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Gregor Mendel

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Title: Gregor Mendel


1
Gregor Mendel
  • The Father of Genetics

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Mendel
  • Modern genetics had its beginnings in an abbey
    garden, where a monk named Gregor Mendel
    documented a particular mechanism of inheritance.
  • He discovered the basic principles of heredity by
    breeding garden peas in carefully planned
    experiments.

4
Why peas?
  • Peas are normally self-pollinating.
  • Peas are easily grown,
  • Peas mature quickly
  • Peas produce many seeds
  • Peas show several pairs of obvious contrasting
    traits
  • The use of plants also allowed strict control
    over the mating.

5
Peas contrasting traits
  • Tall plant vs. dwarf plant
  • Yellow seeds vs. green seeds
  • Smooth seeds vs. wrinkled seeds
  • Inflated pod vs. constricted pod
  • Purple flower vs. white flower
  • Green pod vs. yellow pod
  • Axial flower vs. terminal flower

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Mendel experiments
  • Mendel spent several
  • years self-pollinating
  • the pea plants in order
  • to establish purebred
  • plants.

8
Mendels experiments
  • These pure-breeding plants were called the P
    generation.
  • Mendel had strains of peas that were pure
    breeding for height the plants were either tall
    or dwarf
  • He had strains that had either yellow pods or
    green pods, inflated pods or constricted pods.

9
Mendels experiments
  • When a pure breeding tall plant is crossed with a
    pure breeding dwarf plant, all the resulting
    plants are called hybrids.
  • All the hybrids are called the F1 generation (
    first filial generation)
  • All of the F1 generation were tall

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Mendels experiment
  • The same pattern was observed in each of the 7
    contrasting characteristics.
  • In the F1 generation, all of the plants showed
    one characteristic.
  • Mendel called this characteristic the dominant
    trait
  • The trait that was not expressed in F1 was called
    the recessive trait

12
Mendels experiment
  • Next, Mendel crossed the F1 generation plants.
  • He wanted to know if the F1 plants were identical
    to the P generation
  • So he crossed two of the F1 plants

13
Mendels experiment
  • The resulting plants (the F2 generation) yielded
    3 tall plants and 1 dwarf plant.
  • A ratio of 31

14
Mendels experiment
  • This meant that the tall F1 plants ( the hybrids)
    were different than the tall P generation plants
    (the purebred plants) even though they were all
    tall.

15
Mendels experiment
  • Mendel repeated this experiment with all of the
    traits and the results were similar.
  • The F2 generation displayed a phenotypic ratio of
    31

16
Mendels explanation
  • Units of inheritance, called factors (we now call
    them genes) were involved
  • For any given characteristic there were several
    different forms (now called alleles)
  • Each plants phenotype (what they look like) was
    determined by a pair of alleles that can be
    identical or different

17
Mendels explanation
  • In a hybrid plant one allele of a pair has the
    ability to express itself while the other one is
    not expressed.
  • Recessive characteristics are expressed only when
    there is no dominant allele present

18
Mendels explanation
  • When gametes are produced, the members of each
    pair of alleles are separated into different
    reproductive cells.
  • A gamete can contain only one allele of a
    particular characteristic.
  • When fertilization occurs these alleles unite to
    give the zygote the necessary pair of alleles.

19
Mendels first law
  • The Law of Segregation
  • Members of a pair of alleles for a given trait
    are segregated when gametes are formed

20
Genotype
  • The genotype represents the genes that exist in
    the organism
  • Mendel used letters of the alphabet to represent
    genes.
  • Capital letters represent the dominant allele
  • Lower case letters represent the recessive allele

21
Genotype
  • A purebred tall plant would have a genotype of TT
  • A purebred dwarf plant would have a genotype of
    tt
  • Genotypes with identical alleles are called
    homozygous
  • Genotypes with different alleles are called
    heterozygous

22
  • The sex cells of a TT plant would contain only
    the dominant allele T
  • The sex cells of a tt plant would contain only
    the recessive allele t
  • The F1 generation would all have the genotype Tt
  • The phenotype of all the F1 generation would be
    tall

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Mendels impact
  • Mendels theories of inheritance, first
    discovered in garden peas, are equally valid for
    figs, flies, fish, birds and human beings.
  • Mendels impact endures, not only on genetics,
    but on all of science, as a case study of the
    power of hypothesis/deductive thinking.

