DNA Replication PDF

Summary

This document explains the process of DNA replication, including the role of enzymes such as helicase and polymerase. It details how existing DNA strands act as templates for creating new complementary strands in a semi-conservative manner, using diagrams and descriptions. The document also examines the intricacies of DNA replication in eukaryotes.

Full Transcript

During DNA replication, base pairing enables existing DNA
strands to serve as templates for new complimentary strands

 When a cell copies a DNA molecule, each strand serves as a template for ordering

nucleotides into a new complimentary strand.



Nucleotides line up along the template strand according to the base-pairing rules.
The nucleotides are linked to form new strands (complementary).

DNA Replication:
1. During DNA replication, base pairing enables
existing DNA strands to serve as templates for new
complimentary strands.
2. Several enzymes and other proteins carry out DNA
replication:
Helicase,
Primase,
Polymerase,
Ligase.

The ends of DNA molecules are replicated by a special
mechanism.

The Replication Mechanism
 It takes E. coli less than an hour to copy each of the 5 million base

pairs in its single chromosome and divide to form two identical
daughter cells.
 A human cell can copy its 6 billion base pairs and divide into

daughter cells in only a few hours.
 This process is remarkably accurate, with only one error per billion
nucleotides.
 A helicase; untwists and separates the template DNA strands at the

replication fork.
 Single-strand binding proteins; keep the unpaired template
strands apart during replication.

• The replication of a DNA molecule begins at special site called
origin of replication which is a single specific sequence of
nucleotides that is recognized by the replication enzymes.

• Replication enzymes separate the strands, forming a
replication “bubble”.
– Replication proceeds in both directions until the entire molecule is
copied.

 In eukaryotes, there may be

hundreds or thousands of
bubbles (each has origin sites for
replication) per chromosome.




At the origin sites, the DNA strands
separate forming a replication
“bubble” with replication forks at
each end.
The replication bubbles elongate as
the DNA is replicated and eventually
fuse.

 Primer: (a short segment of

RNA, 10 nucleotides long) is
required to start a new chain.
 Primase: (an RNA polymerase)

links ribonucleotides that are
complementary to the DNA
template into the primer.
•

DNA polymerases: catalyze the
elongation of new DNA at a
replication fork. After
formation of the primer, DNA
polymerases can add
deoxyribonucleotides to the 3’
end of the ribonucleotide
chain.

•

Another DNA polymerase later
replaces the primer
ribonucleotides with
deoxyribonucleotides
complimentary to the
template.

 DNA polymerases can only add nucleotides to the free 3’ end of a growing DNA strand.

 A new DNA strand can only elongate in the 5’->3’ direction.
 At the replication fork, one parental strand (3’-> 5’ into the fork), the leading strand,

can be used by polymerases as a template for a continuous complimentary strand.

To elongate the other new strand of DNA in
the obligatory 5’->3’ direction, DNA pol III
must work along the other template strand in the
direction away from the replication Fork .
The DNA strand elongating in this direction
is called the lagging strand.
the lagging strand is synthesized
discontinuously, as a series of segments (called
Okazaki fragments.

laying

 Okazaki fragments (each about 100-200
nucleotides) are joined by DNA ligase to
form the sugar-phosphate backbone of a
single DNA strand.

Step 1
 Helicases: Enzymes that separate the DNA strands

 Helicase move along the strands and breaks the hydrogen bonds between the

complimentary nitrogen bases
 Replication Fork: the Y shaped region that results from the separation of the
strands

Step 2
• DNA Polymerase: enzymes that add complimentary nucleotides.
• Nucleotides are found floating freely inside the nucleus
• Covalent bonds form between the phosphate group of one nucleotide and the
deoxyribose of another
• Hydrogen bonds form between the complimentary nitrogen bases

Step 3
• DNA polymerases finish replicating the DNA and fall off.
• The result is two identical DNA molecules that are ready to move to new cells in
cell division.
• Semi-Conservative Replication: this type of replication where one strand is
from the original molecule and the other strand is new

 Each strand is making its own new strand.
 DNA synthesis is occurring in two different directions
 One strand is being made towards the replication fork and the other

is being made away from the fork. The strand being made away
from the fork has gaps.
 Gaps are later joined by another enzyme, DNA ligase

•
•

The strands in the double helix are
antiparallel.
The sugar-phosphate backbones run in
opposite directions.
– Each DNA strand has a 3’ end with a free
OH group attached to deoxyribose and a
5’ end with a free phosphate group
attached to
deoxyribose.
– The 5’ -> 3’ direction of one strand runs
counter to ‫ ُمعاكس لـ‬the 3’ -> 5’ direction of
the other strand.

SUMMARY OF DNA REPLICATION MECHANISM
The two DNA-strands separate forming replication
bubbles.
Each strand functions as a template for synthesizing new
complementary & lagging strands via primers, polymerase and
ligase.
3
5
T

A

C

T

G

A

C

A

T

G

A

C

T

G

3

5

Complementary
(leading) strand

T

A

C

T

G

Primer

Polymeras
Ligase
e
A

C

5

3
Lagging strand
(complementary)

Okazaki
fragments

Templates

1

2
3
4

Fig. 16.15, Page 298