Effects of chronic hypoxia on MK-801-induced changes in the acute hypoxic ventilatory response.

Chronic hypoxia increases the sensitivity of the central nervous system to afferent input from carotid body chemoreceptors. We hypothesized that this process involves N-methyl-D-aspartate (NMDA) receptor-mediated mechanisms and predicted that chronic hypoxia would change the effect of the NMDA receptor blocker dizocilpine (MK-801) on the poikilocapnic hypoxic ventilatory response (HVR). Male Sprague-Dawley rats were studied before and after acclimatization to hypoxia (70 Torr inspiratory Po(2) for 9 days). We measured ventilation (VI) and the HVR before and after systemic MK-801 treatment (3 mg/kg ip). MK-801 resulted in a constant respiratory frequency (approximately 175 min(-1)) during acute exposure to 10% and 30% O(2) before and after acclimatization. MK-801 had no effect on tidal volume (VT) before acclimatization, but it significantly decreased Vt when the animals were breathing 10% O(2) after acclimatization. The net effect of MK-801 was to eliminate the O(2) sensitivity of Vi before (via changes in respiratory frequency) and after (via changes in VT) acclimatization. Hence, chronic hypoxia altered the effect of MK-801 on the acute HVR, primarily because of increased effects on Vt. This indicates that changes in NMDA receptor-mediated neurotransmission may be involved in ventilatory acclimatization to hypoxia. However, further experiments are necessary to determine the precise location of such plasticity in the central nervous system.     

GABA-mediated neurotransmission in the nucleus of the solitary tract alters resting ventilation following exposure to chronic hypoxia in conscious rats

This study investigated whether changes in GABA-mediated neurotransmission within the nucleus of the solitary tract (NTS) contribute to the changes in breathing (resting ventilation and the acute HVR) that occur following exposure to chronic hypoxia (CH). Rats were exposed to 9 days of hypobaric hypoxia (0.5 atm) and then subjected to acute hypoxic breathing trials before and after bilateral microinjections of GABA, bicuculline (a GABAA-receptor antagonist), or bicuculline plus CGP-35348 (a GABAB receptor antagonist) into the caudal regions of the NTS. Breathing was measured using whole body plethysmography. CH caused an increase in resting ventilation when the animals were breathing 30% O2 but did not alter ventilation during acute hypoxia (10% O2). GABA alone had no effect on breathing in either the control or chronically hypoxic rats. Bicuculline and bicuculline/CGP had no effect on breathing in control rats. Following CH, bicuculline and bicuculline/CGP reduced minute ventilation (VI) during acute exposure to 30% O2 but had no effect during acute exposure to 10% O2. The bicuculline-induced reduction in VI resulted from a decrease in breathing frequency (fR) and tidal volume (VT). The bicuculline/CGP-induced reduction in VI was due to a decrease in fR with no change in VT. The results suggest that changes in GABA receptor-mediated neurotransmission, within the NTS, are involved in the increase in resting ventilation that occurs following CH.     

Effects of hypoxia and cold acclimation on thermoregulation in the rat.

The effects of hypoxia (inspired O2 fraction = 0.12) on thermoregulation and on the different sources of thermogenesis were studied in rats before and after periods of 1-4 wk of cold acclimation. Measurements of metabolic rate (VO2) and body temperature (Tb) were made at 5-min intervals, and shivering activity was recorded continuously in groups of rats subjected to three protocols. In protocol 1, rats were exposed to normoxia to an ambient temperature (Ta) of 5 degrees C for 2 h. In protocol 2, at Ta of 5 degrees C, rats were exposed for 30 min to normoxia, then for 45 min to hypoxia, and finally for 30 min to normoxia. In protocol 3, in the non-cold-acclimated (NCA) rats, Ta was decreased from 30 to 5 degrees C in steps of 5 degrees C and of 30-min duration while in cold-acclimated (CA) rats at 5 degrees C for 4-wk, Ta was increased from 5 to 30 degrees C in steps of 5 degrees C and of 30-min duration. Recordings were made in normoxia and in hypoxia on different days in the same animals. The results showed that 1) in NCA rats, cold exposure in normoxia induced increases in VO2 and shivering that were proportional to the decrease in Ta; 2) in CA rats in normoxia, for a given Ta, VO2 and Tb were higher than in NCA rats, whereas shivering was generally lower; and 3) in both NCA and CA rats, hypoxia induced a transient decrease in shivering and a sustained decrease in nonshivering thermogenesis associated with a marked decrease in Tb that was about the same in NCA and CA rats. We speculate that hypoxia acts on Tb control to produce a general inhibition of thermogenesis. Nonshivering thermogenesis is markedly sensitive to hypoxia, especially demonstrable in CA rats; a recovery or even an increase in shivering can compensate for the decrease in nonshivering thermogenesis.     

