1. Protein Synthesis Making Proteins 1

2. Lesson 1
DNA

3. Do Now
BrainPop Video: DNA

4. Bodies  Cells  DNA Bodies are made up of cells
All cells run on a set of instructions spelled out in DNA 4

5. DNA  Cells  Bodies How does DNA code for cells & bodies?
how are cells and bodies made from the instructions in DNA 5

6. DNA  Proteins  Cells  Bodies
DNA has the information to build proteins
genes
proteins
cells
DNA gets all the glory, Proteins do all the work
bodies 6

7. How do proteins do all the work
proteins run living organisms
enzymes
control all chemical reactions in living organisms
structure
all living organisms are built out of proteins 7

8. Cell organization DNA DNA is in the nucleus
genes = instructions for making proteins
want to keep it there = protected
“locked in the vault”
cytoplasm
nucleus 8

9. Cell organization Proteins chains of amino acids
made by a “protein factory” in cytoplasm
protein factory = ribosome
cytoplasm
nucleus
build proteins
ribosome 9

10. In class assignment
Multiple Choice worksheet

11. Homework
Vocab and DNA worksheets

12. Lesson 2
PASSING ON DNA

13. Do Now
BrainPop video: RNA
Multiple choice worksheet

14. Passing on DNA information
Need to get DNA gene information from nucleus to cytoplasm
need a copy of DNA
messenger RNA
cytoplasm
nucleus
build proteins
mRNA
ribosome 14

15. From nucleus to cytoplasm
transcription
DNA
mRNA
protein
translation
trait
nucleus
cytoplasm 15

16. DNA vs. RNA DNA RNA deoxyribose sugar nitrogen bases double stranded
G, C, A, T
T : A
C : G
double stranded
RNA
ribose sugar
nitrogen bases
G, C, A, U
U : A
C : G
single stranded 16

17. Transcription Making mRNA from DNA
DNA strand is the template (pattern)
match bases
U : A
G : C
Enzyme
RNA polymerase 17

18. Matching bases of DNA & RNA
Double stranded DNA unzips T G G T A C A G C T A G T C A T C G T A C C G T 18

19. Matching bases of DNA & RNA
Double stranded DNA unzips T G G T A C A G C T A G T C A T C G T A C C G T 19

20. Matching bases of DNA & RNA
Match RNA bases to DNA bases on one of the DNA strands U G A G U G U C U G C A A C U A A G C
RNA
polymerase U A G A C C T G G T A C A G C T A G T C A T C G T A C C G T 20

21. Matching bases of DNA & RNA
U instead of T is matched to A
TACGCACATTTACGTACGCGG
DNA
AUGCGUGUAAAUGCAUGCGCC
mRNA
ribosome U C A G 21

22. In class assignment
Protein Synthesis1

23. Homework
Protein Synthesis Practice 2

24. Lesson 3
MRNA CODES

25. Do Now
RNA Vocab worksheet

26. How does mRNA code for proteins
mRNA leaves nucleus
mRNA goes to ribosomes in cytoplasm
Proteins built from instructions on mRNA
How?
mRNA U C A G aa 26

27. How does mRNA code for proteins?
TACGCACATTTACGTACGCGG
DNA
ribosome
AUGCGUGUAAAUGCAUGCGCC
mRNA ?
Met Arg Val Asn Ala Cys Ala
protein aa
How can you code for 20 amino acids with only 4 DNA bases (A,U,G,C)? 27

28. mRNA codes for proteins in triplets
TACGCACATTTACGTACGCGG
DNA
ribosome
AUGCGUGUAAAUGCAUGCGCC
mRNA
AUGCGUGUAAAUGCAUGCGCC
mRNA ?
Met Arg Val Asn Ala Cys Ala
protein
Codon = block of 3 mRNA bases 28

29. The mRNA code For ALL life! Code has duplicates Start codon
strongest support for a common origin for all life
Code has duplicates
several codons for each amino acid
mutation insurance!
Strong evidence for a single origin in evolutionary theory.
Start codon
AUG
methionine
Stop codons
UGA, UAA, UAG 29

30. How are the codons matched to amino acids?
TACGCACATTTACGTACGCGG
DNA
AUGCGUGUAAAUGCAUGCGCC
mRNA
codon
UAC
Met
GCA
Arg
tRNA
CAU
Val
anti-codon
amino acid
Anti-codon = block of 3 tRNA bases 30

31. mRNA to protein = Translation
The working instructions  mRNA
The reader  ribosome
The transporter  transfer RNA (tRNA)
ribosome
mRNA U C A G aa
tRNA G U aa
tRNA U A C aa
tRNA G A C
tRNA aa A G U 31

