bio 9b: friday, 3.19.10 title: introduction to genetic inheritance and variation

Bio 9B: Friday, 3.19.10Title: Introduction to Genetic Inheritance and Variation

Homework: Give me your Notebooks at the end of class (After

the Do Now and the Genetics Overview)!!!! Finish drawing your baby!

Do Now: How can an error in meiosis result in abnormal

chromosome numbers in people? Nondisjunction Videos

Today’s Objectives: Experiment with probability to see the diversity of

offspring that can be made through sexual reproduction

Karyotyping Activity – Part II Review

Nondisjunction Videos

MENDELIAN GENETICS &GENETIC INHERITANCEBiology 9

Moretti and Dickson

Genetics Overview

The study of gene inheritance and variation

Answers big questions like: How are traits inherited? Why do offspring look similar to their

parents but not exactly like their parents? How do we have so many different types of

organisms and so much genetic variation?

Objectives for Class:• Experiment with probability to see the diversity of offspring that can be made through sexual

reproduction

Mendelian Genetics and Probability

New Vocabulary: Dominant and Recessive Genotypes and Phenotypes

Objectives for Class:• Experiment with probability to see the diversity of offspring that can be made through sexual

reproduction

New Vocabulary: Dominant and Recessive

Dominant: The allele that is always expressed as a trait if it is present

(regardless of other alleles) Recessive:

The allele that is only expressed as a trait if the dominant allele is not present

Mendelian Genetics and Probability

Objectives for Class:• Experiment with probability to see the diversity of offspring that can be made through sexual

reproduction

Evidence:

True-breeding yellow x True-breeding green

(YY) (yy)

All yellow offspring (Yy)

New Vocabulary: Genotypes and Phenotypes

Genotypes: The genetic make-up of an organism The combination of alleles

Phenotypes: The expressed physical characteristics The “Trait”

“Phenotypes are the sum of Genotypes + Environment”

Mendelian Genetics and Probability

Objectives for Class:• Experiment with probability to see the diversity of offspring that can be made through sexual

reproduction

“Makin’ Babies”: Mendelian Genetics & Probability

Use the “Genotype Data Table” to determine the Traits of your baby by flipping the coin a total of two times for each trait (once for each allele). Heads = Dominant and X Tails = Recessive and Y

For example: Face shape = R, so heads=R and tails = r

Write the combination of the alleles in the box next to the trait. This is the Genotype for each trait

Then, go to the Phenotype chart Determine the Phenotype based on the Genotype from page 1 For example: if you flipped two RR for face shape, the phenotype

would be Round After all of the Phenotypes are determined, draw your baby by using the

traits from the Phenotype chartObjectives for Class:• Experiment with probability to see the diversity of offspring that can be made through sexual

reproduction

Bio 9B: Monday, 3.22.10Title: Genetic Inheritance and Variation

Homework: Complete the analysis questions for the Makin’

Babies Activity

Do Now: Learning how to use the “CLICKERS” Actual Do Now in a few slides…

Today’s Objectives: Differentiate between genotypes and phenotypes Experiment with probability to see the diversity of

offspring that can be made through sexual reproduction

Learning how to use the “Clickers”

What are they? Audience response tools that allow you

to enter your response/ answer by “clicking” the handheld response card (sort of like Jeopardy).

Why are they cool? Everyone can participate in class! You can answer questions from class

without waiting to be called upon! In seconds, we can determine how

many people really understand what we are doing and adjust accordingly to meet the needs of the class!

Learning how to use the “Clickers”

How do they work? Each of you will get a clicker

assigned to you (based on your last name position in the alphabet).

Every day you come to class, you will take your Clicker from the Clicker rack and sit down.

As I post slides that have questions for you to answer, you will “click” your answer on the handheld Clicker.

Your response goes right to the computer where software records the responses, tabulates the numbers of responses, and creates graphs to show how the class responds.

