1. Lecture 29 Inheritance

2. Importance of genetics Understanding hereditary diseases and to develop new treatmentsUnderstanding hereditary diseases and to develop new treatments Donor matchesDonor matches PaternityPaternity ForensicsForensics EvolutionEvolution

3. Genetic Testing Would you want to know? Ethical concerns Cost Insurance companies

4. Difference between Meiosis and Mitosis

5. Meiosis I Interphase Prophase IMetaphase IAnaphase ITelephase I

6. Crossing Over of Nonsister Chromatids between Homologous Chromosomes

7. Meiosis II Prophase IIMetaphase IIAnaphase IITelephase II

9. Genetic Testing

10. Gel electrophoresis

11. PCR way of copying specific DNA fragments from small sample DNA material "molecular photocopying" It’s fast, inexpensive and simple Polymerase Chain Reaction

13. Genetic Testing Paternity Test $99 $299, looks at specific diseases 23 and me

14. Genes- genetic material on a chromosome that codes for a specific trait Genotype- the genetic makeup of the organism Phenotype- the expressed trait Allel- an alternative form of a gene Genetic Definitions

15. Dominance Mechanism Two alleles are carried for each trait In true-breeding individuals, both alleles are the same (homozygous). Hybrids, on the other hand, have one of each kind of allele (heterozygous). One trait is dominant, the other trait is recessive

16. Homunculus How is “heredity passed on: Spermist vs Ovists Spermist conception of a human sperm

17. Homunculus Leeuwenhoek’s black male and white female rabbit experiments: spermist “proof”

18. Mendel’s Three Principles Dominance Segregation Independent Assortment The foundation of “classical” science (1822-1884)

19. Dominance Traits of both parents inherited, but one shows over the other Traits are not blended

20. Dominance Mechanism Two alleles are carried for each trait In true-breeding individuals, both alleles are the same. Hybrids, on the other hand, have one of each kind of allele. One trait is dominant, the other trait is recessive

21. Segregation Half the gametes (egg or sperm) will carry the traits of one parent and half the traits for the other parent Pairs of alleles are separated (=segregated) during meiosis

22. Two different parental characteristics will be inherited independently of one another during gamete formation. Independent Assortment Example: flower color and leaf shape

23. Genetic Information Genes are traits “Eye color” Ear lobe connectedness Genes produce proteins Enzymes are proteins

24. Homologous Chromosomes gene: location allele: specific trait

25. Allele Example Gene = “eye color” Alleles brown blue green lavender

26. Allele Examples appearance eye color: homozygous

27. Allele Examples appearance eye color: heterozygous, brown dominant over blue

28. Genotype vs Phenotype homozygous (dominant) heterozygous homozygous (recessive) genotype phenotype appearance

29. Punnett Square If male & female are heterozygous for eye color X brown:3/4 offspring blue:1/4 offspring male female

30. PKU Each parent carries one gene for PKU. Pp Pp X P p pP P P P p p P p p Possible genotypes: 1PP 2Pp 1pp Possible phenotypes:no PKUPKU

31. Compare this to what would have happened if one parent was homozygous for sickle cell. HbA HbS X HbA HbS HbA HbS HbA HbS HbA all offspring are carriers of sickle cell trait

32. Where Does Genetic Diversity Come From? Mutation Chromosomal Aberrations Genetic Recombination (e.g., from sexual reproduction) Mutation Chromosomal Aberrations Genetic Recombination (e.g., from sexual reproduction)

33. mutation Sickle Cell Mutation CTG ACT CCT GAG GAG AAG TCT Leu Thr Pro Glu Glu Lys Ser CTG ACT CCT GAG GTG AAG TCT Leu Thr Pro Glu Val Lys Ser NORMAL Hb SICKLE CELL

34. Autosomes and Sex Chromosomes

35. Red-Green Color Blindness Sex-linked trait XCXC Y XCXC XcXc X XCXC XcXc YXCXC XCXC XCXC XCXC Y XcXc XCXC Y XcXc Normal male Normal female recessive gene Possible outcomes:X C X C X C X c X C YX c Y Normal female Normal Female (carrier) Normal male Color-blind male

36. Eunconnected earlobe econnected earlobe Eunconnected earlobe econnected earlobe allele gene PEE x ee gametes E e F1F1 unconnected connected

37. F1F1 Ee x Ee gametes 1/2 E 1/2 e E e Ee EEEe ee F2F2 1 EE 2 Ee 1 ee Punnett Square

38. Genotypes Phenotypes Experiment to determine dominant vs. recessive

39. Genetic Sleuthing My eye color phenotype is brown. What is my genotype?

40. Complexities Multiple genes for one trait Example: eye color Blended traits (“incomplete dominance”) Influence of the environment (UV, smoking, alcoholism)

41. Complexities Co-dominance-neither allele is recessive and the phenotypes of both alleles are expressed. Blood types- AB (not O); sickle cell anemia heterochromia

42. Disorders Down’s Syndrome (chrom 21) Huntington’s (chrom 4) Alzheimer’s (chrom 1, 10, 14, 19, 21)

44. Tongue Roller R = Tongue Roller r = Unable to Roll Tongue

45. Widow’s Peak W = Widows Peak w = Lack of Widow’s Peak

46. Free Ear Lobe Attached Ear Lobe E = Free Ear Lobe e = Attached Ear Lobe

47. Hitchhiker’s Thumb Hi = Straight Thumb hi = Hitchhiker’s Thumb

48. Bent Little Finger Bf = Bent Little Finger bf = Straight Little Finger

49. Mid-digital Hair M = Mid-Digital Hair m = Absence of Mid-Digital Hair

50. Dimples D = Dimples d = Absence of Dimples

51. Short Hallux Ha = Short Hallux ha = Long Hallux

52. Short Index Finger S s = Short Index Finger S 1 = Long Index Finger *Sex-Influenced Trait

53. PTC Tasting (lab activity) codes for part of the bitter taste receptor cabbage, Brussel sprouts, and broccoli phenylthiocarbamide 7

54. http://www.youtube.com/watc h?v=gCPuHzbb5hA