For these experiment assume allele A = red, allele a = white . There are three flower colors(phenotypes and genotypes) for this species where AA=red, Aa = pink, aa = white.• A population of Four O-Clocks is in Hardy-Weinberg equilibrium and no evolutionary forces areacting on the population. Bees are introduced into the population. Individual bees only visit asingle color of flower so that red flowers only mate with red flowers, pink with pink, and whitewith white.Assume you start out with a population where the frequency of the A allele is 0.2 and the populationis initially in Hardy Weinberg equilibrium. What would the frequency of the Aa genotype be in thethe next generation where positive assortative mating is 100% (i.e. there is no random mating)?

In this question, we have to find out the frequency of Aa genotype be in the next generation where…

Assume you start out with a population where the frequency of the A allele is 0.2 and the population is initially in Hardy Weinberg equilibrium. What would the frequency of the Aa genotype be in the the next generation where positive assortative mating is 100% (i.e. there is no random mating)?

Assume you start out with a population where the frequency of the A allele is 0.2 and the population is initially in Hardy Weinberg equilibrium. What would the frequency of the Aa genotype be in the the next generation where positive assortative mating is 100% (i.e. there is no random mating)?

Biology (MindTap Course List)

11th Edition

ISBN:9781337392938

Author:Eldra Solomon, Charles Martin, Diana W. Martin, Linda R. Berg

Publisher:Eldra Solomon, Charles Martin, Diana W. Martin, Linda R. Berg

Chapter53: Introduction To Ecology: Population Ecology

Section: Chapter Questions

Problem 15TYU

See similar textbooks

Related questions

Q: Full color (D) in domestic cats is dominant over dilute color (d). Of 325cats observed, 194 have…

A: According to Hardy-Weinberg Principle, gene frequencies will remain constant if all the five…

Q: It is a common but mistaken belief that because some allele are dominant and others are recessive,…

A: Hardy Weinberg Equilibrium was discovered in 1908 by G.H. Hardy (British mathematician) and W.…

Q: In a population with two alleles at the C locus (C and c), the frequency of the genotype cc is 0.14.…

A: Introduction In the absence of disrupting events, the Hardy-Weinberg equilibrium states that…

Q: In a population with two alleles at the R locus (R and r), the frequency of the genotype rr is 0.23.…

A: Given, Genotypic frequency of rr(recessive)= 0.23 As the R locus is in Hardy-Weinberg equilibrium,…

Q: Consider the Hardy-Weinberg equations. If the frequency of a recessive allele is 0.3, what is the…

A: Hardy–Weinberg principle states that the total allele and genotypic frequency in a population will…

Q: . List the five conditions necessary for the allele frequencies of a population to be in…

A: Hardy-Weinberg equilibrium principle states that a population genotype frequencies will remain…

Q: In a Hardy-Weinberg situation, suppose that 253 out 400 individuals in a population express a…

A: * Hardy Weinberg equilibrium states that the allele frequency and genotype frequencies in a…

Q: Under Hardy-Weinberg equilibrium, if a population exists that contains 2 alleles only, each has a…

A: If a population exists that contains 2 alleles only, each has a respective frequency: p=0.3 and…

Q: In a population with two alleles at the R locus (R and r), the frequency of the genotype rr is 0.31.…

A: Hardy Weinberg principle says that allelic frequency or genetotypic frequency in a population will…

Q: In a population of 527 individuals, a locus has two alleles: T and t. If 148 individuals have the tt…

A: Hardy Weinberg equilibrium- explains that frequency of allels and genotypes remains constant from…

Q: You are given the frequencies of all three genotypes (AA, Aa, aa) in a population, and all three are…

A: The Hardy-Weinberg model, named when the 2 scientists that derived it within the early a part of…

Q: If a population has only two alleles for a gene (B, b) with equal frequencies and it is in…

A: The Hardy-Weinberg Principle or the Hardy-Weinberg Equilibrium Model states that “allele and…

Q: In plants, violet flower color (V) is dominant over white (v). If p = 0.8 and q = 0.2 in a…

A: As per the Hardy-Weinberg equilibrium, p2 + 2pq + q2 = 1 p2 = frequency of the VV genotype2pq =…

Q: A population of dragons is as follows: 46 are green with genotype GG 106 are green with genotype Gg…

Q: Consider a population in which the D locus has two alleles, D and d, with f(D) = 0.6 and f(d) = 0.4.…

A: In the Hardy-Weinberg equilibrium, the allele frequency and the genotype frequency of the…

