Mutualism increases diversity, stability, and function of multiplex networks that integrate pollinators into food webs
Hale et al., 2020
Ecosystems are composed of complex networks of many species interacting in different ways. While ecologists have long studied food webs of feeding interactions, recent studies increasingly focus on mutualistic networks including plants that exchange food for reproductive services provided by animals such as pollinators. Here, we synthesize both types of consumer-resource interactions to better understand the controversial effects of mutualism on ecosystems at the species, guild, and whole-community levels. We find that consumer-resource mechanisms underlying plant-pollinator mutualisms can increase persistence, productivity, abundance, and temporal stability of both mutualists and non-mutualists in food webs. These effects strongly increase with floral reward productivity and are qualitatively robust to variation in the prevalence of mutualism and pollinators feeding upon resources in addition to rewards. This work advances the ability of mechanistic network theory to synthesize different types of interactions and illustrates how mutualism can enhance the diversity, stability, and function of complex ecosystems.
https://www.nature.com/articles/s41467-020-15688-w
.
Hale et al., 2020
Ecosystems are composed of complex networks of many species interacting in different ways. While ecologists have long studied food webs of feeding interactions, recent studies increasingly focus on mutualistic networks including plants that exchange food for reproductive services provided by animals such as pollinators. Here, we synthesize both types of consumer-resource interactions to better understand the controversial effects of mutualism on ecosystems at the species, guild, and whole-community levels. We find that consumer-resource mechanisms underlying plant-pollinator mutualisms can increase persistence, productivity, abundance, and temporal stability of both mutualists and non-mutualists in food webs. These effects strongly increase with floral reward productivity and are qualitatively robust to variation in the prevalence of mutualism and pollinators feeding upon resources in addition to rewards. This work advances the ability of mechanistic network theory to synthesize different types of interactions and illustrates how mutualism can enhance the diversity, stability, and function of complex ecosystems.
Interspecific and intraspecific mechanisms of feeding and reproduction
combine to describe pollination mutualisms and traditional trophic
interactions. Biomass of plants with pollinators is partitioned into two
pools, vegetation (purple node) and floral rewards (light purple node),
coupled by intraspecific dynamic feedbacks (dashed arrows). Rewards
production is proportional to vegetative biomass but subject to
self-limitation such that reward productivity per unit biomass decreases
with increasing rewards abundance. Producing rewards incurs costs
(reduced vegetative productivity), which creates tradeoffs between
producing rewards to attract pollinators and benefiting from the
quantity (number of visits measured as feeding rate on rewards) and
quality (conspecific feeding/total feeding) of pollinators’ reproductive
services (purple arrow) that are required for vegetative production. At
saturation, reproductive services allow plants with pollinators to
potentially achieve a 25% higher per-biomass growth rate than that of
plants without pollinators whose intrinsic growth rate is independent of
consumers’ behavior. All plants are also subjected to competition from
the plant community (not shown), which reduces per-biomass vegetative
growth rate close to carrying capacity. Gray arrows show herbivores
feeding on vegetation and pollinators feeding on rewards.
https://www.nature.com/articles/s41467-020-15688-w
.
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