Reference no: EM13916679

Materials: Bag of 15 bean soup (dry beans), cup, 2 Paper lunch bags, paper and pencil.

1. We shall simulate genetic drift and effects of a bottleneck on genetic drift in this simulation.

Review "Evolution Occurs in Several Ways".

Instructions:

Count out 25 speckled beans, 25 black beans, 25 white beans and 25 red beans (it is easiest if you choose beans of the same size and put in container. The beans represent different alleles. This means each type of bean makes up 25% of the total number of beans (or alleles) (25/100 = 0.25).

Write two hypotheses answering the two questions below:

a. How would the ratio of bean phenotypes change if you randomly pick 40 beans from the container? Will the ratio change significantly in each repetition (generation)?

b. How would the ratio of bean phenotypes change if you only pick 10 beans from the container? Will the ratio change significantly in each repetition (generation)?

Method:

Now take 40 beans from the counter and count the different phenotypes black, white, red and speckled. Write the results in the data chart, then return the beans to the container, shake to mix, and repeat the experiment two more times. Next, take only 10 beans from the container. Count the different beans and add the data to the chart. Return the beans to the container and repeat three more times. Complete the data chart below.

Were your hypotheses correct?

Answer the following questions:

I. What was the range of ratios of bean phenotypes in the large sample? In the small sample?

II. How would genetic drift affect the gene pool in a genetic bottleneck?

III. Could genetic drift lead to evolution of new species? Consider ratios of phenotypes of each small sample. Under which condition would this change lead to speciation?

2. Simulation of Hardy Weinberg Equilibrium

Review "Evolution is Inevitable in Real Populations ", Chapter 11. 3 in your textbook.

Also, web site: https://www.nfstc.org/pdi/Subject07/pdi_s07_m01_02.htm (click the glasses for more help)

We shall simulate the frequency of two alleles in a population in Hardy Weinberg Equilibrium over several generations.

Instructions:

This time the beans will represent alleles (remember we carry two alleles for each trait or gene, one from the father and one from the mother)

The red bean represents a dominant allele and the white bean represents a recessive allele. The homozygous dominant individual is represented by 2 red beans, the homozygous recessive individual is represented by 2 white beans, and heterozygous individuals are represented by one red bean and one white bean.

Method

Count and set aside 60 red beans and 40 white beans. Label one paper bag male and the other paper bag female. Divide beans evenly into bags (30 red beans and 20 white beans into each bag). You will grab one bean from each bag for the allele combination in the F1 generation, for a total of 50 pairs (50 individuals) in the F1 generation.

Preparation:

Calculate the frequency of p (dominant allele - red) and q (recessive allele - white) in population.

p=red beans/total # beans

q=white beans/total # beans

p+q = ?
2pq = ?
P2  = ?
q² = ?

What does p², q² and 2pq represent?

Write a hypothesis answering the following question:

a. If the population is in Hardy Weinberg equilibrium, what would be the frequency of both alleles in the F1, F2 and F3 generations?

Experiment 1

Remove one bean from each bag blindly and set the pair aside. Repeat until all beans are paired. This represents one generation.

1.1 Count:

Red pairs (dominant homozygous ) = p²
White pairs (recessive homozygous) = q²
Red-white pairs (heterozygous) = 2pq.

P² + 2pq + q² = 1

Calculate p = (2x red pairs + red-white pairs)/ total number of alleles (beans) = ?

q = (2x white pairs + red-white pairs)/total number of alleles (beans) = ?

p+q= ?

Return beans to bags and repeat the pairing two times, recording p², 2pq and q² each time.

1.2 Count:

Red pairs (dominant homozygous ) = p²
White pairs (recessive homozygous) = q²
Red-white pairs (heterozygous) = 2pq.
P² + 2pq + q² = 1

Calculate p = (2x red pairs + red-white pairs)/ total number of alleles (beans) = ?
q = (2x white pairs + red-white pairs)/total number of alleles (beans) = ?
p+q= ?

1.3 Count:
Red pairs (dominant homozygous ) = p²
White pairs (recessive homozygous) = q²
Red-white pairs (heterozygous) = 2pq.
P² + 2pq + q² = 1

Calculate p = (2x red pairs + red-white pairs)/ total number of alleles (beans) = ?
q = (2x white pairs + red-white pairs)/total number of alleles (beans) = ?
p+q= ?

Answer the following questions:

I. How much did your experimental data differ from the calculated data?
II. Do you accept or reject your hypothesis?

Experiment 2 :

Remove one bean from each bag blindly and set the pair aside. Repeat 10 times. This represents a loss of 10% of the population (migration).
Now repeat steps of experiment 1.

2.1 Count:

Red pairs (dominant homozygous ) = p²
White pairs (recessive homozygous) = q²
Red-white pairs (heterozygous) = 2pq.
P² + 2pq + q² = 1

Calculate p = (2x red pairs + red-white pairs)/ total number of alleles (beans) = ?
q = (2x white pairs + red-white pairs)/total number of alleles (beans) = ?
p+q= ?

Repeat three times, each time removing 10% of the pairs, so remove 9 and 8 pairs respectively. Keep the changing total number of beans in mind when calculating allele (bean) frequencies.

2.2 Count
Red pairs (dominant homozygous ) = p²
White pairs (recessive homozygous) = q²
Red-white pairs (heterozygous) = 2pq.
Calculate p = (2x red pairs + red-white pairs)/ total number of alleles (beans) = ?
q = (2x white pairs + red-white pairs)/total number of alleles (beans) =?
p+q= ?

2.3 Count
Red pairs (dominant homozygous ) = p²
White pairs (recessive homozygous) = q²
Red-white pairs (heterozygous) = 2pq.
Calculate, p and q. p + q = ?
Calculate p = (2x red pairs + red-white pairs)/ total number of alleles (beans) = ?
q = (2x white pairs + red-white pairs)/total number of alleles (beans) =?
p+q= ?

Answer the following questions:

I. How much did your experimental data differ from the calculated data?
II. Do you accept or reject your hypothesis?
III. Under what conditions is an allele within a population in Hardy Weinberg equilibrium?

Experiment 3

Remove one bean from each bag blindly and set the pair aside. Repeat until all beans are paired. Remove all white pairs (lost to predation) This represents natural selection.

3.1 Count

Red pairs (dominant homozygous ) = p²
White pairs (recessive homozygous) = q²
Red-white pairs (heterozygous) = 2pq.

Calculate p = (2x red pairs + red-white pairs)/ total number of alleles (beans) = ?
q = (2x white pairs + red-white pairs)/total number of alleles (beans) =?
p+q= ?

Write a hypothesis answering the following question:

What will happen to p and q if this selective pressure repeats in the next generation?

Work through another generation. Divide remaining beans equally and return to bags, and repeat the experiment.

3.2 Count

Red pairs (dominant homozygous ) = p²
White pairs (recessive homozygous) = q²
Red-white pairs (heterozygous) = 2pq.

Calculate p = (2x red pairs + red-white pairs)/ total number of alleles (beans) = ?
q = (2x white pairs + red-white pairs)/total number of alleles (beans) =?
p+q= ?

Answer the following questions:

I. How much did your experimental data differ from the calculated data?
II. Do you accept or reject your hypothesis?
III. How does natural selection affect allele frequencies?

Answer the following question in full sentences, at least 150 to 200 words.

What did you learn in this lab about the effects of population size, migration and natural selection on allele frequencies in populations? How do allele frequencies relate to evolution of species?