1. 1 Mendelian Genetics

2. Genetic Terminology copyright cmassengale 2 Heredity – passing of traits from parent to offspring Trait – any characteristic that can be passed from parent to offspring Genetics– study of heredity Gene – a unit of heredity located on a chromosome (one protein)

3. Gregor Johann Mendel (1822-1884) Austrian monk Taught high school and at the same time kept a garden He found that the plants’ offspring retained traits of the parents Worked mostly with pea plants Called the “Father of Genetics" 3

4. 4 He worked with pea plants because they had many different traits and could cross pollinate

5. Designer “Genes” 5 Gene – inheritable unit of information in DNA Alleles – alternate expression of the same gene; a different protein for the same trait Ex. eye color –Brown eye allele (B), Blue eye allele (b)

6. Dominant vs. Recessive Dominant - stronger of two genes expressed, will be visible if present; represented by a capital letter (R) Recessive – describing a trait that is hidden by a dominant trait; can only be expressed when the dominant gene (allele) is absent; (r) Dominant vs. Recessive

7. 7 Mendel found seven contrasting traits in the peas/pea plants T t R r Y y C c I i G g A a

8. Each trait was always carried from parent to the offspring. Tall parents produced tall offspring and yellow parents produced yellow offspring. That makes Sense! Then, Mendel crossed plants with contrasting traits. Tall X short (parents) “X” means cross with, mating.

9. This mating produced all ______offspring. Tall Why aren’t they medium? The trait for short plants seemed to be lost. Mendel called the parent plants in this first cross the P 1 generation (parent)

10. The generation produced by this cross is the F 1 generation or first filial (family) generation. P 1 TT x tt Pure Tall Short X T T tt Tt F 1 generation

11. A cross between two members of the F 1 generation produced the F 2 generation. F 1 Tt x Tt XT T t TTTt t tt F 2 generation ¾ tall plants and ¼ short plants in the F 2

12. Types of Genetic Crosses 12 Monohybrid cross - cross involving a single trait mono - one e.g. flower color Dihybrid cross - cross involving two traits di - two e.g. flower color & plant height

13. Grid system created by R.C. Punnett in the early 1900 to help solve genetics problems 13 Punnett Square

14. 14

15. More Terminology 15 Genotype – the genetic makeup of an organism; the actual genes (alleles) composing the organism (cannot be determined visually) Represented by: Rr, RR, rr Phenotype – The visible characteristics of an organism; traits which can be observed, or the traits expressed such as color of hair or eyes

16. Genotypes can be homozygous or heterozygous for a specific trait. Homozygous (pure) – the gene pair or alleles are identical (AA, aa, BB) homo-Latin for same Heterozygous (hybrid) – the gene pair or alleles are different (Aa, Bb) hetero-Latin for different The capital letter in a heterozygous pair is written first. Is it hetero or homo? Look at the case of the letter! More Terminology

17. Let’s Review 17 Parental P 1 Generation = the parental generation in a breeding experiment. ex. TT and tt F 1 generation = the first-generation offspring in a breeding experiment. (1st filial generation) From breeding individuals from the P 1 generation ex. Tt and Tt F 2 generation = the second-generation offspring in a breeding experiment. (2nd filial generation) From breeding individuals from the F 1 generation ex. TT, Tt, tt

18. Following the Generations 18 P 1 Cross 2 Pure Plants TT x tt F 1 Results in all Hybrids Tt F 2 Cross 2 Hybrids get 3 Tall & 1 Short TT, Tt, tt

19. Solving Monohybrid Crosses 19

20. P 1 Monohybrid Cross 20 Step 1: Trait(s) --- Seed Shape Step 2: Alleles --- R – Roundr – Wrinkled Step 3: Cross -- Homo Round seeds x Homo Wrinkled seeds RR x rr R R rr Rr Step 5: Genotype Genotype: Rr-hetero round-4 (100%) Genotypic Ratio: 4:0 Step 6: Phenotype Phenotype: round – 4 (100%) wrinkled – 0 (0%) Phenotypic ratio: 4:0 Step 4: Punnett Square

