The haploinsufficient Col3a1 mouse as a model for vascular Ehlers-Danlos syndrome.

Vascular Ehlers-Danlos syndrome is a rare genetic disorder resulting from mutations in the α-1 chain of type III collagen (COL3A1) and manifesting as tissue fragility with spontaneous rupture of the bowel, gravid uterus, or large or medium arteries. The heterozygous Col3a1 knockout mouse was investigated as a model for this disease. The collagen content in the abdominal aorta of heterozygotes was reduced, and functional testing revealed diminishing wall strength of the aorta in these mice. Colons were grossly and histologically normal, but reduced strength and increased compliance of the wall were found in heterozygotes via pressure testing. Although mice demonstrated no life-threatening clinical signs or gross lesions of vascular subtype Ehlers-Danlos syndrome type IV, thorough histological examination of the aorta of heterozygous mice revealed the presence of a spectrum of lesions similar to those observed in human patients. Lesions increased in number and severity with age (0/5 [0%] in 2-month-old males vs 9/9 [100%] in 14-month-old males, P < .05) and were more common in male than female mice (23/26 [88.5%] vs 14/30 [46.7%] in 9- to 21-month-old animals, P < .05). Haploinsufficiency for Col3a1 in mice recapitulates features of vascular Ehlers-Danlos syndrome in humans and can be used as an experimental model.

Cold acclimation-induced increase of systolic blood pressure in rats is associated with volume expansion.

To investigate the mechanisms of cold-induced hypertension, the systolic blood pressure (SBP) and average daily water consumption were measured weekly in 6-month-old male Wistar rats; they were subsequently acclimated to thermoneutrality (26 degrees C for 7 weeks), to cold temperature (6 degrees C for 9 weeks), and then again reacclimated to 26 degrees C for 5 weeks. Circulating plasma volume and whole blood viscosity were measured in subgroups of rats at the end of acclimation to 26 degrees C after 2 days, after 1, 6, and 8 weeks of cold, and after 2 and 5 weeks of rewarming. The control values obtained at the end of thermoneutral period were: SBP = 130.8 +/- 18.6 mm Hg, plasma volume = 41.9 +/- 4.64 mL/kg, whole body viscosity at shear rate of 22.5 per sec = 6.7 +/- 0.48 cps, and daily water consumption = 42.25 +/- 16.81 mL. After 48 h of cold exposure there was almost a 50% increase in plasma volume that persisted to a lesser degree throughout the whole period of cold exposure (P < .05). After 2 weeks of cold exposure the daily water consumption increased and SBP began to increase. After 6 weeks of cold exposure the SBP was 30 mm Hg above that of the control level (P < .001) and was accompanied by a 25% increase in whole blood viscosity (P < .05). At the end of 8 weeks of cold exposure the plasma volume was 56.8 +/- 9.51 mL/ kg and the whole blood viscosity was 8.0 +/- 1.79 cps at the 22.5 per sec shear rate. During the 5 weeks of rewarming the elevation of SBP and increased whole blood viscosity persisted, whereas the increased daily water consumption and expanded plasma volume returned to normal. Therefore, the acclimation to cold is accompanied by the development of a volume-associated hypertension, which is sustained after rewarming without volume expansion.

The effect of exercise training in cold on shivering and nonshivering thermogenesis in adult and aged C57BL/6J mice.

To understand the mechanisms of improvement of cold-induced heat production in aged mice following exercise training, the relative contributions of shivering and nonshivering thermogenesis to cold-induced metabolic responses were assessed in adult and aged C57BL/6J male mice, which inhabited sedentarily at room temperature, or were subjected either to a regimen of moderate intensity exercise training at 6 degrees C, or to sedentary repeated exposures to the same temperature. The main findings were that (1) aged mice had greater cold-induced nonshivering thermogenesis, but lower shivering than adult mice; (2) exercise training in a cold environment enhanced cold-induced nonshivering thermogenesis in adult mice, but suppressed it in aged animals; (3) exercise training in a cold environment increased shivering thermogenesis in both age groups, but this increase was much greater in aged mice; (4) the increase of cold-induced shivering thermogenesis was mainly responsible for increased cold tolerance in aged mice after exercise training in a cold environment.

