Chapter 11 Nucleic Acid Structure and DNA Replication PDF

Summary

This document is a chapter on nucleic acid structure and DNA replication. It covers the basic structure and function of DNA along with its replication model. It is intended for an academic audience, likely an undergraduate course in biology.

Full Transcript

CHAPTER 11

NUCLEIC ACID
STRUCTURE AND
DNA REPLICATION

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 Genetic material
Genetic material must be able to:. Contain the information necessary to construct an entire organism. Pass from parent to offspring and from cell to cell during cell division. Be accurately copied. Account for the known variation within and between species. Late 1800s scientists postulated a biochemical basis. Researchers became convinced chromosomes carry genetic information. 1920s to 1940s expected the protein portion of chromosomes to be the genetic
material

Genetic Material – DNA or Protein?

What did scientists do to figure out if it is DNA or Protein?
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Genetic Material: DNA or Protein?The answer!
The Griffith transformation Experiment:
Injection into mice of the pneumoniae bacteria Streptococus pneumoniae

Experiment 1:
2 strains were injected:

S strain: produce Shiny and smooth
colonies. S strain is encapsulated

R Strain: produce Rough appearance
colonies

Observations:

S strain injected to mice: mice died
(virulent),
Virulence due to the capsule

R strain injected to mice: mice did not
die (non-virulent)
 Experiment 2:
Observations:

Living S strain were
recovered from body

Substance necessary for
virulence passed from dead
S strain to living R strain
Bacteria

R strain bacteria was
transformed

Conclusion:
Genetic material from the heat-killed type S bacteria had been transferred to the living
type R bacteria. The transforming substance passed was genetic material.

This trait gave them the capsule and was passed on to their offspring
 Levels of DNA structure
1. Nucleotides are the building blocks of DNA
(and RNA).

2. Nucleotides polymerizes to form the strand
of DNA (or RNA)

3. Two strands form a double helix.

4. In living cells, DNA is associated with an
array of different proteins to form
chromosomes.

5. A genome is the complete complement of
an organism’s genetic material.

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Nucleotides
3 components:
- Phosphate group
- Pentose sugar
- Nitrogenous base
DNA
3 components:
Phosphate group
Pentose sugar: Deoxyribose
Nitrogenous base:
Purines
Adenine (A), guanine (G)
Pyrimidines
Cytosine (C), thymine (T),
RNA
3 components:
Phosphate group
Pentose sugar: Ribose
Nitrogenous base
Purines
Adenine (A), guanine (G)
Pyrimidines
Cytosine (C), uracil (U) 6
Conventional numbering system. Sugar carbons 1’ to 5’. Base attached to 1’. Phosphate attached to 5’

DNA strands. Nucleotides covalently bonded. Phosphodiester bond: phosphate group links 2 sugars. Phosphates and sugars from backbone. Bases project from backbone. Directionality- 5’ to 3’. 5’ – TACG – 3’

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DNA is:
Double stranded
Helical
Sugar-phosphate backbone
Bases on the inside
Stabilized by hydrogen bonding
Base pairs with specific pairing

AT/GC or Chargoff’s rule
A pairs with T
G pairs with C

10 base pairs per turn

2 DNA strands are complementary
5’ – GCGGATTT – 3’
3’ – CGCCTAAA – 5’

2 strands are antiparallel
One strand 5’ to 3’
Other stand 3’ to 5’
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 Space-filling model shows grooves
 Major groove
Where proteins bind
 Minor groove

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 DNA Replication
3 different models for DNA replication proposed in
late 1950s:
- Semiconservative
- Conservative
- Dispersive

Newly made strands are daughter strands

Original strands are parental strands

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 DNA Replication
During replication 2 parental strands separate
and serve as template strands

New nucleotides must obey the AT/GC rule

End result 2 new double helices with same base
sequence as original

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 DNA Replication
- Origin of replication
Site of start point for replication

- Bidirectional replication
Replication proceeds outward in opposite
directions
-Bacteria have a single origin
-Eukaryotes require multiple origins

