1. UNIT 4
GENETICS

2. Chapter 11
Heredity

11. “hairy ears” (hypertrichosis)- due to holandric gene
“hairy ears” (hypertrichosis)- due to holandric gene (Y chromosome)-only occurs in males. Appears in all sons.

13. Polydactyly- having extra fingers

14. Wendy the Whippet. Double mutation of both myostatin gene.

15. A 31-year-old Chinese man (shown on right) whose body is 96 per cent coated in hair has an extra chunk of DNA that could explain his condition – called congenital generalized hypertrichosis terminalis (CGHT).

19. ‘Myths and Mutants’
Work with animals led to recognition of heritable traits in humans
Stories of heritable deformities in humans appear in myths and legends (e.g. cyclops, giants, etc.)
60 birth defects on Babylonian clay tablets (5000 years ago)
Knowledge of traits played role in shaping social customs and mores (e.g. choosing a wife/husband)

20. I. Chromosomes, Mitosis and Meiosis
A. You have many types of specialized cells in your body
1. Cells can be divided into two types:
a. Body cells that make up most of your body tissues and organs. **These cells undergo a special type of cell division called Mitosis in which each new cell has an exact copy of DNA as the parent cell.

21. b. Sex Cells in your reproductive organs (the ovaries and testes)
1). Called gametes, which form the egg and sperm cells.

22. 2. Gametes contain the DNA that will be passed to offspring in chromosomes

23. B. Each species has characteristic number of chromosomes per cell.
Ex. Humans have 46 or 23 pairs of chromosomes
Dogs have 78 or 39 pairs of chromosomes
Donkeys have 62 or 31 pairs of chromosomes.   
***Complexity of an organism is not determined by the number of chromosomes
***Organisms differ from each other because of way genes are expressed, not because they have different genes.

24. So, now you know!
Your cells have body and sex chromosomes depending on the cells they are found in!
A. Your body cells have 23 pairs of homologous chromosomes
In other words, you have two pairs (diploid) of chromosomes in each body cell- one from father and one from mother

25. Therefore, you have 22 homologous chromosomes in your body cells.
a. Each homolog is very similar to each other
- same length and carry same genes 

26. Sex chromosomes- one pair (Haploid) of non-homologous chromosomes
1. Directly control development of sexual characteristics
2. Very different in humans (not homologous)
    
a. X chromosome- female
b. Y-chromosome- male
Sex chromosomes

27. Sexual reproduction involves fusion of sperm and egg and is called fertilization
  a. results in genetic mixture of both parents
Remember: Egg and sperm only have half usual number of chromosomes (haploid). Fertilization results in a diploid cell.

28. Review: Diploid and Haploid cells
  a. Body cells are diploid (two copies of each chromosome)
  b. Sperm and egg are haploid (have one copy of each chromosome) 

29. Maintaining the correct number of chromosomes is important to survival of organisms
**This is example of nondisjunction=mutation

30.  Sex Cells undergo process of meiosis to form sperm and eggs.  
a. diploid cell divides into haploid cell during meiosis

31. Meiosis differs from mitosis in significant ways.

32. Meiosis vs. Mitosis Videos
Fill in worksheet while watching and following films
Mitosis basics (8 min)
Meiosis basics (8 min)

33. II. Mendel and Heredity
A. Gregor Mendel laid the groundwork for genetics
1. Traits are distinguishing characteristics that are inherited.
2. Genetics is the study of biological inheritance patterns and variation.
3. Gregor Mendel showed that traits are inherited as discrete units.
4. Many in Mendel’s day thought traits were blended. 

34. B. Mendel’s data revealed patterns of inheritance
1. Mendel studied plant variation in a monastery garden
2. Mendel made three key decisions in his experiments
a. Control over breeding
b. Use of purebred plants
c. Observation of “either- or” traits (only appear two alternate forms)

35. 3. Experimental design
a. Mendel chose pea plants because reproduce quickly and could control how they mate 

36. b. Crossed purebred white-flowered with purebred purple-flowered pea plants.
1). Called parental, or P generation
2). Resulting plants (first filial or F1 generation) all had purple flowers 

37. c. Allowed F1 generation to self-pollinate
  1). Produced F2 generation that had both plants with purple and white flowers)
2). Trait for white had been “hidden”, it did not disappear. 

