Running performance with emphasis on low temperatures in a Patagonian lizard, Liolaemus lineomaculatus

Cecchetto, Nicolás R.; Medina, Susana Marlin; Ibargüengoytía, Nora R.

doi:10.1038/s41598-020-71617-3

Cited by 14 publications

(27 citation statements)

References 96 publications

(110 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Liolaemid lizards living in the temperate cold climate of Patagonia show a remarkable capacity to endure low temperatures, since their locomotor performance capacities and thermal sensitivities are adjusted at temperatures that are suboptimal for lizards from lower latitude (Cecchetto et al . 2020). The thermal optimum and the thermal performance breadth of L. multimaculatus showed weak to null associations with thermal tolerance breadth.…”

Section: Discussionmentioning

confidence: 99%

“…2017; Cecchetto et al . 2020). Discerning the physiological responses in the context of climatic variability due to latitude is an important task that contributes to an understanding of theoretical topics in biology, and it can be useful in establishing management strategies in view of future scenarios of environmental change.…”

Section: Introductionmentioning

confidence: 99%

“…We expected the individuals of L. multimaculatus from higher latitudes to have broader thermal tolerance breadth and thermal performance breadth than the individuals from lower latitudes. Second, we expected a locally adapted response in liolaemid lizards (Labra et al 2009;Cecchetto et al 2020); therefore, individuals of L. multimaculatus from higher latitudes were expected to show relatively lower thermal optimum and decreased limits of thermal performance breadth in comparison with those from lower latitudes. Third, Lizards from low-temperature environments would have higher physiological performance at low temperatures than those from warm-temperature environments (Hare et al 2010); therefore, at relatively low temperatures, the V max of L. multimaculatus individuals from higher latitudes would be higher than that of individuals inhabiting lower latitudes.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Latitudinal pattern of the thermal sensitivity of running speed in the endemic lizard Liolaemus multimaculatus

et al. 2021

View full text Add to dashboard Cite

Physiological performance in lizards may be affected by climate across latitudinal or altitudinal gradients. In the coastal dune barriers in central‐eastern Argentina, the annual maximum environmental temperature decreases up to 2°C from low to high latitudes, while the mean relative humidity of the air decreases from 50% to 25%. Liolaemus multimaculatus, a lizard in the family Liolaemidae, is restricted to these coastal dunes. We investigated the locomotor performance of the species at 6 different sites distributed throughout its range in these dune barriers. We inquired whether locomotor performance metrics were sensitive to the thermal regime attributable to latitude. The thermal performance breadth increased from 7% to 82% with latitude, due to a decrease in its critical thermal minimum of up to 5°C at higher latitudes. Lizards from high latitude sites showed a thermal optimum, that is, the body temperature at which maximum speed is achieved, up to 4°C lower than that of lizards from the low latitude. At relatively low temperatures, the maximum running speed of high‐latitude individuals was faster than that of low‐latitude ones. Thermal parameters of locomotor performance were labile, decreasing as a function of latitude. These results show populations of L. multimaculatus adjust thermal physiology to cope with local climatic variations. This suggests that thermal sensitivity responds to the magnitude of latitudinal fluctuations in environmental temperature.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Latitudinal pattern of the thermal sensitivity of running speed in the endemic lizard Liolaemus multimaculatus

et al. 2021

View full text Add to dashboard Cite

show abstract

“…Overall, this suggests that incorporating the temperature-dependence of movement is important for predicting net energy gain across the range of temperatures observed in nature. However, generalizations across taxonomic groups are also possible using allometric but temperature-independent scaling relationships for movement speed, for which more data is available (Angilletta et al 2007;Hirt et al 2017;Rezende & Bozinovic 2019;Cecchetto et al 2020). Furthermore, it stresses the dominant importance of the temperature-dependence of prey density and parallels findings of models and experiments showing that food intake strongly affects optimum temperatures and upper thermal limits (Brett 1970;Thomas et al 2017 Lister & Garcia 2018) will thus enhance the vulnerability of ectotherms to warming (Huey & Kingsolver 2019).…”

