Alveolar epithelial barrier functions in ventilated perfused rabbit lungs

We employed ultrasonic nebulization for homogeneous alveolar tracer deposition into ventilated perfused rabbit lungs. (22)Na and (125)I-albumin transit kinetics were monitored on-line with gamma detectors placed around the lung and the perfusate reservoir. [(3)H]mannitol was measured by repetitive counting of perfusion fluid samples. Volume of the alveolar epithelial lining fluid was estimated with bronchoalveolar lavage with sodium-free isosmolar mannitol solutions. Sodium clearance rate was -2.2 +/- 0.3%/min. This rate was significantly reduced by preadministration of ouabain/amiloride and enhanced by pretreatment with aerosolized terbutaline. The (125)I-albumin clearance rate was -0.40 +/- 0.05%/min. The appearance of [(3)H]mannitol in the perfusate was not influenced by ouabain/amiloride or terbutaline but was markedly enhanced by pretreatment with aerosolized protamine. An epithelial lining fluid volume of 1.22 +/- 0.21 ml was calculated in control lungs. Fluid absorption rate was 1.23 microl x g lung weight(-1) x min(-1), which was blunted after pretreatment with ouabain/amiloride. We conclude that alveolar tracer loading by aerosolization is a feasible technique to assess alveolar epithelial barrier properties in aerated lungs. Data on active and passive sodium flux, paracellular solute transit, and net fluid absorption correspond well to those in previous studies in fluid-filled lungs; however, albumin clearance rates were markedly higher in the currently investigated aerated lungs.     

Isoproterenol improves ability of lung to clear edema in rats exposed to hyperoxia.

Exposure of adult rats to 100% O(2) results in lung injury and decreases active sodium transport and lung edema clearance. It has been reported that beta-adrenergic agonists increase lung edema clearance in normal rat lungs by upregulating alveolar epithelial Na(+)-K(+)-ATPase function. This study was designed to examine whether isoproterenol (Iso) affects lung edema clearance in rats exposed to 100% O(2) for 64 h. Active Na(+) transport and lung edema clearance decreased by approximately 44% in rats exposed to acute hyperoxia. Iso (10(-6) M) increased the ability of the lung to clear edema in room-air-breathing rats (from 0.50 +/- 0.02 to 0.99 +/- 0. 05 ml/h) and in rats exposed to 100% O(2) (from 0.28 +/- 0.03 to 0. 86 +/- 0.09 ml/h; P < 0.001). Disruption of intracellular microtubular transport of ion-transporting proteins by colchicine (0. 25 mg/100 g body wt) inhibited the stimulatory effects of Iso in hyperoxia-injured rat lungs, whereas the isomer beta-lumicolchicine, which does not affect microtubular transport, did not inhibit active Na(+) transport stimulated by Iso. Accordingly, Iso restored the lung's ability to clear edema after hyperoxic lung injury, probably by stimulation of the recruitment of ion-transporting proteins (Na(+)-K(+)-ATPase) from intracellular pools to the plasma membrane in rat alveolar epithelium.     

Transvascular protein transport in mice lacking endothelial caveolae

Caveolae are Omega-shaped vesicular structures postulated to play a role in transvascular protein transport. Studies on mice lacking endothelial caveolae, caveolin-1 knockout (Cav-1-KO) mice, indicate increased macromolecular transport rates. This was postulated to be due to the appearance of an alternative pathway. The present study tested whether an alternative pathway had appeared in Cav-1-KO mice. Male Cav-1-KO (n=12) and male control mice (n=13) were intubated and anesthetized using 2% isoflurane. 125I-labeled albumin, 131I-labeled immunoglobulin M (IgM), and polydisperse FITC-Ficoll were administered intravenously. During tracer administration, a 90-min peritoneal dialysis dwell was performed. Clearance of tracers to dialysate and permeability-surface area product for glucose were assessed. Transvascular protein transport was higher in Cav-1-KO compared with control mice. Albumin clearance from plasma to peritoneum was 0.088+/-0.008 microl/min in control and 0.179+/-0.012 microl/min in Cav-1-KO (P=0.001) mice. IgM clearance was 0.049+/-0.003 and 0.083+/-0.010 microl/min in control and Cav-1-KO mice, respectively (P=0.016). Ficoll clearance was increased in Cav-1-KO mice. In conclusion, the lack of caveolae in Cav-1-KO mice resulted in a marked increase in macromolecular transport. A two-pore analysis of the Ficoll clearance data revealed that the higher transport rate in Cav-1-KO mice was not compatible with the appearance of an alternative pathway for macromolecular transport. In contrast, the higher transperitoneal protein and Ficoll clearance is consistent with passive porous transport through an unperturbed two-pore system, presumably at an elevated capillary hydraulic pressure. Alternatively, the data may be explained by reductions in the selectivity of the endothelial glycocalyx, leading to an increased capillary hydraulic conductivity and large solute filtration.     

