DNA REPLICATION, TRANSCRIPTION AND TRANSLATION Part-III
DNA Replication (Part 1C)
Mechanism of DNA Replication (Step-by-Step)
Introduction
After understanding the basic concepts of DNA replication (Part
1A) and the enzymes involved (Part 1B), we now study the actual
mechanism of DNA replication.
DNA replication is one of the most accurate biological processes known.
Millions of nucleotides are copied in the correct order within a short period
with an error rate of only about 1 in 10⁹–10¹⁰ nucleotides after
proofreading and repair.
The process consists of three major stages:
- Initiation
- Elongation
- Termination
Overview Of DNA Replication
│
▼
DNA Unwinding (Helicase)
│
▼
RNA Primer Formation (Primase)
│
▼
DNA Synthesis (DNA Polymerase)
│
▼
Primer Removal
│
▼
Gap Filling
│
▼
DNA Ligase Seals Nicks
│
▼
Two Identical DNA Molecules
Step 1 — Initiation of DNA Replication
Initiation is the first stage of DNA replication. It begins at the Origin
of Replication (Ori).
A. Recognition of Origin
Special initiator proteins recognize the origin sequence. In Escherichia
coli, these proteins bind to OriC. This marks the site where
replication begins.
B. DNA Unwinding
Enzyme: DNA Helicase
Helicase:
- Breaks hydrogen bonds.
- Separates the two DNA strands.
- Opens the double helix.
Result: Formation of a Replication Bubble.
Before
====================
After
======< >======
C. Formation of Replication Forks
Each replication bubble possesses two replication forks. Replication
proceeds simultaneously in opposite directions. Therefore, DNA replication is Bidirectional.
D. Stabilization of Single Strands
Protein Involved
Single-Strand Binding Proteins (SSBs)
Functions:
- Prevent DNA strands from
rejoining.
- Protect DNA.
- Stabilize replication fork.
E. Removal of Supercoiling
Helicase creates torsional strain.
Enzyme
In bacteria: DNA Gyrase
Function: Removes supercoils ahead of replication fork.
Step 2 — Primer Synthesis
DNA polymerase cannot start DNA synthesis.
Therefore, RNA primers are synthesized.
Enzyme- Primase
Primer: Short RNA segment
Provides: Free 3'-OH group, Necessary for DNA polymerase.
Step 3 — DNA Chain Elongation
Main Enzyme- DNA Polymerase
IMPORTANT RULE
DNA polymerase always synthesizes DNA
5' → 3'
while reading the template
3' → 5'
Why Are Two Strands Synthesized Differently?
The two parental DNA strands are antiparallel.
Therefore, One strand can be copied continuously.
The other cannot. Hence- Two different modes of synthesis occur.
Definition
The strand synthesized continuously toward the replication fork.
Characteristics:
- Continuous synthesis
- Only one RNA primer needed
- Faster synthesis
Diagram
Replication Fork →
Template
3' -----------------5'
↓
Continuous DNA synthesis
5' -----------------3'
Definition
The strand synthesized discontinuously away from the replication fork.
Characteristics:
- Discontinuous synthesis
- Many RNA primers required
- Slower synthesis
Diagram
Replication Fork →
5' ----------------3'
↓
Short DNA pieces
□□□□ □□□□ □□□□
These short pieces are called Okazaki Fragments.
Okazaki Fragments
Definition
Short DNA fragments synthesized on the lagging strand during replication.
Discovered by: Reiji Okazaki and Tsuneko Okazaki.
Approximate Length
Prokaryotes- 1000–2000 nucleotides
Eukaryotes- 100–200 nucleotides
Why Are Okazaki Fragments Formed?
DNA polymerase works only
5' → 3'
Since the lagging strand runs in the opposite orientation, DNA must be
synthesized in small fragments.
DNA Synthesis on Both Strands
|
Leading Strand |
Lagging Strand |
|
Continuous |
Discontinuous |
|
One primer |
Many primers |
|
No Okazaki fragments |
Okazaki fragments present |
|
Faster |
Slightly slower |
Step 4 — Removal of RNA Primers
RNA primers are temporary. They must be removed.
In Prokaryotes
DNA Polymerase I removes primers. It replaces RNA with DNA.
In Eukaryotes
RNA primers are removed by:
- RNase H
- Flap Endonuclease (FEN1)
DNA Polymerase fills the resulting gaps.
Step 5 — Ligation
After primer removal, DNA fragments remain separated.
Enzyme
DNA Ligase
Function
Forms phosphodiester bonds. Joins Okazaki fragments. Produces a
continuous DNA strand.
Step 6 — Termination
Replication continues until: Entire chromosome is copied.
In Prokaryotes
Replication forks meet at termination (Ter) sites. Replication stops. Two
daughter DNA molecules separate.
In Eukaryotes
Replication forks from adjacent origins eventually meet and fuse. Replication
terminates after the entire chromosome has been duplicated.
