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Genetics

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Genetics Vocabulary Segregation Trait Gametes Genes Alleles True breeding Hybrids Homozygous Heterozygous Phenotype Genotype Traits Traits are qualities, features or ... – PowerPoint PPT presentation

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Title: Genetics


1
Genetics
2
Vocabulary
  • Segregation Trait
  • Gametes
  • Genes
  • Alleles
  • True breeding
  • Hybrids
  • Homozygous
  • Heterozygous
  • Phenotype
  • Genotype

3
Traits
  • Traits are qualities, features or other things
    that distinguish the organism. Traits can include
    things like hair color, tooth shape, beak shape,
    bone size, or muscle structure.
  • Traits come in two varieties acquired and
    inherited.

4
Acquired Traits
  • Animals can acquire usesful abilities.
  • These acquired traits can not be passed on
    genetically. You can't inherit your uncle's
    knowledge, skills, ideas or memories and it
    doesnt' work that way with other organisms
    either.
  • Acquired traits include things such as calluses
    on fingers, larger muscle size from exercise or
    from avoiding predators.
  • Behaviors that help an organism survive would
    also be considered acquired characteristics most
    of the time. Things like where to hide, what
    animals to hide from.

5
Inherited Traits
  • In organisms, inherited traits must come from a
    parent or other ancestor.
  • A trait may seem to skip a generation or even two
    or three, but if a trait shows up it must have
    been present in an ancestor.
  • Inherited traits include things such as hair
    color, eye color, muscle structure, bone
    structure, and even features like the shape of a
    nose.
  • Inheritable traits are traits that get passed
    down from generation to the next generation. This
    might include things like passing red hair down
    in a family.

6
The basics
  • Gregor Mendel "father of genetics"
  • Blending Theory of Inheritance - offspring of two
    parents "blend" the traits of both
    parentsParticulate Theory of Inheritance -
    traits are inherited as "particles", offspring
    receive a "particle" from each parent.
  • Evidence for Particulate Theory of Inheritance A
    plant with purple flowers is crossed with another
    plant that has purple flowers. Some of the
    offspring have white flowers (wow!). Mendel set
    out to discover how this could happen.

7
Mendel
  • parents were farmers
  • he became ordained as a priest
  • studied science and mathemathics at the
    University of Vienna
  • Mendel's Experiments - chose pea plants as his
    experimental subjects, mainly because they were
    easy to cross and showed a variety of contrasting
    traits (purple vs white flowers, tall vs short
    stems, round vs wrinkled seeds)

8
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9
  • _______________ was the father of genetics.
  • Charles Darwin b. Gregor Mendel
  • c. Charles Watson
  • What did he use in his research?
  • Corn b. Fruit flies
  • Peas
  • Hidden characteristics show up in_________ of the
    second generation.
  • One half b. One quarter
  • c. One third d. All of them

10
Mendels Procedure
  • 1. Mendel chose true-breeding lines of each
    plant/trait he studied (true breeding lines
    always produced offspring of the same type)
  • 2. He crossed a true breeding plant with a plant
    of the opposite trait (purple x white). He called
    this the Parental (P) generation.
  • 3. He recorded data on the offspring of this
    cross (First Filial, F1)
  • 4. He self pollinated the F1 offspring
  • 5. He recorded data on the offspring of the
    second generation, calling it the Second Filial
    generation (F2)

11
Mendels Analysis
  • The F1 generation always displayed one trait (he
    later called this the dominant trait)
  • The F1 generation must have within it the trait
    from the original parents - the white trait
  • The F2 generation displayed the hidden trait, 1/4
    of the F2 generation had it (he later called this
    hidden trait the recessive trait)
  • Each individual has two "factors" that determine
    what external appearance the offspring will have.
    (We now call these factors genes or alleles)

