Pulmonary reduction of an intravascular redox polymer

Pulmonary endothelial cells in culture reduce external electron acceptors via transplasma membrane electron transport (TPMET). In studying endothelial TPMET in intact lungs, it is difficult to exclude intracellular reduction and reducing agents released by the lung. Therefore, we evaluated the role of endothelial TPMET in the reduction of a cell-impermeant redox polymer, toluidine blue O polyacrylamide (TBOP(+)), in intact rat lungs. When added to the perfusate recirculating through the lungs, the venous effluent TBOP(+) concentration decreased to an equilibrium level reflecting TBOP(+) reduction and autooxidation of its reduced (TBOPH) form. Adding superoxide dismutase (SOD) to the perfusate increased the equilibrium TBOP(+) concentration. Kinetic analysis indicated that the SOD effect could be attributed to elimination of the superoxide product of TBOPH autooxidation rather than of superoxide released by the lungs, and experiments with lung-conditioned perfusate excluded release of other TBOP(+) reductants in sufficient quantities to cause significant TBOP(+) reduction. Thus the results indicate that TBOP(+) reduction is via TPMET and support the utility of TBOP(+) and the kinetic model for investigating TPMET mechanisms and their adaptations to physiological and pathophysiological stresses in the intact lung.     

Movement of ions and small solutes across endothelium and epithelium of perfused rabbit lungs

In situ and isolated fluid-filled rabbit lungs were used to study the transport of indicators between the air space and vascular compartments. These indicators were placed in either the perfusate or air spaces and samples were collected from the perfusate at intervals during a 1-h perfusion period. At the end of the hour, fluid was pumped out of the air space compartment into serial tubes and indicator concentrations were determined in both the air space and perfusion fluids. One hour after introducing the indicators into the air space, the relative decreases in solute concentration were (arranged from the greatest to the least decline): [14C]urea greater than 36Cl- = 125I- greater than 22Na+ greater than [3H]mannitol. The relative rates at which the indicators appeared in the perfusate were similar. When the indicators were placed in the perfusate, a similar relationship was observed in the increase in air space concentrations, but the loss of 22Na+ from the perfusate was similar to those of 36Cl- and 125I-. Losses of all indicators from the perfusate were two or more times those from the air spaces, and although the loss of [3H]mannitol from the perfusate was similar to that of 22Na+ for about 30 min, subsequent loss was much slower. Very little 125I-albumin traversed the tissue barrier, and the small changes in the concentrations of 125I-albumin in the air spaces suggested that little fluid movement had occurred. These studies suggest that the epithelium is less permeable to solutes than the endothelium and permits passage of anions at a faster rate than 22Na+.(ABSTRACT TRUNCATED AT 250 WORDS)     

Opposite effects of methylene blue and ascorbate on lipid peroxidation in muscles. Correlation with the redox state. I. Experiments on satisfied frogs

Homogenates of heart, stomach and rectus abdominis muscles of the frog have shown different degrees of malondialdehyde (MDA) formation. MDA content was highest in heart, and lowest in stomach musculature. The resultant tissue redox-state potential (RSP) and redox potential (E'0) in homogenates determined potentiometrically also showed differences with opposite signs in relation to MDA levels. An electron acceptor, methylene blue (MB), decreased but an electron donor, ascorbate (Asc), increased the MDA level in each of the muscles. These effects were dependent upon the concentration of MB and Asc and proportional to the control MDA content in each muscle. Thus an inverse interdependence between MDA level and redox state existed even when a positive change in redox potentials was induced by MB, and also when a negative change was induced by Asc. Since there was a close negative correlation between the changes of MDA concentration and redox potential in the homogenates, it is strongly suggested that the changes of redox state in muscle are implicated in the processes leading to lipid peroxidation (LP).     

