DNA Replication Lectures 3-4 BIOL2010 PDF

Summary

These lecture notes cover DNA replication, focusing on processes in E. coli. It examines the composition and structure of DNA, compares DNA synthesis and replication, explores problems unique to E. coli replication, and further investigates how eukaryotic and viral DNA replication differs. Includes visuals.

Full Transcript

BIOL2010

DNA replication
Lectures
3-4

Dr M.L.Bellamy
Overview

1) Composition/structure of DNA
2) DNA synthesis vs DNA replication
3) Problems and solutions in E.coli
4) The 3 steps in replication
5) Differences in eukaryotes/viruses
DNA synthesis PCR
Only 1 enzyme required: Taq (DNA Polymerase)
+ dNTPs (ATP,CTP,GTP,TTP), Template DNA, primers

Heat to 95°C (Denaturing)
Cool to 55°C (Annealing)
Heat to 72°C (Extending)
DNA synthesis Escherichia coli
Only 1 enzyme required: DNA polymerase III
+ dNTPs (ATP,CTP,GTP,TTP), Template DNA, primers
But to replicate the entire chromosome:
+ Helicase
+ Topoisomerases
+ Primase
+ SSB proteins
+ DNA Polymerase I
+ DNA ligase
+…
DNA synthesis Escherichia coli
Bacterial cells contain multiple
DNA polymerases
Named in order of discovery, not importance
Pol I: DNA repair and replication
Pol II: DNA repair
Pol III: Principal DNA replication enzyme
Pol IV: DNA repair
Pol V: DNA repair
All synthesize DNA 5’→3’
DNA synthesis Escherichia coli
Bacterial cells contain multiple
DNA polymerases
Comparison of Pol I and Pol III:
Pol I: one gene,109 kDa, ~400 copies per cell
~10 nt/s, 20-100 nt at a time
→ Too slow (>100 hours per genome)

Pol III: 22 genes,106 kDa,~10 copies per cell
~1600 nt/s, >50,000 nt at a time
→ 40 minutes per genome (4.6 x 106 nt)
DNA replication E.coli
How can we determine which genes
(proteins) are important?
Simple knock-outs will be lethal
Temperature-sensitive mutants allow proteins
to be switched on or off by changing the temperature
e.g. protein works at 20°C, but not 37°C
Allow cells to begin replication, then deactivate
one protein to see the effect
1) Quick stop mutants: Replication immediately stops
2) Slow stop mutants: Current round of replication
finishes, but a new one can’t start
DNA replication E.coli
Gene Function
dnaA Initiation at oriC
dnaG primase (primer synthesis)
dnaI Initiation at oriC
dnaL DNA ligase
dnaN Pol III β subunit (sliding clamp)
dnaQ Pol III ε subunit (proofreading)
dnaS UTPase
dnaX Pol III holoenzyme γ subunit (binds ATP)
dnaZ Pol III τ subunits (dimerization)
holA Pol III δ subunit
holB Pol III (δ’ subunit)
holC Pol III (χ subunit)
holD Pol III (ψ subunit)
holE Pol III (θ subunit)
gyrA DNA gyrase α subunit
gyrB DNA gyrase β subunit
ssb single strand DNA binding protein
polA Pol I
polB Pol II
lig DNA ligase
rep ATP-dependent helicase
DNA replication Overview
1. DNA synthesis is simple
2. DNA replication is complex
Overview

1) Composition/structure of DNA
2) DNA synthesis vs DNA replication
3) Problems and solutions in E.coli
4) The 3 steps in replication
5) Differences in eukaryotes/viruses
DNA replication Problems
1. Strands being coiled (topology)
2. Circular DNA molecules (topology)
3. Antiparallel strands (polarity & topology)
4. Mutations/errors (fidelity)

Need solutions that
allow accurate
synthesis, without
slowing down the overall
process too much.
DNA replication Problem 1
Strands being coiled (topology)

5’

3’

DNA strands are plectonemically coiled
→ have to be unwound to separate them
DNA replication Problem 1
"Since the two chains in our
model are intertwined, it is
essential for them to untwist if
they are to separate….
Although it is difficult at the
moment to see how these
processes occur without
everything getting tangled,
we do not feel that this
objection will be insuperable."
DNA replication Problem 1
Helicases can separate and
unwind the duplex using
ATP hydrolysis (3 bp/ATP)
Hexamer ring surrounds a
single DNA strand.

Conformational changes in
the helicase pull on the DNA
strand, separating it from its
partner.
 DNA replication Problem 1
Helicases move towards the 3’ end of the strand
they are clamped to. One on each strand.

