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Chapter 3: Mendelian Inheritance Student Learning Objectives Upon completion of this chapter you should be able to: 1. Recognize the importance of Mendel’s work to the study of inheritance. 2. Construct Punnett square diagrams of one- and two-factor crosses to predict phenotypic and genotypic ratios of offspring. 3. Recognize the importance of the chromosome theory of inheritance to the study of genetics. 4. Analyze pedigree diagrams for patterns of inheritance. 5. Apply the rules of probability (sum, product, and binomial expansion) to the study of patterns of inheritance. 6. Use the chi square test to examine the validity of a hypothesis. 3.1 Mendel’s Study of Pea Plants Overview The first section of this chapter provides an introduction to Mendel’s contributions to the study of genetics. Mendel’s success is based on many factors. These include his development of a mathematical, or empirical approach, to analyzing patterns of inheritance, and his exceptional ability to design quality experiments to test his ideas. Mendel’s experimental approach centered on the use of the pea plant as a model organism. It is unlikely that Mendel was truly interested in the genetics of peas directly, but he recognized that this organism had the characteristics necessary to study inheritance. First, it was relatively easy to grow. Second, it had easily identifiable variants of traits, and third, he could easily self-fertilize the plants and produce true-breeding lines. These characteristics of a model organism are still recognized by geneticists in modern studies of inheritance. Outline of Key Terms Stigma Fertilization Cross-fertilization Self-fertilization Characters Traits Variants True-breeding line Strain Pangenesis Blending hypothesis of inheritance Hybridization (Crossed) Hybrids Anthers Pollen grains Sperm (male gamete) Ovaries Ovules Egg (female gamete) Focal Points Flower structure, pollination, and cross-fertilization in peas (Figures 3.2 and 3.3) The seven characters that Mendel studied (Figure 3.4) - 27 - Exercises and Problems For questions 1 to 6, complete the sentence with the most appropriate term(s): 1. The scientific name for the garden pea is _________. 2. In pea plants, male gametes are produced within pollen grains formed in the ________. 3. In pea plants, female gametes are contained within ________ that form in the ovaries. 4. For fertilization to occur, a pollen grain lands on the ________, thus stimulating growth of a pollen tube. 5. A variety that continues to produce the same characteristic after several generations of selffertilization is called a ________ line. 3.2 Law of Segregation Overview Mendel’s single-factor (or monohybrid) cross is recognized by many scientists as a classic model of the experimental method. Mendel hypothesized that inheritance patterns followed natural laws, and thus could be quantified using mathematical principles. His experimental system (pages 44-47) provided clear evidence of several fundamental principles of genetics. The concept of dominance The particulate theory of inheritance The law of segregation It is important to note that earlier researchers had suggested many of these same principles, but it was Mendel’s experimental system that provided the first direct evidence. Outline of Key Terms Monohybrid cross (single-factor cross) Monohybrids Empirical approach Empirical laws Generations P generation (parental) F1 generation (first filial) F2 generation (second filial) Particulate theory of inheritance Gene Allele Law of segregation Segregate Dominant Recessive Homozygous Heterozygous Genotype Phenotype Punnett square Focal Points Single-factor crosses and the law of segregation (pages 44-47 and Figure 3.6) The use of Punnett squares to visualize genetic crosses (pages 47-48) -9- Exercises and Problems For questions 1 to 12, match the definition on the left with the correct term on the right. _____ 1. A genetic experiment involving a single trait _____ 2. The offspring of two distinct individuals with different characteristics _____ 3. The first generation in Mendel’s monohybrid cross _____ 4. The study of the mathematical relationships of an observation _____ 5. A variation of a gene _____ 6. The genetic composition of an individual _____ 7. An individual who has two different alleles for a trait _____ 8. The observable characteristics of an organism _____ 9. An individual with two identical alleles for a trait _____ 10. The basic unit of heredity _____ 11. Used to predict the outcome of genetic crosses _____ 12. The second generation in Mendel’s monohybrid cross a. monohybrid cross b. allele c. genotype d. hybrid e. P generation f. empirical approach g. phenotype h. heterozygous i. homozygous j. gene k. F1 generation l. Punnett square In pea plants, T (Tall) is dominant to t (dwarf). Determine the genotypic and phenotypic ratios in the offspring in each of the following cases: 13. TT plant is crossed to a tt plant. 