Endothermy makes fishes faster but does not expand their thermal niche

The physiology and behaviour of fish are strongly affected by ambient water temperature. Physiological traits related to metabolism, such as aerobic scope (AS), can be measured across temperature gradients and the resulting performance curve reflects the thermal niche that fish can occupy. We measured AS of Westslope Cutthroat Trout (Oncorhynchus clarkii lewisi) at 5, 10, 15, 20, and 22°C and compared temperature preference (Tpref) of the species to non-native Brook Trout, Brown Trout, and Rainbow Trout. Intermittent-flow respirometry experiments demonstrated that metabolic performance of Westslope Cutthroat Trout was optimal at ~15 °C and decreased substantially beyond this temperature, until lethal temperatures at ~25 °C. Adjusted preferred temperatures across species (Tpref) were comparatively high, ranging from 17.8-19.9 °C, with the highest Tpref observed for Westslope Cutthroat Trout. Results suggest that although Westslope Cutthroat Trout is considered a cold-water species, they do not prefer or perform as well in cold water (≤ 10°C), thus, can occupy a warmer thermal niche than previously thought. The metabolic performance curve (AS) can be used to develop species‐specific thermal criteria to delineate important thermal habitats and guide conservation and recovery actions for Westslope Cutthroat Trout.

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Thermal niche conservatism in an environmental gradient in the spider Sicarius thomisoides (Araneae: Sicariidae): Implications for microhabitat selection

Journal of Thermal Biology ◽

10.1016/j.jtherbio.2018.10.018 ◽

2018 ◽

Vol 78 ◽

pp. 298-303 ◽

Cited By ~ 4

Author(s):

A. Taucare-Rios ◽

C. Veloso ◽

R.O. Bustamante

Keyword(s):

Environmental Gradient ◽

Niche Conservatism ◽

Microhabitat Selection ◽

Thermal Niche

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Do Differences in Latitudinal Distributions of Species and Organelle Haplotypes Reflect Thermal Reaction Norms Within the Emiliania/Gephyrocapsa Complex?

Frontiers in Marine Science ◽

10.3389/fmars.2021.785763 ◽

2021 ◽

Vol 8 ◽

Author(s):

Peter von Dassow ◽

Paula Valentina Muñoz Farías ◽

Sarah Pinon ◽

Esther Velasco-Senovilla ◽

Simon Anguita-Salinas

Keyword(s):

Local Adaptation ◽

Coastal Upwelling ◽

Environmental Gradients ◽

Reaction Norm ◽

Emiliania Huxleyi ◽

Thermal Reaction ◽

Reaction Norms ◽

Thermal Niche ◽

Significant Difference ◽

The Difference

The cosmopolitan phytoplankter Emiliania huxleyi contrasts with its closest relatives that are restricted to narrower latitudinal bands, making it interesting for exploring how alternative outcomes in phytoplankton range distributions arise. Mitochondrial and chloroplast haplogroups within E. huxleyi are shared with their closest relatives: Some E. huxleyi share organelle haplogroups with Gephyrocapsa parvula and G. ericsonii which inhabit lower latitudes, while other E. huxleyi share organelle haplogroups with G. muellerae, which inhabit high latitudes. We investigated whether the phylogeny of E. huxleyi organelles reflects environmental gradients, focusing on the Southeast Pacific where the different haplogroups and species co-occur. There was a high congruence between mitochondrial and chloroplast haplogroups within E. huxleyi. Haplogroup II of E. huxleyi is negatively associated with cooler less saline waters, compared to haplogroup I, both when analyzed globally and across temporal variability at the small special scale of a center of coastal upwelling at 30° S. A new mitochondrial haplogroup Ib detected in coastal Chile was associated with warmer waters. In an experiment focused on inter-species comparisons, laboratory-determined thermal reaction norms were consistent with latitudinal/thermal distributions of species, with G. oceanica exhibiting warm thermal optima and tolerance and G. muellerae exhibiting cooler thermal optima and tolerances. Emiliania huxleyi haplogroups I and II tended to exhibit a wider thermal niche compared to the other Gephyrocapsa, but no differences among haplogroups within E. huxleyi were found. A second experiment, controlling for local adaptation and time in culture, found a significant difference between E. huxleyi haplogroups. The difference between I and II was of the expected sign, but not the difference between I and Ib. The differences were small (≤1°C) compared to differences reported previously within E. huxleyi by local adaptation and even in-culture evolution. Haplogroup Ib showed a narrower thermal niche. The cosmopolitanism of E. huxleyi might result from both wide-spread generalist phenotypes and specialist phenotypes, as well as a capacity for local adaptation. Thermal reaction norm differences can well explain the species distributions but poorly explain distributions among mitochondrial haplogroups within E. huxleyi. Perhaps organelle haplogroup distributions reflect historical rather than selective processes.

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Deciphering lifelong thermal niche using otolith δ 18 O thermometry within supplemented lake trout ( Salvelinus namaycush ) populations

Freshwater Biology ◽

10.1111/fwb.13497 ◽

2020 ◽

Vol 65 (6) ◽

pp. 1114-1127

Author(s):

Olivier Morissette ◽

Louis Bernatchez ◽

Michael Wiedenbeck ◽

Pascal Sirois

Keyword(s):

Lake Trout ◽

Salvelinus Namaycush ◽

Thermal Niche

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Latitude, distance offshore and local environmental features as modulators of zooplankton assemblages across the NE Atlantic Shelves Province

Journal of Plankton Research ◽

10.1093/plankt/fbz015 ◽

2018 ◽

Vol 41 (3) ◽

pp. 293-308

Author(s):

Alvaro Fanjul ◽

Arantza Iriarte ◽

Fernando Villate ◽

Ibon Uriarte ◽

Miguel Artiach ◽

...

Keyword(s):

Latitudinal Gradient ◽

Single Species ◽

English Channel ◽

Ne Atlantic ◽

Species Dominance ◽

Environmental Features ◽

Thermal Niche ◽

The North ◽

Niche Differences ◽

The North Sea

Abstract Contribution of latitude, distance offshore and environmental factors to variations in zooplankton assemblages across the Northeast Atlantic Shelves Province, from the Bay of Biscay [Bilbao 35 (B35) and Urdaibai 35 (U35)] to the English Channel (Plymouth L4; L4) and the North Sea (Stonehaven; SH), were assessed mainly by redundancy analysis. For coarse zooplankton groups latitude explained the main between-site differences, and meroplankton contributed more than holoplankton. Latitudinal differences were best indicated by contrasting abundances of cirripede larvae and doliolids (most abundant at the lowest latitude sites) and bryozoan and polychaete larvae (most abundant at the highest latitude site). Doliolids were best indicators of temperature-mediated latitudinal differences. The interaction between latitude and distance offshore or salinity and phytoplankton biomass explained smaller percentages of the variability. The main differences in copepod and cladoceran genera reflected the oceanic influence, with highest presence of Corycaeus and Oncaea at L4, likely related to the higher influence of off-shelf water intrusions, and neritic Acartia dominating at SH, U35 and B35. Podon and Evadne, which decreased from south to north, reflected latitude-related differences driven more by salinity than by temperature. Instances where a single species (e.g. Acartia clausi) dominated showed common relationships with temperature, consistent with a common thermal niche. Differences in co-generic species dominance between sites depicted the latitudinal gradient.

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