Your Clicker Number:Write it on the FRONT of your notebook

Clicker Number

Student Name

1 Adel2 Jisraele3 Christina4 Rachelle5 Gabrielle6 Wilson7 Weston8 Loic9 Jefferson

10 Yikaalo11 Jennifer12 Sophia13 Mildred

Clicker Number

Student Name

14 Danika15 Reggie16 Josh17 Andrew18 Ruth19 Scarlett20 Emma21 Clamentina22 Nick23 Chyneree24 Graceann25 Djinnie

Now…

Get your clicker Once everyone has their clicker…

Hold down the Channel button for a few seconds

Press ZERO and then TWO Press Channel again

(This will set your clicker to the proper channel)

DO NOW: Does this picture show GENOTYPES or PHENOTYPES? “Click” your answer…

A. GenotypesB. Phenotypes

Objectives for Class:• Differentiate between genotypes and phenotypes

Vocabulary Review

Genotype:

genetic make-up/combination of alleles (Ex: AA, Aa, or aa)

Phenotype:

The traits that an organism has (Ex: purple flowers or white flowers)

Trait:

a specific characteristic that varies between individuals (Ex: flower color)

Objectives for Class:• Differentiate between genotypes and phenotypes

Vocabulary Review

Fill in the blanks…

Which allele is dominant? Recessive? How do you know? Purple (A) = Dominant White (a) = Recessive

What is the phenotype?

What is the phenotype?

What is the genotype?

Objectives for Class:• Differentiate between genotypes and phenotypes

New Vocabulary: Homozygous and Heterozygous

Homozygous: Two of the same allele for a particular trait are present

Ex: RR = Round Face Ex: rr = Square Face

Heterozygous: Two different alleles for a particular trait are present

Ex: Rr = Round Face

Mendelian Genetics and Probability

Objectives for Class:• Experiment with probability to see the diversity of offspring that can be made through sexual

reproduction

Now we will use the Clickers to collect the Class Results for question 4.

To do this, enter in your baby’s phenotype for each of the following traits:

Face Shape Cleft Chin Widow’s Peak Earlobes Gender

As we address each trait, write the percentages for each phenotype in the Class Results chart.

Use this data to complete analysis question #4.

“Makin’ Babies”: Review and Analysis (w/ the Clickers)

Objectives for Class:• Experiment with probability to see the diversity of offspring that can be made through sexual

reproduction

Phenotype Class Results:What is the face shape of your baby?

1 2

27%

73%1. Round (dominant)

2. Square (recessive)

Objectives for Class:• Experiment with probability to see the diversity of offspring that can be made through sexual

reproduction

1 2

14%

86%

Phenotype Class Results:Does your baby have a cleft chin?

1. No, it’s absent (dominant)

2. Yes, it’s present (recessive)

Objectives for Class:• Experiment with probability to see the diversity of offspring that can be made through sexual

reproduction

Phenotype Class Results:Does your baby have a widow’s peak?

1 2

23%

77%1. Yes, it’s present (dominant)

2. No, it’s absent (recessive)

Objectives for Class:• Experiment with probability to see the diversity of offspring that can be made through sexual

reproduction

Phenotype Class Results:What kind of earlobes does your baby have?

1 2

32%

68%1. Unattached (dominant)

2. Attached (recessive)

Objectives for Class:• Experiment with probability to see the diversity of offspring that can be made through sexual

reproduction

Phenotype Class Results:What is the gender of your baby?

1 2

64%

36%

1. Girl (XX)2. Boy (XY)

Objectives for Class:• Experiment with probability to see the diversity of offspring that can be made through sexual

reproduction

Complete the Analysis Questions for the “Makin’ Babies” Activity

Please complete the questions on a separate sheet of paper…

3.23.10: Get Your Clicker…

Clicker Number

Student Name

1 Adel2 Jisraele3 Christina4 Rachelle5 Gabrielle6 Wilson7 Weston8 Loic9 Jefferson

10 Yikaalo11 Jennifer12 Sophia13 Mildred

Clicker Number

Student Name

14 Danika15 Reggie16 Josh17 Andrew18 Ruth19 Scarlett20 Emma21 Clamentina22 Nick23 Chyneree24 Graceann25 Djinnie

Bio 9B: Tuesday, 3.23.10Title: Genetic Inheritance & Variation - Mendel’s Principle of Segregation

Homework: Complete the Monohybrid Crosses Worksheet

Do Now: Get a clicker and answer the question Take out the Making Babies Analysis Questions

Today’s Objectives: Use Mendel’s Principle of Segregation to explain: How

can children show traits that their parents don’t have?

