Abstract
Cave‐dwelling ectotherms, which have evolved for millions of years under stable thermal conditions, could be expected to have adjusted their physiological limits to the narrow range of temperatures they experience and to be highly vulnerable to global warming. However, most of the few existing studies on thermal tolerance in subterranean invertebrates highlight that despite the fact that they show lower heat tolerance than most surface‐dwelling species, their upper thermal limits are generally not adjusted to ambient temperature. The question remains to what extent this pattern is common across subterranean invertebrates. We studied basal heat tolerance and its plasticity in four species of distant arthropod groups (Coleoptera, Diplopoda, and Collembola) with different evolutionary histories but under similar selection pressures, as they have been exposed to the same constant environmental conditions for a long time. Adults were exposed at different temperatures for 1 week to determine upper lethal temperatures. Then, individuals from previous sublethal treatments were transferred to a higher temperature to determine acclimation capacity. Upper lethal temperatures of three of the studied species were similar to those reported for other subterranean species (between 20 and 25°C) and widely exceeded the cave temperature (13–14°C). The diplopod species showed the highest long‐term heat tolerance detected so far for a troglobiont (i.e., obligate subterranean) species (median lethal temperature after 7 days exposure: 28°C) and a positive acclimation response. Our results agree with previous studies showing that heat tolerance in subterranean species is not determined by environmental conditions. Thus, subterranean species, even those living under similar climatic conditions, might be differently affected by global warming.
Highlights
According to Janzen's mountain passes hypothesis (Janzen, 1967) and the climatic variability hypothesis (Stevens, 1989), a posi‐ tive relationship exists between the thermal tolerance breadth and the level of climatic variability experienced by taxa, which has been demonstrated at different taxonomic resolutions (e.g., Addo‐Bediako, Chown, & Gaston, 2000; Calosi, Bilton, & Spicer, 2007; Cruz, Fitzgerald, Espinoza, & Schulte, 2005; Kellermann, Heerwaarden, Sgrò, & Hoffmann, 2009; Sunday, Bates, & Dulvy, 2011)
Subterranean species are generally assumed to be stenothermal, since thermal stability in these climatically buffered environments could impose a strong selective pressure on thermal tolerance traits (Angilletta, 2009; Culver & Pipan, 2009; Humphreys, 2018)
The four species studied here can survive, at least for 1 week, at temperatures much higher than the narrow range cur‐ rently experienced in their habitat
Summary
According to Janzen's mountain passes hypothesis (Janzen, 1967) and the climatic variability hypothesis (Stevens, 1989), a posi‐ tive relationship exists between the thermal tolerance breadth and the level of climatic variability experienced by taxa, which has been demonstrated at different taxonomic resolutions (e.g., Addo‐Bediako, Chown, & Gaston, 2000; Calosi, Bilton, & Spicer, 2007; Cruz, Fitzgerald, Espinoza, & Schulte, 2005; Kellermann, Heerwaarden, Sgrò, & Hoffmann, 2009; Sunday, Bates, & Dulvy, 2011). Some Antarctic cold‐stenothermal species (e.g., Clark, Fraser, Burns, & Peck, 2008; Clark Fraser & Peck, 2008; La Terza, Papa, Miceli, & Luporini, 2001; Rinehart et al, 2006; Somero, 2005) as well as warm stenothermal coral reef fishes (Kassahn et al, 2007; Nilsson, Östlund‐Nilsson, & Munday, 2010) have lost the ability to activate a heat shock response via the expression of heat shock proteins, which makes them especially vulnerable to global change (Kellermann & van Heerwaarden, 2019; Patarnello, Verde, Prisco, Bargelloni, & Zane, 2011; Somero, 2005) These questions remain poorly explored in other extremely thermally stable habitats, such as subterranean environments, some recent studies have found support for the climatic variability hypotheses for cave springtails (Raschmanová, Šustr, Kováč, Parimuchová, & Devetter, 2018) and spiders (Mammola, Piano, Malard, Vernon, & Isaia, 2019). We studied heat tolerance, accounting for both basal (upper lethal temperature—ULT) and induced tolerance (plasticity of ULTs via acclimation), through controlled laboratory experiments, in four distantly related arthropod species with different evolutionary origins that inhabit the same cave
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