Baroreflex regulation of blood pressure is important for maintaining appropriate tissue perfusion. Although temperature affects heart rate (fH) 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 fH along with winter metabolic downregulation, independent of body temperature. Through pharmacological interventions (phenylephrine and sodium nitroprusside), the baroreflex control of fH was studied at ∼25°C in spring–summer- and winter-acclimated tegus. In winter lizards, resting and minimum fH 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), while no acclimation differences occurred in resting blood pressure (5.14±0.38 versus 5.06±0.56 kPa), baroreflex gain (94.3±10.7 versus 138.7±30.3% kPa−1) or rate-pressure product (an index of myocardial activity). Vagal tone exceeded the sympathetic tone of fH, especially in the winter group. Therefore, despite the lower fH, winter acclimation does not diminish the fH baroreflex responses or rate-pressure product, possibly because of increased stroke volume that may arise because of heart hypertrophy. Independent of acclimation, fH responded more to hypotension than to hypertension. This should imply that tegus, which have no pressure separation within the single heart ventricle, must have other protection mechanisms against pulmonary hypertension or oedema, presumably through lymphatic drainage and/or vagal vasoconstriction of pulmonary artery. Such a predominant fH reflex response to hypotension, previously observed in anurans, crocodilians and mammals, may be a common feature of tetrapods.
Baroreflex regulation of arterial blood pressure is important to the maintenance of adequate tissue perfusion and thus matching oxygen and nutrient delivery to metabolic demands (Bagshaw, 1985; Hagensen et al., 2010; Zena et al., 2015). With respect to ectothermic reptiles, there is evidence of baroreceptors that monitor blood pressure in turtles (Millard and Moalli, 1980; Stephens et al., 1983; Crossley et al., 2015), snakes (Lillywhite and Seymour, 1978; Lillywhite and Gallagher, 1985), the lizard Tiliqua rugosa (formerly known as Trachydosaurus rugosus; Berger et al., 1980) and crocodilians (Altimiras et al., 1998; Crossley et al., 2003; Hagensen et al., 2010).
Baroreflex regulation in crocodilians is characterized by a pronounced heart rate (fH) reflex response to hypotension, as has been reported for the saltwater crocodile, Crocodylus porosus, and the broad-snouted caiman, Caiman latirostris (Altimiras et al., 1998; Hagensen et al., 2010). 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). Seasonal reductions in metabolic rate of ectotherms is marked by profound temperature-independent suppression of many physiological and biochemical processes (Navas and Carvalho, 2010), including reduction in fH (Delaney et al., 1974; Glass et al., 1997; Bícego-Nahas et al., 2001; da Silva et al., 2008; Sanders et al., 2015).
The South American tegu lizard Salvator merianae (Harvey et al., 2012), formerly known as Tupinambis merianae (Duméril and Bibron 1938), exhibits a pronounced seasonal cycle of activity/inactivity. During spring and summer, tegus are diurnally active (Klein et al., 2006). As winter approaches, animals retreat to underground burrows and actively suppress metabolism (Lopes and Abe, 1999; Sanders et al., 2015) even though ambient temperatures in winter in southeastern Brazil are relatively benign (tegu burrows can reach ∼17°C; Abe, 1995; Andrade et al., 2004; Sanders et al., 2015). Investigations of seasonal energy metabolism, ventilation and cardiac morphology in tegus have focused on the underlying mechanism(s) of metabolic suppression (Abe, 1983; Andrade and Abe, 1999; de Souza et al., 2004; Milsom et al., 2008; Toledo et al., 2008; da Silveira et al., 2013) and have elucidated reduced thermal sensitivity of metabolic rate in dormant tegus (Abe, 1995; Milsom et al., 2008; Sanders et al., 2015). Therefore, this species is especially important as a model for investigating fH baroreflex responses independent of temperature because it may undergo changes in cardiovascular autonomic balance across seasons.
In the present study, we hypothesize that the metabolic reduction of winter-acclimated S. merianae decreases fH baroreflex sensitivity along with the suppression of other cardiovascular variables in comparison to the spring–summer-acclimated animals at the same ambient temperature (∼25°C). To this end, peripheral injections of sodium nitroprusside (SNP), a vasodilator, and the α1-adrenergic agonist phenylephrine (PE), a vasoconstrictor, were performed to evaluate the reflex responses of fH against changes in blood pressure. In addition, adrenergic and cholinergic tones on the heart were determined, and a full autonomic blockade was performed to test the relative role of sympathetic and parasympathetic modulation on the tegu fH response to hypotension and hypertension. In addition, the underlying influences of α- and β-adrenergic receptors in the tegu cardiovascular system were measured.
