Pedro Garcia-Barreno

Comparison between intra- and extracellular surfactant in respiratory distress induced by oleic acid

The present study compares the phospholipid distribution and protein content in bronchoalveolar lavage, purified extracellular surfactant and lamellar bodies isolated from rabbits killed at intervals of 2.5, 12 and 24 h after oleic acid administration. The data suggest that the alteration of pulmonary surfactant could be partially due to the type II cell response to the injury.

Phospholipase C-diglyceride lipase is a major pathway for arachidonic acid release in macrophages.

Macrophages are a rich source of arachidonic acid oxygenated metabolites and play a remarkable role in a number of physiopathological situations. The synthesis and secretion of arachidonic acid metabolites are triggered at the cytoplasmic membrane level. The present study was outlined to further investigate the cellular mechanisms controlling arachidonic acid release in macrophages. The results presented here strongly suggest that the amount of arachidonic acid released in macrophages in response to phagocytic challenge could be accounted for by a phospholipase C-diglyceride lipase system being unnecessary the presence of phospholipase A2 whose activity, on the other hand, was found vanishingly small in macrophage homogenates.

Mitogenic activity and inositide metabolism in thrombin-stimulated pig aorta endothelial cells

The mitogenic activity of thrombin in endothelial cells is not well understood. The inositide metabolism is an ubiquitous transducing mechanism that seems to be involved in the control of cell growth. Thrombin is a potent stimulant of the release of inositol phosphates in platelets. The data presented here suggest that thrombin is able to induce competence in pig aorta endothelial cells to proliferate in response to insulin. Also thrombin is a potent stimulant of the inositide metabolism what suggests that the activation of this pathway might be at least one of the mechanisms through which thrombin induces competence in this cells.

Lipid alterations in liver and kidney induced by normobaric hyperoxia: correlations with changes in microsomal membrane fluidity

The effects of normobaric hyperoxia on both microsomal membrane fluidity and mechanism of phospholipid synthesis in rabbit liver and kidney have been studied. Hyperoxia induces in both organs an impairment of de novo synthesis of glycerolipids which could be due to an inactivation of acyltransferase activities involved in the initial formation of phosphatidic acid. The ability to replace phospholipid fatty acids by reacylation mechanism decreases slightly in the hyperoxic kidney, while it does not change in the hyperoxic liver. Concerning the effect of high arterial pO2 on microsomal membrane fluidity, the hyperoxic liver shows a more fluid environment within the membrane core of microsomes; however, no difference was shown in that of microsomal membrane core of hyperoxic kidney. An insight into the lipid composition of microsomes indicates that liver microsomal membranes have lower cholesterol content and higher unsaturation degree of phospholipid fatty acids, whereas hyperoxic kidney microsomes become more saturated and did not show any difference in their cholesterol content. In both hyperoxic liver and kidney microsomes, phospholipid content decreases in agreement with the depression of phosphatidic acid biosynthesis. These results are discussed in relation to the values of microsomal membrane microviscosity obtained.

Membrane regulation of liver and lung microsomes under low oxygen tension

A highly monitorized animal model has been developed for the study of the influence of low oxygen tension on lipid composition, microviscosity and regulation of enzyme activities involved in the phospholipid synthesis of hepatic and pulmonary microsomes. Microviscosity decreased in liver microsomes whereas no difference was shown in that of microsomal membrane core of hypoxemic lung. Nevertheless, phospholipid and cholesterol content of both liver and lung membranes changed significantly. Microsomal membranes of hypoxemic liver increased the unsaturation degree of fatty acids, whereas hypoxemic lung membranes become more saturated, mainly due to the increase of palmitic acid. The adaptive response of lung was confirmed by the high increase of the deacylation-reacylation mechanism.