Pulmonary epithelial sieving of small solutes in rat lungs

Transport and consumption of glucose from the air spaces of isolated, fluid-filled lungs can result in significantly lower glucose concentrations in the air spaces than in the perfusate compartment (11). This concentration difference could promote the osmotic movement of water from the air spaces to the perfusate, but the rate of fluid extraction from the air spaces would then be limited by the rates of electrolyte transport through the epithelium. In the present study, measurements were made of solute and water losses from the air spaces of fluid-filled rat lungs and the transport of these solutes and water into the vasculature after addition of hypertonic glucose or sucrose to the perfusate. Increases in the concentrations of Na+, Cl-, K+, and labeled mannitol in the air space were initially comparable to those of albumin labeled with Evans blue. Similarly, decreases in electrolyte concentrations in the perfusate were comparable to those of labeled albumin, indicating that very little solute accompanied the movement of water out of the lungs. Nor was evidence found that exposure of the vasculature to hypertonic glucose resulted in an increase in the rate at which fluid was reabsorbed from the air spaces over a 1-h interval, aside from an initial, abrupt loss of solute-free water from the lungs. These observations suggest that perfusion of fluid-filled lungs with hypertonic solutions of small solutes results in the extraction of water from the air spaces and pulmonary parenchyma across membranes that resist the movement of electrolytes and other lipophobic solutes.     

Pulmonary microvascular response to LTB4: effects of perfusate composition

We examined the effects of leukotriene B4 (LTB4) on pulmonary hemodynamics and vascular permeability using isolated perfused guinea pig lungs and cultured monolayers of pulmonary arterial endothelial cells. In lungs perfused with Ringer solution, containing 0.5 g/100 ml albumin (R-alb), LTB4 (4 micrograms) transiently increased pulmonary arterial pressure (Ppa) and capillary pressure (Pcap). Pulmonary edema developed within 70 min after LTB4 injection despite a normal Pcap. The LTB4 metabolite, 20-COOH-LTB4 (4 micrograms), did not induce hemodynamic and lung weight changes. In lungs perfused with autologous blood hematocrit = 12 +/- 1%; protein concentration = 1.5 +/- 0.2 g/100 ml), the increases in Ppa and Pcap were greater, and both pressures remained elevated. The lung weight did not increase in blood-perfused lungs. In lungs perfused with R-alb (1.5 g/100 ml albumin) to match the blood perfusate protein concentration, LTB4 induced similar hemodynamic changes as R-alb (0.5 g/100 ml) perfusate, but the additional albumin prevented the pulmonary edema. LTB4 (10(-11)-10(-6) M) with or without the addition of neutrophils to the monolayer did not increase endothelial 125I-albumin permeability. Therefore LTB4 induces pulmonary edema when the perfusate contains a low albumin concentration, but increasing the albumin concentration or adding blood cells prevents the edema. The edema is not due to increased endothelial permeability to protein and is independent of hemodynamic alterations. Protection at higher protein-concentration may be the result of LTB4 binding to albumin.     

Reduction and uptake of methylene blue by human erythrocytes

A thiazine dye reductase has been described in endothelial cells that reduces methylene blue (MB), allowing its uptake into cells. Because a different mechanism of MB uptake in human erythrocytes has been proposed, we measured MB uptake and reduction in this cell type. Oxidized MB (MB⁺) stimulated reduction of extracellular ferricyanide in a time- and concentration-dependent manner, reflecting extracellular reduction of the dye. Reduced MB was then taken up by the cells and partially oxidized to MB⁺. Both forms were retained against a concentration gradient, and their redox cycling induced an oxidant stress in the cells. Whereas concentrations of MB⁺ <5 µM selectively oxidized NAD(P)H, higher concentrations also oxidized both glutathione (GSH) and ascorbate, especially in the absence of D-glucose. MB⁺-stimulated ferricyanide reduction was inhibited by thiol reagents with different mechanisms of action. Phenylarsine oxide, which is selective for vicinal dithiols in proteins, inhibited MB⁺-dependent ferricyanide reduction more strongly than it decreased cell GSH and pentose phosphate cycle activity, and it did not affect cellular NADPH. Open erythrocyte ghost membranes facilitated saturable NAD(P)H oxidation by MB⁺, which was abolished by pretreating ghosts with low concentrations of trypsin and phenylarsine oxide. These results show that erythrocytes sequentially reduce and take up MB⁺, that both reduced and oxidized forms of the dye are concentrated in cells, and that the thiazine dye reductase activity initially responsible for MB⁺ reduction may correspond to MB⁺-dependent NAD(P)H reductase activity in erythrocyte ghosts. thiazine dyes; ascorbic acid; ferricyanide; phenylarsine oxide; oxidant stress; redox cycling     

Mechanisms of extracellular reactive oxygen species injury to the pulmonary microvasculature.

