Production of proteolytic enzymes in mast cells, fibroblasts, vascular smooth muscle and endothelial cells cultivated under normoxic or hypoxic conditions.

Matrix metalloproteinases (MMPs) is a family of proteolytic enzymes involved in remodeling of extracellular matrix. Although proteolytic enzymes are produced by many cell types, mast cells seem to be more important than other types in remodeling of pulmonary arteries during hypoxia. Therefore, we tested in vitro production of MMPs and serine proteases in four cell types (mast cells, fibroblasts, vascular smooth muscle cells and endothelial cells) cultivated for 48 h under normoxic or hypoxic (3% O2) conditions. MMP-13 was visualized by immunohistochemistry, MMP-2 and MMP-9 were detected by zymography in cell lysates. Enzymatic activities (MMPs, tryptase and chymase) were estimated in the cultivation media. Hypoxia had a minimal effect on total MMP activity in the cultivation media of all types of cells, but immunofluorescence revealed higher intensity of MMP-13 in the cells exposed to hypoxia except of fibroblasts. Tryptase activity was three times higher and chymase activity twice higher in mast cells cultivated in hypoxia than in those cultured in normoxia. Among all cell types studied here, mast cells are the most abundant source of proteolytic enzymes under normoxic and hypoxic conditions. Moreover, in these cells hypoxia increases the production of both specific serine proteases tryptase and chymase, which can act as MMPs activators.

Hyperoxia blunts acute hypoxia- and PGF2alpha-induced pulmonary vasoconstriction in chronically hypoxic rats.

We investigated the influence of oxygenation of in vitro lung preparation on the pulmonary vascular reactivity. Small pulmonary vessels isolated from adult male Wistar rats exposed for 4 days to hypoxia (F(iO2) = 0.1, group CH) were compared with those of normoxic controls (group N). The bath in the chamber of small vessel myograph was saturated with gas mixture containing either 21% or 95% of O(2) with 5% CO(2) and we measured the reactions of vessels to acute hypoxic challenge with 0% O(2) or to PGF(2alpha). We did not observe any difference of the contractile responses between both groups when the normoxic conditions were set in the bath. When the bath oxygenation was increased to 95% O(2), the contractions induced by hypoxic challenge and PGF(2alpha) decreased in chronically hypoxic rats and did not change in normoxic controls. We hypothesize that reduced reactivity of vessels from hypoxic rats in hyperoxia results from the effect of chronic hypoxia on Ca(2+) signaling in the vascular smooth muscle, which is modulated by increased free radical production during the exposure to chronic hypoxia and further hyperoxia.

Hypercapnia attenuates hypoxic pulmonary hypertension by inhibiting lung radical injury.

Chronic lung hypoxia results in hypoxic pulmonary hypertension. Concomitant chronic hypercapnia partly inhibits the effect of hypoxia on pulmonary vasculature. Adult male rats exposed to 3 weeks hypoxia (Fi(02)=0.1) combined with hypercapnia (Fi(C02)=0.04-0.05) had lower pulmonary arterial blood pressure, increased weight of the right heart ventricle, and less pronounced structural remodeling of the peripheral pulmonary arteries compared with rats exposed only to chronic hypoxia (Fi(02)=0.1). According to our hypothesis, hypoxic pulmonary hypertension is triggered by hypoxic injury to the walls of the peripheral pulmonary arteries. Hypercapnia inhibits release of both oxygen radicals and nitric oxide at the beginning of exposure to the hypoxic environment. The plasma concentration of nitrotyrosine, the marker of peroxynitrite activity, is lower in hypoxic rats exposed to hypercapnia than in those exposed to hypoxia alone. Hypercapnia blunts hypoxia-induced collagenolysis in the walls of prealveolar pulmonary arteries. We conclude that hypercapnia inhibits the development of hypoxic pulmonary hypertension by the inhibition of radical injury to the walls of peripheral pulmonary arteries.

In vitro hypoxia increases production of matrix metalloproteinases and tryptase in isolated rat lung mast cells.