12
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13
Mendels Conclusion
  • Mendel established three principles (or Laws)
    from his research
  • 1. The Principle of Dominance and Recessiveness -
    one trait is masked or covered up by another
    trait
  • 2. Principle of Segregation - the two factors
    (alleles) for a trait separate during gamete
    formation
  • 3. Principle of Independent Assortment - factors
    of a trait separate independently of one another
    during gamete formation another way to look at
    this is, whether a flower is purple has nothing
    to do with the length of the plants stems - each
    trait is independently inherited

14
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15
  1. True or False Principle of Dominance states
    that one factor in a pair may prevent the other
    factor from appearing.
  2. True or False the recessive factor is kept from
    appearing by the dominant factor

16
  • True or False each trait is controlled by 3
    factors.
  • The principle of dominance states that one factor
    in a pair may prevent another factor from
    appearing.
  • The _____________ factor is kept from appearing
    by the ______________ factor.
  • a. Dominant, recessive
  • b. Recessive, dominant
  • If a dominant and recessive trait combine only
    ___________ will be displayed.
  • a. Dominant
  • b. Recessive
  • True or False The recessive trait disappears and
    will never appear again.

17
The Law of Segregation
  • The Law of Segregation two alleles separate
    during gamete formation (a Tt parent can produce
    both T sperm, and t sperm)
  • A punnet square is a representation of this law,
    showing how gametes separate and then come
    together during fertilization

18
A simpler look at Mendels generations
19
Modern Genetics
  • Mendel's factors are now called ALLELES. For
    every trait a person has, two alleles determine
    how that trait is expressed.
  • We use letters to denote alleles, since every
    gene has two alleles, all genes can be
    represented by a pair of letters.
  • PP purple, Pp purple, pp white

20
Important Terms
  • Homozogyous when the alleles are the same, the
    individual is said to be homozygous, or true
    breeding. Letters designating a homozgyous
    individual could be capital or lowercase, as long
    as they are the same. Ex. AA, bb, EE, dd
  • Heterozygous when the alleles are different, in
    this case the DOMINANT allele is expressed. Ex.
    Pp, Aa
  • Monohybrid cross a cross involving one pair of
    contrasting traits. Ex. Pp x Pp
  • Punnet Square used to determine the PROBABILITY
    of having a certain type of offspring given the
    alleles of the parents

21
Homozygous vs. Heterozygous
  • Homozygous involves traits where both alleles are
    the same , either dominant or recessive. If we
    were talking about round or wrinkeled seeds we
    could use the letter R. RR would be homozygous
    dominant and rr would be homozygous recessive
  • Heterozygous involves traits where one inherited
    allele is dominant and the other is recessive
    such as Rr

22
Indicate whether the following are homozygous
dominant, homozygous recessive or heterozygous
  1. HH _________________
  2. Hh
  3. hh
  4. Rr
  5. rr
  6. RR

23
  • In this picture the two "hot dog" shapes
    represent a pair of homologous chromosomes. 
    Homologous chromosomes are the same size have
    the same genetic info (genes).  Each letter in
    the diagram stands for an allele (form of a
    gene).  What's important to notice is that the
    letters can be in different forms (capital or
    lowercase) --- that is what we mean by allele ---
    and that the letters are lined-up in the same
    order along each hot dog --- homologous
    chromosome. The "a-forms" are in corresponding
    positions, so are the "B-forms", the "c" alleles,
    the "d" alleles, etc. etc. Reread that "allele"
    definition again study the picture.
  • back to our abbreviations, we could use a "C" for
    the curly allele, and a "c" for the straight
    allele.  A person's genotype with respect to hair
    texture has three possiblilties CC, Cc, or cc. 
    So to review some vocab, homozygous means having
    two of the same allele in the genotype (2 big or
    2 little letters --- CC or cc).  Heterozygous
    means one of each allele in the genotype (ex
    Cc).

