What is the Difference Between Disruptive Selection and Stabilizing Selection?
🆚 Go to Comparative Table 🆚The main differences between disruptive selection and stabilizing selection are as follows:
- Extremes vs. Intermediates: Stabilizing selection eliminates extremes (both the lowest and highest values of the trait), whereas disruptive selection eliminates intermediates (the average or intermediate phenotypes).
- Speciation: Stabilizing selection does not lead to speciation, while disruptive selection can lead to speciation, as it may cause the formation of two new populations with distinct phenotypes.
- Effect on Genetic Variance: Stabilizing selection reduces the genetic variance of a population, as it eliminates both extreme phenotypes. In contrast, disruptive selection can increase genetic variance within the population, as it selects against the average or intermediate phenotypes.
- Adaptation: Stabilizing selection occurs when the population stabilizes on a particular trait value, making the individuals more adapted to the environment. Disruptive selection, on the other hand, acts against individuals in the middle of the trait distribution, potentially favoring populations with more diverse phenotypes.
In summary, stabilizing selection favors the middle of a trait distribution and eliminates extreme values, while disruptive selection favors the extremes and eliminates the middle values. Stabilizing selection tends to make populations more homogeneous, while disruptive selection can lead to increased diversity and even speciation.
Comparative Table: Disruptive Selection vs Stabilizing Selection
Disruptive selection and stabilizing selection are two types of natural selection processes that influence the genetic variance of a population. Here is a table highlighting the differences between them:
| Feature | Disruptive Selection | Stabilizing Selection |
|---|---|---|
| Definition | Disruptive selection favors both extreme phenotypes over intermediate phenotypes, increasing the genetic variance of the population. | Stabilizing selection favors average phenotypes in a population and eliminates both types of extreme phenotypes, decreasing the population's genetic variance. |
| Genetic Variance | Increases the population's genetic variance. | Decreases the population's genetic variance. |
| Phenotypes | Favors both extreme phenotypes. | Favors intermediate phenotypes and eliminates extreme phenotypes. |
| Examples | A population of plants with medium height is favored, as both short and tall plants have lower fitness due to sunlight and wind damage, respectively. | A population of mice that live in the woods, natural selection will tend to favor individuals that best blend in with the forest floor, disfavoring extreme shades of fur. |
In summary, disruptive selection increases the genetic variance of a population by favoring both extreme phenotypes, while stabilizing selection decreases the genetic variance by favoring intermediate phenotypes and eliminating extreme phenotypes.
- Directional vs Disruptive Selection
- Stabilizing vs Balancing Selection
- Natural Selection vs Sexual Selection
- Natural Selection vs Artificial Selection
- Natural Selection vs Genetic Drift
- Natural Selection vs Evolution
- Spatial Sorting vs Natural Selection
- Assortative vs Disassortative Mating
- Natural Selection vs Adaptation
- Selective Breeding vs Genetic Engineering
- Artificial Selection vs Genetic Engineering
- Transgenesis vs Selective Breeding
- Intrasexual vs Intersexual Selection
- GMO vs Selective Breeding
- Continuous vs Discontinuous Variation
- Fixation vs Stabilization
- Insertion Sort vs Selection Sort
- Convergent vs Divergent Evolution
- Bubble Sort vs Selection Sort