Arboreality drives heat tolerance while elevation drives cold tolerance in tropical rainforest ants

Leahy, Lily; Scheffers, Brett R.; Williams, Stephen E.; Andersen, Alan N.

doi:10.1002/ecy.3549

Cited by 25 publications

(31 citation statements)

References 49 publications

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“…Our analyses highlight that habitats impose local variability in maximum peak temperature and heat tolerance, not influencing minimum temperature or cold tolerance. This similar contrasting pattern appears in other terrestrial ectotherms (Frishkoff et al 2015, Kaspari et al 2015, Nowakowski et al 2017, Pintanel et al 2019, Anderson et al 2022, Leahy et al 2022. The divergence on the variation of extreme environmental temperatures (i.e.…”

Section: Discussionsupporting

confidence: 69%

Elevational and local climate variability predicts thermal breadth of mountain tropical tadpoles

et al. 2022

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The climate variability hypothesis posits that increased environmental thermal variation should select for thermal generalists, while stable environments should favor thermal specialists. This hypothesis has been tested on large spatial scales, such as latitude and elevation, but less so on smaller scales reflective of the experienced microclimate. Here, we estimated thermal tolerance limits of 75 species of amphibian tadpoles from an aseasonal tropical mountain range of the Ecuadorian Andes, distributed along a 3500 m elevational range, to test the climatic variability hypothesis at a large (elevation) and a small (microhabitat) scale. We show how species from less variable thermal habitats, such as lowlands and those restricted to streams, exhibit narrower thermal tolerance breadths than highland and pond‐dwelling species respectively. Interestingly, while broader thermal tolerance breadths at large scales are driven by higher cold tolerance variation (heat‐invariant hypothesis), at local scales they are driven by higher heat tolerance variation. This contrasting pattern may result from divergent selection on both thermal limits to face environmental thermal extremes at different scales. Specifically, within the same elevational window, exposure to extreme maximum temperatures could be avoided through habitat shifts from temporary ponds to permanent ponds or streams, while minimum peak temperatures remained invariable between habitats but steadily decreased with elevation. Therefore an understanding of the effects of habitat conversion is crucial for future research on resilience to climate change.

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Section: Discussionsupporting

confidence: 69%

Elevational and local climate variability predicts thermal breadth of mountain tropical tadpoles

et al. 2022

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“…Distributional records are the focus of the Global Ant Biodiversity Informatics (GABI) Project (Guenard et al, 2017). Genomes are being collated through Fourmidable (Wurm et al, 2009) (Diamond et al, 2012;Leahy et al, 2021;Penick et al, 2017;Roeder et al, 2021); dietary traits, such as nitrogen stable isotope composition, have been used extensively in recent studies that explore the position of ants on a spectrum from herbivores to predators (Davidson, 2005;Davidson et al, 2003;Gibb & Cunningham, 2013); and key life-history traits such as colony size, have featured in studies that cover a broad range of species (e.g. Burchill & Moreau, 2016;Kaspari & Vargo, 1995).…”

Section: Current Data Strengths and Opportunitiesmentioning

confidence: 99%

Ecological strategies of (pl)ants: Towards a world‐wide worker economic spectrum for ants

et al. 2022

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1. Current global challenges call for a rigorously predictive ecology. Our understanding of ecological strategies, imputed through suites of measurable functional traits, comes from decades of work that largely focussed on plants.However, a key question is whether plant ecological strategies resemble those of other organisms.2. Among animals, ants have long been recognised to possess similarities with plants: as (largely) central place foragers. For example, individual ant workers play similar foraging roles to plant leaves and roots and are similarly expendable. Frameworks that aim to understand plant ecological strategies through key functional traits, such as the 'leaf economics spectrum', offer the potential for significant parallels with ant ecological strategies.3. Here, we explore these parallels across several proposed ecological strategy dimensions, including an 'economic spectrum', propagule size-number tradeoffs, apparency-defence trade-offs, resource acquisition trade-offs and stresstolerance trade-offs. We also highlight where ecological strategies may differ between plants and ants. Furthermore, we consider how these strategies play out among the different modules of eusocial organisms, where selective forces act on the worker and reproductive castes, as well as the colony.4. Finally, we suggest future directions for ecological strategy research, including highlighting the availability of data and traits that may be more difficult to measure, but should receive more attention in future to better understand the ecological strategies of ants. The unique biology of eusocial organisms provides an unrivalled opportunity to bridge the gap in our understanding of ecological

