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Competition (biology)

March 17, 2024

Competition is an interaction between organisms or species in which both require a resource that is in limited supply (such as food, water, or territory).[1] Competition lowers the fitness of both organisms involved since the presence of one of the organisms always reduces the amount of the resource available to the other.[2]

Great egret and neotropic cormorant competing over territory

In the study of community ecology, competition within and between members of a species is an important biological interaction. Competition is one of many interacting biotic and abiotic factors that affect community structure, species diversity, and population dynamics (shifts in a population over time).[3]

There are three major mechanisms of competition: interference, exploitation, and apparent competition (in order from most direct to least direct). Interference and exploitation competition can be classed as "real" forms of competition, while apparent competition is not, as organisms do not share a resource, but instead share a predator.[3] Competition among members of the same species is known as intraspecific competition, while competition between individuals of different species is known as interspecific competition.

According to the competitive exclusion principle, species less suited to compete for resources must either adapt or die out, although competitive exclusion is rarely found in natural ecosystems.[3] According to evolutionary theory, competition within and between species for resources is important in natural selection. More recently, however, researchers have suggested that evolutionary biodiversity for vertebrates has been driven not by competition between organisms, but by these animals adapting to colonize empty livable space; this is termed the 'Room to Roam' hypothesis.[4]

Interference competition edit

 
Male-male competition in red deer during rut is an example of interference competition within a species.

During interference competition, also called contest competition, organisms interact directly by fighting for scarce resources. For example, large aphids defend feeding sites on cottonwood leaves by ejecting smaller aphids from better sites. Male-male competition in red deer during rut is an example of interference competition that occurs within a species.

Interference competition occurs directly between individuals via aggression when the individuals interfere with the foraging, survival, and reproduction of others, or by directly preventing their physical establishment in a portion of the habitat. An example of this can be seen between the ant Novomessor cockerelli and red harvester ants, where the former interferes with the ability of the latter to forage by plugging the entrances to their colonies with small rocks.[5] Male bowerbirds, who create elaborate structures called bowers to attract potential mates, may reduce the fitness of their neighbors directly by stealing decorations from their structures.[6]

In animals, interference competition is a strategy mainly adopted by larger and stronger organisms within a habitat. As such, populations with high interference competition have adult-driven generation cycles.[7] At first, the growth of juveniles is stunted by larger adult competitors. However, once the juveniles reach adulthood, they experience a secondary growth cycle.[7] Plants, on the other hand, primarily engage in interference competition with their neighbors through allelopathy, or the production of biochemicals.[8]

Interference competition can be seen as a strategy that has a clear cost (injury or death) and benefit (obtaining resources that would have gone to other organisms).[9] In order to cope with strong interference competition, other organisms often either do the same or engage in exploitation competition. For example, depending on the season, larger ungulate red deer males are competitively dominant due to interference competition. However, does and fawns have dealt with this through temporal resource partitioning — foraging for food only when adult males are not present.[10]

Exploitation competition edit

Exploitation competition, or scramble competition, occurs indirectly when organisms both use a common limiting resource or shared food item. Instead of fighting or exhibiting aggressive behavior in order to win resources, exploitative competition occurs when resource use by one organism depletes the total amount available for other organisms. These organisms might never interact directly but compete by responding to changes in resource levels. Very obvious examples of this phenomenon include a diurnal species and a nocturnal species that nevertheless share the same resources or a plant that competes with neighboring plants for light, nutrients, and space for root growth.[11][8]

This form of competition typically rewards those organisms who claim the resource first. As such, exploitation competition is often size-dependent and smaller organisms are favored since smaller organisms typically have higher foraging rates.[7] Since smaller organisms have an advantage when exploitative competition is important in an ecosystem, this mechanism of competition might lead to a juvenile-driven generation cycle: individual juveniles succeed and grow fast, but once they mature they are outcompeted by smaller organisms.[7]

In plants, exploitative competition can occur both above- and below ground. Aboveground, plants reduce the fitness of their neighbors by vying for sunlight plants consume nitrogen by absorbing it into their roots, making nitrogen unavailable to nearby plants. Plants that produce many roots typically reduce soil nitrogen to very low levels, eventually killing neighboring plants.

Exploitative competition has also been shown to occur both within species (intraspecific) and between different species (interspecific). Furthermore, many competitive interactions between organisms are some combination of exploitative and interference competition, meaning the two mechanisms are far from mutually exclusive. For example, a recent 2019 study found that the native thrip species Frankliniella intonsa was competitively dominant over an invasive thrip species Frankliniella occidentalis because it not only exhibited greater time feeding (exploitative competition) but also greater time guarding its resources (interference competition).[12] Plants may also exhibit both forms of competition, not only scrambling for space for root growth but also directly inhibiting other plants' development through allelopathy.