MATERIALS AND METHODS
Experiments were conducted on unanaesthetized tegu lizards S. merianae. Tegus of both sexes had been captive bred at the Jacarezário, São Paulo State University, in Rio Claro, São Paulo state (IBAMA permit no. 02001-000412/94-28 and SISBIO-ICMBio/n. 26677-1). Different young animals, during their second year cycle, were used for the spring–summer (from October to February; 586.2±72.2 g body mass) versus the winter (July; 392±30.67 g) experiments, which were performed in two consecutive years. At least 3 weeks before the experiments were initiated, animals were group-housed indoors in plastic boxes (70×70×100 cm) lined with wood shavings and containing PVC tubes for sheltering. During the spring–summer season, tegus were maintained under a natural photoperiod and fed with chicken eggs and fruits three times per week until 7 days before surgery. Water was available ad libitum. A source of heat for thermoregulation was provided by a heating lamp programmed to turn on at 09:00 h and turn off at 17:00 h, except for the week before surgery. Temperatures varied from 23–25°C (lamp off) to 33–35°C (lamp on). During winter months, tegus were maintained in darkness at 23–25°C with no source of heat and no food. These animals, even in captivity, voluntarily stop eating at the beginning of winter (K.C.B., personal observations; Andrade and Abe, 1999; de Souza et al., 2004). This study was conducted with the approval of the local ethical committee of São Paulo State University (CEUA; protocol no. 021802-07).
SNP (nitric oxide donor), PE (agonist of α-1 adrenergic receptors), atropine (antagonist of muscarinic receptors), sotalol (antagonist of β-adrenergic receptors), prazosin (antagonist of α1-adrenergic receptors) and isoproterenol (agonist of β-adrenergic receptors) were purchased from Sigma (St Louis, MO, USA). All drugs were dissolved in sterile saline.
Lizards were anaesthetized with 5% isoflurane in 100% oxygen, via face mask, in an open circuit. After induction, the trachea was intubated with an endotracheal tube inserted through the mouth; the endotracheal tube was fitted for the animal's trachea. Isoflurane (∼1 Vol%) was delivered with 0.5 l min−1 oxygen flow from an agent-specific vaporizer (VetCase, Brasmed, São Paulo, Brazil). The depth of anaesthesia was monitored during the surgical procedure by maintaining breathing frequency at 1–2 breaths min−1. A polyethylene cannula (Clay Adams, Parsippany, NJ, USA) made from a connection between a PE-10 cannula and a PE-50 cannula filled with heparinized 0.9% NaCl solution (100 i.u. ml−1 heparin) was occlusively inserted into the femoral artery for the measurement of pulsatile arterial pressure (PAP). The same procedure was followed to cannulate the femoral vein for drug injections. After surgery, animals received intramuscular injections of an analgesic (flunixin meglumine; 1 mg kg−1) and an antibiotic (enrofloxacin; 5 mg kg−1) agent according to recommended dosages for reptiles (Martinez-Jimenez and Hernandez-Divers, 2007; Mosley, 2011). After recovery from anaesthesia, each animal was individually placed in an experimental chamber, where it was kept for a minimum of 24 h without disturbance until the beginning of the experimental procedure.
Measurements of blood pressure and heart rate
The arterial cannula was connected to a pressure transducer (TSD 104A, Biopac Systems, Santa Barbara, CA, USA) calibrated against a mercury column. The signal from the pressure transducer was collected by an acquisition system (Biopac Systems model MP 100A-CE). Heart rate was derived from the PAP signal and mean arterial blood pressure (PMA) was calculated as PMA=PD+1/3(PS– PD), where PD is the diastolic pressure and PS is the systolic pressure. Rate-pressure product (RPP), as a measure of myocardial activity, was calculated as fH×PS (kPa min−1).
