Transport of glucose and fructose in rat hepatocytes at 37 degrees C

The kinetic parameters for transport of the nonmetabolizable glucose analogue 3-O-methyl-D-glucose and the relationship between transport and metabolism of D-glucose and D-fructose were determined in isolated rat hepatocytes at 37 degrees C and pH 7.4. 3-O-Methylglucose at a very low concentration (0.1 mM) equilibrated with the intracellular water with a rate constant of 0.41 s-1. Km for equilibrium exchange entry was 5.5 mM and Vmax was 2.2 mM X s-1 and similar results were obtained when using the zero-trans entry protocol. The rate constant for entry of tracer D-glucose was 0.15 s-1 and Km for glucose was about 20 mM. The phosphorylation rate for D-glucose was much slower than the transport rate. The rate constant for D-fructose entry was about 0.04 s-1, the apparent Km was about 100 mM and Vmax about 5 mM X s-1. The concentration dependence of 3-O-methylglucose inhibition of labelled fructose transport revealed biphasic kinetics indicating that fructose was transferred by both the glucose transporter and a fructose transporter. At concentrations lower than 1 mM, fructose metabolism appeared to be limited by the transport step.     

Cytochalasin B inhibition and temperature dependence of 3-O-methylglucose transport in fat cells

The transport of 3-O-methylglucose in white fat cells was measured under equilibrium exchange conditions at 3-O-methylglucose concentrations up to 50 mM with a previously described method (Vinten, J., Gliemann, J. and Osterlind, K. (1976) J. Biol. Chem. 251, 794--800). Under these conditions the main part of the transport was inhibitable by cytochalasin B. The inhibition was found to be of competitive type with an inhibition constant of about 2.5 . 10(-7) M, both in the absence and in the presence of insulin (1 micrometer). The cytochalasin B-insensitive part of the 3-O-methylglucose permeability was about 2 . 10(-9) cm . s-1, and was not affected by insulin. As calculated from the maximum transport capacity, the half saturation constant and the volume/surface ratio, the maximum permeability of the fat cell membrane to 3-O-methylglucose at 37 degrees C and in the presence of insulin was 4.3 . 10(-6) cm . s-1. From the temperature dependence of the maximum transport capacity in the interval 18--37 degrees C and in the presence of insulin, an Arrhenius activation energy of 14.8 +/- 0.44 kcal/mol was found. The corresponding value was 13.9 +/- 0.89 in the absence of insulin. The half saturating concentration of 3-O-methylglucose was about 6 mM in the temperature interval used, and it was not affected by insulin, although this hormone increased the maximum transport capacity about ten-fold to 1.7 mmol . s-1 per 1 intracellular water at 37 degrees C.     

Effect of chemotactic factors on hexose transport in polymorphonuclear leucocytes

Transport of the nonmetabolizable glucose analogue, 3-O-methylglucose, was assessed in human polymorphonuclear leucocytes with or without the chemotactic peptide N-formylmethionylleucylphenylalanine (fMet-Leu-Phe). The peptide increased entry of labelled 3-O-methylglucose about 5-fold and the intracellular distribution space about 70%. The half-time of equilibration was 3 s in the treated cells. Similar effects were observed with zymosan-treated serum (containing the chemotactic factor C5a), with arachidonic acid, calcium ionophore A23187 and phorbol myristate acetate. However, the chemotactic protein, thrombin, had no effect, even though binding to high-affinity receptors was demonstrated. Km for zero-trans entry of 3-O-methylglucose was about 1 mM and fMet-Leu-Phe increased Vmax from 5 to about 25 amol.s-1.cell-1. Similar values were obtained from incubations for a few seconds with glucose and 2-deoxyglucose. The rate of 2-deoxyglucose uptake (8 min incubations) was limited by the transport step at substrate concentrations lower than approx. 0.1 mM, whereas the phosphorylation step became rate-limiting at higher concentrations. Thus, 2-deoxyglucose uptake can only be taken as a measure of transport at a tracer concentration. It is concluded that chemotactic factors can, but do not necessarily, increase the maximal transport velocity of hexoses entering the polymorphonuclear leucocyte via the glucose transporter.     