Apparent competition edit

Apparent competition occurs when two otherwise unrelated prey species indirectly compete for survival through a shared predator.[13] This form of competition typically manifests in new equilibrium abundances of each prey species. For example, suppose there are two species (species A and species B), which are preyed upon by food-limited predator species C. Scientists observe an increase in the abundance of species A and a decline in the abundance of species B. In an apparent competition model, this relationship is found to be mediated through predator C; a population explosion of species A increases the abundance of predator species C due to a greater total food source. Since there are now more predators, species A and B would be hunted at higher rates than before. Thus, the success of species A was to the detriment of species B — not because they competed for resources, but because their increased numbers had indirect effects on the predator population.

This one-predator/two-prey model has been explored by ecologists as early as 1925, but the term "apparent competition" was first coined by University of Florida ecologist Robert D. Holt in 1977.[13][14] Holt found that field ecologists at the time were erroneously attributing negative interactions among prey species to niche partitioning and competitive exclusion, ignoring the role of food-limited predators.[13]

Apparent competition and realized niche edit

Apparent competition can help shape a species' realized niche, or the area or resources the species can actually persist due to interspecific interactions. The effect on realized niches could be incredibly strong, especially when there is an absence of more traditional interference or exploitative competition. A real-world example was studied in the late 1960s, when the introduction of snowshoe hares (Lepus americanus) to Newfoundland reduced the habitat range of native arctic hares (Lepus arcticus). While some ecologists hypothesized that this was due to an overlap in the niche, other ecologists argued that the more plausible mechanism was that snowshoe hare populations led to an explosion in food-limited lynx populations, a shared predator of both prey species. Since the arctic hare has a relatively weaker defense tactic than the snowshoe hare, they were excluded from woodland areas on the basis of differential predation. However, both apparent competition and exploitation competition might help explain the situation to some degree.[13] Support for the impact of competition on the breadth of the realized niche with respect to diet is becoming more common in a variety of systems based upon isotopic and spatial data, including both carnivores[15] and small mammals.[16]

Asymmetric apparent competition edit

Apparent competition can be symmetric or asymmetric.[17] Symmetric apparent competition negatively impacts both species equally (-,-), from which it can be inferred that both species will persist. However, asymmetric apparent competition occurs when one species is affected less than the other. The most extreme scenario of asymmetric apparent competition is when one species is not affected at all by the increase in the predator, which can be seen as a form of amensalism (0, -).[18] Human impacts on endangered prey species have been characterized by conservation scientists as an extreme form of asymmetric apparent competition, often through introducing predator species into ecosystems or resource subsidies. An example of fully asymmetric apparent competition which often occurs near urban centers is subsidies in the form of human garbage or waste. In the early 2000s, the common raven (Corvus corax) population in the Mojave Desert increased due to an influx of human garbage, leading to an indirect negative effect on juvenile desert tortoises (Gopherus agassizii).[19] Asymmetry in apparent competition can also arise as a consequence of resource competition. An empirical example is provided by two small fish species in postglacial lakes in Western Canada, where resource competition between prickly sculpin and threespine stickleback fish leads to a spatial niche shift mainly in threespine stickleback.[20] As a consequence of this shift, predation by a shared trout predator increases for stickleback but decreases for sculpin in lakes where the two species co-occur compared to lakes in which each species occurs on its own together with trout predators. Because sharing predators often comes together with competition for shared food resources, apparent competition and resource competition may often interplay in nature.[21]

Apparent competition in the human microbiome edit

Apparent competition has also been viewed in and on the human body. The human immune system can acts as the generalist predator, and a high abundance of a certain bacteria may induce an immune response, damaging all pathogens in the body. Another example of this is of two populations of bacteria that can both support a predatory bacteriophage. In most situations, the one that is most resistant to infection by the shared predator will replace the other.[17]

Apparent competition has also been suggested as an exploitable phenomenon for cancer treatments. Highly specialized viruses that are developed to target malignant cancer cells often go locally extinct prior to eradicating all cancer. However, if a virus were developed that targets both healthy and unhealthy host cells to some degree, the large number of healthy cells would support the predatory virus for long enough to eliminate all malignant cells.[17]

Size-asymmetric competition edit

Main article: Size-asymmetric competition

Competition can be either complete symmetric (all individuals receive the same amount of resources, irrespective of their size), perfectly size symmetric (all individuals exploit the same amount of resource per unit biomass), or absolutely size-asymmetric (the largest individuals exploit all the available resource).

Among plants, size asymmetry is context-dependent and competition can be both asymmetric and symmetric depending on the most limiting resource. In forest stands, below-ground competition for nutrients and water is size-symmetric, because a tree's root system is typically proportionate to the biomass of the entire tree.[22] Conversely, above-ground competition for light is size-asymmetric — since light has directionality, the forest canopy is dominated entirely by the largest trees. These trees disproportionately exploit most of the resource for their biomass, making the interaction size asymmetric.[23] Whether above-ground or below-ground resources are more limiting can have major effects on the structure and diversity of ecological communities; in mixed beech stands, for example, size-asymmetric competition for light is a stronger predictor of growth compared with competition for soil resources.[24]

