Selective effect of phorbol ester on serotonin removal and ACE activity in rabbit lungs

The effect of phorbol myristate acetate (PMA) on pulmonary removal of [14C]serotonin (5-[14C]HT) and metabolism of [3H]benzoyl-phenylalanyl-alanyl-proline (BPAP), a synthetic substrate for angiotensin-converting enzyme (ACE), was evaluated in isolated rabbit lungs perfused in situ with Krebs-albumin. Metabolic functions were assessed before, during, and after perfusion with 80 nM PMA (n = 11), or PMA plus 133 microM papaverine (n = 10) or PMA diluent (dimethyl sulfoxide, n = 11). Organ kinetic parameters (apparent Vmax, Km) were calculated by use of indicator-dilution techniques and by a mathematical model of whole-organ metabolism. PMA treatment resulted in a significant decline in Vmax for BPAP metabolism (from 52 +/- 4 to 30 +/- 4 nmol/s) and 5-HT removal (from 2.1 +/- 0.2 to 1.1 +/- 0.1 nmol/s). Km for BPAP was not significantly altered, whereas Km for 5-HT removal was higher after treatment (before treatment, 1.1 +/- 0.1 microM; after treatment, 2.3 +/- 0.6 microM). Coperfusion with papaverine, which attenuated the pressor response to PMA, abolished PMA-induced changes in Vmax for BPAP metabolism and in Km for 5-HT removal but left PMA-induced changes in Vmax for 5-HT removal intact. We conclude that PMA alters endothelial metabolic function by both hemodynamic and biochemical mechanisms that are independent of circulating blood cells. Pulmonary capacity for BPAP metabolism may largely reflect perfused surface area, and capacity for 5-HT removal may be more sensitive to frank endothelial cell dysfunction in this model.     

Early pulmonary endothelial enzyme dysfunction after phorbol ester in conscious rabbits

We investigated changes in angiotensin converting-enzyme (ACE) activity before and at 5, 15, 60, and 240 min after 20 micrograms phorbol myristate acetate/kg body wt iv in conscious rabbits. ACE activity was estimated in vivo from the single-pass transpulmonary metabolism of the synthetic substrate [3H]benzoyl-Phe-Ala-Pro [( 3H]BPAP) under first-order reaction conditions. Within 5 min after PMA administration, all animals developed profound granulocytopenia (15% of control) and moderate thrombocytopenia (57% of control), both lasting for the duration of the experiment. Concomitantly, there was a significant decrease in the transpulmonary metabolism of [3H]BPAP and the calculated apparent first-order reaction constant Amax/Km of ACE for [3H]BPAP. No histological evidence of lung injury was observed at these times. Since a concomitant fall in the permeability surface area product for urea was also observed, we considered that the apparent decline in ACE activity might have resulted from a reduction in perfused endothelial surface area. To resolve this, we studied the effect of PMA on the Km (a measure of enzyme affinity for its substrate) and Amax (a derivative of Vmax that is dependent upon total enzyme present and thus capillary surface area) of ACE and 5'-nucleotidase for [3H]BPAP and [14C]AMP, respectively. A significant increase in Km for both enzymes was observed at 1 h after PMA, whereas Amax was unaffected, suggesting that low-dose PMA may indeed produce endothelial cell enzyme dysfunction independent of its effect on capillary surface area. These results provide evidence of pulmonary capillary functional injury before or in the absence of structural endothelial damage.     

Effect of flow and surface area on angiotensin-converting enzyme activity in rabbit lungs

Pulmonary angtiotensin-converting enzyme (ACE) is located on the luminal surface of pulmonary microvasculature. Multiple indicator-dilution techniques have been used to measure pulmonary ACE activity in vivo and in isolated lungs. These studies suggest that ACE activity is depressed in several forms of acute lung injury. Depression of ACE activity may reflect impaired substrate delivery to enzyme sites because of flow-related reduction of perfused surface area. To assess the role of altered microvascular flow and surface area in the measurement of ACE activity, we utilized similar techniques to estimate the apparent Km and Vmax of pulmonary ACE in isolated, Krebs-perfused rabbit lungs. Km is an estimate of the affinity of a synthetic ACE substrate, [3H]benzoyl-phenyl-alanyl-alanyl-proline ([3H]BPAP), for ACE and should not be influenced by the rate of substrate delivery to luminal enzyme sites. Conversely, Vmax is an index of the number of ACE sites and should be influenced by perfusion changes that alter the number of perfused sites (recruitment or derecruitment). When isolated lungs were subjected to physiological maneuvers designed to increase or decrease perfused surface area, apparent Vmax increased or decreased respectively. Apparent Km was not altered by these maneuvers. Km and Vmax were independent of changes in perfusion rate when surface area was held constant. Thus these parameters should be useful in evaluating perfusion changes in normal and injured lungs.     

