EberhartDNAmodel

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EberhartDNAmodel

  1. 1. DNA Replication Animation By: Alex Eberhart
  2. 2. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  3. 3. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  4. 4. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  5. 5. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  6. 6. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  7. 7. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  8. 8. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  9. 9. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  10. 10. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  11. 11. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  12. 12. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  13. 13. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  14. 14. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  15. 15. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  16. 16. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  17. 17. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  18. 18. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  19. 19. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  20. 20. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  21. 21. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  22. 22. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Cytosine -Phosphate -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  23. 23. 5’ 3’ Replication begins at the origin of replication. The DNA Helicase unwinds or unzips the double helix so there will be two separate DNA strands to begin replicating. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Helicase
  24. 24. 5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3’ 5’ -Thymine -Cytosine -Nucleotide
  25. 25. 5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3’ 5’ -Thymine -Cytosine -Nucleotide
  26. 26. 5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3’ 5’ -Thymine -Cytosine -Nucleotide
  27. 27. 5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3’ 5’ -Thymine -Cytosine -Nucleotide
  28. 28. 5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3’ 5’ -Thymine -Cytosine -Nucleotide
  29. 29. 5’ 5’ 3’ Single-Stranded Binding Proteins bind to the leading strand to keep it stable while the enzyme, DNA Polymerase III comes in and synthesizes the leading strand constantly. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Polymerase III
  30. 30. 5’ 5’ 3’ Single-Stranded Binding Proteins bind to the leading strand to keep it stable while the enzyme, DNA Polymerase III comes in and synthesizes the leading strand constantly. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Polymerase III
  31. 31. 5’ 3’ Single-Stranded Binding Proteins bind to the leading strand to keep it stable while the enzyme, DNA Polymerase III comes in and synthesizes the leading strand constantly. 5’ -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Polymerase III
  32. 32. 5’ 3’ Single-Stranded Binding Proteins bind to the leading strand to keep it stable while the enzyme, DNA Polymerase III comes in and synthesizes the leading strand constantly. 5’ -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Polymerase III
  33. 33. 5’ 3’ Single-Stranded Binding Proteins bind to the leading strand to keep it stable while the enzyme, DNA Polymerase III comes in and synthesizes the leading strand constantly. 5’ -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Polymerase III
  34. 34. 5’ 3’ Single-Stranded Binding Proteins bind to the leading strand to keep it stable while the enzyme, DNA Polymerase III comes in and synthesizes the leading strand constantly. -Sugar 5’ -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’ -Thymine -DNA Polymerase III
  35. 35. 5’ 3’ Single-Stranded Binding Proteins bind to the leading strand to keep it stable while the enzyme, DNA Polymerase III comes in and synthesizes the leading strand constantly. -Sugar -Phosphate 5’ -Nucleotide -Adenine -Guanine 3’ -Cytosine 5’ -Thymine -DNA Polymerase III
  36. 36. 5’ 3’ Single-Stranded Binding Proteins bind to the leading strand to keep it stable while the enzyme, DNA Polymerase III comes in and synthesizes the leading strand constantly. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine 5’ 3’ -Guanine 5’ -Thymine -DNA Polymerase III
  37. 37. 5’ 3’ 3’ Single-Stranded Binding Proteins bind to the leading strand to keep it stable while the enzyme, DNA Polymerase III comes in and synthesizes the leading strand constantly. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’ 5’ -Thymine -DNA Polymerase III
  38. 38. 5’ 3’ 3’ 3’ -Sugar -Phosphate -Adenine -Guanine 3’ 5’ 5’ -Thymine -Cytosine -Nucleotide
  39. 39. 5’ 3’ 3’ 3’ -Sugar -Phosphate -Adenine -Guanine 3’ 5’ 5’ -Thymine -Cytosine -Nucleotide
  40. 40. 5’ 3’ 3’ 3’ -Sugar -Phosphate -Adenine -Guanine 3’ 5’ 5’ -Thymine -Cytosine -Nucleotide