Use Punnett Squares to solve monohybrid crosses

Do Now: Which of the following terms applies to traits, such as eye color, that are controlled by more than one gene?

1. Codominant2. Polygenic 3. Recessive4. Dominant

Vocabulary Review

Fertilization: the joining of two

gametes in sexual reproduction

Zygote: a fertilized egg cell that

will grow and develop into an offspring

A human zygote, like most other human cells, contains 46 chromosomes. How many chromosomes does the a zygote receive from the mother?

1. 122. 233. 464. 92

In the diagram below, which process is fertilization?

1. Process A2. Process B

Some background on Mendel and what he did to advance genetics

You Don’t need to write this down:

Gregor Mendel studied genetics by doing experiments with pea plants.

He started with true-breeding plants, which he knew were homozygous for their traits.

Objectives for Class:• Use Mendel’s Principle of Segregation to explain: How can children show traits that their parents don’t have?

• Use Punnett Squares to solve monohybrid crosses

Objectives for Class:• Use Mendel’s Principle of Segregation to explain: How can children show traits that their parents don’t have?

• Use Punnett Squares to solve monohybrid crosses

You don’t need to write this down: Gregor Mendel studied genetics by doing

experiments with pea plants. He started with true-breeding plants,

which he knew were homozygous for their traits.

When he cross-bred these plants, he found that one phenotype was dominant over the other.

But when he cross-bred the offspring, the recessive phenotype reappeared!

How can we explain this??

Some background on Mendel and what he did to advance genetics

Mendel’s Discoveries

Principle of Segregation Principle of Independent

Assortment

Objectives for Class:• Use Mendel’s Principle of Segregation to explain: How can children show traits that their parents don’t have?

• Use Punnett Squares to solve monohybrid crosses

Mendel’s Discoveries: Principle of Segregation

Alleles segregate (separate) during meiosis so each gamete gets one allele

a a A A

a Aa

A

Two choices for gametes:A or a

Principle of Segregation (continued…)

This explains why the recessive trait reappears in the F2 generation…

In ¼ of the offspring.

Source of Gametes

In guinea pigs, rough coat (R) is dominant over smooth coat (r). A heterozygous guinea pig is mated with another heterozygous pig.What percentage of the next generation will have smooth coat?

1. 100%2. 50%3. 25%4. 75%

Bio 9B: Thursday, 3.23.10Title: Genetic Inheritance & Variation - Mendel’s Principle of Independent Assortment

Homework: Complete the calculations for the Part B and C analysis.

Complete conclusion questions 1 and 2. (note: different than assignment sheet).

Do Now: Homework Review: We need 3 volunteers to put problems 2,

3, and 4 on the side board Everyone else is “clicking” their answers to the questions on

the board

Today’s Objectives: Use Punnett Squares to solve monohybrid crosses Use Punnett Squares to solve dihybrid crosses Use Mendel’s Principle of Independent Assortment to explain how genetic

variation is created in individuals.

Double Block

Question 2 (d): What is the probability of purple flowers?

1 2 3 4

33%

0%

67%

0%

1. 25%2. 50%3. 75%4. 0%

Question 3 (C): If Ben and Jaelene has a child, what is the probability s(he) will have attached earlobes?

1 2 3 4

42%

0%0%

58%1. 25%2. 50%3. 75%4. 0%

Question 4 (b): A cross between a cow and a bull that both have red and white spots. What are the probabilities of a red calf?

