Unit 8 - Genetics

1. Unit 8 - Genetics Probability - The likelihood of a particular event occurring. - The chance of something happening - It can be expressed as a Fraction ( ¼ ), Percent ( 25 % ), or Decimal ( .25 ) - Probability is a mathematical way of making a prediction

2. How to Determine or Calculate Probability # of Desired Outcomes Probability = # of All Possibilities To determine the odds of rolling an even # on a die: # of Even Numbers (3) # of All Numbers (6) = ½ or 50% or .50

3. Rules of Probability • Probability suggests what is Likely to happen, NOT what will Definitely happen. Ex Not all females have half male and half female kids 2) Previous outcomes DO NOT affect future outcome Ex A coin will not come up heads just because it was tails the time before 3) In order for Probability to be accurate, the sample size must be large. Ex This class is not 50% male and 50% female, but the school population is

4. Calculating Probability for Multiple Events • Multiply the probability of each event by each other Ex The odds of flipping 3 coins & they all land tails up. ½ x ½ x ½ = 1/8 .50 x .50 x .50 = .125 50% x 50% x 50% =12.5% Ex The odds of rolling a 6 three times in a row 1/6 x 1/6 x 1/6 = 1/216 .166 x .166 x .166 = .0045 or 0.45%

5. Probabilities Role in Genetics • Each parent has two sets of DNA • Only one set can be passed to the offspring. • What are the odds certain traits being passed on based on the combinations. Ex MOM DAD set “A” set “B” set “A” set “B” 1-23 1-23 1-23 1-23 Mom A & Dad A or Mom A & Dad B or Mom B & Dad A or Mom B & Dad B

7. Purebred Homozygous Dominant TRAITS Purebred Homozygous Recessive R Tongue Rolling r R r Mother’s DNA Strand # 1 Father’s DNA Strand # 2 PH-NO PH-Roll 1 Gene 2 Gene 3 Gene 4 Gene Purebred Homozygous Recessive Purebred Homozygous Recessive c Cleft c c c PH-NO PH-NO Purebred Homozygous Recessive Hybrid Heterozygous Polydactyl p p P p PH-5 PH-6 Hybrid Heterozygous Purebred Homozygous Dominant Height T t T T PH- Medium PH- Tall

8. Each parent possesses 2 strands of 23 different types of DNA • 1 strand came from their Mom & 1 strand came from their Dad • Each parent can only give one strand to their child • Each strand has hundred/thousands of segments called Genes • Each gene is the information needed to develop a Trait or Characterisitic • Some traits have many different types or forms that can show up called Alleles Ex Trait: Eye Color Alleles: Gray Brown Blue Green

9. Unit 8 – Genetics • The basic rules of Heredity were first discovered by Gregor Mendel, who conducted his experiments on garden peas (pg 256) • He was the first to determine that genes (factors) are the carriers of traits and that it takes two genes to cause a characteristic to develop Guidelines Used By Mendel • Concentrated on one trait at a time • Used large numbers organisms (trails) • Used rules of probability to check his work

10. The original Parents (P1) were Purebred Tall crossed with Purebred Short • The 1st generation offspring (F1) were all Tall • The 2nd generation offspring (F2) had some tall and some short plants

11. Law of Dominance **When two different alleles are crossed and one masks over the other Dominant - The allele that is expressed in a hybrid - Symbolized by a Capitol Letter Recessive - The allele that is masked over in a hybrid - Symbolized by a lower case letter Purebred Dominant x Purebred Recessive = Hybrid RR x rr = Rr

12. Parents Phenotype Tall & Short • Parents Genotype TT & tt • Cross parents (find all the possible offspring genotypes & phenotypes by using a Punnett Square) • 1st generation offspring phenotype Tall • Genotype Tt

14. Indicate whether it is heterozygous or homozygous: AA ______ dd _______ Bb ______ EE _______ Cc ______ Ff _______ For each genotype below determine the phenotype: (purple is dominant to white) PP ______ Pp ______ pp ______

15. B = Blue b = gold Genotype Phenotype Homozygous dominant Purebred recessive Heterozgous Hybrid Homozygous recessive

16. A tall plant (TT) is crossed with a short plant (tt). Show the cross. What % will be tall? • A Tt plant is crossed with a Tt plant. What is the phenotypic and genotypic ratio? • A heterozygous round seeded plant is crossed with a homozygous round seeded plant. Round is dominant to wrinkled. Show the cross. (Use letter R)

17. Unit 8 - Genetics • Each individual has two alleles/genes for each trait, but only has the ability to pass on one of them to its offspring Law of Segregation - The random passing of only one of an organism’s two alleles to its offspring ** The alleles/genes segregate or separate because of Synapsis in Anaphase I of Meiosis I **The new offspring must also have 2 alleles for each trait and it will receive only one from each parent. This results in 4 diff. possible combinations instead of 2

18. Pedigree Charts **A chart that is used in human genetics to analyze Mendelian inheritance of certain traits, especially diseases. Pedigree Chart Rules: Males:Are represented by a square shape Females:Are represented by a circle shape Husband & Wife: Are represented by a line between a square and a circle Children: Are represented by lines coming down from the line between husband & wife

19. Which color is dominant? RED PINK WHITE

20. Law of Incomplete Dominance Traits Definition When neither of the two genes are dominant or recessive, there is a blending of the two traits where they meet in the middle Example: When red colored petunias are crossed with white petunias some pink petunias show up in the offspring.