Q: Consider the following, hypothetical data for the genotypic frequen- cies associated with the A, B,…

A: ANSWER: Applying the Hardy-Weinberg law: Derivation of the Hardy-Weinberg Law- The law states that…

Q: Geneticists claim that if gene and genotype frequencies are not already in HW equilibrium, then one…

A: The HW equilibrium or the Hardy-Weinberg equilibrium is a law that states, the genetic variation in…

Q: There are two alleles (AT and A2) at a single locus of a population. The population is in…

A: According to the Hardy-Weinberg law, the value of allele frequencies and genotype frequencies will…

Q: At least one of the discoverers of this genetic equilibrium (Hardy) developed this HW equation to…

A: Any one of two or more genes that can exist alternately at a specific place (locus) on a chromosome…

Q: In a Hardy-Weinberg population with two alleles, that are in equilibrium, the frequency of recessive…

A: When a population is in Hardy-Weinberg equilibrium for a gene, it is not evolving, and allele…

Q: When we find a population whose allele frequencies are not in Hardy–Weinberg equilibrium, what can…

A: As per Hardy Weinberg equilibrium, the frequencies of alleles and genotypes in a population is…

Q: Short eyelashes are dominant to extra-long eye lashes. In a large, randomly mating population with…

A: The total population of the individual with the two traits is 10000, out of which 1600 people have…

Q: Applying Hardy-Weinberg equilibrium. In a population of 100 individuals, 49% are YY. What percentage…

A: Introduction: The Hardy-Weinberg equilibrium is a principle stating that in the absence of…

Q: Hardy-Weinberg principle

A: Definition: Hardy-Weinberg law of genetic equilibrium is that both gene frequencies and genotype…

Q: Color in a species of minnows is determined by a single locus with two alleles: D and d. DD…

A: Hardy Weinberg principal shows that frequency of allels and genotypes remains constant from…

Q: population, and both are non-zero. Under what conditions can you determine genotype frequencies?

A: An allele frequency is calculated by dividing range|the amount|the quantity} of times the allele of…

Q: Suppose a population has two alleles at a particular locus, and individuals with different diploid…

A: Fitness refers to how well an organism passes its own genes to the next generation. It refers to…

Q: In a population of cats, the phenotypic frequency of black cats is 91%, and the phenotypic frequency…

A: Introduction : The Hardy-Weinberg equilibrium states that in the absence of disturbing factors, the…

Q: IN a Hardy-Weinberg equilibrium, as the frequencies of homozygous genotypes increase, the frequency…

A: According to the Hardy-Weinberg equilibrium, the frequencies of the alleles and genotypes in a…

Q: You are given the frequencies of all three genotypes (AA, Aa, aa) in a population, and all three are…

A: Hardy Weinberg equilibrium is a imaginary which considers if there is no evolution then the…

Q: Color in a species of minnows is determined by a single locus with two alleles: D and d. DD…

A: There are few points about the Hardy Weinberg law: We know that population genetics is the study of…

Q: You are studying the genetics of an enzyme found in fish. In the population in one lake, the value…

A: The Hardy-Weinberg Equilibrium is a key principle in population genetics, stating that “genotype…

Q: If the frequency of a dominant allele “B” in a population is 80%, and assuming genetic equilibrium…

A: Hardy-Weinberg Equilibrium is a concept that serves as a benchmark for researchers to analyze gene…

Q: In a population of 441 individuals, a locus has two alleles: T and t. If 53 individuals have the tt…

A: Given population count (no. of individuals) = 441 The two alleles are T (dominant) and t…

Q: In a population with two alleles at the C locus (C and c), the frequency of the genotype cc is 0.17.…

A: Hardy Weinberg Equilibrium states the genetic equilibrium of the population.

Q: In peas, purple flowers (P) is dominant over white flowers (p). In a population of 200 plants, 102…

A: Introduction In the absence of other evolutionary factors, the Hardy–Weinberg principle, also known…

Q: Grey eyes (b) are recessive to brown eyes (B) in rabbits. In an ideal rabbit population exhibiting…

A: The Hardy-Weinberg equilibrium is a principle that defines the genetic disparity in a population,…

Q: If gene A/a is not in Hardy-Weinberg equilibrium due to natural selection such that individuals with…

A: The relative fitness is the reproduction or survival rate of a particular genotype with respect to…

Q: If the Hardy-Weinberg equation enables us to use information on genotype and allele frequencies to…

A: Hardy -Weinberg Principle: In 1908, G.H. Hardy and W.Weinberg described a mathematical relationship…

