chapter 10:
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Chapter 10:. Patterns of Inheritance. Thinking Time!!!!!!!!!. Why is it, in some cases, that two brown-eyed parents have all brown-eyed children, and in other cases two brown-eyed parents have some brown-eyed children and some blue-eyed children? - PowerPoint PPT PresentationTRANSCRIPT
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Chapter 10:
Patterns of Inheritance
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Thinking Time!!!!!!!!!
• Why is it, in some cases, that two brown-eyed parents have all brown-eyed children, and in other cases two brown-eyed parents have some brown-eyed children and some blue-eyed children?
• What do you think would be the result of a cross between a red flower and a white flower?
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1. The Blending Hypothesis:– Predicts that offspring appearances will be blends of the
phenotypes of their parents.
2. The Particulate Hypothesis (Mendel): – One copy of each factor is inherited from each parent.– The factors remain intact and do not physically blend
together.
+ red white all pink
+ red white
+red white
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Genetic Vocabulary:
• Trait: Variation of a particular character. – Ex: eye color is a character,
• Hybrids: The offspring of 2 different true-breeding species.
• Monohybrid cross: a pairing in which the parents differ in only one (mono) character. – Ex: Flower color
traits
while
+ mule
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P generation: Parent plants
F1 generation: The hybrid offspring
F2 generation: When F1 plants self-fertilize or fertilize each other, their offspring makes up the F2 generation.
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Terms need to know:
• Allele: The different forms of genes. – Organisms have two alleles for each trait, one from each
parent.
• Dominant: appear to hide other traits.– capital letters
• Recessive: can be hidden in one generation and then appear in the next.– lower-caser letters
• Phenotype - the way an organisms’ genes express themselves (physical type, description)– either short, tall, purple, white, & etc
• Genotype - the gene type of an organism (genes, letters)– TT, Tt, tt
ABCDEFGH
abcdefgh
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Homozygous vs. Heterozygous
In pea plants,
• Homozygous - 2 alleles are the same.– homozygous dominant
• 2 dominant genes : PP– homozygous recessive
• 2 recessive genes : pp• Heterozygous – 2 alleles are different.
– 1 dominant gene and 1 recessive gene: Pp.
is dominant over
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Gregor Mendel
• Often called the "Father of Genetics”• Performed many experiments with
plants, mostly garden peas.• His 1st step: identify true-breeding
plant.• 2nd step: He crossed true-breeding
plants that had two distinct traits.
?
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Mendel’s First Experiment:
¾ of plants are purple¼ of plants are white
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Mendel’s Results:• He examined the inheritance patterns of 7 different
pea-plant characters. • For each character, one of the two parent traits
disappeared in the F1, but reappeared in ¼ of the F2 generation.
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The Testcross:
• It is not possible to predict the genotype of an organism with a dominant phenotype.
• It could be homozygous dominant PP or heterozygous Pp.
• A test cross can determine the identity of the unknown allele.
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Writing Genotypes from phenotypes:
For Height: tall (T) is dominant and short (t) is recessive.
• 1. homozygous dominant for height– Answer: TT
• 2. heterozygous for height– Answer: Tt
• 3. homozygous tall– Answer: TT
• 4. recessive for height– Answer: tt
• 5. heterozygous tall– Answer: Tt
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Writing phenotypes from genotypes:For Height:
tall (T) is dominant and short (t) is recessive.For Flower color:
red (R) is dominant and white (r) is recessive.• 6. TT
– Answer: homozygous dominant, tall• 7. tt
– Answer: homozygous recessive, short• 8. Tt
– Answer: heterozygous, tall• 9. Rr
– Answer: heterozygous, red• 10. rr
– Answer: homozygous recessive, white
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Activity Time:The Coin Activity
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• When tossing one penny, what is the probability of getting one head?
• When tossing one penny, what is the probability of getting one tail?
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When tossing two pennies, what is the probability of getting one head and one tail?
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Punnett Squares
• It shows the possible outcomes for the Phenotypes of the individual.
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Predicting Genotypes & Phenotypes
• In pea plants,
• Cross: homozygous tall X homozygous short
Tall Short
is dominant
over
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Step 1:
• Write down the genotypes of each parent – ABCDEFGH dominant traits– abcdefgh recessive traits
• Homozygous tall:
• Homozygous short:
TT
tt
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Step 2:
• Draw a Punnett square• Write the gametes of one parent across the top
and the other parent along the side
T T
t
t
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Step 3:
• Fill in each box of the Punnett square– Capital letter goes 1st
T T
t
t TT
TT
tt
tt
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Step 4:
• List the possible genotypes and phenotypes of the offspring.
• Possible genotypes:
• Possible phenotypes:
Tt
Tall
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T T
t
t
Tt
Tt Tt
Parent 1:
Parent 2:
Tt
Results
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Results
• Each of the offspring has a ____ /4 or _____% chance of showing ______ genotype.