14C sucrose efflux from the perimedulla of growing potato tubers

Abstract An experimental system has been developed for studying efflux of ¹⁴C assimilates in growing potato tubers. Small wells are cut into the phloem-rich perimedulla and filled with trap solutions of varying composition which inhibit or promote assimilate efflux. One well on each tuber acts as the treatment while a second well acts as the control. Movement of ¹⁴C into wells occurred at comparable rates to that found in intact tissue, harvested from importing tubers in the form of microcores. Sucrose was the predominant translocated sugar in the stolon and was not hydrolysed in either the wells or the microcores following unloading. Efflux into wells containing agar traps was stimulated 40-fold relative to buffer controls by the addition of 20 mol m^?3 EGTA to the agar. This was interpreted as passive efflux to the apoplast due to increased membrane permeability in the pathway between the sieve elements and the collecting wells. The EGTA stimulation was reversed by addition of Ca²⁺. ¹⁴C efflux into buffered solutions was inhibited significantly by both DNP and PCMBS, suggesting the involvement of active and carrier-mediated transport components. However, it was not possible to determine whether these compounds acted at the site of unloading only, or on the short-distance transfer step between phloem and collecting wells. The rate of tracer efflux was not significantly different when 1 mol m^?3 and 300 mol m^?3 sucrose were applied to the wells, indicating insensitivity of solute movement to low apoplastic solute concentrations. However, raising the solute concentration to 800 mol m^?3 caused a severe inhibition of tracer efflux. These results were duplicated with mannitol as the osmoticum. It is suggested that plasmolysis prevented further efflux by disruption of a predominantly symplastic transport pathway between the phloem and collecting wells.     

Simultaneous measurement of fluid and protein permeability in isolated rabbit lungs during edema.

Fluid conductance and protein permeability have been studied in isolated perfused lung models of pulmonary edema. However, previous studies have not investigated changes of both fluid conductance and protein permeability in the same isolated lung preparation after injury. Arachidonic acid (AA) metabolites are involved in the inflammatory processes that lead to the development of pulmonary edema. The hemodynamic effects of AA have been well established; however, controversy exists concerning the ability of AA to alter the permeability of the pulmonary microvasculature to fluid and protein. The purpose of this study was to simultaneously determine whether transvascular fluid conductance and protein permeability are increased in isolated perfused rabbit lungs with pulmonary edema induced by AA. Indomethacin (80 microM) was added to the perfusate to inhibit the hemodynamic effects of AA and produce a pressure-independent model of pulmonary edema. Fluid conductance was assessed by determination of the capillary filtration coefficient (Kf), and protein permeability was evaluated by measurement of 125I-albumin clearance. The injection of AA (3 mg/200 ml of perfusate) into the pulmonary arterial catheter resulted in an increase in lung weight over the remaining 30-min experimental period. Kf (microliter.s-1 x cmH2O-1 x g dry lung-1) was increased (P < 0.05) in AA-treated lungs at 10 and 30 min post-AA injection when compared with control lungs and baseline values (determined 10 min before AA injection). Albumin clearance was also greater (P < 0.05) in lungs that received AA. 125I-albumin clearance was measured at different rates of fluid flux produced by elevation of venous pressure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Protein clearance from the air spaces and lungs of unanesthetized sheep over 144 h