Q: In a population of 344 individuals, a locus has two alleles: T and t. If 125 individuals have the tt…

A: Given population count (no. of individuals) = 344 The two alleles are T (dominant) and t…

Q: Imagine that in squirrels, the gene for brown coat is coded by two alleles, D for dark brown and d…

A: According to Hardy weinberg equation p2 + 2pq + q2 = 1 and p + q = 1 p = frequency of the dominant…

Q: Consider a finite population in which individuals carry two alleles at a particular genetic locus.…

A: In population genetics, a gene or allele will be fixed or lost is dependent on the selection…

Q: In a population with two alleles at the R locus (R and r), the frequency of the genotype rr is 0.24.…

A: Introduction In population genetics, the Hardy–Weinberg principle, also known as the Hardy–Weinberg…

Q: > Within a certain population, there are exactly 2 alleles at the T locus: T and t. Among the entire…

A: Since you have asked multiple questions, according to our policy, we can only answer one question at…

Q: In a population of 265 individuals, a locus has two alleles: E and e. If 59 individuals have the ee…

A: According to the Hardy-Weinberg law, the allelic frequencies in a non-evolving population are stable…

Q: In a population that is in HW equilibrium, 96% of the individuals have the dominant phenotype (A-),…

A: The explanation is given below.

Q: Below is a plot of genotype frequencies in a population. Assuming the population is in…

A: Allele Frequency is defined as the number of times that allele is in a population. It is calculated…

Q: In a population of 501 individuals, a locus has two alleles: T and t. If 177 individuals have the tt…

A: The Hardy–Weinberg principle, also known as the Hardy–Weinberg equilibrium, model, theorem, or law…

Q: Considering the Hardy-Weinberg theorem’s assumptions, which of the following statements is NOT…

A: Evolution is a process in which certain changes in the characteristics of a population occurs. These…

Q: In a population with two alleles at the R locus (R and r), the frequency of the genotype rr is 0.10.…

A: Hardy Weinberg's principle describes the allele equilibrium in a population. The allele frequencies…

Concept explainers

Gene Flow

Gene flow, also known as gene migration, is the introduction of genetic material from a particular population to another population of the same species through interbreeding. For example, a bee facilitates its reproductive process by carrying pollen from one flower to another. The flow alters the composition of the gene pool of the receiving population. It introduces new alleles within the population and helps increase variability. This exchange of genetic material occurs through reproduction and brings about new combinations of traits into the population. Where human beings are concerned, actual migration of populations, whether voluntary or forced, brings about gene flow.

Population Biology

Population biology is the study of patterns in organism populations, specifically the growth and management of population size, population genetics, the evolution of life history, species interactions, and demography.

Speciation

The process of speciation involves the formation of new species during evolution. The new species evolve in such a way that both new and old species are not able to interbreed. Thus, speciation occurs when few members of one species get separated from the main species due to geographical, mechanical, or reproductive isolation. These separated members develop new traits that make them different from the main species. In other words, speciation could be defined as the absence of gene flow between two populations that become new species.

Allele Fixation

A gene is a unit of heredity and contains both physical and functional information that shapes an individual. Genes are made up of DNA (deoxyribonucleic acid), which carry genetic information from one generation to another, from one set of parents to their offspring, and so on. Every cell in a human body, or any living organism, has the same DNA, which implies that every cell in an individual’s body has all the information it needs to build and sustain the body!

Question

For these experiment assume allele A = red, allele a = white . There are three flower colors
(phenotypes and genotypes) for this species where AA=red, Aa = pink, aa = white.
• A population of Four O-Clocks is in Hardy-Weinberg equilibrium and no evolutionary forces are
acting on the population. Bees are introduced into the population. Individual bees only visit a
single color of flower so that red flowers only mate with red flowers, pink with pink, and white
with white.
Assume you start out with a population where the frequency of the A allele is 0.2 and the population
is initially in Hardy Weinberg equilibrium. What would the frequency of the Aa genotype be in the
the next generation where positive assortative mating is 100% (i.e. there is no random mating)?

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

SEE SOLUTION Check out a sample Q&A here

Step 1

VIEW

Step 2

VIEW

Step by step

Solved in 2 steps

SEE SOLUTION Check out a sample Q&A here

Knowledge Booster

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, biology and related others by exploring similar questions and additional content below.

