Heated communities: large inter- and intraspecific variation in heat tolerance across trophic levels of a soil arthropod community

Franken, Oscar; Huizinga, Milou; Ellers, Jacintha; Berg, Matty P.

doi:10.1007/s00442-017-4032-z

Cited by 52 publications

(48 citation statements)

References 86 publications

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“…CT max values ranged from 52 to 55°C on average. These values are likely comparable to the CT max of 51-52°C found for desert-dwelling spiders (Franken et al, 2018;van den Berg et al, 2015), which were measured under a slower ramping rate, and higher than species found in the Namib, assessed using a non-ramping method (Lubin and Henschel, 1990).…”

Section: Evidence For Brett's Rulesupporting

confidence: 77%

Low temperatures impact species distributions of jumping spiders across a desert elevational cline

Brandt

Roberts

Williams

et al. 2020

Journal of Insect Physiology

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Temperature is known to influence many aspects of organisms and is frequently linked to geographical species distributions. Despite the importance of a broad understanding of an animal's thermal biology, few studies incorporate more than one metric of thermal biology. Here we examined an elevational assemblage of Habronattus jumping spiders to measure different aspects of their thermal biology including thermal limits (CT min , CT max), thermal preference, VĊO 2 as proxy for metabolic rate, locomotor behavior and warming tolerance. We used these data to test whether thermal biology helped explain how species were distributed across elevation. Habronattus had high CT max values, which did not differ among species across the elevational gradient. The highest-elevation species had a lower CT min than any other species. All species had a strong thermal preference around 37°C. With respect to performance, one of the middle elevation species was significantly less temperature-sensitive in metabolic rate. Differences between species with respect to locomotion (jump distance) were likely driven by differences in mass, with no differences in thermal performance across elevation. We suggest that Habronattus distributions follow Brett's rule, a rule that predicts more geographical variation in cold tolerance than heat. Additionally, we suggest that physiological tolerances interact with biotic factors, particularly those related to courtship and mate choice to influence species distributions. Habronattus also had very high warming tolerance values (> 20°C, on average). Taken together, these data suggest that Habronattus are resilient in the face of climate-change related shifts in temperature.

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Section: Evidence For Brett's Rulesupporting

confidence: 77%

Low temperatures impact species distributions of jumping spiders across a desert elevational cline

Brandt

Roberts

Williams

et al. 2020

Journal of Insect Physiology

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“…juveniles and larvae) which by definition are not yet fully developed, both show improved heat tolerance with increasing body mass, contrasting with impaired heat tolerance in adults (Figure S9, electronic supplementary material). Along the same line, in a study looking at intraspecific variation in body mass, CTmax improved with body mass in juveniles of a spider species, but deteriorated with size of adults in species of Hemiptera and Collembola [38]. Thus, an oxygen-based mechanism could play a role in heat tolerance but appears to be more relevant for water-breathers and on longer timescales: i.e.…”

Section: Discussionmentioning

confidence: 99%

“…While studies to date hint at a possible size-dependence of thermal limits, no studies have tested this possibility comprehensively. In fact, most studies have focused on one or a few species and although these often find no effect of body mass when included as a covariate in analyses, thermal tolerance limits (heat tolerance rather than cold tolerance) are more frequently reported to decrease rather than increase with increasing body mass [35–38]. In an effort to address this knowledge gap regarding how body mass modulates the response to the temperature in ectotherms, we take advantage of the large body of literature and created a database of upper and lower thermal limits supplemented with biological information of 510 species.…”

Section: Introductionmentioning

confidence: 99%

Scaling of thermal tolerance with body mass and genome size in ectotherms: A comparison between water-and air-breathers