A kinetic analysis of hexose transport in cultured human lymphocytes (IM-9)

3-O-Methyl-D-glucose transport across the plasma membrane of cultured human lymphocytes of the IM-9 line was followed for net entry into sugar-free cells (zero trans entry), net exit into sugar-free medium (zero trans exit) and for equilibration of labelled sugar in cells with the same sugar concentration in the intracellular water as in the medium (equilibrium exchange). The measurements were performed at 37 degrees C (pH 7.4). Equilibrium exchange of 1 mM 3-O-methylglucose (t 1/2 about 7 S) was exponential, suggesting a homogeneous cell suspension. Initial rates of transport showed a Michaelis-Menten dependency on the sugar concentration. The transport system was found to be asymmetric with the following kinetic parameters. Zero trans entry: Km = 2.8 mM, Vmax = 10.7 mM X min-1. Zero trans exit: Km = 9.5 mM, Vmax = 37.9 mM X min-1. Equilibrium exchange: Km = 9.9 mM, Vmax = 44.0 mM X min-1. Finally, the affinity constant for the internal site was measured as approx. 1.2 mM using the infinite cis protocol.     

Glucose transport kinetics in human red blood cells

D-[14C]Glucose self exchange and unidirectional efflux from human red blood cells were studied at 20 degrees C (pH 7.2) by means of the Millipore-Swinnex filtering technique whose time resolution is greater than 1 s and the continuous flow-tube method with a time resolution of greater than 2 ms. The unidirectional efflux data were analyzed using both the method of initial rates and the integrated rate equation. Simple Michaelis-Menten kinetics apply to the results obtained under both experimental conditions. In self-exchange mode, the half-saturation constant, K1/2ex, was 10 (S.E. +/- 1) mM. In unidirectional efflux mode K1/2ue was 6.6 (S.E. +/- 0.5) mM (initial rates) or by the method of integrated rates 7.7 mM, with a range of 2.7-12.1 mM, K1/2ue increasing with an increased initial intracellular glucose concentration. Our results of K1/2ex oppose previous published values of 32 mM for self exchange (Eilam and Stein (1972) Biochim. Biophys. Acta 266, 161-173) and 25 mM for unidirectional efflux (Karlish et al. (1972) Biochim. Biophys. Acta 255, 126-132) that have been used extensively in kinetic considerations of glucose transport models. Under self-exchange conditions Jmaxex was 1.8 x 10(-10) mol cm-2s-1, and in unidirectional efflux mode Jmaxue was 8.3 x 10(-11) mol cm-2s-1 (initial rates) and 8.6 x 10(-11) mol cm-2s-1 (integrated rates). We suggest that the previous high values of Jmax and in particular K1/2 are due to the use of methods with insufficient time resolution. Our results indicate that the transport system is less asymmetric than was generally accepted, and that complicated transport models developed to account for the great difference between the determined K1/2 and J max values are redundant.     

Effects of insulin on glucose transport and glucose transporters in rat heart.

The effect of insulin on glucose transport and glucose transporters was studied in perfused rat heart. Glucose transport was measured by the efflux of labelled 3-O-methylglucose from hearts preloaded with this hexose. Insulin stimulated 3-O-methylglucose transport by: (a) doubling the maximal velocity (Vmax); (b) decreasing the Kd from 6.9 to 2.7 mM; (c) increasing the Hill coefficient toward 3-O-methylglucose from 1.9 to 3.1; (d) increasing the efficiency of the transport process (k constant). Glucose transporters in enriched plasma and microsomal membranes from heart were quantified by the [3H]cytochalasin-B-binding assay. When added to normal hearts, insulin produced the following changes in the glucose transporters: (a) it increased the translocation of transporters from an intracellular pool to the plasma membranes; (b) it increased (from 1.6 to 2.7) the Hill coefficient of the transporters translocated into the plasma membranes toward cytochalasin B, suggesting the existence of a positive co-operativity among the transporters appearing in these membranes; (c) it increased the affinity of the transporters (and hence, possibly, of glucose) for cytochalasin B. The data provide evidence that the stimulatory effect of insulin on glucose transport may be due not to the sole translocation of intracellular glucose transporters to the plasma membrane, but to changes in the functional properties thereof.     