Within and between species edit

See also: Female intrasexual competition
 
Sea anemones compete for the territory in tide pools

Competition can occur between individuals of the same species, called intraspecific competition, or between different species, called interspecific competition. Studies show that intraspecific competition can regulate population dynamics (changes in population size over time). This occurs because individuals become crowded as the population grows. Since individuals within a population require the same resources, crowding causes resources to become more limited. Some individuals (typically small juveniles) eventually do not acquire enough resources and die or do not reproduce. This reduces population size and slows population growth.[citation needed]

Species also interact with other species that require the same resources. Consequently, interspecific competition can alter the sizes of many species populations at the same time. Experiments demonstrate that when species compete for a limited resource, one species eventually drives the populations of other species extinct. These experiments suggest that competing species cannot coexist (they cannot live together in the same area) because the best competitor will exclude all other competing species.[citation needed]

Intraspecific edit

Main article: Intraspecific competition

Intraspecific competition occurs when members of the same species compete for the same resources in an ecosystem.[25] A simple example is a stand of equally-spaced plants, which are all of the same age. The higher the density of plants, the more plants will be present per unit ground area, and the stronger the competition will be for resources such as light, water, or nutrients.

Interspecific edit

Main article: Interspecific competition

Interspecific competition may occur when individuals of two separate species share a limiting resource in the same area. If the resource cannot support both populations, then lowered fecundity, growth, or survival may result in at least one species. Interspecific competition has the potential to alter populations, communities, and the evolution of interacting species. An example among animals could be the case of cheetahs and lions; since both species feed on similar prey, they are negatively impacted by the presence of the other because they will have less food, however, they still persist together, despite the prediction that under competition one will displace the other. In fact, lions sometimes steal prey items killed by cheetahs. Potential competitors can also kill each other, in so-called 'intraguild predation'. For example, in southern California coyotes often kill and eat gray foxes and bobcats, all three carnivores sharing the same stable prey (small mammals).[26]

An example among protozoa involves Paramecium aurelia and Paramecium caudatum. Russian ecologist, Georgy Gause, studied the competition between the two species of Paramecium that occurred as a result of their coexistence. Through his studies, Gause proposed the Competitive exclusion principle, observing the competition that occurred when their different ecological niches overlapped.[27]

Competition has been observed between individuals, populations, and species, but there is little evidence that competition has been the driving force in the evolution of large groups. For example, mammals lived beside reptiles for many millions of years of time but were unable to gain a competitive edge until dinosaurs were devastated by the Cretaceous–Paleogene extinction event.[4]

Evolutionary strategies edit

Main articles: r/K selection theory and Verhulst equation

In evolutionary contexts, competition is related to the concept of r/K selection theory, which relates to the selection of traits which promote success in particular environments. The theory originates from work on island biogeography by the ecologists Robert MacArthur and E. O. Wilson.[28]

In r/K selection theory, selective pressures are hypothesized to drive evolution in one of two stereotyped directions: r- or K-selection.[29] These terms, r, and K, are derived from standard ecological algebra, as illustrated in the simple Verhulst equation of population dynamics:[30]

 

where r is the growth rate of the population (N), and K is the carrying capacity of its local environmental setting. Typically, r-selected species exploit empty niches, and produce many offspring, each of whom has a relatively low probability of surviving to adulthood. In contrast, K-selected species are strong competitors in crowded niches, and invest more heavily in much fewer offspring, each with a relatively high probability of surviving to adulthood.[30]

Competitive exclusion principle edit

 
1: a smaller (yellow) species of bird forages across whole tree.
2: a larger (red) species competes for resources.
3: red dominates in middle for the more abundant resources. Yellow adapts to a new niches, avoiding competition.
Main article: Competitive exclusion principle

To explain how species coexist, in 1934 Georgii Gause proposed the competitive exclusion principle which is also called the Gause principle: species cannot coexist if they have the same ecological niche. The word "niche" refers to a species' requirements for survival and reproduction. These requirements include both resources (like food) and proper habitat conditions (like temperature or pH). Gause reasoned that if two species had identical niches (required identical resources and habitats) they would attempt to live in exactly the same area and would compete for exactly the same resources. If this happened, the species that was the best competitor would always exclude its competitors from that area. Therefore, species must at least have slightly different niches in order to coexist.[31][32]

Character displacement edit

 
Medium ground finch (Geospiza fortis) on Santa Cruz Island in the Galapagos
Main article: Character displacement

Competition can cause species to evolve differences in traits. This occurs because the individuals of a species with traits similar to competing species always experience strong interspecific competition. These individuals have less reproduction and survival than individuals with traits that differ from their competitors. Consequently, they will not contribute many offspring to future generations. For example, Darwin's finches can be found alone or together on the Galapagos Islands. Both species populations actually have more individuals with intermediate-sized beaks when they live on islands without the other species present. However, when both species are present on the same island, competition is intense between individuals that have intermediate-sized beaks of both species because they all require intermediate-sized seeds. Consequently, individuals with small and large beaks have greater survival and reproduction on these islands than individuals with intermediate-sized beaks. Different finch species can coexist if they have traits—for instance, beak size—that allow them to specialize in particular resources. When Geospiza fortis and Geospiza fuliginosa are present on the same island, G. fuliginosa tends to evolve a small beak and G. fortis a large beak. The observation that competing species' traits are more different when they live in the same area than when competing species live in different areas is called character displacement. For the two finch species, beak size was displaced: Beaks became smaller in one species and larger in the other species. Studies of character displacement are important because they provide evidence that competition is important in determining ecological and evolutionary patterns in nature.[33]

