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CP Biology Chapter 10 - Genetics Go to Section: 11-1: The Work of Mendel •“Father of Genetics” •Austrian monk, spent time teaching high school age students and tended to the monastery garden. •YouTube - Mendel - From the Garden to the Genome Go to Section: •“self-pollinating” peas – Mendel used to produce future offspring – Knew that each flower produces both male (sperm –found in pollen) and female (egg) gametes – Fertilized flower’s egg with its own sperm • ASEXUAL REPRODUCTION! • Produced what he called a “true breed” • Offspring would be identical genetically Go to Section: Go to Section: •Then experimented with cross-pollination – Cut the pollen bearing anther off of the flowers and applied pollen from different flowers to the stigma (part that catches pollen) Go to Section: Go to Section: So with cross-pollination what did Mendel expect? A: Probably a blend of both parents. What did he get? A: Not really what he expected. Go to Section: Genes and Dominance • Trait – specific characteristic that varies from one individual to the next – Important that Mendel used traits that were unambiguous • 1. 2. 3. 4. 5. 6. 7. Mendel’s seven traits: Seed coat color Seed color Seed shape Pod color Pod shape Plant height Flower position Go to Section: •Crossed true breeds with each other (P generation – “parental”) •Offspring known as F1 •Plants that were products of cross-pollination known as “hybrids.” •F1 generation was not a blend of parental char. •Instead…. Go to Section: Mendel’s Monohybrid Cross – P to F1 A Punnett square, something we’ll cover in a moment. Huh?!?....all yellow seeds!!! Go to Section: In fact………here’s what happened with the rest of the traits. Go to Section: Figure 11-3 Mendel’s Seven F1 Crosses on Pea Plants Section 11-1 Seed Coat Color Pod Shape Pod Color Smooth Green Seed Shape Seed Color Round Yellow Gray Wrinkled Green White Constricted Round Yellow Gray Smooth Go to Section: Flower Position Plant Height Axial Tall Yellow Terminal Short Green Axial Tall •Mendel concluded that heredity is dictated by chemical factors called genes (it would be almost 100 years later before Watson & Crick and the whole DNA thing) •Genes have alternate forms depending on the plant – These alternate versions of the same gene are called alleles Plant height = gene Short and tall = alleles •Both alleles are present. •One type (recessive) can only be expressed if the other (dominant) is not present Go to •All these are found on chromosomes!! Section: Genes, Alleles, and Chromosomes Go to Section: Segregation •What happened to the other traits? •Self-pollinated the F1 plants •The “other” (recessive) traits reappeared in the F2 – He was floored, I’m sure… Go to Section: Principles of Dominance Section 11-1 P Generation Tall Go to Section: Short F1 Generation Tall Tall F2 Generation Tall Tall Tall Short Principles of Dominance Section 11-1 P Generation Tall Go to Section: Short F1 Generation Tall Tall F2 Generation Tall Tall Tall Short Principles of Dominance Section 11-1 P Generation Tall Go to Section: Short F1 Generation Tall Tall F2 Generation Tall Tall Tall Short Go to Section: Segregation (cont.) •How did the alleles get separated (segregated)? – Mendel suggested the alleles segregated when the gametes formed. – So every sperm or egg cell has one version (allele) for that gene • Some (50%) have allele for tall, others (50%) have allele for short Go to Section: Genes, Alleles, and Chromosomes Go to Section: Interest Grabber Section 11-2 Tossing Coins If you toss a coin, what is the probability of getting heads? Tails? If you toss a coin 10 times, how many heads and how many tails would you expect to get? Working with a partner, have one person toss a coin ten times while the other person tallies the results on a sheet of paper. Then, switch tasks to produce a separate tally of the second set of 10 tosses. Go to Section: Interest Grabber continued Section 11-2 1. Assuming that you expect 5 heads and 5 tails in 10 tosses, how do the results of your tosses compare? How about the results of your partner’s tosses? How close was each set of results to what was expected? 2. Add your results to those of your partner to produce a total of 20 tosses. Assuming that you expect 10 heads and 10 tails in 20 tosses, how close are these results to what was expected? 3. If you compiled the results for the whole class, what results would you expect? 