24
Genotype vs. Phenotype
  • Genotype letters used to denote alleles (BB, Pp,
    etc.)
  • Phenotype what an organism looks like (brown,
    purple..) Its physical appearance.
  • If we donate PP for purple flowers and p for pink
    flowers, fill in the genotype and phenotype of a
  • 1. homozygous dominant flower
  • 2. homozygous recessive flower
  • 3. heterozygous flower

25
Answers
  • Homozygous dominant flower
  • genotype - PP
  • phenotype purple
  • Homozygous recessive flower
  • genotype pp
  • phenotype pink
  • Heterozygous flower
  • genotype Pp
  • phenotype - purple

26
PUNNETT SQUARES
  • In pea plants, round seeds are dominant to
    wrinkled. The genotypes and phenotypes are
  • RR roundRr roundrr wrinkled

27
Punnett Squares Monohybrid cross
28
Punnett Squares Monohybrid cross
29
Punnett Squares Monohybrid cross
  • PARENTS One is tall TT (homozygous) and one is
    short tt (homozygous)

T
T
t
Tt Tt
Tt Tt
t
All offspring are tall!
30
Punnett Squares Monohybrid cross
  • In the previous slide the two homozygous parents
    had all tall children who were heterozygous. Now
    we cross the offspring Tt x Tt

T
t
TT Tt
Tt tt
T
t
Now the probability of having a tall child is
lower It is 31, because three are tall one one
is short
31
How to make a punnett square
  • 1. Determine the genotypes (letters) of the
    parents. Bb x Bb2. Set up the punnett square
    with one parent on each side.3. Fill out the
    Punnett square middle4. Analyze the number of
    offspring of each type.
  • In pea plants, round seeds are dominant to
    wrinkled. The genotypes and phenotypes areRR
    roundRr roundrr wrinkled

32
  • If you get stuck make a "key". Sometimes the
    problems won't give you obvious information.
    Example In radishes, a bent root is a dominant
    trait, though some roots are straight (which is
    recessive). If a straight rooted plant is crossed
    with a heterozyous bent root plant, how many of
    the offspring will have straight roots?
  • Say what? First of all, this problem doesn't make
    it easy. Start by assigning genotypes and
    phenotypes. Pick the letter of the dominant
    trait. B for bent
  • BB bentBb bentbb straightNow use the key
    to figure out your parents. In this case you have
    a straight root plant (bb) crossed with a
    heterozyous bent plant (Bb). Once you've figured
    that out, the cross is simple!

33
Incomplete dominance
  • Some alleles are neither dominant nor recessive,
    and many traits are controlled by mulitple
    alleles or multiple genes
  • Incomplete dominance is when one allele is not
    completely dominant over another results in
    blended traits

34
Incomplete Dominance
  • There is no dominant or recessive, the
    heterozygous condition results in a "blending" of
    the two traits. Example Snapdragons can be red,
    white, or pink (heterozygous)

R allele for red flowers W allele for white
flowers red x white ---gt pink RR x WW ---gt 100
RW
35
Now you try
  • 1. A cross between a blue blahblah bird a white
    blahblah bird produces offspring that are
    silver.  The color of blahblah birds is
    determined by just two alleles. a) What are the
    genotypes of the parent blahblah birds in the
    original cross? b) What is/are the genotype(s)
    of the silver offspring? c) What would be the
    phenotypic ratios of offspring produced by two
    silver blahblah birds?

36
  • 1. A cross between a blue blahblah bird a white
    blahblah bird produces offspring that are
    silver.  The color of blahblah birds is
    determined by just two alleles. a) What are the
    genotypes of the parent blahblah birds in the
    original cross?
  •   Since there are only 2 alleles three
    phenotypes (blue, white, silver), we must be
    dealing with incomplete dominance.  So the blue
    parent is homozygous blue (BB) the white parent
    is homozygous white (WW).
  • b) What is/are the genotype(s) of the silver
    offspring? 
  • The silver offspring are hybrids (BW), one blue
    allele one white allele, neither one dominating
    the other.  Instead, we get a blending of blue
    white, i.e. silver. c) What would be the
    phenotypic ratios of offspring produced by two
    silver blahblah birds?    silver x silver BW
    x BW
  • The p-square would look like what you see here.