We studied the rate, the routes, and the mechanisms for protein clearance from the air spaces and lungs of 20 unanesthetized sheep over 144 h. We instilled 100 ml of autologous serum labeled with 125I-albumin into one lung. At the end of 24, 48, 96, or 144 h, the lungs were removed and the residual native protein and 125I-albumin in the air spaces were determined by bronchoalveolar lavage. Also the fraction of the instilled 125I-albumin remaining in the rest of the lung was measured in the lung homogenate. Clearance of the 125I-albumin from the lung into the plasma, lymph, thyroid, urine, and feces was also determined. The removal of both the 125I-albumin and the native protein from the air spaces was slow, following a monoexponential decline. The removal rate of the 125I-albumin from the air spaces was slightly but significantly faster (1.6%/h) than the clearance rate of the native protein (0.9%/h). Clearance of the 125I-albumin from the lung also followed a slow monoexponential decline at a rate of 1.4%/h. At all time periods, 75% of the 125I-albumin remaining in the lung was located in the air spaces, thus indicating that the pulmonary epithelium is the principal barrier to protein clearance from the normal lung. Macrophages appeared to play a minor role in alveolar protein clearance because the quantity of 125I-albumin present in the phagocytic cells in the air spaces was less than 1% of the instilled 125I-albumin at all time periods. However, macrophages may play some role in protein clearance after 48 h because we visualized phagolysosomes in macrophages, and there was an increase in free iodine in lung lavage, urine, thyroid, and feces after 48 h. However, gel electrophoretic studies showed that most of the 125I-albumin was cleared from the lung as an intact molecule, although only 24.7 +/- 4.7% of the 125I-albumin was cleared by the lymphatics.     

Surfactant replacement attenuates the increase in alveolar permeability in hyperoxia

Rabbits exposed to hyperoxia develop surfactant deficiency, abnormal lung mechanics, and increased permeability to solute. We investigated whether replenishment of depleted alveolar surfactant by the intratracheal instillation of calf lung surfactant extract (CLSE) would mitigate the increase in alveolar permeability to solute. Twenty-eight rabbits were exposed to 100% O2 for 72 h and received intratracheal instillations of 125 mg CLSE (approximately 170 mumol dipalmitoyl phosphatidylcholine) at 24 and 48 h. The interlobar and intralobar distribution of CLSE was quantified by adding [14C]dipalmitoyl phosphatidylcholine liposes into the instillate and measuring the levels of activity in lung tissue. CLSE was nonuniformly distributed in the different lung lobes, the right lower lobe receiving more CLSE than the rest. Alveolar epithelial permeability to solute was assessed by instilling 10 ml isotonic saline, which contained a trace amount of [57Co]cyanocobalamin, in the right lower lobe and measuring the disappearance of the tracer from the alveolar saline and its appearance in the arterial blood during a 1-h period. CLSE treatment was associated with significantly increased 72-h survival in hyperoxia compared with saline-treated controls (number of survivors: 16/17 vs. 5/11, P less than 0.01). CLSE treatment significantly reduced the rate constant for the movement of cyanocobalamin out of the alveolar space (24 +/- 5 vs. 42 +/- 6 min-1 x 10(-3), P less than 0.01) and tracer appearance in the blood at the end of the study (7 +/- 1 vs. 34 +/- 13%, P less than 0.01) when compared with values in saline controls.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of acute hyperoxic exposure on solute fluxes across the blood-gas barrier in rat lungs

Zheng, Lu P., Rui Sheng Du, and Barbara E. Goodman.Effects of acute hyperoxic exposure on solute fluxes across the blood-gas barrier in rat lungs. J. Appl.Physiol. 82(1): 240-247, 1997.We investigatedeffects of acute hyperoxia on solute transport from air space tovascular space in isolated rat lungs. Air spaces were filled withKrebs-Ringer bicarbonate solution containing fluoresceinisothiocyanate-labeled dextran (FD-20; mol wt 20,000) and either²²Na⁺and [¹⁴C]sucrose, orD-[¹⁴C]glucoseandL-[³H]glucose.Apparent permeability-surface area products for tracers over time (upto 120 min) were calculated for isolated perfused lungs from controlrats (room air) and rats exposed to >95%O₂ for 48 or 60 h immediatelypostexposure. After O₂ exposures,mean fluxes for[¹⁴C]sucrose and FD-20were significantly higher than in room-air control lungs. However,amiloride-sensitive Na⁺ and activeD-glucose fluxes were unchangedafter hyperoxic exposure. Therefore, it is unlikely that decreases innet solute transport in this lung-injury model contributed to pulmonaryedema resulting from O₂ toxicity.Increased net solute transport shown to help resolve pulmonary edemaafter acute hyperoxic exposure must therefore begin during the recoveryperiod. In summary, our data show increases in passive solute fluxesbut no changes in active solute fluxes immediately after acutehyperoxic lung injury.