14. Tt plant is crossed to a Tt plant. 15. Tt plant is crossed to a tt plant. 3.3 Law of Independent Assortment Overview The two-factor crosses (or dihybrid crosses) are an extension of the monohybrid cross and were used by Mendel to further explore the results of the single-factor cross. It is important to note the relationship between Mendel’s observations and the conceptual level of genes and alleles (see text Figure 3.8). The fact that during a two-factor cross the traits segregate from each other, producing non-parental offspring, is the basis of his second law of heredity, more often called the law of independent assortment. As was the case with monohybrid crosses, you can also use Punnett squares to predict the outcome of crosses involving two genes that assort independently (Figure 3.10). For crosses involving three or more genes, the Punnett square becomes too cumbersome. A better approach involves the forked-line method, which is shown in Solved Problem 4 (pages 64-65). The section also examines the concept of testcrosses (page 52), which Mendel used to verify independent assortment. Finally, the discussion turns to modern genetics, which attempts to understand the relationship between the molecular expression of genes and the outcome of traits. Note that the recessive variants Mendel studied are due to loss-of-function mutations that rendered the genes defective, and thus incapable of producing a functional protein. -9- Outline of Key Terms Multiplication method Forked-line method Dihybrid testcross Loss-of-function alleles Dihybrid cross (two-factor cross) Genetic recombination Nonparentals Mendel’s law of independent assortment Focal Points Mendel’s analysis of dihybrid crosses (Figure 3.8) Mendel’s law of independent assortment (Figure 3.9) A Punnett square for a dihybrid cross (Figure 3.10) Exercises and Problems 1. How many different types of gametes are produced by a plant that is AaBB? List them. 2. How many different types of gametes are produced by an animal that is AABbCc. List them. Consider an individual with genotype AaBb. What is the phenotypic ratio in the offspring if … 3. … this individual is self-fertilized? 4. … this individual is test-crossed? A plant that is AaBbCc is crossed with one that is aaBbCC. What is the likelihood of obtaining an offspring that is …. 5. …. heterozygous for all three genes? 6. …. homozygous recessive for all three genes? 7. One of the pea characteristics studied by Mendel was seed shape. The two phenotypes that he studied were round and wrinkled seeds. In his experiments, Mendel obtained a pure-breeding line of round seeded plants and a pure-breeding line of wrinkled seeded plants. When these lines were crossed, the F1 generation always yielded round seeds. Based on this information: a. Which of the two traits is the dominant trait? b. If two individuals from the F1 generation were crossed, what would be the phenotypic and genotypic ratios of their offspring? - 10 - 8. As a geneticist you decide to attempt to recreate some of Mendel’s experiments. In your experiment you decide to use the traits of plant height (tall versus short) and pod color (yellow versus green). You obtain a pure-breeding line of plants that is tall (T) with yellow pods (g) and a second line that is short (t) with green pods (G). a. Using the Punnett square below, outline the cross of these parental strains. b. What is the genotypic and phenotypic ratios of the F1 generation? c. You now cross two members of the F1 generation to obtain an F2 generation. Diagram this cross using a Punnett square. d. What is the phenotypic ratio of the offspring? 9. Using the information from question 8, if you obtained 1248 offspring in the F2 generation, how many of each phenotypic class would you expect to have? -9- 10. In peas, round seed (R) is dominant to wrinkled (r), and yellow seed (Y) is dominant to green seed (y). A plant that is RRYY is crossed to one that is rryy. The F1 generation is then selffertilized. What is the probability of getting a wrinkled, yellow plant in the F2 generation? 11. Use the information from question 10 to determine the probability of getting a true-breeding round, yellow plant. 