Translating animal model research: does it matter that our rodents are cold?

Does it matter that rodents used as preclinical models of human biology are routinely housed below their thermoneutral zone? We compile evidence showing that such rodents are cold-stressed, hypermetabolic, hypertensive, sleep-deprived, obesity-resistant, fever-resistant, aging-resistant, and tumor-prone compared with mice housed at thermoneutrality. The same genotype of mouse has a very different phenotype and response to physiological or pharmacological intervention when raised below or at thermoneutrality.

Long term ablation of protein kinase A (PKA)-mediated cardiac troponin I phosphorylation leads to excitation-contraction uncoupling and diastolic dysfunction in a knock-in mouse model of hypertrophic cardiomyopathy.

The cardiac troponin I (cTnI) R21C (cTnI-R21C) mutation has been linked to hypertrophic cardiomyopathy and renders cTnI incapable of phosphorylation by PKA in vivo. Echocardiographic imaging of homozygous knock-in mice expressing the cTnI-R21C mutation shows that they develop hypertrophy after 12 months of age and have abnormal diastolic function that is characterized by longer filling times and impaired relaxation. Electrocardiographic analyses show that older R21C mice have elevated heart rates and reduced cardiovagal tone. Cardiac myocytes isolated from older R21C mice demonstrate that in the presence of isoproterenol, significant delays in Ca(2+) decay and sarcomere relaxation occur that are not present at 6 months of age. Although isoproterenol and stepwise increases in stimulation frequency accelerate Ca(2+)-transient and sarcomere shortening kinetics in R21C myocytes from older mice, they are unable to attain the corresponding WT values. When R21C myocytes from older mice are treated with isoproterenol, evidence of excitation-contraction uncoupling is indicated by an elevation in diastolic calcium that is frequency-dissociated and not coupled to shorter diastolic sarcomere lengths. Myocytes from older mice have smaller Ca(2+) transient amplitudes (2.3-fold) that are associated with reductions (2.9-fold) in sarcoplasmic reticulum Ca(2+) content. This abnormal Ca(2+) handling within the cell may be attributed to a reduction (2.4-fold) in calsequestrin expression in conjunction with an up-regulation (1.5-fold) of Na(+)-Ca(2+) exchanger. Incubation of permeabilized cardiac fibers from R21C mice with PKA confirmed that the mutation prevents facilitation of mechanical relaxation. Altogether, these results indicate that the inability to enhance myofilament relaxation through cTnI phosphorylation predisposes the heart to abnormal diastolic function, reduced accessibility of cardiac reserves, dysautonomia, and hypertrophy.

Amylin-leptin coadministration stimulates central histaminergic signaling in rats.

Combined amylin+leptin (AMN+LEP) can reduce diet induced obesity and is very effective in combating LEP resistance. The purpose of this study was to evaluate the effect of AMN+LEP on central histaminergic signaling in lean and obese rats. Male rats were administered LEP (300 µg/kg/d), AMN (100 µg/kg/d), AMN+LEP or vehicle (SAL, 0.9% normal saline), via a subcutaneous mini-osmotic pump or single injection (LEP, 300 µg/kg and AMN, 100 µg/kg) for acute studies. AMN+LEP administration increased expression of histamine H1 receptor (HIR) and histidine decarboxylase (HDC) mRNA in the hypothalamus. Increased levels of H1R were seen in arcuate (Arc) and ventromedial hypothalamus (VMH) as well as the area postrema (APOS) and nucleus of solitary tract (NTS) following AMN+LEP administration. APOS and NTS also showed expression of immediate early gene c-FOS in the hindbrain in AMN+LEP-treated rats. We confirmed previous evidence indicating that AMN+LEP increased STAT-3 protein phosphorylation in Arc and VMH. Finally, by in vivo microdialysis, we observed an increase in methyl HIS levels in the VMH of AMN, LEP and AMN+LEP-treated rats. Taken together, these observations are consistent with an important role that neuronal HIS may play in mediating the potent effects of AMN+LEP on food intake and body weight.

Evidence for the role of hindbrain orexin-1 receptors in the control of meal size.

