Transport enhancement and reversal: glucose and 3-O-methyl glucose.

In chick embryo fibroblast cultures the 15- to 30-fold enhancement of D-glucose uptake observed when cells are starved of glucose for 24 hours is not duplicated for derivatives of glucose that compete effectively for uptake and have generally been considered to use the same carrier. 2-deoxy-D-glucose, D-mannose, D-galactose and D-glucosamine are derepressed progressively less sharply in that order with glucosamine uptake never more than doubled by starvation. D-glucose at a concentration of 5.5 mM in the 24-hour conditioning medium is a strong "repressor" resulting in low "transport" behavior for each of the five sugars cited. D-glucosamine is equally effective at the same concentration. A 10-fold reduction in the concentration of glucosamine (0.55 mM) allows for the escape from repression of mannose, glucose, and deoxyglucose uptake while the others remain repressed. Mannose uptake escapes as well when the glucose concentration in the "conditioning" medium is similarly reduced. Under certain conditions of starvation and cell density dramatic effects of supplemental stimulation by insulin can be achieved. Insulin withdrawal interrupts the supplemental stimulation process. Cycloheximide, actinomycin D and cordycepin block both non-insulin and insulin-induced derepression. Short exposure (15-30 minutes) of 24-hour starved cells to glucose (5.5 mM) reduces glucose sharply but does not affect 3-O-methyl glucose uptake. If the exposure is to 2-deoxyglucose (5.5 mM) further derepression of glucose uptake results.     

Regulation of glycolysis and sugar phosphotransferase activities in Streptococcus lactis: growth in the presence of 2-deoxy-D-glucose.

Streptococcus lactis K1 has the capacity to grow on many sugars, including sucrose and lactose, in the presence of high levels (greater than 500 mM) of 2-deoxy-D-glucose. Initially, growth of the organism was transiently halted by the addition of comparatively low concentrations (less than 0.5 mM) of the glucose analog to the culture. Inhibition was coincident with (i) rapid accumulation of 2-deoxy-D-glucose 6-phosphate (ca. 120 mM) and preferential utilization of phosphoenolpyruvate via the mannose:phosphotransferase system, (ii) depletion of phosphorylated glycolytic intermediates, and (iii) a 60% reduction in intracellular ATP concentration. During the 5- to 10-min period of bacteriostasis the intracellular concentration of 2-deoxy-D-glucose 6-phosphate rapidly declined, and the concentrations of glycolytic intermediates were restored to near-normal levels. When growth resumed, the cell doubling time (Td) and the steady-state levels of 2-deoxy-D-glucose 6-phosphate maintained by the cells were dependent upon the medium concentration of 2-deoxy-D-glucose. Resistance of S. lactis K1 to the potentially toxic analog was a consequence of negative regulation of the mannose:phosphotransferase system by two independent mechanisms. The first, short-term response occurred immediately after the initial "overshoot" accumulation of 2-deoxy-D-glucose 6-phosphate, and this mechanism reduced the activity (fine control) of the mannose:phosphotransferase system. The second, long-term mechanism resulted in repression of synthesis (coarse control) of enzyme IImannose. The two regulatory mechanisms reduced the rate of 2-deoxy-D-glucose translocation via the mannose:phosphotransferase system and minimized the activity of the phosphoenolpyruvate-dependent futile cycle of the glucose analog (J. Thompson and B. M. Chassy, J. Bacteriol. 151:1454-1465, 1982). Phosphoenolpyruvate was thus conserved for transport of the growth sugar and for generation of ATP required for biosynthetic and work functions of the growing cell.     

Novel phosphoenolpyruvate-dependent futile cycle in Streptococcus lactis: 2-deoxy-D-glucose uncouples energy production from growth.

