1. DNA Technology

2. Techniques in DNA technology
Restriction enzymes
Gel electrophoresis
PCR – polymerase chain reaction
Recombinant DNA

3. SCI.9-12.B [Indicator] - Exemplify ways that introduce new genetic characteristics into an organism or a population by applying the principles of modern genetics.

4. DNA Extraction Chemical treatments cause cells and nuclei to burst
The DNA is inherently sticky, and can be pulled out of the mixture
This is called “spooling” DNA
DNA Extraction

5. “Spooled” DNA

6. Cutting DNA
Restriction enzymes cut DNA at specific sequences
Useful to divide DNA into manageable fragments

7. Electrophoresis
DNA can be separated based on size and charge
The phosphate groups are negatively charged
DNA is placed in a gel and electricity is run through

8. Electrophoresis Negative DNA moves toward the positive end
Smaller fragments move farther and faster
Electrophoresis

9. Electrophoresis

13. Polymerase Chain Reaction
Copying DNA
Polymerase Chain Reaction
Also called PCR
A method of making many copies of a piece of DNA

14. SCI.9-12.B [Indicator] - Exemplify ways that introduce new genetic characteristics into an organism or a population by applying the principles of modern genetics.

15. Steps in Copying DNA A DNA molecule is placed in a small test tube
DNA polymerase that can work at high temps is added
Steps in Copying DNA

16. Steps in Copying DNA
The DNA is heated to separate the two strands
Primers, short pieces of DNA complementary to the ends of the molecule to be copied, are added

17. The tube is cooled, and DNA polymerase adds new bases to the separated strands
Copying DNA

18. Large amounts of DNA can be made from a small starting sample
PCR
Large amounts of DNA can be made from a small starting sample

19. Genetic Engineers can alter the DNA code of living organisms.
Selective Breeding
Recombinant DNA
PCR
Gel Electrophoresis
Transgenic Organisms
Genetic Engineering

20. Breed only those plants or animals with desirable traits
People have been using selective breeding for 1000’s of years with farm crops and domesticated animals.
Selective Breeding

21. The ability to combine the DNA of one organism with the DNA of another organism.
Recombinant DNA technology was first used in the 1970’s with bacteria.
Recombinant DNA

22. Recombinant Bacteria Remove bacterial DNA (plasmid).
Cut the Bacterial DNA with “restriction enzymes”.
Cut the DNA from another organism with “restriction enzymes”.
Combine the cut pieces of DNA together with another enzyme and insert them into bacteria.
Reproduce the recombinant bacteria.
The foreign genes will be expressed in the bacteria.
Recombinant Bacteria

23. Benefits of Recombinant Bacteria
1. Bacteria can make human insulin or human growth hormone. 2. Bacteria can be engineered to “eat” oil spills.
Benefits of Recombinant Bacteria

24. The DNA of plants and animals can also be altered.
disease-resistant and insect- resistant crops
2. Hardier fruit
% of food in supermarket is genetically modified.

25. How to Create a Genetically Modified Plant
1.Create recombinant bacteria with desired gene. 2. Allow the bacteria to “infect" the plant cells. 3. Desired gene is inserted into plant chromosomes.
How to Create a Genetically Modified Plant

26. What do you think about eating genetically modified foods?

27. Genetically modified organisms are called transgenic organisms.
TRANSGENIC ANIMALS
Mice – used to study human immune system
Chickens – more resistant to infections
Cows – increase milk supply and leaner meat
4. Goats, sheep and pigs – produce human proteins in their milk
Genetically modified organisms are called transgenic organisms.

29. Transgenic Goat .
This goat contains a human gene that codes for a blood clotting agent. The blood clotting agent can be harvested in the goat’s milk.
Human DNA in a Goat Cell

30. How to Create a Transgenic Animal
Desired DNA is
added to an egg cell.
How to Create a Transgenic Animal

32. PCR Polymerase chain reaction
This process makes millions of copies of DNA to use in DNA fingerprinting. If a single hair is found at a crime scene, there is not enough DNA for fingerprinting. So, you take the DNA from the hair, put it into the PCR machine and you get lots of DNA to run tests on.

33. Gel Electrophoresis
Gel electrophoresis is a commonly used method of separating molecules based
on their charge, size, and shape. It is especially useful in separating charged molecules of DNA and RNA. [When an electric current is applied to the gel, negatively charged molecules move
toward the positive end, and positively charged molecules move toward the negative end.] The charge, size, and
shape of a particular molecule all affect
the rate at which a molecule moves
through the gel.

34. DNA Fingerprinting
You first must have enough DNA to run a fingerprint. PCR or polymerase chain reaction is used to make enough DNA.
The DNA is then cut with restriction enzymes. The more enzymes you use, the more accurate the results.

35. 3. After the DNA is cut into small pieces, it is separated on a gel
3. After the DNA is cut into small pieces, it is separated on a gel. The gel is sometimes made of agarose. The DNA is put into little holes in the gel called wells.
4. The gel is put into a electrophoresis chamber. A liquid buffer is poured over the gel and the electricity is turned on.

36. 5. The electricity is turned on and the DNA fragments separate from each other. The largest fragments are too heavy to be carried far and the smallest fragments are carried closer to the other end.
Is the other end positively or negatively charged?