All experiments were conducted in tegus at an ambient temperature of 25.5°C±1.5°C, measured by a temperature sensor connected to an acquisition system (Biopac Systems model MP 100A-CE). After a 30–40 min basal recording of PAP, 0.5 ml kg−1 of saline was injected into the femoral vein to verify the possibility that the injection per se may influence PMA and fH. Serial increasing doses of SNP (2.5, 5.0, 10.0 and 25.0 µg kg−1) and PE (5.0, 10.0, 25.0 and 50.0 µg kg−1) were then injected (0.25 ml kg−1 followed by 0.25 ml kg−1 of saline during 1 min). Each dose was injected only after the recorded cardiovascular variables had returned to the pre-injection values. This baroreflex protocol was performed in both spring–summer- and winter-acclimated animals. Because no difference in baroreflex sensitivity was observed between groups (Table 1), the pharmacological autonomic blockade of the fH reflex responses was only performed in spring–summer tegus. To this end, atropine (1.5 mg kg−1; muscarinic antagonist) plus sotalol (6.0 mg kg−1; β-adrenergic antagonist) were injected before PE (25.0 µg kg−1) or SNP (10.0 µg kg−1). Spring–summer animals were further tested to verify the influence of α1- and β-adrenergic receptors on PMA and fH (the mechanism that underlies the hypertensive response to PE, the tachycardic response to isoproterenol, as well as the effectiveness of drugs): (1) injection of prazosin (0.2 mg kg−1; α1-adrenergic antagonist) alone or combined with PE (25.0 µg kg−1) and (2) injection of sotalol (6.0 mg kg−1) alone or combined with isoproterenol (2.5 µg kg−1; β-adrenergic antagonist). All doses were chosen on the basis of preliminary experiments and previous reports on reptiles (Altimiras et al., 1998; Skovgaard et al., 2005; Hagensen et al., 2010).
Analysis of the baroreflex
Calculation of adrenergic and cholinergic tones
The adrenergic and cholinergic tones on the heart were calculated based on the cardiac interval (1/fH; in s) derived from the PS pulse. For this, changes in the cardiac interval induced by atropine (1.5 mg kg−1) or sotalol (6.0 mg kg−1) were expressed relative to the intrinsic cardiac interval obtained after full autonomic blockade (atropine+sotalol) of the heart (Altimiras et al., 1997).
Data are shown as means±s.e.m. The effect of the pharmacological treatments on PMA and fH between winter and spring–summer animals was analyzed through two-way repeated-measures ANOVA (factors: PE or SNP serial doses and season), and the differences among means were assessed by Tukey's post hoc test. A two-way ANOVA was used to compare adrenergic and cholinergic tonus between seasons. The effect of season on resting PMA and fH as well as on all baroreflex parameters derived from sigmoidal baroreflex–fH curves was analyzed through a Student's t-test. The full autonomic blockade on baroreflex responses and the influence of α1- and β-adrenergic receptors on PMA and fH were analyzed through one-way ANOVA or one-way repeated-measures ANOVA (factor: treatment), respectively, and the differences among means were assessed by Tukey's post hoc test. Means were considered to be different at P≤0.05.
Mean resting cardiovascular parameters for spring–summer and winter tegus are shown in Table 1. No significant seasonal difference in PMA was observed (P=0.91), whereas fH was significantly lower during winter (P=0.039).
Fig. 1A depicts original traces of PAP of a tegu exhibiting a typical tachycardic reflex response to reduction in PMA after injection of SNP (10.0 µg kg−1), and an increase in PMA after a bolus injection of PE (25.0 µg kg−1). In contrast to a prominent tachycardia induced by hypotension, hypertension caused a very small bradycardia. In Fig. 1B, an abolition of reflex changes of fH is shown after animals’ pre-treatment with atropine and sotalol (full autonomic blockade).
PE caused significant increases in PMA in both winter and spring–summer animals (effect of treatment: P<0.001; Fig. 2A). The hypertensive effect of PE did not differ between groups (P=0.38). Additionally, PE caused a small reflex bradycardia for all doses tested in spring–summer (P<0.001; Fig. 2B), and for the two higher doses (10.0 and 25.0 µg kg−1) in winter animals (P<0.05; Fig. 2B); winter animals reached significantly lower values for reflex bradycardia compared with spring–summer (P<0.01).