38. d. He began to observe patterns- Each cross yielded similar ratios in F2 generation (3/4 had purple, and 1/4 white)   

39. 4. Mendel made three important conclusions
  a. Traits are inherited as discrete units (explained why individual traits persisted without being blended or diluted over successive generations)

40. b. Two other key conclusions collectively called the law of segregation
1). Organisms inherit two copies of each gene, one from each parent
2). Organisms donate only one copy of each gene in their gametes
**Remember: two copies of each gene segregate, or separate, during gamete formation

41. Aa represents the two copies of genes an individual received from mom and dad (one from each). They are able to donate either an A or an a to their offspring

42. Introduction to mendelian genetics Bozeman
dAY
Introduction to Punnet Squares and monohybrid crosses film (8 min) Amoeba Sisters

43. III. Traits, Genes, and Alleles
A. The same gene can have many versions
1. gene- a “piece” of DNA that provides a set of instructions to a cell to make a certain protein.

44. Most genes exist in many forms (called alleles)
You have two alleles for each gene` 

45. 2. Homozygous- means two of same allele
3. Heterozygous- two different alleles 

46. B. Genes influence the development of traits
1. Genome- is all the organisms genetic material

47. 2. Genotype- refers to genetic makeup of a specific set of genes
3. Phenotypes- physical characteristics of organism (wrinkled or round seeds)

48. Genotypes and phenotypes
Bozeman (12 min) Optional: Reviews transcription/translation/mutations…gene to phenotypes

49. C. Dominant and Recessive Alleles
1. Dominant alleles- allele that is expressed when two different alleles or two dominant alleles are present (use capital letter to represent)

50. 2. Recessive alleles- only expressed if have
2. Recessive alleles- only expressed if have two copies of recessive present (use small-case letter to represent)
3. Homozygous dominant = TT
4. Heterozygous = Tt
5. Homozygous recessive = tt 

51. D. Alleles and Phenotypes
1. Both homozygous dominant and heterozygous genotypes yield a dominant phenotype.
2. Most traits occur in a range and do not follow simple dominant-recessive patterns

52. V. Traits and Probability
A. Punnett squares illustrate genetic crosses
1. Used to predict possible genotypes resulting from a cross
a. Axes of grid represent possible gamete genotypes of each parents
b. Boxes show genotypes of offspring
c. Can determine ratio of genotypes in each generation

53. Punnett Square parents gametes Dominant Allele Possible offspring
Recessive allele
homozygous
heterozygous

54. B. Monohybrid cross involves one trait
1. Homozygous dominant X Homozygous recessive
Genotypic ratio
100% Ff
Phenotypic ratio
100% purple

55. 2. Heterozygous X Heterozygous
Genotypic ratio
1:2:1
Phenotypic ratio
3:1

56. 3. Heterozygous X Homozygous recessive
Genotypic ratio
1:1
Phenotypic ratio

57. Monohybrid traits and Punnet squares
Amoeba sisters and Bozeman
(8 min)
(12 min)

58. Monohybrid cross activities

59. C. Test Cross- a cross between organism with an unknown genotype and an organism with a recessive phenotype

60. D. Dihybrid cross involves two traits
1. Mendel also conducted dihybrid crosses- wondered if both traits would always appear together or if they would be expressed independently of each other
2. Mendel discovered phenotypic ratio in F2 generation as always 9:3:3:1 regardless of combination traits he used when parents are heterozygous for both traits.

62. 3. Mendel’s dihybrid crosses led to his second law,the law of independent assortment.
 4. The law of independent assortment states that allele pairs separate independently of each other during meiosis 
So, the parent will give up either a A or an a to offspring AND they will give up either a B or a b to offspring= ½ ( A or a) x ½ (B or b) = % probability an allele will pair up during meiosis

63. Dihybrid Crosses
Ameoba sisters (8 min)

65. E. Heredity patterns can be calculated with probability
1. probability - the likelihood that a particular event will happen
2. Probability applies to random events such as meiosis and fertilization 

66. Bozeman probability

67. VI. Meiosis and Genetic Variation
A. Sexual reproduction creates unique gene combinations
1. Sexual reproduction creates unique combination of genes
a. independent assortment of chromosomes in meiosis
b. random fertilization of gametes

68. 2. 223 possible sperm or egg cells combinations produced
223 X 223 = about 70 trillion different combinations of chromosomes

69. Probability Bozeman probability

70. B. Crossing over during meiosis increases genetic diversity
1. crossing over - exchange of chromosome segments between homologous chromosomes during Prophase I of Meiosis I
2. Results in new combination of genes 

71. C. Linked genes - genes located on the same chromosome inherited
C. Linked genes - genes located on the same chromosome inherited together.
1. Closer together they are high chance of inheriting together
2. If genes far apart, crossing-over may separate them
3. Gene linkage used to build genetic map of many species

73. Incomplete Dominance
Heterozygous phenotype is somewhere in between the two homozygous phenotypes
Ex. Red and white flowers blend to give pink flowers

74. Codominance Both alleles contribute to the phenotype. Both traits show
Ex. Blood types

75. Not the same thing!!!

76. Martian genetics activity
Alien genetics practice problems
End of unit 