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Structure, Replication and Recombination of DNA

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Title: Structure, Replication and Recombination of DNA


1
Structure, Replication and Recombination of DNA
2
Information Flow From DNA
DNA
3
DNA Structure
Primary Structure Chain of Nucleotides
Secondary Structure Double Helix
4
DNA Structure
Nucleotide building block of DNA
  • Three components of a nucleotide
  • 1. Nitrogen-containing base
  • purine or pyrimidine
  • 2. 5-carbon sugar
  • 3. Phosphate group

5
DNA Structure
Purine bases Adenine (A) Guanine (G)
Pyrimidine bases Cytosine (C) Thymine (T)
5-carbon sugar Deoxyribose
Phosphate PO4
6
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7
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8
Chemical Bonding
Covalent Bond Strong Atoms Share Electrons Formation of a Nucleotide
Hydrogen Bond Weak Atoms Share a Hydrogen Pairing of Nucleotide Bases
9
Hydrogen bonds hold pairs of bases together.
10
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11
DNA Secondary Structure The Double Helix
  • Two polynucleotide chains are wound together
  • Bases are located inside the helix
  • Sugar-phosphate groups are on the outside as a
    backbone
  • Bases are arranged like rungs on a ladder,
    perpendicular to the backbone

12
DNA Secondary Structure The Double Helix
  • Hydrogen bonding between bases holds the chains
    together
  • A pairs with T
  • G pairs with C
  • Polynucleotide chains have opposite polarity
  • One is 5 ? 3
  • other is 3 ? 5
  • 10 base pairs per turn of the helix

13
DNA Replication An Overview
14
DNA Replication
DNA replication is semiconservative. Each strand
is used as a template to produce a new strand.
AGCTAGCTAGCT TCGATCGATCGA
TCGATCGATCGA new
AGCTAGCTAGCT new
15
DNA Replication
DNA replication requires 1. DNA
polymerase, an enzyme that adds
nucleotides in a 5?3 direction. 2.
Nucleoside triphosphates 3. Energy release
of diphosphate
5A G C T 3
A 5
G
C
3 T
G
C
T 3
5 A
3T C G A5
16
Origin of Replication
DNA replication begins at a replication origin
and proceeds bidirectionally, creating two
replication forks for each origin. Eukaryotic
chromosomes have multiple origins of replication.
17
Continuous and Discontinuous Synthesis
DNA Polymerase builds a new strand in a 5?3
direction. This leads to continuous synthesis on
the strand oriented 3?5 and discontinuous on
the strand oriented 5?3.
18
Steps in DNA Replication (Bacterial)
  • Initiation
  • Initiator Proteins bind to replication
    origin and cause a small section to unwind.

19
Steps in DNA Replication (Bacterial)
  • Unwinding
  • Helicase molecules further unwind helix.
  • Single-stranded binding proteins keep helix
    from reforming.DNA gyrase reduces supercoils
    ahead of replication fork.

20
Steps in DNA Replication (Bacterial)
  • Elongation
  • Primase synthesizes a short RNA strand
    primer.
  • DNA polymerase III adds nucleotides to the
    primer in a 5?3 direction.

21
Steps in DNA Replication (Bacterial)
  • Elongation
  • A single primer is required for leading
    strand replication. On the lagging strand, a new
    primer is used at the start of each Okasaki
    fragment.

22
Steps in DNA Replication (Bacterial)
  • Elongation
  • DNA polymerase I replaces primer RNA with
    DNA nucleotides. DNA ligase seals gaps in
    sugar-phosphate backbone.

23
Steps in DNA Replication (Bacterial)
  • Termination
  • Termination occurs when two replication
    forks meet.
  • E. coli cells have a protein called Tus
    that binds to termination sequences and blocks
    helicase movement.

24
Accuracy of DNA Replication
  1. Nucleotide Selection
  2. DNA proofreading 3?5 exonuclease activity of
    DNA polymerase
  3. Mismatch Repair repair enzymes

25
Modes of Replication
26
Differences for Eukaryotic DNA Replication
  • Replication Licensing Factor attaches to each
    origin, initiator protein only recognizes
    licensed origins
  • Multiple polymerases function in replication,
    recombination, repair
  • Alpha synthesizes primer and a short stretch of
    DNA
  • Delta continues replication on the lagging
    strand
  • Epsilon continues replication on the leading
    strand
  • Topoisomerase enzymes relax supercoils

27
Replication at the Ends of Linear Chromosomes
  • Removal of the primer at the end of a linear
    chromosome leaves a gap
  • Linear chromosomes tend to shorten at the
    telomeres over repeated cycles of replication

28
Telomerase Extends the Telomeres 3 End
  • Telomerase is an enzyme composed of both protein
    and RNA
  • RNA portion binds to the overhanging 3 end of
    the telomere, providing a template for elongation
  • Mechanism for replicating the complementary
    strand is uncertain

29
Recombination
30
Holliday Model of Recombination
  • Single strand breaks occur at the same
    position on homologous DNA helices.
  • Single-stranded ends migrate into the
    alternate helix.

31
Holliday Model of Recombination
  • Each migrating strand joins to the existing
    strand, creating a Holliday junction.
  • Branch point can migrate, increasing the
    amount of heteroduplex DNA.

32
Holliday Model of RecombinationResolving the
Holliday Intermediate
  • Separation of the duplexes requires cleavage
    in either the horizontal or vertical plane.

33
Holliday Model of RecombinationResolving the
Holliday Intermediate
  • Cleavage in the vertical plane, followed by
    rejoining of nucleotide strands, produces
    crossover recombinant products.

34
Gene Conversion Occurs with Repair of
Heteroduplex DNA
35
Gene Conversion Occurs with Repair of
Heteroduplex DNA
Gene Conversion can lead to abnormal genetic
ratios.
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