SNP induced a significant decrease in PMA at all doses tested in spring–summer animals (effect of treatment: P<0.001; Fig. 2C). During winter, only the two higher doses of SNP (10.0 and 25.0 μg kg−1) decreased PMA (P<0.001). The hypotensive effects of SNP were always followed by tachycardia in both groups (P<0.001; Fig. 2D), although spring–summer animals showed higher values (effect of season: P=0.026).
Fig. 3 depicts the responses to changes in PMA with PE and SNP in baroreflex–fH curves at the two groups for each animal and the mean PMA/fH relationships. The coefficients of determination (R2) of the mean curves were 0.92±0.02 (spring–summer) and 0.86±0.06 (winter), indicating that 92% and 86% of the fH variations in the respective seasons are explained by PMA changes. In addition, resting fH values were at the low end of the reflex curves. As for the baroreflex parameters derived from sigmoidal baroreflex–fH curves, the maximal fH, the slope of the linear part of the curve, the PMA at the midpoint in the fH range, the maximal gain and the normalized gain were not different between groups (Table 1). In contrast, minimum fH was significantly higher during spring–summer compared with winter tegus (P=0.013; Table 1).
Cholinergic and adrenergic tones on the heart in winter and spring–summer tegus are shown in Fig. 4. Resting and undisturbed tegus from both groups were characterized by a large cholinergic tone (winter: 122±9.2%; spring–summer: 62.3±11.9%) in comparison to a low adrenergic tone (winter: 31.5±14.1%; spring–summer: 31.3±4.6%; P<0.001). Winter animals had the highest parasympathetic modulation of fH (P=0.015).
Pharmacological autonomic blockade attenuated the reflex bradycardia (P<0.05; Fig. 5B) and further increased PMA (P<0.01; Fig. 5A) after PE injection. Reflex tachycardia induced by hypotension was completely inhibited in those animals pretreated with atropine plus sotalol (P<0.001; Fig. 5D); in contrast, there was no change in hypotensive effect evoked by SNP (P=0.06; Fig. 5C).
The antagonism of α1-adrenergic receptors with prazosin alone (0.2 µg kg−1) did not decrease PMA (P=0.16), but inhibited the hypertensive effect induced by PE (25.0 µg kg−1, P<0.001; Fig. 6A); prazosin did not change fH (P=0.56; Fig. 6B). Antagonism of β-adrenergic receptors with sotalol had no effect on resting PMA or fH (P=0.36; Fig. 6C,D); however, it was able to inhibit the great β-adrenergic stimulation on the heart induced by isoproterenol (P<0.001; Fig. 6D).
The main findings of the present study are that resting winter tegu lizards, even exhibiting lower fH and higher cardiac parasympathetic tone, maintain unchanged fH baroreflex sensitivity in comparison with spring–summer animals at the same temperature (∼25°C); moreover, both winter and spring–summer tegus have higher vagal over sympathetic tone on the heart, allowing them to mount a pronounced reflex tachycardia against hypotension over a negligible bradycardia against hypertension.
Resting cardiovascular variables and seasonal variation
In winter tegus, fH was ∼23% lower than in spring–summer tegus at the same temperature (Table 1), which is in agreement with a higher parasympathetic drive on the heart (Fig. 4). 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 fH 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 fH and metabolic rate under steady-state conditions (Butler et al., 2002; Piercy et al., 2015). Therefore, gas exchange and fH 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, 1995; Andrade 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. The rate of oxygen consumption reported for winter tegus can be 32% lower than values reported for resting animals during the active season at the same temperature (Abe, 1995).
Besides significant decrease in fH in winter tegus, RPP (Table 1), as a measure of myocardial activity (Glass et al., 1997; da Silva et al., 2008), remained unchanged between spring–summer and winter groups. Juvenile tegu lizards undergo cardiac hypertrophy in anticipation of winter hibernation (da Silveira et al., 2013), which could be a compensatory mechanism to maintain blood pressure at low fH by sustaining stroke volume; however, the maintenance of blood pressure during dormancy in tegu lizards does not exclude a possible contribution from increased peripheral vascular resistance. It is interesting to note that hibernating golden-mantled ground squirrels (Callospermophilus lateralis) undergo an ∼30% increase in the left ventricular chamber mass maintaining extremely low fH, while stroke volume is significantly increased (Nelson and Rourke, 2013). Heart hypertrophy has also been reported in the Andean lizard, Liolaemus nigroviridis, during hibernation (Naya et al., 2009). Therefore, adjustments in cardiac function that allow lower fH and sustained blood pressure in winter tegus remain to be explored in the context of heart hypertrophy in anticipation of the winter season. Furthermore, a reduction in fH without changes in blood pressure is also observed in aestivating toads and lungfish at constant body temperature (Glass et al., 1997; Bícego-Nahas et al., 2001; da Silva et al., 2008), which might indicate a pattern of cardiovascular regulation in ectotherms that face seasonal metabolic reductions such as hibernation and aestivation.