Transport and metabolism of glucose in an insulin-secreting cell line, beta TC-1.

Kinetic characteristics of glucose transport and glucose phosphorylation were studied in the islet cell line beta TC-1 to explore the roles of these processes in determining the dependence of glucose metabolism and insulin secretion on external glucose. The predominant glucose transporter present was the rat brain/erythrocyte type (Glut1), as determined by RNA and immunoblot analysis. The liver/islet glucose transporter (Glut2) RNA was not detected. The functional parameters of zero-trans glucose entry were Km = 9.5 +/- 2 mM and Vmax = 15.2 +/- 2 nmol min-1 (microL of cell water)-1. Phosphorylation kinetics of two hexokinase activities were characterized in situ. A low-Km (0.036 mM) hexokinase with a Vmax of 0.40 nmol min-1 (microL of cell water)-1 was present along with a high-Km (10 mM) hexokinase, which appeared to conform to a cooperative model with a Hill coefficient of about 1.4 and a Vmax of 0.3 nmol min-1 (microL of cell water)-1. Intracellular glucose at steady state was about 80% of the extracellular glucose from 3 to 15 mM, and transport did not limit metabolism in this range. In this static (nonperifusion) system, 2-3 times more immunoreactive insulin was secreted into the medium at 15 mM glucose than at 3 mM. The dependence of insulin secretion on external glucose roughly paralleled the dependence of glucose metabolism on external glucose. Simulations with a model demonstrated the degree to which changes in transport activity would affect intracellular glucose levels and the rate of the high-Km hexokinase (with the potential to affect insulin release).     

Accelerated net efflux of 3-O-[14C]methylglucose in isolated fat cells

A flow-tube apparatus suited for measurement of rapid efflux of sugars from adipocytes is described. Due to heterogeneity of fat cell populations, a conventional analysis of the time-course of net efflux of 3-O-methylglucose based on the integrated rate equation can produce gross errors in estimates of kinetic parameters. The half-saturation constant and maximum transport capacity for 3-O-methylglucose transport were found to be about 3-fold higher for net efflux than for equilibrium exchange flux, both in insulin-stimulated and non-stimulated adipocytes. This suggests asymmetric kinetic parameters for 3-O-methylglucose transport.     

Pathways of reducing equivalents in hepatocytes from rats. Estimation of cytosolic fluxes by means of 3H-labelled substrates for either A- or B-specific dehydrogenases.

The rat insulinoma-derived RINm5F cell line retains many differentiated functions of islet beta-cells. However, it fails to recognize glucose as an insulin secretagogue in the physiological concentration range. With this cell line, glucose-transport kinetics were investigated, by using a double-label technique with the non-metabolizable glucose analogue 3-O-methylglucose (OMG). RINm5F cells possess a passive glucose-transport system with high capacity and low affinity. Equilibration across the plasma membrane of extracellular OMG concentrations up to at least 20 mM is achieved within 2 min at 37 degrees C. The half-saturation of OMG uptake occurs at 32 mM. At lower temperatures OMG uptake is markedly retarded, with a temperature coefficient (Q10) of 2.9. As indicated by efflux measurements, transport is symmetrical. Cytochalasin B at micromolar concentrations and phlorrhizin in millimolar concentrations are potent inhibitors of OMG uptake. Neutralization of the secreted insulin with antibodies does not alter OMG uptake kinetics. The glucose metabolism of RINm5F cells is much exaggerated compared with that of islet beta-cells. Nonetheless, when measured in parallel to uptake, transport exceeds by far the rate of metabolism at glucose concentrations above 3 mM. Measurements of intracellular D-glucose reveal a lower intracellular glucose concentration relative to the extracellular in RINm5F cells. This seems to be due to abnormalities in the subsequent steps of glucose metabolism, rather than to abnormalities in hexose uptake. The loss of glucose-induced insulin release in RINm5F cells cannot be explained by alterations in hexose transport.     