1 2 3 4

78%

0%

13%9%

1. 25%2. 50%3. 75%4. 0%

Review: Principle of Segregation and Meiosis

AA

AaAaAaAa

A aA a

aaDiploid Cells

Segregation

Fertilization

Possible Haploid

Gametes

Possible Diploid Zygotes

Part A: Developing Your Hypothesis Use your knowledge of probability and inheritance to develop a

hypothesis for the percentages of two different phenotypes found in the F2 generation of corn offspring (seeds).

Part B: Investigating an actual F2

Test your hypothesis with an ear of corn. The kernels on these ears of corn are the F2 offspring from a cross that began with two parental varieties of corn with contrasting phenotypes (one yellow one purple).

Part C: Investigating Two Traits For this section you will see what happens when you look at the

inheritance of two separate traits? Mendel studied this by looking at seed color AND seed shape in pea plants – and that’s what you will do next, with an ear of corn.

“Counting Corn”: Genetic Crosses in Organisms

Objectives for Class:• Use Punnett Squares to solve monohybrid crosses• Use Punnett Squares to solve dihybrid crosses• Use Mendel’s Principle of Independent Assortment to explain how genetic variation is

created in individuals.

“Counting Corn”: Genetic Crosses in Organisms

Part A Procedure: Examine the pictures for corn kernel color and answer questions in your notebooksParent

(P1)

First Generation (F1)

Second Generation (F2)

Parent (P2)

X

X

“Counting Corn”: Genetic Crosses in Organisms Part B Data Table: Create in Notebooks

Phenotype Your Group’s Counts Class Count Totals

Yellow

Total Kernels ____________

Purple

Total Kernels ____________

Total # of Kernels Counted

Part A: Developing Your Hypothesis Use your knowledge of probability and inheritance to develop a

hypothesis for the percentages of two different phenotypes found in the F2 generation of corn offspring (seeds).

Part B: Investigating an actual F2

Test your hypothesis with an ear of corn. The kernels on these ears of corn are the F2 offspring from a cross that began with two parental varieties of corn with contrasting phenotypes (one yellow one purple).

Part C: Investigating Two Traits For this section you will see what happens when you look at the

inheritance of two separate traits? Mendel studied this by looking at seed color AND seed shape in pea plants – and that’s what you will do next, with an ear of corn.

“Counting Corn”: Genetic Crosses in Organisms

Objectives for Class:• Use Punnett Squares to solve monohybrid crosses• Use Punnett Squares to solve dihybrid crosses• Use Mendel’s Principle of Independent Assortment to explain how genetic variation is

created in individuals.

Bio 9B: Friday, 3.26.10Title: Genetic Inheritance & Variation - Mendel’s Principle of Independent Assortment (Moretti Absent – Sub-Plan)

Homework: Complete the Analysis and Conclusion Sections (should be

able to do this in class). Brainstorm the background information in your notebook

(clearly label this!). Type the background information section based on your brainstorm (don’t forget to make connections between the points).

Do Now: Get an ear of corn and complete the dihybrid analysis.

Today’s Objectives: Use Punnett Squares to solve dihybrid crosses Use Mendel’s Principle of Independent Assortment to explain

how genetic variation is created in individuals.

Part A: Developing Your Hypothesis Use your knowledge of probability and inheritance to develop a

hypothesis for the percentages of two different phenotypes found in the F2 generation of corn offspring (seeds).

Part B: Investigating an actual F2

Test your hypothesis with an ear of corn. The kernels on these ears of corn are the F2 offspring from a cross that began with two parental varieties of corn with contrasting phenotypes (one yellow one purple).

Part C: Investigating Two Traits For this section you will see what happens when you look at the

inheritance of two separate traits? Mendel studied this by looking at seed color AND seed shape in pea plants – and that’s what you will do next, with an ear of corn.

“Counting Corn”: Genetic Crosses in Organisms

Objectives for Class:• Use Punnett Squares to solve monohybrid crosses• Use Punnett Squares to solve dihybrid crosses• Use Mendel’s Principle of Independent Assortment to explain how genetic variation is

created in individuals.

Bio 9B: Monday, 3.29.10Title: Genetic Inheritance & Variation - Mendel’s Principle of Independent Assortment

Homework: Pass forward the monohybrid cross activity. Type the Background Info, procedure, purpose, and Part

A Hypothesis. Note: Brainstorm your background information section in your notebooks!