The addition of 2-deoxy-D-glucose to cultures of Streptococcus lactis 133 that were growing exponentially on sucrose or lactose reduced the growth rate by ca. 95%. Inhibition did not occur with glucose or mannose as the growth sugar. The reduction in growth rate was concomitant with rapid accumulation of the analog in phosphorylated form (2-deoxy-D-glucose 6-phosphate) via the phosphoenolpyruvate-dependent mannose:phosphotransferase system. Within 5 min the intracellular 2-deoxy-D-glucose 6-phosphate concentration reached a steady-state level of greater than 100 mM. After maximum accumulation of the sugar phosphate, the rate of sucrose metabolism (glycolysis) decreased by only 30%, but the cells were depleted of fructose-1,6-diphosphate. The addition of glucose to 2-deoxy-D-glucose 6-phosphate preloaded cells caused expulsion of 2-deoxy-D-glucose and a resumption of normal growth. S. lactis 133 contained an intracellular Mg2+-dependent, fluoride-sensitive phosphatase which hydrolyzed 2-deoxy-D-glucose 6-phosphate (and glucose 6-phosphate) to free sugar and inorganic phosphate. Because of continued dephosphorylation and efflux of the non-metabolizable analog, the maintenance of the intracellular 2-deoxy-D-glucose 6-phosphate pool during growth stasis was dependent upon continued glycolysis. This steady-state condition represented a dynamic equilibrium of: (i) phosphoenolpyruvate-dependent accumulation of 2-deoxy-D-glucose 6-phosphate, (ii) intracellular dephosphorylation, and (iii) efflux of free 2-deoxy-D-glucose. This sequence of events constitutes a futile cycle which promotes the dissipation of phosphoenolpyruvate. We conclude that 2-deoxy-D-glucose functions as an uncoupler by dissociating energy production from growth in S. lactis 133.     

The Glucose Transport System in Leishmania tropica Promastigotes*

Transport of glucose by Leishmania tropica promastigotes was measured by the uptake of the nonutilizable glucose analog, 2-deoxy-D-glucose (2-DOG), using the rapid filtration method. Both D-glucose and 2-DOG show identical rates of initial uptake. Intracellular 2-DOG readily exchanges with extracellular D-glucose and 2-DOG uptake is competitively inhibited by D-glucose. These observations suggest that both sugars are taken up by the same system. Neither the glucose analog α-methyl-D-glucoside (α-MG) nor 3-0-methyl glucose (3-0-MG) is taken up to any appreciable extent. Transport of 2-DOG shows saturation kinetics with a V_max of 3.2 nmoles/mg cells/min and a K_m of 0.16 mM. There is thus a stereospecific, carrier-mediated transport system for glucose uptake in L. tropica. About 2/3 of the intracellular pool following transport consists of 2-deoxy-D-glucose phosphate (2-DOG-P) and the remainder is free, unaltered 2-DOG.     

Hexose uptake and control of fibroblast proliferation

The role of glucose uptake in control of cell growth was studied by experimentally varying the rate of glucose uptake and examining the subsequent effect on initiation and cessation of cell proliferation. The rate of glucose uptake was varied by adjusting the concentration of glucose in the culture medium. This permitted analysis of two changes in rate of glucose uptake which are closely related to the regulation of cell growth: (1) the rapid increase in glucose uptake that can be detected within several minutes after mitogenic stimulation of quiescent fibroblasts and (2) the decrease in glucose uptake which accompanies growth to a quiescent state. Quiescent cultures of mouse 3T3, human diploid foreskin and secondary chick embryo cells were switched to fresh serum-containing medium with either the normal amount of glucose or a reduced level that lowered the rate of glucose uptake below the rate characteristic of quiescent control cells. The subsequent increases in cell number were equal in both media, demonstrating that the increase in glucose uptake, commonly observed after mitogenic stimulation, was not necessary for initiation of cell division. Measurements of intracellular D-glucose pools after serum stimulation of quiescent cells revealed that the increase in glucose uptake was not accompanied by a detectable change in the intracellular concentration of glucose. Nonconfluent growing cultures of mouse 3T3, human diploid foreskin and secondary chick embryo cells were switched to low glucose media, lowering the rate of glucose uptake below levels observed for quiescent cells. This did not affect rates of DNA synthesis or cell division over a several-day period. Thus, the decrease in glucose uptake, which usually occurs at about the same time as the decrease in DNA synthesis as cells grow to quiescence, does not cause the decline in cell proliferation. Experiments indicated that there was no set temporal relationship between the decline in glucose uptake and DNA synthesis as cells grew to quiescence. The sequence was variable and probably depended on the cell type as well as culture conditions. Measurements of intracellular D-glucose pools in secondary chick embryo cells demonstrated that the internal concentration of glucose in these cells did not significantly vary during growth to quiescence. Taken together, our results show that these fluctuations in the rate of glucose uptake do not lead to detectable changes in the intracellular concentration of glucose and that they do not control cell proliferation rates under usual culture conditions.     

