Transcription Chapter 17b. Objectives Understand the process of transcription Recognize the role of RNA Polymerase Recognize the significance of promoter.

Slides:

Advertisements

Similar presentations

Ch 17 Gene Expression I: Transcription

Advertisements

DNA was dicovered by Juhann Friedrich in And the first demonstration that DNA contain genetic information was made in 1944 by Avery, Macleod.

Topic 7.3 Transcription.

T HE C ENTRAL D OGMA OF B IOLOGY STATES THAT DNA CODES FOR RNA, AND RNA CODES FOR P ROTEINS When DNA codes for RNA, the process is called TRANSCRIPTION.

SBI 4U November 14 th, What is the central dogma? 2. Where does translation occur in the cell? 3. Where does transcription occur in the cell?

(CHAPTER 12- Brooker Text)

Step 1 of Protein Synthesis

Transcription: Synthesizing RNA from DNA

Protein Synthesis.

Genes and Protein Synthesis

RNA (Ribonucleic acid)

Transcription: Synthesizing RNA from DNA

FROM GENE TO PROTEIN: TRANSCRIPTION & RNA PROCESSING Chapter 17.

Protein Synthesis The genetic code – the sequence of nucleotides in DNA – is ultimately translated into the sequence of amino acids in proteins – gene.

CHAPTER 17 FROM GENE TO PROTEIN Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings Section B: The Synthesis and Processing of RNA.

Activate Prior Knowledge

From Gene to Protein Chapter 17.

From Gene to Protein A.P. Biology. Regulatory sites Promoter (RNA polymerase binding site) Start transcription DNA strand Stop transcription Typical Gene.

Chapter 17 From Gene to Protein

PROTEIN SYNTHESIS. Protein Synthesis: overview  DNA is the code that controls everything in your body In order for DNA to work the code that it contains.

Genetics 3: Transcription: Making RNA from DNA. Comparing DNA and RNA DNA nitrogenous bases: A, T, G, C RNA nitrogenous bases: A, U, G, C DNA: Deoxyribose.

DNA Function: Information Transmission. ● DNA is called the “code of life.” What does it code for? *the information (“code”) to make proteins!

Chapter 17: From Gene to Protein Objectives 1. To understand the central dogma 2.To understand the process of transcription 3.To understand the purpose.

Chapter 17 From Gene to Protein. Gene Expression DNA leads to specific traits by synthesizing proteins Gene expression – the process by which DNA directs.

Transcription Packet #10 Chapter #8.

Protein Synthesis Transcription.

Transcription and mRNA Modification

RNA & Transcription. RNA (Ribonucleic Acid) Journal For all your RNA news!

GenePolypeptide Gene  Polypeptide Transcription 1.RNAP binds to promoter 2.Separates DNA strands 3.Transcribes the DNA (adds RNA nucleotides in a 5'-3'

Transcription … from DNA to RNA.

From Gene to Protein Chapter 17. One Gene One Enzyme.

Protein Synthesis. DNA is in the form of specific sequences of nucleotides along the DNA strands The DNA inherited by an organism leads to specific traits.

Transcription in Prokaryotic (Bacteria) The conversion of DNA into an RNA transcript requires an enzyme known as RNA polymerase RNA polymerase – Catalyzes.

Chapter 5 RNA and Transcription From Gene to Protein Honors Genetics Ms. Gaynor.

TRANSCRIPTION Copying of the DNA code for a protein into RNA Copying of the DNA code for a protein into RNA 4 Steps: 4 Steps: Initiation Initiation Elongation.

Transcription. Recall: What is the Central Dogma of molecular genetics?

Transcription Chapter 25. Objectives  Understand the process of transcription  Recognize the role of RNA Polymerase  Recognize the significance of.

Protein Synthesis-Transcription Why are proteins so important? Nearly every function of a living thing is carried out by proteins … -DNA replication.

Genes and Protein Synthesis

The Central Dogma of Molecular Biology replication transcription translation.

Lesson 3 – Gene Expression

Protein Synthesis- Transcription DNA-->RNA. Expression of Gene or Protein Synthesis I. Transcription A. Initiation B. Elongation C. Termination D. RNA.

TRANSCRIPTION. Initiation  Transcription factors bind to the promoter region  RNA polymerase binds to the promoter region  The enzyme’s active site.