32. From gene to protein DNA mRNA protein trait tRNA transcriptionaa
transcription
translation
DNA
mRNA
protein
ribosome U C A G
tRNA aa
trait
nucleus
cytoplasm 32

33. cytoplasm
protein
transcription
translation
nucleus
trait 33

34. From gene to protein
protein
transcription
translation 34

35. In class assignment
Protein Synthesis 3

36. Homework
Vocabulary worksheet

37. Lesson 4
PROTEIN SYNTHESIS LAB

38. MUTATIONS AND GEL ELECTROPHORESIS
Lesson 5
MUTATIONS AND GEL ELECTROPHORESIS

39. Do Now

40. Mutations Changes to DNA 40

41. Mutations Changes to DNA are called mutations change the DNA
changes the mRNA
may change protein
may change trait
DNA
TACGCACATTTACGTACG
mRNA
AUGCGUGUAAAUGCAUGC aa
protein
trait

42. Does this change the sentence?
Point Mutations
One base change
can change the meaning of the whole protein
THEFATCATANDTHEREDRATRAN
Does this change the sentence?
A LITTLE!
THEFATCARANDTHEREDRATRAN OR
THEFATCATENDTHEREDRATRAN 42

43. Does this change the protein?
Frameshift Mutations
Addition = add one or more bases
AUGCGUGUAUACGCAUGCGAGUGA
MetArgValTyrAlaCysGluStop
Does this change the protein?
A LOT!
AUGCGUGUAUACGUCAUGCGAGUGA
MetArgValTyrValMetArgValA 43

44. Does this change the protein?
Frameshift Mutations
Deletion = lose one or more bases
AUGCGUGUAUACGCAUGCGAGUGA
MetArgValTyrAlaCysGluStop
Does this change the protein?
A LOT!
AUGCGUGUAUACGAUGCGAGUGA
MetArgValTyrAspAlaSerGA 44

45. Biotechnology Gel Electrophoresis 45

46. Many uses of restriction enzymes…
Now that we can cut DNA with restriction enzymes…
we can cut up DNA from different people… or different organisms… and compare it
why?
forensics
medical diagnostics
paternity
evolutionary relationships
and more… 46

47. Comparing cut up DNA How do we compare DNA fragments?
separate fragments by size
How do we separate DNA fragments?
run it through a gelatin
gel electrophoresis
How does a gel work? 47

48. “swimming through Jello”
Gel electrophoresis
A method of separating DNA in a gelatin-like material using an electrical field
DNA is negatively charged
when it’s in an electrical field it moves toward the positive side
DNA        – +
“swimming through Jello” 48

49. “swimming through Jello”
Gel electrophoresis
DNA moves in an electrical field…
so how does that help you compare DNA fragments?
size of DNA fragment affects how far it travels
small pieces travel farther
large pieces travel slower & lag behind
DNA        – +
“swimming through Jello” 49

50. DNA & restriction enzyme
Gel Electrophoresis
DNA & restriction enzyme -
wells
longer fragments
power
source
gel
shorter fragments +
completed gel 50

51. fragments of DNA separate out based on size
Running a gel
fragments of DNA separate out based on size
cut DNA with restriction enzymes 1 2 3
Stain DNA
ethidium bromide binds to DNA
fluoresces under UV light 51

52. Uses: Evolutionary relationships
Comparing DNA samples from different organisms to measure evolutionary relationships
turtle
snake
rat
squirrel
fruitfly – 1 3 2 4 5 1 2 3 4 5
DNA  + 52

53. Uses: Medical diagnostic
Comparing normal allele to disease allele
chromosome with normal allele 1
chromosome with disease-causing allele 2
allele 1
allele 2 –
DNA 
Example: test for Huntington’s disease + 53

54. Uses: Forensics
Comparing DNA sample from crime scene with suspects & victim
suspects
crime scene sample S1 S2 S3 V –
DNA  + 54

55. DNA fingerprints
Comparing blood samples on defendant’s clothing to determine if it belongs to victim
DNA fingerprinting 55

56. RFLP / electrophoresis use in forensics
1st case successfully using DNA evidence
1987 rape case convicting Tommie Lee Andrews
“standard”
semen sample from rapist
blood sample from suspect
“standard”
How can you compare DNA from blood & from semen? RBC?
“standard”
semen sample from rapist
blood sample from suspect
“standard” 56

57. Electrophoresis use in forensics
Evidence from murder trial
Do you think suspect is guilty?
blood sample 1 from crime scene
blood sample 2 from crime scene
blood sample 3 from crime scene
“standard”
blood sample from suspect
OJ Simpson
blood sample from victim 1
N Brown
blood sample from victim 2
R Goldman
“standard” 57

