Question

In: Biology

THIS LAB CORRESPONDS TO LAB TOPIC 11: POPULATION GENETICS:  THE HARDY-WEINBERG EQUILIBRIUM. THE FOLLOWING NEEDS TO BE...

THIS LAB CORRESPONDS TO LAB TOPIC 11: POPULATION GENETICS:  THE HARDY-WEINBERG EQUILIBRIUM.

THE FOLLOWING NEEDS TO BE COMPLETED AND TURNED IN FOR LAB

  1. Define and provide examples of the following terms:
  1. Evolution:

  1. Population:

  1. Gene pool:

  1. Gene flow:

  1. Genetic drift:

  1. Bottleneck effect:

  1. Founder effect:

  1. Natural selection:

  1. Genetic fixation:

  1. Genotypic frequency:

  1. Allelic frequency:

  1. Model:

THIS LAB CORRESPONDS TO LAB TOPIC 11: POPULATION GENETICS:  THE HARDY-WEINBERG EQUILIBRIUM.

THE FOLLOWING NEEDS TO BE COMPLETED AND TURNED IN FOR LAB

  1. Define and provide examples of the following terms:
  1. Evolution:

  1. Population:

  1. Gene pool:

  1. Gene flow:

  1. Genetic drift:

  1. Bottleneck effect:

  1. Founder effect:

  1. Natural selection:

  1. Genetic fixation:

  1. Genotypic frequency:

  1. Allelic frequency:

  1. Model:

Solutions

Expert Solution


Related Solutions

For the following population determine if the population is in Hardy-Weinberg Equilibrium. Round to two decimal...
For the following population determine if the population is in Hardy-Weinberg Equilibrium. Round to two decimal places. AA: 15 Aa: 22 aa: 63 What are the genotype frequencies? What are the allele frequencies? What are expected/predicted genotype frequencies?
In a Hardy-Weinberg population with two alleles, A and a, that are in equilibrium, the frequency...
In a Hardy-Weinberg population with two alleles, A and a, that are in equilibrium, the frequency of allele A is 0.35. What is the percentage of the population that is homozygous for this allele?
Describe the assumptions of a population that is in Hardy-Weinberg Equilibrium, and the two principles of...
Describe the assumptions of a population that is in Hardy-Weinberg Equilibrium, and the two principles of this population at a single bi-allelic genomic locus.
For a population at Hardy-Weinberg equilibrium, what is the frequency of heterozygotes if p = 0.8?
For a population at Hardy-Weinberg equilibrium, what is the frequency of heterozygotes if p = 0.8?
Five conditions are required to maintain the Hardy–Weinberg equilibrium in a population. A. Closed population B....
Five conditions are required to maintain the Hardy–Weinberg equilibrium in a population. A. Closed population B. Large population C. Random mating D. No net mutations E. No natural selection If any of these conditions is not being met, the allele frequencies in the population will change, leading to microevolution in the population. Match each of the following scenarios to the Hardy–Weinberg condition that is not being met:                        An increase in antibiotic resistance among bacteria...
Consider a population of 1000 birds in Florida. Gene 1 is in Hardy-Weinberg equilibrium, and the...
Consider a population of 1000 birds in Florida. Gene 1 is in Hardy-Weinberg equilibrium, and the frequency of the N allele is 0.2. Also, there are 30 BB and 80 bb individuals. Answer the following: a. What is the frequency of the R allele? b. What are the frequencies of the RR, RN, and NN genotypes? c. How many individuals have the RN genotype? d. How many individuals have the Bb genotype? e. What are the frequencies of the B...
Is a small population or a large population more likely to satisfy Hardy-Weinberg Equilibrium? Why? Why...
Is a small population or a large population more likely to satisfy Hardy-Weinberg Equilibrium? Why? Why is genetic isolation critical to speciation? What is the difference between pre and post-zygotic isolation? What is reinforcement and under what conditions would you expect to find evidence for reinforcement?
(Show all work for credit) A population is in Hardy-Weinberg equilibrium with two alleles, B and...
(Show all work for credit) A population is in Hardy-Weinberg equilibrium with two alleles, B and B at a frequency 0.8 (B) and 0.2 (b). Allele B results in blue colored flowers and is dominant to the allele b which results in white flowers. I. Find the percentages for each genotype for the following generation II. Calculate the percentage of each phenotype III. Calculate the allele frequency in the new generation
Apply a rule and determine which of the following populations are in Hardy-Weinberg equilibrium. Show your...
Apply a rule and determine which of the following populations are in Hardy-Weinberg equilibrium. Show your work. Genotypes AA Aa. aa Population I .430 .481 .089 Population II .64 .32 .04 Population III .25 .50 .25 a. Is population I in equilibrium b. Is population II in equilibrium c. Is population III in equilibrium
Hardy-Weinberg Equilibrium Problems: A population of beetles have either long or short antennae, where short antennae...
Hardy-Weinberg Equilibrium Problems: A population of beetles have either long or short antennae, where short antennae are dominant over long antennae. There are 653 individuals in the population. 104 beetles have long antennae and 549 have short antennae. a. Determine the frequency of the dominant and recessive alleles and the frequency of individuals with dominant, heterozygous, and recessive genotypes. The next generation of beetles in this population has 560 individuals with short antennae and 840 individuals with long antennae. b....
ADVERTISEMENT
ADVERTISEMENT
ADVERTISEMENT