See also edit

References edit

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  21. ^ Roesti, M., Groh, J.S., Blain, S.A., Huss, M., Rassias, P. & Bolnick, D.I. et al. (2023) Species divergence under competition and shared predation. Ecology Letters, 26, 111–123. Available from: https://doi.org/10.1111/ele.14138
  22. ^ West, P. W.; Ratkowsky, D. A. (2021-10-04). "Problems with models assessing influences of tree size and inter-tree competitive processes on individual tree growth: a cautionary tale". Journal of Forestry Research. 33 (2): 565–577. doi:10.1007/s11676-021-01395-9. ISSN 1993-0607. S2CID 244202914.
  23. ^ Pretzsch, Hans; Biber, Peter (2010-02-15). "Size-symmetric versus the size-asymmetric competition and growth partitioning among trees in forest stands along an ecological gradient in central Europe". Canadian Journal of Forest Research. 40 (2): 370–384. doi:10.1139/x09-195. ISSN 0045-5067.
  24. ^ del Río, Miren; Condés, Sonia; Pretzsch, Hans (2014-08-01). "Analyzing size-symmetric vs. size-asymmetric and intra- vs. inter-specific competition in beech (Fagus sylvatica L.) mixed stands". Forest Ecology and Management. 325: 90–98. doi:10.1016/j.foreco.2014.03.047.
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External links edit

