1. Biotechnology Chapter 13

2. BIOTECHNOLOGY… the use of biological processes, organisms, or systems to manufacture products intended to improve the quality of human life

3. Applied Genetics the application of genetic information and manipulation of the hereditary characteristics of an organism to improve or create specific traits in offspring directed at changing the genomes (GENETIC MAKEUP) of organisms, to increase their utility to humans

4. Traditional Uses of Applied Genetics Selective Breeding (aka Artificial Selection) Hybridization Inbreeding

5. Selective Breeding… (aka Artificial Selection) Human selection of plants or animals (for breeding) because of a desired or useful trait man has used selective breeding to develop plants and animals with “desirable traits” nearly all domestic animals – dogs, cats, horses, and most crop plants have been produced by selective breeding selective breeding includes hybridization and inbreeding

6. Selective Breeding…of plants

7. Selective Breeding…of animals

8. Hybridization… crossing dissimilar individuals to bring together the best traits of both organisms hybrids are often healthier and hardier EXAMPLE - hybrid pansies are produced by breeding different varieties of pansies

9. ZEDONK – cross between a zebra and a donkey Hybridization - Interspecific Hybrids… mating two species, normally from within the same genus offspring display traits and characteristics of both parents offspring are often sterile

10. Hybridization - Interspecific Hybrids… Liger – cross between a male lion and a female tiger Tigon – cross between a female lion and a male tiger

11. Hybridization - Interspecific Hybrids… male DONKEY and female HORSE = MULE The hybrid mule has greater endurance, is stronger and less excitable than a horse.

12. Inbreeding… breeding individuals with SIMILAR characteristics used to maintain characteristics IN A BREED EXAMPLE – cattle breeds are maintained by inbreeding Why do we have different breeds of cattle?

13. Inbreeding…

14. New Uses of Applied Genetics DNA TECHNOLOGY

15. HUMAN GENOME PROJECT Began 1990 GOAL – to MAP AND sequence all of the human GENOME ( DNA) COMPLETED 2003 Genome = an organism’s DNA

16. Applications of Human Genome Project diagnose genetic disorders Genomics - the study and comparison of genomes Proteomics - the study and comparison of proteins Bioinformatics - the using of computer databases to deal with storage and analysis of biological data

17. APPLIED GENETICS GENE ISOLATION –WE HAVE TO BE ABLE TO CUT OUT/SEPARATE GENES…SO WE NEED “DNA SCISSORS” RESTRICTION ENZYMES

18. DNA fingerprinting or DNA profiling A technique for analyzing and comparing DNA from separate sources Used to identify criminal suspects, determine paternity or the identity of unknown persons or decomposing bodies, match ancestors to decendants DNA samples are taken from hair, blood, semen, or other biological materials No two people, except identical twins, have exactly the same DNA According to the DNA fingerprint above, who are the parents of the child? A (A+B) B (C+D) C (E+F) D (G+H)

19. DNA fingerprints of 3 people. What do persons 1 and 2 2 and 3 1 and 3 share in common?

20. CLONING process of producing an identical copy of an organism How cloning is accomplished?

21. What have we cloned? hyperlink hyperlink Sea urchins Salamander Frogs Fruit flies Carp Sheep Mouse Cows Goats Pigs Mouflon Rabbit Cat Asian Wild Ox Rhesus Monkey African Wildcat Rat Mule Horse Deer Wolves Buffalo Dog Ferrets Camel

22. Limitations of Cloning… 1. High failure rate – hit and miss procedure Process is inefficient success rate from 0.1 percent to 3 percent 2. Problems during later development Cloned animals do not live as long and tend to have health problems 3. Abnormal gene expression patterns Clones and originals have identical DNA, but will the clone express the right genes at the right time?

23. What is genetic engineering? (genetic modification/alteration) the direct human manipulation of an organism’s genetic material (DNA, chromosomes, genes) in a way that does not occur under natural conditions Genetic engineering alters the genetic makeup of an organism using techniques that… either remove genetic material (DNA) or that introduce genetic material (DNA)

24. Genetic engineering has applications in medicine, research, industry and agriculture …. and can be used on a wide range of plants, animals and microorganisms What is considered to be genetic engineering? Gene Therapy Cell Transformation Recombinant DNA Transgenic or GMO’s

25. Manipulating DNA… Today, we have expanded our use of genetic information and we are able to use techniques for manipulating (modifying) DNA. We can…. extract DNA from cells, cut it into small pieces, identify the genes and sequences in DNA make copies

26. GENE THERAPY process in which an absent or faulty gene is replaced by a normal, working gene various approaches have been taken… –bone marrow has been removed, modified in the laboratory and placed back in the body –modified viruses have been used to carry replacement genes into the body –inhalation of genetically engineered viruses containing “good” genes has been attempted Up to this point, gene therapy has not been very successful.

27. (Cell) Transformation…. process by which a cell takes in DNA from an outside (external) source Transformation occurs naturally in some species of bacteria, but it can also be accomplished by artificial means in other types of living things. the external DNA may become part of the cell’s DNA

29. Recombinant DNA – taking DNA from one organism and combining it with another organism

30. Uses Of Recombinant DNA Recombinant human insulin Recombinant human growth hormone (HGH) Recombinant blood clotting factor VIII Recombinant hepatitis B vaccine Hervicide-resistant crops Insect-resistant crops

31. Transgenic Organism… or Genetically Modified Organism (GMO) any organism containing genes from another organism (via human manipulation) Plants, animals or microrganisms that have changed through genetic engineering 8] Bacteria were the first organisms to be genetically modified. 8] cow containing genes for producing human milk proteins bacterium containing recombinant DNA

32. Genetic Diversity While applied genetics techniques often limit genetic variation, scientists are also interested in preserving the genetic diversity in organisms. WHY is it important to maintain diversity/variation?

33. How is diversity within a species maintained? 1. By mutations (chemicals, radiation, …) – by natural or artificial causes mutation = a change in the DNA 2. By polyploidy – having extra sets of chromosomes – often results in more vigor or increased size – by natural or artificial causes 3. By genetic recombination as a result of … * crossing over during prophase I of meiosis * sexual reproduction - union of 2 haploid gametes