Pulmonary metabolic function in the awake lamb: effect of development and hypoxia

The effect of postnatal development and acute alveolar hypoxia on pulmonary metabolic function was studied in conscious newborn lambs. Measurements of the ability of the lungs of these animals to metabolize [3H]benzoyl-L-phenyl-alanyl-L-alanyl-L-proline ([3H]BPAP; a synthetic substrate for angiotensin-converting enzyme, ACE) and to remove 5-hydroxy-[14C]tryptamine (5-[14C]HT) were made by modified indicator-dilution techniques during normoxic and hypoxic (fraction of inspired O2 = 0.10) conditions at 1 day, 1 wk, and 1 mo of age. Six additional sheep (8-23 wk old) were studied acutely as "adult" controls. BPAP metabolism in the 1-day-old group was 48 +/- 3% and increased slowly to 57 +/- 1% (P less than 0.05) at 1 mo of age and to 79 +/- 3% (P less than 0.01) by 23 wk of age. Pulmonary 5-[14C]HT removal was adultlike at birth (69 +/- 2%). Alveolar hypoxia significantly decreased BPAP only in the 1-day-old group (41 +/- 3%; P less than 0.05) and had no significant effect on 5-[14C]HT removal over the range of ages studied. These data demonstrate a selective and gradual postnatal development of pulmonary ACE which could be due to alterations in either the affinity or maximal capacity of pulmonary ACE, or increased endothelial cell surface area secondary to rapid growth of small blood vessels in this period. Alveolar hypoxia does not appear to closely regulate either ACE activity or 5-HT removal in conscious lambs greater than 1 day old when trace amounts of substrate are used.     

Effects of acid-base imbalance on pulmonary angiotensin-converting enzyme in vivo

The effects of acid-base balance disturbances on pulmonary endothelial angiotensin-converting enzyme (ACE) were studied in anesthetized mechanically ventilated rabbits. Enzyme function was estimated from [3H]benzoyl-Phe-Ala-Pro ([3H]BPAP) utilization under first-order reaction conditions during a single transpulmonary passage and expressed as 1) substrate metabolism (M), 2) Amax/Km (Amax being equal to the product of enzyme mass and the constant of product formation), and 3) (Amax/Km)/100 ml blood flow. When respiratory acidosis/alkalosis was produced by altering respiratory rate at constant airway pressure, substrate (BPAP) utilization varied proportionally to arterial pH and inversely proportionally to arterial PCO2 (PaCO2) (P less than 0.05). Percent BPAP metabolism (%M) ranged from 92 +/- 3 (respiratory alkalosis) to 85 +/- 3 (normal), 82 +/- 3 (respiratory acidosis), and 78 +/- 2% (severe respiratory acidosis). Amax/Km similarly decreased from 899 +/- 129 to 825 +/- 143, 601 +/- 74, and 450 +/- 34 ml/min, respectively, and (Amax/Km)/100 ml blood flow was reduced from 176 +/- 26 to 131 +/- 22, 111 +/- 12, and 97 +/- 5, respectively. However, when respiratory acidosis/alkalosis was produced by altering both respiratory rate and airway pressure, no changes were observed in either %M, Amax/Km or (Amax/Km)/100 ml blood flow. Similarly metabolic alkalosis or acidosis did not alter M, Amax/Km or (Amax/Km)/100 ml blood flow. These results indicate that pulmonary endothelial ACE function can be affected by acid-base disturbances, probably indirectly through changes in perfused microvascular surface area.     

Effects of blood flow on lung ACE kinetics: evidence for microvascular recruitment.

