Respiratory activity of lung mitochondria isolated from oxygen-exposed rats.

The effects of in vivo oxygen exposure on mitochondrial energy metabolism were assessed by measurements of ADP-stimulated rates of oxygen utilization in lung homogenates and mitochondria isolated from rats after 24 h of exposure to 100% oxygen. Oxygen utilizations supported by FAD-linked metabolism of succinate and alpha-glycerophosphate were unaffected by oxygen exposure. On the other hand, mitochondrial respiratory activities supported by the NAD-linked substrates, isocitrate and alpha-ketoglutarate, were significantly reduced by 32 and 25%, respectively. These results could not be explained by changes in mitochondrial pyridine nucleotide or calcium contents. The activity of mitochondrial isocitrate dehydrogenase, measured in the absence of respiratory chain activity, was shown to be unaltered by oxygen exposure, suggesting that a potential site of oxygen-induced impairment is located within the respiratory chain rather than at the enzyme site of reducing equivalent transfer from NAD to components of the respiratory chain. Because lung mitochondrial alpha-glycerophosphate dehydrogenase activity was unaffected by oxygen exposure, it may maintain the oxidation of cytosolic reducing equivalents and subsequent energy generation under conditions when NAD-linked proton-shuttle mechanisms are impaired.

Lung mitochondrial function following oxygen exposure and diethyl maleate-induced depletion of glutathione.

Diethyl maleate (DEM) pretreatment has previously been shown to result in a transient depletion of lung glutathione and an associated decrease of the time to the onset of rat mortality resulting from exposures to 100% oxygen in vivo. The effects of oxygen exposure on mitochondrial energy metabolism were assessed by measurements of ADP-stimulated rates of O2 utilization by lung homogenates prepared from untreated and DEM-treated rats following 4 and 24 hr of exposure to either air or 100% oxygen. Twenty-four hours of oxygen exposure of untreated rats resulted in significant decreases in lung homogenate ADP-stimulated rates of respiration supported by the substrates, pyruvate, isocitrate, and alpha-ketoglutarate. No changes were observed in succinate-supported respiration, indicating that oxygen exposure appears to adversely affect NAD-linked rather than FAD-linked pathways of mitochondrial energy metabolism. The decreased lung mitochondrial glutathione, observed 4 hr following DEM treatment, returned to normal levels following 24 hr of air and oxygen exposure. No effects of glutathione depletion were observed on ADP-stimulated rates of respiratory activity 4 hr following DEM treatment. The DEM-induced transient depletion of glutathione also did not result in any additional detrimental effects on mitochondrial respiratory activity following 24 hr of oxygen exposure in vivo. These results suggested that transient mitochondrial depletion of glutathione does not accelerate the oxygen-induced impairment of mitochondrial energy metabolism. The onset of mortality associated with DEM-pretreatment might therefore result from a failure of glutathione-dependent cytosolic protective mechanisms, rather than from an increased rate of oxygen-induced mitochondrial damage.

Tricarboxylic acid cycle activity in perfused rat lungs after O2 exposure.

O2-induced impairment of mitochondrial energy generation was examined in intact lungs isolated from rats after 18-30 h exposure to either air or 100% O2 in vivo. Mitochondrial metabolic rates were determined by separate measurements of 14CO2 production from [1-14C]pyruvate and [U-14C]palmitate, perfused under normal and stimulated metabolic conditions brought about by perfusion with the uncoupler of oxidative phosphorylation, 2,4-dinitrophenol (DNP). In the absence of DNP, O2 exposure did not significantly alter 14CO2 productions from either substrate. DNP increased lung pyruvate and palmitate catabolism to CO2 twofold in air-exposed lungs but did not alter 14CO2 production in lungs isolated from O2-exposed rats. These data demonstrated an O2-induced impairment of maximal mitochondrial metabolism of both pyruvate and palmitate that could not be explained by alterations in tissue free coenzyme A or by loss of pyridine nucleotides. However, comparisons of the steady-state levels of tricarboxylic acid cycle intermediates between O2- and air-exposed lungs did identify isocitrate dehydrogenase as a possible site of O2-induced enzyme inactivation.

Pretreatment with EDU decreases rat lung cellular responses to ozone.

The phenylurea compound EDU (N-[2-(2-oxo-1-imidazolindinyl)ethyl]-N'-phenylurea) has been shown to protect plants from the damaging effects of ozone exposure. Models of rat lung injury, based on acute exposure to 2 ppm ozone for 3 hr and on exposure to 0.85 ppm ozone for 2 days, were used to determine whether EDU pretreatment of rats protected lungs from oxidant injury. Rats were pretreated with 100 mg/kg body wt EDU by ip administration for 2 days prior to and on the days of ozone exposure. No adverse toxicological effects of EDU pretreatment were observed. Lung superoxide dismutase (SOD) and catalase (CAT) activities were significantly enhanced from 636 to 882 U/lung and from 599 to 856 U/lung, respectively. One day following acute exposure (2 ppm for 3 hr), an ozone-induced increase of polymorphonuclear leukocytes (PMNs) from 0.01 to 1.18 million cells/lung was decreased to 0.68 million by EDU pretreatment. No alteration occurred in the degree of lung permeability indicated by increased lavage fluid albumin. EDU pretreatment also significantly decreased ozone-induced increases in PMN recovery after 2 days exposure to 0.85 ppm ozone from 5.54 to 2.12 million cells/lung. However, in this second case, EDU pretreatment reduced the observed ozone damage, indicated by a decrease in lavage fluid albumin and by a decrease in the macrophage and lymphocyte infiltration associated with this length of ozone exposure. The observation that EDU-treated cultured pulmonary arterial endothelial cells increased SOD and CAT activities identified a potential lung site of EDU interaction. These data demonstrated that although EDU pretreatment appears not to prevent initial ozone damage, it does reduce the infiltration of PMNs and might therefore prevent amplification of the injury associated with this cell type.