Chronic hypoxia results in hypoxic pulmonary hypertension characterized by fibrotization and muscularization of the walls of peripheral pulmonary arteries. This vessel remodeling is accompanied by an increase in the amount of lung mast cells (LMC) and the presence of small collagen cleavage products in the vessel walls. We hypothesize that hypoxia activates LMC, which release matrix metalloproteinases (MMPs) cleaving collagen and starting increased turnover of connective tissue proteins. This study was designed to determine whether in vitro hypoxia stimulates production of MMPs in rat LMC and increases their collagenolytic activity. The LMC were separated on the Percoll gradient and then were divided into two groups and cultivated for 24 h in 21 % O(2) + 5 % CO(2) or in 10 % O(2) + 5 % CO(2). Presence of the rat interstitial tissue collagenase (MMP-13) in LMC was visualized by immunohistological staining and confirmed by Western blot analysis. Total MMPs activity and tryptase activity were measured in both cultivation media and cellular extracts. Exposure to hypoxia in vitro increased the amount of cells positively labeled by anti-MMP-13 antibody as well as activities of all measured enzymes. The results therefore support the concept that LMC are an important source of increased collagenolytic activity in chronic hypoxia.

Oxidative stress in the lung tissue--sources of reactive oxygen species and antioxidant defence.

Reactive oxygen species are oxygen-based molecules readily reacting with various compounds. It is already known that they play significant role in many physiological as well as pathological body processes. The aim of our review is to briefly summarize our knowledge of possible ROS sources in the lung tissue.

Depletion of alveolar macrophages attenuates hypoxic pulmonary hypertension but not hypoxia-induced increase in serum concentration of MCP-1.

Exposure to hypoxia, leading to hypoxic pulmonary hypertension (HPH), is associated with activation of alveolar macrophages (AM). However, it remains unclear how AM participate in this process. There are studies which imply that the AM product monocyte chemoattractant protein-1 (MCP-1) plays an important role. Thus we tested: 1. if the selective elimination of AM attenuates HPH in rats, 2. the correlation of MCP-1 plasmatic concentrations with the presence and absence of AM during exposure to hypoxia, 3. the direct influence of hypoxia on MCP-1 production in isolated AM. We found that experimental depletion of AM attenuated the chronic hypoxia-induced increase in mean pulmonary arterial pressure, but did not affect the serum MCP-1 concentrations. Furthermore, the MCP-1 production by AM in vitro was unaffected by hypoxia. Thus we conclude that AM play a significant role in the mechanism of HPH, but MCP-1 release from these cells is most likely not involved in this process. The increase of MCP-1 accompanying the development of HPH probably originates from other sources than AM.

Mast cells, hypoxia and structure of the vascular bed.

Mast cells represent a heterogeneous and multifunctional cells population distributed throughout tissues. Their participation in the response to chronic hypoxia is discussed in consideration to their role in the angiogenesis and remodeling of pulmonary vasculature, including relevance of proangiogenic factors, mediators and proteolytic enzymes released by activated mast cells. Possible mechanism of mast cells activation by hypoxia is considered.

Role of vagal fibers in the hypoxia-induced increases in end-expiratory lung volume and diaphragmatic activity.

The possible role of pulmonary C fibers in the hypoxia-induced concomitant increases in end-expiratory lung volume (EELV) and in the activity of the diaphragm at the end of expiration (DE) were evaluated by measuring the effects of hypoxia (10% O2) on ventilation, EELV, and DE in eight chloralose-urethan anesthetized rats. Recordings were made before and after blocking vagal C fibers and after bilateral vagotomy. C-fiber conduction was blocked by applying capsaicin perineurally to the cervical vagi. The efficiency of C-fiber blockade was tested with intravenous capsaicin and its selectivity by the Hering-Breuer reflex. Perineural capsaicin abolished the reflex apnea induced by intravenous capsaicin and transiently reduced Hering-Breuer reflex. Perineural capsaicin affected neither ventilation, DE, and EELV in air nor the hypoxia-induced increases in these parameters. Vagotomy caused the typical changes of breathing pattern in air, but the ventilatory response to hypoxia was unchanged. Vagotomy performed during hypoxia resulted in large decreases in DE and EELV. Hypoxia increased DE and EELV in vagotomized rats but less than in intact rats. We conclude that the hypoxia-induced increases in EELV and diaphragmatic activity are probably not mediated by vagal C fibers and that vagal afferents are involved but not fully responsible for this phenomenon.

Changes in end-expiratory lung volume and diaphragmatic activity during hypoxia and hypercapnia in cats.