The parameter Amax/Km (product of reactant enzyme mass in perfused microvessels and the constant kcat/Km), calculated from in vivo assays of pulmonary endothelial ectoenzymes (e.g., angiotensin-converting enzyme, ACE), can provide estimates of the perfused pulmonary microvascular surface area (PMSA) in the absence of enzyme dysfunction. We examined the relationship between PMSA and pulmonary blood flow (Qb) in anesthetized rabbits placed on total heart bypass, using [3H]benzoyl-Phe-Ala-Pro (BPAP) as the ACE substrate. When Qb was increased from 250 to 1,100 ml/min, at zone 3 conditions, pulmonary arterial pressure increased, pulmonary vascular resistance (PVR) decreased, and Amax/Km increased linearly, reflecting increasing PMSA. When only the left lung was perfused, increasing Qb from 250 to 636 +/- 17 ml/min (the last value representing fully recruited and/or distended vascular bed), PVR decreased, while Amax/Km increased. When Qb was further increased to 791 +/- 44 ml/min, both PVR and Amax/Km remained unchanged, confirming the lack of additional changes in PMSA. We conclude that Amax/Km provides a sensitive indication of PMSA, because it 1) increases with increasing Qb and decreasing PVR, 2) reaches a maximum at Qb values that correspond to the minimal values in PVR, and 3) like PVR, did not change with further increases in Qb. Compared with predicted changes in PMSA produced by either microvascular recruitment alone or distension alone, our data indicate that recruitment is a larger contributor to the observed increase in PMSA.     

Lung serotonin uptake kinetics from indicator-dilution and constant-infusion methods

The kinetics of the pulmonary endothelial uptake of serotonin (5-HT) were evaluated in isolated dog lung lobes using three methods. In method A serotonin was infused at various constant rates to provide a range of capillary concentrations that included Km. The arterial and venous concentrations measured by high-performance liquid chromatography were then used to determine the effect of concentration on the rate of 5-HT uptake. In method B trace doses of 5-[3H]HT and a reference indicator (indocyanine green dye) were injected during each constant infusion of unlabeled 5-HT to provide a measure of unidirectional 5-HT uptake at each background concentration. In method C boluses containing different amounts of unlabeled 5-HT, along with the 5-[3H]HT and the dye, were injected such that each bolus resulted in a range of concentrations and provided a measure of the unidirectional uptake at each concentration. Each method provided the data needed to calculate the maximum uptake rate (Vmax) and the concentration at Vmax/2 (Km), assuming that the uptake kinetics can be represented by the Michaelis-Menten equation. However, the mathematical model underlying each method involved different assumptions about the returning flux of the 5-HT which entered the endothelial cell and the heterogeneity of vascular transit times. The results obtained, considered in light of the different assumptions involved, indicate that all three methods can provide reasonable estimates of the mass transfer kinetic constants if the constant infusions of 5-HT are of short duration and/or the boluses are adequately dispersed prior to reaching the capillary bed.     

Effects of gas composition and pH on kinetics of lung angiotensin-converting enzyme

Given the pH dependence of enzymes in general and the potential importance of a blood and alveolar gas composition dependency on the interpretation of changes in the hydrolysis of angiotensin-converting enzyme (ACE) substrates by pulmonary endothelial ACE, we examined the influence of Pco2 and Po2 on the hydrolysis of a synthetic ACE substrate (benzoyl-phenylalanyl-alanyl-proline, BPAP) on passage through isolated rabbit lungs. Perfusate pH values of about 7.1, 7.4, and 7.9 were obtained by ventilating the lungs with gas containing different CO2 concentrations and Po2 values of approximately 110 and approximately 10 Torr were obtained by varying the concentration of O2 in the ventilating gas mixture. In the range studied neither acidosis nor alkalosis produced any significant changes in BPAP hydrolysis or in the kinetic parameters, Vmax and Km, for the hydrolysis process. On the other hand, a reduction in BPAP hydrolysis was detected when the Po2 was reduced from 110 to 10 Torr. The Vmax for BPAP hydrolysis by the lung was inversely correlated with the magnitude of the hypoxic vasoconstriction that occurred, suggesting that the reduced BPAP hydrolysis with hypoxia was due to the loss of perfused surface area due to the vasoconstriction. The results suggest that correlations between Pco2 and/or pH and whole-lung ACE activity that might occur in diseased lungs do not imply causalty. The hemodynamic consequences of changing Po2 (i.e., hypoxic vasoconstriction) may alter whole-organ ACE activity in the sense of changing the perfused surface area (i.e., the amount of ACE in contact with flowing perfusate).     