Similar questions

A population of birds has two alleles encoding for three different phenotypes: long wings, wingsss, and mid-length wings. . The initial frequency of the Sallele was 0.63 and the sallele was 0.37. However 97% of the long-winged birds survived to reproductive age56% of mid-length birds survived to reproductive age, and only 10% of short-winged birds survived to reproductive age. You are going to determine if natural selection has an effect on the allele frequency What is the expected frequency of the Sallele in the next generation when you incorporate the survival rate? Please use as many decimals points as possible when doing your calculations. Please answer using four decimal points. (Your population can be 100 or 1000 individuals or any numberreally up to you.I work with 1000but that won't change the results because we are talking about frequency.)
Imagine you were trying to test whether a population of flowers is undergoing evolution. In a field, you can't 600 blue flowers and 200 red flowers, and you know from previous research that blue flower color is dominant to red flower color. What would you expect the allele frequency's of this flower population to be?
A population with allele frequencies p=0.6 and q=0.4 is subjected to selection against the dominant allele. If selection is completely effective (W11=0, W12=0, W22=1), what will be the frequency of the dominant allele in the next generation?
Considering the Hardy-Weinberg theorem’s assumptions, which of the following statements is NOT correct? (Recall that there are certain assumptions that must be true in order for the Hardy-Weinberg theorem to accurately predict genotype ratios in the next generation.)a) The population must be very large so there random genetic drift will not occur.b) No natural selection can occur.c) Mating must be random.d) Individuals must migrate into and out of the population so that gene flow will occur.e) Mutations must not occur.
Imagine you are studying a population of finches on one of the Galápagos Islands. You have been recording many of the birds’ physical traits, including the length of both wings. You observe that for 80% of individuals measured, the length of the left wing is not significantly different from the length of the right wing (in other words, they are symmetrical). But for about 20% of birds measured, the wing lengths are asymmetrical. This distribution is true from generation to generation. Suddenly, a rare 5-day windstorm takes over the island. After the storm, you spend the next several days netting each bird on the island that survived the storm. You discover that 85% of the birds with symmetrical wings survived the storm, whereas only 5% of the birds with asymmetrical wings did. a. Propose a hypothesis to explain this observation. b. If such storms become increasingly common due to changes in climate, how might you expect the population to change over time with respect to wing symmetry?
The allele frequencies of the parents in our simulation were p = 0.75 and q = 0.25. The heterozygote has a selective advantage and therefore a fitness of W12 = 1. Assume the homozygotes have a fitness of W11 = 0.4 and W22 = 0.1, respectively. Calculate the allele frequencies after two rounds of selection and show your work.
The relative fitnesses of A1A1, A1A2, and A2A2 are 0.5,0.8 and 1 respectively. What is the expected result of natural selection in this selection? a.) A1 will increase and A2 will decrease. b.) A2 will increase and A1 will decrease. c. Both alleles will decrease in frequency d.) A stable equilibrium will be achieved in which both alleles are maintained e.) An unstable equilibrium will exist and the outcome depends on the allele frequencies.
Suppose that, in one generation, the frequency of the A allele is 40 percent (p=0.40) and the frequency of a allele is 60 percent (q=0.60). If this population is in genetic equilibrium, (1) chances of an individual in the next generation having genotype AA would be ___?(2) The probabilities of genotype aa would be ___? (3) The probability of genotype Aa would be ___? Direction: Provide an answer in 1, 2 and 3 question.
Present the name of the population undergoing natural selection and its selection pressure (e.g., what is causing the change in the population's alleles); the nature of the change and its implications of that change for the population.
You observe a population of Japanese 4’oclock plants. These plants can display red, pink or white flowers. Plants with red flowers are homozygous dominant (RR); plants with white flowers are homozygous recessive (rr) and plants with pink flowers are heterozygous (Rr). Based on the following data: 35 plants with red flowers; 25 plants with white flowers; 40 plants with pink flowers. Show all work A) Calculate genotype frequencies of RR; Rr and rr in the population. B) Calculate the allele frequencies of R and r in the population.
Johnston et al. estimate that 50% of males with the Ho Ho genotype develop scurs (instead of full horns). They also estimate that around 13% of the total male population, at birth, will develop scurs. The males who managed to get access to mating opportunities with females seem to show no preference for whether the females have horns or not. Thus in the adult mating population, mating is random with respect to the genotype at this locus. What is the frequency of the Hop allele in the population?
In a population experiencing no selection, genetic drift, gene flow, mutation or non random mating, the allele frequencies at a locus where the R allele is dominant over the r allele, are as follows. R= 0.3 r=0.7 What is the expected heterozygosity of the population at that locus?