Download - Practice Pedigrees! Try them out!

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Page 1: Practice Pedigrees! Try them out!

Practice Pedigrees! Try them out!

A shape with a dot in the center denotes a ‘carrier’

Page 2: Practice Pedigrees! Try them out!

Cartoons of the Day!

Page 3: Practice Pedigrees! Try them out!

Cartoons of the Day!

Page 4: Practice Pedigrees! Try them out!

Cartoons of the Day!

Page 5: Practice Pedigrees! Try them out!

Cartoons of the Day!

Page 6: Practice Pedigrees! Try them out!

Cartoons of the Day!

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Are you ready for some Pedigrees?!?! Before we move on any questions regarding

Punnett Squares?

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What are Pedigrees? A pedigree is a diagram of family relationships that uses

symbols to represent people and lines to represent genetic relationships.

Pedigrees are often used to determine the mode of inheritance (dominant, recessive, etc.) of genetic diseases.

Autosomal: Refers to chromosomes that are NOT sex chromosomes (xx or xy).

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Anatomy of a PedigreeCircle= FemaleSquare= Male

A line connecting a square and a circle implies they “mated.” Probably in the early afternoon.

If a circle or square is darkened, that means has a particular trait or suffers from a disease/disorder.

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Different Modes of Inheritance: 1.) Autosomal Dominant Diseases or traits that exhibit an Autosomal Dominant

inheritance pattern follow the following rule:

A = the trait (a genetic disease or abnormality, dominant)a = normal (recessive)

Examples of autosomal dominant disorders: Achondroplasia, pseudoachondroplasia, the multiple epiphyseal dysplasias, chondrodysplasias, osteogenesis imperfecta, Marfan syndrome, polydactyly, hereditary motor sensory neuropathies I and II (Charcot-Marie-Tooth disease), myotonic dystrophy, and neurofibromatosis.

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Are these both examples of Autosomal Dominant Pedigrees?

A B

Explain your answer!

What are the genotypes in pedigree B?

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Quick Review Question! You know you love it!

What can you conclude from these two examples about the parents of a person that has a dominant characteristic?

A.)If a person has a dominant trait, the parents will not have the trait.B.)If a person has a dominant trait, the parents might have the trait or they might not have it.C.) If a person has a dominant trait, at least one of the parents will have the trait.D.)If a person has a dominant trait, both of the parents will have the trait.

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Another Example: Aww Yea!!

What are the genotypes in this pedigree?

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Quick Review Questions: The Adventure Continues! 1.) Is it possible that this pedigree is for an

autosomal dominant trait? 2.) Can two individuals that have an autosomal

dominant trait have unaffected children?

A.)If two individuals have a dominant trait, none of their offspring will have the trait.B.)If two individuals have a dominant trait, their offspring might or might not have the trait.C.)If two individuals have a dominant trait, their offspring will have the trait.

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Different Modes of Inheritance: 2.) Autosomal Recessive

Diseases or traits that follow Autosomal Recessive inheritance patterns:

A = normala = the trait (a genetic disease or abnormality)

Examples of Autosomal Recessive diseases: Cystic fibrosis, sickle cell anemia (We will study this very soon), and Tay Sachs disease.

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Guess what: More Pedigrees! Assuming that the trait is recessive, write the

genotype of each individual next to the symbol.

Is this an example of an Autosomal Recessive Pedigree?

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What About this one?

Assuming the disorder is recessive, is this an example of an Autosomal Recessive pedigree?Write in the Genotypes for each individual.

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Quick Review Question: Great things come in 3’s 1.) If a trait is autosomal recessive, what can you

conclude about the children if both parents are affected?

A.) If both parents are affected, none of the children will be affected.

B.)If both parents are affected, the children might or might not be affected.C.)If both parents are affected, all of the children will be affected.

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Hmm, what about this one?

Is it possible that this pedigree is for an autosomal recessive trait?

What are the Genotypes for these individuals?

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Quick Review Question: If a trait is autosomal recessive, what can you

conclude about the children of two parents that are not affected?

A.) If two parents have a dominant trait, the children will not have the trait.B.) If two parents have a dominant trait, the children might or might not have the trait.C.) If two parents have a dominant trait, the children will have the trait.

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Challenge Question 1

Can this pedigree possible represent an Autosomal Recessive disease?What does this pedigree infer about recessive traits?

Assign Genotypes as usual.

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Different Modes of Inheritance: 3.) X-Linked Recessive

The sex of an individual has been linked to certain disorders, we’ll finish by examining these pedigrees.

New NomenclatureXA = normalXa = the trait (a genetic disease or abnormality)Y = Y chromosome (males only)

Examples for a Female: XAXa, XAXA, XaXa

What would the male sex genotype look like?

