5 Must Know Facts For Your Next Test

1. Allele frequencies are typically expressed as a proportion or percentage of the total alleles present in a population, with values ranging from 0 to 1 or 0% to 100%.
2. The Hardy-Weinberg principle provides a mathematical framework for predicting allele frequencies under ideal conditions, where no evolution occurs.
3. In a population with multiple alleles, the total frequency of all alleles for a given gene must equal 1.
4. Changes in allele frequencies over generations can provide evidence of evolutionary forces such as selection, drift, and migration.
5. Monitoring allele frequencies helps scientists track changes in populations due to environmental pressures, conservation efforts, and disease outbreaks.

Review Questions

• How does the Hardy-Weinberg equilibrium relate to allele frequency, and what conditions must be met for it to hold true?
  • The Hardy-Weinberg equilibrium provides a baseline expectation for allele frequencies in a population that is not evolving. For this equilibrium to hold true, five conditions must be met: no mutations, random mating, no natural selection, an infinitely large population size to prevent drift, and no gene flow. When these conditions are satisfied, allele frequencies will remain constant across generations, allowing researchers to identify deviations that may indicate evolutionary change.
• Discuss how multiple alleles influence allele frequency within a population and the potential implications for genetic diversity.
  • In populations with multiple alleles for a given gene, allele frequencies can vary significantly depending on factors such as mutation rates, selection pressures, and genetic drift. The presence of multiple alleles contributes to greater genetic diversity within the population, which can enhance adaptability and resilience against environmental changes. Monitoring these frequencies allows researchers to assess the overall health of populations and make informed conservation decisions.
• Evaluate the impact of gene flow on allele frequency and how it can alter the genetic landscape of both donor and recipient populations.
  • Gene flow can significantly impact allele frequency by introducing new alleles into a recipient population from a donor population. This influx of genetic material can increase genetic diversity and potentially enhance adaptability in the recipient population. Conversely, it may dilute unique adaptations present in the recipient population if dominant alleles from the donor become more prevalent. Understanding this dynamic is crucial for conservation efforts and managing biodiversity, as it highlights the interconnectedness of populations and their evolutionary trajectories.

© 2024 Fiveable Inc. All rights reserved.

AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.