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Frequency-dependent Selection01:21

Frequency-dependent Selection

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.Positive Frequency-Dependent SelectionIn positive...
Understanding Species and Reproductive Barriers01:17

Understanding Species and Reproductive Barriers

A species is a group of organisms that interbreed and produce fertile offspring. Typically, individuals of the same species appear similar and share common characteristics due to their highly similar genomes. However, not all organisms that look alike are members of the same species. Various mechanisms keep most species discrete. While some mechanisms prevent reproductive behavior and fertilization (pre-zygotic isolation), others prevent the production of fertile offspring after mating has...
Asexual Reproduction02:38

Asexual Reproduction

Asexual reproduction allows plants to reproduce without growing flowers, attracting pollinators, or dispersing seeds. Offspring are genetically identical to the parent and produced without the fusion of male and female gametes.
Monohybrid Crosses01:20

Monohybrid Crosses

Overview
Formation of Species01:31

Formation of Species

Speciation describes the formation of one or more new species from one or sometimes multiple original species. The resulting species are discrete from the parent species, and barriers to reproduction will typically exist. There are two primary mechanisms, speciation with and without geographic isolation—allopatric and sympatric speciation, respectively.Allopatric SpeciationIn allopatric speciation, gene flow between two populations of the same species is prevented by a geographic barrier, like...
Chromosomal Theory of Inheritance01:39

Chromosomal Theory of Inheritance

In 1866, Gregor Mendel published the results of his pea plant breeding experiments, providing evidence for predictable patterns in the inheritance of physical characteristics. The significance of his findings was not immediately recognized. In fact, the existence of genes was unknown at the time. Mendel referred to hereditary units as “factors.”

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Related Experiment Video

Updated: Jul 12, 2026

Determination of Self- and Inter-(in)compatibility Relationships in Apricot Combining Hand-Pollination, Microscopy and Genetic Analyses
08:08

Determination of Self- and Inter-(in)compatibility Relationships in Apricot Combining Hand-Pollination, Microscopy and Genetic Analyses

Published on: June 16, 2020

Gametophytic self-incompatibility reexamined.

D L Mulcahy, G B Mulcahy

    Science (New York, N.Y.)
    |June 17, 1983
    PubMed
    Summary

    The traditional view of self-incompatibility in flowering plants may be too simple. New evidence suggests many genes, not just a few, control pollen-style interactions, potentially changing our understanding of plant reproduction.

    Area of Science:

    • Plant reproductive biology
    • Genetics
    • Molecular biology

    Background:

    • Gametophytic self-incompatibility (GSI) in angiosperms is traditionally explained by a few multiallelic loci inhibiting pollen tube growth.
    • Recent experimental findings challenge this model, suggesting a more complex genetic basis with numerous loci involved.

    Purpose of the Study:

    • To propose an alternative hypothesis for gametophytic self-incompatibility.
    • To integrate recent data indicating multiple loci into a new theoretical framework.
    • To explore the role of extensive pollen-style interactions in plant reproduction.

    Main Methods:

    • Review and synthesis of existing experimental data on self-incompatibility.
    • Development of a theoretical model incorporating multiple loci and complementary interactions.

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    Last Updated: Jul 12, 2026

    Determination of Self- and Inter-(in)compatibility Relationships in Apricot Combining Hand-Pollination, Microscopy and Genetic Analyses
    08:08

    Determination of Self- and Inter-(in)compatibility Relationships in Apricot Combining Hand-Pollination, Microscopy and Genetic Analyses

    Published on: June 16, 2020

    Determination of Self-(In)compatibility and Inter-(In)compatibility Relationships in Citrus Using Manual Pollination, Microscopy, and S-Genotype Analyses
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    Determination of Self-(In)compatibility and Inter-(In)compatibility Relationships in Citrus Using Manual Pollination, Microscopy, and S-Genotype Analyses

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  • Comparative analysis of conventional and alternative hypotheses.
  • Main Results:

    • The conventional hypothesis with few loci does not fully explain current experimental observations.
    • An alternative model involving numerous loci and complex pollen-style interactions provides a better fit for the data.
    • This alternative model suggests gametophytic self-incompatibility might be a facet of broader pollen-style interactions, possibly without a single S gene.

    Conclusions:

    • The established model of gametophytic self-incompatibility requires revision.
    • A multi-locus, interaction-based model offers a more comprehensive explanation for self-incompatibility mechanisms in angiosperms.
    • Further research is needed to elucidate the intricate network of pollen-style interactions governing plant reproduction.