Evolution: Hardy-Weinberg equilibrium

Evolution

Chapter 12&13

Lesson 4: Hardy-Weinberg equilibrium

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Slide 1: Slide

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This lesson contains 35 slides, with interactive quizzes, text slides and 4 videos.

Lesson duration is: 45 min

Items in this lesson

Evolution

Chapter 12&13

Lesson 4: Hardy-Weinberg equilibrium

Slide 1 - Slide

Learning objectives

You can distinguish between allele frequency, genotype frequency, gene, allele and gene pool
You can explain the requirements necessary for a population to meet the Hardy-Weinberg equilibrium
You can use the Hardy-Weinberg equations to perform calculations on population genetics

Slide 2 - Slide

Gene

Allele

Phenotype

Genotype

Gene pool

Version of a gene

All copies of a gene in a population

Section of DNA that controls a particular trait

Set of alleles

Observable features

Slide 3 - Drag question

1: two W alleles

2: one W allele and one w allele

3: two w alleles

Slide 4 - Slide

Total number of alleles?
Number of W?
Number of w?

Slide 5 - Open question

Total: 18

W: 13

w: 5

Allele frequency

timer

3:00

Calculate allele frequency of W and the allele frequency of w

Slide 6 - Slide

Total: 18

W: 13

w: 5

Allele frequency

Allele frequency of W:13/18=0,72

Allele frequency of w: 5/18=0,28

Total=1,00

Make sense?

Slide 7 - Slide

Allele frequency formula

We assign p to the dominant allele

We assign q to the recessive allele

Result:

p + q = 1

Slide 8 - Slide

What is represented by the letter q?

the gene pool

the dominant allele

the recessive allele

the genotype

Slide 9 - Quiz

If p= 0,7, q is?

0,3

1,0

0,2

0,7

Slide 10 - Quiz

If the frequency of the dominant allele is 0,6, the frequency of p is?

1,0

0,4

0,5

0,6

Slide 11 - Quiz

Genotype frequency

Frequency WW?
Frequency Ww?
Frequency ww?

timer

2:00

Slide 12 - Slide

Genotype frequency

Usually more interesting

Frequency WW?:
6/9=0,67
Frequency Ww?
1/9=0,11
Frequency ww?
2/9=0,22

Slide 13 - Slide

Calculate chance of genotype WW

= W

= w

Frequency W in population
Frequency = chance to 'pull'
Chance to pull WW = chance to pull W x chance to pull W

timer

2:00

Slide 14 - Slide

Calculate chance of genotype WW

= W

= w

Frequency W in population
Frequency = chance to 'pull'
Chance to pull WW = chance to pull W x chance to pull W

Frequency W = 0,7

Chance WW = 0,7 x 0,7 =0,49

Slide 15 - Slide

A population of 150 individuals has an allele frequency of 0,6 for the dominant allele (B) and a frequency of 0,4 for the recessive allele (b). Use the Hardy-Weinberg equation to determine the frequency of the genotype (bb).

0,36

0,4

0,16

0,24

Slide 16 - Quiz

Turning it into p and q

If WW is W x W, how do you write it using p?

If ww is w x w, how do you write it using q?

Slide 17 - Slide

Turning it into p and q

If WW is W x W, how do you write it using p?

If ww is w x w, how do you write it using q?

p x p = p2

q x q = q2

Slide 18 - Slide

How would you calculate the chance of a heterozygote?

Slide 19 - Mind map

Turning it into p and q

How would you calculate the chance of a heterozygote?

Slide 20 - Slide

Calculating genotype frequencies

Homozygous dominant: p x p = p2

Heterozygous: p x q + q x p = 2pq

Homozygous recessive: q x q = q2

In total:

p2 + 2pq + q2 = 1

Total is 1 because together they make up all genotypes

Slide 21 - Slide

q2 is the frequency of:

the recessive allele

the dominant allele

the recessive genotype

the dominant genotype

Slide 22 - Quiz

p=0,2. What is the frequency of the recessive phenotype?

0,04

0,4

0,32

0,64

Slide 23 - Quiz

Give the frequencies

Slide 24 - Open question

Slide 25 - Slide

Hardy-Weinberg equilibrium

p+q=1 and p2+2pq+q2=1 are formulas that belong to the Hardy-Weinberg equilibrium.

They are used to track allele frequencies and see if they chance/ make predictions about and how they will change.

Slide 26 - Slide

If a population is in a Hardy-Weinberg equilibrium this means the allele frequencies are not changing. Therefore, there is no evolution!

Equilibrium only exists if these five requirements are met

Remember the five fingers of evolution?

Slide 27 - Slide

What if requirements are not met?

Evolution!

Slide 28 - Slide

A population's recessive allele frequency is 25%. What is the percentage of the Homozygous Dominant genotype?

Slide 29 - Open question

64% of the population has the recessive phenotype. What is the percentage of the heterozygous genotype?

Slide 30 - Open question

Homework

Worksheet Hardy-Weinberg on Classroom

Slide 31 - Slide

Slide 32 - Video

Slide 33 - Video

Slide 34 - Video

Slide 35 - Video

Evolution: Hardy-Weinberg equilibrium

Items in this lesson

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Slide 3 - Drag question

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Slide 5 - Open question

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Slide 9 - Quiz

Slide 10 - Quiz

Slide 11 - Quiz

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Slide 16 - Quiz

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Slide 19 - Mind map

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Slide 22 - Quiz

Slide 23 - Quiz

Slide 24 - Open question

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Slide 29 - Open question

Slide 30 - Open question

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Slide 32 - Video

Slide 33 - Video

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Slide 35 - Video

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