March 17, 2024
competition, biology, competition, interaction, between, organisms, species, which, both, require, resource, that, limited, supply, such, food, water, territory, competition, lowers, fitness, both, organisms, involved, since, presence, organisms, always, reduc. Competition is an interaction between organisms or species in which both require a resource that is in limited supply such as food water or territory 1 Competition lowers the fitness of both organisms involved since the presence of one of the organisms always reduces the amount of the resource available to the other 2 Great egret and neotropic cormorant competing over territoryIn the study of community ecology competition within and between members of a species is an important biological interaction Competition is one of many interacting biotic and abiotic factors that affect community structure species diversity and population dynamics shifts in a population over time 3 There are three major mechanisms of competition interference exploitation and apparent competition in order from most direct to least direct Interference and exploitation competition can be classed as real forms of competition while apparent competition is not as organisms do not share a resource but instead share a predator 3 Competition among members of the same species is known as intraspecific competition while competition between individuals of different species is known as interspecific competition According to the competitive exclusion principle species less suited to compete for resources must either adapt or die out although competitive exclusion is rarely found in natural ecosystems 3 According to evolutionary theory competition within and between species for resources is important in natural selection More recently however researchers have suggested that evolutionary biodiversity for vertebrates has been driven not by competition between organisms but by these animals adapting to colonize empty livable space this is termed the Room to Roam hypothesis 4 Contents 1 Interference competition 2 Exploitation competition 3 Apparent competition 3 1 Apparent competition and realized niche 3 2 Asymmetric apparent competition 3 3 Apparent competition in the human microbiome 4 Size asymmetric competition 5 Within and between species 5 1 Intraspecific 5 2 Interspecific 6 Evolutionary strategies 7 Competitive exclusion principle 8 Character displacement 9 See also 10 References 11 External linksInterference competition edit nbsp Male male competition in red deer during rut is an example of interference competition within a species During interference competition also called contest competition organisms interact directly by fighting for scarce resources For example large aphids defend feeding sites on cottonwood leaves by ejecting smaller aphids from better sites Male male competition in red deer during rut is an example of interference competition that occurs within a species Interference competition occurs directly between individuals via aggression when the individuals interfere with the foraging survival and reproduction of others or by directly preventing their physical establishment in a portion of the habitat An example of this can be seen between the ant Novomessor cockerelli and red harvester ants where the former interferes with the ability of the latter to forage by plugging the entrances to their colonies with small rocks 5 Male bowerbirds who create elaborate structures called bowers to attract potential mates may reduce the fitness of their neighbors directly by stealing decorations from their structures 6 In animals interference competition is a strategy mainly adopted by larger and stronger organisms within a habitat As such populations with high interference competition have adult driven generation cycles 7 At first the growth of juveniles is stunted by larger adult competitors However once the juveniles reach adulthood they experience a secondary growth cycle 7 Plants on the other hand primarily engage in interference competition with their neighbors through allelopathy or the production of biochemicals 8 Interference competition can be seen as a strategy that has a clear cost injury or death and benefit obtaining resources that would have gone to other organisms 9 In order to cope with strong interference competition other organisms often either do the same or engage in exploitation competition For example depending on the season larger ungulate red deer males are competitively dominant due to interference competition However does and fawns have dealt with this through temporal resource partitioning foraging for food only when adult males are not present 10 Exploitation competition editExploitation competition or scramble competition occurs indirectly when organisms both use a common limiting resource or shared food item Instead of fighting or exhibiting aggressive behavior in order to win resources exploitative competition occurs when resource use by one organism depletes the total amount available for other organisms These organisms might never interact directly but compete by responding to changes in resource levels Very obvious examples of this phenomenon include a diurnal species and a nocturnal species that nevertheless share the same resources or a plant that competes with neighboring plants for light nutrients and space for root growth 11 8 This form of competition typically rewards those organisms who claim the resource first As such exploitation competition is often size dependent and smaller organisms are favored since smaller organisms typically have higher foraging rates 7 Since smaller organisms have an advantage when exploitative competition is important in an ecosystem this mechanism of competition might lead to a juvenile driven generation cycle individual juveniles succeed and grow fast but once they mature they are outcompeted by smaller organisms 7 In plants exploitative competition can occur both above and below ground Aboveground plants reduce the fitness of their neighbors by vying for sunlight plants consume nitrogen by absorbing it into their roots making nitrogen unavailable to nearby plants Plants that produce many roots typically reduce soil nitrogen to very low levels eventually killing neighboring plants Exploitative competition has also been shown to occur both within species intraspecific and between different species interspecific Furthermore many competitive interactions between organisms are some combination of exploitative and interference competition meaning the two mechanisms are far from mutually exclusive For example a recent 2019 study found that the native thrip species Frankliniella intonsa was competitively dominant over an invasive thrip species Frankliniella occidentalis because it not only exhibited greater time feeding exploitative competition but also greater time guarding its resources interference competition 12 Plants may also exhibit both forms of competition not only scrambling for space for root growth but also directly inhibiting other plants development through allelopathy Apparent competition editApparent