Density-dependent indirect effects: apparent mutualism and apparent competition coexist in a two-prey system

Long, W. Christopher; Gamelin, Emily F.; Johnson, Eric; Hines, Anson H.

doi:10.3354/meps09702

Cited by 32 publications

(24 citation statements)

References 52 publications

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“…Less diversity among these tertiary and secondary consumers can decrease competition within these trophic levels, ultimately decreasing the diversity of prey due to decreased apparent mutualisms (in line with the principle that “the predator/competitor of my predator is my friend”; Abrams , Abrams and Matsuda , Long et al. ). This decrease in prey diversity would finally serve to increase the competition between predators, decreasing the persistence of less competitive predator species (Kratina et al.…”

Section: Discussionmentioning

confidence: 90%

“…We argue that the inverse may be occurring on invaded islands: lower foliar (and leaf litter) nutrients will lead to lower abundance and nutrient content of primary consumers, which in turn leads to the decline of secondary and tertiary consumer diversity. Less diversity among these tertiary and secondary consumers can decrease competition within these trophic levels, ultimately decreasing the diversity of prey due to decreased apparent mutualisms (in line with the principle that "the predator/competitor of my predator is my friend"; Abrams 1987, Abrams and Matsuda 1996, Long et al 2012. This decrease in prey diversity would finally serve to increase the competition between predators, decreasing the persistence of less competitive predator species (Kratina et al 2007, Hammill et al 2015, and further decreasing the number of species the ecosystem can support.…”

Section: Discussionmentioning

confidence: 97%

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Invasive rodents have multiple indirect effects on seabird island invertebrate food web structure

Thoresen

Towns

Leuzinger

et al. 2017

Ecological Applications

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Burrowing seabirds that nest on islands transfer nutrients from the sea, disturb the soil through burrowing, damage tree foliage when landing, and thereby modify the surface litter. However, seabirds are in decline worldwide, as are their community- and ecosystem-level impacts, primarily due to invasive predatory mammals. The direct and indirect effects of seabird decline on communities and ecosystems are inherently complex. Here we employed network analysis, as a means of simplifying ecological complexity, to better understand the effects seabird loss may have on island invertebrate communities. Using data on leaf litter communities, we constructed invertebrate food webs for each of 18 offshore oceanic islands in northeastern New Zealand, nine of which have high seabird densities and nine of were invaded by rats. Ten network topological metrics (including entropy, generality, and vulnerability) were compared between rat-invaded and uninvaded (seabird-dominant) islands. We found that, on rat-invaded islands, the invertebrate food webs were smaller and less complex than on their seabird-dominated counterparts, which may be due to the suppression of seabird-derived nutrients and consequent effects on trophic cascades. This decreased complexity of food webs due to the presence of rats is indicative of lower ecosystem resistance via lower trophic redundancy. Our results show that rat effects on island ecosystems are manifested throughout entire food webs, and demonstrate how network analysis may be useful to assess ecosystem recovery status as these invaded islands are restored.

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Section: Discussionmentioning

confidence: 90%

Section: Discussionmentioning

confidence: 97%

Invasive rodents have multiple indirect effects on seabird island invertebrate food web structure

Thoresen

Towns

Leuzinger

et al. 2017

Ecological Applications

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“…As the densities of these prey decrease, the proportional mortality decreases, so the prey have a low-density refuge from predation. The functional response can be changed both qualitatively and quantitatively by changes in habitat (Lipcius and Hines 1986, Dittel et al 1995, Long et al 2012b, predator size and density (Mansour andLipcius 1991, Gonza´lez-Sua´rez et al 2011), the presence and density of alternative prey (Chesson 1989, Long et al 2012a, and the spatial arrangement of prey (Hines et al 2009, Long andHines 2012). Blue crabs have a type III FR toward M. balthica (Eggleston et al 1992, Taylor andEggleston 2000), but as hypoxia should decrease predator search time for M. balthica, we hypothesized that it may change the FR from a type III to a type I or II.…”