Transport of AMP by Rickettsia prowazekii.

Rickettsia prowazekii possesses an exchange transport system for AMP. Chromatographic analysis of the rickettsiae demonstrated that transported AMP appeared intracellularly as AMP, ADP, and ATP, and no hydrolytic products appeared in either the intracellular or extracellular compartments. The phosphorylation of AMP to ADP and ATP was prevented by pretreatment of the cells with 1 mM N-ethylmaleimide without inhibiting the transport of AMP. Although no efflux was demonstrable in the absence of nucleotide in the medium, the intracellular adenine nucleotide pool could be exchanged with external unlabeled adenine nucleotides. Both ADP and ATP were as effective as AMP at inhibiting the uptake of [3H]AMP. Although this transport system was inhibited by low temperature (0 degrees C) and partially inhibited by the protonophore carbonyl cyanide-m-chlorophenyl hydrazone (1 mM), it was relatively insensitive to KCN (1 mM). The uptake of AMP at 34 degrees C had an apparent Kt for influx of 0.4 mM and a Vmax of 354 pmol min-1 per mg. At 0 degrees C there was a very rapid and unsaturable association of AMP with these organisms. Correction of the uptake data at 34 degrees C for the 0 degrees C component lowered the apparent Kt to 0.15 mM. Both magnesium and phosphate ions are required for optimal transport activity. Chemical measurements of the total intracellular nucleotide pools demonstrated that this system was not a net adenine nucleotide transport system, but that uptake of AMP was the result of an exchange with internal adenine nucleotides.     

Glucose tolerance factor stimulates 3-O-methylglucose transport into isolated rat adipocytes

Glucose tolerance factor partially purified from yeast extract powder stimulated [U-14C]-D-glucose uptake to a level 5.6 times greater than the basal level in the absence of insulin in isolated adipocytes prepared from rats fed with normal laboratory chow. The factor also stimulated 3-O-methylglucose transport 2.2-fold from the basal level in the absence of insulin, but not in the presence of 8 nM insulin. Kinetic analysis revealed that glucose tolerance factor increased 3-O-methylglucose transport by decreasing the Ks value for 3-O-methylglucose with little change in the Vmax.     

Expression of a functional glucose transporter in Xenopus oocytes

A cDNA encoding the rat brain glucose transporter was inserted between the 5' and 3' untranslated regions from the Xenopus globin gene and downstream of an SP6 RNA polymerase start site. RNA synthesized from this vector was microinjected into oocytes from Xenopus laevis; this resulted in expression of the glucose transporter, as determined by both immunoblotting and the appearance of transport activity. The properties of the transporter were those expected from previous studies: it was glycosylated, and its activity, measured by 3-O-methylglucose transport, was inhibited by D-glucose and cytochalasin B, but not by L-glucose. The low level of endogenous glucose transport activity found in water-injected oocytes makes this a useful system in which to determine the kinetic parameters of transport. The Km for 3-O-methylglucose was found to be 20 mM under equilibrium exchange conditions. Despite the fact that oocytes exhibit insulin-dependent responses, insulin did not stimulate 3-O-methylglucose transport by injected oocytes.     

Effect of glucocorticoids on the glucose transport system of isolated fat cells.