competition occurs when two otherwise unrelated prey species indirectly compete for survival through a shared predator 13 This form of competition typically manifests in new equilibrium abundances of each prey species For example suppose there are two species species A and species B which are preyed upon by food limited predator species C Scientists observe an increase in the abundance of species A and a decline in the abundance of species B In an apparent competition model this relationship is found to be mediated through predator C a population explosion of species A increases the abundance of predator species C due to a greater total food source Since there are now more predators species A and B would be hunted at higher rates than before Thus the success of species A was to the detriment of species B not because they competed for resources but because their increased numbers had indirect effects on the predator population This one predator two prey model has been explored by ecologists as early as 1925 but the term apparent competition was first coined by University of Florida ecologist Robert D Holt in 1977 13 14 Holt found that field ecologists at the time were erroneously attributing negative interactions among prey species to niche partitioning and competitive exclusion ignoring the role of food limited predators 13 Apparent competition and realized niche edit Apparent competition can help shape a species realized niche or the area or resources the species can actually persist due to interspecific interactions The effect on realized niches could be incredibly strong especially when there is an absence of more traditional interference or exploitative competition A real world example was studied in the late 1960s when the introduction of snowshoe hares Lepus americanus to Newfoundland reduced the habitat range of native arctic hares Lepus arcticus While some ecologists hypothesized that this was due to an overlap in the niche other ecologists argued that the more plausible mechanism was that snowshoe hare populations led to an explosion in food limited lynx populations a shared predator of both prey species Since the arctic hare has a relatively weaker defense tactic than the snowshoe hare they were excluded from woodland areas on the basis of differential predation However both apparent competition and exploitation competition might help explain the situation to some degree 13 Support for the impact of competition on the breadth of the realized niche with respect to diet is becoming more common in a variety of systems based upon isotopic and spatial data including both carnivores 15 and small mammals 16 Asymmetric apparent competition edit Apparent competition can be symmetric or asymmetric 17 Symmetric apparent competition negatively impacts both species equally from which it can be inferred that both species will persist However asymmetric apparent competition occurs when one species is affected less than the other The most extreme scenario of asymmetric apparent competition is when one species is not affected at all by the increase in the predator which can be seen as a form of amensalism 0 18 Human impacts on endangered prey species have been characterized by conservation scientists as an extreme form of asymmetric apparent competition often through introducing predator species into ecosystems or resource subsidies An example of fully asymmetric apparent competition which often occurs near urban centers is subsidies in the form of human garbage or waste In the early 2000s the common raven Corvus corax population in the Mojave Desert increased due to an influx of human garbage leading to an indirect negative effect on juvenile desert tortoises Gopherus agassizii 19 Asymmetry in apparent competition can also arise as a consequence of resource competition An empirical example is provided by two small fish species in postglacial lakes in Western Canada where resource competition between prickly sculpin and threespine stickleback fish leads to a spatial niche shift mainly in threespine stickleback 20 As a consequence of this shift predation by a shared trout predator increases for stickleback but decreases for sculpin in lakes where the two species co occur compared to lakes in which each species occurs on its own together with trout predators Because sharing predators often comes together with competition for shared food resources apparent competition and resource competition may often interplay in nature 21 Apparent competition in the human microbiome edit Apparent competition has also been viewed in and on the human body The human immune system can acts as the generalist predator and a high abundance of a certain bacteria may induce an immune response damaging all pathogens in the body Another example of this is of two populations of bacteria that can both support a predatory bacteriophage In most situations the one that is most resistant to infection by the shared predator will replace the other 17 Apparent competition has also been suggested as an exploitable phenomenon for cancer treatments Highly specialized viruses that are developed to target malignant cancer cells often go locally extinct prior to eradicating all cancer However if a virus were developed that targets both healthy and unhealthy host cells to some degree the large number of healthy cells would support the predatory virus for long enough to eliminate all malignant cells 17 Size asymmetric competition editMain article Size asymmetric competition Competition can be either complete symmetric all individuals receive the same amount of resources irrespective of their size perfectly size symmetric all individuals exploit the same amount of resource per unit biomass or absolutely size asymmetric the largest individuals exploit all the available resource Among plants size asymmetry is context dependent and competition can be both asymmetric and symmetric depending on the most limiting resource In forest stands below ground competition for nutrients and water is size symmetric because a tree s root system is typically proportionate to the biomass of the entire tree 22 Conversely above ground competition for light is size asymmetric since light has directionality the forest canopy is dominated entirely by the largest trees These trees disproportionately exploit most of the resource for their biomass making the interaction size asymmetric 23 Whether above ground or below ground resources are more limiting can have major effects on the structure and diversity of ecological communities in mixed beech stands for example size asymmetric competition for light is a stronger predictor of growth compared with competition for soil resources 24 Within and between species editSee also Female intrasexual competition nbsp Sea anemones compete for the territory in tide poolsCompetition can occur between individuals of the same species called intraspecific competition or between different species called interspecific competition Studies show that intraspecific competition can regulate population dynamics changes in population size over time This occurs because individuals