Presentation is loading. Please wait.

Presentation is loading. Please wait.

Monohybrid Crosses. Gregor Mendel Austrian monk who started the study of genetics in his monastery’s garden in the 1860s Studied heredity in garden peas.

Published byCrystal Morton Modified over 8 years ago

Similar presentations

Presentation on theme: "Monohybrid Crosses. Gregor Mendel Austrian monk who started the study of genetics in his monastery’s garden in the 1860s Studied heredity in garden peas."— Presentation transcript:

1 Monohybrid Crosses

2 Gregor Mendel Austrian monk who started the study of genetics in his monastery’s garden in the 1860s Studied heredity in garden peas

3 Why did he study peas? 1.They had a variety of characteristics that occur in two different forms or.

4 Why did he study peas? 1.They had a variety of characteristics that occur in two different forms or alleles.

5 Why did he study peas? 1.They had a variety of characteristics that occur in two different forms or alleles.

6 Why did he study peas?

7 2.He could easily control which plants pollinated each other.

8 Why did he study peas? 2.He could easily control which plants pollinated each other. – Pea plants can, which is when a plant’s pollen, which contains the sperm, is used to fertilize the same plant’s egg. If he wanted pure breeding plants, he could allow the plants to self- pollinate over many generations.

9 Why did he study peas? 2.He could easily control which plants pollinated each other. – Pea plants can self-pollinate, which is when a plant’s pollen, which contains the sperm, is used to fertilize the same plant’s egg. If he wanted pure breeding plants, he could allow the plants to self- pollinate over many generations.

10 Why did he study peas? 2.He could easily control which plants pollinated each other. – Pea plants can self-pollinate, which is when a plant’s pollen, which contains the sperm, is used to fertilize the same plant’s egg. If he wanted pure breeding plants, he could allow the plants to self- pollinate over many generations. – Pea plants can also, which is when the pollen of one plant is used to fertilize another plant. He could do this by removing stamens or male parts of the flowers. He could brush pollen from one flower to the female parts of another flower.

11 Why did he study peas? 2.He could easily control which plants pollinated each other. – Pea plants can self-pollinate, which is when a plant’s pollen, which contains the sperm, is used to fertilize the same plant’s egg. If he wanted pure breeding plants, he could allow the plants to self- pollinate over many generations. – Pea plants can also cross-pollinate, which is when the pollen of one plant is used to fertilize another plant. He could do this by removing stamens or male parts of the flowers. He could brush pollen from one flower to the female parts of another flower.

12 Why did he study peas?

13 3.Peas produce a lot of offspring quickly, so he could obtain lots of data quickly.

14 Why did he study peas? 3.Peas produce a lot of offspring quickly, so he could obtain lots of data quickly. – P generation-

15 Why did he study peas? 3.Peas produce a lot of offspring quickly, so he could obtain lots of data quickly. – P generation- 1 st generation; parental (p) generation

16 Why did he study peas? 3.Peas produce a lot of offspring quickly, so he could obtain lots of data quickly. – P generation- 1 st generation; parental (p) generation – F1 generation-

17 Why did he study peas? 3.Peas produce a lot of offspring quickly, so he could obtain lots of data quickly. – P generation- 1 st generation; parental (p) generation – F1 generation- The first generation of offspring

18 Why did he study peas? 3.Peas produce a lot of offspring quickly, so he could obtain lots of data quickly. – P generation- 1 st generation; parental (p) generation – F1 generation- The first generation of offspring F stands for filial or son.

19 Why did he study peas? 3.Peas produce a lot of offspring quickly, so he could obtain lots of data quickly. – P generation- 1 st generation; parental (p) generation – F1 generation- The first generation of offspring F stands for filial or son. – F2 generation-

20 Why did he study peas? 3.Peas produce a lot of offspring quickly, so he could obtain lots of data quickly. – P generation- 1 st generation; parental (p) generation – F1 generation- The first generation of offspring F stands for filial or son. – F2 generation- The second generation of offspring; offspring of the F1 generation

21 3 Steps of Mendel’s Experiments 1. Produce a true-breeding P generation Long stemmed plant Short stemmed plant Self Pollination Long stemmed plant P generation Short stemmed plant P generation

22 3 Steps of Mendel’s Experiments 2. Producing an F1 generation Cross PollinationCross Pollination Long stemmed F1 Generation

23 3 Steps of Mendel’s Experiments 3. Producing an F2 Generation Cross PollinationCross Pollination ¾ Long Stemmed ¼ Short Stemmed F2 Generation

24 Mendel’s Law of Segregation Genes for different traits can segregate (or separate) independently during the formation of gametes This is because the two different alleles that an organism has are on different chromosomes in a homologous pair.

25 Mendel’s Law of Segregation Parent Cell Meiosis I Meiosis II Gametes

26 Practice What are the possible genetic contents of the gametes made by a person with the genotype BB? What are the possible genetic contents of the gametes made by a person with the genotype Tt?

27 Practice What are the possible genetic contents of the gametes made by a person with the genotype BB? B or B What are the possible genetic contents of the gametes made by a person with the genotype Tt?

28 Practice What are the possible genetic contents of the gametes made by a person with the genotype BB? B or B What are the possible genetic contents of the gametes made by a person with the genotype Tt? T or t

29 Making Sense of Mendel’s Findings Probability-

30 Making Sense of Mendel’s Findings Probability- the likelihood that a particular event will occur

31 Making Sense of Mendel’s Findings Probability- the likelihood that a particular event will occur – Scientists use probability to predict the phenotypes and genotypes of the offspring.