Ventilatory and metabolic responses to hypoxia in the smallest simian primate, the pygmy marmoset.

The pygmy marmoset (Cebuella pygmaea) is the smallest New World Monkey (average body mass of 120-130 g). As such, it faces possible challenges to thermoregulation. Small mammals (e.g., rats) are well known to lower body temperature and metabolism in response to hypoxia; however, small primates have not been studied in this respect nor have, in general, the interactions between metabolism and ventilation. Because little is known about these responses in small primates, it seemed of great interest to assess the hypoxia-induced metabolic depression and drop in body temperature and the associated ventilatory requirements in this species under hypoxic conditions. Exposure to graded hypoxia (30 min at each of 18, 16, 14, 12, and 10% O(2)) caused body temperature to drop from the normoxic value of 39 to 37 degrees C. This was accompanied by a marked metabolic depression (O(2) consumption was approximately 68% of the normoxic value, implying a suppression of metabolism greater than that predicted from a typical value of the effect of 10 degrees C change on metabolism of 2-3 times). Minute ventilation declined in parallel to metabolism, maintaining a constant air-convection requirement during hypoxia; thus this species did not show the typical mammalian hyperventilation. Acute exposure to 10% O(2) led to a similar overall decline in metabolism and body temperature and qualitative differences in the timing of these changes. The pygmy marmoset shares some similarities in its hypoxic metabolic response with other mammals of similar size yet appears to be unique in its much diminished ventilatory response to hypoxia.     

Dopaminergic modulation of ventilation in obese Zucker rats.

To investigate the hypothesis that the impaired respiratory drive noted in morbid obesity was attributable to altered dopaminergic mechanisms acting on peripheral and/or central chemoreflex sensitivity, seven obese and seven lean Zucker rats were studied at 11 wk of age. Ventilation (VE) was measured by the barometric technique during hyperoxic (100% O(2)), normoxic (21% O(2)), hypoxic (10% O(2)), and hypercapnic (7% CO(2)) exposures after the administration of vehicle (control), haloperidol [Hal, 1 mg/kg, a central and peripheral dopamine (Da) receptor antagonist], or domperidone (Dom, 0.5 mg/kg, a peripheral Da receptor antagonist). In both lean and obese rats, Hal increased tidal volume and decreased respiratory frequency during hyperoxia or normoxia, resulting in an unchanged VE. In contrast, Dom did not affect tidal volume, frequency, or VE during hyperoxia or normoxia. During hypoxia, however, VE significantly increased from 1,132 +/- 136 to 1,348 +/- 98 ml. kg(-1). min(-1) (P < 0.01) after the administration of Dom in obese rats, whereas no change was observed in lean rats. Hal significantly decreased VE during hypoxia compared with control in lean but not obese rats. In both lean and obese rats, Hal decreased VE in response to hypercapnia, whereas Dom had no effect. Our major findings suggest that peripheral chemosensitivity to hypoxia in obese Zucker rats is reduced as a result of an increased dopaminergic receptor modulation in the carotid body.     

Ventilatory effects and interactions with change in PaO2 in awake goats.

We utilized selective carotid body (CB) perfusion while changing inspired O2 fraction in arterial isocapnia to characterize the non-CB chemoreceptor ventilatory response to changes in arterial PO2 (PaO2) in awake goats and to define the effect of varying levels of CB PO2 on this response. Systemic hyperoxia (PaO2 greater than 400 Torr) significantly increased inspired ventilation (VI) and tidal volume (VT) in goats during CB normoxia, and systemic hypoxia (PaO2 = 29 Torr) significantly increased VI and respiratory frequency in these goats. CB hypoxia (CB PO2 = 34 Torr) in systemic normoxia significantly increased VI, VT, and VT/TI; the ventilatory effects of CB hypoxia were not significantly altered by varying systemic PaO2. We conclude that ventilation is stimulated by systemic hypoxia and hyperoxia in CB normoxia and that this ventilatory response to changes in systemic O2 affects the CB O2 response in an additive manner.     