Glucocorticoids inhibit glucose utilization by fat cells. The possibility that this effect results from altered glucose transport was investigated using an oil-centrifugation technique which allows a rapid (within 45 s) estimation of glucose or 3-O-methylglucose uptake by isolated fat cells. At high concentration (greater than 25 muM), dexamethasone inhibited glucose uptake within 1 min of its addition to fat cells. Efflux of 3-O-methylglucose was also impaired by 0.1 mM dexamethasone. However, diminished glucose uptake was not a specific effect of glucocorticoids; high concentrations (0.1 mM) of 17beta-estradiol, progesterone, and deoxycorticosterone produced a similar response in adipocytes. At a more physiologic steroid concentration (0.1 muM), glucocorticoids inhibited glucose uptake in a time-dependent manner (maximum effect in 1 to 2 hours). This effect was specific for glucocorticoids since, under these conditions, glucose uptake was not changed by the non-glucocorticoid steroids. Lineweaver-Burk analysis showed that 0.1 muM dexamethasone treatment produced a decrease in Vmax for glucose uptake but did not change the Ku. Hexokinase activity and ATP levels were not altered by this treatment, suggesting that processes involved in glucose phosphorylation were not affected. Dexamethasone treatment also caused a reduction in uptake of 3-O-methylglucose when assayed using a low sugar concentration (0.1 mM). At a high concentration (10 mM), uptake of the methyl sugar was only slightly less than normal in treated cells. Stimulation by insulin markedly enhanced uptake of glucose and 3-O-methylglucose by both treated and untreated cells. At a low hexose concentration (0.1 mM) and in the presence of insulin, sugar uptake by dexamethasone-treated cells was slightly less than control cells. Stimulation by insulin did however completely overcome the alteration in hexose uptake when larger concentrations of sugars (greater than 5 mM) were used. There was no detectable change in total protein synthesis during incubation of fat cells with dexamethasone. However, actinomycin C blocked the inhibitory effect of dexamethasone on glucose uptake. Cycloheximide, which caused a small inhibition in glucose uptake, prevented the full expression of the inhibitory effect of dexamethasone on glucose transport. These results indicate that dexamethasone alters the facilitated transport of glucose and, secondly, suggest that synthesis of RNA and protein is needed for glucocorticoid action.     

Glucose and insulin co-regulate the glucose transport system in primary cultured adipocytes. A new mechanism of insulin resistance

We have previously shown in primary cultured rat adipocytes that insulin acts at receptor and multiple postreceptor sites to decrease insulin's subsequent ability to stimulate glucose transport. To examine whether D-glucose can regulate glucose transport activity and whether it has a role in insulin-induced insulin resistance, we cultured cells for 24 h in the absence and presence of various glucose and insulin concentrations. After washing cells and allowing the glucose transport system to deactivate, we measured basal and maximally insulin-stimulated 2-deoxyglucose uptake rates (37 degrees C) and cell surface insulin binding (16 degrees C). Alone, incubation with D-glucose had no effect on basal or maximal glucose transport activity, and incubation with insulin, in the absence of glucose, decreased maximal (but not basal) glucose transport rates only 18% at the highest preincubation concentration (50 ng/ml). However, in combination, D-glucose (1-20 mM) markedly enhanced the long-term ability of insulin (1-50 ng/ml) to decrease glucose transport rates in a dose-responsive manner. For example, at 50 ng/ml preincubation insulin concentration, the maximal glucose transport rate fell from 18 to 63%, and the basal uptake rate fell by 89%, as the preincubation D-glucose level was increased from 0 to 20 mM. Moreover, D-glucose more effectively promoted decreases in basal glucose uptake (Ki = 2.2 +/- 0.4 mM) compared with maximal transport rates (Ki = 4.1 +/- 0.4 mM) at all preincubation insulin concentrations (1-50 ng/ml). Similar results were obtained when initial rates of 3-O-methylglucose uptake were used to measure glucose transport. D-glucose, in contrast, did not influence insulin-induced receptor loss. In other studies, D-mannose and D-glucosamine could substitute for D-glucose to promote the insulin-induced changes in glucose transport, but other substrates such as L-glucose, L-arabinase, D-fructose, pyruvate, and maltose were without effect. Also, non-metabolized substrates which competitively inhibit D-glucose uptake (3-O-methylglucose, cytochalasin B) blocked the D-glucose plus insulin effect.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mechanism of insulin resistance in the post receptor events in sheep: 3-O-methylglucose transport in ovine adipocytes