Leiva

Calosi

Verberk

2019

Preprint

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16Global warming appears to favour smaller-bodied organisms, but whether larger species are also 17 more vulnerable to thermal extremes, as suggested for past mass-extinction events, is still an 18 open question. Here, we tested whether interspecific differences in thermal tolerance (heat and 19 cold) of ectotherm organisms are linked to differences in their body mass and genome size (as a 20 proxy for cell size). Since the vulnerability of larger, aquatic taxa to warming has been attributed 21 to the oxygen limitation hypothesis, we also assessed how body mass and genome size modulate 22 thermal tolerance in species with contrasting breathing modes, habitats and life-stages. A 23 database with the upper (CTmax) and lower (CTmin) critical thermal limits and their 24 methodological aspects was assembled comprising more than 500 species of ectotherms. Our 25 results demonstrate that thermal tolerance in ectotherms is dependent on body mass and genome 26 size and these relationships became especially evident in prolonged experimental trials where 27 energy efficiency gains importance. During long-term trials, CTmax was impaired in larger-28 bodied water-breathers, consistent with a role for oxygen limitation. Variation in CTmin was 29 mostly explained by the combined effects of body mass and genome size and it was enhanced in 30 larger-celled, air-breathing species during long-term trials, consistent with a role for 31 depolarization of cell membranes. Our results highlight the importance of accounting for 32 phylogeny and exposure duration. Especially when considering long-term trials, the observed 33 effects on thermal limits are more in line with the warming-induced reduction in body mass 34 observed during long-term rearing experiments. 36The capacity of organisms to take up and transform resources from their environment is a 37 key attribute governing growth, reproduction and subsequently affecting population dynamics, 38 community composition and ecosystem functioning [1,2]. Such capacity seems to be mainly 39 dictated by the species' body mass [3]. Macroecological and paleoecological data show spatial 40 (e.g. Bergmann's rule [4,5]) and temporal (Lilliput's effect [6]) variation in body mass, which 41 share a common point related to the environmental temperature: at warmer, tropical latitudes and 42 during the past mass extinctions, warming appears to select for smaller-bodied species [5,[7][8][9]. 43Body size reductions with warming appear to be stronger in aquatic taxa than in terrestrial taxa 44 [5]. In tandem with body size reductions, both aquatic and terrestrial species are shifting their 45 distribution towards cooler habitats and their phenology to earlier and hence, cooler conditions 46 [10,11]. One approach that has been taken to clarify the extent and variation in species 47 redistributions, and to determine which taxonomic groups are potentially more vulnerable to the 48 effects of climate change, is that of comparative studies that analyze thermal tolerance limits 49 (upper and lower) synthesized...

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“…A major challenge in soils is to track such phenological shifts of species in response to warming given the complexity of the soil habitat and a high density of species [33]. The indication of trophic mismatches in soils in response to climate warming thus mainly comes from studies that have shown differential responses among communities of different trophic levels of brown food webs [4,35,36], potentially also owing to interspecific variation in thermal tolerance between predators and prey communities [37]. These differences in responses are often measured in terms of microbial biomass and soil thermal tolerances Figure 1.…”

Section: Climate Change and Trophic Mismatches In Food Websmentioning

confidence: 99%

Climate warming and trophic mismatches in terrestrial ecosystems: the green–brown imbalance hypothesis

Thakur

2020

Biol. Lett.

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Anthropogenic climate change can give rise to trophic mismatches in food webs owing to differential responses of consumer and resource organisms. However, we know little about the community and ecosystem level consequences of trophic mismatches in food webs. Terrestrial food webs are broadly comprised of two types of food webs: green food webs aboveground and brown food webs belowground between which mass and energy flow mainly via plants. Here, I highlight that the extent of warming-induced trophic mismatches in green and brown food webs differ owing to a greater stasis in brown food webs, which could trigger an imbalance in mass and energy flow between the two food webs. I then discuss the consequences of green–brown imbalance on terrestrial ecosystems and propose research avenues that can help understand the relationships between food webs and ecosystem functions in a warmer world.

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Heated communities: large inter- and intraspecific variation in heat tolerance across trophic levels of a soil arthropod community

Cited by 52 publications

References 86 publications

Low temperatures impact species distributions of jumping spiders across a desert elevational cline

Low temperatures impact species distributions of jumping spiders across a desert elevational cline

Scaling of thermal tolerance with body mass and genome size in ectotherms: A comparison between water-and air-breathers

Climate warming and trophic mismatches in terrestrial ecosystems: the green–brown imbalance hypothesis

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