To assess the role of diaphragmatic activity at the end of expiration (DE) in the control of end-expiratory lung volume (EELV), 1) these two parameters were correlated in anesthetized cats breathing different gas mixtures; and 2) expiratory flow volume curves in normoxia and hypoxia together with changes in esophageal pressure were measured. The influence of volume feedback on DE control was tested by applying positive end-expiratory pressure (PEEP). The effect of anesthesia was determined by measuring DE in unanesthetized cats. In hyperoxia, DE (but not EELV) decreased. In hypocapnic hypoxia (12, 10, and 8% O2), both DE and EELV gradually increased, and these changes were significantly correlated. When normocapnia was restored in 8% O2, DE and EELV decreased but remained higher than in air. Hypercapnia affected neither DE nor EELV. PEEP blocked the hypoxia-induced increase in DE. Hypoxia decreased expiratory flow and esophageal pressure. Finally, the increases in DE at 12 and 10% O2 were more pronounced when the cats were unanesthetized. These results suggest that the increase in diaphragmatic activity induced by hypocapnic hypoxia during expiration affects expiratory flow and thoracic volume and, therefore, plays a major role in increasing EELV. This phenomenon may also be controlled by volume feedback.

Lung mechanics and end-expiratory lung volume during hypoxia in rats.

We investigated whether an hypoxia-induced increase in airway resistance mediated by vagal efferents participates in the increase in end-expiratory lung volume (EELV) observed in hypoxia. We also assessed the contribution of the end-expiratory activity of the diaphragm (DE) to this phenomenon. Therefore, we measured EELV, total lung resistance (RL), dynamic lung compliance (Cdyn), DE, and minute ventilation (VE) in anesthetized rats during normoxia and hypoxia (10% O(2)) before (control) and after administration of atropine or saline. In the control group, hypoxia increased EELV, Cdyn, DE, and VE but slightly decreased RL. These changes were unaffected by saline or atropine, except that, in the atropine-treated rats, hypoxia did not change RL. These results suggest that 1) the increase in EELV observed in hypoxia cannot result from an increase in airway resistance; 2) the increased and persistent activity of inspiratory muscles during expiration is the most likely cause of the increase in EELV during hypoxia; and 3) the decrease in RL induced by hypoxia could result from the increase in lung volume including EELV.

Biphasic ventilatory response of adult cats to sustained hypoxia has central origin.

Hypoxia stimulates ventilation, but when it is sustained, a decrease in the response is often seen. The mechanism of this depression or "roll off" is unclear. In this study we attempted to localize the responsible mechanism at one of three possible sites: the carotid bodies, the central nervous system (CNS), or the ventilatory apparatus. The ventilatory response to sustained hypoxia (PETO2, 40-50 Torr) was tested in 5 awake and 14 anesthetized adult cats. The roll off was found in both anesthetized and awake cats. Isocapnic hypoxia initially increased ventilation as well as phrenic and carotid sinus nerve activity in anesthetized cats (288 +/- 31, 269 +/- 31, 273 +/- 29% of control value, respectively). During the roll off, ventilation and phrenic nerve activity decreased similarly (to 230 +/- 26 and 222 +/- 28%, respectively after the roll off), but in contrast carotid sinus nerve activity remained unchanged (270 +/- 26%). Thus the ventilatory roll off was reflected in phrenic but not in carotid sinus nerve activity. We conclude that the cat represents a useful animal model of the roll off phenomenon and that the mechanism responsible for the secondary decrease in ventilation lays within the CNS.

Interindividual variation in hypoxic ventilatory response: potential role of carotid body.

There is considerable interindividual variation in ventilatory response to hypoxia in humans but the mechanism remains unknown. To examine the potential contribution of variable peripheral chemorecptor function to variation in hypoxic ventilatory response (HVR), we compared the peripheral chemoreceptor and ventilatory response to hypoxia in 51 anesthetized cats. We found large interindividual differences in HVR spanning a sevenfold range. In 23 cats studied on two separate days, ventilatory measurements were correlated (r = 0.54, P less than 0.01), suggesting stable interindividual differences. Measurements during wakefulness and in anesthesia in nine cats showed that although anesthesia lowered the absolute HVR it had no influence on the range or the rank of the magnitude of the response of individuals in the group. We observed a positive correlation between ventilatory and carotid sinus nerve (CSN) responses to hypoxia measured during anesthesia in 51 cats (r = 0.63, P less than 0.001). To assess the translation of peripheral chemoreceptor activity into expiratory minute ventilation (VE) we used an index relating the increase of VE to the increase of CSN activity for a given hypoxic stimulus (delta VE/delta CSN). Comparison of this index for cats with lowest (n = 5, HVR A = 7.0 +/- 0.8) and cats with highest (n = 5, HVR A = 53.2 +/- 4.9) ventilatory responses showed similar efficiency of central translation (0.72 +/- 0.06 and 0.70 +/- 0.08, respectively). These results indicate that interindividual variation in HVR is associated with comparable variation in hypoxic sensitivity of carotid bodies. Thus differences in peripheral chemoreceptor sensitivity may contribute to interindividual variability of HVR.

