Changes in thermal quality of the environment along an elevational gradient affect investment in thermoregulation by Yarrow’s spiny lizards

Lymburner, Alannah; Blouin‐Demers, Gabriel

doi:10.1111/jzo.12818

Cited by 7 publications

(10 citation statements)

References 96 publications

(167 reference statements)

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“…Such as S. anahuacus, there are other Sceloporus species that show a low Tb like S. malachiticus (Tb = 28.6 °C; Vial, 1984), S. mucronatus mucronatus (Tb = 29.4 ± 0.7 °C; Lemos-Espinal et al, 1997a), S. bicanthalis (Tb = 28.8 ± 0.69 °C; Andrews et al, 1999) and S. palaciosi (Tb = 27.82 ± 5.31 °C;Güizado-Rodríguez et al, 2011). This low Tb is presumably due to thermal constraints imposed by the spatial and temporal distribution of environmental temperatures that determine daily and seasonal activity because usually at high elevations, thermal quality is low (Lymburner & Blouin-Demers, 2020). Lara-Reséndiz et al, (2014) evaluated the thermal habitat quality of a lizard community along an altitude gradient, in order to determine if thermal environment has an effect on distribution and thermal ecology.…”

Section: Discussionmentioning

confidence: 99%

Intra-population variation of body temperature of the lizard Sceloporus anahuacus (Squamata: Phrynosomatidae) in Sierra del Ajusco, Mexico

Güizado-Rodriguez

García‐Vázquez

Solano‐Zavaleta

et al. 2022

AZM

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We evaluated intra-population variation of body temperature of the Mexican lizard Sceloporus anahuacus (Phrynosomatidae) in Sierra del Ajusco, Mexico. The geographic distribution of this lizard is restricted to the higher parts of the mountains bordering the south of the Mexican Valley in Mexico City. The study of the body temperature of S. anahuacus and its relationship with the environment is important because high elevation taxa are seriously threatened by climate change. For that reason, and compared body temperature between sex, age class, reproductive condition and activity state. Overall, mean body temperature was 26.2 ± 5.5 °C with a range between 9–39 °C. We did not find differences between body temperatures of males and females. However, we found significant differences depending on activity state in both sexes. In females, body temperature did not vary as a function of age class or reproductive status. Instead, we found differences in body temperature between males of different age classes. Juveniles had the highest body temperature, probably due to differential temperature requirements associated with development. On the other hand, body temperature of active and inactive S. anahuacus was strongly associated with environmental temperature, perhaps due to sedentary habits and territorial behavior. Exploring why such variation exists on body temperature regulation may provide information on factors influencing the survivorship of this endemic Mexican lizard.

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Section: Discussionmentioning

confidence: 99%

Intra-population variation of body temperature of the lizard Sceloporus anahuacus (Squamata: Phrynosomatidae) in Sierra del Ajusco, Mexico

Güizado-Rodriguez

García‐Vázquez

Solano‐Zavaleta

et al. 2022

AZM

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“…Body temperatures of ectotherms, including reptiles, strongly depend on thermal properties of their microhabitats (Goller et al, 2014; Gómez Alés et al, 2017; Huey and Slatkin, 1976; Ortega and Pérez-Mellado, 2016). However, terrestrial environments show thermal variation to varying degrees in several spatial and temporal levels, including altitudinal (Kuyucu et al, 2018; Lymburner and Blouin-Demers, 2020; Van Damme et al, 1989; Zamora-Camacho et al, 2016), seasonal (Díaz et al, 2006; Huey and Pianka, 1977; Liz et al, 2019; Van Damme et al, 1987) and microhabitat level (Adolph, 1990; Goller et al, 2014; Ortega et al, 2016b; Scheers and Van Damme, 2002). Because of this heterogeneity of the thermal environment, behavioral thermoregulation holds crucial importance for ectothermic organisms including reptiles (Cowles and Bogert, 1944; Huey and Slatkin, 1976; Kearney et al, 2009; McMaster and Downs, 2013; Rangel-Patiño et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Thermal biology of two sympatric Lacertids lizards (Lacerta diplochondrodesandParvilacerta parva) from Western Anatolia

