chapter 2: dna synthesis (replication) required reading: stryer’s biochemistry 5 th edition p....
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Chapter 2: DNA Synthesis (Replication)
Required reading: Stryer’s Biochemistry 5th edition p. 127-128, 750-754, 759-766, 768-773(or Stryer’s Biochemistry 4th edition p. 88-93, 799-809, 982-986, 809-814)
Normal recitation time: Thursdays 11-12, B-185 PWB
Exam: Wed., December 1 Proposed recitation time for this exam: Tue, Nov. 30, 11-12
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DNA Polymerization Reaction
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E. coli DNA Polymerases
Characteristic Pol I Pol II Pol III Mol. Weight (Da) 103,000 88,000 900,000
Number of polypeptides
1 4 10
Polymerase 5' 3' yes yes yes rate (nucleotides/sec) 16-20 7 250-1000 3' 5' exonuclease yes yes yes 5' 3' exonuclease yes no no
# molecules/cell 400 100 10 function Primer removal,
gap filling unknown Major replicative
polymerase
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N C
E. coli DNA Polymerase I
Klenow Fragment
Polymerase3' 5‘ Nucl. 5' 3' Nucl.
36 kDa 67 kDa
• a large cleft for binding duplex DNA • flexible "finger" and "thumb" regions for positioning DNA duplex
and the incoming dNTP • polymerase site located in the "palm" region • 3' 5' and 5'- nuclease catalytic sites
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Typical Polymerase Structure: E. Coli Pol I
thumb
palm
fingers
exonuclease
polymerase
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Polymerase with bound DNA
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Mechanism of phosphoryl transfer
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Polymerase fidelity mechanisms
1. Watson-Crick base pairing between the incoming dNTP and the corresponding base in the template strand.
2. H-bond formation between the minor groove of the new base pair and the amino acids in the polymerase active site.
3. Proofreading mechanism via 3' exonuclease that excises incorrectly added nucleotides.
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1. Correct Watson-Crick base pairing between the incoming dNTP and the corresponding base in the template strand induces conformational change required for polymerization reaction:
Thumb
Fingers
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2. H-bond formation between the minor groove of the new base pair and amino acids in the polymerase active site:
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All Watson-Crick base pairs contain two H-bond acceptors at the same sites of the
minor groove
HN
N
O
O
NN
N
NNH 2
A•TG•C
NH
N
NO
NH 2
NN
N
H2N
O
NH
N
N
O
NH2
N
NN
2NH2
O
C:G
HNN
O
O
N
N
N
NHN2
T:A
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3. 3’-Exonuclease Proofreading function of DNA polymerases excises incorrectly added nucleotides.
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Fidelity of DNA Polymerization: Absolutely Essential!!
Error Probability = Polymerization error (10-4)
X 3' 5' Nuclease error (10-3)
= 10-7 (1 in 10,000,000 nt)
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DNA Polymerization Has Three Stages
1) Initiation
2) Priming
3) Processive Synthesis
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Problems to overcome: DNA Polymerization
1. The two strands must be separated, and local DNA over-windingmust be relaxed. The single stranded DNA must be prevented fromre-annealing and protected from degradation by cellular nucleases.
2. Both antiparallel strands must be synthesized simultaneously inthe 5’ 3’ direction.
3’
5’
3. A primer strand is required.
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DNA Polymerization: Initiation
• DNA replication begins at a specific site.
• Example: oriC site from E. coli.
• 245 bp out of 4,000,000 bp
• contains a tandem array of three 13-mers; GATCTNTTNTTTT
• Synthesis takes place in both directions from the origin (two replication forks)
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E. coli replication origin
•GATC common motif in oriC
•AT bp are common to facilitate duplex unwinding
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DNA Polymerization: Initiation
• DNA replication begins at a specific site.
• Example: oriC site from E. coli.
• 245 bp out of 4,000,000 bp
• contains atandem array of three 13-mers; GATCTNTTNTTTT
•GATC common motif in oriC
•AT bp are common to facilitate duplex unwinding
• Synthesis takes place in both directions from the origin (two replication forks)
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Enzyme Function
dnaA recognize replication origin and melts DNA duplex at several sites
Helicase (dnaB) unwinding of ds DNA
DNA gyrase generates (-) supercoiling
SSB stabilize unwound ssDNA
Primase (dnaG) an RNA polymerase, generates primers for DNA Pol
Enzymes involved in the initiation of DNA Polymerization
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Crystal structure of bacterial DNA helicase
Stryer Fig. 27.16
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DNA helicase: proposed mechanism
Stryer Fig. 27.17
B1 A1
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Problems to overcome: DNA Polymerization
1. The two strands must be separated, and local DNA over-windingmust be relaxed. The single stranded DNA must be prevented fromre-annealing and protected from degradation by cellular nucleases.