     

Proteolysis of very low density lipoprotein in perfused lung.

Perfusion of homologous 125I-labeled rat very low density lipoprotein through isolated rat lungs in the presence of heparin resulted in apoprotein proteolysis. At least the apoprotein C was degraded into two peptides smaller than 7500 daltons as measured by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The lung uptake of radioactivity was small and due mainly to the presence of the larger of the two peptides. The lung protease was not active against an 125-I-labeled albumin substrate and was not released into the medium by heparin.     

Compartmental analysis of the efflux of l-[3H]norepinephrine from isolated perfused rat lungs

Isolated rat lungs, pretreated with 100 microM pargyline and 100 microM U-0521 (3',4'-dihydroxy-2-methylpropriophenone) to block metabolism of norepinephrine (NE), were perfused with 0.3 microM 3H-labeled l-norepinephrine (1-[3H]-NE) for 30 min. Efflux samples were then collected for 30 min during washout of the tissue with amine-free Krebs solution. Compartmental analysis (nonlinear least-squares regression) of the efflux of tissue l-[3H]NE content vs. time indicates that NE is accumulated in a large slowly equilibrating compartment (t 1/2 = 58.15 +/- 6.84 min) in addition to distribution in the vascular (blue dextran tracer) and extracellular ([3H]sorbitol tracer) fluid compartments of the lung. Pretreatment of the lungs with 100 microM cocaine hydrochloride reduces the total l-[3H]NE space from 7.44 +/- 1.91 to 2.48 +/- 0.23 ml/g (P less than 0.05) by selectively decreasing the size of the slow NE compartment from 6.99 +/- 1.97 to 1.67 +/- 0.14 ml/g (P less than 0.05). The large size, cocaine sensitivity, and long efflux half time of this compartment suggest that neuronal uptake contributes to the pulmonary vascular inactivation of l-[3H]NE.     

Alveolar liquid and protein clearance from normal dog lungs

To determine whether liquid and protein clearance from the air spaces and lungs of anesthetized and unanesthetized dogs is the same as in sheep, we quantified these variables at three different time periods (4, 8, and 12 h) by instilling heparinized plasma (3 ml/kg) labeled with 125I-albumin into one lower lobe. Protein clearance, measured from the residual 125I-albumin in the lung homogenate, was slow and monoexponential (approximately 1%/h), similar to our previous data for protein clearance from the lungs in sheep. Lung liquid clearance in dogs, however, was 50% less than in previous experiments in sheep. Residual lung liquid (as percent of instilled) was 88.7 +/- 7.0 at 4 h, 70.5 +/- 9.1 at 8 h, and 64.0 +/- 5.8 at 12 h. At each time period, alveolar protein concentration increased by 0.6 +/- 0.4 g/dl at 4 h, 1.3 +/- 1.2 g/dl at 8 h, and 2.1 +/- 0.8 g/dl at 12 h. This increase in alveolar protein concentration was proportional to the volume of liquid removed from the lungs. beta-Adrenergic agonist therapy with terbutaline (10(-5) M mixed with the instilled plasma) doubled the volume of liquid cleared from the lungs over 4 h, and the alveolar protein concentration increased proportionally. However, lung liquid clearance in dogs that were treated with beta-agonists was proportionally (50%) less than in sheep treated with beta-agonists. The slower liquid clearance in dogs compared with sheep cannot be explained by differences in hemodynamics, pulmonary blood flow, anesthesia, mode of ventilation, or alveolar surface area.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evans blue dye as a marker of albumin clearance in cultured endothelial monolayer and isolated lung.

