Disassortative mating
Disassortative mating, also known as negative assortative mating or heterogamy, is a non-random mating pattern in biology where individuals preferentially select partners with dissimilar phenotypes or genotypes, in contrast to assortative mating where similar individuals pair more frequently.[1] This preference promotes genetic diversity by increasing heterozygosity in offspring, reducing the risks associated with inbreeding and enhancing overall population variability.[2] In evolutionary terms, disassortative mating plays a key role in maintaining genetic polymorphism and can evolve under conditions of heterozygote advantage or negative frequency-dependent selection, where rare alleles confer higher fitness.[2] It often arises in contexts where genetic compatibility benefits offspring survival, such as improved immune responses through diverse alleles at loci like the major histocompatibility complex (MHC).[3] For instance, in humans, studies of European populations have shown that couples exhibit greater MHC dissimilarity than expected by chance, potentially reducing offspring homozygosity by about 1% and bolstering pathogen resistance.[3] Examples of disassortative mating span diverse taxa, illustrating its adaptive value. In vertebrates, female preferences for MHC-dissimilar males occur in mammals, birds, fish, and reptiles, supporting broader immune diversity in progeny.[3] Among birds, the white-throated sparrow displays plumage-based disassortative mating that sustains morph polymorphism.[2] In insects, Heliconius numata butterflies show strong disassortative preferences for wing pattern morphs, linked to heterozygote advantage at supergene loci.[2] Plants enforce disassortative mating through structural adaptations like dioecy (separate sexes) or heterostyly (differing flower styles), which prevent self-pollination and foster hybrid vigor, as seen in increased yields from outcrossed corn varieties.[1] Overall, while rarer than assortative mating, disassortative strategies contribute to long-term adaptability by countering genetic homogenization.[2]Fundamentals
Definition
Disassortative mating is a form of non-random mating in which individuals preferentially pair with others exhibiting dissimilar phenotypes or genotypes, occurring more frequently than would be predicted by random mating alone.[2] This pattern contrasts with assortative mating, where similarity drives mate choice.[4] The concept of disassortative mating was first formalized in population genetics by Sewall Wright in his 1921 series of papers on mating systems, where it was described as a mechanism involving pairing based on somatic dissimilarity, diverging from the random mating assumption central to the Hardy-Weinberg equilibrium model established in 1908. Wright's work highlighted how such mating deviates from panmixia, influencing genetic correlations between relatives.[5] A key characteristic of disassortative mating is its tendency to increase heterozygosity in offspring by promoting unions between genetically diverse individuals, thereby reducing homozygosity compared to random expectations.[6] It is commonly quantified using correlation coefficients, where negative values (e.g., mating correlation r < 0) indicate a preference for dissimilarity in traits or alleles.[7] In a basic two-allele model at a single locus (with alleles A and a), disassortative mating manifests as an elevated frequency of pairings between dissimilar genotypes (e.g., AA \times aa, AA \times Aa, aa \times Aa) relative to random proportions, while similar pairings (e.g., AA \times AA, aa \times aa, Aa \times Aa) occur less often. This can be represented by the probability of dissimilar matings exceeding the product of genotype frequencies under equilibrium, such as P(AA \times aa) > p^2 q^2, where p and q are allele frequencies, thereby shifting genotypic proportions toward greater heterozygote production.[8]Comparison with Assortative Mating
Assortative mating refers to a non-random mating pattern characterized by a positive correlation (r > 0) between the phenotypes or genotypes of mating partners, where individuals preferentially pair with those exhibiting similar traits.[9] This contrasts with disassortative mating, which involves a negative correlation (r < 0), favoring pairings between dissimilar individuals.[9] Random mating serves as the neutral baseline for both patterns, where mate choice occurs without regard to traits (r = 0), producing offspring genotype frequencies expected under Hardy-Weinberg equilibrium.[10] Key differences between the two mating patterns emerge in their genetic consequences. Disassortative mating reduces homozygosity by promoting unions between dissimilar genotypes, thereby decreasing overall trait variance within populations and promoting genetic mixing to reduce phenotypic divergence.[11] In contrast, assortative mating increases homozygosity and trait variance, which can accelerate genetic differentiation and contribute to speciation by limiting gene flow between dissimilar groups.[11][12] These effects are summarized in the following comparison:| Aspect | Assortative Mating (r > 0) | Disassortative Mating (r < 0) |
|---|---|---|
| Homozygosity | Increases | Decreases |
| Trait Variance | Increases (additive genetic variance rises) | Decreases |
| Population Divergence | Reinforces, potentially leading to speciation | Reduces, promoting genetic mixing |
| Gene Flow | Reduces between dissimilar phenotypes | Increases between dissimilar phenotypes |