We investigated the effect of xanthine (X) plus xanthine oxidase (XO) on pulmonary microvascular endothelial permeability in isolated rabbit lungs perfused with Krebs buffer containing bovine serum albumin (5 g/100 ml). Addition of five mU/ml XO and 500 microM X to the perfusate caused a twofold increase in the pulmonary capillary filtration coefficient (Kf,c) 30 min later without increasing the pulmonary capillary pressure. This increase was prevented by allopurinol or catalase but not by superoxide dismutase or dimethyl sulfoxide. Because these data implicated hydrogen peroxide (H2O2) as the injurious agent, we measured its concentration in the perfusate after the addition of X and XO for a 60-min interval. In the absence of lung tissue and albumin, H2O2 increased with time, reaching a concentration of approximately 250 microM by 60 min. If albumin (5 g/100 ml) was added to the perfusate, or in the presence of lung tissue, the corresponding values were 100 microM and less than 10 microM, respectively. To understand the mechanisms of H2O2 scavenging by lung tissue, we added a 250 microM bolus of H2O2 to the lung perfusate. We found that H2O2 was removed rapidly, with a half-life of 0.31 +/- 0.04 (SE) min. This variable was not increased significantly by inhibition of lung catalase activity with sodium azide or inhibition of the lung glutathione redox cycle with 1-chloro-2,4-dinitrobenzene. However, inhibition of both enzymatic systems increased the half-life of H2O2 removal to 0.71 +/- 0.09 (SE) min (P less than 0.05).(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.     

The effects of neutrophils and phospholipase A2 on transvascular albumin flux in isolated rabbit lungs

In this study, addition of phospholipase A2 (PLA2) to salt-perfused isolated rabbit lungs containing rabbit polymorphonuclear leukocytes leads to an increase in pulmonary capillary permeability. We add 1.5 X 10(8) polymorphonuclear leukocytes to the perfusate. Next, indomethacin is added to the perfusate and 40 units of PLA2 are infused into the pulmonary arterial inflow of the lungs. At the end of the study, a lung sample is removed for measurement of transvascular albumin flux using I125-albumin as a measure of the permeability-surface area product. Control studies demonstrate no increase in transvascular albumin flux. Addition of a dual cyclooxygenase and lipoxygenase inhibitor, BW755C, to the perfusate prevents the increase in transvascular albumin flux. We conclude that PLA2 interacts with polymorphonuclear leukocytes to increase protein permeability. Since PLA2 can release endogenous arachidonic acid and platelet-activating factor from cells, this suggests that release of such products may contribute to an increase in pulmonary capillary permeability from polymorphonuclear leukocytes. The ability of BW755C to prevent the increase suggests the possibility that lipoxygenase products contribute.     

The metabolism of 3-H-cortisone and 3-H-cortisol by the isolated perfused rat and guinea pig lungs.

Isolated perfused rat lungs removed more than 35% of 3-H-cortisone (1 times 10-9M) from the perfusate during one passage through the pulmonary circulation. The cortisone in the lungs was then rapidly converted to cortisol, which was returned to the perfusate. The tritiated steroid taken up was so rapidly washed from the lung, that only 10% remained after a 12 minute perfusion with steroid-free medium. In recirculating experiments, nearly 60% conversion to cortisol occurred over 32 cycles; in addition, there was a slow increase in the percentage of polar compounds in the medium. Similarly, the perfused hindlimbs preparation from the rat converted cortisone to cortisol and returned the cortisol to the perfusate. In contrast, guinea pig isolated perfused lungs had neglible effect on cortisone. Rat lungs demonstrated only a limited ability to convert 3-H-cortisol to cortisone. The results suggest that the lungs may play an important role in maintaining cortisone/cortisol levels in the plasma.     