58. Uses: Paternity
Who’s the father? –
Mom F1 F2
child
DNA  + 58

59. Homework
Regents Review: Protein Synthesis

60. Biodiversity Lab

61. Lesson 6
GENETIC ENGINEERING

62. Do Now
T Chart

63. We have been manipulating DNA for generations!
Artificial breeding
creating new breeds of animals & new crop plants to improve our food 63

64. Animal breeding 64

65. Breeding food plants “Descendants” of the wild mustard
the “Cabbage family” 65

66. Evolution of modern corn (right) from ancestral teosinte (left).
Breeding food plants
Evolution of modern corn (right) from ancestral teosinte (left). 66

67. human genome 3.2 billion bases
TACGCACATTTACGTACGCGGATGCCGCGACTATGATCACATAGACATGCTGTCAGCTCTAGTAGACTAGCTGACTCGACTAGCATGATCGATCAGCTACATGCTAGCACACYCGTACATCGATCCTGACATCGACCTGCTCGTACATGCTACTAGCTACTGACTCATGATCCAGATCACTGAAACCCTAGATCGGGTACCTATTACAGTACGATCATCCGATCAGATCATGCTAGTACATCGATCGATACTGCTACTGATCTAGCTCAATCAAACTCTTTTTGCATCATGATACTAGACTAGCTGACTGATCATGACTCTGATCCCGTAGATCGGGTACCTATTACAGTACGATCATCCGATCAGATCATGCTAGTACATCGATCGATACTGCTACTGATCTAGCTCAATCAAACTCTTTTTGCATCATGATACTAGACTAGCTGACTGATCATGACTCTGATCCCGTAGATCGGGTACCTATTACAGTACGATCATCCGATCAGATCATGCTAGTACATCGATCGATACT
human genome 3.2 billion bases

68. Can we mix genes from one creature to another?
YES! 68

69. Mixing genes for medicine…
Allowing organisms to produce new proteins
bacteria producing human insulin
bacteria producing human growth hormone 69

70. How do we do mix genes? Genetic engineering find gene
cut DNA in both organisms
paste gene from one creature into other creature’s DNA
insert new chromosome into organism
organism copies new gene as if it were its own
organism reads gene as if it were its own
organism produces NEW protein: Remember: we all use the same genetic code! 70

71. Cutting DNA DNA “scissors” GTAACG|AATTCACGCTT CATTGCTTAA|GTGCGAA
enzymes that cut DNA
restriction enzymes
used by bacteria to cut up DNA of attacking viruses
EcoRI, HindIII, BamHI
cut DNA at specific sites
enzymes look for specific base sequences
GTAACG|AATTCACGCTT
CATTGCTTAA|GTGCGAA
GTAACGAATTCACGCTT
CATTGCTTAAGTGCGAA 71

72. restriction enzyme cut site restriction enzyme cut site
Restriction enzymes
Cut DNA at specific sites
restriction enzyme cut site
GTAACGAATTCACGCTT
CATTGCTTAAGTGCGAA
restriction enzyme cut site
GTAACG AATTCACGCTT
CATTGCTTAA GTGCGAA 72

73. Uses of genetic engineering
Genetically modified organisms (GMO)
enabling plants to produce new proteins
Protect crops from insects: BT corn
corn produces a bacterial toxin that kills corn borer (caterpillar pest of corn)
Extend growing season: fishberries
strawberries with an anti-freezing gene from flounder
Improve quality of food: golden rice
rice producing vitamin A improves nutritional value
For example, a transgenic rice plant has been developed that produces yellow grains containing beta-carotene.
Humans use beta-carotene to make vitamin A.
Currently, 70% of children under the age of 5 in Southeast Asia are deficient in vitamin A, leading to vision impairment and increased disease rates. 73

74. Bacteria Bacteria are great! one-celled organisms reproduce by mitosis
easy to grow, fast to grow
generation every ~20 minutes 74

75. Bacterial DNA Single circular chromosome Other DNA = plasmids!
only one copy = haploid
no nucleus
Other DNA = plasmids!
bacteria chromosome
plasmids 75

76. There’s more… Plasmids small extra circles of DNA
carry extra genes that bacteria can use
can be swapped between bacteria
bacterial sex!!
rapid evolution = antibiotic resistance
can be picked up from environment
Mini-chromosomes 76

77. How can plasmids help us?
A way to get genes into bacteria easily
insert new gene into plasmid
insert plasmid into bacteria = vector
bacteria now expresses new gene
bacteria make new protein
transformed bacteria
gene from other organism
recombinant plasmid
vector
plasmid
cut DNA +
glue DNA 77

78. Grow bacteria…make more
transformed bacteria
gene from other organism +
recombinant plasmid
vector
plasmid
grow bacteria
harvest (purify) protein 78

79. Applications of biotechnology79

80. Homework
Genetics Review