A severe resistance to the stimulatory action of insulin on glucose metabolism has been shown in ruminant adipose tissue or isolated adipocytes as compared to that of rats. To elucidate the mechanism of insulin resistance in ruminants, we measured the stimulatory effect of insulin on 3-O-methylgulose transport and on intracellular glucose metabolism in isolated adipocytes from sheep and rats. At a glucose concentration (0.1 mM) where transport is thought to be rate-limiting for metabolism, lipogenesis from [U-14C]glucose by ovine adipocytes was markedly less than by rat adipocytes in both the basal state and at all insulin concentrations. The responsiveness to insulin assessed by percent increase above basal was reduced to about 15% of that in rat adipocytes, but the insulin sensitivity was similar, because the insulin concentration giving half-maximal stimulation, ED50, did not differ significantly between ovine and rat adipocytes. The maximal insulin-stimulated 3-O-methylglucose transport in ovine adipocytes per cell was less than 20% of that in rat adipocytes, with a significant lowering in basal rates of transport. However, when data was expressed per 3-O-methylglucose equilibrium space no significant differences were found between ovine and rat in the basal transport rates, but a lowered ability of insulin to stimulate glucose transport was still seen in ovine adipocytes. The dose-response curve for glucose transport was slightly shifted to the right in ovine adipocytes compared to rat adipocytes, indicating a small decrease in insulin sensitivity. The decrease in glucose transport was due to 60% reduction in the maximum velocity in the insulin--stimulated state, with no change in the Km.     

Glycolytic enzymes and a GLUT-1 glucose transporter in the outer segments of rod and cone photoreceptor cells

The presence of glycolytic enzymes and a GLUT-1-type glucose transporter in rod and cone outer segments was determined by enzyme activity assays, glucose uptake measurements, Western blotting, and immunofluorescence microscopy. Enzyme activities of six glycolytic enzymes including hexokinase, phosphofructokinase, aldolase, glyceraldehyde-3-phosphate dehydrogenase, phosphoglycerate kinase, pyruvate kinase, and lactate dehydrogenase, were found to be present in purified rod outer segment (ROS) preparations. Immunofluorescence microscopy of bovine and chicken retina sections labeled with monoclonal antibodies against glyceraldehyde-3-phosphate dehydrogenase, phosphoglycerate kinase, and lactate dehydrogenase have confirmed that these enzymes are present in rod and cone outer segments and not simply contaminants from the inner segments or other cells. Rod outer segments were also found to contain glucose transport activity as detected by 3-O-[14C]methylglucose uptake and exchange. The glucose transporter had a Km of 6.3 mM and a Vmax of 0.15 nmol of 3-O-methylglucose/s/mg of ROS membrane protein for net uptake and a Km of 29 mM and a Vmax of 1.06 nmol of 3-O-methylglucose/s/mg of ROS membrane protein for equilibrium exchange. These Km values for net uptake and equilibrium exchange are similar to values obtained for human red blood cells and are characteristic of GLUT-1-type glucose transporter. The transport was inhibited by both cytochalasin B and phloretin. Western blot analysis and immunofluorescence microscopy using type-specific glucose transporter antibodies indicated that both rod and cone outer segment plasma membranes have a GLUT-1 glucose transporter of Mr 45K as found in red blood cells and brain microsomal membranes. Solid-phase radioimmune competitive inhibition studies indicated that rod outer segment plasma membranes contained 15% the number of glucose transporters found in human red blood cell membranes and had an estimated density of 400 glucose transporter per micron2 of plasma membrane. These studies support the view that outer segments can generate energy in the form of ATP and GTP by anaerobic glycolysis to supply at least some of the energy requirements for phototransduction and other metabolic processes.     