21. P 1 Monohybrid Cross Review 21  Homozygous dominant x Homozygous recessive  Offspring all Heterozygous (hybrids)  Offspring called F 1 generation  Genotypic & Phenotypic ratio is ALL ALIKE 4:0 or 100% of the dominant trait is visible

22. F 1 Monohybrid Cross 22 Step 1: Trait - Seed Shape Step 2: Alleles- R – Roundr – Wrinkled Step 3: Cross- Hetero Round seeds x Hetero Round seeds Rr x Rr R r rR RR rrRr Step 5: Genotype Genotype: homo round RR-1 25% hetero round Rr-2 50% homo wrinkled rr-1 25% Genotypic Ratio: 1:2:1 Step 6: Phenotype Phenotype: Round-3 (75%) & wrinkled -1 (25%) Phenotypic Ratio: 3:1 Step 4: Punnett Square

23. F 1 Monohybrid Cross Review 23  Heterozygous x heterozygous  Offspring: 25% Homozygous dominant RR 50% Heterozygous Rr 25% Homozygous Recessive rr  Offspring called F 2 generation  Genotypic ratio is 1:2:1  Phenotypic Ratio is 3:1

24. 24 What Do the Peas Look Like?

25. F 2 Monohybrid Cross (1 st ) 25 Step 1: Trait - Seed Shape Step 2: Alleles- R – Roundr – Wrinkled Step 3: Cross- Round seeds x Round seeds RR x Rr R R rR RR RrRR Rr Step 5 Genotype Genotype: homo round RR-2 (50%), hetero round Rr-2 (50%) Genotypic Ratio – 2:2 Step 6 Phenotype Phenotype: Round – 4 (100%) Phenotypic Ratio: 4:0 Round Step 4: Punnett Square

26. F 2 Monohybrid Cross (2nd) 26 Step 1: Trait - Seed Shape Step 2: Alleles- R – Roundr – Wrinkled Step 3: Cross- homo wrinkled seeds x hetero round seeds rr x Rr r r rR Rr rrRr rr Step 5: Genotype Genotype: Hetero round Rr (2) 50%, Homo wrinkled- rr (2) 50% Genotypic Ratio: 2:2 or 1:1 Step 6: Phenotype Phenotype: Round (2) 50% Wrinkled (2) 50% Phenotypic Ratio: 2:2 or 1:1 Step 4: Punnett Square

27. F 2 Monohybrid Cross Review 27  Homozygous x heterozygous (hybrid)  Offspring: 50% Homozygous RR or rr 50% Heterozygous Rr  Phenotypic Ratio is 1:1

28. Results of Monohybrid Crosses 28 Inheritable factors or genes are responsible for all heritable characteristics Phenotype is based on Genotype Each trait is based on two genes, one from the mother and the other from the father True-breeding individuals are homozygous ( both alleles) are the same

29. Mendel’s Three Laws of Inheritance

30. Mendel’s Hypothesis For each inherited trait, an individual has two copies of the gene – one from each parent There are alternate versions of genes, or alleles. (Pea flower color can be purple or white.) When two different alleles occur together, one of them may be completely expressed, while the other may have no observable effect on the organism’s appearance. (Dominant vs Recessive) 30

31. Mendel’s Hypothesis continued When gametes are formed, the alleles for each gene in an individual separate independently of one another. Thus, gametes only carry one allele for each inherited trait. When gametes unite during fertilization, each gamete contributes one allele.

32. Laws of Inheritance Mendel’s hypothesis led to laws and principles. Principle of Dominance Law of Segregation Law of Independent Assortment (to be discussed later)

33. Principle of Dominance 33 In a cross of parents that are pure for contrasting traits, only one form of the trait will appear in the next generation. Offspring that are hybrid for a trait will have only the dominant trait in the phenotype. (Yy – yellow)

34. Law of Segregation 34 During the formation of gametes (eggs or sperm - Meiosis), the two alleles responsible for a trait separate from each other. Alleles for a trait are then "recombined" at fertilization, producing the genotype for the traits of the offspring.

35. 35 Applying the Law of Segregation

36. Mendel’s Law of Segregation Alleles segregate (separate) during meiosis so each gamete gets only one allele a a A A a A a A Two choices for gametes: A or a

37. Mendel’s Law of Independent Assortment To be discussed later…