Reduced lung endothelial angiotensin-converting enzyme activity in Watanabe hyperlipidemic rabbits in vivo

We investigated pulmonary endothelial function in vivo in 12- to 18-mo-old male Watanabe heritable hyperlipidemic (WHHL; n = 7) and age- and sex-matched New Zealand White (n = 8) rabbits. The animals were anesthetized and artificially ventilated, and the chest was opened and put in total heart bypass. The single-pass transpulmonary utilizations of the angiotensin-converting enzyme (ACE) substrate [(3)H]benzoyl-Phe-Ala-Pro (BPAP) and the 5'-nucleotidase (NCT) substrate [(14)C]AMP were estimated, and the first-order reaction parameter A(max)/K(m), where A(max) is the product of enzyme mass and the catalytic rate constant and K(m) is the Michaelis-Menten constant, was calculated. BPAP transpulmonary utilization and A(max)/K(m) were reduced in WHHL (1.69 +/- 0.16 vs. 2.9 +/- 0.44 and 599 +/- 69 vs. 987 +/- 153 ml/min in WHHL and control rabbits, respectively; P < 0.05 for both). No differences were observed in the AMP parameters. BPAP K(m) and A(max) values were estimated separately under mixed-order reaction conditions. No differences in K(m) values were found (9.79 +/- 1 vs. 9.9 +/- 1.31microM), whereas WHHL rabbit A(max) was significantly decreased (5.29 +/- 0.88 vs. 7. 93 +/- 0.8 micromol/min in WHHL and control rabbits, respectively; P < 0.05). We conclude that the observed pulmonary endothelial ACE activity reduction in WHHL rabbits appears related to a decrease in enzyme mass rather than to alterations in enzyme affinity.     

Propranolol and serotonin removal in lung injury

Indicator dilution technique was used to study effects of reduced vascular volume or acute injury on removal of low doses of [3H]propranolol and [14C]serotonin (5-hydroxytryptamine, 5-HT) by perfused rabbit lung. Glass-bead (500 micron) embolization doubled pulmonary arterial pressure (Ppa) at flow rates of 20, 50, and 100 ml/min, decreased volume of distribution by approximately 50%, and increased pulmonary vascular resistance by at least 60%. Before embolization, (flow rate 20 ml/min) removal of [3H]propranolol and [14C] 5-HT was 89 +/- 2 and 75 +/- 5%, respectively, and was unaltered by changes in flow rate. However, after embolization, [3H]propranolol and [14C]5-HT removal decreased in a flow-dependent manner, reaching 28 +/- 4 and 1 +/- 3% (P less than 0.05), respectively, at a flow rate of 100 ml/min. When phorbol myristate acetate (PMA, 200 nM) was perfused (50 ml/min) through the lungs for 15 min, Ppa increased from 13 +/- 1 to 25 +/- 2 cmH2O (P less than 0.05), whereas [3H]propranolol removal decreased from 92 +/- 1 to 75 +/- 5% (P less than 0.05) and [14C]5-HT removal decreased from 73 +/- 3 to 46 +/- 8% (P less than 0.05). The PMA also caused vasoconstriction, which could be partially blocked by adding papaverine (500 microM) to the perfusion medium. Under the latter conditions, Ppa increased to 19 +/- 1 cmH2O and [3H]propranolol removal was unaffected. However, the combination of PMA and papaverine reduced [14C]5-HT removal from 64 +/- 4 to 19 +/- 3%.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ramipril inhibition of rabbit (Oryctolagus cuniculus) small intestinal brush border membrane angiotensin converting enzyme

1. Rabbit small intestinal brush border membranes possessed prominent angiotensin converting enzyme (ACE) activity. 2. Intestinal ACE was located on the lumen surface, as verified by ACE co-enrichment with brush border membrane marker enzymes. 3. Hydrolysis kinetics of rabbit intestinal ACE were comparable to the lung, utilizing the substrate (N-[3-(2-furyl)acryloyl]-L-phenylalanylglycylglycine; the Vmax = 543 +/- 51 mumol/min/g and Km = 0.62 +/- 0.09 mmol/l. 4. Intestinal brush border ACE activity was strongly inhibited by the antihypertensive drug Ramipril, which yielded an IC50 value of 5 nmol/l; the ACE activity remained completely inhibited during 15 days after a single dose of 10 mumol/l Ramipril.     