Rat lung glucose metabolism after 24 h of exposure to 100% oxygen.

Previous studies with lung homogenates and isolated cells have suggested oxygen cell injury results from the inhibition of key enzymes involved in both cytosolic and mitochondrial energy generation. In this study, the extent and pattern of metabolism of D-[U-14C, 5-3H]glucose was examined in perfused lungs isolated from rats before and after 24 h of in vivo exposure to 100% O2. Lung ATP levels after O2 exposure were maintained by a 53% increase in glucose utilization from an unexposed control value of 18.0 +/- 3.2 to 27.5 +/- 3.0 mumol 3H2O.h-1.g dry wt-1, accounted for by an enhanced rate of lactate plus pyruvate production from 15.7 +/- 2.0 to 32.7 +/- 4.1 mumol.h-1.g dry wt-1 with no alteration in lactate-to-pyruvate ratio. CO2 production was unaltered from a control rate of 27.5 +/- 4.0 14CO2 mumol.h-1.g dry wt-1. Maximal rates of glucose metabolism were determined by perfusion with 0.8 mM dinitrophenol, giving for air-exposed lungs a rate of 53.5 +/- 5.0 mumol 3H2O.h-1.g dry wt-1 and increased lactate plus pyruvate and 14CO2 production rates of 46.5 +/- 6.5 and 128.3 +/- 19.6 mumol.h-1.g dry wt-1, respectively. Although this maximal rate of glucose utilization was unaltered in oxygen-exposed lungs, lactate plus pyruvate production was further increased to 80.0 +/- 9.1 mumol.h-1.g dry wt-1 with a concomitant decrease in the dinitrophenol-induced rate of 14CO2 production to 81.5 +/- 9.2 mumol.h-1.g dry wt-1.(ABSTRACT TRUNCATED AT 250 WORDS)

A reversible model of acute lung injury based on ozone exposure.

In this study inflammatory responses were determined in rat lungs 0, 1, 3, and 8 days following single 2- and 4-hr exposures to 1.8 ppm ozone. Analysis of lavage fluid immediately following exposure demonstrated enhanced lactate dehydrogenase activity and decreased numbers of lavageable macrophages but no alterations in albumin content. Similar analyses at one day postexposure demonstrated 282% and 456% increases in albumin content and enhanced numbers of lavageable neutrophils from a control value of 0.01 +/- 0.01 to 0.27 +/- 0.10 and 0.78 +/- 0.11 million cells per lung for 2-hr and 4-hr exposures, respectively. The observed increased levels of albumin were also present at 3 days, at which time the number of lavageable neutrophils was not significantly different than control. At both one and 3 days postexposure, lavageable lymphocytes were significantly increased 10-fold from a control value of 0.03 +/- 0.01 million cells per lung. However, the number of lavageable macrophages was unaltered on day 1, but enhanced on day 3, giving values of 0.67 +/- 0.05 (control), 2.25 +/- 0.46 (2 hr), and 2.70 +/- 1.05 (4 hr) million cells per lung. By 8 days both inflammatory cell numbers and albumin levels had returned to control values. Since these data demonstrated different time courses for each inflammatory cell type, this reversible model of acute lung injury should be useful for establishing possible involvement of these cells in processes of lung injury.

Rat lung recovery from 3 days of continuous exposure to 0.75 ppm ozone.

The present study investigated the inflammatory responses and enzyme levels in lungs isolated from male Wistar rats after 3 d of continuous exposure to 0.75 ppm ozone and following 4 d of recovery in air. These times are associated with maximal proliferation of the alveolar type II epithelium and their subsequent transformation to new type I cells. Immediately following ozone exposure, bronchoalveolar lavage demonstrated neutrophil accumulation that was no longer present 4 d later. The number of lavaged macrophages was also found to be increased immediately following ozone exposure, and remained elevated at 4 d postexposure. Whole-lung determinations of key enzymes involved in energy generation (succinate oxidase) and maintenance of lung NADPH and reduced glutathione were corrected for changes in cell number, by use of lung DNA measurements. Immediately following ozone exposure succinate oxidase (SOX), glucose-6-phosphate (G6PD), and 6-phosphogluconate (6PGD) dehydrogenase activities per milligram DNA were significantly enhanced by 76%, 48%, and 21%, respectively. These data suggested that ozone-exposed lungs had cells with increased mitochondria and NADPH-generating capability consistent with the increased metabolic needs of a proliferating epithelium. At 4 d postexposure, only G6PD activity per milligram DNA remained higher by 22% than air-exposed controls. Although both glutathione reductase (GSSG-R) and peroxidase (GSH-Px) activities per lung were elevated in lungs immediately following exposure and 4 d later, when corrected for DNA only GSH-Px activity was significantly increased by 29% in lungs after the postexposure period. Lungs 4 d postexposure therefore had cells relatively enriched in G6PD and GSH-Px that might account for the increased ozone tolerance that has previously been associated with the formation of new type I epithelium.