ways Kin28/CDK7 functions in regulating gene expression beyond its canonical roles in promoting RNA synthesis.
Author: Nathaniel Tate Burkholder
Publisher:
ISBN:
Category :
Languages : en
Pages : 292
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Book Description
Transcription from a most basic perspective is the process of generating strands of RNA from DNA templates. However, in order to control when, where, and how much of specific RNAs are made, cells have evolved vast arrays of transcriptional regulatory mechanisms that allow for extensive differentiation and formation of complex traits. One of the unique and most important mechanisms of transcriptional regulation in eukaryotic cells is the reversible phosphorylation of the RNA polymerase II C-terminal domain (RNAPII CTD). The CTD contains heptad repeats composed of the consensus sequence Tyr1-Ser2-Pro3-Thr4-Ser5-Pro6-Ser7 and all of the non-proline sites are phosphorylated in cells. The human CTD contains 52 repeats where the first 26 proximal heptads are mostly consensus sequence whereas the last 26 distal heptads contain several variations primarily at the Ser7 position. In Chapter 2, I describe how these variations and their modifications alter the phosphorylation of Tyr1 sites by using a combination of biochemical assays and mass spectrometry. Data presented in this chapter reveal how a conserved positively charged pocket in tyrosine kinases likely mediates the interaction residues in the Ser7 position and can potentially affect in vivo Tyr1 phospho-patterning. Futhermore, in Chapter 3 I describe the methodology behind synthesis and testing of cis/trans-locked Ser-Pro CTD peptides for understanding the role of prolyl isomerization on CTD regulation. We used these tools to determine the specificity of several CTD phosphatases, which revealed how the Ser5 phosphatase SSU72 structurally prefers the cis- over the trans-configuration of the phosphorylated Ser5-Pro6 motif. Among the phosphatases discovered to dephosphorylate the CTD, the family of SCP phosphatases seem to be more involved in regulating transcription through dephosphorylation of a different protein called the RE-1 silencing transcription factor (REST). REST is a major silencer of neuronal gene expression in non-neuronal cells which helps prevent development of improper neuronal phenotypes. Abnormally high protein levels of REST have been found in subsets of glioblastoma isolates which likely contributes to their oncogenesis and resistance of chemotherapeutics. SCP1 upregulates REST protein levels through dephosphorylating two degron sites that normally promote rapid turnover of REST, making it a potential drug target for glioblastomas in future studies. In Chapter 4, we show structurally how SCP1 recognizes these REST phosphorylation sites through complex x-ray crystallography. Data presented in this chapter reveal SCP1 specificity for each REST site and how SCP1 activity towards both of them promote REST gene silencing function
Author: Yanling Zhao
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Author: Susanne Jutta Hoheisel
Publisher:
ISBN:
Category :
Languages : en
Pages : 328
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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: Stefan Böing
Publisher:
ISBN:
Category :
Languages : en
Pages : 266
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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: Susanne M. Bailer
Publisher: Humana
ISBN: 9781627036009
Category : Medical
Languages : en
Pages : 0
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Book Description
Virus-Host Interactions: Methods and Protocols covers various aspects of virological research, such as biochemical approaches, including molecular interactions and regulatory mechanisms on the protein as well as the RNA level with a strong focus on the manifold possibilities to study protein-protein interactions, as well as cell biological and immunological methodologies. Viruses represent a reduced form of life that depends on host cells for propagation. To this end, viruses approach and penetrate cells and usurp cellular machineries for their own benefit. Recent technological improvements have enabled the systematic analysis of the virus-host interplay be it on the genomic, the transcriptomic, or proteomic level. In parallel, bioinformatic tools have emerged in support of the large datasets generated by these high-throughput approaches. Written in the 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 protocols, and notes on troubleshooting and avoiding known pitfalls. Authoritative and easily accessible, Virus-Host Interactions: Methods and Protocols will prove invaluable to professionals and novices with its well-honed methodologies and protocols.
Author: Bruce Stillman
Publisher: CSHL Press
ISBN: 9780879695507
Category : Medical
Languages : en
Pages : 724
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Book Description
Proceedings of a summer 1998 meeting, presenting results of recent studies in gene transcription. Covers events ranging from activation, through promoter recognition, repression, chromosome structure, chromatin remodeling, initiation and elongation, and regulatory complexes and pathways. Subjects include targeting sir proteins to sites of action, the yeast RNA polymerase III transcription machinery, nuclear matrix attachment regions to confer long-range function on immunoglobulin, ATP-dependent remodeling of chromatin, and the transcriptional basis of steroid physiology. Annotation copyrighted by Book News, Inc., Portland, OR.
Author: John F. Atkins
Publisher: Springer Science & Business Media
ISBN: 0387893822
Category : Science
Languages : en
Pages : 473
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Book Description
The literature on recoding is scattered, so this superb book ?lls a need by prov- ing up-to-date, comprehensive, authoritative reviews of the many kinds of recoding phenomena. Between 1961 and 1966 my colleagues and I deciphered the genetic code in Escherichia coli and showed that the genetic code is the same in E. coli, Xenopus laevis, and guinea pig tissues. These results showed that the code has been c- served during evolution and strongly suggested that the code appeared very early during biological evolution, that all forms of life on earth descended from a c- mon ancestor, and thus that all forms of life on this planet are related to one another. The problem of biological time was solved by encoding information in DNA and retrieving the information for each new generation, for it is easier to make a new organism than it is to repair an aging, malfunctioning one. Subsequently, small modi?cations of the standard genetic code were found in certain organisms and in mitochondria. Mitochondrial DNA only encodes about 10–13 proteins, so some modi?cations of the genetic code are tolerated that pr- ably would be lethal if applied to the thousands of kinds of proteins encoded by genomic DNA.