4. How do the expected results differ from the observed results? Go to Section: Section Outline Section 11-2 11–2 Probability and Punnett Squares A. Genetics and Probability B. Punnett Squares C. Probability and Segregation D. Probabilities Predict Averages Go to Section: 11-2: Probability and the Punnett Square •Probability – likelihood of an even to take place – What are the chances for a coin to be flipped heads three times in a row? ½X½X½=⅛ •Probability explains everything in predicting outcomes of genetic crosses. Go to Section: Punnett Squares •Possible gene combinations are represented showing a Punnett Square. •Homozygous – same allele (SS or ss) •Heterozygous - different allele (Ss) •Genotype – genetic makeup (SS, Ss, ss) •Phenotype – physical feature observed (Smooth, wrinkled) Go to Section: Go to Section: Go to Section: Go to Section: Go to Section: Go to Section: Go to Section: Go to Section: Probability and Segregation Consistency is Good No matter what the characteristic, Mendel observed a 3:1 ratio of characteristics in the F2. Go to Section: Characters investigated by Mendel Monohybrid Crosses Yielded Consistent Results Therefore, the Principle of Segregation indeed is a general principle of genetics. Go to Section: Probabilities Predict Averages •More the times you flip the coin, the closer it will be to the expected result •Consequently the more offspring that an organism has, the closer the results will be to the averages. •This is why scientists perform MANY experiments. – Avoid the small percentage event and assume it is the trend. Go to Section: Interest Grabber Section 11-3 Height in Humans Height in pea plants is controlled by one of two alleles; the allele for a tall plant is the dominant allele, while the allele for a short plant is the recessive one. What about people? Are the factors that determine height more complicated in humans? Go to Section: Interest Grabber continued Section 11-3 1. Make a list of 10 adults whom you know. Next to the name of each adult, write his or her approximate height in feet and inches. 2. What can you observe about the heights of the ten people? 3. Do you think height in humans is controlled by 2 alleles, as it is in pea plants? Explain your answer. Go to Section: Section Outline Section 11-3 Go to Section: 11–3 Exploring Mendelian Genetics A. Independent Assortment 1. The Two-Factor Cross: F1 2. The Two-Factor Cross: F2 B. A Summary of Mendel’s Principles C. Beyond Dominant and Recessive Alleles 1. Incomplete Dominance 2. Codominance 3. Multiple Alleles 4. Polygenic Traits D. Applying Mendel’s Principles E. Genetics and the Environment Independent Assortment •Mendel wondered if alleles for separate genes influenced each other when they segregate. – Ex: Does a round seed always have to be yellow, or can it be green? •Two-factor cross – Followed two separate genes from generation to generation Independent Assortment of Alleles Go to Section: Two Factor Cross •Crossed true bred round/yellow (RRYY) pea plants with wrinkled/green (rryy) plants •F1 – 100% round/yellow (RrYy) – No surprise to Mendel •Mendel hypothesized there was dependent assortment, therefore predicted 3:1 ratio in the F2 (just like in the first experiment) – 3 round/yellow : 1 wrinkled/green Go to Section: Go to Section: Fig. 10.12a Dihybrid cross: F1 generation Go to Section: Fig. 10.12b Dihybrid cross: F2 generation Ratio: 9:3:3:1 Go to Section: Beyond dominance and recessiveness •Incomplete dominance – Hybrids (heterozygous) exhibit blend of traits – 4 o’clock plants • Red and white produce heterozygous pink plants Go to Section: Figure 11-11 Incomplete Dominance in Four O’Clock Flowers Section 11-3 Go to Section: Figure 11-11 Incomplete Dominance in Four O’Clock Flowers Section 11-3 Go to Section: Codominance •Similar to incomplete dominance however both traits are actually visual instead of blended – Chickens with speckled black spots on white feathers – Humans have gene for protein controlling cholesterol – if heterozygous two forms are made. Go to Section: MOO Multiple Alleles •When there are more than two alleles for a particular gene – Blood type (also demonstrates some codominance) Polygenic traits •Traits controlled by many genes – – – – – – – Height SLE (Lupus) Weight Eye Color Intelligence Skin Color Many forms of behavior Go to Section: Go to Section: Go to Section: Go to Section: Applying Mendel’s Principles •Good animal to test was fruit fly – Drosophilia melanogaster •Fast reproductive rate/life cycle and produced many offspring Go to Section: Go to Section: Environmental impact on gene expression • Environmental factors/conditions may alter gene expression. Example: Soil pH and flower color. Go to Section: Go to Section: Interest Grabber Section 11-4 How Many Chromosomes? Normal human body cells each contain 46 chromosomes. The cell division process that body cells undergo is called mitosis and produces daughter cells that are virtually identical to the parent cell. Working with a partner, discuss and answer the questions that follow. Go to Section: Interest Grabber continued Section 11-4 1. How many chromosomes would a sperm or an egg contain if either one resulted from the process of mitosis? 