Section: Mapping the Net Energy Gain To Quantify Performance Changes ...mentioning

confidence: 92%

Integrating trait-based movement into mechanistic predictions of thermal performance

Terlau

Brose

Antunes

et al. 2022

Preprint

View full text Add to dashboard Cite

Despite the diversity and functional importance of invertebrates, predicting their response to global warming remains challenging as it requires extensive measurements of physiological performance or rarely available high-resolution distribution data. Mechanistic models can help overcome these limitations by generalizing fundamental physiological processes. However, their predictions typically omit the effects of species interactions. Movement is a key process of species interactions underpinning animal performance in the real world. Here, we developed an empirically-grounded mechanistic model that incorporates allometric and thermodynamic constraints on movement and predator-prey interactions. We illustrate how it can be used to quantify the thermal performance of invertebrates under current and future climatic conditions. This trait-based approach (1) contributes to our understanding of the mechanisms underlying thermal fitness, (2) allows generalized predictions of thermal performance across invertebrate species worldwide and (3) can be used to inform species distribution models and thereby help infer species range limits under climate change.

show abstract

“…To determine the available spatiotemporal heterogeneity of the microenvironmental temperatures for thermoregulation, operative temperatures (T e , sensu Bakken 93 ) were obtained using nine polyvinyl chloride (PVC) pipe models connected to external dataloggers (HOBO, U23-003, T°/T°C ± 1 °C) during the collection of lizards. The model with the greatest correspondence of thermal data to reflect the lizard T b was a PVC pipe (80 mm length × 2.15 mm thickness) sealed at both ends with silicone Fastix (Regression: Adjusted R 2 = 0.846, N = 2836, slope = 1.09, confidence interval = 1.05 ‒ 1.14) 94 , 95 . Subsequently, the models were deployed in the study area in the most representative microhabitats used by L. montanezi : (i) Bare soil with sunny, sandy substrate, (ii) Bare soil with shady, sandy substrate (beneath shrubs), and (iii) Weathered rocks in the shade beneath shrubs (3 microhabitats × 3 replicates).…”

Section: Methodsmentioning

confidence: 99%

Vulnerability to climate change of a microendemic lizard species from the central Andes

Laspiur

Santos

Medina

et al. 2021

Sci Rep

Self Cite

View full text Add to dashboard Cite

Given the rapid loss of biodiversity as consequence of climate change, greater knowledge of ecophysiological and natural history traits are crucial to determine which environmental factors induce stress and drive the decline of threatened species. Liolaemus montanezi (Liolaemidae), a xeric-adapted lizard occurring only in a small geographic range in west-central Argentina, constitutes an excellent model for studies on the threats of climate change on such microendemic species. We describe field data on activity patterns, use of microhabitat, behavioral thermoregulation, and physiology to produce species distribution models (SDMs) based on climate and ecophysiological data. Liolaemus montanezi inhabits a thermally harsh environment which remarkably impacts their activity and thermoregulation. The species shows a daily bimodal pattern of activity and mostly occupies shaded microenvironments. Although the individuals thermoregulate at body temperatures below their thermal preference they avoid high-temperature microenvironments probably to avoid overheating. The population currently persists because of the important role of the habitat physiognomy and not because of niche tracking, seemingly prevented by major rivers that form boundaries of their geographic range. We found evidence of habitat opportunities in the current range and adjacent areas that will likely remain suitable to the year 2070, reinforcing the relevance of the river floodplain for the species’ avoidance of extinction.

show abstract

Running performance with emphasis on low temperatures in a Patagonian lizard, Liolaemus lineomaculatus

Cited by 14 publications

References 96 publications

Latitudinal pattern of the thermal sensitivity of running speed in the endemic lizard Liolaemus multimaculatus

Latitudinal pattern of the thermal sensitivity of running speed in the endemic lizard Liolaemus multimaculatus

Integrating trait-based movement into mechanistic predictions of thermal performance

Vulnerability to climate change of a microendemic lizard species from the central Andes

Contact Info

Product

Resources

About