Mutualistic interactions are mutually beneficial species interactions. Plant-pollinator mutualisms are particularly important, and involve nearly 170,000 plant and 200,000 animal species.
Mutualistic interactions, or mutualisms, are ubiquitous in nature. This type of species interaction involves the exchange of goods or services between two species, called mutualist partners. By definition, each species involved in a mutualism must receive a benefit from the interaction, and that benefit usually comes at a cost (Bronstein 1994). However, mutualist partners do not necessarily receive equal benefits or incur equal costs. While the activities of each partner benefits the other species in some way, neither species behaves altruistically. Instead, each species pursues its own selfish interest, and any benefit incurred by the mutualist partner is an unintended consequence of the interaction. Darwin acknowledged that mutualistic interactions are not altruistic when he wrote in On the Origin of Species (1859), " . . . I do not believe that any animal in the world performs an action for the exclusive good of another of a distinct species, yet each species tries to take advantage of the instincts of others . . . "
Many different kinds of organisms are involved in mutualisms, so the types of goods and services that are exchanged are highly variable, as are the mechanisms by which the exchanges are made. For example, the mutualistic interactions between flowering plants and their animal pollinators (Figure 1) are very different from interactions between acacia trees and the ants that inhabit and protect them (Janzen 1966), or interactions between plant and fungal species that form mycorrhizae (van der Heijden and Horton 2009). The variable nature of mutualistic interactions has made it difficult to develop quantitative mathematical models that generalize all mutualisms. However, quantitative models have been developed for particular types of mutualisms (e.g., plant-pollinator interactions) (Mitchell et al. 2009).
This Bombus bee is foraging on the flowers of Dicentra cucullaria (L.) Bernh.; pollen is visible on the underside of the bee. (Courtesy of Julie Wittmer)
Plant-pollinator interactions are good examples of mutualistic interactions because nearly three-quarters of all extant flowering plants (angiosperms) receive pollination services from animals (National Research Council 2007). Animal pollination is considered the ancestral form of pollination in angiosperms (Hu et al. 2008), and the rapid diversification of flowering plants that occurred 90–130 million years ago has been attributed, in part, to pollination mutualisms (Crepet 2008). The majority of animal pollinators are insects; bees, butterflies, moths, flies, wasps, and beetles are the most common insect pollinators (National Research Council 2007). Many birds and bats are also important pollinator species. Plants always receive pollination services through the interaction, but the goods or services received by the animal pollinators vary. Most pollinators receive food in the form of pollen or nectar, but some bees also use waxes and resins from flowers to build their hives (Michener 2007), and male euglossine bees use volatile compounds from orchid flowers as "perfume" to attract mates (Zimmermann et al. 2006). Other insect species, such as yucca moths, lay their eggs within the yucca flowers they pollinate, and some, but not all, of the seeds produced are consumed by the developing moth larvae (Pellmyr 2003).
Pollination mutualisms have been of interest to biologists for over a century. Darwin addressed their potential importance in the process of natural selection when he wrote, " . . . I can understand how a flower and a bee might slowly become, either simultaneously or one after the other, modified and adapted in the most perfect manner to each other, by the continued preservation of individuals presenting mutual and slightly favourable deviations of structure" (Darwin 1859).
Classical pollination studies were primarily focused on the reproductive cycles of the plant species and, other than their importance as pollen vectors, pollinators were largely ignored. These studies usually took one of two approaches — they were either focused on the evolutionary consequences of pollination dynamics or on the ecological processes that resulted in pollination. Current research in pollination biology attempts to join ecological and evolutionary approaches as a way to understand evolutionary processes in the ecological contexts in which they occur; for example, how pollinator foraging behaviors affect plant fitness by determining plant mating systems (Mitchell et al. 2009).
While mutualisms are often characterized by the kinds of goods or services exchanged, there are several other ways to characterize these interactions: by the degree of dependency, whether the interaction is obligate or facultative; by the degree of specificity, whether the interaction occurs between species pairs or between groups of species; and by the degree of physical association, how physically close the mutualist partners are to one another. These three methods of characterization include intermediates. Regardless of which method is used, it is important to consider the perspective of each mutualist partner when characterizing the interaction.
