3. A. DNA— deoxyribonucleic acid; determines an organism’s traits by controlling when proteins in the body are made 1. Proteins and enzymes —control most aspects of cellular function in an organism

4. B. Structure of DNA 1. Made of long chains of nucleotides a. 3 parts of a nucleotide: - phosphate group - simple sugar (deoxyribose) - nitrogen base

5. b. 4 types of nitrogen bases: - adenine (A) - guanine (G) - cytosine (C) - thymine (T) Adenine (A) Guanine (G)Thymine (T)Cytosine (C)

6. Adenine (A) Guanine (G)Thymine (T)Cytosine (C) d. Nucleotides join together in long chains to form nucleic acids. c. Complementary base pairs: - A pairs with T - G pairs with C

7. 2. All organisms are made up of the same nucleotides, just in different order a. Example: All words are made up of the same letters, just in different order

8. A. Discovered by James Watson and Francis Crick in 1953. 1. Double Helix — double stranded, twisted ladder shape of DNA 2. If DNA is a ladder: a. Sugar and phosphate groups form the backbone or the sides of the ladder b. Nitrogen bases form the rungs of the ladder.

9. James Watson and Francis Crick

10. 3. Individual nucleotides are joined by covalent bonds. 4. Nitrogen bases in the middle of the helix are joined by hydrogen bonds.

11. B. How does DNA fit in the cell? 1. Think about it! The DNA strand can be incredibly LONG! Human DNA molecules contain up to 4,639,221,000 base pairs. That means there is about 1-2 meters of DNA in each cell. How can it be kept in such a small area?

12. 2. The solution: a. Chromatin is made of DNA packed around histone proteins. b. During interphase, these are dispersed and uncoiled. When cells enter prophase, they pack tightly to form chromosomes.

13. A. DNA Replication - Whenever a cell divides, the DNA must be copied before it splits 1. DNA helicase, an enzyme, unzips the double helix (breaks the hydrogen bonds) to form two single strands still joined at the replication forks. Replication Fork DNA helicase

14. 2. DNA polymerase, an enzyme, adds new nucleotides to each single strand according to their complementary base pairs a. DNA polymerase also “proofreads” for errors Replication Fork DNA helicase DNA polymerase

15. 3. DNA Ligase, an enzyme, reseals the gaps remaining in the sugar/phosphate backbone to finish. Replication Fork DNA helicase DNA polymerase DNA ligase

16. 4. END RESULT: 2 new and identical molecules of DNA are formed a. 1 strand made of “old” DNA b. 1 strand made of “new” DNA

17. Original DNA Original DNA Strand Free Nucleotides New DNA molecule New DNA Strand New DNA molecule

18. Replication DNA

19. 5. Example Complementary Base Pairing a. (Find each complementary base pair for the strand of DNA) A—C—T—A—G—A—C—C—T—A—G—T | | | | | | | | | | | | T G A T C T G G A T C A

20. 6. Example of DNA Replication a. (Unzip the following molecule of DNA, and write the two new strands of DNA that would result from the replication) b. Original DNA Molecule C—G—T—C—A—T—C—G—C—A—A—T—G | | | | | | | | | | | | | G—C—A—G—T—A—G—C—G—T—T—A—C Molecule #1 C—G—T—C—A—T—C—G—C—A—A—T—G | | | | | | | | | | | | | G—C—A—G—T—A—G—C—G—T—T—A—C Molecule #2 | | | | | | | | | | | | | G—C—A—G—T—A—G—C—G—T—T—A—C C—G—T—C—A—T—C—G—C—A—A—T—G

21. A.DNA- Double stranded nucleic acid that is stored in the nucleus of the cell. 1. Gene- piece of DNA that controls a specific trait

22. B. RNA - a single stranded nucleic acid found all over the cell (nucleus, cytoplasm, and ribosome) 1. Made of long chains of nucleotides: a. 3 parts of a nucleotide— -phosphate group - simple sugar (ribose) - nitrogen base

23. b. 5 types of Nitrogen Bases - adenine (A) - guanine (G) - cytosine (C) - thymine (T) - Uracil (U) c. Complementary base pairs - A pairs with U - T pairs with A - G pairs with C d. Nucleotides join together in long chains to form nucleic acids.