Plasma protein binding and endothelial enzyme interactions in the lung

The influence of plasma albumin binding of the synthetic angiotensin-converting enzyme (ACE) substrate [3H]benzoyl-phenylalanyl-alanyl-proline (BPAP) on BPAP hydrolysis by pulmonary endothelial ACE was studied in isolated rabbit lungs perfused with a salt solution containing either 5% bovine serum albumin (BSA) or 5% dextran. The single-pass indicator-dilution method was used to measure the fraction (M) of [3H]BPAP hydrolyzed. Lung M was greater with albumin-free perfusate than when BSA was present. M decreased as the time (ti) that the BPAP was in contact with the BSA before reaching the lung was increased, suggesting that some BSA binding sites for BPAP were not in equilibrium during bolus transit through the lungs. The M vs. ti data were correlated using a model incorporating both rapid and slow binding kinetics of BPAP and BSA. For the slow BPAP-BSA interaction, the dissociation rate constant was approximately 0.015 s-1, and the fraction of the BPAP bound to these slowly equilibrating sites at equilibrium was approximately 22%. The results indicate that transient plasma protein binding kinetics can affect lung BPAP hydrolysis.     

Effects of alveolar pressure on lung angiotensin-converting enzyme function in vivo

Angiotensin-converting enzyme lines the luminal surface of pulmonary capillary endothelial cells. The metabolism of its synthetic substrate, 3H-benzoyl-L-phenylalanyl-L-alanyl-L-proline ([3H]BPAP) has been used as an indicator of pulmonary microvascular function. Because the flow-volume status of the pulmonary capillaries is dependent on intra-alveolar pressure, we have studied the effects of airway pressure on endothelial plasmalemmal angiotensin-converting enzyme function in rabbit lungs in vivo. Static inflation of the lungs to a pressure of 0 or 5 Torr did not change percent transpulmonary metabolism and Amax/Km ratio (defined as E X Kcat/Km and thus, under normal conditions, an indirect measure of perfused endothelial luminal surface area) compared with control measurements during conventional mechanical ventilation. When the inflation pressure was increased to 10 Torr, percent metabolism of [3H]BPAP remained unaltered but Amax/Km decreased to 60% of the control value. This decrease was in close relation to the decrease in pulmonary blood flow. Addition of 5 cmH2O positive end-expiratory pressure (PEEP) to the mechanical ventilation also decreased Amax/Km values and pulmonary blood flow but did not influence percent metabolism of [3H]BPAP. These results suggest that the detected alterations in apparent enzyme kinetics were more likely due to hemodynamic changes than to alterations in angiotensin-converting enzyme function. Thus high static alveolar pressures as well as PEEP probably reduced the fraction of perfused microvessels as reflected in changes in Amax/Km ratios. This information should prove useful in interpreting the response of pulmonary endothelial enzymes to injury.     

Correlation of pulmonary ACE activity and capillary surface area during postnatal development

Although a considerable amount of information is available regarding the remodeling and growth of the pulmonary arterial circulation, relatively little is known regarding postnatal development of the pulmonary microcirculation. We hypothesized that the maximal velocity (Vmax) of pulmonary angiotensin-converting enzyme (ACE) activity, measured from indicator-dilution outflow curves using a synthetic substrate, 3H-labeled benzoyl-phenylalanyl-alanyl-proline (BPAP), is directly related to the capillary endothelial cell surface area in the lungs of developing lambs. Accordingly we measured apparent kinetics of pulmonary ACE activity in 22 anesthetized ventilated lambs (2-171 days old) and compared our functional assessment to simultaneous in vivo determinations of CO diffusing capacity (DLCO) and postmortem structural assessment of alveolar septal dimensions using stereology and electron microscopy. There was a progressive increase in Vmax of ACE in this age group, with little change in apparent affinity for BPAP. Similar functional manifestation of growth was noted by an age-dependent increase in DLCO. Neither Vmax nor DLCO was significantly affected by an increase in left atrial pressure to 19 Torr (via inflation of a balloon in the left atrium), suggesting little recruitment of vessels under conditions of the present protocol. A close correlation was observed when either Vmax for ACE activity or DLCO was plotted vs. capillary endothelial cell surface area. Double logarithmic transformation of capillary endothelial cell surface area, Vmax-ACE and DLCO vs. lung volume revealed power functions with slopes all greater than that predicted from isotropic growth, suggesting selective differential postnatal development of the endothelium of the alveolar septum in lambs from 2-171 days of age.     