Hypothalamic orexin neurons project to the hindbrain, and 4th-ventricle intracerebroventricular (4th-icv) injection of orexin-A treatment increases food intake. We assessed the effects of hindbrain orexin-A and the orexin-1-receptor antagonist SB334867 on meal pattern in rats consuming standard chow. When injected 4th-icv shortly before dark onset, lower doses of orexin-A increased food intake over a 2-h period by increasing the size of the first meal relative to vehicle, whereas the highest dose increased food intake by causing the second meal to be taken sooner. Conversely, hindbrain SB334867 reduced food intake by decreasing the size of the first meal of the dark phase. We also examined the effects of 4th-icv orexin-A and SB334867 on locomotor activity. Only the highest dose of orexin-A increased activity, and SB334867 had no effect. In addition, hindbrain SB334867 induced c-Fos in the nucleus of the solitary tract. These data support the suggestion that endogenous hindbrain orexin-A acts to limit satiation. Both orexin-A and the pancreatic satiation hormone amylin require an intact area postrema to affect food intake, so we asked whether 4th-icv orexin-A impairs the satiating effect of peripheral amylin treatment. Amylin reduced the size of the first meal of the dark cycle when rats were pretreated with 4th-icv saline, yet amylin was ineffective after 4th-icv orexin-A pretreatment. Using double-label immunohistochemistry, we determined that some orexin-A fibers in the area postrema are located in proximity to amylin-responsive neurons. Therefore, hindbrain orexin-A may increase food intake, in part, by reducing the ability of rats to respond to amylin during a meal.

Long-term caloric restriction reduces metabolic rate and heart rate under cool and thermoneutral conditions in FBNF1 rats.

The long-term metabolic and cardiovascular responses to caloric restriction (CR) are poorly understood. We examined the responses to one year of CR in FBNF1 rats housed in cool (COOL; T(a)=15 °C) or thermoneutral (TMN; T(a)=30 °C) conditions. Rats were acclimated to COOL or TMN for 2 months, instrumented for cardiovascular telemetry and studied in calorimeters. Baseline caloric intake, oxygen consumption (VO(2)), mean arterial blood pressure (MAP), and heart rate (HR) were determined prior to assignment to ad lib (AL) or CR groups (30-40% CR) within each T(a) (n = 8). Groups of rats were studied after 10 weeks CR, one year CR, and after 4 days of re-feeding. Both 10 weeks and one year of CR reduced HR and VO(2) irrespective of T(a). Evaluation of the relationship between metabolic organ mass (liver, heart, brain, and kidney mass) and energy expenditure revealed a clear shift induced by CR to reduce expenditure per unit metabolic mass in both COOL and TMN groups. Re-feeding resulted in prompt elevations of HR and VO(2) to levels observed in control rats. These findings are consistent with the hypothesis that long term CR produces sustained reductions in metabolic rate and heart rate in rats.

Female mice and rats exhibit species-specific metabolic and behavioral responses to ovariectomy.

Ovariectomy (OVX) leads to hyperphagia and weight gain in rats, which can be prevented by estradiol (E2) replacement; however, the role of endogenous E2 on feeding and energy homeostasis in female mice has not been well characterized. The primary goal of this study was to assess the relative contribution of increased energy intake and decreased energy expenditure to OVX-induced weight gain in female rats and mice. OVX led to hyperphagia in rats, but did not produce daily, nor cumulative, hyperphagia in mice. OVX decreased mass-specific metabolic rate in mice, but not in rats. OVX decreased home cage locomotor activity in both species. Pair-feeding attenuated OVX-induced weight gain in rats and produced both short- and long-term changes in expression of key hypothalamic genes involved in food intake and energy homeostasis, i.e., the anorexigenic neuropeptide pro-opiomelanocortin (POMC) and the orexigenic neuropeptides: melanin-concentrating hormone (MCH) and agouti-related peptide (AgRP). No differences in hypothalamic gene expression were observed between OVX'd and sham mice. The results suggest that OVX-induced weight gain is mediated by hyperphagia and reduced locomotor activity in rats, but that in mice, it is primarily mediated by reduced locomotor activity and metabolic rate.

