BIOLOGY B-4 MOLECULAR GENETICS BIOTECHNOLOGY PART 2

1. BIOLOGYB-4 MOLECULAR GENETICSBIOTECHNOLOGYPART 2 Chapters 12 & 13 B-4: Demonstrate an understanding of the molecular basis of heredity (indicators4.1-4,9)

2. Notes (B-4.4) Protein SynthesisText sec 12-3 • How are traits expressed (proteins made) in a cell? • What role do the 3 types of RNA play in making a protein? • How does transcription and translation make a protein? • Summarize transcription and translation.

3. How are traits expressed (proteins made) in a cell? DNA is the “master plan” (original copy) and can NOT leave the nucleus • RNA carries copies to the ribosome to assemble proteins • DNA = blue print : RNA = construction workers Review: A gene is a segment of DNA with instructions to make a specific protein (trait)

4. What role does RNA play in making a protein? mRNA (messenger) • Complimentary copy of DNA • Ex: DNA = TAG mRNA = AUC • Codon (code for 1 amino acid) = 3 bases Ex: AUC  Isoleucine tRNA (transfer) • Carries specific amino acid based on mRNA • Anti-codon (transports 1 amino acid) = 3 bases rRNA (ribosomal) • Makes up structure of ribosome

5. How does transcription and translation make a protein? Transcription • Makes copy of instructions (transcribes) • mRNA is the copy of DNA goes to ribosome (reminder- DNA cannot leave nucleus) Translation • Reads instructions to build protein • Ribosomes assemble amino acids into a protein (use instructions from mRNA)

6. (1st) Transcription In the Nucleus DNA is copied to Mrna mRNA leaves nucleus, goes to ribosome (2nd) Translation In the cytoplasm, Ribosome reads mRNA Codon (mRNA) calls for specific Anticodon(tRNA) Anticodon carries amino acid Amino acids are linked together to make a chain (polypetide or protein) “stop” codon releases PROTEIN Summarize protein synthesis.

7. Protein Synthesis Step 1 - Transcription Nucleus mRNA Lysine tRNA Phenylalanine Methionine Step 2 - Translation Anti-codon Ribosome codon mRNA

8. Translation Continued Growing polypeptide chain Ribosome tRNA Lysine tRNA mRNA Translation direction Ribosome

9. Practice Protein Synthesis #1 DNA  AGC GTG CCA • (Transcribe) mRNA __________________ • (Translate)tRNA ____________________ Amino Acid: __Serine; Histidine; Glycine_ #2 DNA  GTG ACA ATC • (Transcribe) mRNA __________________ • (Translate)tRNA ____________________ • Amino Acid: ___Histadine; Cysteine; Stop

10. ANSWER:Practice Protein Synthesis #1 DNA  AGC GTG CCA • (Transcribe)mRNA ___UCG CAC GGU_ • (Translate) tRNA ____ AGC GUG CCA _ • Amino Acid: __Serine; Histidine; Glycine_ #2 DNA  GTG ACA ATC • (Transcribe)mRNA __CAC UGU UAG _ • (Translate) tRNA ____GUG ACA AUC__ • Amino Acid: ___Histadine; Cysteine; Stop

11. Each codon CODES for 1 amino acid: Start codon

12. 2nd Base

13. Codon Chart / Wheel Practice: Ex: DNA AAC GGA • mRNA: _UUG CCU____ • Amino Acid: _Leucine; Proline__ (3)DNA: TAT ATT • mRNA: ________________ • Amino Acid: ____________ (4)Amino Acid: Methonine HistIdine • mRNA: _____________________ • DNA: _____________________

14. ANSWER:Codon Chart / Wheel Practice: (3)DNA: TAT ATT • mRNA: _AUA UAA_____ • Amino Acid: __Isoleucine; Stop__ (4)Amino Acid: Methonine Histidine • mRNA: __AUG _CAC or CAU__ • DNA: ___ TAC__GTG or GTA__

15. B-4.8 Mutations (sec 12-4) • What is a gene mutation? • What can cause a mutation? • Summarize the consequences of mutations in body cells. • Summarize the consequences of mutations in gametes (egg/sperm). • Can mutations be beneficial? • Explain how genetic diseases relate to mutations.

16. Different Genes = Different Traits A gene is a segment of DNA that codes for 1 protein which expresses a trait. What would happen if the DNA sequence in a gene is changed? http://www.cancer.gov/cancertopics/understandingcancer/genetesting/page7

17. What is a gene mutation? Gene mutations involve a change in a single gene (changes a single protein); . • Substitution: replaces one nucleotide • affects one amino acid • EX: Sickle Cell Anemia • Insertion or Deletion: nucleotide is added or deleted • affects EVERY amino acid beyond the mutation • http://ghr.nlm.nih.gov/handbook/illustrations/mutationtypes?show=missense Sometimes the protein will be able to function, but imperfectly… Sometimes the protein won’t function at all… Sometimes it will cause severe problems for the organism.