Metabolic costs of mounting an antigen-stimulated immune response in adult and aged C57BL/6J mice.

Animals must balance their energy budget despite seasonal changes in both energy availability and physiological expenditures. Immunity, in addition to growth, thermoregulation, and cellular maintenance, requires substantial energy to maintain function, although few studies have directly tested the energetic cost of immunity. The present study assessed the metabolic costs of an antibody response. Adult and aged male C5BL/6J mice were implanted with either empty Silastic capsules or capsules filled with melatonin and injected with either saline or keyhole limpet hemocyanin (KLH). O2 consumption was monitored periodically throughout antibody production using indirect calorimetry. KLH-injected mice mounted significant immunoglobulin G (IgG) responses and consumed more O2 compared with animals injected with saline. Melatonin treatment increased O2 consumption in mice injected with saline but suppressed the increased metabolic rate associated with an immune response in KLH-injected animals. Melatonin had no effect on immune response to KLH. Adult and aged mice did not differ in antibody response or metabolic activity. Aged mice appear unable to maintain sufficient heat production despite comparable O2 production to adult mice. These results suggest that mounting an immune response requires significant energy and therefore requires using resources that could otherwise be allocated to other physiological processes. Energetic trade-offs are likely when energy demands are high (e.g., during winter, pregnancy, or lactation). Melatonin appears to play an adaptive role in coordinating reproductive, immunologic, and energetic processes.

Change in heat loss as a part of adaptation to repeated cold exposures in adult and aged male C57BL/6J mice.

Previous studies have shown that adult mice increase cold-induced heat production as a result of repeated exposures to cold, but that aged mice do not. The objective of the present study was to investigate changes in heat loss during repeated cold exposures in adult and aged C57BL/6J mice. Mice were partially restrained for three hours at 6 degrees C, three times at one-week intervals. Dry heat loss was inferred from measurements of differential temperature between the incoming and outgoing air in the experimental chamber. During the first cold exposure, aged mice showed less heat loss (both total and adjusted for body temperature) than adult animals, suggesting greater peripheral vasoconstriction in aged mice. With repeated cold exposures, both age groups showed increased heat loss, but the aged mice showed greater increase of heat loss, so that by the third cold stress test, no significant differences in heat loss between adult and aged mice were observed. The increase of heat loss after repeated cold exposures in aged mice might reflect a lesser peripheral vasoconstriction, serving to reduce the possibility of tissue necrosis in the cold.

Central neural correlates of learned heart rate control during exercise: central command demystified.

To identify the brain areas involved in central command, four monkeys were trained to attenuate the tachycardia of exercise while different brain sites affecting heart rate (HR) were simultaneously stimulated electrically. Among 24 brain sites located mostly in the limbic structures, we have identified four types of control systems that mediate cardiovascular and motor behavior during exercise. One system increases HR equivalently during both exercise and operantly controlled HR, whereas another increases HR during both tasks and abolishes operant HR control. In the third system, the effect of brain stimulation on HR is attenuated during exercise and during exercise with operantly controlled HR. The fourth system increases HR in both tasks, but its effect is significantly attenuated during operant HR control. We believe that this last system, which includes the mediodorsal nucleus, nucleus ventralis anterior, and cingulate cortex, plays a significant role in central command.

The effect of exercise training in a cold environment on thermoregulation in adult and aged C57BL/6J mice.

We studied the effect of exercise training in cold environment (six weeks of daily, one-hour runs on a treadmill at ambient temperature of 6 +/- 1 degrees C at 60-65% of VO2max) on cold-induced metabolic heat production, heat loss, and cold tolerance in adult and aged C57BL/6J male mice. In adult mice, exercise training in cold environment resulted in greater cold-induced heat production and cold tolerance without changes in heat loss, similar to the effects of daily cold exposure without exercise. In aged mice, daily cold exposures did not affect cold tolerance and cold-induced heat production, but exercise training in the cold resulted in greater cold-induced heat production and cold tolerance. Heat loss in aged mice increased similarly after both repeated cold exposures and exercise training in the cold. Therefore, mechanisms of effect of exercise training on cold tolerance are different in adult and aged animals. Exercise training in cold environment does not affect cold-induced heat production and cold tolerance in adult mice, but improves them in aged animals.

