The relationship between body temperature, heart rate, breathing rate, and rate of oxygen consumption, in the tegu lizard (Tupinambis merianae) at various levels of activity

Piercy, Joanna Carolyne; Rogers, Kip; Reichert, Michelle; Andrade, Denis V.; Abe, Augusto Shinya; Tattersall, Glenn J.; Milsom, William K.

doi:10.1007/s00360-015-0927-3

Cited by 26 publications

(27 citation statements)

References 56 publications

(68 reference statements)

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“…Collectively, these results indicate a certain degree of metabolic depression, which is supported by observations in reptiles, including tegu lizards, of a linear correlation between f H and metabolic rate under steady-state conditions (Butler et al, 2002;Piercy et al, 2015). Therefore, gas exchange and f H are seasonally adjusted to match the differing steady-state metabolic demands (Andrade et al, 2004;Clark et al, 2005;Piercy et al, 2015). In fact, hibernation in S. merianae is characterized by an active metabolic reduction during the winter season (Abe, 1983(Abe, , 1995Andrade and Abe, 1999;Lopes and Abe, 1999;de Souza et al, 2004;Sanders et al, 2015), which, in southeastern Brazil, is synchronized with the driest phase of the year.…”

Section: Resting Cardiovascular Variables and Seasonal Variationsupporting

confidence: 78%

“…Interestingly, it was recently reported that tegus implanted with a telemetry ECG device and kept under semi-natural conditions anticipate the winter season through a gradual monthly decrease in f H at constant body temperatures (Sanders et al, 2015). Collectively, these results indicate a certain degree of metabolic depression, which is supported by observations in reptiles, including tegu lizards, of a linear correlation between f H and metabolic rate under steady-state conditions (Butler et al, 2002;Piercy et al, 2015). Therefore, gas exchange and f H are seasonally adjusted to match the differing steady-state metabolic demands (Andrade et al, 2004;Clark et al, 2005;Piercy et al, 2015).…”

Section: Resting Cardiovascular Variables and Seasonal Variationmentioning

confidence: 66%

“…It is interesting to note that baroreflex sensitivity is enhanced at a high temperature (30°C) in C. latirostris (Hagensen et al, 2010), and also in the toad Rhinella schneideri (Zena et al, 2015), but the ability to respond mainly to hypotension is preserved regardless of temperature in both species. Temperature is known to directly influence metabolic rate and the cardiovascular adjustments to the new metabolic demands seem to be a proportional response (Piercy et al, 2015). In contrast, there are situations when metabolic rate can be downregulated independent of temperature in ectotherms; for example, when they are seasonally exposed to adverse environmental conditions and enter the physiological/behavioural state of hibernation or aestivation (Abe, 1995;Glass et al, 1997;Bícego-Nahas et al, 2001;Andrade et al, 2004;Milsom et al, 2008;Navas and Carvalho, 2010).…”

Section: Introductionmentioning

confidence: 99%

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Winter metabolic depression does not change arterial baroreflex control of heart rate in the tegu lizard (Salvator merianae)

Zena

Dantonio

Gargaglioni

et al. 2016

Journal of Experimental Biology

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Baroreflex regulation of blood pressure is important for maintaining appropriate tissue perfusion. Although temperature affects heart rate ( f H ) reflex regulation in some reptiles and toads, no data are available on the influence of temperature-independent metabolic states on baroreflex. The South American tegu lizard Salvator merianae exhibits a clear seasonal cycle of activity decreasing f H along with winter metabolic downregulation, independent of body temperature. Through pharmacological interventions ( phenylephrine and sodium nitroprusside), the baroreflex control of f H was studied at ∼25°C in spring-summer-and winter-acclimated tegus. In winter lizards, resting and minimum f H were lower than in spring-summer animals (respectively, 13.3±0.82 versus 10.3±0.81 and 11.2±0.65 versus 7.97±0.88 beats min −1

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Section: Resting Cardiovascular Variables and Seasonal Variationsupporting

confidence: 78%

Section: Resting Cardiovascular Variables and Seasonal Variationmentioning

confidence: 66%

Section: Introductionmentioning

confidence: 99%

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Winter metabolic depression does not change arterial baroreflex control of heart rate in the tegu lizard (Salvator merianae)

