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13–2 Manipulating DNA

13–2 Manipulating DNA. A. The Tools of Molecular Biology DNA Extraction Homogenization : Cell walls, membranes, and nuclear material are broken Emulsification : Soap and enzymes break down membranes and emulsify lipids and proteins.

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13–2 Manipulating DNA

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  1. 13–2 Manipulating DNA A. The Tools of Molecular Biology DNA Extraction Homogenization: Cell walls, membranes, and nuclear material are broken Emulsification: Soap and enzymes break down membranes and emulsify lipids and proteins. Precipitation: Alcohol is layered on top of the solution. DNA is not soluble in alcohol and precipitates either in the alcohol or at the interface between the alcohol and the rest of the mixture. Collection: DNA can be pulled up from the interface or alcohol with a paper clip or glass rod.

  2. 13–2 Manipulating DNA Cutting DNA “Restriction Enzymes” Cut DNA at precise locations, Cut a specific sequence of nucleotides

  3. 13–2 Manipulating DNA Recognition sequences DNA sequence Cutting DNA “Restriction Enzymes” Cut DNA at precise locations, Cut a specific sequence of nucleotides Restriction enzyme EcoRI cuts the DNA into fragments. Sticky end

  4. 13–2 Manipulating DNA Recognition sequences DNA sequence Cutting DNA “Restriction Enzymes” Cut DNA at precise locations, Cut a specific sequence of nucleotides Restriction enzyme EcoRI cuts the DNA into fragments. Sticky end

  5. 13–2 Manipulating DNA DNA plus restriction enzyme Power source Longer fragments 3. Separating DNA Shorterfragments Mixture of DNA fragments Gel Electrophoresis

  6. 13–2 Manipulating DNA B. Using the DNA Sequence 1. Reading the Sequence 2. Cutting and Pasting 3. Making Copies

  7. Single strand of DNA Fluorescent dye Strand broken after A Power source Strand broken after C Strand broken after G Strand broken after T Gel 13–2 Manipulating DNA B. Using the DNA Sequence 1. Reading the Sequence 2. Cutting and Pasting 3. Making Copies p324

  8. 13–2 Manipulating DNA DNA polymerase adds complementary strand DNA heated to separate strands B. Using the DNA Sequence 1. Reading the Sequence 2. Cutting and Pasting 3. Making Copies DNA fragment to be copied p325 PCRcycles 1 DNAcopies 1 4 8 5 etc. 16 etc. 2 2 3 4

  9. 13–2 Manipulating DNA DNA polymerase adds complementary strand DNA heated to separate strands B. Using the DNA Sequence 1. Reading the Sequence 2. Cutting and Pasting 3. Making Copies DNA fragment to be copied p325 PCRcycles 1 DNAcopies 1 4 8 5 etc. 16 etc. 2 2 3 4

  10. 13–3 Cell Transformation Sneaking In You probably have heard of computer viruses. Once inside a computer, these programs follow their original instructions and override instructions already in the host computer. Scientists use small “packages” of DNA to sneak a new gene into a cell, much as a computer virus sneaks into a computer.

  11. 13–3 Cell Transformation 1. Computer viruses enter a computer attached to some other file. What are some ways that a file can be added to a computer’s memory? 2. Why would a person download a virus program? 3. If scientists want to get some DNA into a cell, such as a bacterial cell, to what sort of molecule might they attach the DNA? Sneaking In

  12. CELL TRANSFORMATION Essential Questions •What happens during cell transformation? •How can you tell if a transformation experiment has been successful? In 13.2 we talked about manipulating DNA How do we get it back into the cell? TRANSFORMATION- a cell takes in DNA from outside the cell. The DNA becomes part of the cell’s DNA REMEMBER - Griffith’s experiment

  13. TRANSFORMING BACTERIA In 13.2 we talked about manipulating DNA.How do we get it back into the cell? TRANSFORMATION- a cell takes in DNA from outside the cell. That DNA becomes part of the cell’s DNA REMEMBER - Griffith’s experiment Transforming Bacteria Foreign DNA attached to plasmid Plasmid - small circular piece of natural DNA •ensures DNA will be replicated •contains genetic marker such as resistance to antibiotic (cells that survive antibiotic have been transformed)