Effects of halothane on transport of 5-hydroxytryptamine by platelet membranes.

Na+-dependent uptake of 5-HT (5-hydroxytryptamine) into plasma membrane vesicles derived from bovine blood platelets and ATP-dependent 5-HT uptake into storage vesicles in platelet lysates were measured. Na+-dependent uptake was temperature-dependent, inhibited by imipramine and exhibited Michaelis-Menten kinetics (apparent Km, 0.12 +/- 0.02 microM; Vmax. 559 +/- 54 pmol/min per mg of protein. Halothane had no effect on Na+-dependent transport of 5-HT in plasma-membrane vesicles. ATP-dependent 5-HT transport into storage granules also exhibited Michaelis-Menten kinetics (apparent Km 0.34 +/- 0.03 microM; Vmax. 34.3 +/- 1.7 pmol/min per mg of protein) and was inhibited by noradrenaline (norepinephrine), but not by imipramine. Exposure of the granules to halothane resulted in a progressive decrease in Vmax. The results demonstrate a possible site for disruption of platelet function by anaesthetics.     

Synthesis of serine-AMC-carbamate: a fluorogenic tryptophanase substrate.

A new fluorogenic substrate for the pyridoxal 5'-phosphate-dependent enzyme tryptophanase is described. L-Serine, which is linked to 7-amino-4-methylcoumarin through an O-carbamoyl tether, serves as a substrate for the enzyme. The released moiety, 7-amino-4-methylcoumarin (AMC), can be detected by either absorbance (355 nm) or fluorescence (excitation 365 nm/emission 440 nm). Kinetic constants were measured using each of these techniques: Km = 85 +/- 20 microM, Vmax = 2.9 +/- 0.4 mumol/min/mg (fluorescence) and Km = 129 +/- 21 microM, Vmax = 3.1 +/- 0.3 mumol/min/mg (absorbance). The Vmax for serine-AMC-carbamate is approximately 1.9 times faster than that of the natural substrate, tryptophan. Using fluorescence detection, solutions containing 10(-3) units of activity could be routinely assayed.     

Isotope effect studies of the role of metal ions in isocitrate dehydrogenase.

Pig heart NADP+-dependent isocitrate dehydrogenase requires a metal ion for activity. Under optimum conditions (pH 7.5, Mg2+ present), the carbon isotope effect is k12/k13 = 0.9989 +/- 0.0004 for the carboxyl carbon undergoing decarboxylation and hydrogen isotope effects are VmaxH/VmaxD = 1.09 +/- 0.04 and (Vmax/Km)H/(Vmax/Km)D = 0.76 +/- 0.12 with threo-D,L-[2-2H]isocitric acid. Deuterium isotope effects measured by the equilibrium perturbation technique under the same conditions are VH/VD = 1.20 for the forward reaction and 1.02 for the reverse reaction. Under these conditions the rate-determining step in the enzymatic reaction must be product release. Dissociation of isocitrate from the enzyme-isocitrate complex and the enzyme-NADP+ complex must be two or more orders of magnitude slower than the chemical steps. The catalytic activity of the enzyme is about tenfold lower in the presence of Ni2+ than in the presence of Mg2+. The carbon isotope effect in the presence of Ni2+ at pH 7.5 is k12/k13 = 1.0051 +/- 0.0012 and the hydrogen isotope effects are VmaxH/VmaxD = 0.98 +/- 0.07 and (Vmax/Km)H/(Vmax/Km)D = 1.11 +/- 0.14. Thus, the rate decrease caused by substitution of Ni2+ for Mg2+ must result from the effects of metal on substrate and product binding and dissociation, rather than effects of metal on catalysis. However, a more detailed analysis of the carbon isotope effects reveals that there is also a large metal effect on the rate of the decarboxylation step, consistent with the view that the carbonyl oxygen of the oxalosuccinate intermediate is coordinated to the metal during decarboxylation.     

