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Epistasis Analysis01:09

Epistasis Analysis

6.3K
Although Mendel chose seven unrelated traits in peas to study gene segregation, most traits involve multiple gene interactions that create a spectrum of phenotypes. When the interaction of various genes or alleles at different locations influences a phenotype, this is called epistasis. Epistasis often involves one gene masking or interfering with the expression of another (antagonistic epistasis). Epistasis often occurs when different genes are part of the same biochemical pathway. The...
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Epistasis01:39

Epistasis

51.7K
In addition to multiple alleles at the same locus influencing traits, numerous genes or alleles at different locations may interact and influence phenotypes in a phenomenon called epistasis. For example, rabbit fur can be black or brown depending on whether the animal is homozygous dominant or heterozygous at a TYRP1 locus. However, if the rabbit is also homozygous recessive at a locus on the tyrosinase gene (TYR), it will have an unshaded coat that appears white, regardless of its TYRP1...
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Types of Selection01:46

Types of Selection

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Natural selection influences the frequencies of particular alleles and phenotypes within populations in several different ways. Primarily, natural selection can be directional, stabilizing, or disruptive. Directional selection favors one extreme trait and shifts the population towards that phenotype while selecting against individuals displaying alternate traits. Stabilizing selection favors an intermediate trait with a narrow range of variation. Deviation from the optimal phenotype towards an...
46.7K
Evolution of New Traits in Microbes01:24

Evolution of New Traits in Microbes

185
Microorganisms evolve rapidly due to their large population sizes and short generation times, often exhibiting measurable changes within days under laboratory conditions. Natural selection acts on standing genetic variation, enabling the retention and amplification of beneficial traits that confer fitness advantages in changing environments.Adaptive Pigment Regulation in RhodobacterIn Rhodobacter, a genus of purple non-sulfur bacteria, light-harvesting pigments such as bacteriochlorophyll and...
185
Limits to Natural Selection01:38

Limits to Natural Selection

36.3K
Organisms that are well-adapted to their environment are more likely to survive and reproduce. However, natural selection does not lead to perfectly adapted organisms. Several factors constrain natural selection.
36.3K
Frequency-dependent Selection01:21

Frequency-dependent Selection

24.6K
When the fitness of a trait is influenced by how common it is (i.e., its frequency) relative to different traits within a population, this is referred to as frequency-dependent selection. Frequency-dependent selection may occur between species or within a single species. This type of selection can either be positive—with more common phenotypes having higher fitness—or negative, with rarer phenotypes conferring increased fitness.
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Related Experiment Video

Updated: Apr 20, 2026

Mutagenesis and Functional Selection Protocols for Directed Evolution of Proteins in E. coli
09:01

Mutagenesis and Functional Selection Protocols for Directed Evolution of Proteins in E. coli

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Long-term selection experiments: epistasis and the response to selection.

Charles Goodnight1

  • 1Department of Biology, University of Vermont, Marsh Life Science Building, 109 Carrigan Drive, Burlington, VT, 05405-0086, USA, charles.goodnight@uvm.edu.

Methods in Molecular Biology (Clifton, N.J.)
|November 19, 2014
PubMed
Summary
This summary is machine-generated.

Gene interaction, specifically epistasis, can explain extended responses and intermediate plateaus in long-term selection experiments, suggesting a richer source of genetic variation than previously assumed.

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Area of Science:

  • Evolutionary genetics
  • Quantitative genetics

Background:

  • Long-term selection experiments often show no limits due to genetic variation loss.
  • Selection plateaus, where response halts for generations, are common in these experiments.

Purpose of the Study:

  • To investigate the role of gene interaction (epistasis) in generating patterns observed in long-term selection experiments.
  • To explore how epistasis influences genetic variation and response to selection over time.

Main Methods:

  • Utilized previously published theoretical results.
  • Employed a simple deterministic model to simulate selection experiments.

Main Results:

  • Epistasis can provide a continuous source of genetic variation for selection.
  • This variation can lead to extended responses to selection beyond initial expectations.

Conclusions:

  • Gene interaction is a significant factor in maintaining genetic variation during long-term selection.
  • Epistasis can explain the occurrence of intermediate selection plateaus observed in experiments.