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6 DNA Replication and Repair

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DNA lacks the ability to perform the process of ... DNA helicase unwinds DNA strands ... DNA topoisomerase relieves mechanical strain induced by unwinding ... – PowerPoint PPT presentation

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Title: 6 DNA Replication and Repair


1
6 DNA Replication and Repair
2
DNA Replication
  • DNA lacks the ability to perform the process of
    duplication alone
  • The machinery of the cell is required
  • DNA strands are complementary
  • Each contains the information to replicate the
    alternate strand

3
DNA Replication
  • Semiconservative Replication
  • Each daughter duplex is composed of one parent
    strand and one which is newly synthesized

4
DNA Replication
5
DNA Replication
  • The machinery of replication
  • Replication forks
  • Points at which each of the replicated segments
    come together
  • Each is a site where
  • Parental double helix strands are separating
  • Nucleotide incorporated into new complementary
    strands

6
DNA Replication
  • The machinery of replication
  • Some Enzyme Classes
  • DNA helicase unwinds DNA strands
  • Single strands are stabilized by single strand
    DNA binding proteins
  • DNA topoisomerase relieves mechanical strain
    induced by unwinding
  • DNA polymerases synthesize new strands
  • DNA ligase forms new bonds between adjacent
    nucleotides

7
DNA Replication
  • The machinery of replication
  • Properties of DNA polymerases
  • Cannot initiate the formation of a new DNA strand
  • Add nucleotides to the 3 hydroxyl terminus
  • A strand is required to provide the 3OH
  • Termed a primer
  • All DNA polymerases have two requirements
  • A template DNA strand to copy
  • A primer strand to which nucleotides can be added
  • All add nucleotides from the 5 to 3 direction

8
DNA Replication
  • The machinery of replication
  • Semidiscontinuous replication
  • OH group at the 3 end of the primer reacts with
    the 5 a-phosphate of the incoming nucleoside
    phosphate
  • Polymerase molecules on both strands move in the
    5 to 3 direction
  • One strand grows toward the replication fork
  • The other grows away from the fork

9
DNA Replication
  • The machinery of replication
  • Semidiscontinuous replication
  • Strand growing towards the fork
  • Continuous additions of nucleotides to 3 end
  • Strand growing away from fork
  • Synthesized discontinuously
  • As fragments
  • Before synthesis the fork must move away
  • Once initiated the fragment grows 5 to 3
  • Subsequently each fragment is linked to the next
  • The two daughter strands are synthesized by very
    different processes

10
DNA Replication
  • The machinery of replication
  • Semidiscontinuous replication
  • Strand synthesized continuously leading strand
  • Strand synthesized discontinuously lagging
    strand
  • Okazaki fragments
  • Linked by DNA ligase

11
DNA Replication
  • The machinery of replication
  • Semidiscontinuous replication
  • Initiation not via DNA polymerase by an RNA
    polymerase a primase
  • Constructs a short primer of RNA not DNA
  • Required for both strands
  • RNA primers subsequently removed
  • Gaps filled with DNA
  • Sealed by DNA ligase

12
DNA Replication
  • The machinery of replication

13
DNA Replication
  • The machinery of replication
  • Semidiscontinuous replication
  • DNA polymerase occasionally inserts an incorrect
    nucleotide
  • DNA polymerase has multiple enzymatic sites an
    exonuclease site
  • If an incorrect nucleotide is incorporated
  • Strand tends to bulge
  • Form a single-stranded 3 terminus
  • Enters the exonuclease site
  • The polymerase stalls allowing the slow-acting
    exonuclease to excise the incorrect nucleotide

14
DNA Replication
  • The machinery of replication
  • Additional features of eurkaryotic cells
  • Incorporate nucleotides into DNA at slower rates
  • Genome replicated in small portions
  • Replicons
  • 50-300 base pairs
  • Replicons close together tend to replicate
    simultaneously
  • Timing of replication determined by
  • Activity of the genes
  • State of compaction

15
DNA Replication
  • The machinery of replication
  • Additional features of eurkaryotic cells
  • Yeast used as a model for eukaryotes
  • Isolation of sequences which promote replication
    autonomous replicating sequences (ARSs)
  • Core element 11 base pairs
  • Binding site for protein complex origin
    recognition complex (ORC)
  • Many sites where DNA replication may be initiated
  • Most inhibited by
  • Nucleosome positioning
  • Higher order chromatin structure

16
DNA Replication
  • The machinery of replication
  • Additional features of eurkaryotic cells
  • One replication per cycle control
  • The origin of replication passage through a
    series of steps
  • Origin of replication bound by ORC
  • Licensing factors bind assemble the
    prereplication complex
  • Licensing factors at least six Mcm2-Mcm7
  • Mcm proteins move with the replication fork
  • Mcm proteins are then displaced from DNA but
    remain in nucleus
  • Mcm proteins cannot reassociate with an origin of
    replication which has already fired

17
DNA Replication
  • The machinery of replication
  • Additional features of eurkaryotic cells
  • Chromatin structure
  • Nucleosomes and the replication fork
  • Histones H3H4 tetramers remain intact and are
    distributed between the daughter duplexes
  • Old and new H3H4 tetramers found on each duplex
  • H2A/H2B dimers separate and bind randomly to
    H3H4 tetramers already in place

18
DNA Repair
  • DNA is susceptible to damage
  • Ionizing radiation breaks the backbone of the
    structure
  • Metabolites alter base structure
  • UV Radiation adjacent pyrimidines dimerise
  • Mutations affect germ cells
  • modified trait passed on
  • Mutations affect somatic cells
  • malignant transformation
  • aging

19
DNA Repair
  • DNA is susceptible to damage
  • Huge variety of repair mechanisms to repair DNA
  • Proteins patrol DNA searching for alterations and
    distortions
  • Most repair systems excise the damaged section
  • DNA duplex each strand contains the information
    required for constructing its partner

20
DNA Repair
  • Nucleotide Excision Repair (NER)
  • A cut and patch mechanism
  • Removes bulky lesions
  • Pyrimidine dimers
  • Chemical groups attached
  • Two pathways
  • Transcription coupled pathway
  • Global pathway

21
DNA Repair
  • Base Excision Repair (BER)
  • Initiated by a DNA glycosylase
  • Recognizes alteration
  • Removes base by cleavage of glycosidic bond
    between the base and deoxyribose
  • Several specific types of DNA glycosylase for
    specific modifications
  • Uracil formed from hydrolytic removal of amino
    group of cytosine
  • Formation of 8-hydroxyguanine by oxygen free
    radicals
  • Formation of 3-methyl adenine
  • Following removal of the base remaining
    deoxyribose phosphate is removed by endonuclease
    / phosphodiesterase
  • Gap filled via DNA polymerase and sealed by DNA
    ligase

22
DNA Repair
  • Base Excision Repair (BER)

23
DNA Repair
  • Mismatch Repair
  • Mismatch causes distortion of helix
  • Recognized by a repair enzyme
  • Repair system recognizes newly synthesized strand
  • New strand recognized by presence of breaks

24
DNA Repair
  • Postreplication Repair
  • Blockage of DNA polymerase progression by
    pyrimidine dimers and other lesions
  • Replication can be restarted by synthesis of an
    Okazaki fragment
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