Short-term physiological hyperleptinemia decreases arterial blood pressure.

We examined the possibility that chronic, low-dose peripheral leptin infusion would inhibit food intake but not increase blood pressure. Male Fisher Brown Norway (FBNF1) and Sprague-Dawley (SD) rats were instrumented for cardiovascular telemetry, housed in metabolic chambers, and given leptin (LEP: 600 microg/kg/day) or vehicle (SAL: 10 microl/h) via a subcutaneous osmotic pump for seven days. Leptin infusion increased plasma leptin levels to about 40 ng/ml, decreased food intake by 25-35% and stimulated lipolysis in both strains of rats. Leptin infusion for one week decreased mean arterial pressure from baseline. The reduction developed slowly, was generally about 3 to 7 mm Hg, and observed in both strains. The peripheral, hypotensive effect of chronic leptin in FBNF1 rats was prevented by blockade of nitric oxide production with L-NAME treatment. These results indicate that peripheral leptin treatment, at a level which inhibits food intake and induces lipolysis, produces nitric oxide-dependent decreases in blood pressure.

Cardiovascular effects of melanin-concentrating hormone.

Melanin-concentrating hormone (MCH) is a cyclic 19-amino acid neuropeptide exclusively synthesized in the lateral hypothalamic area (LHA) and the zona incerta (ZI) that has been implicated in the regulation of energy balance. Despite what is known about the orexigenic effect of MCH, whether MCH has distinct cardiovascular and metabolic effects has yet to be determined. Thus, our goal here was to characterize the concurrent cardiovascular, metabolic, and behavioral responses of male rats to chronic intracerebroventricular (icv) infusion of MCH. Male Long-Evans rats were instrumented with telemetry transmitters for measurement of heart rate (HR) and housed in room calorimeters for assessment of food intake and oxygen consumption (VO(2)) at standard lab ambient temperature (23 degrees C) in order to examine physiological responses to chronic infusion of MCH (8 microg/d and 16 microg/d). Our findings provide the first evidence that chronic administration of MCH induces bradycardia and reduced mean arterial pressure, while it did not affect VO(2). A second experiment was performed in which the physiological responses to an acute icv infusion of MCH were observed. The results of experiment 2 indicate that MCH leads to a low HR that is maintained during the first 2 h post-infusion, the time period during which MCH acutely stimulated feeding. Collectively, these findings confirm that MCH may be an important modulator of sympathetic nervous system activity and thus may play a critical role in coordinating normal responses to negative energy balance.

Central thyrotropin-releasing hormone infusion opposes cardiovascular and metabolic suppression during caloric restriction.

Inhibition of hypothalamic thyrotropin-releasing hormone (TRH) neuronal activity is a well-established adaptation to caloric restriction (CR) that suppresses pituitary secretion of thyroid-stimulating hormone, but may also participate in modulation of autonomic function. Thus, we hypothesized that decreased hypothalamic TRH activity contributes to CR-induced bradycardia and decreased metabolic rate. To test this hypothesis, male Sprague-Dawley rats were instrumented with telemetry devices for measurement of heart rate (HR) and blood pressure (BP) and a lateral intracerebroventricular (i.c.v.) guide cannula for central infusions. After recovery, rats were housed in metabolic chambers and given either ad libitum(ad-lib) or CR treatments for 7 days; half of each diet group was then given continuous i.c.v. infusions of TRH (25 nmol/h) or saline (0.25 microl/h) for 7 days via osmotic pump. This dose of TRH did not significantly alter peripheral free T(4) levels. In ad-lib rats, TRH infusion produced small reductions in food intake and small increases in HR and BP over saline-infused controls. In CR rats, TRH infusion resulted in an increase in HR and also energy expenditure over saline-infused controls. These results support the hypothesis that suppression of central TRH activity contributes to the homeostatic suppression of energy expenditure and HR observed during CR.

Estradiol decreases the orexigenic effect of melanin-concentrating hormone in ovariectomized rats.

