1. Biotechnology

2. A Brave New World

3. human genome 3.2 billion bases
TACGCACATTTACGTACGCGGATGCCGCGACTATGATCACATAGACATGCTGTCAGCTCTAGTAGACTAGCTGACTCGACTAGCATGATCGATCAGCTACATGCTAGCACACYCGTACATCGATCCTGACATCGACCTGCTCGTACATGCTACTAGCTACTGACTCATGATCCAGATCACTGAAACCCTAGATCGGGTACCTATTACAGTACGATCATCCGATCAGATCATGCTAGTACATCGATCGATACTGCTACTGATCTAGCTCAATCAAACTCTTTTTGCATCATGATACTAGACTAGCTGACTGATCATGACTCTGATCCCGTAGATCGGGTACCTATTACAGTACGATCATCCGATCAGATCATGCTAGTACATCGATCGATACTGCTACTGATCTAGCTCAATCAAACTCTTTTTGCATCATGATACTAGACTAGCTGACTGATCATGACTCTGATCCCGTAGATCGGGTACCTATTACAGTACGATCATCCGATCAGATCATGCTAGTACATCGATCGATACT
human genome 3.2 billion bases

4. Biotechnology today Genetic Engineering Our tool kit…
manipulation of DNA
if you are going to engineer DNA & genes & organisms, then you need a set of tools to work with
this unit is a survey of those tools…
Our tool kit…

5. Bacteria Bacteria review one-celled prokaryotes reproduce by mitosis
binary fission
rapid growth
generation every ~20 minutes
108 (100 million) colony overnight!
dominant form of life on Earth
incredibly diverse

6. How have these little guys gotten to be so diverse??
Bacterial genome
Single circular chromosome
haploid
naked DNA
no histone proteins
~4 million base pairs
~4300 genes
1/1000 DNA in eukaryote
Genome = all the DNA of an organism
Eukaryotes
• 1000 times more DNA
• only 10 times more genes
- introns, spacers, inefficiency
How have these little guys gotten to be so diverse??

7. Transformation Bacteria are opportunists
promiscuous!?
Bacteria are opportunists
pick up naked foreign DNA wherever it may be hanging out
have surface transport proteins that are specialized for the uptake of naked DNA
import bits of chromosomes from other bacteria
incorporate the DNA bits into their own chromosome
express new genes
transformation
form of recombination
mix heat-killed pathogenic & non-pathogenic
bacteria
While E. coli lacks this specialized mechanism, it can be induced to take up small pieces of DNA if cultured in a medium with a relatively high concentration of calcium ions.
In biotechnology, this technique has been used to introduce foreign DNA into E. coli.
mice die

8. Plasmids Small supplemental circles of DNA carry extra genes
,000 base pairs
self-replicating
carry extra genes
2-30 genes
genes for antibiotic resistance
can be exchanged between bacteria
bacterial sex!!
rapid evolution
can be imported from environment
Mini-chromosomes

9. 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

10. insert “gene we want” into plasmid... “glue” together
Biotechnology
Plasmids used to insert new genes into bacteria
cut DNA
gene we want
like what?
…insulin
…HGH
…lactase
cut plasmid DNA
Cut DNA?
DNA scissors?
ligase
insert “gene we want” into plasmid... “glue” together
recombinant plasmid

11.  How do we cut DNA? Restriction enzymes restriction endonucleases
discovered in 1960s
evolved in bacteria to cut up foreign DNA
“restrict” the action of the attacking organism
protection against viruses & other bacteria
bacteria protect their own DNA by methylation & by not using the base sequences recognized by the enzymes in their own DNA 

12. What do you notice about these phrases?
radar
racecar
Madam I’m Adam
Able was I ere I saw Elba
a man, a plan, a canal, Panama
Was it a bar or a bat I saw?
go hang a salami I’m a lasagna hog
palindromes

13. Restriction enzymes Madam I’m Adam Action of enzyme
cut DNA at specific sequences
restriction site
symmetrical “palindrome”
produces protruding ends
sticky ends
will bind to any complementary DNA
Many different enzymes
named after organism they are found in
EcoRI, HindIII, BamHI, SmaI 
CTGAATTCCG
GACTTAAGGC 
CTG|AATTCCG
GACTTAA|GGC