become crowded as the population grows Since individuals within a population require the same resources crowding causes resources to become more limited Some individuals typically small juveniles eventually do not acquire enough resources and die or do not reproduce This reduces population size and slows population growth citation needed Species also interact with other species that require the same resources Consequently interspecific competition can alter the sizes of many species populations at the same time Experiments demonstrate that when species compete for a limited resource one species eventually drives the populations of other species extinct These experiments suggest that competing species cannot coexist they cannot live together in the same area because the best competitor will exclude all other competing species citation needed Intraspecific edit Main article Intraspecific competition Intraspecific competition occurs when members of the same species compete for the same resources in an ecosystem 25 A simple example is a stand of equally spaced plants which are all of the same age The higher the density of plants the more plants will be present per unit ground area and the stronger the competition will be for resources such as light water or nutrients Interspecific edit Main article Interspecific competition Interspecific competition may occur when individuals of two separate species share a limiting resource in the same area If the resource cannot support both populations then lowered fecundity growth or survival may result in at least one species Interspecific competition has the potential to alter populations communities and the evolution of interacting species An example among animals could be the case of cheetahs and lions since both species feed on similar prey they are negatively impacted by the presence of the other because they will have less food however they still persist together despite the prediction that under competition one will displace the other In fact lions sometimes steal prey items killed by cheetahs Potential competitors can also kill each other in so called intraguild predation For example in southern California coyotes often kill and eat gray foxes and bobcats all three carnivores sharing the same stable prey small mammals 26 An example among protozoa involves Paramecium aurelia and Paramecium caudatum Russian ecologist Georgy Gause studied the competition between the two species of Paramecium that occurred as a result of their coexistence Through his studies Gause proposed the Competitive exclusion principle observing the competition that occurred when their different ecological niches overlapped 27 Competition has been observed between individuals populations and species but there is little evidence that competition has been the driving force in the evolution of large groups For example mammals lived beside reptiles for many millions of years of time but were unable to gain a competitive edge until dinosaurs were devastated by the Cretaceous Paleogene extinction event 4 Evolutionary strategies editMain articles r K selection theory and Verhulst equation In evolutionary contexts competition is related to the concept of r K selection theory which relates to the selection of traits which promote success in particular environments The theory originates from work on island biogeography by the ecologists Robert MacArthur and E O Wilson 28 In r K selection theory selective pressures are hypothesized to drive evolution in one of two stereotyped directions r or K selection 29 These terms r and K are derived from standard ecological algebra as illustrated in the simple Verhulst equation of population dynamics 30 d N d t r N 1 N K displaystyle frac dN dt rN left 1 frac N K right qquad nbsp where r is the growth rate of the population N and K is the carrying capacity of its local environmental setting Typically r selected species exploit empty niches and produce many offspring each of whom has a relatively low probability of surviving to adulthood In contrast K selected species are strong competitors in crowded niches and invest more heavily in much fewer offspring each with a relatively high probability of surviving to adulthood 30 Competitive exclusion principle edit nbsp 1 a smaller yellow species of bird forages across whole tree 2 a larger red species competes for resources 3 red dominates in middle for the more abundant resources Yellow adapts to a new niches avoiding competition Main article Competitive exclusion principle To explain how species coexist in 1934 Georgii Gause proposed the competitive exclusion principle which is also called the Gause principle species cannot coexist if they have the same ecological niche The word niche refers to a species requirements for survival and reproduction These requirements include both resources like food and proper habitat conditions like temperature or pH Gause reasoned that if two species had identical niches required identical resources and habitats they would attempt to live in exactly the same area and would compete for exactly the same resources If this happened the species that was the best competitor would always exclude its competitors from that area Therefore species must at least have slightly different niches in order to coexist 31 32 Character displacement edit nbsp Medium ground finch Geospiza fortis on Santa Cruz Island in the GalapagosMain article Character displacement Competition can cause species to evolve differences in traits This occurs because the individuals of a species with traits similar to competing species always experience strong interspecific competition These individuals have less reproduction and survival than individuals with traits that differ from their competitors Consequently they will not contribute many offspring to future generations For example Darwin s finches can be found alone or together on the Galapagos Islands Both species populations actually have more individuals with intermediate sized beaks when they live on islands without the other species present However when both species are present on the same island competition is intense between individuals that have intermediate sized beaks of both species because they all require intermediate sized seeds Consequently individuals with small and large beaks have greater survival and reproduction on these islands than individuals with intermediate sized beaks Different finch species can coexist if they have traits for instance beak size that allow them to specialize in particular resources When Geospiza fortis and Geospiza fuliginosa are present on the same island G fuliginosa tends to evolve a small beak and G fortis a large beak The observation that competing species traits are more different when they live in the same area than when competing species live in different areas is called character displacement For the two finch species beak size was displaced Beaks became smaller in one species and larger in the other species Studies of character displacement are important because they provide evidence that competition is important in determining ecological