As you can see, 25 (1/4) of the offspring are
homozygous white (WW), 25 (1/4) are homozygous
blue (BB), 50 (2/4) are hybrid therefor have
the silver phenotype.
37
Codominance
  • Both alleles attribute to the phenotype
  • Trait is not blended (as in the pink snapdragons)
    rather they are both expressed example would be
    spotted coats
  • R allele for red flowers W allele for white
    flowers
  • red x white ---gt red white spotted RR x WW
    ---gt 100 RW

38
Now you try
  • 1. A cross between a black cat a tan cat
    produces a tabby pattern (black tan fur
    together). a) What pattern of inheritence does
    this illustrate? b) What percent of kittens
    would have tan fur if a tabby cat is crossed with
    a black cat?

39
  • a) What pattern of inheritence does this
    illustrate?  Codominance, two phenotypes
    together at the same time
  • b) What percent of kittens would have tan fur if
    a tabby cat is crossed with a black cat?   Tabby
    cats are the hybrids (because they have both
    colors) a black cat must be homozygous black. 
    So the cross for this problem is BB (black) x BT
    (tabby).
  • The results show that 50 of the offspring will
    be BB (black) 50 will be tabby (BT).  So to
    answer the question, 0 of the kittens will be
    tan.

40
Multiple Alleles
  • Genes which have more than two alleles does not
    mean that the individual has more than two, just
    means that more than two possiblities exist in
    the population. Examples include different color
    coats, blood types in humans
  • Blood type in humans is controlled by three
    alleles A, B, and O

Phenotype Genotype
A AA or AO
B BB or BO
AB AB only
O OO only
41
Examples of Blood type crosses

42
Polygenic Traits
  • Traits controlled by two or more genes
  • Wide variety of phenotypes
  • Example skin color in humans

43
Punnett Squares Dihybrid cross
  • Monohybrid crosses are used to determine only ONE
    trait.
  • Dihybrid crosses involve TWO traits

44
Dihybrid crosses
  • Crosses that involve 2 traits
  • For these crosses your punnet square needs to be
    4x4
  • In any case where the parents are heterozygous
    for both traits (AaBb x AaBb) you will get a
    9331 ratio.

45
Now you try
  • If you cross other combinations, you will need to
    do a square.
  • Try RrYy x rryy

46
Meiosis Warm Up 1 pg. 43 HonorsPg. 41 regulars
  • What is the main goal of meiosis?
  • What is a gamete?
  • How many cells are produced through mitosis?
  • How many cells are produced through meiosis?
  • 2n30, what is the haploid number?
  • GRAB YOUR CLICKERS!

47
Did you know?
  • A group of ravens is called a murder.
  • A group of bears is called a sleuth.
  • Twelve or more cows is called a flink.
  • A baby oyster is called a spat.
  • A group of unicorns is called a blessing.
  • A group of kangaroos is called a mob.

48
Did you know?
  • By some unknown means, an iguana can end its own
    life.

49
Did you know?
  • It was discovered on a space mission that a frog
    can throw up. The frog throws up its stomach
    first, so the stomach is dangling out of its
    mouth. Then the frog uses its forearms to dig
    out all of the stomachs contents and then
    swallows the stomach back down again.

50
Did you know?
  • The woodland frog is the only animal able to
    survive being completely frozen. These frogs
    live north of the arctic circle and can be frozen
    for weeks their cells dont freeze but the
    water outside their cells does. The heart can
    also stop, but once the temperature rises they
    come back to life

51
Did you know?
  • The bagpipe was originally made from the whole
    skin of a sheep.

52
Did you know?
  • More people are killed annually by donkeys than
    in airplane crashes.

53
Did you know?
  • When a horned toad is angry, it squirts blood
    from its eyes.

54
Did you know?
  • The average garden-variety caterpillar has 248
    muscles in its head.

55
Chapter 14 Human Genome
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