Do Now: Where are you with the Corn Lab? “Share-out” survey

on the side board.

Today’s Objectives: Use Punnett Squares to solve dihybrid crosses Use Mendel’s Principle of Independent Assortment to

explain how genetic variation is created in individuals.

Answering Corn Lab Questions Why Part A? How does Part A connect to Part B? How does having 2 traits change things?

Bio 9B: Tuesday, 3.30.10Title: Genetic Inheritance & Variation - Mendel’s Principle of Independent Assortment

Homework: Finish the Dihybrid Crosses Worksheet if you didn’t finish it

in class. Revise or complete Steps 5-9 of Part C on the Corn Lab if

you haven’t already, or if you can do a better job after today’s lesson on dihybrid crosses. Refer to the Dihybrid Crosses Worksheet for help if you need it.

Do Now: On the next slide…

Today’s Objectives: Use Punnett Squares to solve dihybrid crosses Use Mendel’s Principle of Independent Assortment to explain

how genetic variation is created in individuals.

In sheep, the allele for white wool is dominant (W) and the allele for black wool (w) is recessive. A farmer has mated two sheep for a few years and produced six offspring : 4 white and 2 black. One of the sheep has black wool and the other has white wool. Which of the following is likely the genotypes of the parent sheep?

1. WW and Ww2. WW and ww3. Ww and Ww4. Ww and ww

Quick Review from Yesterday

What is one difference between these two cells?

Which chromosome is homologous to this one? If we looked at human cells, how many pairs of

homologous chromosomes would they contain? Answer: 23 pairs (22 pairs plus the sex

chromosomes)

aa

A A

b b

BB

a a A A

Cell 1

Cell 2

A

B

A A aa

b bBB

A A aa

b b BB

A

B

a

b

a

b

or…

a

B

A

b

a

B

A

b

Four different possible gametes:AB ab Ab aB

Alleles for different genes segregate independently during meiosis.

In other words: If a gamete gets A or a, this doesn’t effect whether it gets B or b. Any combo is possible:Parent: AaBb

Possible gametes: AB Ab aB ab

This creates genetic diversity between gametes, and therefore a greater diversity of offspring.

Mendel’s Discoveries: Principle of Independent Assortment

Objectives for Class:• Use Punnett Squares to solve dihybrid crosses• Use Mendel’s Principle of Independent Assortment to explain how genetic variation is

created in individuals.

Bio 9B: Thursday, 4.1.10Title: Genetic Inheritance & Variation - Mendel’s Principle of Independent Assortment

Homework: Finish typing the lab for Monday. Complete the Mendelian Genetics Review packet

Do Now: Take out the Dihybrid cross HW worksheet Answer the question on the next slide…

Today’s Objectives: Use Punnett Squares to solve dihybrid crosses Use Mendel’s Principle of Independent Assortment to

explain how genetic variation is created in individuals.

From Q1: What are the four possible gametes for Suzy?

1. RrYy, RRYY2. RY, RY, rY, rY3. Rr, RR, YY, Yy4. RY, Ry, rY, ry

Today in Class: Finish Dihybrid work Make corrections to Dihybrid Cross Activity Collect class data for Part B Setting up our Dihybrid cross for Part C of the

corn lab/ finishing Part C Begin Mendelian Genetics Review Activity

“Counting Corn”: Genetic Crosses in Organisms

Objectives for Class:• Use Punnett Squares to solve dihybrid crosses• Use Mendel’s Principle of Independent Assortment to explain how genetic variation is

created in individuals.

example: dihybrid cross

Example: Dihybrid Cross(only write what’s in purple)

Unattached earlobe (E) is dominant over attached (e)

Black hair (B) is dominant over blond hair (b) What are the potential phenotypic

combinations?

Two parents are heterozygous for both traits:(1) Write the parent genotypes:

(2) What gametes can they make?

