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Chapter 11 Notes: Mendelian Genetics

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Title: Chapter 11 Notes: Mendelian Genetics


1
Chapter 11 Notes Mendelian Genetics
  • Genetics is the scientific study of heredity that
    involves how genes are passed from parents to
    their offspring.

2
History of Genetics
  • Gregor Mendel was an Austrian monk and scientist
    who was in charge of the monastery garden.
    Mendel studied garden peas.

3
Pea plants happened to be a good choice to study
because
  • They are self-pollinating.
  • He had different pea plants that were
    true-breeding.
  • True-breeding - means that they are homozygous
    for that trait.
  • EX. if the plants self-pollinate they produce
    offspring identical to each other and the
    parents.

4
Pea plants happened to be a good choice to study
because
  • He developed a technique of producing seeds from
    a process called cross-pollination, in which he
    dusted the pollen of one pea plant onto another
    plant.
  • He was in control of which plants crossed with
    each other.

5
Genes and Dominance
  • A trait is a specific characteristic that varies
    from one individual to another.
  • Mendel studied seven different pea plant traits
    including seed shape, seed color, seed coat
    color, pod shape, pod color, flower position, and
    plant height.
  • Mendel studied two alleles, or different
    versions, of each trait (wrinkled or smooth pea
    shape, green or yellow seed color, etc.)

6
When discussing generations traits, we label
them as following
  • The true-breeding parental generation is called
    the P generation.
  • The offspring of the two parental plants is
    called the F1 generation.
  • A cross between F1 generation would be called F2
    generation.

7
Original cross
Cross pollination
8
Mendels Investigations
  • Mendel wanted to cross (or breed) two plants with
    different versions of the same trait. He wanted
    to know if the characteristics of the plants were
    blended in the offspring.

9
Mendels Investigations
  • Mendel saw that when he crossed plants with
    different versions of the same trait (P
    generation), the F1 offspring were NOT blended
    versions of the parents.
  • The F1 plants resembled only one of the parents.

Tall x short ? all tall
10
Mendel concluded
  • 1. Biological inheritance is determined by
    factors that are passed from one generation to
    the next.
  • Factors were later defined as genes-
  • Mendel discovered all of this without the
    knowledge of DNA!

11
Mendel concluded
  • In Mendels plants, there was one gene for each
    trait. For example, there was one gene for
    plant height.
  • But, there were two versions of this gene one
    for a tall plant and one for a short plant.
  • Alleles Different versions of the same gene
  • Remember, genes are used to make proteins.
  • Each allele contains the DNA that codes for a
    slightly different version of the same protein
  • This gives us the different characteristics for
    each trait

12
2. Principal of dominance
  • Some alleles are dominant and some alleles are
    recessive.
  • Recessive alleles are able to be masked
  • Dominant alleles mask recessive alleles
  • The trait that was represented in the F1
    generation was the dominant trait.

13
2. Principal of dominance
  • How many alleles do you have for each gene?
  • Where do they come from?

14
3. Segregation
  • Experiment Mendel self-pollinated the F1
    plants, or crossed the F1 plants with each other,
    to produce the F2 generation. From his F1
    crosses, Mendel observed
  • The versions of the traits coded for by recessive
    alleles reappeared in the F2 plants.
  • The recessive trait was still there!

15
3. Segregation
  • About 25 (or ¼) of the F2 plants exhibited the
    recessive version of the trait. In this case the
    recessive phenotype is short. The dominant
    phenotype, tall, was found in 75 (or ¾) of the
    F2 plants.

P generation F1 generation F2 generation
16
Segregation of alleles during meiosis
  • When the F1 plants produce gametes (sex cells)
    and self-pollinate, the two alleles for the same
    gene separate from each other so that each gamete
    carries only one copy of each gene.
  • Remember, gametes are haploid. In the example,
    we use T to represent the dominant, tall allele
    and t to represent the recessive, short allele.

17
4. Law of Independent Assortment
  • Law of Independent Assortment- genes for each
    trait can be inherited independently from each
    other. For example
  • not all tall plants have green pea pods and
  • not all people with brown hair have brown eyes.

18
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19
Key Terms in Mendelian Genetics
  • Dominant- allele that can mask represented by
    capital letters (B, D, F, etc.)
  • Recessive- alleles that can be masked
    represented by lower case letters (b, d, f, etc.)

20
Key Terms in Mendelian Genetics
  • Phenotype- observable traits (brown eyes, yellow
    seed pods)
  • Genotype- actual alleles describes the genetic
    characteristics (BB, dd, Ff)

Phenotype brown eyes Genotype could be BB,
or Bb
21
Key Terms in Mendelian Genetics
  • Homozygous (True-Breeding)- having two identical
    alleles for the same trait (TT, tt) homo means
    same
  • Heterozygous- having two different alleles from
    the same trait (Tt) hetero means different

22
  • Punnett Squares must be taught before continuing ?