Baroreflex control of fH and seasonal variation
The reflex responses of fH against changes in blood pressure in tegus were accessed by pharmacological manipulation of arterial pressure, which is a common method of studying baroreflex in vertebrates (Bagshaw, 1985; Altimiras et al., 1998; Crossley et al., 2003; Hagensen et al., 2010). Although this ‘closed-loop study’ tends to overestimate the reflex sensitivity, it offers the advantages of both being performed with minimal instrumentation on unanaesthetized animals and providing an integrated response caused by activation of all relevant receptors (Altimiras et al., 1998; Crossley et al., 2003; Hagensen et al., 2010). This was an appropriate study to be performed in tegus because the baroreceptor locations as well as their characterization have not previously been demonstrated in these animals.
Even at reduced metabolic rate, suggested by smaller resting fH in our winter tegus, fH baroreflex sensitivity appeared to be preserved. In semi-natural conditions, the abandonment of thermoregulatory behaviour and the commitment to dormancy during winter in tegus allow body temperature to decline to an ambient temperature of approximately 17°C (Abe, 1995; Andrade et al., 2004; Sanders et al., 2015). At that point, lower body temperatures could affect the central nervous system's capacity for regulating the cardiovascular system, thereby preventing tegus from responding to hypotension, as is seen in other ectotherms such as caimans (Hagensen et al., 2010), turtles (Crossley et al., 2015) and toads (Zena et al., 2015), where low temperature decreases fH baroreflex sensitivity. Overall, these data indicate that seasonal variations in baroreflex sensitivity of S. merianae in the field, should they exist, are likely explained by differences in body temperature during the different seasons rather than an endogenous seasonal cycle of cardiovascular control.
Salvator merianae showed a clear tachycardic response to decreases in blood pressure with SNP, whereas PE-induced hypertension caused a negligible bradycardia in both winter and spring–summer tegus. The observed low resting fH positioned at the low end of the baroreflex curves is compatible with the presence of low sympathetic and high parasympathetic drives on the heart. This is supported by a great increase in fH induced by sympathetic activation in response to hypotension, which was confirmed by abolition of the reflex tachycardia after β-adrenergic blockade. Accordingly, the minimal bradycardia induced by PE hypertension is compatible with an already high parasympathetic drive operating on the heart (Fig. 4) that prevents these animals from further fH reductions in response to increases in blood pressure. In fact, many species of undisturbed and resting reptiles are normally characterized by high vagal tone on the heart (Taylor et al., 2014).
The reduced ability of tegus to decrease fH in response to high pressures raises the question of why some ectotherms defend hypotension more than hypertension. Studies on anurans have recently demonstrated the presence of a specialized lymphatic system that has the ability to return excessive transcapillary fluids back to the venous system and thereby maintain blood volume homeostasis; these animals are capable of lymph fluid formation 10 times higher than mammals (Hedrick et al., 2007; Hillman et al., 2010). Therefore, the importance of baroreceptors for defending against increases in blood pressure seems not to be the case for anurans (Hedrick et al., 2015; Zena et al., 2015). Like anurans, tegus have cardiac ventricles that are anatomically and functionally undivided, and hence there is no pressure separation within the ventricle (Jensen et al., 2014). At least in the turtle Chrysemys picta, which also has a three-chambered heart, the net loss of plasma through the lung capillaries accounts for 10 to 20 times greater flow than in mammals because of a high pulmonary arterial blood pressure, a variable pulmonary blood flow and/or low plasma colloid osmotic pressure (Zweifach and Intaglietta, 1971; Burggren, 1982). In tegus, the absence of a meaningful bradycardic response against hypertension may expose their pulmonary capillaries to a relatively higher pressure, increasing the rate of fluid formation, which might be avoided by a protective mechanism, such as the lymphatic system. Among ectothermic reptiles, besides the presence of lymphatic vessels and lymph heart structure, which have been identified in some snakes, lizards, turtles and crocodilians, there is not sufficient information available regarding the function of this system in fluid volume homeostasis (for a review, see Hedrick et al., 2013). More studies are necessary to clarify the effect of lymph mobilization capacity on blood pressure homeostasis in reptiles. Besides this mechanism, one cannot rule out the possibility of vagal activity increasing pulmonary vascular resistance (Burggren, 1977; Milsom et al., 1977; Taylor et al., 2009), which could shunt blood away from the lungs during hypertensive episodes.