Estradiol exerts an inhibitory effect on food intake via interactions with anorexigenic peptides, like cholecystokinin, that function to decrease meal size. It is currently unknown whether estradiol also interacts with orexigenic compounds implicated in the physiological control of food intake. Thus, the primary goal of this study was to determine whether estradiol decreases the orexigenic effect of melanin-concentrating hormone (MCH), a neuropeptide that, like estradiol, appears to influence food intake by selectively affecting the controls of meal size. Food and water intake were monitored following lateral ventricular (icv) infusions of 5 mug MCH or saline vehicle in oil- and estradiol-treated ovariectomized rats. MCH increased food intake throughout the first 4 h of the dark phase in oil-treated rats, but only for the last 2 h of the same 4-h interval in estradiol-treated rats. As a result, the orexigenic effect of MCH was significantly lower in estradiol-treated rats, relative to oil-treated rats. During this interval of MCH-stimulated feeding, a prandial increase in water intake was not observed in either oil- or estradiol-treated rats. We conclude that estradiol decreases the orexigenic effect of MCH in ovariectomized rats.

Perinatal MSG treatment attenuates fasting-induced bradycardia and metabolic suppression.

We studied the effect of arcuate nucleus (ARC) lesions induced pharmacologically by the perinatal treatment of monosodium l-glutamate (MSG) on the cardiovascular, metabolic, and behavioral responses to fasting. Saline and MSG-treated male Sprague-Dawley rats were instrumented with telemetry devices for measurement of mean arterial pressure (MAP) and heart rate (HR) and housed in room calorimeters at an ambient temperature (T(a)) of 23 degrees C for assessment of oxygen consumption (VO(2)). At baseline, controls and MSG-treated rats had similar MAP (control=95+/-4; MSG=91+/-2 mmHg), HR (control=323+/-4; MSG=324+/-2 bpm), and VO(2) (control=8.7+/-0.3; MSG=8.6+/-0.2 ml/min). There were no differences in fasting-induced reductions in body weight or in food intake upon refeeding. MSG-treatment significantly attenuated fasting-induced reductions in HR and VO(2). This effect was specific to reduced caloric availability, as MSG-treated rats exhibited intact capacity to both increase and decrease HR and VO(2) in response to cold (T(a)=15 degrees C) and to thermoneutrality (T(a)=30 degrees C). Additional studies were performed in saline- and MSG-treated rats chronically treated with beta(1)-adrenergic receptor blockade (atenolol) prior to and during fasting. In controls, the cardiovascular responses to fasting during beta(1)-blockade were blunted and generally mimicked the effects of MSG-treatment, while beta(1)-blockade had no additional effect on MSG-treated rats. The results are consistent with the hypothesis that ARC neuronal signaling is requisite for intact homeostatic responses to fasting and may participate in fasting-induced withdrawal of cardiac sympathetic activity.

Regulation of metabolic rate and substrate utilization by zinc deficiency.

The trace metal zinc (Zn) is essential for the catalytic activity of many enzymes involved in energy nutrient metabolism and appears to regulate hormones, such as insulin, leptin, and thyroid hormone that play key roles in metabolism. Thus, this study used the continuous monitoring of oxygen consumption, carbon dioxide production, locomotion, and food intake to determine the effect of dietary Zn restriction on metabolic rate (MR), basal metabolic rate (BMR), and respiratory quotient (RQ). Rats were fed a Zn-adequate (ZA, 28 ppm) or Zn-deficient (ZD, <1 ppm) diet for 8 days, followed by a 4-day refeeding period. To control for reductions in food intake that characteristically occur in ZD rats, an additional group was pair-fed (PF) the same amount ZA food eaten by ZD rats. The mean caloric intake of ZD rats was significantly lower than ZA rats by day 3. By day 8, ZD and PF rats weighed 64% and 67% of ZA rats, respectively, (P <.01). Pair feeding resulted in increased locomotor activity, such that the distance traveled for PF rats (316 +/- 43 m) was 6 times that of ZA (53 +/- 6 m). Despite the fact that PF and ZD rats had the same food intake, there was no increase in locomotor activity in ZD rats suggesting that the mechanisms responsible for increased physical activity in food restricted animals may be Zn dependent. Furthermore, differences in activity between PF and ZD animals were not reflected in differences in MR. Both ZD and PF significantly reduced MR compared with ZA rats beginning on day 4. There was a significant relationship between RQ and caloric intake (r = 0.708, P <.01), but no specific effect of Zn status. Thus, while there may be an effect of Zn on locomotion and the energetic cost of activity, it appears that the most profound effect of Zn status on MR and substrate utilization is the result of Zn deficiency-induced anorexia.