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“…This is especially so in hotter microenvironments such as forest canopy in ants (Leahy et al. 2022) or in open sunlit temporary ponds in aquatic subtropical amphibian tadpoles (Duarte et al. 2012; Sanabria et al.…”

Section: Discussionmentioning

confidence: 99%

“…However, their warming tolerance is low, in agreement with current evidence showing that upper tolerances in ectotherms from low latitudes are close to the current maximal experienced temperatures. This is especially so in hotter microenvironments such as forest canopy in ants (Leahy et al 2022) or in open sunlit temporary ponds in aquatic subtropical amphibian tadpoles (Duarte et al 2012;Sanabria et al 2021). Recently, Campos et al (2021) have reported decreased warming tolerances for low-latitude South American freshwater fishes that would be at high risk of suffering heat impacts.…”

Section: Discussionmentioning

confidence: 99%

Upper thermal tolerances and vulnerability to global warming in a Brazilian Caatinga fishAstyanax bimaculatus (Linnaeus, 1758) population

et al. 2022

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Global warming is predicted to increase both average temperatures and the frequency and duration of heat waves. Tropical ectotherms, particularly those living in warm environments are more prone to receive heat impacts. Then, it is crucial to identify those populations already exposed to high temperatures that may be at risk of decimation by ongoing warming. We assessed heating risk in a population of the fish species Astyanax bimaculatus, inhabiting hot pools in intermittent streams in the Brazilian Caatinga ecoregion. We experimentally examined the upper thermal tolerance (CT max ), and provided estimates of warming tolerance (WT), as the difference between CT max and micro-environmental peak temperatures (T max ). Two CT max estimates ranged between 37.6 and 40.6°C, whereas pond T max ranged between 34.6 and 41.3°C. This determines very narrow, even negative WTs, for these extreme heated A. bimaculatus populations, which ultimately may determine their local extinction in the coming decades. Abstract in Portuguese is available with online material.Prevê-se que o aquecimento global aumente tanto as temperaturas m edias como a frequência e durac ßão das ondas de calor. Ectot ermicos tropicais, principalmente aqueles que habitam ambientes temperados, estão mais expostos a impactos t ermicos. Portanto, identificar populac ßões que j a estão expostas a temperaturas altas o suficiente para serem ameac ßadas pelo aquecimento atual e crucial. O risco de exposic ßão a altas temperaturas foi estabelecido na esp ecie de peixe Astyanax bimaculatus, que habita poc ßas quentes nos rios intermitentes presentes na ecorregião conhecida como Caatinga. A tolerância t ermica superior (CT max ) foi aferida experimentalmente e apresentamos medidas de tolerância t ermica (WT), definida como a diferenc ßa entre a CT max e as temperaturas m aximas registradas na escala microambiental (T max ). Duas estimativas de CT max ficaram entre 37,6°C e 40,6°C, enquanto o T max das poc ßas variou entre 34,6°C e 41,3°C. Isso determina valores muito estreitos, e at e mesmo negativos, de WTs para a populac ßão de A. bimaculatus estudada, o que pode vir a determinar sua extinc ßão em d ecadas futuras.

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Arboreality drives heat tolerance while elevation drives cold tolerance in tropical rainforest ants

Cited by 25 publications

References 49 publications

Elevational and local climate variability predicts thermal breadth of mountain tropical tadpoles

Elevational and local climate variability predicts thermal breadth of mountain tropical tadpoles

Ecological strategies of (pl)ants: Towards a world‐wide worker economic spectrum for ants

Upper thermal tolerances and vulnerability to global warming in a Brazilian Caatinga fishAstyanax bimaculatus (Linnaeus, 1758) population

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