Chronic hypoxia abolishes posthypoxia frequency decline in the anesthetized rat

In anesthetized rats, increases in phrenic nerve amplitude and frequency during brief periods of hypoxia are followed by a reduction in phrenic nerve burst frequency [posthypoxia frequency decline (PHFD)]. We investigated the effects of chronic exposure to hypoxia on PHFD and on peripheral and central O2-sensing mechanisms. In Inactin-anesthetized (100 mg/kg) Sprague-Dawley rats, phrenic nerve discharge and arterial pressure responses to 10 s N2 inhalation were recorded after exposure to hypoxia (10 +/- 0.5% O2) for 6-14 days. Compared with rats maintained at normoxia, PHFD was abolished in chronic hypoxic rats. Because of inhibition of PHFD, the increased phrenic burst frequency and amplitude after N2 inhalation persisted for 1.8-2.8 times longer in chronic hypoxic (70 s) compared with normoxic (25-40 s) rats (P < 0.05). After acute bilateral carotid body denervation, N2 inhalation produced a short depression of phrenic nerve discharge in both chronic hypoxic and normoxic rats. However, the degree and duration of depression of phrenic nerve discharge was smaller in chronic hypoxic compared with normoxic rats (P < 0.05). We conclude that after exposure to chronic hypoxia, a reduction in PHFD contributes to an increased duration of the acute hypoxic ventilatory response in anesthetized rats. Furthermore, after exposure to chronic hypoxia, the central network responsible for respiration is more resistant to the depressant effects of acute hypoxia in anesthetized rats.     

Effect of two paradigms of chronic intermittent hypoxia on carotid body sensory activity.

Reflexes arising from the carotid bodies may play an important role in cardiorespiratory changes evoked by chronic intermittent hypoxia (CIH). In the present study, we examined whether CIH affects the hypoxic sensing ability of the carotid bodies and, if so, by what mechanisms. Experiments were performed on adult male rats (Sprague-Dawley, 250-300 g) exposed to two paradigms of CIH for 10 days: 1) multiple exposures to short durations of intermittent hypoxia per day (SDIH; 15 s of 5% O(2) + 5 min of 21% O(2), 9 episodes/h, 8 h/day) and 2) single exposure to longer durations of intermittent hypoxia per day [LDIH; 4 h of hypobaric hypoxia (0.4 atm/day) + 20 h of normoxia]. Carotid body sensory response to graded isocapnic hypoxia was examined in both groups of animals under anesthetized conditions. Hypoxic sensory response was significantly enhanced in SDIH but not in LDIH animals. Similar enhancement in hypoxic sensory response was also elicited in ex vivo carotid bodies from SDIH animals, suggesting that the effects were not secondary to cardiovascular changes. SDIH, however, had no significant effect on the hypercapnic sensory response. The effects of SDIH on the hypoxic sensory response completely reversed after SDIH animals were placed in a normoxic environment for an additional 10 days. Previous treatment with systemic administration of O(2)(-)* radical scavenger prevented SDIH-induced augmentation of the hypoxic sensory response. These results demonstrate that SDIH but not LDIH results in selective augmentation of the hypoxic response of the carotid body and O(2)(-)* radicals play an important role in SDIH-induced sensitization of the carotid body.     

