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Gel Electrophoresis If DNA is millions of base pairs long, how do we get the small fragments that are shown on the gel?  Use Restriction Enzymes.

Published byClaud George Modified over 9 years ago

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Presentation on theme: "Gel Electrophoresis If DNA is millions of base pairs long, how do we get the small fragments that are shown on the gel?  Use Restriction Enzymes."— Presentation transcript:

1

2 Gel Electrophoresis

3 If DNA is millions of base pairs long, how do we get the small fragments that are shown on the gel?  Use Restriction Enzymes

4 Restriction Enzymes: Restriction Enzymes cut DNA at very specific sites Separate the base pairs of both strands Human Cut Bacterium DNA cut

5 Most restriction enzymes leave “Sticky ends”  DNA cuts that have single stranded ends  Attract corresponding base pairs  Made by special restriction (cutting) enzymes TTACG AATGCAATT TTAAGAAT CTTA TTACGTTAAGAAT AATGCAATTCTTA

6 Application of these two techniques (electrophoresis & restriciton enzymes)  Sam Sheppard  Turtles

7 Genetic Technology I  Recombinant DNA &  Bacterial Transformation

8 1. Transgenic tobacco plant?  Genetically engineered  Inserting fire fly genes into the plant  Using “cut & paste” enzymes

9 2. Genetic Engineering:  Altering the genetic makeup of an organism  By Cutting DNA from one organism and inserting fragments into a host  Recombinant DNA  Alters the allele frequency of a population by artificial means

10 Recombinant DNA:  “Recombine”  Connecting or reconnecting DNA fragments  DNA of two different organisms  Example: lab of inserting human DNA into bacteria

11 Genetic Engineering of Insulin Human DNA cut out Human DNA put into bacteria DNA Bacteria DNA is opened up Many Bacteria Grow human insulin

12 4. Transgenic Organism:  “trans” = across  “genic” = race  Contains genes from another organism  Bacteria  Virus  Human

13 5. Tobacco Recombinant DNA Process: a. Isolated DNA to be inserted into host b. Attach DNA fragment to a vehicle (vector) c. Transfer the vector to the host= Transgenic organisms

14 Vectors = vehicles  Carry foreign DNA fragments into the host  Bacteria carried the firefly DNA into the tobacco cells  Biological or  Mechanical

15 Vectors: Biological:  Virus  Bacterial plasmid (circular DNA) Mechanical:  Micropipette  Metal bullet coated with DNA

16 Recombinant DNA Uses:  Grow human hormones in bacteria cultures  Artificial sweeteners using bacteria to make amino acids  Study human diseases by inserting human DNA into mice  Replace incorrect DNA sequences  Replace harmful bacteria on plants  Nitrogen bacteria in the soil & plants to make fertilizer  Improve transport of fruits  Resist diseases  Increase protein production

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