Use of size-based production and stable isotope analyses to predict trophic transfer efficiencies and predator-prey body mass ratios in food webs

Jennings, Simon; Warr, Karema J.; Mackinson, Steven

doi:10.3354/meps240011

Cited by 200 publications

(201 citation statements)

References 52 publications

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“…The potential explanatory power of this mode of systemic selection matches the consistent observations of a 1:2 species-richness ratio in host-parasite communities [19,42,43] and 1:3 richness ratios at adjacent trophic levels in multitrophic food webs [19,[44][45][46] (Figure 3).…”

Section: Limits Of Feasible Coexistencementioning

confidence: 70%

Selection on stability across ecological scales

Borrelli

Allesina

Amarasekare

et al. 2015

Trends in Ecology & Evolution

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Section: Limits Of Feasible Coexistencementioning

confidence: 70%

Selection on stability across ecological scales

Borrelli

Allesina

Amarasekare

et al. 2015

Trends in Ecology & Evolution

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“…Due to variability in species diet that generally changes during life history (e.g. Jennings et al 2002a) and the lack of dietary information for many fish species, the trophic position of a species is better characterized by a range of fractional TLs rather than a single value. Table 1.…”

Section: Trophic Spectramentioning

confidence: 99%

Trophic-level determinants of biomass accumulation in marine ecosystems

Pranovi¹,

Link²,

Fu³

et al. 2012

Mar. Ecol. Prog. Ser.

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Metrics representative of key ecosystem processes are required for monitoring and understanding system dynamics, as a function of ecosystem-based fisheries management (EBFM).Useful properties of such indicators should include the ability to capture the range of variation in ecosystem responses to a range of pressures, including anthropogenic (e.g. exploitation pressures) and environmental (e.g. climate pressures), as well as indirect effects (e.g. those related to food web processes). Examining modifications in ecological processes induced by structural changes, however, requires caution because of the inherent uncertainty, long feedback times, and highly nonlinear ecosystem responses to external perturbations. Yet trophodynamic indicators are able to capture important changes in marine ecosystem function as community structures have been altered. One promising family of such metrics explores the changing biomass accumulation in the middle trophic levels (TLs) of marine ecosystems. Here we compared cumulative biomass curves across TLs for a range of northern hemisphere temperate and boreal ecosystems. Our results confirm that sigmoidal patterns are consistent across different ecosystems and, on a broad scale, can be used to detect factors that most influence shifts in the cumulative biomass−TL curves. We conclude that the sigmoidal relationship of biomass accumulation curves over TLs could be another possible indicator useful for the implementation of EBFM.

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“…Ecogeochemical methods and techniques draw ecological information from the spatial distribution of elements and isotopes across time and space, and from biochemical processes that alter the relative concentrations of elements or isotopes compared with the surrounding environment. Ecogeochemical approaches, particularly stable isotope-based methods, are widely adopted in the study of modern animal ecology, and play a central role in reconstructions of food web structure and trophic niches [2,3], animal movements [4,5] and ecological nutrient flux [6]. Ecogeochemical approaches are particularly well suited to reconstructing behavioural and physiological traits; aspects of biodiversity that are otherwise difficult to infer from macrofossils.…”

Section: Introductionmentioning

confidence: 99%

Ecogeochemistry potential in deep time biodiversity illustrated using a modern deep-water case study

Trueman

Chung

Shores

2016

Phil. Trans. R. Soc. B

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One contribution of 11 to a theme issue 'The regulators of biodiversity in deep time'. The fossil record provides the only direct evidence of temporal trends in biodiversity over evolutionary timescales. Studies of biodiversity using the fossil record are, however, largely limited to discussions of taxonomic and/or morphological diversity. Behavioural and physiological traits that are likely to be under strong selection are largely obscured from the body fossil record. Similar problems exist in modern ecosystems where animals are difficult to access. In this review, we illustrate some of the common conceptual and methodological ground shared between those studying behavioural ecology in deep time and in inaccessible modern ecosystems. We discuss emerging ecogeochemical methods used to explore population connectivity and genetic drift, life-history traits and field metabolic rate and discuss some of the additional problems associated with applying these methods in deep time.

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Use of size-based production and stable isotope analyses to predict trophic transfer efficiencies and predator-prey body mass ratios in food webs

Cited by 200 publications

References 52 publications

Selection on stability across ecological scales

Selection on stability across ecological scales

Trophic-level determinants of biomass accumulation in marine ecosystems

Ecogeochemistry potential in deep time biodiversity illustrated using a modern deep-water case study

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