000			02120 am a22002293u 4500
042			_adc
100	1	0	_aSynodinos, Alexis D. _eauthor _92127
700	1	0	_aHaegeman, Bart _eauthor _92128
700	1	0	_aSentis, Arnaud _eauthor _92129
700	1	0	_aMontoya, José M. _eauthor _92130
245	0	0	_aTheory of temperature-dependent consumer-resource interactions
260			_c2021-08-01.
500			_a/pmc/articles/PMC7614043/
500			_a/pubmed/34120390
520			_aChanges in temperature affect consumer-resource interactions, which underpin the functioning of ecosystems. However, existing studies report contrasting predictions regarding the impacts of warming on biological rates and community dynamics. To improve prediction accuracy and comparability, we develop an approach that combines sensitivity analysis and aggregate parameters. The former determines which biological parameters impact the community most strongly. The use of aggregate parameters (i.e., maximal energetic efficiency, ρ, and interaction strength, κ), that combine multiple biological parameters, increases explanatory power and reduces the complexity of theoretical analyses. We illustrate the approach using empirically derived thermal dependence curves of biological rates and applying it to consumer-resource biomass ratio and community stability. Based on our analyses, we generate four predictions: (1) resource growth rate regulates biomass distributions at mild temperatures, (2) interaction strength alone determines the thermal boundaries of the community, (3) warming destabilises dynamics at low and mild temperatures only and (4) interactions strength must decrease faster than maximal energetic efficiency for warming to stabilise dynamics. We argue for the potential benefits of directly working with the aggregate parameters to increase the accuracy of predictions on warming impacts on food webs and promote cross-system comparisons.
540			_a
546			_aen
690			_aArticle
655	7		_aText _2local
786	0		_nEcol Lett
856	4	1	_uhttp://dx.doi.org/10.1111/ele.13780 _zConnect to this object online.
999			_c387 _d387