Why is genetic drift a more powerful force in small populations? The inheritance of genes in sexual reproduction has a major chance component. During meiosis homologous chromosomes separate and migrate to different poles. The haploid daughter cells each have one allele for each gene, but which allele they have is random. Essentially meiosis is like flipping thousands of coins and getting either a head (one allele) or a tail (the other allele) for each one. At a single locus each parent passes on either a head or a tail with a 50% probability of each. Over an entire population each allele should be passed on proportionately to its frequency. In other words if 10% of the alleles in a population are A then allele A should show up in 10% of the gametes.However, results do not always follow probability, especially with small sample sizes. The results of one coin flip are independent of the results of the next coin flip. If a coin is flipped 2 times it is not unlikely that the results will be 2 heads or 2 tails. If a coin is flipped 10 times it is very unlikely that the result will be 10 heads or 10 tails. And if the coin is flipped 100 times it is so unlikely that all the flips will be tails (or heads) that for practical purposes it can be regarded as impossible. Similarly in a small population, random chance can significant change the frequency of alleles in a short time. In a large population, genetic drift has only very small effects in any given generation. View the animation below, then complete the quiz to test your knowledge of the concept.Genetic driftMultiple Choicereduces genetic variation in a population.increases genetic variation in a population.has no effect on the genetic variation in a population.causes extinction in a population.makes a population more genetically similar to other populations.
Question
Why is genetic drift a more powerful force in small populations? The inheritance of genes in sexual reproduction has a major chance component. During meiosis homologous chromosomes separate and migrate to different poles. The haploid daughter cells each have one allele for each gene, but which allele they have is random. Essentially meiosis is like flipping thousands of coins and getting either a head (one allele) or a tail (the other allele) for each one. At a single locus each parent passes on either a head or a tail with a 50% probability of each. Over an entire population each allele should be passed on proportionately to its frequency. In other words if 10% of the alleles in a population are A then allele A should show up in 10% of the gametes.However, results do not always follow probability, especially with small sample sizes. The results of one coin flip are independent of the results of the next coin flip. If a coin is flipped 2 times it is not unlikely that the results will be 2 heads or 2 tails. If a coin is flipped 10 times it is very unlikely that the result will be 10 heads or 10 tails. And if the coin is flipped 100 times it is so unlikely that all the flips will be tails (or heads) that for practical purposes it can be regarded as impossible. Similarly in a small population, random chance can significant change the frequency of alleles in a short time. In a large population, genetic drift has only very small effects in any given generation. View the animation below, then complete the quiz to test your knowledge of the concept.Genetic driftMultiple Choicereduces genetic variation in a population.increases genetic variation in a population.has no effect on the genetic variation in a population.causes extinction in a population.makes a population more genetically similar to other populations.
Solution
Genetic drift reduces genetic variation in a population. This is because it is a random process that can lead to the loss of certain gene variants (alleles) in small populations. When there are fewer individuals, there is a higher chance that some alleles will not be passed on to the next generation simply by chance. Over time, this can lead to a reduction in genetic diversity, making the population less adaptable to changes in the environment. In contrast, in larger populations, the effects of genetic drift are less pronounced because the larger number of individuals ensures a greater likelihood that a wide variety of alleles will be passed on to the next generation.
Similar Questions
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One cause of genetic drift is _____, in which a small group of individuals leaves its home population and establishes a new, isolated settlement.Multiple choice question.Hardy-Weinberg equilibriumthe founder effectneutral variationheterozygote advantage
Genetic drift is a change in allele frequencies that occurs by ______ and, unlike mutations, it tends to eliminate alleles from the population.Multiple choice question.chancedirectional selectionnatural selectionrandom mating
In a hypothetical population of endangered turtles, a few individuals find themselves abandoned on an island. Due to the scarce resources and little genetic contact with populations of mainland turtles, their population size has remained modest over numerous generations. As a result, the island population develops distinct genetic traits. Which of the following sums up the idea of genetic drift in this population of isolated turtles the best? Genetic drift is responsible for the island population's increased genetic diversity, promoting adaptation to the unique island environment Genetic drift is the mechanism behind the emergence of unique genetic characteristics in the island population, due to random fluctuations in allele frequencies Genetic drift occurs when the island population actively selects traits that enhance their survival, leading to genetic divergence Genetic drift and natural selection are synonymous in this scenario, as they both contribute to the island population's unique genetic features
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