3.4 Chromosome Theory of Inheritance Overview Chapter 2 introduced you to the process of cell division. In this chapter we have examined Mendel’s principles of inheritance. Although both meiosis and Mendel’s principles were known at the start of the 20th century, it took the work of many scientists to understand that Mendel’s laws were based on the stages of meiosis. The chromosome theory of inheritance was proposed independently by Walter Sutton and Theodor Boveri. However, other researchers contributed to its development and proof (Please refer to Table 3.1). The principles of the chromosome theory of inheritance are provided on page 54 of the text. Although these seem obvious to us today, at the time they were developed they were revolutionary ideas. The important aspect of this section is how the chromosome theory relates to the principles of inheritance first established by Mendel. Note that both the law of segregation (Figure 3.16) and law of independent assortment (Figure 3.17) are based upon the events of meiosis. You need to study and understand these figures well before proceeding. Outline of Key Terms Chromosome theory of inheritance Focal Points Mendel’s law of segregation explained (Figure 3.11) Mendel’s law of independent assortment explained (Figure 3.12) Exercises and Problems For questions 1 to 3, complete the sentence with the most appropriate term(s): 1. The chromosome theory of inheritance was proposed by Walter ______ and Theodor ______. 2. The law of segregation is explained by the separation of homologs in ________ of meiosis. 3. The law of independent assortment is explained by the random alignment of bivalents during ________ of meiosis. 4. A cell has three pairs of chromosomes. In how many different ways can these chromosomes line up in the metaphase plate during meiosis I? 5. Assuming no crossing-over, how many different types of gametes can the above cell produce? - 10 - 3.5 Studying Inheritance Patterns in Humans Overview Mendel’s work was made possible by the fact that he could selectively breed the peas and then analyze large numbers of offspring to establish mathematical patterns. However, this is not the case with many organisms, including humans. Instead, human geneticists must observe patterns of inheritance in families to establish the genetics of a trait. This is called a pedigree analysis (pages 56-57). Pedigree studies differ from the crosses conducted by Mendel in that they do not involve large numbers of offspring and the analysis of ratios of phenotypes in the offspring. However, they do abide by the Mendelian concepts of dominance and the segregation of traits first described by Mendel. Outline of Key Terms Pedigree analysis Focal Points Pedigree analysis (Figure 3.13) Exercises and Problems 1. As a genetic counselor you have been asked by a family to study the inheritance of cystic fibrosis over the past three generations. The pedigree diagram for this family is below. a. Based on this diagram, is cystic fibrosis a dominant or recessive trait? b. Give the genotypes of the following individuals: II-2 II-3 II-4 III-5 c. Individual III-5 would like to start a family. What are the chances that she will pass a cystic fibrosis allele on to her offspring? -9- 3.6 Probability and Statistics Overview One of Gregor Mendel’s greatest contributions to the study of inheritance was the application of mathematical and statistical principles to observed patterns of inheritance. While the Punnett square analysis of the previous section is very useful to visualize a genetic cross, it has severe limitations in crosses involving more than three traits or when predicting the probability of certain genotypes or phenotypes in the offspring. This section of the text introduces the concepts of probability and statistics to the study of inheritance. The challenge of this section is to identify which method to use to solve the problem at hand. The table below provides a quick summary of these methods. Method Application Algebraic Expression Sum rule To determine the probability of one event OR another occurring. To determine the probability of two events occurring, in a specific order. To determine the probability that a proportion of the events will have the selected outcome, regardless of order To test the goodness of fit between the observed and the expected results. P(a) + P(b) Product rule Binomial Expansion Chi square test P(a) x P(b) P= n! px q n-x x! (n-x)! X2 = ∑ (O- E)2 E The laws of probability may be applied to the study of inheritance. The Punnett square diagrams used in the previous sections are basically graphic representations of probable outcomes given a certain set of parents. However, at levels above a two-factor cross, Punnett squares become very cumbersome to use. The sum and product rules of probability analysis