Determination of protein transfer across the endothelial barrier or the entire alveolar capillary membrane is critical for investigation of mechanisms leading to pulmonary edema. The purpose of this study was to evaluate Evans blue dye for determination of protein clearance across cultured bovine pulmonary artery endothelial cell monolayers and as a quantitative marker for albumin leakage to the air spaces in isolated perfused rat lungs. Evans blue dye bound tightly to albumin (EBA) as determined by lack of transfer through dialysis membranes and specific elution with albumin from a molecular exclusion column. EBA was equivalent to 125I-labeled albumin for calculation of albumin clearance rates (Calb) across intact and challenged monolayers [Calb (+ vehicle) = 0.12 microliters/min; Calb (+10 nM alpha-thrombin) = 0.47 microliters/min; Calb (+5 mg/ml trypsin) = 1.29 microliters/min]. Transfer of EBA was linear with time in both the endothelial cell monolayer model and the perfused lung. EBA was a sensitive marker for early edema in the perfused lung (before detectable weight gain) as well as for severe edema in the oxidant-injured lung (marked EBA accumulation in lavage fluid) and was a more specific marker for protein transfer than lavage fluid protein. EBA transfer is a convenient, reproducible, and accurate means to assess alterations in vascular permeability.     

C-receptor ligand blocks pulmonary clearance of atrial natriuretic peptide in isolated rat lungs.

Pulmonary clearance of atrial natriuretic peptide (ANP) was measured by indicator dilution technique in isolated perfused rat lungs with and without ANP clearance receptor (C-receptor) blockade. Approximately 50% of a bolus injection of 125I-ANP was removed during a single pass through the lungs compared with the intravascular marker 14C-dextran. Pulmonary clearance of 125I-ANP was suppressed in a dose-dependent fashion by unlabeled ANP. C-receptor blockade suppressed pulmonary clearance of 125I-ANP to the same degree as unlabeled ANP. High-performance liquid chromatography analysis of the pulmonary venous effluent from lungs treated with C-receptor ligand demonstrated intact 125I-ANP. We conclude that virtually all of the pulmonary vascular uptake of 125I-ANP during a single pass through isolated lungs is secondary to removal by ANP C-receptors.     

Transalveolar osmotic and diffusional water permeability in intact mouse lung measured by a novel surface fluorescence method

A surface fluorescence method was developed to measure transalveolar transport of water, protons, and solutes in intact perfused lungs. Lungs from c57 mice were removed and perfused via the pulmonary artery (approximately 2 ml/min). The airspace was filled via the trachea with physiological saline containing a membrane-impermeant fluorescent indicator (FITC-dextran or aminonapthalene trisulfonic acid, ANTS). Because fluorescence is detected only near the lung surface due to light absorption by lung tissue, the surface fluorescence signal is directly proportional to indicator concentration. Confocal microscopy confirmed that the fluorescence signal arises from fluorophores in alveoli just beneath the pleural surface. Osmotic water permeability (Pf) was measured from the time course of intraalveolar FITC-dextran fluorescence in response to changes in perfusate osmolality. Transalveolar Pf was 0.017 +/- 0.001 cm/s at 23 degrees C, independent of the solute used to induce osmosis (sucrose, NaCl, urea), independent of osmotic gradient size and direction, weakly temperature dependent (Arrhenius activation energy 5.3 kcal/mol) and inhibited by HgCl2. Pf was not affected by cAMP activation but was decreased by 43% in lung exposed to hyperoxia for 5 d. Diffusional water permeability (Pd) and Pf were measured in the same lung from intraalveolar ANTS fluorescence, which increased by 1.8-fold upon addition of 50% D2O to the perfusate, Pd was 1.3 x 10(-5) cm/s at 23 degrees C. Transalveolar proton transport was measured from FITC-dextran fluorescence upon switching perfusate pH between 7.4 and 5.6; alveolar pH half-equilibrated in 1.9 and 1.0 min without and with HCO3-, respectively. These results indicate high transalveolar water permeability in mouse lung, implicating the involvement of molecular water channels, and establish a quantitative surface fluorescence method to measure water and solute permeabilities in intact lung.     

