RNA polymerase #1 General properties E. coli RNA polymerase Eukaryotic RNA polymerases.

Slides:



Advertisements
Similar presentations
Transcription General Prokaryotic –Mechanism –Apparatus –Regulation Eukaryotic –Mechanism –Apparatus –Regulation.
Advertisements

RNA: Structure & Synthesis By Amr S. Moustafa, M.D.; Ph.D.
V. Transcription (DNA-directed RNA synthesis) A. Prokaryotes: RNA polymerase, Promoters – sigma factor B. Eukaryotes: RNA polymerases, Promoters – transcription.
Transcription Transcription of DNA into RNA DNA transcription produces a single-stranded RNA molecule that is complementary to one strand of DNA.
Chap. 7 Transcriptional Control of Gene Expression (Part A) Topics Control of Gene Expression in Bacteria Overview of Eukaryotic Gene Control and RNA Polymerases.
Review: Proteins and their function in the early stages of replication 1 = initiator proteins 2 = single strand binding proteins 3 = helicase 4.
Mechanism of Transcription
Come to lectures! All exam questions will be from lectures. Supplemental and updated course materials will be posted on the course web site regularly;
Chapter 21 (part 1) Transcription. Central Dogma.
Chapter 21 (part 1) Transcription. Central Dogma.
(CHAPTER 12- Brooker Text)
Bacterial Physiology (Micr430) Lecture 8 Macromolecular Synthesis and Processing: DNA and RNA (Text Chapter: 10)
Elongation and Termination of Transcription. Elongation phase of transcription Requires the release of RNA polymerase from the initiation complex Highly.
Transcription.
Relationship between Genotype and Phenotype
GENE: RNA polymerases and transcription factors. Structure of genes Prokaryotic and eukaryotic genes differ in their structure, however there are a number.
E. coli RNA Polymerase M.Prasad Naidu MSc Medical Biochemistry,
Bacterial Transcription Dr Mike Dyall-Smith, lab 3.07 Aim: Understand the general process of bacterial transcription References: Schaecter et al, Microbes,
Transcription Chapter 11.
Chapter 13 - Transcription
Bacterial Transcription
Chapter 9 Transcription.
Chapter 26 - RNA Metabolism
RNA SYNTHESIS Mukund Modak, Ph.D. Lecture 32 Modak.
1 SURVEY OF BIOCHEMISTRY Transcription and Translation.
Chapter 31 The Prokaryotic Transcription Apparatus (pages ) Learning objectives: Understand the following Differences between DNA and RNA polymerases.
GENETICS ESSENTIALS Concepts and Connections SECOND EDITION GENETICS ESSENTIALS Concepts and Connections SECOND EDITION Benjamin A. Pierce © 2013 W. H.
LECTURE CONNECTIONS 13 | Transcription © 2009 W. H. Freeman and Company.
Berg • Tymoczko • Stryer
Transcription.
Mechanisms of Transcription 生物学基地班 魏昌勇.
Biochemistry Sixth Edition
DNA Replication Robert F. Waters, Ph.D.. Goals:  What is semi-conservative DNA replication?  What carries out this process and how?  How are errors.
Transcription Chapter 8. The Problem Information must be transcribed from DNA in order function further. Information must be transcribed from DNA in order.
Relationship between Genotype and Phenotype
13.1 RNA Consisting of a Single Strand of Ribonucleotides Participates in a Variety of Cellular Functions.
1. Transcription Dr. Ishtiaq Ahmad Khan Dr. Panjwani Center for Molecular Medicine and Drug Research.
BIOCHEMISTRY REVIEW Overview of Biomolecules Chapter 12 Transcription.
DNA mRNA Transcription Cell Polypeptide (protein) Translation Ribosome Transcription.
Transcription Chapter 8. The Problem Information must be transcribed from DNA in order function further. Information must be transcribed from DNA in order.
Transcription. DNA stores genetic information in a stable form that can be readily replicated. The expression of this genetic information requires its.
TRANSCRIPTION IN PROKARYOTES
Gene Expression. Central Dogma Information flows from: DNA  RNA  Protein Exception: reverse transcriptase (retroviruses) RNA  DNA  RNA  Protein.
Transcription in Prokaryotic (Bacteria) The conversion of DNA into an RNA transcript requires an enzyme known as RNA polymerase RNA polymerase – Catalyzes.
LECTURE CONNECTIONS 13 | Transcription © 2009 W. H. Freeman and Company.
Transcription and Post Transcription processing
Relationship between Genotype and Phenotype
RNA and Gene Expression BIO 224 Intro to Molecular and Cell Biology.
Lecture 4: Transcription in Prokaryotes Chapter 6.
TOPIC 2.7 TRANSCRIPTION & TRANSLATION. Nucleus: the control center  contains nuclear envelope, nucleoli, chromatin, and distinct compartments rich in.
Transcription of the Genetic Code: The Biosynthesis of RNA Mar 1, 2015 CHEM 281.
Transcription and RNA processing Fall, Transcription Outline Notes RNA Polymerase Structures Subunits Template versus coding strands Polymerase.
GENE TRANSCRIPTION AND RNA MODIFICATION
Gene expression. Transcription
Peter John M.Phil, PhD Atta-ur-Rahman School of Applied Biosciences (ASAB) National University of Sciences & Technology (NUST)
RNA Synthesis (Transcription)
Gene Expression - Transcription
Transcription.
Relationship between Genotype and Phenotype
Biochemistry Free For All
Peter John M.Phil, PhD Atta-ur-Rahman School of Applied Biosciences (ASAB) National University of Sciences & Technology (NUST)
Lecture 5. Transcription: DNA→RNA
Relationship between Genotype and Phenotype
Transcription in Prokaryotic (Bacteria)
Transcription Figure: Title: One strand is transcribed into RNA
TRANSCRIPTION--- SYNTHESIS OF RNA
RNA Synthesis (Transcription)
Regulation of transcription Plant Biotechnology Lecture 2
Relationship between Genotype and Phenotype
Presentation transcript:

RNA polymerase #1 General properties E. coli RNA polymerase Eukaryotic RNA polymerases

Pathway for Gene Expression

Reaction catalyzed by RNA polymerase Catalyzes the synthesis of RNA directed by DNA as a template = transcription Makes an RNA chain with a sequence complementary to the template strand of DNA Does NOT require a primer; can start RNA synthesis at a site on the DNA template

Sequential addition of ribonucleotides + + Pyrophosphate = PPi

E. coli RNA polymerase Synthesizes all classes of RNA –mRNA –rRNA –tRNA Core=  2  ’ catalyzes elongation of an RNA chain Holoenzyme =  2  ’  catalyzes initiation or RNA synthesis specifically at a promoter

Two Definitions of Promoter 1. The sequence of DNA required for accurate, specific initiation of transcription 2. The sequence of DNA to which RNA polymerase binds to accurately initiate transcription In most cases, RNA polymerase binds to a DNA sequence including the initiation site, but it can be directed there by sequences flanking the initiation site. Thus definition 2 can be a subset of definition 1.

RNA polymerase at a promoter  : assembly and binds to UP  ’: form catalytic center  : binds -10 and -35 of promoter to confer specificity during initiation

Determination of 3-D structure by electron crystallography

3-D images of core and holoenzyme CoreHoloenzyme

Holoenzyme for RNA polymerase from E. coli

Role of  subunit in assembly of RNA polymerase and other functions

Mode of action of  factors The  factor causes RNA polymerase to be selective in its choice of initiation sites by affecting the dissociation rate of polymerase from DNA. –Core dissociates from general DNA with a half- time of 60 min; use in elongation. –Holoenzyme dissociates from general DNA with a half-time of 1 sec! –Holoenzyme dissociates from promoter DNA with a half-time of hours (in absence of rNTPs).

Events at initiation of transcription

Transcription cycle Initiation –Holoenzyme binds to the promoter, unwinds DNA, and forms phosphodiester bonds between 7 to 12 nucleotides –Need  Elongation –  dissociates –Core elongates RNA with high processivity –May use NusA Termination –Polymerase dissociates from template DNA and releases new RNA –Often use .

Diagram of Transcription Cycle in Bacteria StartStop RNA pol core Sigma NusA Rho Start Stop RNA pol holoenzyme Nontemplate Template Closed complex Open complex Elongating complex Terminating complex

Sites on RNA polymerase core Enzyme covers about 60 bp of DNA, with about 17 bp unwound = transcription bubble. The bubble must contact the active site for polymerization. At the beginning of the bubble, the DNA is unwound, implicating a helicase activity. At the end of the bubble, the DNA is rewound.

Transcription bubble and RNA polymerase

Effects of transcription on supercoiling of the template The unwinding (untwisting) and rewinding of the DNA template introduces positive supercoils ahead of the polymerase and negative supercoils behind it. Unwinding will decrease T by 1 for every 10 bp unwound. Since  L=0,  W=-  T, and  W=+1 for every 10 bp unwound. The opposite occurs upon rewinding.  T=+1 for every 10 bp rewound, and thus  W=-1 for every 10 bp rewound. In vivo, topoisomerases aid transcription.

3 RNA polymerases in eukaryotes Name Makes  -amanitin RNA pre-rRNA insensitive Polymerase I RNA pre-mRNA very sensitive Polymerase II some snRNAs RNA pre-tRNA less sensitive Polymerase III other small RNAs some snRNAs

Subunit structure of eukaryotic RNA polymerases All 3 have multiple subunits (8 to 14 ). MW for each polymerase is about 500,000 Some subunits are common to all 3 RNA polymerases All 3 RNA polymerases have subunits that are homologous to the bacterial ,  ’ and  subunits.

Subunits of yeast RNA Pol II Approximate subunits per size (kDa)polymeraserole / comment 2201related to  ' 1301related to  402related to  35< 1 302common to all 3 271common to all 3 24< 1 201common to all

Distinct forms of RNA polymerase used for initiation and elongation: RNA Pol II Model: Phosphorylation of Pol IIa to make Pol IIo is needed to release the polymerase from the initiation complex and allow it to start elongation. CTD has repeat of (YSPTSPT) CTD = C-terminal domain

3-dimensional view of yeast RNA Pol II Both yeast RNA Pol II and E. coli RNA polymerase core Have a similar shape and have the channel for DNA template. Images from Dr. S. Darst Core Holoenzyme

RNA Pol II bound to DNA and general transcription factors