TRANSCRIPTION (DNA → mRNA). Fig. 17-7a-2 Promoter Transcription unit DNA Start point RNA polymerase Initiation RNA transcript 5 5 Unwound.

The Central Dogma of Life. replication. Protein Synthesis The information content of DNA is in the form of specific sequences of nucleotides along the.

Protein Synthesis Introduction Chapter 17. What you need to know! Key terms: gene expressions, transcription, and translation How eukaryotic cells modify.

From Gene to Protein Chapter 17. Overview of Transcription & Translation.

1 RNA ( Ribonucleic acid ) Structure: Similar to that of DNA except: 1- it is single stranded polyunucleotide chain. 2- Sugar is ribose 3- Uracil is instead.

RNA & Transcription.

Genetics Unit I-Part C Transcription

Chapter 5 RNA and Transcription

Chapter 10 How Proteins Are Made.

Transcription Ms. Day AP Biology.

Agenda 3/7 Protein Warm Up Transcription Notes Transcription Model

From Gene to Protein Chapter 17.

TRANSCRIPTION Sections 5.2 & 5.3.

Gene Expression: From Gene to Protein

Chapter 17 Protein Synthesis.

Transcription in Prokaryotic (Bacteria)

Chapter 17 From Gene to Protein.

Analogy Video Central Dogma Analogy Video (Resources Page)

Protein Synthesis: Transcription

Gene Expression: From Gene to Protein

Protein Synthesis The genetic code – the sequence of nucleotides in DNA – is ultimately translated into the sequence of amino acids in proteins – gene.

Protein Synthesis The genetic code – the sequence of nucleotides in DNA – is ultimately translated into the sequence of amino acids in proteins – gene.

Transcription/ Translation

Dr. Israa ayoub alwan Lec -7-

Presentation transcript:

Transcription Chapter 17b

Objectives Understand the process of transcription Recognize the role of RNA Polymerase Recognize the significance of promoter and terminator regions of DNA Explain how transcribed RNA is modified prior to exiting the nucleus. Understand the significance of this process

Transcription Consists of three stages –Initiation: attachment of RNA Polymerase to the promotor region on DNA –Elongation: building of the mRNA from the 3’ end of the nucleotide polymer –Termination: release of RNA polymerase and mRNA following transcription of the terminator region of the DNA

Initiation Genes on the DNA begin with a promoter region consisting of a sequence of A & T (TATA box) and the first nucleotide involved in the peptide sequence Transcription factors (proteins that assist the binding of RNA polymerase to the promoter) are found in association with the promoter region Transcription initiation complex: transcription factors & RNA polymerase bound to the promoter region of the DNA

Elongation Once initiation is complete the 2 strands of the DNA unwind due to the zipper region of the enzyme RNA polymerase builds a mRNA strand complimentary to the DNA transcription unit (60 bases/sec) Once the RNA Polymerase passes the DNA strands reform their double helix

Termination in Prokaryotes Different mechanisms –Rho-independent mechanism GC rich area followed by Uracils –Rho-dependent mechanism a specific protein called a rho factor binds to the end of the RNA chain slide along the strand towards the polymerase digesting the strand

Termination In Eukaryotes When the RNA Polymerase transcribes the terminator region of the DNA, the polymerase releases the mRNA due to the action of proteins The transcribed termination sequence, also known as the polyadenylation signal in the pre-mRNA, is AAUAAA. Polymerase continues to synthesize RNA until an enzyme catches up to it and causes it to fall off

Transcribed mRNA (pre-mRNA) must be modified before leaving the nucleus modifications include: –addition of 5’cap Prevents “unraveling” Helps ribosome attach –addition of poly A tail Prevents “unraveling” Assists in the export of mRNA from nucleus Modification of mRNA

Transcribed RNA is “too long” and is shortened in the nucleus through RNA splicing Exons are segments of the mRNA that contain information that will be reflected in the polypeptide Introns are segments of the mRNA that separate (intervene) exons Further Transcript Modifications

How is this done? Small nuclear ribonucleicproteins (snRNP) recognize intron ends and together with proteins form a structure called a spliceosome Spliceosomes remove introns while connecting exons together Ribozymes may also catylyze this process in some organisms (introns may act as ribozymes)

Why bother with introns? Introns may regulate gene activity and the passage of mRNA into the cytoplasm Genes may play roles in multiple proteins, introns may enable a gene to be diverse in function May increase recombination of genetic material (easier to cut and paste)