亚甲蓝与多聚阴离子化合物结合反应的研究

对光谱探针亚甲蓝(MB)分别与硫酸化茯苓多糖(SP)、硫酸软骨素(CS)、透明质酸(HA)等多聚阴离子化合物相互作用的吸收光谱进行了比较研究,探讨了CS等多聚阴离子化合物与MB相互作用机理及其与MB结合的功能基团,计算了MB与SP、CS最大结合数分别为54和73。研究结果表明MB与多聚阴离子化合物的磺酸基发生明显的结合反应,与羧基不能发生明显的结合反应,多聚阴离子化合物与MB结合的功能基团是磺酸基。     

Duroquinone reduction during passage through the pulmonary circulation

The lungs can substantially influence the redox status of redox-active plasma constituents. Our objective was to examine aspects of the kinetics and mechanisms that determine pulmonary disposition of redox-active compounds during passage through the pulmonary circulation. Experiments were carried out on rat and mouse lungs with 2,3,5,6-tetramethyl-1,4-benzoquinone [duroquinone (DQ)] as a model amphipathic quinone reductase substrate. We measured DQ and durohydroquinone (DQH2) concentrations in the lung venous effluent after injecting, or while infusing, DQ or DQH2 into the pulmonary arterial inflow. The maximum net rates of DQ reduction to DQH2 in the rat and mouse lungs were approximately 4.9 and 2.5 micromol. min(-1).g dry lung wt(-1), respectively. The net rate was apparently the result of freely permeating access of DQ and DQH2 to tissue sites of redox reactions, dominated by dicumarol-sensitive DQ reduction to DQH2 and cyanide-sensitive DQH2 reoxidation back to DQ. The dicumarol sensitivity along with immunodetectable expression of NAD(P)H-quinone oxidoreductase 1 (NQO1) in the rat lung tissue suggest cytoplasmic NQO1 as the dominant site of DQ reduction. The effect of cyanide on DQH2 oxidation suggests that the dominant site of oxidation is complex III of the mitochondrial electron transport chain. If one envisions DQ as a model compound for examining the disposition of amphipathic NQO1 substrates in the lungs, the results are consistent with a role for lung NQO1 in determining the redox status of such compounds in the circulation. For DQ, the effect is conversion of a redox-cycling, oxygen-activating quinone into a stable hydroquinone.     

Protein concentrations have little effect on reabsorption of fluid from isolated rat lungs

A study was conducted to determine whether differences in the concentrations of large molecules between the air space and perfusate solutions altered the rates at which fluid was reabsorbed from isolated fluid-filled perfused rat lungs. Four groups of experiments were conducted: 1) 5 g/dl albumin in the air spaces and perfusate, 2) 15 g/dl albumin in the air space and 5 g/dl albumin in the perfusate, 3) 5 g/dl albumin in the air space and 15 g/dl albumin in the perfusate, and 4) a mixture of 5 g/dl albumin and 7 g/dl Dextran 70 in the air spaces and 5 g/dl albumin in the perfusate. Fluid reabsorption was determined by following the concentration of albumin labeled with Evans blue (T-1824) in the air space and perfusate compartments. Because leakage of protein between the air space and perfusate compartments is very slow, increases in T-1824 concentrations in the air spaces indicated loss of fluid from this compartment, whereas decreases in these concentrations in the perfusate compartment provided evidence of fluid transport into the vasculature. Approximately 30% of the air space fluid was reabsorbed in a 2-h period, and virtually all of this fluid reached the perfusate compartment. Despite oncotic differences that ranged from -65 to 65 Torr, variations in air space or perfusate albumin concentrations did not have a significant effect on this process. A 30% decrease in fluid reabsorption was observed when dextran was in the air space solution, but this decrease did not appear to be due to the oncotic properties of this solution because albumin did not have a measurable effect on reabsorption.(ABSTRACT TRUNCATED AT 250 WORDS)     

Antibiofilm action of a toluidine blue O-silver nanoparticle conjugate on Streptococcus mutans: a mechanism of type I photodynamic therapy