2. Both antiparallel strands must be synthesized simultaneously inthe 5’ 3’ direction.
3’
5’
3. A primer strand is required.
(overall direction)
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Lagging strand is synthesized in short fragments (1000-2000 nucleotides long) using
multiple primers
3’
5’
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Problems to overcome: DNA Polymerization
1. The two strands must be separated, and local DNA over-windingmust be relaxed. The single stranded DNA must be prevented fromre-annealing and protected from degradation by cellular nucleases.
2. Both antiparallel strands must be synthesized simultaneously inthe 5’ 3’ direction.
3’
5’
3. A primer strand is required.
![Page 26: Chapter 2: DNA Synthesis (Replication) Required reading: Stryer’s Biochemistry 5 th edition p. 127-128, 750-754, 759-766, 768-773 (or Stryer’s Biochemistry](https://reader035.vdocument.in/reader035/viewer/2022062421/56649d9e5503460f94a89358/html5/thumbnails/26.jpg)
A short stretch of RNA is used as a primer for DNA synthesis
(dnaG)
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What is the function of RNA priming?
• DNA polymerase tests the correctness of the preceding base pair before forming a new phosphodiester bond
•de novo synthesis does not allow proofreading of the first nucleotide
•Low fidelity RNA primer is later replaced with DNA
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Lagging strand synthesis in E. coli
3' 5'
Primase
3'5'
5'
DNA Pol III
3'
5'5'
RNA primer
3'
3' 5'3'
DNA Ligase
5'
Template DNA
5' 3'Okazaki fragment
5' 3'
3' 5'3'5'
New DNA
3'5'
5'5' 3'
DNA Pol I
3'
3'
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DNA Synthesis
3'
3'5'
SSB
5'
Leading Strand
5'
DNA Pol I
3'DNA Ligase
Lagging Strand
HelicaseGyrase
3'
5'
DNA Pol III
Primase
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E. coli DNA Polymerase III
Processive DNA SynthesisThe bulk of DNA synthesis in E. coli is carried out by the DNA polymerase III holoenzyme.
• Extremely high processivity: once it combines with the DNA and starts polymerization, it does not come off until finished.
• Tremendous catalytic potential: up to 2000 nucleotides/sec.
• Low error rate (high fidelity) 1 error per 10,000,000 nucleotides
• Complex composition (10 types of subunits) and large size (900 kd)
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E. coli Pol III: an asymmetrical dimer
Polymerase Polymerase
Stryer Fig. 27.30
clamp loader
Sliding clamp
3'-5' exonuclease
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2 sliding clamp is important for processivity of Pol III
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Stryer Fig. 27.33
Lagging strand loops to enable the simultaneous replication of both DNA strands by dimeric DNA Pol III
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DNA Ligase seals the nicks
OH P
O
-O O
O-
O P
O
O
O-DNA Ligase + (ATP or NAD+)
AMP + PPi
• Forms phosphodiester bonds between 3’ OH and 5’ phosphate• Requires double-stranded DNA• Activates 5’phosphate to nucleophilic attack by trans-esterification with activated AMP
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DNA Ligase -mechanism
1. E + ATP E-AMP + PPi
OH +DNA-3' P
O
AMP-O O
O-
5'-DNA O P
O
O
O-
DNA-3' 5'-DNA
+ AMP-OH
3.
2. E-AMP + P-5’-DNA P
O
AMP-O O
O-
5'-DNA
(+)H2NP
O
O(-)
O
OH
O
Ade
ENZYME
OH
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DNA Synthesis in bacteria: Take Home Message
1) DNA synthesis is carried out by DNA polymerases with high fidelity.
2) DNA synthesis is characterized by initiation, priming, and processive synthesis steps and proceeds in the 5’ 3’ direction.
3) Both strands are synthesized simultaneously by the multisubunit polymerase enzyme (Pol III). One strand is made continuously (leading strand), while the other one is made in fragments (lagging strand).
4) Pol I removes the RNA primers and fills the resulting gaps, and the nicks are sealed by DNA ligase