14. Discovery of restriction enzymes
Werner Arber
Daniel Nathans
Hamilton O. Smith
Restriction enzymes are named for the organism they come from:
EcoRI = 1st restriction enzyme found in E. coli
Werner Arber discovered restriction enzymes. He postulated that these enzymes bind to DNA at specific sites containing recurring structural elements made up of specific basepair sequences.
Hamilton Smith verified Arber's hypothesis with a purified bacterial restriction enzyme and showed that this enzyme cuts DNA in the middle of a specific symmetrical sequence. Other restriction enzymes have similar properties, but different enzymes recognize different sequences. Ham Smith now works at Celera Genomics, the company who sequenced the human genome.
Dan Nathans pioneered the application of restriction enzymes to genetics. He demonstrated their use for the construction of genetic maps and developed and applied new methodology involving restriction enzymes to solve various problems in genetics.

15. restriction enzyme cut site restriction enzyme cut site
Restriction enzymes
Cut DNA at specific sites
leave “sticky ends”
restriction enzyme cut site
GTAACGAATTCACGCTT
CATTGCTTAAGTGCGAA
restriction enzyme cut site
GTAACG AATTCACGCTT
CATTGCTTAA GTGCGAA

16. chromosome want to add gene to
Sticky ends
Cut other DNA with same enzymes
leave “sticky ends” on both
can glue DNA together at “sticky ends”
GTAACG AATTCACGCTT
CATTGCTTAA GTGCGAA
gene you want
GGACCTG AATTCCGGATA
CCTGGACTTAA GGCCTAT
chromosome want to add gene to
GGACCTG AATTCACGCTT
CCTGGACTTAA GTGCGAA
combined DNA

17. Sticky ends help glue genes together
cut sites
gene you want
cut sites
TTGTAACGAATTCTACGAATGGTTACATCGCCGAATTCACGCTT
AACATTGCTTAAGATGCTTACCAATGTAGCGGCTTAAGTGCGAA
AATTCTACGAATGGTTACATCGCCG
GATGCTTACCAATGTAGCGGCTTAA
isolated gene
sticky ends
AATGGTTACTTGTAACG AATTCTACGATCGCCGATTCAACGCTT
TTACCAATGAACATTGCTTAA GATGCTAGCGGCTAAGTTGCGAA
chromosome want to add gene to
cut sites
Recombinant DNA molecule
DNA ligase joins the strands
chromosome with new gene added
TAACGAATTCTACGAATGGTTACATCGCCGAATTCTACGATC CATTGCTTAAGATGCTTACCAATGTAGCGGCTTAAGATGCTAGC
sticky ends stick together

18. How can bacteria read human DNA? human insulin gene in bacteria
Why mix genes together?
Gene produces protein in different organism or different individual
human insulin gene in bacteria
TAACGAATTCTACGAATGGTTACATCGCCGAATTCTACGATC CATTGCTTAAGATGCTTACCAATGTAGCGGCTTAAGATGCTAGC aa
“new” protein from organism
ex: human insulin from bacteria
bacteria
human insulin

19. The code is universal Since all living organisms… use the same DNA
use the same code book
read their genes the same way
Strong evidence for a single origin in evolutionary theory.

20. Copy (& Read) DNA Transformation
insert recombinant plasmid into bacteria
grow recombinant bacteria in agar cultures
bacteria make lots of copies of plasmid
“cloning” the plasmid
production of many copies of inserted gene
production of “new” protein
transformed phenotype
DNA  RNA  protein  trait

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

22. 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.

23. Transformed vertebrates
Green with envy??
Jelly fish “GFP”
Transformed vertebrates

24. Cut, Paste, Copy, Find… Word processing metaphor… cut paste copy find
restriction enzymes
paste
ligase
copy
plasmids
bacterial transformation
is there an easier way??
find
????

25. I’m a very special pig! Got any Questions?