Cold acclimation-associated changes in brown adipose tissue do not necessarily indicate an increase of nonshivering thermogenesis in C57BL/6J mice.

We have reported previously that a cold acclimation procedure (3-hr partial restraint at 6 degrees C, repeated 3 times at 2-week intervals) usually improves the cold tolerance of adult C57BL/6J mice. Those mice that did not improve their cold tolerance had lower cold-induced sympathetic nervous outflow to the interscapular brown adipose tissue (IBAT), suggesting a failure in the mechanisms of nonshivering thermogenesis. To understand the origin of this failure, this study was intended to measure nonshivering thermogenesis in mice that did not improve their cold tolerance after the cold acclimation procedure. After being subjected 3 times to a partial restraint at 6 degrees C, mice were anesthetized with urethane, immobilized with vecuronium bromide, and placed on artificial ventilation. The VO2 and VCO2 in expired air were measured and metabolic heat production (MHP) was calculated while body temperature was artificially lowered to 7.5 degrees C below control level. In a separate group of mice, the total amount and concentration of mitochondrial uncoupling protein, thermogenin (UCP), in IBAT was measured immediately after completion of the cold-acclimation procedure. The concentration and the amount of UCP in the mitochondria of IBAT was significantly higher in all mice that had been presented to the cold acclimation procedure, regardless of its outcome, than in mice that had never been exposed to an environment below room temperature (NAIVE). MHP increased significantly during body cooling in all mice. However, MHP before and during cold stimulation in mice that did not improve their cold tolerance as a result of the cold-acclimation procedure was significantly lower than the MHP of animals in which cold tolerance was improved, and was not different from MHP of the NAIVE group. Therefore, in mice in which cold tolerance did not improve after repeated cold exposure, the anatomical and biochemical changes in brown adipose tissue typical of cold acclimation were not associated with a cold-induced increase in MHP. We infer that the expression of UCP in brown adipose tissue is a necessary, but not sufficient, attribute of cold acclimation. Cold acclimation, measured as increased cold tolerance, occurs only if synthesis of UCP in BAT is associated with an increased cold-induced response of the sympathetic nervous system.

Nonshivering thermogenesis in adult and aged C57BL/6J mice housed at 22 degrees C and at 29 degrees C.

Twelve- and 28-month-old C57BL/6J male mice were housed either at room temperature of 22 degrees C or at thermoneutrality (29 degrees C) during the two months prior to experiments. Acute experiments were conducted under anesthesia, myorelaxation, and artificial ventilation. We recorded efferent electrical impulse activity in one of the sympathetic nerves innervating the interscapular brown adipose tissue in response to acute cold stimulation, when body temperature was lowered 7.5 degrees C below control level. In separate experiments we measured O2 consumption and CO2 production and calculated the nonshivering thermogenesis. We also measured the concentration of uncoupling protein in interscapular brown adipose tissue before and after three-hour cold stress. In aged mice, both sympathetic nervous activity and nonshivering thermogenesis were lower in animals housed at thermoneutrality (29 degrees C) than in mice housed at 22 degrees. Among mice maintained at 22 degrees C, but not at thermoneutrality, aged animals had greater nonshivering thermogenesis and greater cold induced concentration of uncoupling protein in the brown adipose tissue than adults. Sympathetic nervous outflow to brown adipose tissue was always greater in aged mice, regardless of the temperature of acclimation. We concluded that aged mice, housed at 22 degrees C, showed the changes in nonshivering thermogenesis associated with cold acclimation. However, an increased sympathetic outflow to brown adipose tissue in aged animals reflects an age-related elevation of the tone and responsiveness of the sympathetic nervous system.

Heat loss during cold exposure in adult and aged C57BL/6J mice.

Metabolic heat production (MHP), colonic temperature (Tco), and nonevaporative (dry) heat loss were measured in ADULT and AGED C57BL/6J male mice during cold exposure. Dry heat loss was assessed as a differential temperature (Td) between incoming and outgoing air through the chamber for indirect calorimetry. The average Td during cold exposure normalized to surface area for ADULT mice was significantly higher than that for the AGED animals (0.0618 +/- 0.0003 degree C/cm2 and 0.0553 +/- 0.0005 degree C/cm2, respectively). Linear regression analysis showed that at the same Tco AGED mice showed lower values of Td normalized to surface area, indicating that at the same body temperature they were losing less heat than ADULT animals. It was concluded that age-related decline in cold tolerance in mice is not due to a lack of ability to reduce heat loss during cold exposure. On the contrary, AGED animals had lower heat loss in comparison with ADULT. We suggest that augmentation of heat conservation mechanisms is an adaptive response to diminishing cold-induced heat production.