The objective of this study was to evaluate the anti-biofilm efficacy of photodynamic therapy by conjugating a photosensitizer (TBO) with silver nanoparticles (AgNP). Streptococcus mutans was exposed to laser light (630 nm) for 70 s (9.1 J cm^?2) in the presence of a toluidine blue O–silver nanoparticle conjugate (TBO–AgNP). The results showed a reduction in the viability of bacterial cells by 4 log₁₀. The crystal violet assay, confocal laser scanning microscopy and scanning electron microscopy revealed that the TBO–AgNP conjugates inhibited biofilm formation, increased the uptake of propidium iodide and leakage of the cellular constituents, respectively. Fluorescence spectroscopic studies confirmed the generation of OH^? as a major reactive oxygen species, indicating type I phototoxicity. Both the conjugates down-regulated the expression of biofilm related genes compared to TBO alone. Hence TBO–AgNP conjugates were found to be more phototoxic against S. mutans biofilm than TBO alone.     

Study of solar photosensitization processes on dermatophytic fungi

The antifungal activity of solar simulator was evaluated in presence of haematoporphyrin derivative (HPD), methylene blue (MB) and toluidine blue O (TBO) as photosensitizers. Seven dermatophytes were used as test fungi. The solar simulator at fluence rate 400 W/m2 for 30 minutes induced marked inhibition for spore germination of the photosensitized fungi. The rate of inhibition varied according to the fungal species and concentration of the photosensitizer. There was an increase in percentage inhibition of spore germination as the concentration of HPD or MB increased. Complete inhibition for spore germination of Trichophyton. verrucosum, T. mentagrophytes, and Miccrosporum canis was induced when these species were pretreated with 10(-3) M of HPD or MB before irradiation. Epidermophyton floccosum, T. rubrum, M. gypseum and T. violaceum were less sensitive to irradiation when pretreated with HPD or MB. On contrary, the maximum reduction in percentage spore germination was induced at the lowest concentration (10(-7) M) of TBO. The tested dermatophytes were mostly capable of producing different enzymes (keratinase, phosphatases, amylase, lipase). The separate application of radiation or photosensitizer was ineffective or exerted slight inhibition on enzyme production. However, the activity of the enzymes was drastically inhibited when the fungi were irradiated after their treatment with photosensitizer. T. verrucosum and T. mentagrophytes were the most sensitive. In a trail to apply a control measure against dermatomycosis using solar simulator radiation, the results revealed that the radiation was successful in curing the MB-photosensitized guinea pigs, artificially infected with T. verrucosum, T. mentagrophytes or M. canis. The percentage of recovery reached 100% in some treatments.     

Influence of flow on pulmonary vascular surface area inferred from blue dextran efflux data.

Blue dextran (BD), which binds to proteins on the pulmonary endothelial surface and to plasma albumin, was used in isolated perfused dog lung lobe experiments to address the question: do changes in perfusate flow rate cause changes in perfused vascular surface area? When BD was added to a protein-free perfusate under zone 3 conditions at a high flow rate (15.8 +/- 0.7 ml/s), it was adsorbed by the endothelial surface. Then by changing the perfusate entering the lobe to an albumin-containing perfusate, the BD was eluted from the perfused surface by competitive binding to the perfusate albumin. The amount of BD eluted was measured in three experiments. In experiment 1, elution of the BD by the perfusate albumin was initiated after a balloon had been inflated within the lobar arterial tree to occlude a portion of the lobar vascular bed containing BD. Then the balloon was deflated, permitting albumin perfusate to perfuse the previously occluded part of the lobe. In experiment 2, BD elution began at a flow rate of 3 +/- 0.1 ml/s under zone 3 conditions and continued after the high-flow zone 3 conditions were reestablished. In experiment 3, the BD elution began at a flow rate of 4.2 +/- 0.7 ml/s under zone 2 conditions and continued after the high-flow zone 3 conditions were reestablished. Balloon inflation reduced the amount of BD recovered by 43%, demonstrating that a decrease in perfused vascular surface area could decrease BD recovery.(ABSTRACT TRUNCATED AT 250 WORDS)     

The role of the blood in metabolism of prostaglandin E1 in the cat lung

We found that when 15-keto-PGE1 was added to cat blood, it was converted to 13,14-dihydro-15-keto-PGE1 (dihydro-keto-PGE1) by a NADH-dependent enzyme associated with some formed element(s) in the blood. When PGE1 was injected into the pulmonary artery of blood-perfused lungs, the only metabolite detectable in the pulmonary venous blood was the dihydro-keto-PGE1. However, when the lungs were perfused with an artificial perfusate containing no blood cells, a small amount of 15-keto-PGE1 was detected in the venous effluent. Therefore it would appear that a blood-borne Δ13 reductase was partially responsible for the conversion of PGE1 to dihydro-keto-PGE1 on passage through blood-perfused cat lungs.     

