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Chapter 12 DNA Information and Heredity, The Cellular Basis of Life Section 12-1: Identifying the Substance of Genes Frederick Griffith’s Experiments (1920’s) Bacterial Transformation 1. He was studying bacteria that cause pneumonia. 2. His experiment led to a discovery of a process a called transformation: - Process in which one strain of bacteria changes into another strain. Bacterial Viruses (Bacteriophages) The molecular cause of transformation What role did bacterial viruses play in identifying the genetic material ? Oswald Avery (1940s) 1. His goal was to determine what molecule was used during transformation. 2. By a process of elimination using biological enzymes they discovered that D N A was the transforming factor. Section 12-1: The Hershey - Chase Experiment (1950s) 1. They did an experiment involving viruses to prove the work of both Griffith & Avery. 2. Viruses are only made of two things: - protein coat - nucleic acid core 3 In step 1 of their experiment, they tagged the DNA core with radioactive P-32 to see if that was the transforming factor. It was the transforming factor!!. 4. In step 2 of their experiment, they tagged the protein coat with radioactive S-35 to see if that was the transforming factor. It was not!. Transformation 12-1 The Role of DNA What is the role of DNA in heredity • • • • The DNA that makes up genes can: 1. Store information in cells. 2. Copy this information in cells. 3. Transmit this information when cells divide. • • Study the book – cell analogy on page 342 of your textbook. A book can store information, you can copy information from this book and the book after being copied can be transmitted or given to others. Section 12-2: The Structure of DNA The Components of DNA: The Nucleotide: 1. A nucleotide is the monomer of a nucleic acid such as DNA or RNA. 2. It has three components: - A phosphate group - A 5-carbon sugar called deoxyribose - A nitrogenous base Nucleotide • Phosphate / sugar / N base 12-2: The Structure of DNA Components of DNA: The Nucleotide: 3. There are four different bases in DNA: - Adenine (A) - Thymine (T) - Guanine (G) - Cytosine (C) 4. These bases are placed in two groups: - Purines (double ring) A & G - Pyrimidines (single ring) C & T 5. Chargoff’s Rules of Base Pairing: - A pairs with T- C pairs with G - a purine will pair with a pyrimidine 12-2: The Structure of DNA The Double Helix: 1. The structure of DNA was discovered through the work of three people: A. Rosalind Franklin (1950s) - she used a technique called x-ray diffraction to show that DNA has two strands that form a helix. 12-2 : The Structure of DNA The Double Helix: 1. The structure of DNA was discovered through the work of three people: B. James Watson & Francis Crick (1953) - They expanded on Franklin’s work by building a 3-D model of DNA - Their model had a double helix structure - The helix had a sugar-phosphate backbone - The bases were in the middle and held together by hydrogen bonds. DNA There are four levels of folding to produce the chromosome structure. 1. beads-on-a-string 2. 30 nm fiber 3. looped domain 4. mitotic chromosome DNA beads-on-a-string DNA is wrapped around histones forming nucleosomes linked in a row. DNA 30 nm fiber The beads-on-a-string level is coiled around itself in a solenoid spiral. DNA looped domain The solenoid spiral loops up and down to compress itself further. DNA mitotic chromosome The beads-on-a-string forming the solenoid spiral forming the looped domain give rise to the mitotic chromosome. DNA 12-3: DNA Replication Coping the Code Eukaryotic Chromosome Structure: Section 12-3: DNA Replication What is replication? This is the process of making a copy of the genome during the S Phase of the cell cycle. The steps: DNA helicase “unzips” the double helix by breaking the H bonds between the bases. - Two helicase enzymes work in opposite directions & form a replication bubble. - The site where the helicase is doing the unzipping is called a replication fork. Section 12-3: Replication The steps: 2. Within the replication bubble, two DNA polymerase work in opposite directions & make a complementary strand of DNA. 3. At the end of replication, there are two exact copies of DNA. 12-3 Replication in Living Cells • • How does DNA replication differ in prokaryotic cells and eukaryotic cells? bacteria • Prokaryotes or cells normally have a single circular strand of DNA. Replication starts from a single point and proceeds in 2 directions. • In Eukaryotes or cells with a nucleus, replication begins at dozens or even hundreds of places and proceeds in both directions.