greatly aid the study of multifactorial crosses. To determine the probability of a three-factor cross, first determine the probability of each trait independently, then multiply the individual probabilities (product rule) to get the probability of all three events being present in the offspring. If you are a visual learner, then the forked-line method may be applied. This is simply an extension of the product rule outlined above. It is presented on page 64-65 of the text. Outline of Key Terms Hypothesis testing Chi square test Goodness of fit Null hypothesis Degrees of freedom P values Probability Random sampling error Product rule Sum rule Binomial expansion equation Multinomial expansion equation - 10 - Focal Points The use of product and sum rules to determine probability (pages 58-59) Binomial expansion (pages 59-60) Hypothesis testing and chi square tests (pages 60-62) Exercises and Problems For questions 1 to 5, choose which of the following methods would best be applied to determine the required information. a. Chi square test b. Sum rule c. Binomial expansion d. Product rule _____ 1. The probability of a couple having three girls out of five offspring. _____ 2. The probability that one or another event will occur in the next generation. _____ 3. The probability of flipping a coin five times, and getting heads each time. _____ 4. To determine if the observed phenotypic ratios of a two-factor cross fit the expected ratios by Mendelian inheritance. _____ 5. The probability of an event occurring in a specific order each time. For questions 6 to 10, match each of the following terms with its most appropriate answer. _____ 6. _____ 7. _____ 8. _____ 9. _____ 10. Degrees of freedom P values Goodness of fit Probability Random sampling error a. the chance that a future event will occur b. the deviation between observed and expected outcomes. c. the probability that the amount of variation is due to random chance. d. a measure of how well the observation matches the expected values. e. the measurement of the number of independent categories in a test. 11. Given the following parental genotypes, determine the probability of the genotypes of the offspring. Parents AaBbCc x AaBbCc a. AaBbCC b. Aabbcc c. AABbCC d. aaBBCc - 14 - 12. Assuming that the probability of having a boy and girl are equal (50% each), what would be the probability of each of the following: a. children in the following order: boy – girl – boy – boy. b. in six children, the first three are boys. c. in six children, any three are boys. 13. In a two-factor cross using Mendelian traits in peas, two individuals who are heterozygous for flower color and height (see page 44) are crossed. What is the probability of getting each of the following phenotypic combinations in their offspring? Use either the forked-line method or the product rule to determine your answer. a. a tall white plant followed by a purple - short plant b. two purple – tall plants followed by a purple – short c. two short-white plants in a row 14. In Mendel’s two-factor cross (Figure 3.8) he obtained the following F2 offspring: 315 round – yellow seeds 101 wrinkled – yellow seeds 108 round – green seeds 32 wrinkled – green seeds Using a chi square test, determine if the observed offspring fit the expected ratios. a. Propose a hypothesis to be tested. b. Calculate the expected values for each of the phenotypic classes. c. Calculate the chi square value. d. Determine the number of degrees of freedom. e. Determine the P value (see Table 3.2 on page 62) f. Is your initial hypothesis accepted or rejected? 15. In Drosophila melanogaster, vestigial wings is a recessive trait to normal wings and ebony body color is recessive to honey body color. A fly who is heterozygous for both wings and body color is crossed to a vestigial wing fly who is heterozygous for body color. The following offspring are observed: 39 vestigial – ebony 125 vestigial – honey 43 normal wings – ebony 121 normal wings – honey Using procedures a-f in question 14, determine if these traits fit the Mendelian model of inheritance. Chapter Quiz 1. Which of the following methods of calculating probability is used if the order of a specific number of events occurring in the total is not important? a. chi square test b. binomial expansion c. product rule d. sum rule - 15 - 2. Mendel’s single factor crosses led to which of the following rules of inheritance? a. concept of dominance b. law of segregation c. support for the particulate theory of inheritance d. all of the above 3. In a Chi square test of a genetic cross there are n different phenotypic classes in the offspring. What is the value for the degrees of freedom for the test? a. n b. n – 1 c. n + 1 d. 2n e. none of the above 4. The pea plant, Pisum sativum, was used by Mendel as a model organism for which of the following reason(s): a. there were easily scorable traits such as flower color and seed shape. b. self-fertilization was possible. c. it was relatively easy to grow. d. all of the above are correct. 