1. Biotechnology Gene: The unit of inherited information in DNA. Gene Splicing: Using restrictive enzymes to cut DNA and add new base pairs. Recombinant DNA: Combining genes from different sources—even different species— into a single DNA Molecule.

2. The Importance of Palindromes to Genetic Engineers The sites where restriction enzymes cut the bacteria plasmid are called the restriction sites. Scientist recognizes these sites because they are palindromes. For Example: 5’ A A T G G C C A T T 3’ 3’ T T A C C G G T A A 5’

3. The Origins of Restriction Enzymes: Scientist obtain restriction enzymes from bacteria. In nature bacteria normally use these enzymes to restrict the invasion of foreign DNA, cutting the foreign DNA up into small, functionless pieces. Function of Restriction Enzymes: Restriction enzymes are used as chemical “scissors” to cut out genes.

4. Ligase: An enzyme. The mechanism of DNA ligase is to form covalent phosphodiester bonds between 3' hydroxyl ends of one nucleotide with the 5' phosphate end of another. http://www.dnalc.org/ddnalc/resources/restriction.html

5. Genetic Engineering can be Harmful New Allergens in the Food Supply Antibiotic Resistance Production of New Toxins Concentration of Toxic Metals Enhancement of the Environment for Toxic Fungi Unknown Harms to Health

6. Genetic Engineering can be Helpful Increase in the Food Supply Production of insulin and other human hormones. Development of effective vaccines against disease causing microbes. Production of natural pesticides

7. Antibiotics are used to detect the transformed plasmids Some plasmids carry resistance genes to several antibiotics. The antibiotics that worked to select transformed bacteria Ampacillin ResistanceTetracycline Resistance Kanamycin Resistance

8. Proteins that are currently Produced using Genetic Engineering Human Insulin Vaccines Human Growth Hormone Other Uses of Restrictive Enzymes Disease Resistant OrganismInsect Resistant Plants Medical ResearchLarger Crops Larger- Nutritionally Enhanced Food

9. Gene splicing is just what it sounds like: cutting the DNA of a gene to add base pairs. Contrary to the immediate image, however, no sharp instruments are involved; rather, everything is done chemically.

10. Bioethics The study of ethical problems arising from scientific advances, especially in the fields of biology and medicine.

11. Examples of Some Bioethical Issues Assisted Suicide Abortion Birth Control Growth Hormones – Performance Enhancement Drugs In Vitro Fertilization Pre-Implantation Genetic Diagnosis Genetic Modification – Genetic Engineering Cloning Stem Cell Research

13. Pre-Implantation Diagnosis - PGD

14. The pre-implantation genetic diagnosis (PGD) genetic testing procedure begins with in vitro fertilization. Embryos are formed in the lab, and then biopsied so cells can be used for genetic testing. The DNA codes of the diseases that PGD can screen for are then compared to the codes of each embryo. Only embryos with normal biopsy results free of genetic defects are used for implantation.

15. Diseases Detected with PGD Genetic Testing Pre-implantation genetic diagnosis checks for genetic and chromosomal abnormalities that cause birth defects and miscarriage. This genetic testing procedure can identify recessive sex-linked disorders, dominant sex-linked disorders, single sex gene disorders, and chromosomal rearrangements.

16. Stem Cells Totipotent Cell: Formed during reproduction, a single cell (zygote: fertilzed egg) that divides to produce all the differentiated cells in an organism, including extraembryonic tissues. Pluripotent Cell: stem cell that has the potential to differentiate into any of the three germ layers: endoderm (interior stomach lining, gastrointestinal tract, the lungs), mesoderm (muscle, bone, blood, urogenital), or ectoderm (epidermal tissues and nervous system). Pluripotent stem cells can give rise to any fetal or adult cell type. Multipotent Cell: progenitor cells can give rise to several other cell types, but those types are limited in number. An example of a multipotent stem cell is a hematopoietic cell — a blood stem cell that can develop into several types of blood cells, but cannot develop into brain cells or other types of cells. Unipotent Cell: Can give rise to only one type of cell.

17. Adult Stem Cells Multipotent Cells From Bone Marrow

18. Adult Stem Cells From Umbilical Cord

19. Embryonic Stem Cells

20. Stem Cell Development 1. Zygote: A fertilized egg. 2. Morula: A solid ball of 2-16 embryonic cells. 3. Blastula: A hollow ball of several hundred embronic cells. 4. Gastrula: Blastula pushes inward forming an inner embryonic cell layer. 5. Ectoderm: Outer embryonic cell layer. Skin, nervous system 6. Mesoderm : Middle embryonic cell layer. Muscle, bone. 7. Endoderm: Inner embronic cell layer. Digestive system.

21. Modeling Stem Cell Development Zygote 1 Cell Fertilized Egg

22. Before 3 Days 1-16 cells Morula

23. 3 - 14 Days Several Hundred Cells Blastula/Blastocyst

24. After 14 Days Several hundred and More Gastrula

26. ECTODERM: Skin, Hair, Nails, Nervous System, Brain MESODERM: Muscles, Circulatory System, Excretory System, Bones, and Cartilage, Gonads ENDODERM: Digestive and Respiratory Tract, Glands including liver and pancreas,