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Chapter 25: Problem 25

What genetic changes take place during speciation?

Short Answer

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Question: Explain the role of genetic changes, such as mutations, gene flow, genetic drift, and natural selection, in the process of speciation. Answer: In the process of speciation, genetic changes play a crucial role in the formation of distinct species. Mutations introduce genetic variations within a population, and if beneficial, can spread through natural selection. Gene flow, the movement of genes between populations, can either promote or hinder speciation by maintaining genetic similarities or allowing populations to evolve independently. Genetic drift, the random change in allele frequencies, can contribute to speciation by causing isolated populations to diverge due to chance events. Natural selection drives speciation by promoting adaptations to local environments, which may eventually lead to reproductive isolation and the formation of new species.

Step by step solution

01

Understand the concept of speciation

Speciation is the process by which populations evolve over time to become distinct species. This occurs because of the accumulation of genetic changes that affect the ability of individuals from different populations to interbreed and produce fertile offspring.
02

Identify the role of mutations in speciation

Mutations are random changes in the DNA sequence of an organism's genome. They act as a source of genetic variations within a population. When a new mutation arises, it may lead to differences in the organisms' phenotypic traits, such as color, size, or behavior. If the mutation is beneficial and increases the organism's fitness, it will be more likely to spread within the population over generations through natural selection. This may lead to the formation of distinct species over time.
03

Explain the effects of gene flow on speciation

Gene flow is the movement of genes between different populations of a species through migration and interbreeding. This can either promote or hinder speciation, depending on the circumstances. When gene flow occurs between diverging populations, it can slow down or even prevent speciation by mixing their gene pools and maintaining genetic similarities between them. On the other hand, if gene flow is restricted between populations, they may evolve independently and accumulate genetic differences, leading to speciation.
04

Discuss the impact of genetic drift on speciation

Genetic drift is the random change in allele frequencies within a population due to chance events, such as the random death of individuals or fluctuations in reproduction rates. In small populations, genetic drift may lead to the fixation of certain alleles, resulting in reduced genetic variation. This can contribute to speciation when populations become isolated and genetic drift causes them to diverge from each other over generations, accumulating differences that may eventually lead to reproductive isolation.
05

Understand the role of natural selection in speciation

Natural selection is the process by which organisms with traits that improve their survival and reproduction rates are more likely to pass their genes to the next generation, causing these advantageous traits to become more common over time. Natural selection can drive speciation by promoting the adaptation of populations to their local environments, leading to the evolution of different traits in separate populations. If these adaptations result in reproductive barriers that prevent interbreeding, new species may arise. In conclusion, during speciation, genetic changes such as mutations, gene flow, genetic drift, and natural selection can lead to the formation of distinct species by causing populations to accumulate genetic differences over time. These differences can eventually result in reproductive isolation, which is the key factor in defining species.

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Most popular questions from this chapter

Read the Chapter Concepts list on page \(681 .\) All these pertain to the principles of population genetics and the evolution of species. Write a short essay describing the roles of mutation, migration, and selection in bringing about speciation.

Recent reconstructions of evolutionary history are often dependent on assigning divergence in terms of changes in amino acid or nucleotide sequences. For example, a comparison of cytochrome c shows 10 amino acid differences between humans and dogs, 24 differences between humans and moths, and 38 differences between humans and yeast. Such data provide no information as to the absolute times of divergence for humans, dogs, moths, and yeast. How might one calibrate the molecular clock to an absolute time clock? What problems might one encounter in such a calibration?

A certain form of albinism in humans is recessive and autosomal. Assume that \(1 \%\) of the individuals in a given population are albino. Assuming that the population is in HardyWeinberg equilibrium, what percentage of the individuals in this population is expected to be heterozygous?

The ability to taste the compound PTC is controlled by a dominant allele \(T,\) while individuals homozygous for the recessive allele \(t\) are unable to taste PTC. In a genetics class of 125 students, 88 can taste \(\mathrm{PTC}\) and 37 cannot. Calculate the frequency of the \(T\) and \(t\) alleles and the frequency of the genotypes in this population.

In a population that meets the Hardy-Weinberg equilibrium assumptions, \(81 \%\) of the individuals are homozygous for a recessive allele. What percentage of the individuals would be expected to be heterozygous for this locus in the next generation?
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