21. ** We use the same capital letter for both since neither is dominant or recessive to each other. A prime ‘ or apostrophe is used to differentiate the letters. GenotypePhenotype RR = red R’R’ = white R’R or RR’ = pink

22. Parents: Red x White RR x R’R’ R’ R’ R RR’ RR’ Results: 100% Pink Phenotype 100% RR’ Genotype R RR’ RR’ ** Now do a cross between 2 pink flowers

23. Human Blood Types & Co-Dominance • The human blood gene has three different alleles; 2 dominant & 1 recessive. More alleles mean more combinations, which results in more phenotypes. • The three alleles are; IA , IB , and i • They result in four blood types: A, B, AB, & O

24. Law of Co-Dominance: Where two different alleles are paired and BOTH are dominant. Both phenotypes show up independently without blending • Both the IA and IB alleles are dominant over the i allele. • Neither the IA nor the IB alleles are dominant over each other.

25. The blood gene cause Antigens (Protein Tags) to form on the red blood cells (RBC). The type of antigen determines the type of blood (phenotype). • Allele IA produces A antigens, IB produces B antigens, and i does not produce any antigens. • Chemicals called antibodies are also found in blood in the liquid plasma part. Antibodies react with antigens by clotting all RBC’s that have the improper antigen together.

27. In blood transfusions we must consider the receivers antibodies & the donors antigens (do they conflict?) According to the chart: Type A blood can receive blood from . . . Type B blood can receive blood from . . . Type AB blood can receive blood from . . . Type O blood can receive blood from . . . Universal Donor = Type O Universal Receiver = Type AB

28. IT TAKES ALL TYPES • The myth that, “my blood type is common, so there are plenty of donors,” is just that, a myth. The more people there are in your blood group, the more that will need your donation. The reverse is also false. “My blood type is so rare, no one will need a donation.” The truth of the matter is, your community blood bank needs all types. From the most common O+’s to the rarest AB-’s. So help save a life today, give the gift of life, GIVE BLOOD! O + . . . 37% O- . . . 7% A + . . . 33% A- . . . 6% B + . . . 11% B- . . . 2% AB+ . . . 3.4% AB- . . . .6%

29. Blood Typing Problems • Mom is heterozygous type A blood. Dad is heterozygous type B blood. What % of their kids would be type A? Type B? Type AB? Type O? • Mom is genotype AB. Dad is genotype Ai. What % of their kids would be type A? Type B? Type AB? Type O? • Mom is heterozygous type B blood. She had a baby with type A blood. She thinks the father is Mr. Y. He is type AB. Could Mr. Y be the father? • A mom who is genotype Ai had a baby who is type A blood. What are the potential genotypes of the father?

30. Sex-Linked Traits Are you Colorblind?

33. Sex-Linked Traits Definition A gene/trait that is found on the sex chromosomes (X or Y) Example Hemophilia and Red-Green Colorblindness are recessive traits found on the “X” chromosome

34. Sample Dad is colorblind and Mom is totally normal. What is the probability of having a colorblind child? XC Y X XCX XY X XCX XY

35. Sample Mom is colorblind and Dad is totally normal A) What is the probability of having a colorblind child? B) What is the probability of their son being colorblind? C) What is the probability of their daughter being colorblind?

36. In the recessive sex-linked traits females can be “carriers.” They do not have the trait, but they carry it on their X chromosome and can pass it on to their offspring. • This is possible because females have two “X” chromosomes. The normal X chromosome is dominant to the defective X CorH chromosome and masks the defective trait. • Males are more likely to get sex-linked traits because they either have the trait or they don’t. Males do not have another X chromosome to mask over the defective X CorH. Their other chromosome is the Y chromosome.

37. Mom is carrier for colorblindness and Dad is colorblind. What would be the phenotypic ratio of the offspring? XC X XC XCXC XCX Y XY XCY 2 Colorblind : 2 Normal

38. 2) Mom is a carrier for Hemophilia and Dad is normal. What are the chances of them having a child who is a Hemophiliac? A male who is a Hemophiliac? A female who is a Hemophiiac? Xh X X XX XhX 25% Hemophilia 50% Male Hemophilia XY Y XhY 0% Female Hemophilia