Overnight heart rate and cardiac function in patients with dual chamber pacemakers.

Animal data indicate that chronic, overnight pacing at normal evening heart rates impairs cardiac function. We examined the relationship of pacing rate and cardiac function in nine patients with dual-chamber pacemakers. We investigated two, 3-week pacing regimens (80 and 50 ppm: DDD mode) in a cross-over design. Doppler echocardiograms were performed at 1700 hours (PM) and 0600 hours (AM) at the end of each regimen. Ventricular function and preload decreased overnight (PM vs AM) with both pacing regimens. Compared to the morning values, the ratio of preejection to ejection time (PEP/ET) rose (0.43 vs 0.46), while the mean velocity of circumferential fiber shortening (Vcf) fell (1.16 cm/s vs 1.11 cm/s). Stroke volume (SV) (61 mL vs 53 mL) and ejection fraction (EF) also fell (0.56 vs 0.53) in the morning. End-diastolic volume (EDV) (94 mL vs 88 mL) decreased in the morning, as did the ratio of passive to active filling (E/A) (1.06 vs 0.96). Isovolumic relaxation time (91 ms vs 101 ms) increased overnight at both pacing rates. Systolic function decreased at 80 ppm relative to 50 ppm at both times of day. SV fell (54 mL vs 61 mL), while both EDV (92 mL vs 90 mL) end-systolic volume (ESV) increased (43 mL vs 40 mL). Contractility measured by Vcf (1.09 cm/s vs 1.18 cm/s) and PEP/ET (0.49 vs 0.41) was reduced at 80 ppm. The heart needs to rest at night by slowing its rate of contraction. Pacing at 80 ppm impairs systolic and diastolic ventricular function compared to 50 ppm. Longer term consequences of ostensibly physiological pacing rates merit inquiry, particularly in those with preexisting cardiac dysfunction.

Oxygen consumption in adult and AGED C57BL/6J mice during acute treadmill exercise of different intensity.

Submaximal and maximal oxygen consumption was determined in untrained adult and aged male C57BL/6J mice during treadmill running. Each of 12-month-old (ADULT) and 24-month-old (AGED) male mice was tested on a motor-driven treadmill once at different speeds. VO2 was measured before, during, and after exercise by means of indirect calorimetry in metabolic treadmill chambers. The resting VO2 averaged 3064.67 +/- 87.71 mL/kg/h for ADULT mice and 2472.95 +/- 69.41 mL/kg/h for AGED mice. During exercise, VO2 increased linearly with work intensity (running speed): ADULT mice--from 5908.06 +/- 422.35 mL/kg/h at 3 m/min to 10861.99 +/- 174.03 mL/kg/h at 25 m/min; AGED mice--from 5217.25 +/- 263.26 mL/kg/h at 3 m/min to 7817.32 +/- 290.28 mL/kg/h at 20 m/min. Further increase of the running speed resulted in a decline of VO2 in ADULT and refusal to run in AGED mice. The results of this study demonstrated that in untrained C57BL/6J mice VO2max and maximal exercise capacity declined with age. At the same absolute and relative workloads, VO2 was lower in AGED mice.

Nonshivering thermogenesis during acute cold exposure in adult and aged C57BL/6J mice.