• Since T (tall) is dominant over t (short). Therefore, each of the offspring has a ____/4 or _____% chance of being __________.
Tt
1004
1004
tall
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Key: brown eyes (B) is dominant, blue eyes (b) is recessive
Homozygous dominant X Heterozygous • Genotypes: BB & Bb
B B
B
b
BB BB
Bb Bb
Practice Time:
is dominant over
Questions:1. Phenotype of offspring?2. Genotype of offspring?3. Phenotypic ratio:4. Genotypic ratio:
all brown
BB & Bb
2 BB: 2Bb
4 brown: 0 blue
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Your Turn
Questions:1. Phenotype of offspring?2. Genotype of offspring?3. Phenotypic ratio:4. Genotypic ratio:
is dominant over
In humans,
heterozygous brown X heterozygous brown
brown & blueBB, Bb & bb
3 Brown: 1 blue
1 BB: 2 Bb: 1 bb
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Dihybrid Cross
• In one dihybrid cross experiment, Mendel studied the inheritance of seed color and seed shape.
is dominant over
Yellow (Y) green (y)
is dominant over
Round (R) wrinkled (r)
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Dihybrid cross:
• Mendel crossed true-breeding plants that had yellow, round seeds (YYRR) with true-breeding plants that has green, wrinkled seeds (yyrr).
• The first parent could only produce RY gametes. The other could only produce ry gametes.
• The union of these gametes results in RrYy.
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Dihybrid Cross:
• Four classes of gametes (YR, Yr, yR, and yr) are produced in equal amounts.
• Which results in 16 equally probable ways in which the alleles can combine in the F2 generation.
• Phenotypic ratio - 9:3:3:1
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Intermediate Inheritance:
• In Mendel’s pea crosses, the F1 offspring always looked like the dominant homozygous parent. – Because the recessive phenotype required two
recessive alleles.
– But, for some characters of organisms, neither allele is dominant intermediate inheritance.
YY yellow
Yy yellow
yy green
Dominant
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• Heterozygous F1 generation hybrids do not show the phenotype of the dominant allele or the recessive allele but somewhere in between.– For example, in a particular breed of chickens
called Andalusians, black and white offspring produce blue F1 hybrid offspring.
– Because neither the black nor white is dominant, capital or lower case letters are not used.
– Instead a C for color is paired with a superscript B for black or W for white.
Intermediate Inheritance:
CB CB CWCW CBCW
black
white blue
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CB CB CWCW
CBCW
CWCWCBCWCBCWCB CB
X
The predicted phenotypes in F2 are 1 black: 2 blue: 1 white
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Multiple Alleles:• Codominant: both alleles are expressed • The gene for human blood type expresses four phenotypes:
– A, B, AB or O.
• The alleles IA and IB are codominant and the i allele is recessive to both.
Phenotypes(Blood type)
Genotypes
A IAIA or IAi
B IBIB or IBi
AB IAIB
O ii
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• The letters refer to two carbohydrates, designated A and B, which are found on the surface of red blood cells.
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• Type O-negative blood does not have any antigens. It is called the "universal donor" type because it is compatible with any blood type.
• Type AB-positive blood is called the "universal recipient" type because a person who has it can receive blood of any type.
FYI:
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Polygenic inheritance
• When a single phenotype results from the expression of two or more genes.
• For instance, phenotypes like high blood pressure are not the result of a single "blood pressure" gene with many alleles.
• The phenotype is an interaction between a person's weight, cholesterol level, kidney function, smoking, and probably lots of others too.
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The Importance of Environment
• An individual’s phenotype depends on environment as well as genes.
• In human, nutrition influences height, exercise affects build, and exposure to sunlight darkens skin.
• The product of a genotype is generally not a single defined phenotype, but a range of possibilities influenced by the environment.
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Chromosome Theory of Inheritance:
• It states that:– Genes are located on chromosomes.– Homologous Chromosomes separate during
meiosis so that alleles are segregated.– Chromosomes under go segregation and
independent assortment during meiosis.
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Mendel’s Law of Genetics:
1. Alleles are different forms of the same gene that segregate during gamete formation (Law of Segregation)
2. Alleles of different genes segregate independently (Law of independent assortment)
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Sex-linked Genes
• Located on a sex chromosome • In humans, most sex-linked genes are found on the X
chromosome, which is much larger than the Y chromosome.
• Discovered by Thomas Hunt Morgan.
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Xr Y
XR XRXr
female
XRY male
XR XRXr
female
XRY male
P:
F1:
All the F1 offspring had red eyes.
Morgan mated a white-eyed male fly with a red-eyed female fly.
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XXRXr
female
XRY
male
F1:
XR Y
XR XRXR
female
XRY male
Xr XRXr
female
XrY male
F2:
Then, he bred the F1 offspring together.
He got the classical 3:1 phenotypic ratio.However, none of the flies with white eyes were female.He concluded that the gene involved is only on the X chromosome.
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Are you colorblind?????
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Are you colorblind?????
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Are you colorblind?????