5’ 3’

3’ 5’

Pol III can synthesize ~1600 nt/s
There are ~10 nt per turn
→ Helicases must rotate DNA at ~10,000rpm!
DNA replication Problem 1
Helicases separate and unwind the two DNA
strands, creating a replication bubble.

REPLICATION FORKS

Uncoiling at one part of the duplex, creates
mechanical strain in the rest of the molecule
DNA replication Problems
1) Strands being coiled (topology)
2) Circular chromosomes (topology)
Unwind part of duplex

Torsional strain elsewhere in duplex

Supercoiling
DNA replication Problem 2
Supercoiling
Relaxed Supercoiled
DNA replication Problem 2
Supercoiling
DNA topology can be described by the equation:
Lk = T + W
Lk = Linking number (fixed value in circular DNA)
T = Twist – number of duplex turns (↑ with more nt)
W = Writhe – number of duplex self-crossings
Twist = N/h (Number of bp/helical repeat)
e.g. pBR322 plasmid → 4361/10.5 = 415
e.g. E.coli genome → 4.6 x 106/10.5 = 440,000
N can’t change, but h can (over- or under-winding)
DNA replication Problem 2
Supercoiling
DNA topology can be described by the equation:
Lk = T + W
Lk = Linking number (fixed value in circular DNA)
T = Twist – number of duplex turns (↑ with more nt)
W = Writhe – number of duplex self-crossings
The relaxed form, where W=0, is called Lk0
If Lk > Lk0 then there is +ve supercoiling (+W)
If Lk < Lk0 then there is –ve supercoiling (-W)
DNA replication Problem 2
Supercoiling

W=2 RELAXED W=-2
W=0

POSITIVE (LEFT) NEGATIVE (RIGHT)
DNA is overwound DNA is underwound
DNA replication Problem 2
Supercoiling

1

2
525 bp Negatively
supercoiled
3

N h
→(525/11.4) 4
(525/10.5)
DNA replication Problem 2
Supercoiling
Superhelical density has the equation:

σ = (Lk-Lk0)/Lk0 = ΔLk/Lk0
This is a normalised way of expressing how
supercoiled a piece of DNA is, removing the
effect of chain length.
In relaxed DNA, σ = 0
Sign indicates type of supercoiling, as before
DNA replication
Supercoiling (-ve)
Biological significance
Purified cellular DNA is negatively supercoiled
σ = -0.06 (eukaryotes and prokaryotes)
Conversion of –ve Writhe to less Twist aids
unwinding for transcription and replication
Unwound
↑h

-ve W
DNA replication
Supercoiling (-ve)
Eukaryotic DNA is –vely supercoiled
around histones when forming a
nucleosome
DNA replication Problem 2
Supercoiling (+ve)
Biological significance
Helicase-based unwinding→overwinding elsewhere
Overwinding will resist replication fork movement
Lk can’t change to relieve the stress without breaking
the phosphodiester bond
→ Positive supercoils form
Also applies to very long linear DNA

Local overwinding
DNA replication Problem 2
Supercoiling (+ve)
Biological significance
↑h
Unwound

Relaxed Overwound
↓h

+vely supercoiled
↑W
+ve supercoiling needs to be removed for
replication to continue.
 DNA replication Problem 2
Supercoil removal
Specific enzymes that act on supercoils were first
discovered by Wang and Gellert (1970s).
Topoisomerases cause a change in Lk.

Type I Cleave backbone of one strand
Type II Cleave backbone of both strands

→ DNA then twists or untwists to get back to h=10.5
→ DNA backbone is resealed after manipulation
 DNA replication Problem 2
Supercoil removal LK ↑↓ by 1
Topoisomerase type I mechanism

1) Phosphodiester bond is transferred to Tyr residue on
enzyme, breaking one DNA strand
2) The other strand passes through the gap
3) The phosphodiester bond is transferred back to DNA,
reforming the backbone on the other side

→ DNA moves one step towards the relaxed form
 DNA replication Problem 2
Supercoil removal LK ↑↓ by 2
Topoisomerase type II mechanism (ATP-dependent)

1) Both strands cleaved
2) A section of duplex is
passed through the gap
3) Gap resealed

Duplex may be from the
same DNA molecule,
or another
DNA replication Problem 2
Supercoil removal LK ↓ by 2
Topoisomerase type II mechanism (ATP-dependent)
Bacteria have a unique type II topoisomerase
DNA gyrase
Can introduce a –ve supercoil, usually by converting
a +ve supercoil

→ Vital for replication fork progression in replication

→ A good antibiotic target
DNA replication Problem 2
Supercoil removal LK ↓ by 2
Topoisomerase type II mechanism DNA gyrase