The role of the blood in metabolism of prostaglandin E1 in the cat lung.

We found that when 15-keto-PGE1 was added to cat blood, it was converted to 13, 14-dihydro-15-keto-PGE1 (dihydro-keto-PGE1) by a NADH-dependent enzyme associated with some formed element(s) in the blood. When PGE1 was injected into the pulmonary artery of blood-perfused lungs, the only metabolite detectable in the pulmonary venous blood was the dihydro-keto-PGE1. However, when the lungs were perfused with an artificial perfusate containing no blood cells, a small amount of 15-keto-PGE1 was detected in the venous effluent. Therefore it would appear that a blood-borne delta13 reductase was partially responsible for the conversion of PGE1 to dihydro-keto-PGE1 on passage through blood-perfused cat lungs.     

Methyl-beta-cyclodextrin directly binds methylene blue and blocks both its cell staining and glucose uptake stimulatory effects

GLUT1, the most ubiquitously expressed member of the GLUT family of glucose transporters, can be acutely activated by a variety of cell stresses. Methylene blue activates glucose transport activity of GLUT1 in L929 fibroblast cells presumably by a redox cycling of MB, which generates an oxidative stress. Data shown here reveal that methyl-beta-cyclodextrin (MCD) blocks both the staining of cells and activation of glucose uptake by directly binding to MB. MCD binding to MB was qualitatively demonstrated by a significantly slower dialysis rate of MB in the presence of MCD. Analysis of the complete spectra of aqueous MB solutions and MB plus MCD solutions by a factor analysis program called SIVVU indicated that these equilibria can be modeled by three species: MB monomer, MB dimer, and MCD-MB inclusion complex. The molar extinction coefficients for each species from 500 to 700nm were determined. The equilibrium association constant (K(a)) for MB dimer formation was measured at 5846+/-30M(-1) and the K(a) for formation of the MCD-MB complex was 310+/-10M(-1). MCD also dramatically enhances the destaining rate of MB-stained cells. The loss of MB from the cell is tightly correlated with the loss of activated glucose uptake. This suggests that the MB activation of glucose uptake is likely not caused by its redox cycling, but more likely the result of a specific interaction between MB and a protein directly involved in the activation of GLUT1.     

Methylene blue stimulates 2-deoxyglucose uptake in L929 fibroblast cells

Methylene blue (MB), a common cell stain, has been shown to inhibit nitric oxide synthase and guanylate cyclase, which has led to the recent use of MB in nitric oxide signaling studies. This study documents the effects of MB on 2-deoxyglucose (2DG) uptake in L929 fibroblast cells where uptake is controlled by a single glucose transporter, GLUT 1. MB significantly activates cytochalasin B-inhibitable glucose transport in a dose dependent fashion within 10 min. A maximal stimulation of up to 800% was achieved by 50 microM MB after a 45-min exposure. The Vmax of transport increased without a change in the Km, which was accomplished without a significant change in the GLUT 1 content. The reduced form of MB, did not stimulate 2DG uptake and potassium ferricyanide, an extracellular redox agent, prevented both the staining and stimulatory effects of MB suggesting MB is reduced at the cell surface before it enters L929 cells. Phenylarsine oxide did not block cell staining as noted in other cells lines, but it did inhibit both basal and MB-stimulated 2DG uptake. Likewise, methyl-beta-cyclodextrin, an agent used to remove membrane cholesterol, blocked both the staining and stimulatory effects of MB. The AMP analog, AICAR, inhibited rather than activated basal 2DG uptake, and it did not alter MB-stimulated uptake suggesting that AMP kinase activation is not critical to the MB effect. Wortmannin, an inhibitor of PI kinase, had no effect on MB-stimulated 2DG uptake. These data provide additional insight into the acute regulation of GLUT 1 transport activity in L929 cells.