Increased carotid body hypoxic sensitivity during acclimatization to hypobaric hypoxia.

Mechanisms of ventilatory acclimatization to chronic hypoxia remain unclear. To determine whether the sensitivity of peripheral chemoreceptors to hypoxia increases during acclimatization, we measured ventilatory and carotid sinus nerve responses to isocapnic hypoxia in seven cats exposed to simulated altitude of 15,000 ft (barometric pressure = 440 Torr) for 48 h. A control group (n = 7) was selected for hypoxic ventilatory responses matched to the preacclimatized measurements of the experimental group. Exposure to 48 h of hypobaric hypoxia produced acclimatization manifested as decrease in end-tidal PCO2 (PETCO2) in normoxia (34.5 +/- 0.9 Torr before, 28.9 +/- 1.2 after the exposure) as well as in hypoxia (28.1 +/- 1.9 Torr before, 21.8 +/- 1.9 after). Acclimatization produced an increase in hypoxic ventilatory response, measured as the shape parameter A (24.9 +/- 2.6 before, 35.2 +/- 5.6 after; P less than 0.05), whereas values in controls remained unchanged (25.7 +/- 3.2 and 23.1 +/- 2.7; NS). Hypoxic exposure was associated with an increase in the carotid body response to hypoxia, similarly measured as the shape parameter A (24.2 +/- 4.7 in control, 44.5 +/- 8.2 in acclimatized cats). We also found an increased dependency of ventilation on carotid body function (PETCO2 increased after unilateral section of carotid sinus nerve in acclimatized but not in control animals). These results suggest that acclimatization is associated with increased hypoxic ventilatory response accompanied by enhanced peripheral chemoreceptor responsiveness, which may contribute to the attendant rise in ventilation.

Hypercapnia does not affect functional residual capacity enlargement induced by chronic hypoxia.

To determine whether changes in partial pressure of CO2 participate in mechanism enlarging the lung functional residual capacity (FRC) during chronic hypoxia, we measured FRC and ventilation in rats exposed either to poikilocapnic (group H, F(I)O2 0.1, F(I)CO2 <0.01) or hypercapnic (group H+CO2, F(I)O2 0.1, F(I)CO2 0.04-0.05) hypoxia for the three weeks and in the controls (group C) breathing air. At the end of exposure a body plethysmograph was used to measure ventilatory parameters (V'(E), f(R), V(T)) and FRC during air breathing and acute hypoxia (10 % O2 in N2). The exposure to hypoxia for three weeks increased FRC measured during air breathing in both experimental groups (H: 3.0+/-0.1 ml, H+CO2: 3.1+/-0.2 ml, C: 1.8+/-0.2 ml). During the following acute hypoxia, we observed a significant increase of FRC in the controls (3.2+/-0.2 ml) and in both experimental groups (H: 3.5+/-0.2 ml, H+CO2: 3.6+/-0.2 ml). Because chronic hypoxia combined with chronic hypercapnia and chronic poikilocapnic hypoxia induced the same increase of FRC, we conclude that hypercapnia did not participate in the FRC enlargement during chronic hypoxia.

Ventilatory response to sustained hypoxia in carotid body denervated rats.

Hypoxia stimulates ventilation, but when it is sustained, a decline in the ventilatory response is seen. The mechanism responsible for this decline lies within the CNS, but still remains unknown. In this study, we attempted to elucidate the possible role of hypoxia-induced depression of respiratory neurons by comparing the ventilatory response to hypoxia in intact rats and those with denervated carotid bodies. A whole-body plethysmograph was used to measure tidal volume, frequency of breathing and minute ventilation (VE) in awake and anesthetized intact rats and rats after carotid body denervation during exposure to hypoxia (FIO2 0.1). Fifteen-minute hypoxia induced an initial increase of VE in intact rats (to 248% of control ventilation in awake and to 227% in anesthetized rats) followed by a consistent decline (to 207% and 196% of control VE, respectively). Rats with denervated carotid bodies responded with a smaller increase in VE (to 134% in awake and 114% in anesthetized animals), but without a secondary decline (145% and 129% of control VE in the 15th min of hypoxia). These results suggest that afferentation from the carotid bodies and/or the substantial increase in ventilation are crucial for the biphasicity of the ventilatory response to sustained hypoxia and that a central hypoxic depression cannot fully explain the secondary decline in VE.