In C57BL/6J adult and aged mice, housed at room temperature (22.5 +/- 1 degrees C), we measured O2 consumption and CO2 production and calculated metabolic heat production under conditions of anesthesia and myorelaxation during acute cold stimulation when body temperature was lowered 7.5 degrees C below control level. An independent group of mice was subjected to a three hour partial physical restraint at 6 degrees C and concentration of uncoupling protein (thermogenin) was measured in interscapular brown adipose tissue mitochondria at different times after cold exposure. Heat production under anesthesia and myorelaxation was about 57-66% lower than in nonanesthetized conditions, but increased significantly during cold stimulation in both age groups. Under anesthesia and myorelaxation before and during cold stimulation aged mice produced about 20% more heat than adult mice. Because in these experiments all sources of facultative thermogenesis, except nonshivering, were suppressed by anesthesia and myorelaxation, and because brown adipose tissue is the major source of nonshivering thermoproduction, we concluded that aged mice housed at room temperature have an increased thermogenesis in brown adipose tissue. This conclusion was also supported by the finding that the concentration of uncoupling protein measured in the mitochondria of brown adipose tissue after single cold exposure was significantly higher in aged than in adult mice. Therefore, we propose that the lower, cold-induced, heat production typically observed in nonanesthetized aged mice may reflect reduced thermogenic capacity of skeletal muscles. While aged mice have less brown adipose tissue than adult animals, the remaining brown adipose tissue may compensate by increasing the concentration of uncoupling protein.

Sympathetic outflow to interscapular brown adipose tissue in cold acclimated mice.

C57BL/6J male mice were subjected to a cold acclimation procedure which consisted of three consecutive cold stress tests: 3-h partial restraint at 6 degrees C at 2-wk intervals. During the week following the last cold stress test, each animal previously subjected to the cold acclimation procedure, and an additional group of naive mice (animals that never had been exposed to an environment below room temperature) were anesthetized with urethan, paralyzed with vecuronium bromide, artificially ventilated, and subjected to cold stimulation for approximately 16 min. Electrical impulse activity from one of the fine sympathetic nerves entering the interscapular brown adipose tissue was recorded before and during cold stimulation, until body temperature dropped 8 degrees C below control level. Sympathetic outflow increased significantly during cold stimulation in all mice. Animals that did not achieve cold acclimation in three repeated cold stress tests (they demonstrated less cold tolerance in the last test) had lower sympathetic nervous outflow to brown adipose tissue at room temperature and during cold stimulation than mice that had achieved cold acclimation. In fact, sympathetic nervous outflow to brown adipose tissue in mice that had failed to show cold acclimation was similar to that of naive mice. These findings indicate that the sympathetic nervous system plays a primary role in cold acclimation.

The effect of exercise training on cold tolerance in adult and old C57BL/6J mice.

In order to ascertain the effect of aging on cross-adaptation between exercise training and cold tolerance, we studied cold tolerance in adult and old C57BL/6J male mice before and after 6 weeks of an exercise regimen of moderate intensity. There were two age groups of 32 mice each, including 12-month-old (adult) and 24-month-old (aged) mice equally divided into control and exercise groups. The exercise consisted of daily runs on a treadmill (1 hr/day, 5 days/week) for 6 weeks, while the control mice spent the same time on a stationary treadmill. All mice were subjected to a cold stress test (3-hr partial restraint at 6 degrees C) prior to and following the designated regimen. The results revealed a statistically significant interaction between age and exercise training. In adult mice, exercise resulted in a reduction of cold-induced heat production and weakening of cold tolerance, while in aged mice, the opposite effect was observed; i.e., an increase in cold-induced heat production accompanied by greater cold tolerance. However, only the attenuating effect on cold tolerance of adults was statistically significant. The results of our experiments do not support the existence of cross-adaptation between exercise training and cold tolerance. They indicate, however, that exercise training affects the cold tolerance in adult and old mice through different physiological mechanisms.

Effect of exercise on cold tolerance and metabolic heat production in adult and aged C57BL/6J mice.

Two groups of adult (12-mo-old) and two groups of aged (24-mo-old) C57BL/6J male mice were subjected to a standardized cold stress test (3-h partial restraint at 6 degrees C). One group from each age group was tested in the morning, and the other was tested in the afternoon. Half of the mice were subjected to running exercise on a treadmill during 1 h before the cold stress test. The other half were placed on a nonoperational treadmill for 1 h before the cold stress test. One hour of exercise resulted in improvement of cold tolerance during the subsequent cold exposure in both age groups but only during afternoon testing. Improvement in cold tolerance was not accompanied by an elevation of cold-induced metabolic heat production in adult mice. Metabolic heat production in aged mice showed only modest elevation. The discrepancy between improvement in cold tolerance and lack of elevation of metabolic heat production suggests that the primary mechanism for augmentation of cold tolerance after exercise in the afternoon is an improvement in cold-induced vasoconstriction of skin vessels, which is probably normally compromised in the afternoon.

