5 Must Know Facts For Your Next Test

1. Allele frequencies are calculated by taking the number of times an allele appears in a population and dividing it by the total number of alleles for that gene in the population.
2. Changes in allele frequencies over time can indicate evolutionary processes such as natural selection, mutation, migration, or genetic drift.
3. A stable allele frequency suggests that the population is not undergoing significant evolutionary change, whereas fluctuations can indicate adaptation or other evolutionary pressures.
4. The study of allele frequencies can help identify populations at risk of inbreeding or extinction due to loss of genetic diversity.
5. Monitoring allele frequencies is important for conservation biology, as it can inform strategies to preserve endangered species and their genetic variability.

Review Questions

• How do changes in allele frequencies contribute to our understanding of evolution within a population?
  • Changes in allele frequencies can reveal how populations evolve over time by highlighting shifts in genetic traits influenced by natural selection, mutation, migration, and genetic drift. For instance, if a certain allele becomes more frequent due to environmental pressures favoring specific traits, it indicates adaptive evolution. By tracking these changes, scientists can gain insights into how populations respond to their environments and how they may adapt or face challenges over generations.
• In what ways does the Hardy-Weinberg Principle relate to the concept of allele frequencies and what does it imply about a population's evolutionary state?
  • The Hardy-Weinberg Principle provides a framework for understanding allele frequencies within a population at equilibrium. It implies that if a population's allele frequencies remain constant from generation to generation, then the population is not evolving. However, if any factors such as selection, drift, or mutation disrupt this equilibrium, allele frequencies will change, indicating that evolution is occurring. This relationship highlights the balance between stability and change in genetic makeup over time.
• Evaluate the role of genetic drift in altering allele frequencies and how this process can affect small populations differently compared to larger ones.
  • Genetic drift plays a significant role in changing allele frequencies through random sampling effects, particularly impacting small populations more than larger ones. In small populations, random events can lead to drastic changes in allele frequencies simply by chance—some alleles may be lost entirely while others may become fixed. This can reduce genetic diversity and increase the risk of extinction since small populations are less able to adapt to environmental changes. In contrast, larger populations tend to buffer against random fluctuations, maintaining more stable allele frequencies and greater genetic diversity.

© 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.