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:''For the [[anarchist]] sense of mutualism, see [[mutualism (economic theory)]]''.
:''For the [[anarchist]] sense of mutualism, see [[mutualism (economic theory)]]''.


In biology, '''mutualism''' is an [[Biological interaction|interaction]] between two or more [[species]] where both species derive benefit. Mutualisms can be lifelong interactions involving close physical and biochemical contact (known as [[symbiosis]]) such as those between trees and [[mycorrhiza]]l fungi; they can also be briefer, non-symbiotic interactions, such as those between [[flowering plant]]s and [[pollinator]]s. Mutualisms may also be obligatory or non-obligatory (facultative). For example, bacteria known as [[rhizobia]] can reproduce either in the soil or in (usually) mutualistic symbiosis with legume plants, sometimes resulting in a [[mutation]]. Mycorrhizal fungi, on the other hand, can be totally dependent on their plant hosts. [[Microbe]]s often band together for mutual benefit in [[biofilms]] to break down solid food sources as in [[rusticle]]s. The relationship between people and their [[pets]] is a non-obligatory mutualism for the human, and, depending on the animal, either obligatory or non-obligatory.
In biology, '''mutualism''' is an [[Biological interaction|interaction, special conection]] between two or more [[species]] where both species derive benefit. Mutualisms can be lifelong interactions involving close physical and biochemical contact (known as [[symbiosis]]) such as those between trees and [[mycorrhiza]]l fungi; they can also be briefer, non-symbiotic interactions, such as those between [[flowering plant]]s and [[pollinator]]s. Mutualisms may also be obligatory or non-obligatory (facultative). For example, bacteria known as [[rhizobia]] can reproduce either in the soil or in (usually) mutualistic symbiosis with legume plants, sometimes resulting in a [[mutation]]. Mycorrhizal fungi, on the other hand, can be totally dependent on their plant hosts. [[Microbe]]s often band together for mutual benefit in [[biofilms]] to break down solid food sources as in [[rusticle]]s. The relationship between people and their [[pets]] is a non-obligatory mutualism for the human, and, depending on the animal, either obligatory or non-obligatory.


The question how and why species might cooperate has received much attention from evolutionary biologists. One way to tackle this question is to look at an interaction between two individuals of these species, and estimate their costs and benefits from each kind of behaviour. Researchers have used the [[Prisoner's Dilemma]] known from [[Game Theory]], to model a situation with two possible strategies: 'cooperate' or 'defect' as one way to understand how cooperation might persist. In a one-time encounter, the safest strategy to use for each side would be to defect. However, cooperation might persist when the interacting organisms remember and react to previous behaviour of their partner in strategies such as 'Tit for Tat', where defecting or cooperating follows the behaviour of the partner in the last round. If the partner defected, I should defect and vice versa. This strategy could lead, in some systems to stable cooperation.
The question how and why species might cooperate has received much attention from evolutionary biologists. One way to tackle this question is to look at an interaction between two individuals of these species, and estimate their costs and benefits from each kind of behaviour. Researchers have used the [[Prisoner's Dilemma]] known from [[Game Theory]], to model a situation with two possible strategies: 'cooperate' or 'defect' as one way to understand how cooperation might persist. In a one-time encounter, the safest strategy to use for each side would be to defect. However, cooperation might persist when the interacting organisms remember and react to previous behaviour of their partner in strategies such as 'Tit for Tat', where defecting or cooperating follows the behaviour of the partner in the last round. If the partner defected, I should defect and vice versa. This strategy could lead, in some systems to stable cooperation.

Revision as of 16:56, 24 May 2006

For the anarchist sense of mutualism, see mutualism (economic theory).

In biology, mutualism is an interaction, special conection between two or more species where both species derive benefit. Mutualisms can be lifelong interactions involving close physical and biochemical contact (known as symbiosis) such as those between trees and mycorrhizal fungi; they can also be briefer, non-symbiotic interactions, such as those between flowering plants and pollinators. Mutualisms may also be obligatory or non-obligatory (facultative). For example, bacteria known as rhizobia can reproduce either in the soil or in (usually) mutualistic symbiosis with legume plants, sometimes resulting in a mutation. Mycorrhizal fungi, on the other hand, can be totally dependent on their plant hosts. Microbes often band together for mutual benefit in biofilms to break down solid food sources as in rusticles. The relationship between people and their pets is a non-obligatory mutualism for the human, and, depending on the animal, either obligatory or non-obligatory.

The question how and why species might cooperate has received much attention from evolutionary biologists. One way to tackle this question is to look at an interaction between two individuals of these species, and estimate their costs and benefits from each kind of behaviour. Researchers have used the Prisoner's Dilemma known from Game Theory, to model a situation with two possible strategies: 'cooperate' or 'defect' as one way to understand how cooperation might persist. In a one-time encounter, the safest strategy to use for each side would be to defect. However, cooperation might persist when the interacting organisms remember and react to previous behaviour of their partner in strategies such as 'Tit for Tat', where defecting or cooperating follows the behaviour of the partner in the last round. If the partner defected, I should defect and vice versa. This strategy could lead, in some systems to stable cooperation.

Other models trying to explain possible cooperation include 'biological marketing'. Here the decision whether and with whom to cooperate is based on comparison of the different potential partners who attempt to outbid each other with benefits they offer. The price of trade is determined by balance between supply and demand for the benefits exchanged.

In most models trying to explain mutualism, there usually is a place for 'cheaters' or 'exploiters'. These do not 'play along' and try maximizing their own net benefit by reducing the cost of the interaction from their side. That is, by avoiding to deliver their trade 'goods', the other partner is seeking. This could lead, in theory, to repeated exploitation by one species, which some call parasitism.

The question how and why species might cooperate has also been addressed by philosophers. Gilles Deleuze, for example, is interested in the way this questioned the conception of evolutionism and the notion of linear historical progress.

See also

References

  • Hoeksema, J.D. & E.M.Bruna. 2000. Pursuing the big questions about interspecific mutualism: a review of theoretical approaches.Oecologia 125:321-330
  • Noe, R. & P. Hammerstein. 1994. Biological markets: supply and demand determine the effect of partner choice in cooperation, mutualism and mating. Behav. Ecol. Sociobiol. 35:1-11