Example: Dihybrid Cross continued(3) Write the gametes along the sides of a

BIG Punnett Square (4 boxes x 4 boxes = 16 boxes)

(4) Use the Punnett Square to calculate probabilities!

What is the probability of having a baby with attached earlobes and black hair?

1 2 3 4

0% 0%

80%

20%

1. 1/162. 8/163. 3/164. 12/16

Remainder of Class: Make corrections to Dihybrid Cross Activity Collect class data for Part B Setting up our Dihybrid cross for Part C of the

corn lab/ finishing Part C Begin Mendelian Genetics Review Activity

“Counting Corn”: Genetic Crosses in Organisms

Objectives for Class:• Use Punnett Squares to solve dihybrid crosses• Use Mendel’s Principle of Independent Assortment to explain how genetic variation is

created in individuals.

Q3 from Dihybrid Activity: What is the probability that Charlie and Jennifer’s child will have a flat chin and bent pinkies?

1 2 3 4

19%

0%6%

75%1. 50%2. 25%3. 75%4. 0%

“Counting Corn”: Genetic Crosses in Organisms

Objectives for Class:• Use Punnett Squares to solve dihybrid crosses• Use Mendel’s Principle of Independent Assortment to explain how genetic variation is

created in individuals.

Remainder of Class: Collect and Review Class Data Setting up our Dihybrid cross for Part C of the

corn lab Begin Mendelian Genetics Review Activity

Table 1: Part B Class DataGroup % Yellow Corn % Purple Corn

1

2

3

4

5

6

7

8

9

10

11

12

“Counting Corn”: Genetic Crosses in Organisms

Objectives for Class:• Use Punnett Squares to solve dihybrid crosses• Use Mendel’s Principle of Independent Assortment to explain how genetic variation is

created in individuals.

Remainder of Class: Setting up our Dihybrid cross for Part C of the

corn lab Begin Mendelian Genetics Review Activity

Bio 9B: Monday, 4.5.10Title: Big Quiz Review Day – Genetics and Inheritance

Homework: Study for the BIG Quiz on Friday

Do Now: On the next slide…

Today’s Objectives: Review Genetics Content for Friday’s BIG QUIZ

(small test)

Do Now: Data Analysis Practice

Take out a calculator. Calculate the % of offspring with long wings. Show your work! Calculate the % of offspring with vestigial wings. Show your

work! Do you think vestigial wings are dominant, recessive, or co-

dominant? Why? What are the genotypes of the two long-winged fruit flies that were

crossed (mated) in this example?

Do Now: Analyzing Genetic Data % of Long Wings =

73 divided by 95 = 0.768 = 77% Long Wings

% of Vestigial Wings =

22 divided by 95 = 0.2316 = 23% Vestigial Wings

Vestigial Wings are…

Recessive because two parents with long wings had some babies with vestigial wings. This means the parents carried a copy of the vestigial allele but didn’t show it.

The two long-winged fruit fly parents are…Heterozygous (Aa x Aa)

What percent of the wings would you expect to be long?

1 2 3 4

0%

12%

84%

4%

1. 25%2. 50%3. 75%4. 100%

Why are the actual percents a bit different?

Have you completed the Mendelian Genetics Review Packet?

1 2

64%

36%

1. Yes2. No

Do you feel like you confidently answered the “challenge” questions in Part III of the Review Packet?

1 2 3

38%

15%

46%1. Yes2. Somewhat3. No

Big Quiz Review: Mendelian Genetics

Continue with the Mendelian Genetics Review Packet.

If you feel like you have confidently answered all of the questions, then complete an “extension” packet

Bio 9B: Tuesday, 4.6.10Title: Big Quiz Review Day – Genetics and Inheritance

Homework: Study for the BIG Quiz on Friday

Do Now: Go through the review guide and rank the topics on a

scale of 1-3 (1=IDK, 2=sort of know it, 3=definitely know this stuff).

When done, create a list of review topic questions in your notebook, starting with the topics that get 1s.

Note: we will NOT review in class on Thursday, but office hours will be Thursday evening.

Today’s Objectives: Review Genetics Content for Friday’s BIG QUIZ (small test)