- Origin of replication provides an opening called a
replication bubble that forms two replication forks
DNA replication occurs near the fork

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 DNA Replication
- Synthesis begins with a primer and proceeds 5’ to 3’
- Leading strand made in direction fork is moving.
Synthesized as one long continuous molecule
- Lagging strand made as Okazaki fragments that
have to be connected later

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https://www.youtube.com/watch?v=TNKWgcFPHqw
 DNA Replication
DNA helicase
Binds to DNA and travels 5’ to 3’ using
ATP to separate strand and move fork
forward
DNA topoisomerase
Relives additional coiling ahead of
replication fork
Single-strand binding proteins
Keep parental strands open to act as
templates
DNA polymerase
Covalently links nucleotides
Deoxynuceloside triphosphates
Free nucleotides with 3 phosphate
groups
Breaking covalent bond to release
pyrophosphate (2 phosphate groups)
provides energy to connect adjacent
nucleotides

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 DNA Replication
DNA polymerase has 2 enzymatic features
to explain leading and lagging strands

1. DNA polymerase unable to begin DNA
synthesis on a bare template strand
- DNA primase must make a short RNA
primer
- RNA primer will be removed and replaced
with DNA later

2. DNA polymerase can only work 5’ to 3’

In the leading strand
- DNA primase makes one RNA primer
- DNA polymerase attaches nucleotides in a 5’
to 3’ direction as it slides forward
In the lagging strand
- DNA synthesized 5’ to 3’ but in a direction
away from the fork
- Okazaki fragments made as a short RNA
primer made by DNA primase at the 5’ end
and then DNA laid down by DNA polymerase
- RNA primers will be removed by DNA
polymerase and filled in with DNA
- DNA ligase will join adjacent DNA fragments 16
 The family of DNA polymerases
3 important issues for DNA polymerase are speed, fidelity, and completeness
Nearly all living species have more than 1 type of DNA polymerase
Genomes of most species have several DNA polymerase genes due to gene duplication

E. coli has 5 DNA polymerases:. DNA polymerase III with multiple subunits responsible for majority of replication. DNA polymerase I has a single subunit whose job is to rapidly remove RNA primers and fill

in DNA. DNA polymerases II, IV and V are involved in DNA repair and replicating damaged DNA
- DNA polymerases I and III stall at DNA damage
-DNA polymerases II, IV and V don’t stall but go slower and make sure replication is

complete

Humans have 12 or more DNA polymerases. Designated with Greek letters. DNA polymerase α has its own built in primase subunit. DNA polymerase δ and ε extend DNA at a faster rate. DNA polymerase γ replicates mitochondrial DNA. When DNA polymerases α, δ or ε encounter abnormalities they may be unable to replicate. Lesion-replicating polymerases may be able to synthesize complementary strands to the
damaged area
https://www.youtube.com/watch?
v=TNKWgcFPHqw
 Specialized form of DNA replication only in eukaryotes in the telomeres
Telomeres are a series of repeat sequences within DNA and special proteins
Telomere at 3’ does not have a complementary strand and is called a 3’
overhang
DNA polymerase cannot copy the tip of the DNA strand with a 3’ end
No place for upstream primer to be made
If this replication problem were not solved, linear chromosomes would become
progressively shorter

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 Telomeres and aging
Body cells have a predetermined life span

Skin sample grown in a dish will double a finite
number of times
Infants, about 80 times
Older person, 10 to 20 times

Senescent cells have lost the capacity to divide

Progressive shortening of telomeres correlated with
cellular senescence

Telomerase present in germ-line cells and in rapidly
dividing somatic cells

Telomerase function reduces with age

Inserting a highly active telomerase gene into cells in
the lab causes them to continue to divide
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 Telomeres and cancer
When cells become cancerous they divide uncontrollably

In 90% of all types of human cancers, telomerase is found at high levels

Prevents telomere shortening and may play a role in continued growth of cancer cells

Mechanism unknown

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