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DNA Structure and Replication Ch. 14

DNA Structure and Replication Ch. 14. DNA and Heredity. Mendel set the stage for inheritance patterns, but it was not yet known that this is through DNA Proteins were considered the better source of variation, why? More possible variation ; 20 AA vs. 4 Base pairs

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DNA Structure and Replication Ch. 14

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  1. DNA Structure and ReplicationCh. 14

  2. DNA and Heredity • Mendel set the stage for inheritance patterns, but it was not yet known that this is through DNA • Proteins were considered the better source of variation, why? • More possible variation; 20 AA vs. 4 Base pairs • A series of researches over decades showed it really DNA: • Griffith • Avery • Hershey and Chase

  3. Frederick Griffith Kills Mice • Worked with Streptococcus pneumoniae • S-Type (smooth) virulent; deadly • R-Type (rough) non-virulent; pretty okay • Ran for tests on mice: • S-type injected into mice • Mice die • R-type injected into mice • Mice live • Heat-killed S-type injected into mice • Mice live • Heat-killed S-type and R-type injected into mice • Mice die Conclusion: • Some material from dead S-type changed R-type into S-type (transformed)

  4. Avery Doesn’t Kill Mice • Works with Streptococcus pneumoniaetoo, but only in test tubes • Used enzymes to destroy either the proteins, DNA, or RNA of the cells and then tried to transform them • R-type + S-type with destroyed proteins transformation • R-type + S-type with destroyed RNA transformation • R-type + S-type with destroyed DNA no transformation Conclusion: • DNA must be needed to transform bacteria cells, so it must be the key to heredity

  5. Hershey and Chase End the Debate • Worked with E. coliand a bacteriophage called T2 • Virus that infects only bacteria; made of just DNA and a protein coat • Labeled DNA and protein coat of virus with radioactive P and S isotopes and traced them through the virus life cycle • E.coli + Virus with labeled protein coat no radioactivity in offspring • E.coli + Virus with labeled DNA radioactivity in offspring Conclusion: • DNA, not proteins, are passed on to offspring

  6. Structure of DNA • Discovered by Watson and Crick with help from Franklin and Wilkins • X-Ray diffraction image of DNA • X-rays shot through crystal containing molecule • Photograph film catches areas exposed when x-rays deflect • What is DNA’s shape? • Double helix • What is it made of? • Nucleotides : Adenine (A), Guanine (G), Thymine (T), and Cytosine (C) • How are the nucleotides connected? • Phosphodiester bonds in a sugar-phosphate backbone; creates 5’ end and a 3’ end • Strands held together by H-bonds

  7. Structure of DNA • How do nucleotides match up? • Purines (two rings) with Pyrimidines (one ring) • A-T; G-C • What is the vocab word for this type of pairing? • Complementary base pairing • In order for pairing to happen, the two strands in DNA must run opposite directions. What is this called? • Antiparallel • Other dementions: • DNA is 2n wide (only Purine-Pyrimidine combination makes this length) • Full twist is 3.4 nm long • Distance between each nucleotide is 0.34nm • SO…there are 10 bases/turn

  8. Semiconservative Replication? • In replication, one strand is used as a template (guide) to build a new strand • Unzipping DNA allows both strands to be copied at the same time, thus producing copies that each have one full strand from the starting DNA • Other options existed… • Conservative model DNA is template but original DNA reforms and new DNA has no original strands • Dispersive Replication model old and new DNA strands mix as they form

  9. Meselson and Stahl • Worked with DNA made of “heavy” 15N isotope • Mixed “heavy” DNA with 14N, did one replication, and then separated DNA types by centrifuge (heavy ones sink more) • Allowed DNA to replicate again and centrifuged again • Semiconservative 1st; lighter DNA (half 15N and half 14N), 2nd; lightest appears (all 14N) • Conservative 1st; heavy DNA (all 15N) and lightest (all 14N), 2nd; same • Dispersive all DNA gets lighter as more 14N is used

  10. Vocabulary Explosion! • Deoxyribosenucleoside triphosphates building blocks of DNA (dATP, dGTP, dCTP, dTTP) • DNA Helicase breaks H-bonds and unwinds DNA • Topoisomerse untwists downstream DNA; DNA twists as it is unzipped • SSBs (Single-stranded binding proteins) hold unzipped DNA strands so they don’t adhere • DNA polymerase III main enzyme used to copy DNA • Sliding DNA Clamp helps DNA polymerase stay attached to DNA

