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The Molecular Basis for Inheritance

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Little was known about nucleic acids. A key factor in determining the identity of the genetic material was the choice ... Telomerase catalyzes lengthening of telomeres ... – PowerPoint PPT presentation

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Title: The Molecular Basis for Inheritance


1
Chapter 16
  • The Molecular Basis for Inheritance

2
  • Characteristics of Genetic Material
  • replication
  • storage
  • expression
  • variation
  • Genetic Material Protein or Nucleic Acid?

3
  • Evidence Favoring Proteins
  • Great specificity of function
  • Little was known about nucleic acids
  • A key factor in determining the identity of the
    genetic material was the choice of appropriate
    experimental organisms
  • The role of DNA in heredity was first worked out
    by studying microbes
  • Bacteria and viruses

4
  • Evidence Favoring DNA
  • Transformation Studies Griffith then Avery,
    McLeod and McCarty
  • Hershey and Chase
  • Indirect evidence from eukaryotes
  • Recombinant DNA technology has provided empirical
    evidence that DNA is the genetic material in most
    organisms. A few organisms possess RNA as the
    genetic material.

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  • Additional evidence came from studies using a
    bacteriophage
  • virus that infects bacteria
  • Phages are widely used as research tools in
    molecular genetics
  • Viruses are much simpler than cells
  • little more than DNA enclosed by a protein coat
  • To reproduce, a virus must infect a cell and take
    over the cells metabolic machinery

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  • Injected DNA provides genetic information that
    makes the cells produce new viral DNA and
    proteins, which assemble into new viruses.
  • Provided evidence that nucleic acids, rather than
    proteins, are the hereditary material, at least
    for viruses

9
  • Indirect Evidence From Eukaryotes That DNA Is the
    Genetic Material of Cells
  • Prior to mitosis, a eukaryotic cell exactly
    doubles its DNA content, and during mitosis, this
    DNA is distributed exactly equally to the two
    daughter cells
  • Nucleic Acids DNA and RNA
  • Polymers of nucleotides
  • Each nucleotide has
  • phosphate group
  • pentose sugar ribose in RNA and deoxyribose in
    DNA
  • nitrogenous base purines (AT) and pyrimidines
    (CG)

10
  • Chargaff found a peculiar regularity in the
    ratios of nucleotide bases
  • the number of adenines approximately equaled the
    number of thymines, and the number of guanines
    approximately equaled the number of cytosines
  • In humans the bases are present in these
    percentages
  • A 30.9 and T 29.4
  • G 19.9 and C 19.8
  • Remained unexplained until the discovery of the
    double helix
  • Chargaffs rules

11
  • Structure of DNA Watson and Crick double helix
  • How could the structure of DNA could account for
    its role in inheritance.
  • The arrangement of covalent bonds in a nucleic
    acid polymer was well established
  • researchers began to focus on discovering the
    three-dimensional structure of DNA

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  • In April 1953, Watson and Crick surprised the
    scientific world with their molecular model for
    DNA the double helix, which has since become the
    symbol of molecular biology.
  • In a second paper that followed their
    announcement of the double helix, Watson and
    Crick stated their hypothesis for how DNA
    replicates

14
  • Two major sources of information used by Watson
    and Crick to determine DNA structure
  • Base composition analysis conducted by Chargaff
  • X-ray diffraction studies conducted by Ashbury
    and Franklin
  • Crystallographers use mathematical equations to
    translate patterns into information about the
    three-dimensional shapes of molecules

15
  • Complementary base pairs
  • Adenine and guanine are purines, while cytosine
    and thymine are pyrimidines
  • Watson tried bases paired like-with-like--for
    example, A with A and C with C but this model did
    not fit the X-ray data
  • A purine-purine pair is too wide and a
    pyrimidine-pyrimidine pair too narrow to account
    for the diameter of the double helix
  • The solution is to always pair a purine with a
    pyrimidine
  • The Watson-Crick model explained Chargaffs rules

16
  • Features of the Watson-Crick Model of DNA
  • 1. Two long polynucleotide chains coiled around
    a central axis, forming a right-handed double
    helix
  • 2. The two chains are antiparallel
  • 3. Bases are flat, lying perpendicular to
    central axis, stacked on top of each other 3.4
    angstroms
  • 4. Nitrogenous bases on opposite chains are
    paired as a result of hydrogen bonding
  • 5. Each complete turn of the helix is 34
    angstroms
  • 6. Alternating larger major grooves and smaller
    minor grooves.
  • 7. Diameter is 20 angstroms

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  • DNA Replication
  • Semi-conservative Replication
  • Origin of replication
  • Replication fork
  • Template

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  • The two DNA strands are antiparallel
  • At the 3' end, a hydroxyl group
  • The 5' end terminates with the phosphate group
  • During the process of replication, the new
    nucleotides are added to the 3' end of the
    growing strand

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  • Enzymes involved in DNA replication
  • Helicase
  • Primase
  • DNA Polymerase III
  • DNA Polymerase I
  • Topoisomerase
  • DNA ligase
  • Single-strand binding proteins

24
  • DNA synthesis in prokaryotes
  • Step 1. Unwinding
  • Step 2. Initiation
  • Step 3. Elongation of leading and lagging strands
  • Step 4. Completion of lagging strand
  • Okazaki fragments joined
  • Step 5. Proofreading

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  • Mismatched nucleotides sometimes evade
    proofreading
  • May arise after DNA synthesis is completed--by
    damage to a nucleotide base
  • Nucleotide excision repair
  • Segment cut out (excised) by nuclease and the gap
    is filled in with correct nucleotides by DNA
    polymerase and ligase

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  • In Eukaryotes
  • synthesis originates in multiple sites
  • more DNA polymerase
  • synthesize entire genome faster
  • DNA polymerases are different
  • Contain telomeres at the ends of DNA

30
  • Add nucleotides only to the 3' end which provides
    no way to complete the 5' ends of daughter DNA
    strands
  • produce shorter and shorter DNA molecules
  • Prokaryotes avoid this with circular DNA
  • Eukaryotes special nucleotide sequences called
    telomeres at the ends that do not contain genes
  • After multiple generations, organisms need a way
    to restore shortened telomeres
  • Telomerase catalyzes lengthening of telomeres

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