Zena

Dantonio

Gargaglioni

et al. 2016

Journal of Experimental Biology

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“…Monthly nighttime minimum levels of oxygen consumption were calculated from the formula derived by Piercy et al (2015) from the relationship between heart rate and metabolic rate for this species of tegu lizard under quiescent conditions. The equation used was: log 10 (O 2 consumption) = −1.47 + 0.67 (log 10 (heart rate)).…”

Section: Discussionmentioning

confidence: 99%

“…Here, we record continuously behaviour and T b along with heart and breathing rates as physiological surrogates for metabolism (Zaar et al 2004;Butler et al 2000Butler et al , 2002Clark et al 2004Clark et al , 2006Green et al 2008;Piercy et al 2015), in a group of black and white tegus, T. merianae, housed outdoors under semi-natural conditions. We hypothesized that metabolic suppression (as indicated by changes in heart rate and breathing frequency) would not be evident until the tegus remained in the burrows for extended periods but that metabolism would then progressively fall and be sustained throughout the dormant period.…”

Section: Introductionmentioning

confidence: 99%

Daily and annual cycles in thermoregulatory behaviour and cardio-respiratory physiology of black and white tegu lizards

et al. 2015

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This study was designed to determine the manner in which metabolism is suppressed during dormancy in black and white tegu lizards (Tupinambis merianae). To this end, heart rate (fH), respiration rate (fR), and deep body temperature (Tb) were continuously monitored in outdoor enclosures by radio-telemetry for nine months. There was a continuous decline in nighttime breathing and heart rate, at constant Tb, throughout the late summer and fall suggestive of an active metabolic suppression that developed progressively at night preceding the entrance into dormancy. During the day, however, the tegus still emerged to bask. In May, when the tegus made a behavioural commitment to dormancy, Tb (day and night) fell to match burrow temperature, accompanied by a further reduction in fH and fR. Tegus, under the conditions of this study, did arouse periodically during dormancy. There was a complex interplay between changes in fH and Tb associated with the direct effects of temperature and the indirect effects of thermoregulation, activity, and changes in metabolism. This interplay gave rise to a daily hysteresis in the fH/Tb relationship reflective of the physiological changes associated with warming and cooling as preferred Tb alternated between daytime and nighttime levels. The shape of the hysteresis curve varied with season along with changes in metabolic state and daytime and nighttime body temperature preferences.

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Control of Breathing in Ectothermic Vertebrates

Milsom

Gilmour

Perry

et al. 2022

Comprehensive Physiology

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The ectothermic vertebrates are a diverse group that includes the Fishes (Agnatha, Chondrichthyes, and Osteichthyes), and the stem Tetrapods (Amphibians and Reptiles). From an evolutionary perspective, it is within this group that we see the origin of air-breathing and the transition from the use of water to air as a respiratory medium. This is accompanied by a switch from gills to lungs as the major respiratory organ and from oxygen to carbon dioxide as the primary respiratory stimulant. This transition first required the evolution of bimodal breathing (gas exchange with both water and air), the differential regulation of O 2 and CO 2 at multiple sites, periodic or intermittent ventilation, and unsteady states with wide oscillations in arterial blood gases. It also required changes in respiratory pump muscles (from buccopharyngeal muscles innervated by cranial nerves to axial muscles innervated by spinal nerves). The question of the extent to which common mechanisms of respiratory control accompany this progression is an intriguing one. While the ventilatory control systems seen in all extant vertebrates have been derived from common ancestors, the trends seen in respiratory control in the living members of each vertebrate class reflect both shared-derived features (ancestral traits) as well as unique specializations. In this overview article, we provide a comprehensive survey of the diversity that is seen in the afferent inputs (chemo and mechanoreceptor), the central respiratory rhythm generators, and the efferent outputs (drive to the respiratory pumps and valves) in this group.

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The relationship between body temperature, heart rate, breathing rate, and rate of oxygen consumption, in the tegu lizard (Tupinambis merianae) at various levels of activity

Cited by 26 publications

References 56 publications

Winter metabolic depression does not change arterial baroreflex control of heart rate in the tegu lizard (Salvator merianae)

Winter metabolic depression does not change arterial baroreflex control of heart rate in the tegu lizard (Salvator merianae)

Daily and annual cycles in thermoregulatory behaviour and cardio-respiratory physiology of black and white tegu lizards

Control of Breathing in Ectothermic Vertebrates

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