Responses of arthropod populations to warming depend on latitude: evidence from urban heat islands

-S. He. 2017. On the controls of abundance for soil-dwelling organisms on the Tibetan Plateau. Ecosphere 8(7):e01901. 10. 1002/ecs2.1901 Abstract. After decades of research, we are starting to understand more about why the number of species varies from place to place on the planet. However, little is known about spatial variation in abundance, especially for soil-dwelling organisms. In this study, we aimed to disentangle the relative influences of climatic factors, soil properties, and plant diversity on the abundance of soil-dwelling invertebrates (i.e., nematodes and soil arthropods) at 48 alpine grassland sites on the Tibetan Plateau. We found that the abundance of these two groups of soil organisms was negatively correlated with soil pH and temperature seasonality, and was positively correlated with soil organic carbon (SOC), mean annual precipitation, and plant species richness; there was no effect of mean annual temperature or seasonality in precipitation on the abundance of nematodes or soil-dwelling arthropods. When we considered only the nematodes, we found that soil pH, mean annual precipitation, temperature seasonality, and SOC were the best predictors of abundance. However, plant species richness was the best predictor of the abundance of soil-dwelling arthropods. Different orders within the arthropods responded differently to the suite of factors we examined. Taken together, our results suggest that increases in temperature alone might not alter the abundances of soil organisms in these alpine grasslands. Instead, altered precipitation regimes and increases in intra-annual variation in temperature, changes in plant community diversity, and the resulting changes in soil characteristics (e.g., pH and organic carbon) could reshape soil communities in the Tibetan grassland ecosystems, and likely elsewhere on the planet.

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“…, Youngsteadt et al. ). From these abundances, we also estimated biomass (biomass C/m 2 of soil; Fierer et al.…”

Section: Methodsmentioning

confidence: 99%

On the controls of abundance for soil‐dwelling organisms on the Tibetan Plateau

et al. 2017

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“…Yet, surprisingly few studies looked at trait differentiation in response to urban heat islands, and we lack evidence whether these differences are genetic (reviewed in Chown & Duffy, ; Diamond, Dunn, Frank, Haddad, & Martin, ; but see Brans et al., ; Brans et al., ). Considering that the temperature difference between urban and rural areas fall frequently within the range of the expected temperature increases by 2,100 under IPCC () scenarios, adaptation to urban environments can inform on the impact of climate change on organisms (Chown & Duffy, ; Youngsteadt, Dale, Terando, Dunn, & Frank, ; Youngsteadt, Ernst, Dunn, & Frank, ).…”

Section: Introductionmentioning

confidence: 99%

Microgeographic differentiation in thermal performance curves between rural and urban populations of an aquatic insect

Tüzün

Beeck

Brans

et al. 2017

Evolutionary Applications

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The rapidly increasing rate of urbanization has a major impact on the ecology and evolution of species. While increased temperatures are a key aspect of urbanization (“urban heat islands”), we have very limited knowledge whether this generates differentiation in thermal responses between rural and urban populations. In a common garden experiment, we compared the thermal performance curves (TPCs) for growth rate and mortality in larvae of the damselfly Coenagrion puella from three urban and three rural populations. TPCs for growth rate shifted vertically, consistent with the faster–slower theoretical model whereby the cold‐adapted rural larvae grew faster than the warm‐adapted urban larvae across temperatures. In line with costs of rapid growth, rural larvae showed lower survival than urban larvae across temperatures. The relatively lower temperatures hence expected shorter growing seasons in rural populations compared to the populations in the urban heat islands likely impose stronger time constraints to reach a certain developmental stage before winter, thereby selecting for faster growth rates. In addition, higher predation rates at higher temperature may have contributed to the growth rate differences between urban and rural ponds. A faster–slower differentiation in TPCs may be a widespread pattern along the urbanization gradient. The observed microgeographic differentiation in TPCs supports the view that urbanization may drive life‐history evolution. Moreover, because of the urban heat island effect, urban environments have the potential to aid in developing predictions on the impact of climate change on rural populations.

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“…Insect thermal tolerance is an important factor mediating population range and dynamics, possibility of invasion, and response to global climate change (Addo-Bediako et al, 2000;J. L. Andersen et al, 2015;Bellard et al, 2013;Youngsteadt et al, 2017). As such, great efforts have been devoted to understanding the molecular, physiological, and evolutionary underpinnings of insect thermal tolerance (Andersen et al, 2017;Andersen et al, 2018;Findsen et al, 2016;Macmillan et al, 2014;Macmillan et al, 2015).…”

Section: Discussionmentioning

confidence: 99%

“…Thus, modeling an insect's current and future geographic range requires accurate measures of its thermal tolerance. The importance of understanding insect thermal tolerance has intensified in recent years as a result of global climate change and the rapid spread of invasive pest species (Bebber, Ramotowski, & Gurr, 2013;Bellard et al, 2013;Macmillan, Findsen, Pedersen, & Overgaard, 2014;Sakai et al, 2001;Youngsteadt, Ernst, Dunn, & Frank, 2017).…”

Section: Introductionmentioning

confidence: 99%

Cold stress results in sustained locomotor and behavioral deficits in Drosophila melanogaster

Garcia

Teets

2019

J Exp Zool Pt A

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Tolerance of climatic stressors is an important predictor of the current distribution of insect species, their potential to invade new environments, and their responses to rapid climate change. Cold stress causes acute injury to nerves and muscles, and here we tested the hypothesis that low temperature causes sublethal deficits in locomotor behaviors that are dependent on neuromuscular function. To do so, we applied a previously developed assay, the rapid iterative negative geotaxis (RING) assay, to investigate behavioral consequences of cold stress in Drosophila melanogaster. The RING assay allows for rapid assessment of negative geotaxis behavior by quantifying climbing height and willingness to climb after cold stress. We exposed flies to cold stress at 0°C and assessed the extent to which duration of cold stress, recovery time, and cold acclimation influenced climbing performance. There was a clear dose‐response relationship between cold exposure and performance deficits, with climbing height and willingness decreasing as cold exposure increased from 2 to 24 hr. Following cold exposure of an intermediate duration (12 hr), climbing height and willingness gradually improved as recovery time increased from 4 to 72 hr but flies never fully recovered. Finally, cold acclimation improved overall climbing height and willingness in both untreated and cold‐stressed flies but did not prevent a reduction in climbing performance. Thus, cold stress causes deficits in locomotor and behavior that are dependent on the dose of cold exposure and persist long after the stress subsides. These results likely have implications for the ecological and evolutionary responses of insect populations to thermally variable environments.

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Responses of arthropod populations to warming depend on latitude: evidence from urban heat islands

Cited by 70 publications

References 49 publications

On the controls of abundance for soil‐dwelling organisms on the Tibetan Plateau

On the controls of abundance for soil‐dwelling organisms on the Tibetan Plateau

Microgeographic differentiation in thermal performance curves between rural and urban populations of an aquatic insect

Cold stress results in sustained locomotor and behavioral deficits in Drosophila melanogaster

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