Prepare your eyes for the greatest DNA animation you have ever seen...

1. DNA Replication
Blake Bizousky

2. 5’
3’
DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
3’
5’
- Nucleotide

3. 5’
3’
DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
3’
5’
- Nucleotide

4. 5’
3’
DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
3’
5’
- Nucleotide

5. DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
- Nucleotide

6. DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
- Nucleotide

7. DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
- Nucleotide

8. DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
- Nucleotide

9. DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
- Nucleotide

10. DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
- Nucleotide

11. DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
- Nucleotide

12. DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
- Nucleotide

13. DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
- Nucleotide

14. DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
- Nucleotide

15. DNA replication is a process where DNA is
copied. This process occurs in a cell stage called
interphase. In order for the DNA molecule to “unzip”
the hydrogen bonds shared between the different
nitrogen bases such as adenine, thymine, guanine,
and cytosine, must break apart. The enzyme that
unwinds and unzips the molecule is DNA helicase.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- DNA helicase
- Nucleotide

16. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

17. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

18. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

19. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

20. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

21. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

22. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

23. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

24. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

25. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

26. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

27. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

28. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

29. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

30. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

31. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

32. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

33. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

34. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

35. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

36. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

37. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

38. Once the DNA molecule is completely
“unzipped”, new nucleotides are linked together to
make exact copies of the DNA. The strand on the left
is strand 1 and the strand on the right is strand 2. This
strand coming into the DNA would be a
complementary strand to strand 1. Only certain bases
can bond together. Mutations can occur during this
process, though they can only happen few times.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

39. Strand 1 is now zipped up in a continuous way.
The strand zips from a 5’ prime to 3’ prime. These two
stands are paired together by DNA polymerase III in
complete part these strands are called the leading
strand.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

40. Strand 1 is now zipped up in a continuous way.
The strand zips from a 5’ prime to 3’ prime. These two
stands are paired together by DNA polymerase III in
complete part these strands are called the leading
strand.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

41. Strand 1 is now zipped up in a continuous way.
The strand zips from a 5’ prime to 3’ prime. These two
stands are paired together by DNA polymerase III in
complete part these strands are called the leading
strand.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

42. Strand 1 is now zipped up in a continuous way.
The strand zips from a 5’ prime to 3’ prime. These two
stands are paired together by DNA polymerase III in
complete part these strands are called the leading
strand.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

43. Strand 1 is now zipped up in a continuous way.
The strand zips from a 5’ prime to 3’ prime. These two
stands are paired together by DNA polymerase III in
complete part these strands are called the leading
strand.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

44. Strand 1 is now zipped up in a continuous way.
The strand zips from a 5’ prime to 3’ prime. These two
stands are paired together by DNA polymerase III in
complete part these strands are called the leading
strand.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

45. Strand 1 is now zipped up in a continuous way.
The strand zips from a 5’ prime to 3’ prime. These two
stands are paired together by DNA polymerase III in
complete part these strands are called the leading
strand.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

46. Strand 1 is now zipped up in a continuous way.
The strand zips from a 5’ prime to 3’ prime. These two
stands are paired together by DNA polymerase III in
complete part these strands are called the leading
strand.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

47. Strand 1 is now zipped up in a continuous way.
The strand zips from a 5’ prime to 3’ prime. These two
stands are paired together by DNA polymerase III in
complete part these strands are called the leading
strand.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

48. Strand 1 is now zipped up in a continuous way.
The strand zips from a 5’ prime to 3’ prime. These two
stands are paired together by DNA polymerase III in
complete part these strands are called the leading
strand.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

49. Strand 1 is now zipped up in a continuous way.
The strand zips from a 5’ prime to 3’ prime. These two
stands are paired together by DNA polymerase III in
complete part these strands are called the leading
strand.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

50. Strand 1 is now zipped up in a continuous way.
The strand zips from a 5’ prime to 3’ prime. These two
stands are paired together by DNA polymerase III in
complete part these strands are called the leading
strand.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

51. Now that one DNA molecule has been copied the
other strand must be paired with it’s complementary
strand too.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

52. Now that one DNA molecule has been copied the
other strand must be paired with it’s complementary
strand too.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

53. Now that one DNA molecule has been copied the
other strand must be paired with it’s complementary
strand too.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

54. Now that one DNA molecule has been copied the
other strand must be paired with it’s complementary
strand too.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

55. Now that one DNA molecule has been copied the
other strand must be paired with it’s complementary
strand too.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

56. Now that one DNA molecule has been copied the
other strand must be paired with it’s complementary
strand too.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

57. Now that one DNA molecule has been copied the
other strand must be paired with it’s complementary
strand too.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

58. Now that one DNA molecule has been copied the
other strand must be paired with it’s complementary
strand too.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

59. Now that one DNA molecule has been copied the
other strand must be paired with it’s complementary
strand too.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

60. Strand 2 from the original DNA molecule must
still be paired together with complementary
nucleotides to form the second copy of the DNA.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

61. Strand 2 from the original DNA molecule must
still be paired together with complementary
nucleotides to form the second copy of the DNA.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

62. Strand 2 from the original DNA molecule must
still be paired together with complementary
nucleotides to form the second copy of the DNA.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

63. Strand 2 from the original DNA molecule must
still be paired together with complementary
nucleotides to form the second copy of the DNA.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

64. Strand 2 from the original DNA molecule must
still be paired together with complementary
nucleotides to form the second copy of the DNA.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

65. Strand 2 from the original DNA molecule must
still be paired together with complementary
nucleotides to form the second copy of the DNA.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

66. Strand 2 from the original DNA molecule must
still be paired together with complementary
nucleotides to form the second copy of the DNA.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

67. Strand 2 from the original DNA molecule must
still be paired together with complementary
nucleotides to form the second copy of the DNA.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III

68. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

69. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

70. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

71. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

72. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

73. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

74. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

75. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

76. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

77. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

78. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

79. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

80. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

81. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

82. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

83. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

84. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

85. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

86. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

87. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

88. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

89. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

90. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

91. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

92. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

93. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

94. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

95. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

96. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

97. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

98. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

99. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

100. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

101. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

102. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

103. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

104. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

105. This DNA molecule will be pair together in 3’ to
5’. This strand is the lagging strand and is paired up in
small segments called Okazaki fragments. Once a
starting point is given by Primase, DNA polymerase III
then finishes pairing the nucleotides with the help of
DNA ligase and DNA polymerase I.
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

106. We now have two identical DNA molecule!
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

107. We now have two identical DNA molecule!
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

108. We now have two identical DNA molecule!
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

109. We now have two identical DNA molecule!
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I

110. 5’
3’
5’
3’
We now have two identical DNA molecule!
- Adenine
- Phosphate
-Thymine
- Sugar
-Guanine
-Cytosine
- Nucleotide
-DNA Polymerase III
-DNA Ligase
- DNA Polymerase I
3’
5’
3’
5’