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Habitat Fragmentation02:31

Habitat Fragmentation

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Habitat fragmentation describes the division of a more extensive, continuous habitat into smaller, discontinuous areas. Human activities such as land conversion, as well as slower geological processes leading to changes in the physical environment, are the two leading causes of habitat fragmentation. The fragmentation process typically follows the same steps: perforation, dissection, fragmentation, shrinkage, and attrition.
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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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Conservation of Small Populations02:04

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Small population sizes put a species at extreme risk of extinction due to a lack of variation, and a consequent decrease in adaptability. This weakens the chances of survival under pressures such as climate change, competition from other species, or new diseases. Large populations are more likely to survive pressures such as these, as such populations are more likely to harbor individuals that have genetic variants that are adaptive under new stresses. Small populations are much less...
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Conservation of Declining Populations02:07

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Conservation of declining population focuses on ways of detecting, diagnosing, and halting a population decline. The approach uses methods to prevent populations from going extinct.
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Mutation, Gene Flow, and Genetic Drift01:09

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In a population that is not at Hardy-Weinberg equilibrium, the frequency of alleles changes over time. Therefore, any deviations from the five conditions of Hardy-Weinberg equilibrium can alter the genetic variation of a given population. Conditions that change the genetic variability of a population include mutations, natural selection, non-random mating, gene flow, and genetic drift (small population size).
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Genetic Drift

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Natural selection—probably the most well-known evolutionary mechanism—increases the prevalence of traits that enhance survival and reproduction. However, evolution does not merely propagate favorable traits, nor does it always benefit populations.
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Related Experiment Video

Updated: Sep 19, 2025

Monitoring Spatial Segregation in Surface Colonizing Microbial Populations
07:40

Monitoring Spatial Segregation in Surface Colonizing Microbial Populations

Published on: October 29, 2016

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Local negative frequency-dependence can decrease global coexistence in fragmented populations.

Anush Devadhasan1,2, Oana Carja1

  • 1Computational Biology Department, School of Computer Science, Carnegie Mellon University, Pittsburgh, PA, USA.

Biorxiv : the Preprint Server for Biology
|June 6, 2025
PubMed
Summary
This summary is machine-generated.

Negative frequency-dependent (NFD) selection promotes biodiversity locally. However, in fragmented landscapes, NFD selection can paradoxically reduce coexistence and diversity, challenging its general role in maintaining biodiversity.

Keywords:
biodiversitycoexistencecomplex spatial structurefragmented populationsfrequency dependent selectionniche theorypopulation structure

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Predicting the Effectiveness of Population Replacement Strategy Using Mathematical Modeling
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Area of Science:

  • Ecology
  • Evolutionary Biology
  • Theoretical Biology

Background:

  • Negative frequency-dependent (NFD) selection is a key mechanism for maintaining biodiversity by favoring rare variants.
  • While NFD selection is confirmed at local scales, its role in maintaining biodiversity across larger, fragmented landscapes is unclear.

Purpose of the Study:

  • To investigate whether local NFD selection is sufficient to maintain biodiversity in fragmented populations.
  • To explore the impact of landscape fragmentation on the dynamics of NFD selection and species coexistence.

Main Methods:

  • Developed a theoretical model using the classic island framework to simulate NFD selection in fragmented populations.
  • Extended the model to a multispecies framework and incorporated spatial variation in carrying capacity.
  • Developed and applied a statistical test to empirical data of avian species in the Ryukyu Islands.

Main Results:

  • In fragmented populations, NFD selection paradoxically reduced coexistence and shortened fixation times compared to neutral processes.
  • Fragmentation led to a non-monotonic relationship between fixation time and population size, with lowest diversity at intermediate scales.
  • Empirical analysis of avian species data provided evidence that NFD selection suppresses coexistence in fragmented systems.

Conclusions:

  • Fragmentation can undermine the biodiversity-promoting effects of NFD selection.
  • The stabilizing role of NFD selection may be limited in heterogeneous and fragmented landscapes.
  • NFD selection's generality as a mechanism for maintaining biodiversity requires re-evaluation in light of landscape structure.