  11. Vocabulary Explosion 2! The Sequel • DNA polymerase I removes RNA primers at 5’ end • Primase makes primers; RNA nucleotides that mark the start of replication • DNA ligase fixes breaks in sugar-phosphate backbone • Leading strand DNA strand continuously replicated • Lagging strand DNA strand replicated in fragments (Okazaki fragments)

  12. DNA Replication: Getting Started • DNA strands have a 5’ and 3’ end, but nucleotides can only be added to the 3’ (free –OH ready for dehydration reaction) • New DNA is built 5’3’, so the template is “read” 3’5’ • Replication starts at ori region of the DNA (origin of replication) • Eukaryotic DNA is too long to replicate from end to end • Hundreds ori sights exist and replication goes in both directions (replication bubbles) • DNA helicase unwinds the strands creating a replication fork (Y-structure) • SSBs hold stands apart

  13. DNA Replication: Primers • Pulling apart strands causes the DNA to twist and bundle up • Topoisomerase cuts DNA ahead of the replication fork, untwists it, and rebinds it • DNA Poly III needs a 3’ end to start replication • Primers (RNA) are base paired at ori and provide a 3’ for Poly III • Primers are built by Primase • Primers are removed by DNA Polymerase I (exonuclease) and replaced with DNA

  14. DNA Replication: Two Types of Synthesis • DNA is antiparallel, so one strand is read 3’5’ (leading strand) while the other runs 5’3’ (lagging strand) • DNA cannot be added in the 5’3’ direction • Leading stand as continuous replication • Lagging strand is replicated in sections (Okazaki Fragments) • Leaves gaps which are filled in by DNA Poly I and Ligase

  15. DNA Replication: Finishing Up • When bubbles meet, the enzymes detach and DNA re-adheres • If DNA is liner, what happens to the starting stands on either end? • They are not be replicated; short section is lost after each replication DNA gets shorts with time • Telomere noncoding area at the end of DNA (5’-TTAGGG-3’) that protect against this • Shortening is believed to be the main cause of aging and death • Telomerase enzyme that adds more telomeres; only active as an embryo • What type of cell is telomerase also active in? • Cancer; If we can turn these off cancer will divide itself to death

  16. DNA Replication: Opps…Mistake… • Polymerase is not perfect; makes a base-pair mismatch 1: 1,000 nucleotides • Proofreading mechanism Poly III can backup and use exonuclease to replace mistakes • Lowers mutation rates to 1:1 million nucleotides • What if Poly III miss the mistake? • DNA repair mechanisms run along the DNA double checking it • Any area wider or narrower than 2nm must have a mistake and replaces the nucleotide

  17. DNA Compaction • DNA is around 2 meter long and must fit in a 10mm nucleus • Most is compacted and only opened for making proteins • Chromatin DNA and Chromosomal proteins • Histone small, positively charged proteins; bind negative backbone of DNA • Histones join together and wrap DNA around them to make nucleosomes • Strings of nucleosomes connected by linkers string of beads • Decreases DNA size by a factor of 7! • Nonhistone proteins effect histone binding so regions of DNA become accessible

  18. DNA Compaction • Nucleosome strings (10-nm chromatin fibers) can wrap around a H1 histone to make 30-nm chromatin fiber • Solenoid model helix of nucleosomes • This level of condensing protects against damage • Euchromatin loosely packed regions (light color band on chromosome); often expressed • Heterchromatin densely packed regions (dark color band on chromosome); often deactivated genes

  19. Bacterial DNA • Prokaryotes have no need for histones • DNA is one circular ring (bacterial chromosome) that is short enough • Kept compacted in a mass called the nucleoid • Addition al DNA can be absorbed by bacteria • Plasmids short DNA rings • Can be copied and exchanged with other bacteria of the same species or genus • Can help form drug resistant bacteria

  20. Homework • Suggested Homework: • Test Your Knowledge Ch. 14 • Actual Homework: • Interpret the Data Ch. 14 • Discuss the Concepts #1 and #4 • Lab Reports due 12/11 • Papers due. 12/13

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