  41. 41. 5’ 3’ 3’ 3’ -Sugar -Phosphate -Adenine -Guanine 3’ 5’ 5’ -Thymine -Cytosine -Nucleotide
  42. 42. 5’ 3’ 3’ 3’ -Sugar -Phosphate -Adenine -Guanine 3’ 5’ 5’ -Thymine -Cytosine -Nucleotide
  43. 43. 5’ 3’ 3’ 3’ -Sugar -Phosphate -Adenine -Guanine 3’ 5’ 5’ -Thymine -Cytosine -Nucleotide
  44. 44. 5’ 3’ 3’ 3’ -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’ 5’ -Thymine -RNA
  45. 45. 5’ 3’ 3’ 3’ -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’ 5’ -Thymine -RNA
  46. 46. 5’ 3’ 3’ -Sugar 3’ -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’ 5’ -Thymine -RNA
  47. 47. 5’ 3’ 3’ -Sugar -Phosphate -Cytosine -Nucleotide 3’ -Adenine -Guanine 3’ 5’ 5’ -Thymine -RNA
  48. 48. 5’ 3’ 3’ -Sugar -Phosphate -Cytosine -Nucleotide -Adenine 3’ -Guanine 3’ 5’ 5’ -Thymine -RNA
  49. 49. 5’ 3’ 3’ -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 3’ 5’ 5’ -Thymine -RNA
  50. 50. 5’ 5’ 3’ 3’ -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 3’ 5’ 5’ -Thymine -RNA
  51. 51. 5’ 3’5’ 3’ -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’3’ 5’ -Thymine -RNA
  52. 52. 5’ 3’5’ 3’ The enzyme, DNA Polymerase I then has to come in and synthesize the lagging strand to change the RNA into DNA. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’3’ 5’ -Thymine -RNA -DNA Polymerase I
  53. 53. 5’ 3’5’ 3’ The enzyme, DNA Polymerase I then has to come in and synthesize the lagging strand to change the RNA into DNA. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’3’ 5’ -Thymine -RNA -DNA Polymerase I
  54. 54. 5’ 3’5’ 3’ The enzyme, DNA Polymerase I then has to come in and synthesize the lagging strand to change the RNA into DNA. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’3’ 5’ -Thymine -RNA -DNA Polymerase I
  55. 55. 5’ 3’5’ 3’ The enzyme, DNA Polymerase I then has to come in and synthesize the lagging strand to change the RNA into DNA. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’3’ 5’ -Thymine -RNA -DNA Polymerase I
  56. 56. 5’ 3’5’ 3’ The enzyme, DNA Polymerase I then has to come in and synthesize the lagging strand to change the RNA into DNA. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’3’ 5’ -Thymine -RNA -DNA Polymerase I
  57. 57. 5’ 3’5’ 3’ The enzyme, DNA Polymerase I then has to come in and synthesize the lagging strand to change the RNA into DNA. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’3’ 5’ -Thymine -RNA -DNA Polymerase I
  58. 58. 5’ 3’5’ 3’ The enzyme, DNA Polymerase I then has to come in and synthesize the lagging strand to change the RNA into DNA. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’3’ 5’ -Thymine -RNA -DNA Polymerase I
  59. 59. 5’ 3’5’ 3’ The enzyme, DNA Polymerase I then has to come in and synthesize the lagging strand to change the RNA into DNA. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’3’ 5’ -Thymine -RNA -DNA Polymerase I
  60. 60. 5’ 3’5’ 3’ The enzyme, DNA Polymerase I then has to come in and synthesize the lagging strand to change the RNA into DNA. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’3’ 5’ -Thymine -RNA -DNA Polymerase I
  61. 61. 5’ 3’5’ 3’ The enzyme, DNA Polymerase I then has to come in and synthesize the lagging strand to change the RNA into DNA. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’3’ 5’ -Thymine -RNA -DNA Polymerase I
  62. 62. 5’ 3’5’ 3’ The enzyme, DNA Polymerase I then has to come in and synthesize the lagging strand to change the RNA into DNA. -Sugar -Phosphate -Cytosine -Nucleotide -Adenine -Guanine 3’ 5’3’ 5’ -Thymine -RNA -DNA Polymerase I
  63. 63. 5’ 3’5’ 3’ The enzyme, DNA Polymerase I then has to come in and synthesize the lagging strand to change the RNA into DNA. -Sugar -Phosphate -Adenine -Guanine 3 5’3’ 5’ -Thymine -Cytosine -Nucleotide
  64. 64. 5’ 3’5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3 5’3’ 5’ -Thymine -Cytosine -Nucleotide
  65. 65. 5’ 3’5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3 5’3’ 5’ -Thymine -Cytosine -Nucleotide
  66. 66. 5’ 3’5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3 5’3’ 5’ -Thymine -Cytosine -Nucleotide
  67. 67. 5’ 3’5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3 5’3’ 5’ -Thymine -Cytosine -Nucleotide
  68. 68. 5’ 3’5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3 5’3’ 5’ -Thymine -Cytosine -Nucleotide
  69. 69. 5’ 3’5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3 5’3’ 5’ -Thymine -Cytosine -Nucleotide
  70. 70. 5’ 3’5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3 5’3’ 5’ -Thymine -Cytosine -Nucleotide
  71. 71. 5’ 3’5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3 5’3’ 5’ -Thymine -Cytosine -Nucleotide
  72. 72. 5’ 3’5’ 3’ -Sugar -Phosphate -Adenine -Guanine 3 5’3’ 5’ -Thymine -Cytosine -Nucleotide
  73. 73. 5’ 3’5’ 3’ In the end there are now 4 strands of DNA. -Sugar -Phosphate -Adenine -Guanine 3 5’3’ 5’ -Thymine -Cytosine -Nucleotide

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