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Chapter 20. DNA Replication and Repair. Watson and Crick Predicted Semi-conservative Replication of DNA. Watson and Crick: "It has not escaped our notice that the specific (base) pairing we have postulated immediately suggests a possible copying mechanism for the genetic material."
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Chapter 20 DNA Replication and Repair
Watson and Crick Predicted Semi-conservative Replication of DNA • Watson and Crick: "It has not escaped our notice that the specific (base) pairing we have postulated immediately suggests a possible copying mechanism for the genetic material." • The mechanism: Strand separation, followed by copying of each strand. • Each separated strand acts as a template for the synthesis of a new complementary strand.
The Semiconservative Model • Matthew Meselson and Franklin Stahl tested semi-conservative model • Template DNA labeled with 15N –nucleotides. (more dense than normal DNA) • Fed 14N –nucleotides. (newly synthesized DNA was less dense than template) • Isolated DNA at different times and fractionated DNA on a density gradient • denser/heavier DNA found lower in the gradient. • Less dense/lighter DNA found higher in gradient.
E. coli genome size = 4.6 X 106 bp • Bacteria have circular chromosome with single origin of replication. • Replication rate is ~1000 base pairs per second. • Duplicate chromosome in 38 minutes.
Eukaryotes have larger genomes 3 X 109 bps • Rate of Eukaryote chromosome replication is slower • But because eukaryote chromosomes have multiple origins of replication, it takes about the same amount of time to replicate complete genome.
The Enzymology of DNA Replication • If Watson and Crick were right, then there should be an enzyme that makes DNA copies from a DNA template • In 1957, Arthur Kornberg and colleagues demonstrated the existence of a DNA polymerase - • Three DNA polymerases in E. coli • DNA polymerase I – DNA repair and participates in synthesis of lagging strand • DNA polymerase II – DNA repair • DNA polymerase III – major polymerase involved in DNA replication.
DNA Replication is a Processive Process. • DNA Polymerase remains bound to the replication fork. • Dimer of b-subunit forms ring structure around the growing DNA chains.
DNA Polymerase also has proof reading function • The polymerization reactions have an error rate of 1 mistake for every 100,000 base pairs incorporated (1 X 10-5 errors per base) • DNA polymerase has 3’ to 5’ exonuclease function (epsilon-subunit) that recognizes base pair mismatches and removes them. • Therefore proof reading function helps eliminate errors which could lead to detrimental mutations. • However proof reading exonuclease has error rate of 1 mistake for every 100 base pairs (1 X 10-2 errors per base) • Overall error rate is 1 X 10-7 errors per base.
Stages of DNA Replication • Initiation • Elongation • Termination
Initiation of Replication • in E. coli • The replisome consists of: DNA-unwinding proteins, the priming complex (primosome) and two equivalents of DNA • polymerase III holoenzyme • Initiation: DnaA protein binds to repeats in ori, initiating strand separation and DnaB, a helicase delivered by DnaC, further unwinds. Primase then binds and constructs the RNA primer
Elongation Stage of Replication • Elongation involves DnaB helicase unwinding, SSB binding to keep strands separated. • Primase Complex Synthesizes short RNA primers. • DNA polymerase grinding away on both strands • Topoisomerase II (DNA gyrase) relieves supercoiling that remains
DNA Polymerase I/ Ligase Required to Join Okazaki Fragments • DNA polymerase I has 5’ to 3’ exonuclease activity that removes RNA primer. • Also has 5’ to 3’ DNA polymerase activity to fill in the gap. (proofreading 3’-5’ exonuclease activity) • Ligase connects loose ends. Used NAD+ in phosphoryltransfer reaction, not a redox reaction (Page 643)
Termination of Replication • Termination occurs at ter region of E. coli chromosome. • ter region rich in Gs and Ts, signals the end of replication. • Terminator utilization substance (Tus) binds to ter region. • Tus prevents replication fork from passing by inhibiting helicase activity.
DNA Replication in Eukaryotes • Occurs similarly to what occurs in prokaryotes. • Multiple origins of replication • Replication is slower than in prokaryotes. • 5 different DNA polymerases in Eukaryotes.
Eukaryotic DNA Polymerases • Alpha – Primer synthesis and DNA repair • Beta – DNA repair • Gamma – Mitochondrial DNA replication • Delta – Leading and lagging strand synthesis, and DNA repair • Epsilon – Repair and gap filling on lagging strand.
PCNA analogous to E. coli b-subunit of E. coli DNA polymerase • Proliferating cell nuclear antigen • Trimeric protein • Sliding clamp structure binds to newly synthesized DNA strand
DNA Repair • A fundamental difference from RNA, protein, lipid, etc. • All these others can be replaced, but DNA must be preserved • Cells require a means for repair of missing, altered or incorrect bases, bulges due to insertion or deletion, UV-induced pyrimidine dimers, strand breaks or cross-links • Two principal mechanisms: methods for reversing chemical damage and excision repair.
General excision-repair pathway • Excision-repair systems scan DNA duplexes for mismatched bases, excise the mispaired region and replace it
Repair of damage resulting from the deamination of cytosine • Deamination of cytosine to uracil is one of most common forms of DNA damage • DNA glycosylases cleave bases at N-glycosidic linkages. Leaving sugar-phosphate backbone. • Endonuclease identifies abscent base and sugar phosphate. • Gap then filled in by DNA polymerase and ligase.