Sieve element unloading: cellular pathway, mechanism and control

The transport and distribution of phloem – mobile solutes is predominantly determined by transport processes located at the sink end of the source – transport – sink system. Transport across the sieve element boundary, sieve element unloading, is the first of a series of sink transport processes. Unloading of solutes from the sieve elements may follow an apo- or symplastic route. It is speculated that the unloading pathway is integrated with sink function and that apoplastic unloading is restricted to situations in which movement through the symplast is not compatible with sink function. These situations include axial transport and storage of osmotically active solutes against concentration and turgor gradients between the sieve elements and sink cells. Coupled with alteration in sink function, the cellular pathway of unloading can switch in stems and possibly other sinks. Experimental systems and approaches used to elucidate the mechanism of sieve element unloading are reviewed. Unloading fluxes to the apoplast can largely be accounted for by membrane diffusion in axial sinks. However, the higher fluxes in storage sinks suggests dependence on some form of facilitated transport. Proton sucrose symport is assessed to be a possible mechanism for facilitated efflux of solutes across the sieve element plasma membrane to the sink apoplast. Unloading through the symplast may occur by diffusion or mass flow. The latter mechanism serves to dissipate phloem water and hence prevent the potential elevation of sieve element turgor that would otherwise slow phloem import into the sink. The possibility of energised plasmodesmatal transport is raised. Sieve element unloading must be integrated with subsequent compartmentation and metabolism of the unloaded solute. Solute levels are an obvious basis for control of sieve element unloading, but are found to offer limited scope for a mass action mechanism. Apoplastic, cellular pathway, sieve element, solute transport, symplastic. Translated into a turgor signal, solute levels could regulate the rate of unloading, metabolism and compartmentation forming part of a turgor homeostat irrespective of the pathway of unloading.     

Regulatory effects of insulin and experimental diabetes on neutral amino acid transport in the perfused rat exocrine pancreas. Kinetics of unidirectional L-serine influx and efflux at the basolateral plasma membrane

Relatively little is known about the hormonal regulation of amino acid transport in the normal and diabetic exocrine pancreas. In this study unidirectional influx and tracer efflux of L-serine at the basolateral interface of the rat pancreatic epithelium was investigated in the perfused exocrine pancreas using a rapid (less than 30 s) paired-tracer dilution technique. In the non-diabetic pancreas L-serine influx was saturable and stimulated by perfusion with exogenous bovine insulin (100 microU/ml). Transport of L-serine and methylaminoisobutyric acid was markedly elevated in pancreata isolated from streptozotocin diabetic rats and insulin partially reversed the stimulation of L-serine transport induced by experimental diabetes. These results suggest that insulin and diabetes modulate the epithelial transport activity for small neutral amino acids in the intact exocrine pancreas.     

Alveolar and lung liquid clearance in anesthetized rabbits

Alveolar and lung liquid clearance were studied over 8 h in intact anesthetized ventilated rabbits by instillation of either isosmolar Ringer lactate (2 ml/kg) or autologous plasma (2 or 3 ml/kg) into one lower lobe. The half time for lung liquid clearance of the isosmolar Ringer lactate was 3.3 h and that for plasma clearance was 6 h. In the plasma experiments, the alveolar protein concentration after 1 h was 5.2 +/- 0.8 g/dl, which was significantly greater than the initial instilled protein concentration of 4.3 +/- 0.7 g/dl (P less than 0.05). Thus alveolar protein concentration increased by 21 +/- 12% over 1 h, which matched clearance from the entire lung of 19 +/- 11% of the instilled volume. Overall the rate of alveolar and lung liquid clearance in rabbits was significantly faster than in prior studies in dogs and sheep. The fast alveolar liquid clearance rate in rabbits was not due to higher endogenous catecholamine release, because intravenous and alveolar (5 x 10(-5) M) propranolol did not slow the clearance. Also, beta-adrenergic therapy with alveolar terbutaline (10(-5) or 10(-4) M) did not increase the alveolar or lung liquid clearance rates. Phloridzin (10(-3) M) did not slow alveolar liquid clearance. However, amiloride (10(-4) M) inhibited 75% of the basal alveolar liquid clearance in rabbits, thus providing evidence that alveolar liquid clearance in rabbits depends primarily on sodium-dependent transport. This rabbit study provides further evidence for important species differences in the basal rates of alveolar liquid and solute clearance as well as the response to beta-adrenergic agonists and ion transport inhibitors.     