Inhibition of glucose-induced insulin release by 3-O-methyl-D-glucose: Enzymatic,metabolic and cationic determinants

The analog of D-glucose, 3-O-methyl-D-glucose, is thought to delay the equilibration of D-glucose concentration across the plasma membrane of pancreatic islet B-cells, but not to exert any marked inhibitory action upon the late phase of glucose-stimulated insulin release. In this study, however, 3-O-methyl-D-glucose, when tested in high concentrations (30-80 mM) was found to cause a rapid, sustained and not rapidly reversible inhibition of glucose-induced insulin release in rat pancreatic islets. In relative terms, the inhibitory action of 3-O-methyl-D-glucose was more marked at low than high concentrations of D-glucose. It could not be attributed to hyperosmolarity and appeared specific for the insulinotropic action of D-glucose, as distinct from non-glucidic nutrient secretagogues. Although 3-O-methyl-D-glucose and D-glucose failed to exert any reciprocal effect upon the steady-state value for the net uptake of these monosaccharides by the islets, the glucose analog inhibited D-[5-3H]glucose utilization and D-[U-14C]glucose oxidation. This coincided with increased 86Rb outflow and decreased 45Ca outflow from prelabelled islets, as well as decreased 45Ca net uptake. A preferential effect of 3-O-methyl-D-glucose upon the first phase of glucose-stimulated insulin release was judged compatible with an altered initial rate of D-glucose entry into islet B-cells. The long-term inhibitory action of the glucose analog upon the metabolic and secretory response to D-glucose, however, may be due, in part at least, to an impaired rate of D-glucose phosphorylation. The phosphorylation of the hexose by beef heart hexokinase and human B-cell glucokinase, as well as by parotid and islet homogenates, was indeed inhibited by 3-O-methyl-D-glucose. The relationship between insulin release and D-glucose utilization or oxidation in the presence of 3-O-methyl-D-glucose was not different from that otherwise observed at increasing concentrations of either D-glucose or D-mannoheptulose. It is concluded, therefore, that 3-O-methyl-D-glucose adversely affects the metabolism and insulinotropic action of D-glucose by a mechanism largely unrelated to changes in the intracellular concentration of the latter hexose.     

Control of sugar transport in human fibroblasts independent of glucose metabolism or carrier-substrate interaction

Transport regulation by different metabolizable and nonmetabolizable sugars was studied in human fibroblasts. Sugars were classed as glucose-like (D-mannose, 3-0-methyl-D-glucose, thio-D-glucose, and D-allose) and starvation-like (D-galactose, D-fructose, L-glucose, D-xylose, 6-deoxy-D-glucose and 2-deoxy-D-glucose) based on their competence in curbing glucose starvation enhanced transport. No significant correlation existed between the ability of a sugar to curb hexose transport and the KI of that sugar in inhibiting hexose transport. Independence of the transport curb from glucose metabolism was observed since nonmetabolizable analogs of D-glucose when substituted for D-glucose in the culture medium effected glucose [i.e. 3-0-methyl-D-glucose (3-OMG)] and starvation-like (i.e. 6- and 2-deoxy-D-glucose) effects. The KI of inhibition pf 2-deoxy-D-glucose transport for 3-OMG was 8.5 mM, similar to those obtained for 6-deoxyglucose and 2-deoxyglucose on 2-deoxyglycose transport (7.5 and 3.5 mM, respectively) and on 3-0-methylglucose transport (3.5 and 2.5 mM, respectively). An equimolar mixture of D-glucose and 3-OMG (5.55 mM each) was more effective than 11.1 mM D-glucose or 3-OMG alone in curbing hexose transport or reversing hexose starvation induced increases in transport. The effect of 3-OMG may be independent of glucose metabolism but it is possible that 3-OMG structurally mimics a metabolite of glucose that may interact with intracellular regulators of carrier degradation and or expression.     