24. 2. Three Types of RNA a. Messenger RNA (mRNA)- carries the information from the DNA in the nucleus to the rest of the cell Codon

25. b. Transfer RNA (tRNA)- helps build proteins by carrying amino acids to ribosomes, following instructions coded for in the mRNA.  Each tRNA carries only ONE type of amino acid  The code of the tRNA is complementary to the mRNA. Amino acid Chain of RNA nucleotides Transfer RNA molecule Anticodon

26. c. Ribosomal RNA (rRNA)- the site of protein synthesis; makes up the ribosome

27. MoleculeDNARNA SugarDeoxyriboseRibose StructureDouble strandSingle strand NucleotidesA, T, G, C Adenine - thymine A, U, T, G, C Adenine - uracil Thymine - Adenine) Location in cell Stays in the nucleusLeaves nucleus to ribosomes C. DNA/RNA Comparison

29. DNA transcription RNAProtein translation D. Protein Synthesis - Using genetic information in DNA to make proteins

30. E. Steps of Protein Synthesis 1. Transcription - Process of making mRNA from DNA a. Why? DNA can’t leave nucleus but RNA can

31. b. Steps of Transcription 1. RNA polymerase, an enzyme, unzips the double helix of DNA inside the nucleus and uses it as a template to create a complementary mRNA strand

32. 2. RNA editing occurs  Introns - sections of the DNA that don’t code for proteins are cut from the mRNA  Exons - sections of the DNA that code for proteins are left on the mRNA

33. 3. DNA rezips and mRNA leaves nucleus and goes to the cytoplasm to find a ribosome for protein synthesis

34. c. Example: Transcribe the DNA into mRNA.  A C C A T G A C C T G A C T T A C  U G G U A C U G G A C U G A A U G

35. 2. Translation: Making chains of amino acids (proteins) by reading/translating mRNA codons (a group of 3 nucleotides) in the ribosome a. The amino acid sequence determines the structure and function of proteins codon

36. b. Steps of Translation 1. mRNA travels to ribosome with a message from the DNA and attaches to the rRNA. 1. 2. 3.

37. 2. As each mRNA codon moves over the ribosome, it is matched with its complementary tRNA anticodon, which is carrying amino acids. 1. 2. 3.

38. 3. Inside the ribosome, peptidase, an enzyme, helps form peptide bonds joining amino acids to make proteins and tRNA is released to go find another amino acid 1. 2. 3.

39. c. Example: Translate the mRNA into proteins (USE CODON CHART!)  mRNA = A U G C A U G G A A G C U G A  amino acid chain =

43. d. There are 20 amino acids created from a combination of the 4 nitrogen bases - Each mRNA codon specifies a different tRNA anticodon to bring amino acids to join to the protein - Every different combination of amino acids forms new proteins Alanine Methionine Peptide bond

44.  Special Codons - some codons signal start or stop  AUG (methoinine) = start building protein  UAA, UAG, and UGA = stop building protein Stop codon

46. ProcessTranscriptionTranslation LocationIn NucleusAt the ribosome PurposeTurn DNA into RNA Turn RNA into proteins Molecules involved DNA, mRNAmRNA, tRNA, rRNA 3. Transcription/Translation Comparison

47. A. Mutation - Mistake or change in DNA sequence 1. The change in the DNA is HUGE since the codon is changed a. If the codons are affected, the amino acids and proteins for the cell are also affected.

48. B. Types of Mutations 1. Point Mutation - change in a SINGLE base pair in DNA a. Substitution Mutation - one nitrogen base is replaced with another - Example: ACTAGGCAC to ACTAGTCAC - Results in a change of one codon

49. Point mutation mRNA Protein Normal mRNA Protein

50. b. Frameshift Mutation - ONE base is added or deleted from DNA, and it shifts the reading of codons - Example: Addition Mutation: ACTAGGCAC to ACTAGGGCAC Deletion Mutation: ACTAGGCAC to ACTAGCAC - Results in EVERY codon after the mutation to change. - Original Protein: Meth-Lys-Phenyl-Gly-Ala- Leu - Mutated protein: Meth-Lys-Leu-Ala-Hist- Cys

51. Deletion of U Without mutation Frameshift mutation mRNA Protein

52. Addition (Frameshift) Deletion (Frameshift) Substitution (Point) Normal

53. 2. Which type of mutation is more serious? a. Frameshift - it affects EVERY amino acid/protein after the mutation Deletion of U Frameshift mutation mRNA Protein

54. 3. Chromosomal mutations - Structural changes in chromosomes a. Are especially common in plants.

55. 4. Four Types of Chromosomal Mutations a. Deletion -part of a chromosome left out (usually deadly) A B C D E F G H Deletion A B C E F G H

56. b. Duplication/Insertion: chromosome part breaks off and reattaches to its sister chromatid

57. A B C D E F G H A B C B C D E F G H Insertion *Genes B and C were inserted into the chromosome* Insertion

58. c. Inversion - chromosome part breaks off and reattaches backwards Inversion A B C D E F G H A D C B E F G H

59. d. Translocation - chromosome part breaks off and adds to a different chromosome Translocation

60. Inversion Insertion Deletion Translocation

61. C. Causes of Mutations 1. Spontaneous/Random mutations– ◦ Some mutations just happen, ( amistake during DNA replication, transcription, mitosis, meiosis).  a. These lead to evolution. 2. Mutagen - Any agent that causes a change in DNA  a. Include radiation (uv or nuclear radiation) and chemicals (asbestos or formaldehyde)  B. Environmental agents