Protein synthesis Transcription. Figure 17.1 Beadle and Tatum’s evidence for the one gene-one enzyme hypothesis.

Slides:

Advertisements

Similar presentations

Chapter 17~ From Gene to Protein

Advertisements

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?

Central Dogma Big Idea 3: Living systems store, retrieve, transmit, and respond to info essential to life processes.

Chapter 4 Transcription and Translation. The Central Dogma.

Chapter 17 AP Biology From Gene to Protein.

Transcription of the DNA code into mRNA.

Chapter 17 From Gene to Protein. Gene Expression The process by which DNA directs the synthesis of proteins 2 stages: transcription and translation Detailed.

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

Gene Structure and Function

Biology 1060 Chapter 17 From Gene to Protein. Genetic Information Important: Fig Describe how genes control phenotype –E.g., explain dwarfism in.

Protein Synthesis - The “Stuff of Life”

NAi_transcription_vo1-lg.mov.

A PowerPoint presentation by Gene Tempest

Chapter 17~ From Gene to Protein.

How DNA is used in Heredity Reading the Book of Life, or Gene Expression.

AP Biology From Gene to Protein How Genes Work AP Biology What do genes code for? proteinscellsbodies How does DNA code for cells & bodies?  how are.

AP Biology Ch. 17 From Gene to Protein.

From Gene to Protein Chapter 17.

Initiating translation

Figure 16.0 Watson and Crick. Figure 16.0x James Watson.

What is the job of p53? What does a cell need to build p53? Or any other protein?

AP Biology From Gene to Protein How Genes Work.

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.

Figure 17.0 Ribosome. Figure 17.1 Beadle and Tatum’s evidence for the one gene-one enzyme hypothesis.

Lecture Series 7 From DNA to Protein: Genotype to Phenotype.

DNA to Protein – 12 Part one AP Biology. What is a Gene? A gene is a sequence of DNA that contains the information or the code for a protein or an RNA.

Review of Protein Synthesis. Fig TRANSCRIPTION TRANSLATION DNA mRNA Ribosome Polypeptide (a) Bacterial cell Nuclear envelope TRANSCRIPTION RNA PROCESSING.

Protein Synthesis. Transcription DNA  mRNA Occurs in the nucleus Translation mRNA  tRNA  AA Occurs at the ribosome.

Ch. 17 From Gene to Protein. Genes specify proteins via transcription and translation DNA controls metabolism by directing cells to make specific enzymes.

Chapter 17 From Gene to Protein.

Protein Synthesis - The “Stuff of Life”

Chapter 17 – From Gene to Protein 1909 – Garrod : First to suggest that genes dictate phenotypes through enzymes that catalyze specific chemical processes.

PROTEIN SYNTHESIS HOW GENES ARE EXPRESSED. BEADLE AND TATUM-1930’S One Gene-One Enzyme Hypothesis.

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 Vocabulary of transcription: transcription - synthesis of RNA under the direction of DNA messenger RNA (mRNA) - carries genetic message from.

Protein Synthesis.

From Gene to Protein n ie: Transcription & Translation.

Gene Activity 1Outline Function of Genes  One Gene-One Enzyme Hypothesis Genetic Code Transcription  Processing Messenger RNA Translation  Transfer.

Protein Synthesis -The “Stuff of Life”

Functions of RNA mRNA (messenger)- instructions protein

Genes and Protein Synthesis

Ch 17 From Gene to Protein Proteins: the links from genotype to phenotype.

The Central Dogma of Molecular Biology DNA  RNA  Protein  Trait.

Gene Activity 1Outline Function of Genes  One Gene-One Enzyme Hypothesis Genetic Code Transcription  Processing Messenger RNA Translation  Transfer.

N Chapter 17~ From Gene to Protein. Protein Synthesis: overview n One gene-one enzyme hypothesis (Beadle and Tatum) –The function of a gene is to dictate.

Protein Synthesis - The “Stuff of Life”. 2 Proteins Proteins are the “workhorse” molecule found in organisms. The blue print for proteins is coded in.

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

Chapter 17 From Gene to Protein. One gene, one protein Chapter 17 From Gene to Protein.

The Ribosome –Is part of the cellular machinery for translation, polypeptide synthesis Figure 17.1.

Gene Activity Chapter 14. Gene Activity 2Outline Function of Genes  One Gene-One Enzyme Hypothesis Genetic Code Transcription  Processing Messenger.

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

Chapter 17 From Gene to Protein.

Figure 17.2 Overview: the roles of transcription and translation in the flow of genetic information (Layer 5)

Protein Synthesis. One Gene – One Enzyme Protein Synthesis.

From Gene to Protein: Transcription & RNA Processing

The Ribosome Is part of the cellular machinery for translation, polypeptide synthesis Figure 17.1.

From Genes to Protein Chapter 17.

From Gene to Protein ie: Transcription & Translation.

Protein Synthesis Ch 17.

Protein Synthesis.

Protein Synthesis.

Chapter 14~ From Gene to Protein

From Gene to Protein: Transcription & RNA Processing

Chapter 17 From Gene to Protein.

Protein Synthesis: Transcription

Chapter 17~ From Gene to Protein

CHAPTER 17 FROM GENE TO PROTEIN.

Lecture #7 Date _________

Presentation transcript:

Protein synthesis Transcription

Figure 17.1 Beadle and Tatum’s evidence for the one gene-one enzyme hypothesis

Figure 17.2 Overview: the roles of transcription and translation in the flow of genetic information (Layer 5)

Figure 17.6 The stages of transcription: elongation

Figure 17.7 The initiation of transcription at a eukaryotic promoter

Figure 17.8 RNA processing; addition of the 5 cap and poly(A) tail

Figure 17.9 RNA processing: RNA splicing

Figure The roles of snRNPs and spliceosomes in mRNA splicing

Figure Correspondence between exons and protein domains

Figure 17.3 The triplet code

The reading frame problem: What message is present? TRTHEFATCATATETHERAT THE FAT CAT ATE THE RAT Need to know –how letters are grouped –where to start How about here? TTAREHTETATACTAFEHTT