Section: Predation and Density Dependencementioning

confidence: 99%

Individual, population, and ecosystem effects of hypoxia on a dominant benthic bivalve in Chesapeake Bay

Long

Seitz

Brylawski

et al. 2014

Ecological Monographs

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Hypoxia is an environmental stressor that affects abundance, biomass, diversity, and ecosystem function of benthic assemblages worldwide, yet its collective impact at individual, population, and ecosystem levels has rarely been investigated. We examined the effects of hypoxia on the biomass-dominant clam, Macoma balthica, in the York and Rappahannock Rivers (Chesapeake Bay, USA). We (1) surveyed the M. balthica populations in both rivers in 2003 and 2004, (2) determined the effects of low dissolved oxygen (DO) on M. balthica fecundity in a laboratory experiment, and (3) employed a predator-exclusion field experiment to establish the effects of hypoxia and prey density on predation upon M. balthica. The resultant data were used to parameterize a matrix model, which was analyzed to define potential effects of hypoxia at the population level. In both rivers, hypoxia decreased individual clam growth and caused local extinction of populations. Hypoxia reduced egg production of M. balthica by 40% and increased protein investment per egg. In the predatorexclusion field experiment, hypoxia magnified predation rates threefold and altered the functional response of predators to M. balthica from a stabilizing type III functional response to a destabilizing type II functional response. In a density-independent matrix model, hypoxia resulted in coupled source-sink metapopulation dynamics, with hypoxic areas acting as blackhole sinks. Increases in the spatial and temporal extent of hypoxia caused the populations to decline toward extinction. In a second model that incorporated density dependence, under mild hypoxic conditions trophic transfer from M. balthica to predators increased, but at increased spatial or temporal extent of hypoxia trophic transfer decreased. The major decline in trophic transfer to predators under severe hypoxia resulted from diversion of M. balthica biomass into the microbial loop. Our model predicted that there are multiple stable states for M. balthica populations (high and very low densities), such that the saddle point (threshold at which the population switches from one state to the other) increased and resilience decreased with the spatial extent of hypoxia. We underscore how effects of a stressor at the individual level can combine to have substantial population and ecosystem-level effects.

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“…In contrast, our results indicate that one would almost always need to know the characteristics of the consumers and resources before being able to adequately describe feeding rates. Moreover, a given consumer's feeding rate could just as easily appear consistent with one model for a first resource and with a different model with regard to another (e.g., Long et al, 2012a) or, worse yet, somewhere in between (e.g., Lester & Harmsen, 2002). Clearly, more empirical work is needed to understand the biology that determines why any given consumer-resource-resource combination lands in one particular location along the spectra of process inter-dependencies, particularly in the context of predators that feed on more than just two prey species.…”

Section: Discussionmentioning

confidence: 86%

Hidden layers of density dependence in consumer feeding rates

Stouffer

Novák

2020

Preprint

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Functional responses relate a consumer's feeding rates to variation in its abiotic and biotic environment, providing insight into consumer behavior and fitness, and underpinning population and food-web dynamics. Despite their broad relevance and long-standing history, we show here that the types of density dependence found in classic resource- and consumer-dependent functional-response models equate to strong and often untenable assumptions about the independence of processes underlying feeding rates. We first demonstrate mathematically how to quantify non-independence between feeding and consumer interference and between feeding on multiple resources. We then analyze two large collections of functional-response datasets to show that non-independence is pervasive and borne out in previously-hidden forms of density dependence. Our results provide a new lens through which to view variation in consumer feeding rates and disentangle the biological underpinnings of species interactions in multi-species contexts.

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Density-dependent indirect effects: apparent mutualism and apparent competition coexist in a two-prey system

Cited by 32 publications

References 52 publications

Invasive rodents have multiple indirect effects on seabird island invertebrate food web structure

Invasive rodents have multiple indirect effects on seabird island invertebrate food web structure

Individual, population, and ecosystem effects of hypoxia on a dominant benthic bivalve in Chesapeake Bay

Hidden layers of density dependence in consumer feeding rates

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