Influence of vasoconstriction, temperature, and flow on the kinetics of serotonin uptake in rabbit lungs

In the process of estimating the kinetic parameters of the pulmonary endothelial serotonin (5-HT) uptake, it is critically important to distinguish the effects of hemodynamic changes from endothelial injury. Therefore, the effects of changes in flow rate (1.7-5.0 ml/s), hemodynamics (vasoconstriction by norepinephrine), and temperature (39 vs. 33 degrees C) were investigated in isolated rabbit lungs. Indicator-dilution data were expressed in terms of the Michaelis-Menten equation for the two 5-HT uptake pathways in the preparation. The maximum uptake velocity (Vmax1) and the 5-HT concentration at half-maximum velocity (Km1) of the first pathway as well as the first-order constant (Vmax2/Km2) of the linear part of the second pathway were determined. Neither vasoconstriction nor flow variations had any effect on Km1, whereas increasing the flow rate caused extensive recruitment, with a concomitant increase in Vmax1 and Vmax2/Km2. Furthermore, all the kinetic parameters were significantly decreased at the lower temperature. We conclude that Km1 is independent of organ hemodynamics (vasoconstriction and flow) but susceptible to changes in 5-HT uptake capacity caused by a change in temperature. Vmax1 and Vmax2/Km2 respond to alterations in 5-HT uptake capacity and perfused organ volume. These are prerequisites to apply kinetic modeling as a method for the investigation of pulmonary endothelial function and integrity.     

In vivo measurement of coronary circulation angiotensin-converting enzyme activity in humans

Angiotensin-converting enzyme (ACE) is present on the luminal surface of the coronary vessels, mostly on capillary endothelium. ACE is also expressed on coronary smooth muscle cells and on plaque lipid-laden macrophages. Excessive coronary circulation (CC)-ACE activity might be linked to plaque progression. Here we used the biologically inactive ACE substrate (3)H-labeled benzoyl-Phe-Ala-Pro ([(3)H]BPAP) to quantify CC-ACE activity in 10 patients by means of the indicator-dilution technique. The results were compared with atherosclerotic burden determined by coronary angiography. There was a wide range of CC-ACE activity as revealed by percent [(3)H]BPAP hydrolysis (30-74%). The atherosclerotic extent scores ranged from 0.0 to 66.97, and the plaque area scores ranged from 0 to 80 mm(2). CC-ACE activity per unit extracellular space (V(max)/K(m)V(i)), an index of metabolically active vascular surface area, was correlated with myocardial blood flow (r = 0.738; P = 0.03) but not with measures of the atherosclerotic burden. These results show that CC-ACE activity can be safely measured in humans and that it is a good marker of the vascular area of the perfused myocardium. It does not, however, reflect epicardial atherosclerotic burden, suggesting that local tissue ACE may be more important in plaque development.     

Metabolic and pharmacokinetic activity of the isolated sheep bronchial circulation

We sought to determine bronchial vascular metabolic and pharmacokinetic activity toward benzoyl-Phe-Ala-Pro (BPAP), ADP, adenosine, and prostaglandin E2 (PGE2) by developing an isolated sheep bronchial circulation preparation. We measured mean transit time (t), uptake, and metabolism by injecting 3H-labeled substrates with [14C]sucrose into the bronchial artery of sheep lungs stripped clean of parenchymal tissue. After [3H]BPAP the t for 3H was the same as for 14C. Thirty-six percent of the injected BPAP was converted to metabolite ([3H]benzoyl-Phe) in a single pass. An inhibitor of angiotensin-converting enzyme, SQ 20,881, depressed BPAP metabolism by 50%, while perfusion of the bronchial circulation with glutaraldehyde reduced metabolism to a basal level. After [3H]ADP the t for 3H was again the same as for 14C. 3H recovery after 40 pmol [3H]ADP was less (58%) than after 400 nmol [3H]ADP (79%). Twenty-two percent of the injected radioactivity emerged in the effluent as metabolites of ADP for either dose. Adenosine and PGE2 uptake was negligible, and most of the recovered radioactivity in each case was unchanged substrate. This study suggests that the bronchial circulation is pharmacokinetically and metabolically active with respect to vasoactive mediators like angiotensin I, bradykinin, and adenine nucleotides, and that the enzymes responsible for this metabolic activity line the vascular lumen.