Dynamics of glucose uptake by single Escherichia coli cells

The fluorescent glucose analog, 2-(N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino)-2-deoxyglucose (2-NBDG), was used to measure rates of glucose uptake by single Escherichia coli cells. When cell populations were exposed to the glucose analog, 2-NBDG was actively transported and accumulated in single cells to a steady-state level that depended upon its extracellular concentration, the glucose transport capacity of the cells, and the intracellular degradation rate. The dependence upon substrate concentration could be described according to Michaelis-Menten kinetics with apparent saturation constant KM = 1.75 microM, and maximum 2-NBDG uptake rate= 197 molecules/cell-second. Specificity of glucose transporters to the analog was confirmed by inhibition of uptake of 2-NBDG by D-glucose, 3-o-methyl glucose, and D-glucosamine, and lack of inhibition by L-glucose. Inhibition of 2-NBDG uptake by D-glucose was competitive in nature. The assay for 2-NBDG uptake is extremely sensitive such that the presence of even trace amounts of D-glucose in the culture medium (approximately 0.2 microM) is detectable. The rates of single-cell analog uptake were found to increase proportionally with cell size as measured by microscopy or single-cell light scattering intensity. The assay was used to identify and isolate mutant cells with altered glucose uptake characteristics. A mathematical model was developed to provide a theoretical basis for estimating single-cell glucose uptake rates from single-cell 2-NBDG uptake rates. The assay provides a novel means of estimating the instantaneous rates of nutrient depletion in the growth environment during a batch cultivation.     

Direct regulation of Na(+)-dependent myo-inositol transport by sugars in retinal pigment epithelium: role of phorbol ester and staurosporin

An Na(+)-dependent active process for myo-inositol (MI) uptake, sharing a common carrier system with glucose and sensitive to phlorizin, was previously established in primary cultures of bovine retinal pigment epithelial (RPE) cells (26, 32). The present report further examines the nature of glucose-induced inhibition of MI transport in primary cultures of RPE cells. RPE cells were grown in supplemented Dulbecco's modification of Eagle's medium (DMEM) containing 5 mM D-glucose (basic growth media) or 40 mM D-glucose or its nonmetabolizable analogue, alpha-methyl-D-glucoside (alpha MG); 1-5 mM nonradioactive MI, pyruvate, or lactate; or 0.2-20 microM phorbol 12-myristate 13-acetate (TPA) or straurosporin (modified growth media), for up to 4 weeks. The capacity of RPE cells to accumulate 3H-MI (ratios of intracellular transported radioactive MI, [MI]i, to external free MI concentration, [MI]i/[MI]o) decreased by up to 41% or 34% when cells were grown for 10 days or longer with 40 mM D-glucose or 40 mM alpha MG, respectively, compared to cells grown in basic growth media. The rate of uptake of 3H-MI also was reduced to 63 +/- 15% or 48 +/- 8% of the control values when cells were fed 1 or 5 mM nonradioactive MI, respectively. In addition, cellular capacity to bind to [3H]phlorizin was reduced to 52 +/- 7%, 61 +/- 5%, or 38 +/- 6% of the controls when RPE cells were fed 40 mM D-glucose, 40 mM alpha MG, or 5 mM nonradioactive MI, respectively. Growth media containing either pyruvate or lactate, the glucose metabolites, did not suppress the ability of RPE cells to accumulate MI. An 18 +/- 8% reduction in [3H]thymidine incorporation into DNA occurred when cells were grown in 40 mM glucose for 12-14 days, compared to cells grown with 5 mM glucose. Chronic treatment (12-14 days) of the cells with phorbol ester, an activator of protein kinase C, caused up to twofold increase in MI uptake, [3H]phlorizin binding, cell number, and DNA synthesis. However, when the rates of MI uptake into cells grown in basic growth media or TPA-treated media were normalized to cell number, no significant difference in MI uptake was found between the treated and untreated cells. Addition of staurosporin, a protein kinase C inhibitor, together with TPA, in the growth media reversed the phorbol-induced increase of MI uptake.(ABSTRACT TRUNCATED AT 400 WORDS)     

