Evolution of vegetative incompatibility in filamentous Ascomycetes: I. Deterministic models

M.J. Nauta*, Rolf F. Hoekstra

*Corresponding author for this work

    Research output: Contribution to journalArticleAcademicpeer-review

    40 Citations (Scopus)

    Abstract

    In ascomycetes vegetative incompatibility can prevent the somatic exchange of genetic material between conspecifics. It must occur frequently in natural populations, since in all species studied many vegetative compatibility groups (VCGs) are found. Using a population-genetic approach, this paper explores two possible selective explanations for the evolution of vegetative incompatibility in asexual fungi: selection by a nuclear parasitic gene, and selection by a harmful cytoplasmic element. In a deterministic model, assuming a random spatial distribution of VCGs in an infinitely sized population, it is found that neither of these forms of frequency-dependent selection can explain the large number of VCGs found in nature. The selective pressure for more VCGs disappears once a limited number of VCGs exist, because the frequency of compatible interactions decreases when the number of VCGs increases. In comparing the two selective explanations, selection by a cytoplasmic element seems a more plausible explanation than selection by a nuclear gene.

    Original languageEnglish
    Pages (from-to)979-995
    Number of pages17
    JournalEvolution
    Volume48
    Issue number4
    DOIs
    Publication statusPublished - Aug-1994

    Keywords

    • FREQUENCY DEPENDENT SELECTION
    • FUNGI
    • HETEROKARYON
    • SELF NONSELF
    • VEGETATIVE INCOMPATIBILITY
    • FUJIKUROI FUSARIUM-MONILIFORME
    • COMPATIBILITY GROUPS
    • GIBBERELLA-FUJIKUROI
    • PODOSPORA-ANSERINA
    • PROTOPLASMIC INCOMPATIBILITY
    • HETEROKARYON INCOMPATIBILITY
    • ALLORECOGNITION SPECIFICITY
    • ASPERGILLUS-FLAVUS
    • OXYSPORUM
    • POPULATION

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