莪术油注射液对慢性低氧大鼠学习与记忆的影响

本文旨在探讨莪术油注射液对慢性低氧大鼠学习与记忆的影响及其可能机制.将Sprague.Dawley大鼠随机分为对照组、慢性低氧组、5 mg/kg体重莪术油组、10 mg/kg体重莪术油组、20 mg/kg体重莪术油组,每组14只.慢性低氧处理采用低氧舱内吸入大约10%O2、5%CO2,饲养10 h/d,持续饲养28 d.莪术油组大鼠低氧处理前腹腔注射相应浓度的莪术油注射液.实验结束次日,通过Morris水迷宫测试各组动物学习和记忆成绩的变化;测定各组大鼠血清和海马组织丙二醛(malonaldehyde,MDA)含量和超氧化物歧化酶(superoxide dismutase,SOD)活性以及海马组织Ca2 浓度([Ca2 i]);通过免疫组织化学和Western blot检测磷酸化Ca2 /钙调蛋白依赖性蛋白激酶Ⅱ(phosphorylated Ca2 /calmodulin-dependent pro-tein kinase Ⅱ,p-CaMKII)在海马组织和胞膜上的表达.结果显示,与对照组相比,慢性低氧组大鼠隐蔽平台的逃避潜伏期明显延长(P<0.05),血清和海马组织MDA含量明显增高,SOD活性显著降低(P<0.05,P<0.01),海马组织[Ca2 ]i明显增高(P<0.01),海马P-CaMKII表达量显著降低(P<0.01).与慢性低氧组比较,莪术油各组发生以下变化:10、20 mg/kg体重莪术油组大鼠隐蔽平台的逃避潜伏期显著缩短(P<0.05):5、10、20 mg/kg体重莪术油组大鼠血清和海马组织MDA含量均显著降低(P相似文献   

游泳运动对低氧性肺动脉高压大鼠肺组织apelin及其受体表达的影响

目的:探讨游泳运动对大鼠肺组织新的小分子活性肽apelin及其受体(APJ)表达的影响。方法:45只雄性大鼠随机分成三组:正常对照组、低氧组(七周)和游泳组(低氧+游泳锻炼七周组,低氧3周后,于每天入低氧舱前行无负重游泳运动60 min,每天1次)。七周后测定各组大鼠平均肺动脉压(mPAP)、右心室与左心室加室间隔的重量比[RV/(LV+S)]、肺细小动脉管壁面积/管总面积(WA/TA)、管腔面积/管总面积(CA/TA)及中膜厚度(PAMT)。免疫蛋白印迹与免疫组化法测定肺组织apelin/APJ的蛋白表达。结果:①低氧组mPAP和RV/(LV+S)比正常对照组分别高73.6%和31.2%(P均<0.01),而游泳组比低氧组分别低21.1%和8.9%(P均<0.05)。②低氧组WA/TA和PAMT较正常对照组分别高70.8%和102%,而游泳组较低氧组分别低24.8%和40.1%(P均<0.01)。低氧组CA/TA较正常对照组低15.1%,而游泳组较低氧组高10.3%(P均<0.01)。③低氧组肺组织apelin蛋白表达较正常对照组上调374%(P<0.01),而APJ蛋白表达下调87.1%(P均<0.01);游泳组肺组织apelin蛋白表达较低氧组下调48%,而APJ蛋白表达上调287%(P均<0.01)。④apelin蛋白主要在血管外膜及炎症细胞胞浆内表达,APJ蛋白主要在血管内膜、外膜及炎症细胞上表达。结论:游泳运动减缓肺动脉高压和肺血管重塑作用可能与调节肺组织apelin/APJ系统的表达有关。     

Dopamine and ventilatory effects of hypoxia and almitrine in chronically hypoxic rats

We hypothesized that the temporary blunted ventilatory response to hypoxia seen in chronically hypoxic rats could be related to the increased amount of dopamine found in their carotid bodies. Rats, kept 2-3 wk in 10% O2, showed reduced nonisocapnic ventilatory responses to 21-12% inspiratory O2 fraction compared with control rats. Stimulus-response curves to almitrine, which simulates the action of hypoxia on the carotid body, were also depressed in chronically hypoxic rats. Responses to hypoxia and almitrine were significantly correlated in the two groups of rats. Dopamine depressed ventilation during normoxia, hypoxia, and almitrine stimulation in both groups, an action abolished by the dopamine-2 antagonist domperidone. Domperidone slightly increased responses to hypoxia and almitrine in control rats but had a greater enhancing effect in chronically hypoxic rats, such that there was no longer a difference between the responses of the two groups.     

Thermal and respiratory control in young rats exposed to cold during postnatal development