Differential effects of turgor on sucrose and potassium transport at the tonoplast and plasma membrane of sugar beet storage root tissue

When turgor was increased, by decreasing the concentration of mannitol bathing discs of sugar beet storage root tissue, the rates of sucrose and potassium uptake into the vacuole were decreased. At all external mannitol concentrations the rate of sucrose and potassium uptake across the plasma membrane was an order of magnitude greater than the rate of quasi-steady uptake into the vacuole, implying a very large efflux. Efflux of both sucrose and potassium was increased at high turgor. However, while increasing turgor decreased the rate of K⁺ uptake, the rate of sucrose uptake at the plasma membrane increased with time. Compartmental analysis of tracer exchange kinetics was used to determine unidirectional K⁺ fluxes. From these results, it was estimated that the increase in K⁺ efflux accompanying a 1.5 MPa increase in turgor could lead to a net increase of 140mol^?3h^?1 in the external potassium concentration. It is suggested that the turgor-imposed increase in solute efflux is a means of regulating intracellular osmotic pressure and/or turgor in sugar beet storage roots, but that sucrose is preferentially retrieved from the apoplast, even under conditions of excessively high turgor. However, much of this sucrose is probably lost from the cell, implying a ‘futile’ sucrose transport cycle at the plasma membrane. The turgor-stimulated leak of potassium could play a major role in the regulation of turgor pressure in sugar beet storage root tissue.     

Site of deposition and factors affecting clearance of aerosolized solute from canine lungs

We determined the influence of several factors on lung solute clearance using aerosolized 99mTc-diethylenetriaminepentaacetate. We used a jet nebulizer-plate separator-balloon system to generate particles with an activity median aerodynamic diameter of 1.1 micron, administered the aerosol in a standard fashion, and determined clearance half times (t1/2) with a gamma-scintillation camera. The following serial studies were performed in five anesthetized, paralyzed, intubated, mechanically ventilated dogs: 1) control, with ventilatory frequency (f) = 15 breaths/min and tidal volume (VT) = 15 ml/kg during solute clearance; 2) repeat control, for reproducibility; 3) increased frequency, with f = 25 breaths/min and VT = 10 ml/kg; 4) positive end-expiratory pressure (PEEP) of 10 cmH2O; 5) unilateral pulmonary arterial occlusion (PAO); and 6) bronchial arterial occlusion (BAO). Control t1/2 was 25 +/- 5 min and did not change in the repeat control, increased frequency, or BAO experiments. PEEP markedly decreased t1/2 to 13 +/- 3 min (P less than 0.01), and PAO increased it to 37 +/- 6 min (P less than 0.05). We conclude that clearance from the lungs by our method is uninfluenced by increased frequency, increases markedly with PEEP, and depends on pulmonary, not bronchial, blood flow.     

Clearance of different-sized proteins from the alveolar space in humans and rabbits.

Investigation of the clearance of proteins from the air spaces is important for an understanding of the resolution of pulmonary edema and also because of current interest in delivery of therapeutic peptides via the distal air spaces. Few experimental studies have examined the size dependence for alveolar clearance of large macromolecules; there have been no human studies. In anesthetized rabbits, we measured clearance of cyanocobalamin and different-sized human proteins instilled into the air spaces. After 8 h, the amounts of instilled tracer recovered in the lungs were [57Co]cyanocobalamin, 19.4 +/- 3.0% (Stokes radius 0.65 nm); 125I-labeled insulin, 64.6 +/- 3.9% (1.2 nm); 131I-labeled albumin, 87.0 +/- 4.0% (3.5 nm); and 125I-labeled immunoglobulin G, 91.8 +/- 3.3% (5.5 nm) (P < 0.05). Sieving of different-sized proteins occurred across the alveolar epithelial barrier because tracer concentrations in air space lavage fluid after 8 h were decreased more for the smaller tracers than the larger ones. Size selectivity for alveolar protein clearance in humans with resolving alveolar edema was investigated by measuring the changes in albumin and total protein concentration. The fraction of total protein concentration made up of albumin was greater in the edema fluid than in the plasma initially. The albumin fraction decreased with time in 9 of 10 patients with resolving edema, from 0.62 +/- 0.2 to 0.58 +/- 0.10 (P < 0.05) after 10 +/- 5 h. Thus both rabbit studies and human studies provide evidence for size-dependent clearance of protein from the air spaces of the lung.(ABSTRACT TRUNCATED AT 250 WORDS)