  14. Transforming Bacteria • Plasmid - circular piece of bacterial DNA Recombinant DNA just has to be inserted into plasmid

  15. Transforming Bacteria Bacterial Transformation

  16. Restriction Enzymes: Proteins that cut the DNA in a specific place Recombinant Plasmid

  17. Bacterial Transformation

  18. Gene for human growth hormone Section 13-3 Recombinant DNA Bacterial Transformation Gene for human growth hormone Human Cell Sticky ends Bacterial chromosome Plasmid Go to Section:

  19. Gene for human growth hormone Section 13-3 Recombinant DNA Bacterial Transformation Gene for human growth hormone Human Cell Sticky ends DNA insertion Bacterial chromosome Bacterial Cell Bacterial cell for containing gene for human growth hormone Plasmid Go to Section:

  20. Transforming Bacteria Foreign DNA attached to plasmid Plasmid - small circular piece of natural DNA •ensures DNA will be replicated •contains genetic marker such as resistance to antibiotic (cells that survive antibiotic have been transformed) Transforming Plant Cells In nature, bacteria insert plasmids into plant cells and produce tumors Researchers disable tumor producing gene and introduce foreign DNA Bacteria insert the foreign DNA into the plant

  21. Transforming Plant Cells In nature bacteria insert plasmid into plant cells that produces tumors Researchers disable tumor producing gene and introduce foreign DNA Bacteria insert the foreign DNA into the plant Sometimes possible to remove cell wall and have plants take up DNA on their own If transformation is successful, the foreign DNA is integrated into one of the host’s chromosomes.

  22. If transformation is successful, the foreign DNA is integrated into one of the host’s chromosomes. Transforming Animal Cells Similar to plants Sometimes possible to inject DNA into egg cells Usually contain marker gene Recently developed techniques enable genes to, “knock out” host gene

  23. Transforming Animal Cells Similar to plants Sometimes possible to inject DNA into egg cells Usually contain marker gene Recently developed techniques enable genes to, “knock out” host gene

  24. 13.4 Applications of Genetic Engineering •What are some examples of useful transgenic organisms? •What are the main steps involved in cloning?

  25. What are some examples of useful transgenic organisms? What are the main steps involved in cloning? Applications of Genetic Engineering In 13.2, we learned how DNA is manipulated In 13.3, we learned how foreign DNA is inserted into host cells Does this work between animals and plants?

  26. In 13.2, we learned how DNA is manipulated In 13.3 we learned how foreign DNA is inserted into host cells Does this work between animals and plants? Transgenic Organisms Contain genes from other organisms Spurred growth of Biotechnology Transgenic Microorganisms Important products •insulin •growth hormone Human genes inserted into bacteria

  27. Transgenic Microorganisms Important products •insulin •growth hormone Human genes inserted into bacteria Transgenic Animals Mice given human genes to study human immune system Livestock given genes for extra growth hormone Poultry given genes to resist infection

  28. Transgenic Animals Mice given human genes to study human immune system Livestock given genes for extra growth hormone Poultry given genes to resist infection Transgenic Plants Important part of food production NOW •52% of soybeans •25%of corn in US Built-in insecticides Built-in weed control A strain of rice with added vitamin A

  29. 13–4 Applications of Genetic Engineering Transgenic Organisms Sometimes DNA directly injected “Knockout” genes

  30. A donor cell is taken from a sheep’s udder. Donor Nucleus These two cells are fused using an electric shock. Fused Cell Egg Cell The nucleus of the egg cell is removed. An egg cell is taken from an adult female sheep. The fused cell begins dividing normally. Embryo The embryo is placed in the uterus of a foster mother. Cloned Lamb The embryo develops normally into a lamb—Dolly Foster Mother Go to Section:

  31. 13–4 Applications of Genetic Engineering: Cloning A body cell is taken from a donor animal. An egg cell is taken from a donor animal. The nucleus is removed from the egg. The body cell and egg are fused by electric shock. The fused cell begins dividing, becoming an embryo. The embryo is implanted into the uterus of foster mother. The embryo develops into a cloned animal.

  32. 13–4 Video: Clone Age Copy these questions and use them to guide your note taking during the video What is a clone? Give some examples of plants and animals that have been cloned. The video claims that there are human clones walking among us. Explain how this could be true. Would a cloned human be the same as the human he or she was cloned from? Explain

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