Why Is DNA Replication Called Semi-Discontinuous?
One strand
↓
Continuous
Other strand
↓
Discontinuous
Therefore,
Replication is called Semi-discontinuous.
Why Is DNA Replication Bidirectional?
Replication proceeds simultaneously in opposite directions from each
origin. Thus, Two replication forks move away from the origin.
Why Is DNA Replication Highly Accurate?
Several factors ensure accuracy.
1. Complementary Base Pairing
A pairs with T
G pairs with C
2. Proofreading
DNA polymerases possess 3' → 5' exonuclease activity. Wrong nucleotide
removed immediately.
3. DNA Repair Mechanisms
Remaining mistakes corrected after replication.
DNA Replication Speed
Prokaryotes
Approximately 1000 nucleotides/second
Eukaryotes
Approximately 50 nucleotides/second, although slower, eukaryotes
compensate by using multiple origins of replication.
Replication Of Circular DNA
Occurs in bacteria. Replication proceeds around the circular chromosome
until completion.
Replication Of Linear DNA
Occurs in eukaryotes. Special problem arises at chromosome ends. This is
called the End Replication Problem.
The End Replication Problem
After removal of the final RNA primer on the lagging strand, there is no
upstream 3′-OH group available for DNA polymerase to fill the gap.
As a result, the newly synthesized lagging strand becomes slightly
shorter after each round of replication. If uncorrected, chromosomes would
progressively shorten with every cell division.
Definition
Telomeres are repetitive, non-coding DNA sequences present at the ends of
linear eukaryotic chromosomes.
In humans, the repeat sequence is: TTAGGG, repeated thousands of
times.
Functions Of Telomeres
- Protect chromosome ends from
degradation.
- Prevent chromosome ends from
fusing with one another.
- Maintain chromosome stability.
- Buffer the loss of DNA during
replication.
Definition
Telomerase is a specialized ribonucleoprotein enzyme that extends
telomeres by adding repetitive DNA sequences to chromosome ends.
It contains:
- A protein component with reverse
transcriptase activity.
- An intrinsic RNA molecule that
serves as the template.
Where Is Telomerase Active?
High activity in:
- Germ cells
- Stem cells
- Early embryonic cells
Low or absent activity in:
- Most adult somatic cells
Many cancer cells reactivate telomerase, allowing unlimited cell
division.
Significance Of Telomerase
- Prevents excessive chromosome
shortening.
- Maintains genomic integrity.
- Contributes to cellular longevity
in specific cell types.
Flow Chart of DNA Replication
Origin of Replication
│
▼
Helicase Unwinds DNA
│
▼
Replication Fork Forms
│
▼
Primase Synthesizes RNA Primers
│
▼
DNA Polymerase Extends DNA
│
├───────────────┐
▼ ▼
Leading Strand Lagging Strand
Continuous Okazaki Fragments
│ │
└──────┬────────┘
▼
Primer Removal
▼
Gap Filling
▼
DNA Ligase Seals Nicks
▼
Termination
▼
Two Identical DNA Molecules
Leading Vs Lagging Strand
|
Feature |
Leading Strand |
Lagging Strand |
|
Direction of synthesis |
Toward replication fork |
Away from replication fork |
|
Nature |
Continuous |
Discontinuous |
|
RNA primers |
One |
Many |
|
Okazaki fragments |
Absent |
Present |
|
DNA ligase requirement |
Minimal |
Essential |
Prokaryotic vs Eukaryotic DNA Replication
|
Feature |
Prokaryotes |
Eukaryotes |
|
Chromosomes |
Circular |
Linear |
|
Origins of replication |
Single |
Multiple |
|
Replication speed |
~1000 nucleotides/s |
~50 nucleotides/s |
|
Okazaki fragment size |
1000–2000 nt |
100–200 nt |
|
Main replicative polymerase |
DNA Polymerase III |
DNA Polymerases δ and ε |
|
Primer removal |
DNA Polymerase I |
RNase H and FEN1 |
|
Telomeres |
Absent |
Present |
|
Telomerase |
Not required |
Required for telomere maintenance |
Clinical Correlation
DNA Repair Defects
Inherited defects in DNA repair pathways can lead to genomic instability
and increased cancer risk.
Example: Xeroderma pigmentosum is caused by defective nucleotide excision
repair, resulting in extreme sensitivity to ultraviolet (UV) radiation.
High-Yield Facts
- DNA polymerases can only extend a
pre-existing primer and cannot initiate DNA synthesis.
- The antiparallel arrangement of
DNA strands results in continuous synthesis on the leading strand and
discontinuous synthesis on the lagging strand.
- Okazaki fragments are formed only
on the lagging strand and are subsequently joined by DNA ligase.
- DNA replication is bidirectional,
semiconservative, and semi-discontinuous.
- Multiple origins of replication
in eukaryotic chromosomes enable timely duplication of the large genome
during the S phase.
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