23
Beyond dominant and recessive alleles
  • There are some exceptions to Mendels principles.
    Luckily, none of these exceptions are exhibited
    in pea plants.
  • If so, Mendel would not have been able to figure
    out inheritance.

24
  • Some alleles are neither dominant nor recessive.
  • Incomplete Dominance
  • Codominance

25
Incomplete dominance
  • situation in which one allele is not completely
    dominant over another the phenotype is a
    blending of the two alleles
  • Example In some plants, when a true-breeding
    plant with red flowers is crossed with a
    true-breeding plant with white flowers, pink
    flowers are produced. Neither red nor white is
    dominant over the other.

26
  • Consider thisPunnett square

27
Codominance
  • situation in which both alleles of a gene
    contribute to the phenotype of the organism both
    alleles are expressed but NOT blended
  • Example In cows, the allele for red fur is
    codominant with the allele for white fur.
    Heterozygous cows carrying one red and one white
    allele have spotted fur, known as roan.

28
  • Consider thisPunnett square

29
  • Many traits are controlled by multiple alleles or
    multiple genes.
  • Multiple alleles (more than 2 choices)
  • Polygenic (multiple genes control a single trait)

30
Multiple alleles
  • the case where three or more alleles of the same
    gene exist. Remember, an organism will have only
    two of these alleles (one from mom and one from
    dad).
  • Examples Coat color in rabbits, blood type in
    humans

31
Multiple alleles
32
Polygenic traits
  • traits that are determined by alleles from more
    than one gene these traits usually have a range
    of phenotypes
  • Examples skin color in humans, height in humans

33
Mapping Genes
  • Its easy to imagine that genes on different
    chromosomes assort independently, but what about
    genes that occur on the same chromosome? Dont
    they always appear together?
  • Not always due to crossing over. Genes that
    occur together on a chromosome will be separated
    when homologous chromosomes exchange genes.
  • The frequency of genes occurring together can
    help us generate a gene map.

34
  • The more often two genes occur together, the
    closer they are to each other on the chromosome.
  • If the genes are never separated by crossing
    over, they always occur together. All offspring
    will look like one of the parents (in reference
    to the genes in question).

35
  • If half of the offspring are parental and half
    are recombinations of the parents (in reference
    to the genes in question), then they are said to
    be independent. This means they are either on
    separate chromosomes or they are almost always
    separated during meiosis.
  • You will learn to calculate distances and create
    a map in AP Bio, or in college

36
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37
Human chromosomes
  • There are two types of chromosomes.
  • Autosomes Of the 46 chromosomes, 44 of them (22
    pairs of chromosomes) are called autosomes
    (non-sex chromosomes).
  • Sex chromosomes The last two chromosomes are
    called the sex chromosomes because they determine
    the sex of the person. Females have two X
    chromosomes (XX) and males have one X and one Y
    chromosome (XY).

38
  • Gametes
  • All gametes are haploid. In humans, that means
    each egg cell and each sperm cell has 1 copy of
    each chromosome for a total of 23 chromosomes.
  • Egg cells All human egg cells carry 23
    chromosomes, one of which is a single X
    chromosome. This is written as 23, X.
  • Sperm cells In males, there are two types of
    sperm cells- one carries an X chromosome (23, X)
    and one carries a Y chromosome (23, Y).

39
  • When a sperm and egg cell combine, half of the
    time the fertilized eggs (also called zygotes)
    are female (46, XX) and half of the time they are
    male (46, XY).

X
X
eggs
X
XX
XX
female
female
Y
XY
XY
male
male
sperm
40
  • Sex Linked traits traits that are determined by
    alleles that are found on the X or Y chromosome.
  • The Y chromosome is shorter and does not carry
    all the same alleles as the X chromosome.

41
  • Females are XX and males are XY.
  • Females can be homozygous or heterozygous for a
    trait carried on the X chromosome, but males
    (having only one X chromosome) are hemizygous.

42
  • If they inherit a defective gene from the parent,
    then they will exhibit the trait because they
    cannot inherit a second gene to mask it.
  • Conversely, a healthy male cannot be hiding a
    bad recessive allele because they only have one X
    chromosome.

43
  • Example of a sex-linked Punnett square
  • XBXb (heterozygous female with normal vision)
    crossed to XBY (hemizygous male with normal
    vision)

XBY
Y
XB
XB XB
XBY
XB
XB Xb
XbY
XB Xb
Xb
44
Genetics and the Environment
  • Characteristics are determined by both genes and
    the environment.
  • External While genes will influence the height
    of a plant, the amount of water, sun, and other
    climate conditions will also affect the height.

45
Genetics and the Environment
  • Internal There are recent findings that
    proteins involved with DNA can turn genes on or
    off based on environmental factors.
  • Certain chemical exposure can turn genes on or
    off (make the traits show up or not) for
    generations after exposure, but there are no
    changes to the DNA (no mutations).
  • This new understanding of how genes are expressed
    is called epigenetics.
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