Role of elastic fibers in cooling-induced relaxation

The objective of this work was to confirm the main role of elastic fibers in differing responses of certain vessels during cooling from 37 to 8 degrees C. Previous results have shown that the nature of the vessel (conduit vessel vs muscular vessel) determines the different behavior (dilatation vs contraction) of isolated vessel segments when temperature decreases from 37 to 8 degrees C. In this work, it has been demonstrated that vessels with a great amount of elastic fibers show a dilatation when cooling. On the other hand, muscular vessels with fewer elastic fibers, such as the renal artery, undergo a contraction. The output of calcium from intracellular stores causes contraction of the renal artery during cooling. In this vessel, vasodilatation occurs only when mechanisms of smooth muscle contraction are inactive, as is the case with vessels that have undergone a cold storage period of 48 h. The results presented in this work confirm that there are two main effects, which directly depend on the vessel origin. In conduit arteries, the decrease of temperature induces a vascular relaxation, dependent on the elastic component of the vessel wall. In muscular vessels, the predominant effect is cooling-induced contraction due to an increase of intracellular calcium. This cooling-induced contraction needs the vessel to be in optimal conditions with an active metabolism of the muscular cells. These results are a crucial issue in the sense of explaining several biomedical mechanisms where hypothermia is implicated. The type of vessel implicated in procedures, such as isolated organ perfusion, extracorporeal circulation, and bypass surgery, must be taken into account.

Hydrodynamic and biochemical effects of isolated hypothermic renal perfusion depending on the pump model and perfusion solution

OBJECTIVES To evaluate hydrodynamic, biochemical, and histological consequences of hypothermic isolated renal perfusion using a new computerized perfusion system. MATERIALS AND METHODS The device that allowed us to obtain on renal hydrodynamics during perfusion included multiple parts. The organ was perfused at 4 degrees C with a constant flow either using a classic roller pump or a pump designed in our laboratory to employ vacuum or atmospheric pressure sequentially to achieve a truly pulsatile wave (vacuum-powered tubular pump). The study included 16 minipigs with Eurocollins or Belzer perfusion solutions sampled at predefined interval and histological studies of the organs performed. RESULTS There was a significant difference in weight increase between the two types of pumps; those perfused with Eurocollins showed greater values than those with Belzer solution. Onset of nitric oxide (NO) in the perfusion solution increased inversely with the renal vascular resistance. The highest NO levels were observed with the Belzer solution and vacuum pump. CONCLUSIONS Changes in renal hydrodynamics, as induced by perfusion wave form and solution type, may be recorded in real time using a computerized system. A vacuum pump with the Belzer solution achieved the best experimental results.

Association of changes in lysophosphatidylcholine metabolism and in microsomal membrane lipid composition to the pulmonary injury induced by oleic acid

Alterations in the lipid composition of lung microsomal membranes occur in oleic acid-induced respiratory distress. The marked decrease in the phosphatidylcholine/lysophosphatidylcholine molar ratio could be related with an altered metabolism of lysophosphatidylcholine in these membranes. Results revealed that the activity of phospholipase A increased whereas that of acyl-CoA:lysophosphatidylcholine acyltransferase decreased. Microsomal lysophospholipase activity remained unchanged. On the other hand, the microsomal enzyme system involved in the de novo synthesis of diacylglycerol was impaired, and cholinephosphotransferase activity was lowered. These changes in the activity of some membrane-bound enzymes were not caused by changes in the membrane lipid fluidity since lipid structural order parameter (SDPH) did not change and neither did the major factors on which the fluidity depends. The possible significance of microsomal lipid alterations in the pathogenesis of respiratory distress induced by oleic acid is discussed.

Arachidonic acid releasing systems in pig aorta endothelial cells

Endothelial cells synthesize prostacyclin both from platelet-derived endoperoxides and from the arachidonic acid released from its intracellular stores. The mechanisms controlling this release does not appear to be mediated through phospholipid methylation but by means of phosphoinositide hydrolysis. As yet two possible mechanisms have so far been proposed to regulate arachidonic acid release in a number of cellular systems: phospholipase C-controlled phospholipase A2 activity or phospholipase C-diglyceride lipase system. The results presented here show that using phospholipases inhibitors is not a reliable strategy to study arachidonic acid release in cultures of endothelial cells. Our data also strongly suggest that the release of prostacyclin may be accounted in these cells for by a phospholipase C-diglyceride lipase system.

Blood biochemistry values of sheep (Ovis aries ligeriensis)

1. Analysis of biochemical parameters were carried out on material pooled from 30 female sheep (Ovis aries ligeriensis). 2. The values determined were for the common metabolites and enzymes utilized for specific studies in general metabolism (urea, glucose, cholesterol, lipids, bilirubin, uric acid, creatinine, alkaline phosphatase, GOT, GPT, LDH, LAP, CGT, CK and amylase). 3. Results of these studies were compared with values from normal human adults. 4. The differences obtained in human and sheep ranges can be explained by the different physiology of the two species. 5. This study gives values for the sheep as an experimental animal in biomedical research.