18. What can cause a mutation? Errors in DNA replication • DNA doubled for cell division • Small differences in copy = mutant cell http://evolution.berkeley.edu/evolibrary/article/0_0_0/mutations_04 Mutagen is anything that causes changes in DNA (causes mutations) – cause DNA to break down • Examples: UV rays, Radiation, Chemicals

19. Consequences of mutations Mutations in BODY CELLS: • ONLY effect that organism • EX: Aging (replication errors), Skin Cancer (uv rays), etc… Mutations in GAMETES (egg/sperm): • May be passed on to offspring • EX: Genetic Disorders SOME mutations are BENEFICIAL: Adaptations are mutations that increase survival

20. Genetic Diseases About 4,000 diseases stem from our genes, which began as a mutation. These genes passed from one generation to the next (parents to children) Examples: • Heart Disease, Many Cancers (breast, prostate) • Combination between genes and environment • Dwarfism, Huntington’s disease • PKU, Albinism, Cystic Fibrosis • Sickle cell http://evolution.berkeley.edu/evolibrary/article/0_0_0/mutations_06

21. http://www.cancer.gov/cancertopics/understandingcancer/genetesting/page17http://www.cancer.gov/cancertopics/understandingcancer/genetesting/page17

22. Notes (B-4.9) BiotechnologySec 13-1,2,3,4 • Explain the difference between inbreeding and hybridization. • What is a gene map? • What is a genome? • What is a GMO? Summarize types of GMO in plants and bacteria? • What is a clone? Summarize the cloning process?

23. INBREEDING : Breeding organisms with same traits Maintain same traits DRAWBACK: Recessive gene defects show up more frequently after several generations Examples: Dog Breeds are maintained through inbreeding Domestic animals & crops http://www.youtube.com/watch?v=Nmkj5gq1cQU HYBRIDIZATION:Breeding organisms with different traits Produce combination of traits BENEFIT: Often offspring are stronger (hardier) because of the increased genetic variation. Examples: “Labradoodles” Crossing disease-resistant plants with high food-producing plants ---- increase overall food production Explain inbreeding and hybridization? Selective breeding is artificially selecting and breeding only organisms with a desired trait to produce the next generation.

24. Hybridization - examples

25. videos Ligers – Hybridization • http://www.youtube.com/watch?v=txcbe4EtuUw • Ligers – Male lion w/ Female tiger • Tigon – Female lion w/ Male tiger Super Cow – Inbreeding • http://www.youtube.com/watch?v=Nmkj5gq1cQU

26. How are gene maps and genomes vital to genetic engineering? Genetic engineeringis the process of replacing specific genes in an organism to express a desired trait. Scientists Use: • Gene maps: show specific location of genes on chromosomes • Genome: all the genetic material of a species mapped out (all possible variations). The HUMAN Genome Project mapped all the DNA of human genes. This allows us to isolate, remove, and insert individual genes.

27. Genetic Engineering: GMO – transgenic organisms GMO = Organism with genes from other species inserted into its genome. • CROPS: contains genes to resist frost, disease, and insects. • BACTERIA: contains human gene for insulin or human growth hormone (create medicine) • ANIMALS: used for gene therapy trials • Onco-mice (insert gene for cancer) – test caner drugs • Obese mice (knockout gene that regulates hunger) • Glowing monkey (gene from jelly fish) – first successful primate. http://www.youtube.com/watch?v=xuWvg7Il9VY

28. Top 5 franken animals • http://www.youtube.com/watch?v=004Iycd9a30

29. Genetic Engineering: Gene Therapy GENE THERAPY = scientists insert a normal gene to replace mutated gene which can cure disease. • Limited success and use due to: • Immune system rejections • Short-lived effects (not permanent cure) • Many disorders are caused by multiple genes • Recent clinical trials: • X-linked SCID, ADA-SCID, Parkinson’s Disease • Other gene therapy studies: • Cancer, HIV,

30. Genetic Engineering: Stem Cells Stem cells are undifferentiated cells that have the potential to become specialized. • Therapy using stem cells can replace tissue that is deficient due to disease or damage. • Adult stem cells: Bone Marrow transplants, Umbilical cord transplants (currently used) • Embryonic stem cells: research stage – hopes to find treatments for Parkinson’s and other diseases.

31. Stem cells

32. Genetic Engineering: Cloning CLONE = Identical copy of a gene or an entire organism. Natural Cloning: Identical twins, Asexual reproduction, Plants (vegetative propagation – cuttings) Genetically Engineered Cloning: • DNA/gene cloning = Isolate DNA (gene) and insert into bacteria plasmid(dna) to make copies • Therapeutic Cloning = Embryo Cloning to make stem cells for research • Create organs for transplants • Reproductive Cloning = creating an entire organism; Dolly the sheep was the 1st cloned mammal 1997 • Save endangered animals / Negatives: cloning entire organisms can result in genetic disorders or health problems.

33. Plant Cloning • http://www.biotechnologyonline.gov.au/biotec/cloneplant.html

35. Cloned Cat “CC” • Left is “Rainbow” and right is her clone “CC”

36. Cloning Process • Body Cell is taken from a donor animal • Egg cell is taken from a donor animal and nucleus is removed • The egg (w/out a nucleus) is fused with the body cell…. Forms embryo • Embryo is implanted into uterus of a “foster” mother.

37. Figure 13-13 Cloning of the First Mammal Section 13-4 A donor cell is taken from a sheep’s udder. Original animal being cloned 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 Cloned Lamb The embryo is placed in the uterus of a foster mother. The embryo develops normally into a lamb—Dolly Foster Mother