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DNA Replication
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Review Why is the process of DNA called a semiconservative process?
Let’s review DNA structure: List all characteristics you can recall about DNA molecule
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A closer look Today we will learn about some incredible stuff happening in your body right now! (p.313)
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Getting Started DNA replication particular sites called origins of replication Proteins attach and begin copying DNA strand Forms replication bubble could be multiple in single DNA helix = speeds up replication process At each end of bubble = replication forks: the y=shaped region where parts of parental DNA being unwound DRAW pic. on pg. 313
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Proteins involved in unwinding
Helicase: untwists/unzips DNA at forks =opens up template strands Single –strand binding proteins: bind to unwound parental strands, keeping them from re-pairing Topoisomerase: helps relieve strain on unwound DNA while unwinding is occurring so DNA does not break permanently
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Replication Initiation
Enzymes that add nucleotides need help to start… can’t initiate process on their own initial nucleotide chain is added = a short RNA chain called a primer created by enzyme called primase -usually 5-10 nucleotides long *new DNA strand will start from 3’ end of primer
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Adding Bases Main protein involved = DNA polymerase
Specifically DNA polymerase I (DNA pol I) and DNA polymerase III (DNA pol III) After primer added, polymerase will begin adding nucleoside triphosphates (dATP) to the strand Similar to ATP except sugar: ATP = ribose, dATP = deoxyribose When added to template, 2 phosphates break off (b/c unstable) = exergonic reaction that drives polymerization
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Antiparallel Elongation
DNA strands/replication has directionality (like 1 way street) compliment strands are antiparallel How does the antiparallel arrangement of the double helix affect replication? (HINT: think back to the rule of the primer)
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Answer: DNA pol can only add bases to 3’ end of primer .. So a new DNA strand can ONLY elongate from 5’- 3’ direction Let’s take a closer look at replication forks of the bubble to see how this works!
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Antiparallel Elongation
1st strand, DNA pol III can synthesize complimentary strand continuously as DNA unwinds from 5’ – 3’ direction = LEADING STRAND Only 1 primer needed 2nd strand, DNA pol III must work in opposite direction (away from replication fork) to continue replication in 5’ – 3’ direction = LAGGING STRAND Synthesized discontinuously in segments called Okazaki fragments
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DNA Replication
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What do we do with the primer?
When segment replication is complete, primer must be removed DNA pol I comes in and removes RNA primer and fills hole with DNA nucleotides An enzyme called DNA ligase comes in and patches two segments of lagging strand together Let’s see it in action!
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Review: For the following enzymes/proteins, list their roles in DNA replication: DNA polymerase III DNA helicase DNA ligase Primase Single-strand binding proteins Topoisomerase
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