Furosemide and Ca2+ affect 86Rb+ efflux from pancreatic beta-cells by different mechanisms

The interaction between furosemide, calcium and D-glucose on the 86Rb+ efflux from beta-cell-rich mouse pancreatic islets was investigated in a perifusion system with high temporal resolution. Raising the glucose concentration from 4 to 20 mM induced an initial decrease in 86Rb+ efflux, which was followed by a steep increase and then a secondary decrease. Removal of extracellular calcium increased the 86Rb+ efflux at 4 mM D-glucose but reduced it at 20 mM. The initial biphasic changes in 86Rb+ efflux induced by 20 mM D-glucose were inhibited by calcium deficiency. Furosemide (100 microM) reduced the 86Rb+ efflux rate both at 4 and 20 mM D-glucose and the magnitudes appeared to be similar at either glucose concentration. Furosemide (100 microM) reduced the glucose-induced (10 mM) 45Ca+ uptake but did not affect the basal (3 mM D-glucose) 45Ca+ uptake. However, the ability of furosemide (100 microM) to reduce the 86Rb+ efflux at a high glucose concentration (20 mM) was independent of extracellular calcium. The inhibitory effects of furosemide and calcium deficiency on the 86Rb+ efflux rate appeared to be additive. It is concluded that the effect of furosemide on 86Rb+ efflux is not secondary to reduced calcium uptake and that the effects of furosemide and calcium deficiency are mediated by different mechanisms. The effect of furosemide is compatible with inhibition of loop diuretic-sensitive co-transport of Na+, K+ and Cl- and the effect of calcium deficiency with reduced activity of calcium-regulated potassium channels.     

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.     

Direct Regulation of Na+-Dependent myo-Inositol Transport by Sugars in Retinal Pigment Epithelium: Role of Phorbol Ester and Staurosporin

An Na⁺-dependent active process for myo-inositol (MI) uptake, sharing a common carrier system with glucose and sensitive to phlorizin, was previously established in primary cultures of bovine retinal pigment epithelial (RPE) cells (26, 32). The present report further examines the nature of glucose-induced inhibition of MI transport in primary cultures of RPE cells. RPE cells were grown in supplemented Dulbecco's modification of Eagle's medium (DMEM) containing 5 mM D-glucose (basic growth media) or 40 mM D-glucose or its nonmetabolizable analogue, α-methyl-D-glucoside (αMG); 1–5 mM nonradioactive MI, pyruvate, or lactate; or 0.2–20 µM phorbol 12-myristate 13-acetate (TPA) or straurosporin (modified growth media), for up to 4 weeks. The capacity of RPE cells to accumulate ³H-MI (ratios of intracellular transported radioactive MI, [MI]_i, to external free MI concentration, [MI]_i/[MI]₀) decreased by up to 41% or 34% when cells were grown for 10 days or longer with 40 mM D-glucose or 40 mM αMG, respectively, compared to cells grown in basic growth media. The rate of uptake of ³H-MI also was reduced to 63 ± 15% or 48 ± 8% of the control values when cells were fed 1 or 5 mM nonradioactive MI, respectively. In addition, cellular capacity to bind to [³H]phlorizin was reduced to 52 ± 7%, 61 ± 5%, or 38 ± 6% of the controls when RPE cells were fed 40 mM D-glucose, 40 mM αMG, or 5 mM nonradioactive MI, respectively. Growth media containing either pyruvate or lactate, the glucose metabolites, did not suppress the ability of RPE cells to accumulate MI. An 18 ± 8% reduction in [³H]thymidine incorporation into DNA occurred when cells were grown in 40 mM glucose for 12–14 days, compared to cells grown with 5 mM glucose. Chronic treatment (12–14 days) of the cells with phorbol ester, an activator of protein kinase C, caused up to twofold increase in MI uptake, [³H]phlorizin binding, cell number, and DNA synthesis. However, when the rates of MI uptake into cells grown in basic growth media or TPA-treated media were normalized to cell number, no significant difference in MI uptake was found between the treated and untreated cells. Addition of staurosporin, a protein kinase C inhibitor, together with TPA, in the growth media reversed the phorbol-induced increase of MI uptake. In contrast to its chronic effect, a 60-min incubation (acute effect) of cells in the presence of TPA, with or without inclusion of stauropsorin, did not alter the uptake of ³H-MI into RPE cells, regardless of glucose levels in the growth media. These studies indicated that glucose itself, and not glucose metabolites, regulated uptake of MI into primary cultures of RPE cells. In addition, glucose-induced down-regulation of MI uptake was not mediated through the protein kinase C pathway, but the staurosporin-inhibited, TPA-stimulated protein kinase C was partly responsible for growth and proliferation of RPE cells.     