32 Making Sense of Mendel’s Findings Probability- the likelihood that a particular event will occur – Scientists use probability to predict the phenotypes and genotypes of the offspring. Punnett Square-

33 Making Sense of Mendel’s Findings Probability- the likelihood that a particular event will occur – Scientists use probability to predict the phenotypes and genotypes of the offspring. Punnett Square- a diagram that shows gene combinations that might result from a genetic cross

34 Making Sense of Mendel’s Findings Probability- the likelihood that a particular event will occur – Scientists use probability to predict the phenotypes and genotypes of the offspring. Punnett Square- a diagram that shows gene combinations that might result from a genetic cross – Punnett squares show predicted results, not actual results.

35 Punnett Square Parent 1 Parent 2 Gamete 1 Gamete 2 Gamete 1 Gamete 2 Offspring 1 Offspring 2 Offspring 3Offspring 4

36 CROSSES INVOLVING ONE TRAIT (MONOHYBRID CROSSES) Let’s take a look at Mendel’s crosses that he completed to determine his laws of heredity. We will use L to represent the allele for long stems and l to represent the allele for short stem.

37 Homozygous x Homozygous When he crossed two pure-breeding plants for the same version of the trait, all of the offspring shared the same phenotype as the parents.

38 Homozygous x Homozygous Parent 1 Parent 2 Gamete 1 Gamete 2 Gamete 1 Gamete 2 Offspring 1 Offspring 2 Offspring 3Offspring 4 LL LL L L

39 Homozygous x Homozygous

40 Test Crosses

41 We can’t tell by looking at an individual with a dominant phenotype if the individual’s genotype is homozygous dominant (BB) or heterozygous (Bb). What can we do to determine the genotype of an individual with a dominant phenotype? Test cross:

42 Test Crosses We can’t tell by looking at an individual with a dominant phenotype if the individual’s genotype is homozygous dominant (BB) or heterozygous (Bb). What can we do to determine the genotype of an individual with a dominant phenotype? Test cross: crossing an organism with a dominant phenotype, but unknown genotype, with a homozygous recessive organism, then observing the phenotypes of the offspring to determine the unknown genotype

Download ppt "Monohybrid Crosses. Gregor Mendel Austrian monk who started the study of genetics in his monastery’s garden in the 1860s Studied heredity in garden peas."

Similar presentations

Intro to Genetics.

Intro to Genetics.
Chapter 10, Genetics.

Chapter 10, Genetics.
11-1 Gregor Mendel 11-2 Punnett Squares

11-1 Gregor Mendel 11-2 Punnett Squares
Genetics.

Genetics.
Genetics. Heredity- passing of traits from parent to offspring Traits- hair color, eye color, height, etc. (are like your parents) -characteristics that.

Genetics. Heredity- passing of traits from parent to offspring Traits- hair color, eye color, height, etc. (are like your parents) -characteristics that.
Chapter 9 Table of Contents Section 1 Mendel’s Legacy

Chapter 9 Table of Contents Section 1 Mendel’s Legacy
Chapter 9 Fundamentals of Genetics Standards SPI 3210.4.4: Determine the probability of a particular trait in an offspring based on the genotype and the.

Chapter 9 Fundamentals of Genetics Standards SPI : Determine the probability of a particular trait in an offspring based on the genotype and the.
Copyright © by Holt, Rinehart and Winston. All rights reserved. ResourcesChapter menu Mendel’s Fundamentals of Genetics.

Copyright © by Holt, Rinehart and Winston. All rights reserved. ResourcesChapter menu Mendel’s Fundamentals of Genetics.
Genetics Chapter 11.

Genetics Chapter 11.
GENETICS & HEREDITY What makes us what we are?. Gregor Mendel Austrian monk in the 19 th century Gardener for the monastery Made observations about the.

GENETICS & HEREDITY What makes us what we are?. Gregor Mendel Austrian monk in the 19 th century Gardener for the monastery Made observations about the.
Genetics. Genetics – branch of biology that deals with patterns of inheritance, or heredity. Heredity- biological process by which parents pass on genetic.

Genetics. Genetics – branch of biology that deals with patterns of inheritance, or heredity. Heredity- biological process by which parents pass on genetic.
Mendel laid the groundwork for genetics.

Mendel laid the groundwork for genetics.
Genetics. Genetics is the study of heredity. Heredity is when a parent passes down physical characteristics to their offspring. These different physical.

Genetics. Genetics is the study of heredity. Heredity is when a parent passes down physical characteristics to their offspring. These different physical.
Classical Genetics Gregor Mendel. Gene versus Allele Gene - a sequence of DNA in a specific location on a chromosome Determines traits in an organism.

Classical Genetics Gregor Mendel. Gene versus Allele Gene - a sequence of DNA in a specific location on a chromosome Determines traits in an organism.
1 Mendelelian Genetics 2 Gregor Mendel (1822-1884) Responsible for the Laws governing Inheritance of Traits.

1 Mendelelian Genetics 2 Gregor Mendel ( ) Responsible for the Laws governing Inheritance of Traits.
Table of Contents Section 1 Mendel’s Legacy Section 2 Genetic Crosses

Table of Contents Section 1 Mendel’s Legacy Section 2 Genetic Crosses
Genetics Chapter 10, Section 1.

Genetics Chapter 10, Section 1.
Mendel Biology Chapter 10.1 p. 258-268.

Mendel Biology Chapter 10.1 p
Lab Biology Chapter 9 - Genetics Mrs. Nemanic

Lab Biology Chapter 9 - Genetics Mrs. Nemanic
Mendelian Genetics. Gregor Mendel (1822-1884) Responsible for the laws governing Inheritance of Traits.

Mendelian Genetics. Gregor Mendel ( ) Responsible for the laws governing Inheritance of Traits.

Similar presentations

Ads by Google