A mutualism is obligate when one species relies completely on another species for goods or services. Yucca moths and yucca plants have a reciprocal obligate relationship- the plants cannot make seeds without the yucca moth, and the moth larvae only reach maturity if they eat developing yucca seeds (Pellmyr 2003). However, mutualist partners do not necessarily rely on each other equally. For example, many dioecious plant species rely completely on animal pollinators for reproductive success, so from the plant perspective, the interaction is obligate. However, the pollinator species that visit the flowers may or may not require pollen or nectar from that plant species in order to survive and reproduce, so from the pollinator perspective, the interaction could range from obligate to facultative. Similarly, most bees rely on floral resources for all their needs (nectar, pollen, waxes, etc.), so from the bee perspective, the interaction is obligate. However, most bee species can utilize resources from a number of flowering plants, so they do not necessarily have obligate relationships with individual plant species. In contrast, some hermaphroditic plant species are self-compatible and also capable of self-pollination, so they can make seeds whether or not their flowers are visited by pollinators. The mutualism is facultative from the perspective of these plants, although the quality of seeds produced through self-pollination is often reduced relative to the quality of seeds produced through outcross pollination (Barrett 2003), so these plants still benefit from mutualistic interactions with pollinators.
In this diagram of a pollination network, each circle represents an animal species and each square represents a plant species. The lines connecting circles with squares indicate pollination interactions between those species. Notice that some species have more mutualist partners than others (*).
The degree of specificity is another way to characterize a mutualism. Highly specific mutualisms that form exclusively between two species are rare (e.g., fig plants, fig wasps). Adult female fig wasps pollinate the flowers of fig plants while laying their eggs inside the specialized inflorescences of the plant. The eggs hatch and the wasp larvae consume some, but not all, of the fig seeds. There are nearly 700 species of fig plants, and in most cases each species is pollinated by only one or a few wasp species (Cook & Rasplus 2003). In contrast, most mutualisms are somewhat diffuse; each plant species is pollinated by multiple animal species, and each animal species pollinates multiple plant species. However, some species have many mutualist partners, such as honey bees (Apis mellifera), which are known to visit the flowers of hundreds of plant species, including cultivated and wild plants (National Research Council 2007), and white mangrove (Laguncularia racemosa), which receives floral visitors from at least 65 different insect species (Landry et al. 2005). Diffuse interactions are common in communities, and result in pollination networks comprised of many interacting plant and animal species (Figure 2).
Mutualisms can also be characterized based on the degree of physical association that occurs between the species. Most plant-pollinator interactions are exhabitational because pollinators live separately from the plants they interact with. However, some pollinators live inside the plants they pollinate for a portion of their lives, which is an inhabitational relationship. Fig wasps and fig plants (Cook & Rasplus 2003), and yucca moths and yucca plants (Pellmyr 2003), are good examples of this extremely rare relationship. Characterizations of the most exclusive mutualistic interactions are correlated, in that inhabitational relationships also tend to be highly specific and obligate. However, exhabitational relationships are not necessarily facultative or diffuse.
To determine whether or not an interaction is a mutualism, it is necessary to determine the benefit received by each mutualist partner. The details of the interaction are important because one partner could cheat the other, and if so, the interaction is not a mutualism. One common example of “cheating” occurs when an insect removes nectar from flowers without pollinating those flowers (Darwin 1859, Michener 2007). The insect consumes nectar, so this interaction is called nectivory, a specialized form of herbivory, and the insect is often referred to as a "nectar thief." Less frequently, animal pollinators are deceived by plants into providing pollination services. For example, some orchid species deceive their male wasp pollinators by producing flowers that look and smell like female wasps. The male wasps provide pollination services when they mistakenly try to mate with the wasp-like flowers (Gaskett et al. 2008). This interaction is a form of parasitism because the wasps expend energy (and sometimes sperm) while providing pollination services, but do not receive any benefits in return.
Pollination mutualisms can affect the outcomes of other kinds of species interactions. Consider a simple example, with two animal-pollinated plant species and one animal pollinator species (Figure 3). If the two plant species flower simultaneously, then they will compete with one another for pollination services. If the pollinator prefers one plant species over the other, then the preferred plant species has a competitive advantage over the second plant species. Both of the plant species have a mutualistic relationship with the pollinator, but the relative fidelity of each mutualism affects the outcome of the competitive interaction between the two plant species. Most communities include many more flowering plants and animal pollinators than are represented in this example, resulting in a network of mutualistic interactions between plants and pollinators. Current research has demonstrated the usefulness of pollination networks as a framework for asking questions about the ecological and evolutionary processes that lead to observed patterns of biodiversity (Bascompte & Jordano 2007, Vasquez et al. 2009).
Visual representation of two plants species (Plant species A and B) competing for pollination services from a pollinator species. Each plant has a mutualistic relationship with the pollinator (beneficial interactions are identified with (+) signs), but the pollinator's preference for Plant species A (demonstrated by thicker arrows) causes a negative indirect effect (-) on Plant species B due to competition for pollination services.