Biphasic ventilatory response to hypoxia in unanesthetized rats.

To determine the role of postinspiratory inspiratory activity of the diaphragm in the biphasic ventilatory response to hypoxia in unanesthetized rats, we examined diaphragmatic activity at its peak (DI), at the end of expiration (DE), and ventilation in adult unanesthetized rats during poikilocapnic hypoxia (10 % O2) sustained for 20 min. Hypoxia induced an initial increase in ventilation followed by a consistent decline. Tidal volume (VT), frequency of breathing (fR), DI and DE at first increased, then VT and DE decreased, while fR and DI remained enhanced. Phasic activation of the diaphragm (DI-DE) increased significantly at 10, 15 and 20 min of hypoxia. These results indicate that 1) the ventilatory response of unanesthetized rats to sustained hypoxia has a typical biphasic character and 2) the increased end-expiratory activity of the diaphragm limits its phasic inspiratory activation, but this increase cannot explain the secondary decline in tidal volume and ventilation.

Hyperoxia prevents carrageenan-induced enlargement of functional residual lung capacity in rats.

Experimental pneumonia induced by intratracheal application of carrageenan or paraquat increases the functional residual lung capacity (FRC) in rats. The mechanism of this increase is not clear, but a decrease in PO(2) may be involved. To test this possibility, we attempted to eliminate the PO(2) decrease in carrageenan-treated rats by exposing them to hyperoxia. Animals of the first group were exposed to 7 days of hyperoxia (F(I)O(2) 0.78-0.84, group Car+O(2)) after intratracheal application of carrageenan (0.5 ml of 0.7 % carrageenan in saline), whereas animals of the second group were given the same dose of carrageenan but breathed air (group Car+A). The third group of rats was kept for seven days in hyperoxia (group O(2)) and the fourth group served as controls (C). The animals were then anesthetized and intubated and their ventilatory parameters and FRC were measured during air breathing. Carrageenan application induced a FRC increase (Car+A 2.0+/-0.2 ml, C 1.6+/-0.1 ml), which was not seen in carrageenan-treated rats exposed to hyperoxia (Car+O(2) 1.6+/-0.1 ml). Hyperoxia alone did not affect the value of FRC (O(2) 1.5+/-0.1 ml). These results support the hypothesis that a decrease in PO(2) plays an important role in the carrageenan-induced increase of FRC in rats.

Perinatal hypoxia suppresses immune response of adult rats.

We tested the effect of perinatal (one week prenatal and one week postnatal) normobaric hypoxia on the immune response of rats in their 9th week of life. We found that perinatally hypoxic rats produced less serum antibodies after sequential immunization with ovalbumin and sheep red blood cells. Also phagocytosis of HEMA microparticles by neutrophil leukocytes from perinatally hypoxic rats was depressed as well as the oxidative burst of their peritoneal macrophages and neutrophils. These results demonstrate that perinatal hypoxia has an important effect on the immune system of the rat.

Perinatal hypoxia suppresses immune response of adult rats.

We tested the effect of perinatal (one week prenatal and one week postnatal) normobaric hypoxia on the immune response of rats in their 9th week of life. We found that perinatally hypoxic rats produced less serum antibodies after sequential immunization with ovalbumin and sheep red blood cells. Also phagocytosis of HEMA microparticles by neutrophil leukocytes from perinatally hypoxic rats was depressed as well as the oxidative burst of their peritoneal macrophages and neutrophils. These results demonstrate that perinatal hypoxia has an important effect on the immune system of the rat.

Hydrogen peroxide in the breath of rats: the effects of hypoxia and paraquat.

The hypothesis that oxidative stress can be induced by hypoxia was tested by measuring the concentration of hydrogen peroxide by a luminometric technique in the breath samples of rats exposed to hypoxia and paraquat. The group of animals (n=15) exposed to normobaric hypoxia (10% O2) for three days had an increased amount of H2O2 (200%, P<0.001) in their breath in comparison to control animals. After 7 days of recovery in air, the exposed animals still produced significantly increased levels of H2O2 (152%, P<0.001). Paraquat administration was used as a positive control, since it is a redox cycling compound producing free radicals. In the animals treated with a toxic dose of paraquat, the peak H2O2 production was observed 5 h after i.p. injection (156%, P<0.02). Within the next 2 h it decreased to the control level and stayed constant for 48 h, when the animals began to die. It is suggested that H2O2, observed in the breath samples, is a product of a metabolic pathway that could itself be sensitive to oxidative damage.