Horizontal
section cut.
W 5’-P linked
to Tyr on A
subunit

Reform
backbone Vertical section
W passed through
DNA topology
Supercoiling
Supercoiled DNA runs faster than linear DNA in an
agarose gel

Relaxed/nicked
DNA replication Problem 2
Bidirectional synthesis

Theta replication Side view
(Greek letter θ)
DNA replication Problem 2
Catenanes
When circular DNA molecules are replicated, the two
daughter rings are interlocked and form a catenane

Topoisomerase IV
(Type II)

Cleave, pass through
and re-seal (decatenation)
DNA replication Problem 3
Antiparallel strands
Best solution: Two polymerases, one for each direction
5 3
’ ’
3 5 5
’ ’ ’
5 3 3
’ ’ ’
3 5
’ genes needed
→ Extra ’
→ Mutation rate ↑100x
DNA replication Problem 3
All DNA polymerases synthesize DNA by adding to
the 3’ end of an existing ds region (primer)

5 3’
’
3 3 5
’ ’ ’
5 3 3
’ ’ ’
3 5
’ ’
Works, but requires complete strand separation before synthesis
can start on upper strand
→ wasted time (separation time + synthesis time)
DNA replication Problem 3
All DNA polymerases synthesize DNA by adding to
the 3’ end of an existing ds region (primer)
→ Loop back the 5’→3’ (lagging) strand to correct direction
5’
3’

Unwind start of duplex

5’
5’ 3’
5’ 5’
5’ 3’
3’

Synthesis of both strands can occur simultaneously, but
semi-discontinuously → fragmented DNA
DNA replication Consequences
End result of semi-discontinuous replication is two,
non-identical dsDNA molecules
5’
3’
LEADING (1 primer)

LAGGING (multiple primers)
5’
3’

Okazaki fragment

Chromosome is replicated, but lagging strand is unfinished:
‘Nicks’ in the new backbone, because Pol III can’t join
fragments. Nick = broken phosphodiester bond. Not a gap.
RNA is present in the DNA
DNA replication Okazaki fragments

Not completely DNA
Primer is RNA
RNA DNA
~10 bp ~2000 bp

We know this because tiny fragments
are left over after using DNAse on
Okazaki fragments
 DNA replication Okazaki fragments

Removal of RNA
Okazaki fragments have RNA at their 5’ end and a
nick at their 3’ end
LAGGING STRAND(multiple primers)
5’
3’

Pol I binds to nicks; Pol III does not
Pol I can remove nt ahead of it; Pol III cannot
 DNA replication Okazaki fragments

Removal of RNA
Pol I binds to nicks
5’
3’

RNA primers removed
by Pol I 5’-3’ exonuclease

Pol I detaches after ~100 bp
→new nick left behind
3’
5’

Pol I causes nick translation
DNA replication Okazaki fragments

Removal of RNA
Alternatively: 3’
5’

RNAse H degrades RNA

Pol I fills in gap

3’
5’
 DNA replication Okazaki fragments

Removal of nicks
LAGGING
5’
3’

DNA ligase seals DNA
nicks (can’t do RNA-DNA)

LAGGING
DNA replication Okazaki fragments

Okazaki investigated the synthesis of DNA
over time using radioactivity
E.coli culture infected with T4 bacteriophage

Add 3H-TTP (tritiated thymidine)

New phage DNA strands will be radioactive
Alkaline lysis (pH13)
Map out sizes of radioactive ssDNA over time
DNA replication Okazaki fragments

Okazaki investigated the synthesis of DNA
over time using radioactivity 3H-TTP
Incr
eas
incr ing
eas time
ing ,
size
DNA replication Okazaki fragments
Sizes mapped with density centrifugation

~2000bp

Full length

2s 5s 10s 60s

→ Size of radioactive ssDNA doesn’t simply increase
smoothly over time. Short pieces are always present.
DNA replication Okazaki fragments

Explanation:
Short fragments are repeatedly being made
on the lagging strand as new sections of DNA
are unwound
After a few seconds they are joined to each
other and to non-radioactive pieces that had
already been synthesized→size jumps
DNA replication Okazaki fragments

Evidence:
1) Pulse/chase experiments
After 2s the 3H-TTP
is removed and
“chased” with normal ~2000bp
TTP
→ Radioactivity
all moves down Full length
the tube
2s 60s
DNA replication Okazaki fragments

Evidence: P
OH
2) DNA ligase mutants
DNA ligase seals “nicks” in
the backbone and can join
Okazaki fragments to each
other. ATP consumed.
DNA replication Okazaki fragments

Evidence:
2) DNA ligase mutants
Short fragments still
made, but they remain
~2000bp
as fragments.
→ Lagging strand can’t
be “finished”
Full length

2s 60s