Non-competitive inhibition of myo-inositol transport in cultured bovine retinal capillary pericytes by glucose and reversal by Sorbinil

myo-Inositol transport by retinal capillary pericytes in culture was characterized. The major myo-inositol transport process was sodium-dependent, ouabain-sensitive, and saturable at 40 mM, indicating a carrier-mediated process. The sodium ion concentration required to produce one-half the maximal rate of myo-inositol uptake ([Na+]0.5) did not show dependence on the external myo-inositol concentration (22.3 mM sodium for 0.005 mM myo-inositol; 18.2 mM sodium for 0.05 mM myo-inositol). myo-Inositol transport was an energy-dependent, active process functioning against a myo-inositol concentration gradient. The kinetics of the sodium-dependent system fitted a 'velocity type' co-transport model where binding of sodium ion to the carrier increased the velocity (Vmax 28 to 313 pmol myo-inositol/micrograms DNA per 20 min when [Na+] varied from 9 to 150 mM) but not the affinity for myo-inositol (Km 0.92 to 0.83 mM when [Na+] varied from 9 to 150 mM). Metabolizable hexoses (D-glucose or D-galactose; greater than 5 mM) inhibited myo-inositol uptake. Dixon-plot analysis indicated that the inhibition was non-competitive with a Ki of 22.7 mM for D-glucose and 72.6 mM for D-galactose. The inhibition was significantly reversed by Sorbinil (0.1 mM), an aldose reductase inhibitor. In contrast, high concentrations of non-metabolizable hexoses (L-glucose, 3-O-methyl-D-glucose), or partially metabolizable 2-deoxy-D-glucose, did not significantly inhibit myo-inositol uptake. The inhibitory effect of D-glucose or D-galactose on myo-inositol transport appeared to be related to glucose or galactose metabolism via the polyol pathway.     

Effect of insulin on the glucose utilization in isolated cardiac myocytes from adult rat

The acute effects of insulin on glucose utilization in isolated rat quiescent cardiac myocytes were studied. Insulin (80 nM) increased the rate of glucose clearance by 2-3 times in the presence of glucose ranging from 0.3 microM to 5.5 mM. Glucose transport, which was measured in terms of both D-glucose uptake in the presence of 0.3 microM D-glucose and initial rate of uptake of 3-O-methylglucose, was stimulated 3-fold in the presence of insulin. At higher glucose concentrations (greater than 100 microM), a decrease in glucose clearance rate due to a shift of the rate-limiting step from glucose transport to a post-transport step in the pathway of glucose metabolism was observed. At the physiological concentration of glucose (5.5 mM), about 73% of glucose was metabolized into lactate, about 10% was oxidized into CO2 and the rest (17%) remained inside the cells. The pentose phosphate pathway did not contribute to the glucose metabolism in these cells. Insulin (80 nM) significantly increased the uptake of glucose (112%), and the conversions of glucose into lactate (16%), glycogen (64%), and triglyceride (18%), but not into CO2 (3%). Insulin transiently increased the percentage of I-form of glycogen synthase by 16% above basal, but did not affect the percentage of a-form of glycogen phosphorylase. The content of glucose 6-phosphate in the cells was increased by 46% above the basal value in the presence of insulin. These results indicate that insulin has different acute stimulatory effects on various steps in the metabolic pathway of glucose in isolated quiescent cardiac myocytes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Direct measurements of sugar uptake in small and large adipocytes from young and adult rats