5. Consider the following cross: AaBBcc X AabbCc. What proportion of the offspring is expected to be dominant for all three traits? Assume independent assortment. a. 1/2 b. 3/4 c. 3/8 d. 9/16 e. 9/32 6. If an organism contains two identical alleles for the same trait, it is said to be a. cross-fertilized. b. heterozygous. c. homozygous. d. a hybrid. e. self-fertilized. 7. Two individuals who are heterozygous for a given trait are crossed. What will be the phenotypic ratio of their offspring? a. 75% will display the dominant trait, 25% will display the recessive trait b. 100% will display the recessive trait c. 100% will be heterozygous individuals d. 50% will display the dominant trait, 50% will display the recessive trait e. all of the above are possible 8. In a two-factor cross, if two individuals who are heterozygous for both traits are crossed with one another, what will be the phenotypic ratio of their offspring based on Mendel’s work? a. 3:1 b. 1:2:1 c. 9:3:3:1 d. 15:1 e. 9:6:1 - 16 - 9. The Punnett square is best used for which of the following? a. to predict the goodness of fit of observations to expectations b. to conduct crosses of four or more traits c. for pedigree analysis d. to visualize the possible outcomes of one and two-factor Mendelian crosses 10. Which of the following statements about pedigree analysis is FALSE? a. it is useful when examining organisms that produce a small number of offspring b. it is useful when ethical problems prohibit controlled matings c. it is frequently used to study patterns of inheritance in humans d. it can be used to determine if a trait is dominant or recessive e. choose this answer if all of the above are correct Answer Key for Study Guide Questions This answer key provides the answers to the exercises and chapter quiz for this chapter. Answers in parentheses ( ) represent possible alternate answers to a problem, while answers marked with an asterisk (*) indicate that the response to the question may vary. 3.1 1. Pisum sativum 2. anthers 3. ovules 4. stigma 5. true-breeding (or pure-breeding) 3.2 1. a 2. d 3. e 4. f 5. b 6. c 7. h 8. g 9. i 10. j 11. l 12. k 3.3 1. Two: AB, aB 2. Four: ABC, ABc, AbC, Abc 3. 9:3:3:1 4. 1:1:1:1 5. 1/8 6. 0 7. a. Round seeds b. phenotypic ratio 3 round : 1 wrinkled genotypic ratio 1 homozygous round : 2 heterozygous : 1 homozygous wrinkled. 8. a. TTgg x ttGG tG tG tG tG Tg TtGg TtGg TtGg TtGg Tg TtGg TtGg TtGg TtGg - 17 - 13. All Tt and tall 14. 1 TT: 2 Tt: 1 tt 3 Tall: 1 dwarf 15. 1 Tt: 1 tt 1 Tall: 1 dwarf Tg TtGg TtGg TtGg TtGg Tg TtGg TtGg TtGg TtGg b. phenotype: genotype: 100% tall with green pods 100% TtGg c. TtGg X TtGg TG TTGG TTGg TtGG TtGg TG Tg tG tg Tg TTGg TTgg TtGg Ttgg tG TtGG TtGg ttGG ttGg Tg TtGg Ttgg ttGg ttgg d. 9 tall with green pods: 3 tall with yellow pods : 3 short with green pods : 1 short with yellow pods 9. 702 tall with green pods 234 tall with yellow pods 234 short with green pods 78 short with yellow pods 10. 11. 3/16 (rrY-) 1/16 (RRYY) 3.4 1. 2. 3. 4. 5. Sutton, Boveri anaphase I metaphase I Four Eight 3.5 1. a. recessive b. II-2 is homozygous dominant, II-3 is homozygous recessive, II-4 is heterozygous, III-5 is homozygous dominant. c. 0% 3.6 1. c 2. b 3. d 4. a 5. d 6. e 7. c 8. d 11. a. 1/16 (0.063) b. 1/32 (0.031) c. 1/32 (0.031) d. 1/32 (0.031) 12. a. 1/16 (0.063) b. 1/8 (0.125) c. 0.313 13. a. 0.105 b. 0.059 c. 0.004 - 17 - 9. a 10. b 14. a. The traits of seed shape and seed color follow a Mendelian pattern of inheritance. b. The total number of F2 offspring is 556. Therefore, we can expect 312.75 round-yellow (9/16), 104.25 wrinkled yellow (3/16), 104.25 round-green (3/16), and 34.75 wrinkled green (1/16). c. 0.470 d. df = 3 e. 0.95 > P > 0.80. The hypothesis is accepted. 15. Note: This is not a dihybrid cross of two heterozygous individuals. Therefore, you may not use the 9:3:3:1 ratio to calculate expected numbers. a. The traits of wing shape and body color follow a Mendelian pattern of inheritance. b. The total number of F2 offspring is 298. Therefore we can expect 37.25 vestigial-ebony flies (1/8), 111.75 vestigial-honey flies (3/8), 37.25 normalebony flies (1/8), and 111.75 normal-honey flies (3/8). c. 3.306 d. df = 3 e. 0.50 > P > 0.2. The hypothesis is accepted. Quiz 1. b 2. d 3. b 4. d 5. c 6. c 7. a 8. c - 18 - 9. d 10. e