We questioned to what extent sustained increases in metabolic rate during the neonatal period may influence the development of thermal and respiratory control. Male rats were exposed to cold (14 degrees C) for the first 3 weeks, which increased metabolic rate with small effects on body growth. Measurements were performed at 1 month of age, when the body weight of the Cold group averaged approximately 88% of Controls. In Cold rats, the concentration of the uncoupling protein of the brown adipose tissue was increased. Acute exposures to different ambient temperatures (5, 15, 25 and 35 degrees C) provoked changes in body temperature similar in Cold and in Control rats. At these temperatures, small differences in the absolute values of oxygen consumption (Vdot;(O(2))) between the two groups could be explained by the differences in body weight. Hematocrit and lung weight of Cold rats were as in Controls, but the lung protein-DNA ratio was increased because of a drop in lung cellularity. The resting ventilation-oxygen consumption ratio (Vdot;(E)/Vdot;(O(2))) was similar between Cold and Controls. Also the changes in Vdot;(O(2)) and Vdot;(E) during acute hypoxia (10% O(2)) or hypercapnia (5% CO(2)), and the corresponding hyperventilatory responses (increases in Vdot;(E)/Vdot;(O(2))) did not significantly differ between the two groups. In conclusion, in the rat, the increased metabolic requirements caused by cold exposure during the early postnatal phases improved the thermogenic capacity, while having negligible impact on the development of respiratory control.     

Effects of acute hypoxia and hyperoxia on respiratory rate in albino rats chronically exposed to hypoxia

Changes in respiratory frequencies with hypoxic or hyperoxic exposure were studied in: 12 normoxic control rats (N) born and raised in normoxic environment at sea level; 12 rats (A) born and raised in normoxic environment at sea level exposed to normobaric hypoxia (10% O2 in N2) as adults; 12 rats of first generation (G1) raised in the above mentioned hypoxic environment since a few hours after birth; 12 rats of third generation (G3) conceived and born in the hypoxic environment of hypoxic parents of second generation and maintained continuously under hypoxic conditions until their utilization. The response of A rats to 10% O2 and 7% O2 breathing was elevated (57% and 86% over air breathing). The mean respiratory frequency of A rats exposed to 7% O2 rose to a greater extent than did that of N rats. The G1 and G3 rats were less responsive to 7% O2 (64% and 37% over air breathing, respectively) than N and A rats; however, in G1 rats the exposure to 7% O2 produced a greater rise of frequency than in G3 rats. Furthermore A rats, G1 rats and G3 rats were less responsive to 97% O2 breathing (19%, 19% and 11% below air breathing, respectively). Comparing these data with previous findings we suggest that, with chronic exposure to hypoxia, changes in ventilatory response to hypoxia and hyperoxia occur in the following manner: I) loss of response to hypoxia if chronic exposure is begun in the immediate postnatal period; 2) degree of response to hypoxia or hyperoxia influenced by duration of chronic exposure.     

Hering-Breuer reflex in conscious newborn rats: effects of changes in ambient temperature during hypoxia.

In a previous study in conscious normoxic newborn rats, we found that the strength of the Hering-Breuer reflex (HB reflex) was greater (188%) at high (36 degrees C) than at low (24 degrees C) ambient temperature (T(a); D. Merazzi and J. P. Mortola. Pediatr. Res. 45: 370-376, 1999). We now asked what the effect would be of changes in T(a) during hypoxia. Rat pups at 3-4 days of age were studied in a double-chamber airflow plethysmograph. The HB reflex was induced by negative body surface pressures of 5 or 10 cmH(2)O and quantified from the inhibition of breathing during maintained lung inflation. Rats were first studied at T(a) = 32 degrees C in normoxia, followed by hypoxia (10% O(2) breathing). During hypoxia, oxygen consumption (VO(2)) averaged 47%, and HB reflex 115%, of the corresponding normoxic values, confirming that in the newborn, differently from the adult, hypoxia does not decrease the strength of the HB reflex. As hypoxia was maintained, lowering T(a) to 24 degrees C or increasing it to 36 degrees C, on average, had no significant effects on VO(2) and the HB reflex. However, with 5-cmH(2)O inflations, the HB reflex during the combined hypoxia and hyperthermia was significantly stronger than in normoxia. We conclude that in conscious newborn rats during normoxia the T(a) sensitivity of the HB reflex is largely mediated by the effects of T(a) on thermogenesis and VO(2); in hypoxia, because thermogenesis is depressed and VO(2) varies little with T(a), the HB reflex is T(a) independent. The observation that the reflex response to lung inflations during hypoxic hyperthermia can be greater than in normoxia may be of importance in the pathophysiology of apneas during the neonatal period.     