Effect of ambient temperature on cardiovascular parameters in rats and mice: a comparative approach.

Ambient air temperatures (T(a)) of <6 degrees C or >29 degrees C have been shown to induce large changes in arterial blood pressure and heart rate in homeotherms. The present study was designed to investigate whether small incremental changes in T(a), such as those found in typical laboratory settings, would have an impact on blood pressure and other cardiovascular parameters in mice and rats. We predicted that small decreases in T(a) would impact the cardiovascular parameters of mice more than rats due to the increased thermogenic demands resulting from a greater surface area-to-volume ratio in mice relative to rats. Cardiovascular parameters were measured with radiotelemetry in mice and rats that were housed in temperature-controlled environments. The animals were exposed to different T(a) every 72 h, beginning at 30 degrees C and incrementally decreasing by 4 degrees C at each time interval to 18 degrees C and then incrementally increasing back up to 30 degrees C. As T(a) decreased, mean blood pressure, heart rate, and pulse pressure increased significantly for both mice (1.6 mmHg/ degrees C, 14.4 beats.min(-1). degrees C(-1), and 0.8 mmHg/ degrees C, respectively) and rats (1.2 mmHg/ degrees C, 8.1 beats.min(-1). degrees C(-1), and 0.8 mmHg/ degrees C, respectively). Thus small changes in T(a) significantly impact the cardiovascular parameters of both rats and mice, with mice demonstrating a greater sensitivity to these T(a) changes.

Glucagon-like peptide-1 receptor stimulation increases blood pressure and heart rate and activates autonomic regulatory neurons.

Glucagon-like peptide-1 (GLP-1) released from the gut functions as an incretin that stimulates insulin secretion. GLP-1 is also a brain neuropeptide that controls feeding and drinking behavior and gastric emptying and elicits neuroendocrine responses including development of conditioned taste aversion. Although GLP-1 receptor (GLP-1R) agonists are under development for the treatment of diabetes, GLP-1 administration may increase blood pressure and heart rate in vivo. We report here that centrally and peripherally administered GLP-1R agonists dose-dependently increased blood pressure and heart rate. GLP-1R activation induced c-fos expression in the adrenal medulla and neurons in autonomic control sites in the rat brain, including medullary catecholamine neurons providing input to sympathetic preganglionic neurons. Furthermore, GLP-1R agonists rapidly activated tyrosine hydroxylase transcription in brainstem catecholamine neurons. These findings suggest that the central GLP-1 system represents a regulator of sympathetic outflow leading to downstream activation of cardiovascular responses in vivo.

Ingestive behavior and body temperature during the ovarian cycle in normotensive and hypertensive rats.

The relationship between ingestive behavior (eating + drinking) and core body temperature (T(b)) in naturally cycling female rats was compared in a normotensive strain (Sprague-Dawley; SD) and a hypertensive strain reputed to have chronically elevated T(b) (spontaneously hypertensive rats; SHR). T(b) (by telemetry) and ingestive behavior (automated recording) were quantified every 30 s. Ingestive behavior and T(b) were related on all days of the ovarian cycle in both strains, but the strength of that relationship was reduced on the day of estrus (E) compared with nonestrous days. Several strain differences in T(b) were found as well. In SHR, dark-phase T(b) was elevated on E, whereas SD remained at the lower nonestrous values. Fluctuations in dark-phase T(b) were correlated with ingestive behavior in both strains but had greater amplitude in SHR except on E. Short-term fasting or sucrose availability did not eliminate elevated dark-phase T(b) on E in SHR. We propose that estrus-related changes unique to SHR may indicate heightened thermal reactivity to hormonal changes, ingestive behavior, and general locomotor activity.