Measurements of basal and insulin-stimulated uptake of D-glucose, 2-deoxy-D-glucose and 3-O-methyl-D-glucose were determined in isolated fat cells from young and adult rats by an oil-centrifugation technique. At low sugar concentrations, uptake of D-glucose and 2-deoxy-D-glucose was greater in large cells from older animals than in small cells from young rats while at higher concentrations (3.0 mM–5.0 mM) uptake was similar. Insulin enhanced uptake of both sugars and the amounts accumulated by the two cell types were not significantly different. Also no difference was noted in basal rate of 3-O-methyl-D-glucose uptake or when uptake was accelerated by insulin stimulation. These findings suggest that large adipocytes from adult rats are not as insulin-resistant as previously suggested but, instead, have an efficient D-glucose transport system which is responsive to insulin stimulation.     

Monosaccharide transport by Eimeria tenella sporozoites

Eimeria tenella sporozoites were incubated in the presence of 3 different [14C]-labeled sugars; D-glucose, 2-deoxy-D-glucose and 3-O-methyl-D-glucose. The initial velocity, Vi, of uptake of D-glucose and 2-deoxy-D-glucose was similar, 41 micrograms/10(10) sporozoites/min and 46 micrograms/10(10) sporozoites/min, respectively; whereas that for 3-O-methyl-D-glucose was significantly lower, 17 micrograms/10(10) sporozoites/min. Initial velocity studies also revealed that glucose uptake was a saturable event, with an apparent KT of 20 mM and an apparent Vmax of 312 micrograms/10(10) sporozoites/min. Uptake was unaffected by exogenous sodium levels or the presence of ouabain. However, 0.1 mM phloretin significantly inhibited glucose uptake. Thus, it would appear that E. tenella sporozoites possess a Na-independent, phloretin-sensitive, carrier-mediated monosaccharide-transport system.     

Regulation of uptake of inositol by glucose in cultured retinal pigment epithelial cells

Long term and acute effects of glucose on myo-inositol (MI) uptake were studied in primary cultures of bovine retinal pigment epithelial (RPE) cells. RPE cells were grown under low (5 mM) or high (20, 40, or 50 mM) glucose levels in the growth medium for up to 18 days. The concentrative capacity of confluent RPE cells to accululate [3H]MI (10 microM) was reduced up to 41% as the glucose concentration in the growth medium increased. When the growth medium glucose was switched from 5 to 40 mM, or vice versa, the capacity of cells to accumulate MI was reversed. Treatment of cells grown in 40 or 50 mM glucose with 0.1 mM Sorbinil (an aldose reductase inhibitor) minimally reversed the ability of cells to accumulate MI. RPE cells, grown in 5 mM glucose, were incubated with 10-60 mM D-glucose or its nonmetabolizable analogues (acute effect). Kinetics of MI uptake inhibition by alpha-methyl glucose according to Dixon plots were characteristic of competitive inhibition (Ki = 28 mM). MI uptake was strongly inhibited by phlorizin. The ability of RPE cells to bind 5 microM [3H]phlorizin also was reduced by increased glucose levels in the growth medium. These studies indicated that MI and glucose shared the same transporter system. Glucose in the incubation medium directly interfered with MI binding to the transporter. High glucose feeding of the cells also down-regulated the transporter density. The uptake and function of solutes such as MI in tissues that operate on the glucose carrier system may be severely impaired in diabetes.     

Polarity of transport of 2-deoxy-D-glucose and D-glucose by cultured renal epithelia (LLC-PK1).