Chronic hypoxia induced ultrastructural changes in the rat adrenal zona glomerulosa

The adrenal cortex plays an important role in adaptation to various forms of stress, including hypoxia. While physiological changes in the aldosterone metabolism during hypoxia have been extensively described, few studies have focused on the morphological changes in the adrenal glands under chronic hypoxia. We studied the ultrastructure of the zona glomerulosa of 6-month-old Wistar rats exposed to chronic normobaric hypoxia. Animals were divided into two groups: control (n=12) and hypoxic (n=12). In this latter group, the animals were kept at 7% O2 concentration after a gradual adaptation (21, 15, 12, 10, 8, 7 vol% O2). The duration of the study was 112 days. In comparison with normoxic rats, body weight and adrenal gland weight of hypoxic animals was significantly reduced by 18.5% (p=0.006) and 14.7% (p=0.001) respectively. The thickness of the zona glomerulosa decreased due to atrophy of cells. The main ultrastructural changes observed were: 1) a decrease in, or complete elimination of, lipid droplet content; 2) a marked increase in lysosome number; and 3) the presence of giant mitochondria. Our findings show that rats fail to adapt to severe chronic hypoxia. The ultrastructural changes in the zona glomerulosa found in the present study could reflect changes in the aldosterone pathway.     

Nonshivering thermogenesis in the rat. I. The relation between drug-induced changes in thermogenesis and changes in the concentration of plasma cyclic AMP.

Barbital-sedated, cold-acclimated (CA) or warm-acclimated (WA) rats were given different doses and combinations of noradrenaline, theophylline, and the adrenergic-blocking agents propranolol and phentolamine, to stimulate or inhibit calorigenesis in various ways. To see whether the effects of these drugs on calorigenesis could be ascribed to effects on the adenylate cyclase (EC 4.6.1.1) - cyclic AMP system, and to try to assess thereby the significance of this system in the regulation of nonshivering thermogenesis (NST), changes in the concentration of plasma cyclic AMP were measured as an index (Broadus, A.E., Hardman, J.G., Kaminsky, N. I., Ball, J. H., Sutherland, E.W., and Liddle, G. W.: 1971. Ann. N.Y. Acad. Sci. 185, 50-60) of changes in tissue levels of cyclic AMP. In CA rats, which have a severalfold greater capacity for NST than WA rats, calorigenic responses to noradrenaline, theophylline, noradrenaline plus theophylline, or phentolamine plus theophylline were as much as four times larger than in WA rats, However, the changes in level of plasma cyclic AMP produced by each of these and other treatments were virtually the same for both groups. It would appear, therefore, that the difference between WA and CA rats in ability to produce heat by NST is not a function of the amplitude of changes in tissue levels of cyclic AMP. Nevertheless, it was also observed, and was particularly striking in CA rats, that when a drug or combination of drugs had a stimulatory, inhibitory, or synergistic effect on calorigenesis, it had a similar effect with respect to elevation of plasma cyclic AMP. Altogether, the results indicate that adenylate cyclase and cyclic AMP are likely to be participants in the regulation of NST in the rat, but that they would be subservient in this regard to whatever factors are responsible for acclimation-related differences in capacity for NST.     

Shivering and nonshivering thermogenesis in exercised cold-deacclimated rats

Norepinephrine (NE)-induced increase in oxygen consumption (VO2) and colonic temperature (Tc) was greater in cold-acclimated rats housed at 4 degrees C for 4 weeks (CA) than warm-acclimated controls housed at 24 degrees C for 4 weeks (WA). On the other hand, shivering activity measured at 4 degrees C was less in CA than in WA, while propranolol administration eliminated the difference between these two groups by enhancing shivering in CA. Wet weight and protein content of interscapular brown adipose tissue (IBAT) were greater in CA than in WA. Following cold acclimation, CA were deacclimated at 24 degrees C for 5 weeks. During deacclimation, half of this latter group were forced to run (15 m.min-1 for 1 h) every day (CD-T) while the remaining rats remained sedentary (CD-S). Shivering activity assessed at 4 degrees C 4 weeks after commencing cold deacclimation was significantly less in CD-T than in CD-S and the difference disappeared following propranolol injection. VO2 and Tc responses to NE injection measured 1, 2 and 5 weeks after commencing cold deacclimation did not differ between CD-S and CD-T. Although IBAT weight was lighter in CD-T than in CD-S, its total protein content was not different between the latter two groups of rats. These results suggest that a greater degree of NE-independent nonshivering thermogenesis (NST) is retained in rats that are exercised during the process of deacclimation as compared with animals that are sedentary. This difference in NST would not seem to be directly related to BAT thermogenic capacity.     

