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9.3 PAGES 187-195 Mendel’s Inheritance. Introduction To understand how Mendel’s laws can be used, you first need to know about probability.

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Presentation on theme: "9.3 PAGES 187-195 Mendel’s Inheritance. Introduction To understand how Mendel’s laws can be used, you first need to know about probability."— Presentation transcript:

1 9.3 PAGES 187-195 Mendel’s Inheritance

2 Introduction To understand how Mendel’s laws can be used, you first need to know about probability.

3 Probability Probability is the likelihood, or chance, that a certain event will occur. Ex. Coin tossing. The same rules of probability in coin tossing apply to the main events that determine the genotypes of offspring: formation of gametes and fertilization.

4 Probability and Gamete Formation During meiosis homologous chromosomes and the alleles they carry segregate and go to different gametes. Bb; half of the gametes produced by the Bb parent will have the B allele and have will have the b allele. (see box on center of pg 188)

5 Probability and Fertilization Fertilization is a matter of chance. To determine the different combinations of alleles, geneticists use a simple tool called a Punnett Square.

6 Using a Punnett Square A punnett square is a chart that allows you to easily determine the expected percents of different genotypes in the offspring of two parents. The gametes produced by the male parent are at the top of the chart. The gametes produced by the female parent are at the side of the chart. The different possible combinations of alleles in their offspring are determined by filling in the cells of the Punnett square with the correct letters (alleles).

7 Video How to draw a Punnett Square by Learn Biology 4:20 http://www.youtube.com/watch?v=prkHKjfUmMs

8 Dihybrid Cross Video 5:54 http://www.youtube.com/watch?v=qRxyIc4vMgA

9 Dihybrid Cross When you cross two traits at the same time it is called a dihybrid cross. You still place the male parent on top of the 4x4 boxes/cross. The female parent goes on the side of the 4x4 cross. You need to distribute the alleles:  First to third  First to fourth  Second to third  Second to fourth

10 Punnett Square for Two Characteristics When you consider more than one characteristic at a time, using a Punnett square is more complicated. For example, with two genes each having two alleles, an individual has four alleles, and these four alleles can occur in 16 different combinations.

11 How Mendel Work Backwards to Get Ahead All of the characteristic Mendel studied happened to be inherited independently. We now know that these characteristics are controlled by genes on non-homologous chromosomes.

12 Non-Mendelian Inheritance The inheritance of characteristics is not always as simple as it is for the characteristics that Mendel studied in pea plants. Complete Dominance is when one gene has two possible allele options, one of which is completely dominant to the other (recessive).

13 Non-Mendelian Inheritance Geneticists now know that inheritance is often more than what Mendel discovered. Geneticists say we have codominance and Incomplete dominance.

14 Co-dominance Co-dominance occurs when both alleles are expressed equally in the phenotype of the heterozygote. Ex. The flower has both white and red petals.

15 Incomplete Dominance Incomplete dominance occurs when the dominant allele is not completely dominant. Expression of the dominant allele is influence by the recessive allele, and an intermediate phenotype results. Ex: Pink flower from a red and white flower.

16 Incomplete dominance video 9:35 http://vimeo.com/54978709 Practice paper

17 Multiple Alleles Many genes have multiple alleles. An example is ABO blood type in humans. There are three common alleles for the gene that controls this characteristic. The alleles for type A is codominant with the alleles for type B, and both alleles are dominant to the allele for type O. Therefore, the possible phenotypes are blood types, A, B, AB, and O

18 Video 9:13 http://www.youtube.com/watch?v=ROL5ekow-Y4

19 Polygenic Characteristics Polygenic Characteristics are characteristics controlled by more than one gene, and each gene may have two or more alleles. The genes may be on the same chromosome or on non-homologous chromosomes. If the genes are located close together on the same chromosome, they are likely to be inherited together. However, it is possible that they will be separated by crossing-over during meiosis, in which case they may be inherited independently of one another.

20 Polygenic Characteristics If the genes are on non-homologous chromosomes, they may be recombined in various ways because of independent assortment. For these reasons, the inheritance of polygenic characteristics is very complicated. Such characteristics may have many possible phenotypes. Many human traits are polygenic traits. The alleles of each gene have a minor additive effect on the phenotype. Ex: human height

21 Effects of Environment on Phenotype Environmental factors, such as sunlight and food availability, can affect how genes are expressed in the phenotype of individuals. Ex: human height and skin color (exposure to sun light).

22 Homework The following questions are due on Thursday 2/20 Use complete sentences and restate question in your answers too. Page 195 #’s 1, 3, 4, 6, 9, 10


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