Kuyucu¹,

Şahin

2021

Preprint

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Sympatric lizard species differing in morphology present convenient models for studying the differentiation in thermal behavior and the role of morphological differences in thermal biology. Here we studied the thermal biology of two sympatric lizard species which occur together sympatrically in western Anatolia, Frig Valley. These two species differ in body size, with the larger Lacerta diplochondrodes and smaller Parvilacerta parva. Field body temperatures of the individuals belonging to both species were recorded in the activity period. Additionally, several environmental parameters including solar radiation, substrate temperature, air temperature and wind speed were also monitored to investigate the relative effect of these abiotic parameters on thermal biology of the two species. The field body temperature and temperature excess (difference between body and substrate temperature) of two species while being relatively close to each other, showed seasonal differences. Solar radiation, substrate temperature and air temperature were the main effective factors on thermal biology in the field. Additionally, although body size did not have a direct significant effect on body temperature or temperature excess, the interaction between body size and wind were effective on temperature excess. In conclusion, our study partially supports the conservation of thermal biology of related lizard species.

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“…Body temperatures of ectotherms, including reptiles, strongly depend on thermal properties of their microhabitats (Goller et al, 2014;Gómez Alés et al, 2017;Huey and Slatkin, 1976;Ortega and Pérez-Mellado, 2016). However, terrestrial environments show thermal variation to varying degrees in several spatial and temporal levels, including altitudinal (Kuyucu et al, 2018;Lymburner and Blouin-Demers, 2020;Van Damme et al, 1989;Zamora-Camacho et al, 2016), seasonal (Díaz et al, 2006;Huey and Pianka, 1977;Liz et al, 2019;Van Damme et al, 1987) and microhabitat level (Adolph, 1990;Goller et al, 2014;Ortega et al, 2016b;Scheers and Van . CC-BY-NC-ND 4.0 International license available under a (which was not certified by peer review) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity.…”

Section: Introductionmentioning

confidence: 99%

“…Because of this heterogeneity of the thermal environment, behavioral thermoregulation holds crucial importance for ectothermic organisms including reptiles (Cowles and Bogert, 1944;Huey and Slatkin, 1976;Kearney et al, 2009;McMaster and Downs, 2013;Rangel-Patiño et al, 2020). The thermoregulatory strategies vary both among and between species, which depends on the costs and benefits of thermoregulation which also depend on several biotic and abiotic factors in the environment Slatkin 1976, Lymburner andBlouin Demers 2020). Species that rely on behavioral thermoregulation can utilize solar radiation by basking (heliothermy) or regulate their heat exchange with the substrate (thigmothermy) (Belliure and Carrascal, 2002;Garrick, 2008;Penniket and Cree, 2015;Rutschmann et al, 2020) to keep their body temperature in set point limits.…”

Section: Introductionmentioning

confidence: 99%

“…It is shown that even sympatric squamate species that live in the same environments might differ in their usage of thermal micro-habitats (Angilletta, 2009;Gomes et al, 2016;Gómez Alés et al, 2017). Therefore, differentiations in thermoregulatory strategies can also result in alterations for their habitat use in spatial and temporal scales (Buckley et al, 2015;Lymburner and Blouin-Demers, 2020;Neel and McBrayer, 2018;Paterson and Blouin-Demers, 2018). Microhabitat selection (Castilla and Bauwens, 1991;Ortega and Pérez-Mellado, 2016), reproduction activities (Ibargüengoytía et al, 2008;Luo et al, 2010;Meiri et al, 2012;Wang et al, 2016), foraging rates (Kearney et al, 2020;Verwaijen and Van Damme, 2007) and growth patterns (Angilletta et al, 2002;Have and Jong, 1996;Refsnider et al, 2019;Sears et al, 2016) are partly determined by thermal factors in ectotherms' environment.…”

Section: Introductionmentioning

confidence: 99%

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Thermal biology of two sympatric Lacertid lizards (Lacerta diplochondrodes and Parvilacerta parva) from Western Anatolia

Şahin

Kuyucu

2021

Journal of Thermal Biology

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Changes in thermal quality of the environment along an elevational gradient affect investment in thermoregulation by Yarrow’s spiny lizards

Cited by 7 publications

References 96 publications

Intra-population variation of body temperature of the lizard Sceloporus anahuacus (Squamata: Phrynosomatidae) in Sierra del Ajusco, Mexico

Intra-population variation of body temperature of the lizard Sceloporus anahuacus (Squamata: Phrynosomatidae) in Sierra del Ajusco, Mexico

Thermal biology of two sympatric Lacertids lizards (Lacerta diplochondrodesandParvilacerta parva) from Western Anatolia

Thermal biology of two sympatric Lacertid lizards (Lacerta diplochondrodes and Parvilacerta parva) from Western Anatolia

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