At least two types of glucose transporter exist in cultured renal epithelial cells, a Na(+)-glucose cotransporter (SGLT), capable of interacting with D-glucose but not 2-deoxy-D-glucose (2dglc) and a facilitated transporter (GLUT) capable of interacting with both D-glucose and 2dglc. In order to examine the polarity of transport in cultured renal epithelia, 2dglc and D-glucose uptakes were measured in confluent cultures of LLC-PK1 cells grown on collagen-coated filters that permitted access of medium to both sides of the monolayer. The rates of basolateral uptake of both 1 mM glucose (Km 3.6 mM) and 1 mM 2dglc (Km 1.5 mM) were greater than apical uptake rates and the (apical-to-basolateral)/(basolateral-to-apical) flux ratio was high for glucose (9.4) and low for 2dglc (0.8), thus, confirming the lack of interaction of 2dglc with the apical SGLT. Specific glucose transport inhibitor studies using phlorizin, phloretin and cytochalasin B confirmed the polarised distribution of SGLT and GLUT in LLC-PK1 cells. Basolateral sugar uptake could be altered by addition of insulin (1 mU/ml) which increased 2dglc uptake by 72% and glucose uptake by 50% and by addition of 20 mM glucose to the medium during cell culture which decreased 2dglc uptake capacity at confluence by 30%. During growth to confluence, 2dglc uptake increased to a maximum, then decreased at the time of confluence, coincident with a rise in uptake capacity for alpha-methyl-D-glucoside, a hexose that interacts only with the apical SGLT. It was concluded that the non-metabolisable sugar 2dglc was a useful, specific probe for GLUT in LLC-PK1 cells and that GLUT was localised at the basolateral membrane after confluence.     

Mechanism of regulation of glucose transport in Rhizobium leguminosarum.

Multiple glucose transport systems were distinguished in Rhizobium leguminosarum. We found nonlinear Lineweaver-Burk plots for the uptake of glucose, 2-deoxy-D-glucose, and alpha-methyl-D-glucoside, and this implied the existence of at least two uptake mechanisms. Different patterns of inhibition of 2-deoxy-D-glucose uptake and alpha-methyl-D-glucoside uptake at 0.1 mM by various carbohydrates revealed differences in the stereospecificities of the transport systems. Osmotic shock treatment abolished transport activities, and two independent glucose-binding activities were detected in the supernatants. Induction of glucose transport was repressed strongly by L-malate, even in the presence of excess D-glucose. Rhizobium bacteroids showed no significant glucose uptake activity at different oxygen concentrations. These results suggested that glucose transport is repressed by dicarboxylic acids during R. leguminosarum symbiosis.     

Transport of D-glucose and 3-O-methyl-D-glucose in the cyanobacteria Aphanocapsa 6714 and Nostoc strain Mac.

1. The cyanobacterium Aphanocapsa 6714 which grow in the dark on D-glucose, will take up D-glucose and the analogue 3-O-methyl-D-glucose; uptake of each of these compounds was inhibited competitively by the other and by 6-deoxy-D-glucose. 2. This cyanobacterium accumulated 3-O-methyl-D-glucose up to 100-fold relative to the medium but did not modify or metabolize it to a significant degree. 3. Intracellular 3-O-methyl-D-glucose was rapidly displaced from Aphanocapsa 6714 by exogenous D-glucose and 3-O-methyl-D-glucose. 4. Although not characterized to the same extent, D-glucose and 3-O-methyl-D-glucose uptake by Nostoc strain Mac, another cyanobacterium capable of growth in the dark on D-glucose, was similar. 5. Other cyanobacteria that do not grow on D-glucose take up this compound at much lower rates which were unaffected by analogues of D-glucose that greatly reduced carbohydrate uptake by Aphanocapsa 6714 and Nostoc strain Mac. 6. It is therefore proposed that Aphanocapsa 6714 and Nostoc strain Mac possess a mechanism for the active transport of D-glucose. The absence of this transport mechanism is suggested as the reason why other strains fail to grow in the dark on this substrate. These latter organisms are therefore naturally cryptic with respect to D-glucose as a growth substrate.