13 4 genetic engineering
1 / 15

13-4: Genetic Engineering - PowerPoint PPT Presentation

  • Uploaded on

13-4: Genetic Engineering. GMOs. Genetically Modified Organisms. Take a gene from a sea anemone that makes them glow in the dark and insert it into the DNA of a puppy and BAM ! …. Glow-in-the-Dark Puppies!!. Not for sale in the U.S.

I am the owner, or an agent authorized to act on behalf of the owner, of the copyrighted work described.
Download Presentation

PowerPoint Slideshow about '13-4: Genetic Engineering' - abiola

An Image/Link below is provided (as is) to download presentation

Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author.While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server.

- - - - - - - - - - - - - - - - - - - - - - - - - - E N D - - - - - - - - - - - - - - - - - - - - - - - - - -
Presentation Transcript

13 4 genetic engineering


Genetically Modified Organisms

13 4 genetic engineering

Take a gene from a sea anemone that makes them glow in the dark and insert it into the DNA of a puppy and BAM!…

Glow-in-the-Dark Puppies!!

Not for sale in the U.S.

13 4 genetic engineering

With the increasing ability of humans to manipulate genes, we are now able to use geneticengineering technology for man’s benefit.

This field of industry is called biotechnology, and it is changing the way humans interact with the natural world.

13 4 genetic engineering

Because all organisms are made up of the universal genetic code (DNA), it is possible to construct organisms that are transgenic, meaning they contain the genes of other organisms.

13 4 genetic engineering

Transgenic microorganisms have revolutionized medicine, because we can transform bacteriacultures to produce human proteins.

  • Example: People with insulin-dependent diabetes are now treated with pure human insulin produced by human genes inserted into bacteria.

  • Steps:

  • 1. Use restriction enzyme to cut out insulin gene from human DNA

  • 2. Insert human DNA into bacteria

  • 3. Extract insulin from bacteria

Old school genetic modification
Old school Genetic Modification because we can transform

Genetically modified organisms
Genetically-Modified Organisms because we can transform

  • Mammals – transgenic mice

    • Genes knocked out to test tissue-specific disease

    • How could this be helpful?

  • EnviroPig – produce enzyme

    • Less costly to feed

    • Reduced phosphorous waste

    • Potential for reduced

      “dead zone” in coastal waters?

Dead zone
Dead Zone because we can transform

  • Algal bloom in Gulf of Mexico, emptying from Mississippi.

  • This type of area is considered a ‘dead zone’ because the massive amount of algae deplete the area of oxygen leaving it completely devoid of marine life.

  • Why do you think this is occurring here?

  • How could this be related to EnviroPig?

Transgenic maize
Transgenic Maize because we can transform

  • Bt Corn is a variety of corn that has been genetically altered to express a Bacillus thuringiensis(Bt) toxin

  • This bacteria produces a protein that can be used as a pesticide

Transgenic maize1
Transgenic Maize because we can transform

  • The effects of Bt corn on non-target species has been studied. Why?

  • Studies on monarch caterpillars show that they have not suffered due to Bt corn.

  • In the US, farmers must plant non-Bt corn near Bt corn. Why would this be law?

  • Pests could eventually develop resistance to Bt

  • Safety issues – liver, kidney, and heart toxicity in rats tested with GM maize

Arguments against gmos
Arguments against GMOs because we can transform

  • GMOs spreading into non-GMO food supplies

    • Wind-borne seeds

    • Cross-pollination

  • GMO-targeted pests developing resistance

  • Health / nutrition of GM foods

  • Environmental impact of GM monocultures

Arguments for gmos
Arguments for GMOs because we can transform

  • Reduce need for pesticides, herbicides, fungicides, etc.

  • Reduce irrigation needs

  • Reduce temperature, pH, climate demands

  • Increase crop yields

  • Quick results in countries that are struggling

13 4 genetic engineering

A because we can transform clone is an individual or cell that is genetically identical to it’s parental cell(s). This process was once considered impossible, but in 1997 Scottish scientist Ian Wilmut successfully cloned a sheep named Dolly.

13 4 genetic engineering

The ability to clone animals holds great promise for medicine in the areas of stem-cells research and disease control/cure. However it is also highly controversial with regard to the possibility of human cloning.