2. If a sperm containing 46 chromosomes fused with an egg containing 46 chromosomes, how many chromosomes would the resulting fertilized egg contain? Do you think this would create any problems in the developing embryo? 3. In order to produce a fertilized egg with the appropriate number of chromosomes (46), how many chromosomes should each sperm and egg have? Go to Section: Section Outline Section 11-4 11–4 Meiosis A. Chromosome Number B. Phases of Meiosis 1. Meiosis I 2. Meiosis II C. Gamete Formation D. Comparing Mitosis and Meiosis Go to Section: 11-4 Meiosis •Process of turning diploid somatic cells into haploid gametes •Must reduce chromosome number so when fertilization takes place we re-establish the regular chromosome number – Humans • Hapolid – sex cells N = 23 • Diploid – somatic cells 2N = 46 N = chromosome number Go to Section: Go to Section: Go to Section: Phases of meiosis Meiosis I and II Go to Section: Go to Section: Go to Section: Figure 11-15 Meiosis Section 11-4 Meiosis I Go to Section: Figure 11-15 Meiosis Section 11-4 Meiosis I Go to Section: Figure 11-15 Meiosis Section 11-4 Meiosis I Go to Section: Figure 11-15 Meiosis Section 11-4 Meiosis I Go to Section: Figure 11-15 Meiosis Section 11-4 Meiosis I Go to Section: Figure 11-17 Meiosis II Section 11-4 Meiosis II Prophase II Metaphase II Anaphase II Meiosis I results in two The chromosomes line up in a The sister chromatids haploid (N) daughter cells, similar way to the metaphase separate and move toward each with half the number of stage of mitosis. opposite ends of the cell. chromosomes as the original. Go to Section: Telophase II Meiosis II results in four haploid (N) daughter cells. Figure 11-17 Meiosis II Section 11-4 Meiosis II Prophase II Metaphase II Anaphase II Meiosis I results in two The chromosomes line up in a The sister chromatids haploid (N) daughter cells, similar way to the metaphase separate and move toward each with half the number of stage of mitosis. opposite ends of the cell. chromosomes as the original. Go to Section: Telophase II Meiosis II results in four haploid (N) daughter cells. Figure 11-17 Meiosis II Section 11-4 Meiosis II Prophase II Metaphase II Anaphase II Meiosis I results in two The chromosomes line up in a The sister chromatids haploid (N) daughter cells, similar way to the metaphase separate and move toward each with half the number of stage of mitosis. opposite ends of the cell. chromosomes as the original. Go to Section: Telophase II Meiosis II results in four haploid (N) daughter cells. Figure 11-17 Meiosis II Section 11-4 Meiosis II Prophase II Metaphase II Anaphase II Meiosis I results in two The chromosomes line up in a The sister chromatids haploid (N) daughter cells, similar way to the metaphase separate and move toward each with half the number of stage of mitosis. opposite ends of the cell. chromosomes as the original. Go to Section: Telophase II Meiosis II results in four haploid (N) daughter cells. Figure 11-17 Meiosis II Section 11-4 Meiosis II Prophase II Metaphase II Anaphase II Meiosis I results in two The chromosomes line up in a The sister chromatids haploid (N) daughter cells, similar way to the metaphase separate and move toward each with half the number of stage of mitosis. opposite ends of the cell. chromosomes as the original. Go to Section: Telophase II Meiosis II results in four haploid (N) daughter cells. Crossing over •Parts of chromosomes “switch places” •Meiosis Go to Section: Crossing-Over Section 11-4 Go to Section: Crossing-Over Section 11-4 Go to Section: Crossing-Over Section 11-4 Go to Section: Mitosis vs. meiosis Go to Section: Section Outline Section 11-5 11–5 Linkage and Gene Maps A. Gene Linkage B. Gene Maps Go to Section: 11-5: Linkage and Gene Maps •Found that some genes were linked to other ones – Seems to violate the rule of independent assortment – Ex: fruit flies – red eyes and minature wings Go to Section: •Mendel missed this…. – He thought the genes independently assorted • Actually it was the chromosomes that do! • Why did he miss it? – 6 of the 7 genes he studied in peas were on separate chromosomes – The two that were on the same chromosome were so far apart they independently assorted Go to Section: Gene Map •Do two genes on the same chromosome mean they are forever linked? – No! Crossing over may put them on separate chromosomes •The further apart genes are the more likely they could be separated during meiosis •Low rate of separation and then recombination means genes are close to one another. Go to Section: Figure 11-19 Gene Map of the Fruit Fly Section 11-5 Exact location on chromosomes Go to Section: Chromosome 2