Panmixia

In simple terms, panmixia (or panmicticism) is the ability of individuals in a population to interbreed without restrictions; individuals are able to move about freely within their habitat, possibly over a range of hundreds to thousands of miles, and thus breed with other members of the population. By comparing real populations to the panmictic ideal, researchers can identify the evolutionary forces that are acting on those populations. To signify the importance of this, imagine several different finite populations of the same species (for example: a grazing herbivore), isolated from each other by some physical characteristic of the environment (dense forest areas separating grazing lands). As time progresses, natural selection and genetic drift will slowly move each population toward genetic differentiation that would make each population genetically unique (that could eventually lead to speciation events or extirpation). However, if the separating factor is removed before this happens (e.g. a road is cut through the forest), and the individuals are allowed to move about freely, the individual populations will still be able to interbreed. As the species's populations interbreed over time, they become more genetically uniform, functioning again as a single panmictic population. In attempting to describe the mathematical properties of structured populations, Sewall Wright proposed a "factor of Panmixia" (P) to include in the equations describing the gene frequencies in a population, and accounting for a population's tendency towards panmixia, while a "factor of Fixation" (F) would account for a population's departure from the Hardy–Weinberg expectation, due to less than panmictic mating. This equation describes how the allelic and genotypic frequencies remain constant in a non-evolving population. In this formulation, the two quantities are complementary, i.e. P = 1 − F. From this factor of fixation, he later developed the F statistics. == Background information ==

In a panmictic species, all of the individuals of a single species are potential partners, and the species gives no mating restrictions throughout the population. Panmixia can also be referred to as random mating, referring to a population that randomly chooses their mate, rather than sorting between the adults of the population. Panmixia allows for species to reach genetic diversity through gene flow more efficiently than monandry species. However, outside population factors, like drought and limited food sources, can affect the way any species will mate. When scientists examine species mating to understand their mating style, they look at factors like genetic markers, genetic differentiation, and gene pool. == Panmictic species ==

'' is considered as a global panmictic population. A panmictic population of Monostroma latissimum, a marine green algae, shows sympatric speciation in southwest Japanese islands. Although panmictic, the population is diversifying. Dawson's burrowing bee, Amegilla dawsoni, may be forced to aggregate in common mating areas due to uneven resource distribution in its harsh desert environment. Indian Scad (Decapterus russelli) is found in the Indian Ocean. It forms a single panmictic stock across the ecosystem, meaning gametes are uniformly dispersed throughout the population. This panmictic stock suggests that individuals from other locations within the Indian Ocean are interbreeding due to limited genetic variation. This is caused by a rapid growth bottleneck effect due to a random event. However, significant genetic differentiation of Decapterus russelli is found between populations from the Indian Ocean and the Indo-Malay Archinpelago, attributed to isolation and environmental factors. Knoxdaviesia proteae, a fungus that lives on flowers of Protea repens, shows extensive genetic variation and weak genetic differentiation. These genetic factors mean the fungus population is well-mixed and maintains panmixia across the population by spreading widely via beetles. This fungus uses mites to travel short distances, but it has been found that instead, Knoxdaviesia proteae rides on beetles to pollinate Protea repens. This allows for frequent genetic exchange due to the fungus's interaction with other colonies instead of cloning itself. == Related experiments and species ==

• Anguilla rostrata, or the American eel, exhibits panmixia throughout the entire species. This allows the eel to have phenotypic variation in their offspring and survive in a wide range of environmental conditions. • In a heterogeneous environment such as the forests of Oregon, United States, Douglas squirrels (Tamiasciurus douglasii) exhibit local patterns of adaptation. In a study conducted by Chaves (2014) a population along an entire transect was found to be panmictic. Traits observed in this study included skull shape, fur color, etc. • Swordfish based in the Indian Ocean (Xiphias gladius) have been found to be a single panmictic population. Markers used in the study carried out by Muths et al. (2013) found large spatial and temporal homogeneity in genetic structure satisfactory in order to consider the swordfish a singular panmictic population. == See also ==