Acute pulmonary alveolar hypoxia increases lung and plasma endothelin-1 levels in conscious rats.

To investigate the effect of pulmonary alveolar hypoxia on the synthesis and release of endothelin (ET)-1, ET-1-like immunoreactivity (-LI) levels of the lung and plasma were measured in conscious unrestrained rats under hypoxic conditions. Sixty-min exposure to alveolar hypoxia (10% O2 or 5% O2) increased the ET-1-LI level in the lung. The plasma ET-1-LI level in hypoxic rats also increased significantly. The increase of plasma and lung ET-1-LI levels were parallel to the severity of hypoxia. These results demonstrates that acute pulmonary alveolar hypoxia increases lung and plasma ET-1-LI levels in conscious unrestrained rats, suggesting a possible physiological or pathophysiological significance of ET in alveolar hypoxia.     

Influence of housing conditions from weaning to adulthood on the ventilatory, thermoregulatory, and endocrine responses to hypoxia of adult female rats

Housing conditions affect animal physiology. We previously showed that the hypoxic ventilatory and thermoregulatory responses to hypoxia of adult male rats housed in triads during the juvenile period (postnatal day 21 to adulthood) were significantly reduced compared with animals housed in pairs. Because sex hormones influence development and responsiveness to environmental stressors, this study investigated the impact of housing on the respiratory and thermoregulatory physiology of female rats. Since neonatal stress attenuates the hypoxic ventilatory response (HVR) of female rats at adulthood, experiments were performed both on "control" (undisturbed) animals and rats subjected to neonatal maternal separation (NMS; 3 h/day, postnatal days 3-12). At adulthood, ventilatory activity was measured by whole body plethysmography under normoxic and hypoxic conditions [fraction of inspired oxygen (Fi(O(2))) = 0.12; 20 min]. The ventilatory and body temperature responses to hypoxia of female rats raised in triads were reduced compared with rats housed in pairs. Housing female rats in triads did not affect basal or hypoxic plasma corticosterone levels but did increase levels of estradiol significantly. We conclude that modest changes in housing conditions (pairs vs. triads) from weaning to adulthood does influence basic homeostatic functions such as temperature and respiratory regulation. Triad housing can reverse the manifestations of respiratory instability at adulthood induced by stressful neonatal treatments. This should raise awareness of the benefits of increasing social interactions in clinical settings but also caution researchers of the potential impact of such subtle changes on experimental protocols and interpretation of results.     

Neonatal maternal separation enhances phrenic responses to hypoxia and carotid sinus nerve stimulation in the adult anesthetized rat.

In awake animals, our laboratory recently showed that the hypoxic ventilatory response of adult male (but not female) rats previously subjected to neonatal maternal separation (NMS) is 25% greater than controls (Genest SE, Gulemetova R, Laforest S, Drolet G, and Kinkead R. J Physiol 554: 543-557, 2004). To begin mechanistic investigations of the effects of this neonatal stress on respiratory control development, we tested the hypothesis that, in male rats, NMS enhances central integration of carotid body chemoafferent signals. Experiments were performed on two groups of adult male rats. Pups subjected to NMS were placed in a temperature-controlled incubator 3 h/day from postnatal day 3 to postnatal day 12. Control pups were undisturbed. At adulthood (8-10 wk), rats were anesthetized (urethane; 1.6 g/kg), paralyzed, and ventilated with a hyperoxic gas mixture [inspired O2 fraction (Fi(O2)) = 0.5], and phrenic nerve activity was recorded. The first series of experiments aimed to demonstrate that NMS-related enhancement of the inspiratory motor output (phrenic) response to hypoxia occurs in anesthetized animals also. In this series, rats were exposed to moderate, followed by severe, isocapnic hypoxia (Fi(O2) = 0.12 and 0.08, respectively, 5 min each). NMS enhanced both the frequency and amplitude components of the phrenic response to hypoxia relative to controls, thereby validating the use of this approach. In a second series of experiments, NMS increased the amplitude (but not the frequency) response to unilateral carotid sinus nerve stimulation (stimulation frequency range: 0.5-33 Hz). We conclude that enhancement of central integration of carotid body afferent signal contributes to the larger hypoxic ventilatory response observed in NMS rats.