and evolutionary patterns in nature 33 See also editBiological interaction Character displacement Community Minimum viable population Scramble competition Resource biology Resource partitioningReferences edit Begon M Harper J L Townsend C R 1996 Ecology Individuals populations and communities Blackwell Science Competition globalchange umich edu Retrieved 2021 12 08 a b c Species Interactions and Competition Learn Science at Scitable www nature com Retrieved 2021 12 08 a b Sahney Sarda Benton Michael J Ferry Paul A 2010 08 23 Links between global taxonomic diversity ecological diversity and the expansion of vertebrates on land Biology Letters 6 4 544 547 doi 10 1098 rsbl 2009 1024 PMC 2936204 PMID 20106856 Barton Kasey E Sanders Nathan J Gordon Deborah M 2002 10 01 The Effects of Proximity and Colony Age on Interspecific Interference Competition between the Desert Ants Pogonomyrmex barbatus and Aphaenogaster cockerelli The American Midland Naturalist 148 2 376 382 doi 10 1674 0003 0031 2002 148 0376 TEOPAC 2 0 CO 2 ISSN 0003 0031 S2CID 7668877 Borgia Gerald 1985 Bower Destruction and Sexual Competition in the Satin Bowerbird Ptilonorhynchus violaceus Behavioral Ecology and Sociobiology 18 2 91 100 doi 10 1007 BF00299037 ISSN 0340 5443 JSTOR 4599867 S2CID 36871646 a b c d Le Bourlot Vincent Tully Thomas Claessen David 2014 11 01 Interference versus Exploitative Competition in the Regulation of Size Structured Populations The American Naturalist 184 5 609 623 doi 10 1086 678083 ISSN 0003 0147 PMID 25325745 S2CID 206002300 a b Schenk H Jochen 2006 03 24 Root competition beyond resource depletion Root competition beyond resource depletion Journal of Ecology 94 4 725 739 doi 10 1111 j 1365 2745 2006 01124 x S2CID 86320966 Case Ted J Gilpin Michael E August 1974 Interference Competition and Niche Theory Proceedings of the National Academy of Sciences of the United States of America 71 8 3073 3077 Bibcode 1974PNAS 71 3073C doi 10 1073 pnas 71 8 3073 ISSN 0027 8424 PMC 388623 PMID 4528606 Stone David B Martin James A Cohen Bradley S Prebyl Thomas J Killmaster Charlie Miller Karl V 2018 07 06 Intraspecific temporal resource partitioning at white tailed deer feeding sites Current Zoology 65 2 139 146 doi 10 1093 cz zoy051 ISSN 2396 9814 PMC 6430969 PMID 30936902 Jensen A L 1987 02 01 Simple models for exploitative and interference competition Ecological Modelling 35 1 113 121 Bibcode 1987EcMod 35 113J doi 10 1016 0304 3800 87 90093 7 hdl 2027 42 26823 ISSN 0304 3800 Bhuyain Mohammad Mosharof Hossain Lim Un Taek 2019 06 14 Interference and Exploitation Competition between Frankliniella occidentalis and F intonsa Thysanoptera Thripidae in Laboratory Assays Florida Entomologist 102 2 322 328 doi 10 1653 024 102 0206 ISSN 0015 4040 S2CID 196662034 a b c d Holt Robert D 1977 10 01 Predation apparent competition and the structure of prey communities Theoretical Population Biology 12 2 197 229 doi 10 1016 0040 5809 77 90042 9 ISSN 0040 5809 PMID 929457 Schreiber Sebastian J Krivan Vlastimil 2020 06 01 Holt 1977 and apparent competition Theoretical Population Biology Fifty years of Theoretical Population Biology 133 17 18 doi 10 1016 j tpb 2019 09 006 ISSN 0040 5809 PMID 31711965 S2CID 207952477 Fowler N L Petroelje T R Kautz T M Svoboda N J Duquette J F Kellner K F Beyer D E Belant J J 2022 Variable effects of wolves on niche breadth and density of intraguild competitors Ecology and Evolution 12 2 e8542 Bibcode 2022EcoEv 12E8542F doi 10 1002 ece3 8542 PMC 8829107 PMID 35154647 Allen A G Roehrs Z P Seville R S Lanier H C 2022 Competitive release during fire succession influences ecological turnover in a small mammal community Ecology 103 8 1 12 Bibcode 2022Ecol 103E3733A doi 10 1002 ecy 3733 PMC 9891167 PMID 35430726 a b c Holt Robert D Bonsall Michael B 2017 11 02 Apparent Competition Annual Review of Ecology Evolution and Systematics 48 1 447 471 doi 10 1146 annurev ecolsys 110316 022628 ISSN 1543 592X Chaneton Enrique J Bonsall Michael B 2000 Enemy Mediated Apparent Competition Empirical Patterns and the Evidence Oikos 88 2 380 394 Bibcode 2000Oikos 88 380C doi 10 1034 j 1600 0706 2000 880217 x ISSN 0030 1299 JSTOR 3547034 DeCesare N J Hebblewhite M Robinson H S Musiani M 2010 Endangered apparently the role of apparent competition in endangered species conservation Animal Conservation 13 4 353 362 Bibcode 2010AnCon 13 353D doi 10 1111 j 1469 1795 2009 00328 x ISSN 1469 1795 S2CID 83416826 Roesti M Groh J S Blain S A Huss M Rassias P amp Bolnick D I et al 2023 Species divergence under competition and shared predation Ecology Letters 26 111 123 Available from https doi org 10 1111 ele 14138 Roesti M Groh J S Blain S A Huss M Rassias P amp Bolnick D I et al 2023 Species divergence under competition and shared predation Ecology Letters 26 111 123 Available from https doi org 10 1111 ele 14138 West P W Ratkowsky D A 2021 10 04 Problems with models assessing influences of tree size and inter tree competitive processes on individual tree growth a cautionary tale Journal of Forestry Research 33 2 565 577 doi 10 1007 s11676 021 01395 9 ISSN 1993 0607 S2CID 244202914 Pretzsch Hans Biber Peter 2010 02 15 Size symmetric versus the size asymmetric competition and growth partitioning among trees in forest stands along an ecological gradient in central Europe Canadian Journal of Forest Research 40 2 370 384 doi 10 1139 x09 195 ISSN 0045 5067 del Rio Miren Condes Sonia Pretzsch Hans 2014 08 01 Analyzing size symmetric vs size asymmetric and intra vs inter specific competition in beech Fagus sylvatica L mixed stands Forest Ecology and Management 325 90 98 doi 10 1016 j foreco 2014 03 047 Townsend Colin R Begon Michael 2008 Essentials of Ecology pp 103 105 ISBN 978 1 4051 5658 5 Fedriani J M T K Fuller R M Sauvajot and E C York 2000 Competition and intraguild predation among three sympatric carnivores Oecologia 125 258 270 Gause G F 1934 The struggle for existence Baltimore MD Williams amp Wilkins MacArthur R and Wilson E O 1967 The Theory of Island Biogeography Princeton University Press 2001 reprint ISBN 0 691 08836 5 Pianka E R 1970 On r and K selection American Naturalist 104 592 597 a b Verhulst P F 1838 Notice sur la loi que la population pursuit dans son accroissement Corresp Math Phys 10 113 121 Hardin Garrett 1960 The competitive exclusion principle PDF Science 131 3409 1292 1297 Bibcode 1960Sci 131 1292H doi 10 1126 science 131 3409 1292 PMID 14399717 Archived from the original PDF on 2017 11 17 Retrieved 2017 01 10 Pocheville Arnaud 2015 The Ecological Niche History and Recent Controversies In Heams Thomas Huneman Philippe Lecointre Guillaume et al eds Handbook of Evolutionary Thinking in the Sciences Dordrecht Springer pp 547 586 ISBN 978 94 017 9014 7 Brown W L and E O Wilson 1956 Character displacement Systematic Zoology 5 49 65 External links edithttp www encyclopedia com topic Competition 28Biology 29 aspx The Biological Basis for the Thrill of Victory Retrieved from https en wikipedia org w index php title Competition biology amp oldid 1214123626, wikipedia, wiki, book, books, library,

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