25
A Punnett Square
  • Punnett squares illustrate the possible outcomes
    of a particular cross (the genotype of the
    offspring)
  • Mendels first experiment could be illustrated
    with the following Punnett square
    TT X tt

tt gametes
t
TT gametes
T
Tt
26
A 2 x 2 Punnett Square
  • The F1 generation cross is a monohybrid cross Tt
    x Tt

Phenotypic ratio 31
27
Single Trait Analysis
  • In humans the ability to taste PTC, T is dominant
    to non-tasting t. Determine the expected
    genotypic and phenotypic ratios resulting from a
    cross between a heterozygous taster and a
    non-taster.

Tt (heterozygous taster) gametes
tt (non-taster) gametes
Genotype ratio 11 (Tttt) Phenotype 11
28
Practice Problem
  • In humans, the allele A, for pigment formation
  • is dominant to the allele for a, the inability
    to
  • form pigment.
  • aa individuals are albino
  • Determine the expected genotypic and
  • phenotypic ratios expected from a cross
  • between two individuals heterozygous for
  • this trait.

29
Solving Punnett Square ProblemsGRASP method
  • Given
  • pigment formation (A) is dominant to the
    inability to form pigment (a)
  • aa individuals are albino
  • The cross is Aa x Aa
  • Required
  • The expected genotypic and phenotypic ratio of
    the cross
  • Analysis
  • Solution
  • Paraphrase

30
Solving Punnett Square ProblemsGRASP method
  • Analysis
  • Solution
  • Paraphrase
  • The phenotypic ratio is 31 normal albino
  • The genotypic ratio is 1 2 1 AAAaaa

A a


AA
Aa
A a
Aa
aa
31
Recognizing Hybrids
  • A geneticist crosses two parent plants that have
    the dominant trait of
  • purple flowers.
  • When the resulting seeds are planted the
    geneticist observes that 145 of
  • the F1 plants have the recessive trait of yellow
    flowers and 430 of the F1
  • plants have purple flowers.
  • How can you explain these results? What are the
    genotypes of the parent
  • plants and the F1 plants?
  • Given F (purple flowers) is dominant to f
    (yellow flowers). Both of the P1
  • plants possess at least one F gene F__ F__
  • Required The genotypes of the parents and F1
    plants
  • Analysis
  • The key to this question is the appearance of the
    ff (yellow plants) in the F1.
  • We know that yellow flowers can only appear if
    the plants are homozygous recessive for yellow
    flowers (ff)
  • Produce a Punnett square of the offspring.

32
  • Let F be the dominant allele for flower colour
    purple and f be the recessive allele for colour
    yellow
  • Phenotypic ratio is 430145

gametes
gametes
33
  • Solution
  • The appearance of the recessive trait in the
  • phenotype of the F1 plants can only occur if
  • they are homozygous recessive (ff). This can
  • only happen if both of the purple parent plants
  • are heterozygous and each parent contributed
  • the recessive allele to these yellow plants. In
  • addition, recognize that the ratio of purple
  • plants to yellow plants is approximately 31.
  • This ratio indicates a monohybrid cross.

34
Dihybrid crosses
  • Dihybrid crosses show the genotypes of offspring
    using 2 different genes on two different
    chromosomes
  • TtRr x TtRr hybrid tall plants with
    round seeds
  • Gametes produced by independent assortment TR,
    tr, Tr, tR
  • These gametes would be present in equal numbers
    (eg. ¼ of the total number)

35
Dihybrid cross
  • TtRr x TtRr

36
Dihybrid cross
  • TtRr x TtRr
  • The expected phenotypic ratio
  • 9/16 tall round plants, 3/16 tall wrinkled plants
  • 3/16 dwarf round plants, 1/16 dwarf wrinkled
    plants

37
Test cross
  • A test cross is a cross with an individual whose
    genotype is being tested to a recessive
    individual
  • We know that the recessive individual must be
    homozygous so it can only produce one type of
    gamete
  • This way we can determine the genotype of the
    test individual.
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