Sympathetic nervous activity to brown adipose tissue increases in cold-tolerant mice.

Brown adipose tissue (BAT) is thought to be responsible for increased heat production in cold-acclimated rodents. We measured sympathetic nerve activity (SNA) in interscapular BAT (IBAT) during cold stimulation in cold-acclimated C57BL/6J mice (ACCLI). Cold acclimation was achieved (cold tolerance was increased) by repeated exposure to cold stress every other week for 3 weeks. We compared SNA in these animals with SNA in mice that had no previous cold stress experience (naive). During the test, mice were anesthetized by urethane and isoflurane and were paralyzed with vecuronium bromide. Sympathetic nerve activity was recorded directly from one of the fine nerves to IBAT. The animal's body caudal to the pelvic area was covered with a plastic bag containing a slurry of ice water to decrease colonic temperature 7 degrees C below control level, which took approximately 20 min. Interscapular BAT-SNA increased during cold stress in both groups, but ACCLI mice had higher IBAT-SNA during cold stress than naive mice. These findings confirmed the hypothesis that during the acute cold exposure, cold-acclimated mice have greater sympathetic outflow to BAT adipocytes.

Metabolic heat production and cold tolerance during cold stress of different intensity of adult and aged male C57BL/6J mice.

Adult and aged male C57BL/6J mice were subjected to a 3-h cold stress test at either 24 degrees C, 18 degrees C, 12 degrees C, or 6 degrees C. Body mass was measured before the test, and colonic temperature, O2 consumption, and CO2 production were measured during the test. The slopes of colonic temperature over time of test and the mean metabolic heat production were calculated for each animal. While adult mice had a relatively small reduction in colonic temperature during the test at all four ambient temperatures, in the aged mice ambient temperatures resulted in steeper reductions of colonic temperature. In adult mice, an increase in metabolic heat production was proportional to ambient cold. The thermogenic response of aged mice at 24 degrees C and at 18 degrees C was similar to adult mice, suggesting that the ability of aged mice to respond to cold by increasing heat production does not diminish with age. However, in aged mice metabolic heat production at 12 degrees C and 6 degrees C was significantly below that of adult mice, which indicated a reduced capacity for thermogenesis.

Aged C57BL/6J mice respond to cold with increased sympathetic nervous activity in interscapular brown adipose tissue.

Aged, male C57BL/6J mice produce less heat than adults during cold, which may lead to a reduced ability to maintain core temperature, but the underlying mechanisms of the decreased heat production in aged mice are still unclear. We measured sympathetic nervous activity (SNA) to interscapular brown adipose tissue (IBAT) in aged mice and compared this activity with that of adults. Mice were anesthetized by urethane and isoflurane, and SNA was recorded from one of the fine nerves to IBAT. The animal's body caudal to the pelvic area was covered with a plastic bag containing iced-water to decrease colonic temperature 7 degrees C below control over 20 minutes. SNA to IBAT (IBAT-SNA) increased during cold in both groups, but aged mice had higher IBAT-SNA before and during cold. These findings indicate that neither the ability of aged mice to detect cold nor their ability to generate sympathetic outflow to BAT is deficient.

Role of postural status in the nocturnal hemodynamic patterns of nonhuman primates.

We compared the nocturnal hemodynamic patterns of seven tethered monkeys (Macaca mulatta) with those of seven chaired animals to determine whether the overnight changes are comparable in the two conditions. In both groups, we found a consistent hemodynamic pattern characterized by an overnight fall in cardiac output and central venous pressure and a rise in total peripheral resistance that maintained blood pressure homeostasis. The pattern of overnight change occurred despite major differences in response levels: cardiac output and central venous pressure were significantly elevated, and total peripheral resistance was significantly reduced at all times (from 1800 to 1200 h the following day) in the chaired animals relative to the tethered animals. This difference was probably due to an expanded plasma volume in the chaired animals, because stroke volume was also significantly elevated. Because the nocturnal hemodynamic pattern occurred under both conditions, it is likely that it is a stable biologic effect, which is probably related to an overnight loss in fluid volume that is not replaced in animals that sleep throughout the night.