Examples for Males: XAY, XaY

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Let’s Practice

Assign the genotypes (Use X and Y’s now).

Is it possible that the pedigree above is  for an X-linked recessive trait?

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Keep Going, almost there!

Assign the genotypes (Use X and Y’s now).

Is it possible that these pedigrees represent an X-linked recessive trait?

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Last Quick Review Questions! What can you conclude about the children of mothers

affected with an X-linked recessive trait: If the mother has an X-linked recessive trait, the children will not have the trait.A. )If the mother has an X-linked recessive trait, the children might or might not have the trait.B.) If the mother has an X-linked recessive trait, all of the children will have the trait.C.) If the mother has an X-linked recessive trait, females will have the trait but males will only have the trait if their father also has the trait.D.) If the mother has an X-linked recessive trait, males will have the trait, but females will only have the trait if their father also has the trait.

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Last Quick Review Questions! A New Hope! What can you conclude about the father of an

affected female?

A.)The father of an affected female will not be affected.B.) The father of an affected female might or might not be affected.C.)The father of an affected female will be affected.

Why is this so? Let’s Explore that tomorrow!

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Homework! Create a simple Pedigree of your own family! Figure out whether a trait (eye color, hair color, a

disease) has an autosomal dominant or autosomal recessive behavior.

2 Generations are requiredbut 3 would be best.

Due Thursday!

Example

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Solution!

EHF

EhF

EhfeHF

ehF

ehf

EHF ehfehFeHFEhfEhFEEHHFF

Fill in the rest of the table and interpret the data!

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Question of the Day!

What makes a family a family? When does a immediate family stop

and an ancestry begin?

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We Are Family! Introduction to Dihybrid

Crosses and Pedigree GeneticsMr. Nichols

PHHS

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Cartoon of the Day!

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Cartoon of the Day!

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Cartoon of the Day!

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Introduction Problems In summer squash, white fruit color (A) is

dominant over yellow fruit color (a) and disk-shaped fruit (D) is dominant over sphere-shaped fruit (d). If a white homozygote squash with Heterozgous disk-shaped fruit  is crossed with a yellow, sphere-shaped fruit,  what will the phenotypic and genotypic ratios be for:

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Try this one on your own! In the deep rainforests of Brazil lives the Ocamazi tribe,

amongst the members of this tribe exists a dominant trait for webbed feet (F), most have this trait, those that don’t have non-webbed feet (f). Additionally most members of this tribe webbed hands(W), a small minority have normal non-webbed fingers (w). Needless to say this tribe is great at swimming.

Problem: An Ocamazi princess Heterozygous for both webbed feet and fingers travels to another tribe to meet her soon to be husband, his tribe also has webbed feet which is also heterozygous for but no webbed hands which he is homozygous for. Draw the cross for the mating of these two people.

Page 36: Practice Pedigrees! Try them out!

Solution Princess: FfWw Husband: Ffww

FFWw FFWw FfWw FfWw

FFww

FfWw

FFww

ffww

ffWw

Ffww

ffww

ffWw

Ffww

Ffww

Ffww

FfWw

FW

fwFw

Fw

fwFw

fW

fw

F-Webbed Feet, f-Non Webbed FeetW- Webbed hands, w-Non Webbed hands

Interpret this data!

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Challenge Problem You are a world-famous breeder of Purple-People

Eaters.  Tragically, your entire stock perishes in a fire except for two individuals.  They are both heterozygous for all three traits desired.  The three traits are as follows:

Traits EE or Ee=Two eyes        ee= One eye HH or Hh= Two horns       hh= One horn FF or Ff= Non-flying      ff= Flying

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HAPPY FRIDAY, GET YOUR NOTES OUT IN PREPARATION FOR AMAZING

THINGS TO COME!!!

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Cartoons of the Day!

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Page 41: Practice Pedigrees! Try them out!
Page 42: Practice Pedigrees! Try them out!

Cartoons of the Day!

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Cartoons of the Day!

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Cartoons of the Day!

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Solve the following Pedigree by assigning genotypes and determining the mode of inheritance.

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Cartoons of the Day!

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Cartoons of the Day!

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Cartoons of the Day!

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Cartoons of the Day!

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Cartoons of the Day!

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Cartoons of the Day!

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Cartoons of the Day!

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Remaining FUNWORK!!!! 1.) Pedigree Practice Problems (Due

Friday) 2.) Family Pedigree (Due Friday) 3.) Midterm Study Guide (Due Thursday)

Besides the midterms these are the remaining assignments for the semester.

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Family Pedigree Assignment 1.) Construct a trio of 3 generation

pedigrees for the following traits. 1 pedigree for each trait.

Hitchhiker’s thumb, widow’s peak, attached earlobes.

Each pedigree must be labeled with the names and ages of those involved. If unknown label ‘Unknown.

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Traits!