The normalized baroreflex gain in tegus (spring–summer: 94% kPa−1; winter: 139% kPa−1; Table 1) is similar to that of another squamate, the lizard T. rugosa (98% kPa−1; Berger et al., 1980), at the same temperature (∼25°C), but is higher than that observed in anurans (ranging from 33.6 to 46% kPa−1; temperature range: 21–25°C; Hedrick et al., 2015; Zena et al., 2015). Thus, in comparison with the anurans, the higher fH baroreflex sensitivity of these lizards may be related to their higher PMA and lower fH (Crossley et al., 2003).
The presence of α1-adrenoreceptors in the vasculature of tegus with a vasoconstrictor function as described for mammals and other reptiles (Overgaard et al., 2002; Breno et al., 2007) was revealed by the blockade of the hypertensive effect of PE by the α1-adrenergic antagonist prazosin (0.2 mg kg−1 i.v.). We also tested two other doses of prazosin (0.5 and 1 mg kg−1; data not shown) in a few animals, and similar results on PMA were observed, in addition to a long-lasting inhibition of the PE effect up to 4 h. Thus, resting S. merianae seems not to have a net α1-adrenergic tone in its vasculature, at least under our experimental conditions. Regarding β-adrenergic receptors, the pharmacological stimulation with isoproterenol increased fH more than threefold from saline values (∼227% increase), which was almost completely blunted by previous injection of sotalol, a response mediated by β-adrenergic receptors on the heart. In resting tegus with low fH, β-adrenergic blockade did not further reduce it; a result similar to that observed in awake and fully recovered rattlesnakes, which have a high parasympathetic tone on the heart (Campbell et al., 2006).
In summary, contrary to our initial hypothesis, the South American tegu S. merianae, known to have an annual cycle of metabolic change, seems to maintain relatively unchanged fH baroreflex sensitivity at a temperature-independent low metabolic state. Even with lower resting fH and higher vagal tone on the heart, the preserved baroreflex response of fH in winter tegus may be related to a cardiac hypertrophy (da Silveira et al., 2013) and, thus, the maintenance of cardiac activity. Independent of acclimation, the predominant tachycardic response against hypotension, similar to what happens in anurans (Zena et al., 2015), crocodilians (Altimiras et al., 1998; Hagensen et al., 2010) and mammals (Crestani et al., 2010), indicates a possible pattern of baroreflex regulation in tetrapods. Finally, the absence of a meaningful bradycardic response to hypertension might account for the presence of an efficient lymphatic system that pulls back transcapillary fluid loss into the venous system, avoiding lung oedema, a mechanism that remains to be explored in reptiles.
We thank the veterinarian André Escobar, who kindly assisted us in the anaesthesia procedures, and Lynn Hartzler for grammatical corrections to an earlier version of the manuscript. We are grateful for many suggestions provided by two anonymous referees, and thank Jacopo Mortola and C. Loren Buck for critically reading the manuscript.
V.D., L.A.Z. and K.C.B. conceived and designed the experiments; V.D. performed the experiments; V.D., L.A.Z. and K.C.B. analyzed and interpreted the data; L.A.Z., K.C.B., V.D., D.V.A., L.H.G. and A.S.A. wrote the manuscript.
This work was supported by Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq; INCT-Fisiologia Comparada, 573921/2008-3 to A.S.A. and K.C.B.) and Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP; 07/54113-0 to K.C.B.). V.D. and L.A.Z. were the recipients of FAPESP undergraduate (nos 09/00806-0 and 10/05063-2) and PhD (no. 12/17379-0) fellowships, respectively.
The authors declare no competing or financial interests.