Reassessment of insulin effects on the Vmax and Km values of hexose transport in isolated rat epididymal adipocytes

Effects of insulin on the kinetic parameters of hexose transport in rat epididymal adipocytes were re-examined. The transport activity was assessed by measuring the rate of uptake of 3-O-[3H]methyl-D-glucose (MeGlc) under equilibrium exchange and zero-trans conditions. The incubation was carried out at 37 degrees C in an infant incubator. During the incubation, the cell suspension (25%, v/v, in a total volume of 48 microliter) was mechanically swirled at a rate of 600 rpm (r = 2 mm). The swirling facilitated the rapid uptake of MeGlc without stimulating the basal transport activity by "mechanical agitation". The basal and insulin-treated cells were incubated under identical conditions, except for the length of the incubation period. The incubation was terminated by the addition of 350 microliters of 1 mM phloretin, which inhibited transport in approximately 0.06 s. The time course of MeGlc uptake was consistent with the view that the process was a multiple-phase reaction. The initial phase of the reaction was completed when the intracellular distribution space of MeGlc was approximately 1% of the total cell volume. Insulin (10 nM) increased the Vmax value of MeGlc uptake 16-fold in equilibrium exchange experiments and 18-fold in zero-trans experiments. At the same time, the hormone decreased the Km value of MeGlc uptake from 11.7 to 5.4 mM in equilibrium exchange experiments and from 9.7 to 4.8 mM in zero-trans experiments. It is concluded that the major effect of insulin on MeGlc uptake is to increase the Vmax value, but the hormone has the additional effect of lowering the apparent Km value.     

ATP-dependent sugar transport complexity in human erythrocytes

Human erythrocyte glucose sugar transport was examined in resealed red cell ghosts under equilibrium exchange conditions ([sugar](intracellular) = [sugar](extracellular), where brackets indicate concentration). Exchange 3-O-methylglucose (3MG) import and export are monophasic in the absence of cytoplasmic ATP but are biphasic when ATP is present. Biphasic exchange is observed as the rapid filling of a large compartment (66% cell volume) followed by the slow filling of the remaining cytoplasmic space. Biphasic exchange at 20 mM 3MG eliminates the possibility that the rapid exchange phase represents ATP-dependent 3MG binding to the glucose transport protein (GLUT1; cellular [GLUT1] of 相似文献   

Urea permeability of human red cells

The rate of unidirectional [14C]urea efflux from human red cells was determined in the self-exchange and net efflux modes with the continuous flow tube method. Self-exchange flux was saturable and followed simple Michaelis-Menten kinetics. At 38 degrees C the maximal self-exchange flux was 1.3 X 10(-7) mol cm-2 s-1, and the urea concentration for half-maximal flux, K1/2, was 396 mM. At 25 degrees C the maximal self-exchange flux decreased to 8.2 X 10(-8) mol cm-2 s-1, and K1/2 to 334 mM. The concentration-dependent urea permeability coefficient was 3 X 10(-4) cm s-1 at 1 mM and 8 X 10(-5) cm s-1 at 800 mM (25 degrees C). The latter value is consonant with previous volumetric determinations of urea permeability. Urea transport was inhibited competitively by thiourea; the half-inhibition constant, Ki, was 17 mM at 38 degrees C and 13 mM at 25 degrees C. Treatment with 1 mM p-chloromercuribenzosulfonate inhibited urea permeability by 92%. Phloretin reduced urea permeability further (greater than 97%) to a "ground" permeability of approximately 10(-6) cm s-1 (25 degrees C). This residual permeability is probably due to urea permeating the hydrophobic core of the membrane by simple diffusion. The apparent activation energy, EA, of urea transport after maximal inhibition was 59 kJ mol-1, whereas in control cells EA was 34 kJ mol-1 at 1 M and 12 kJ mol-1 at 1 mM urea. In net efflux experiments with no extracellular urea, the permeability coefficient remained constantly high, independent of a variation of intracellular urea between 1 and 500 mM, which indicates that the urea transport system is asymmetric. It is concluded that urea permeability above the ground permeability is due to facilitate diffusion and not to diffusion through nonspecific leak pathways as suggested previously.