Uptake of the cephalosporin, cephalexin, by a dipeptide transport carrier in the human intestinal cell line, Caco-2

The transport of the orally absorbed cephalosporin, cephalexin, was examined in the human epithelial cell line, Caco-2 that possesses intestinal enterocyte-like properties when cultured. In sodium-free buffer, the cells accumulated 1 mM D-[9-14C]cephalexin against a concentration gradient and obtained a distribution ratio of 3.5 within 180 min. Drug uptake was maximal when the extracellular pH was 6.0. Uptake was reduced by metabolic inhibitors and by protonophores indicating that uptake was energy- and proton-dependent. Kinetic analysis of the concentration dependence of the rate of cephalexin uptake showed that a non-saturable component (Kd of 0.18 +/- 0.01 nmol/min per mg protein per mM) and a transport system with a Km of 7.5 +/- 2.8 mM and a Vmax of 6.5 +/- 0.9 nmol/min per mg protein were responsible for drug uptake. Uptake was competitively inhibited by dipeptides. The transport carrier exhibited stereospecificity for the L-isomer of cephalexin. Drug uptake was not affected by the presence of amino acids, organic anions, 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid or 4,4'-diisothiocyano-2,2'-disulfonic stilbene. Therefore, Caco-2 cells take up cephalexin by a proton-dependent dipeptide transport carrier that closely resembles the transporter present in the intestine. Caco-2 cells represent a cellular model for future studies of the dipeptide transporter.     

Sodium-dependent phosphate and alanine transports but sodium-independent hexose transport in type II alveolar epithelial cells in primary culture

Inorganic phosphate, amino acids and sugars are of obvious importance in lung metabolism. We investigated sodium-coupled transports with these organic and inorganic substrates in type II alveolar epithelial cells from adult rat after one day in culture. Alveolar type II cells actively transported inorganic phosphate and alanine, a neutral amino acid, by sodium-dependent processes. Cellular uptakes of phosphate and alanine were decreased by about 80% by external sodium substitution, inhibited by ouabain (30 and 41%, respectively) and displayed saturable kinetics. Two sodium-phosphate cotransport systems were characterized: a high-affinity one (apparent Km = 18 microM) with a Vmax of 13.5 nmol/mg protein per 10 min and a low-affinity one (apparent Km = 126 microM) with a Vmax of 22.5 nmol/mg protein per 10 min. Alanine transport had an apparent Km of 87.9 microM and a Vmax of 43.5 nmol/mg protein per 10 min. By contrast, cultured alveolar type II cells did not express sodium-dependent hexose transport. Increasing time in culture decreased Vmax values of the two phosphate transport systems on day 4 while sodium-dependent alanine uptake was unchanged. This study demonstrated the existence of sodium-dependent phosphate and amino acid transports in alveolar type II cells similar to those documented in other epithelial cell types. These sodium-coupled transports provide a potent mechanism for phosphate and amino acid absorption and are likely to play a role in substrate availability for cellular metabolism and in regulating the composition of the alveolar subphase. The decrease in phosphate uptake with time in culture is parallel to decrease in surfactant synthesis reported in cultured alveolar type II cells, suggesting that phosphate availability for surfactant synthesis may be accomplished by a sodium-dependent phosphate uptake.     

A role for membrane transport in modulation of intramuscular free glutamine turnover in streptozotocin diabetic rats.

We wished to examine the effects of diabetes on muscle glutamine kinetics. Accordingly, female Wistar rats (200 g) were made diabetic by a single injection of streptozotocin (85 mg/kg) and studied 4 days later; control rats received saline. In diabetic rats, glutamine concentration of gastrocnemius muscle was 33% less than in control rats: 2.60 +/- 0.06 mumol/g vs. 3.84 +/- 0.13 mumol/g (P < 0.001). In gastrocnemius muscle, glutamine synthetase activity (Vmax) was unaltered by diabetes (approx. 235 nmol/min per g) but glutaminase Vmax increased from 146 +/- 29 to 401 +/- 94 nmol/min per g; substrate Km values of neither enzyme were affected by diabetes. Net glutamine efflux (A-V concentration difference x blood flow) from hindlimbs of diabetic rats in vivo was greater than control values (-30.0 +/- 3.2 vs. -1.9 +/- 2.6 nmol/min per g (P < 0.001)) and hindlimb NH3 uptake was concomitantly greater (about 27 nmol/min per g). The glutamine transport capacity (Vmax) of the Na-dependent System Nm in perfused hindlimb muscle was 29% lower in diabetic rats than in controls (820 +/- 50 vs. 1160 +/- 80 nmol/min per g (P < 0.01)), but transporter Km was the same in both groups (9.2 +/- 0.5 mM). The difference between inward and net glutamine fluxes indicated that glutamine efflux in perfused hindlimbs was stimulated in diabetes at physiological perfusate glutamine (0.5 mM); ammonia (1 mM in perfusate) had little effect on net glutamine flux in control and diabetic muscles. Intramuscular Na+ was 26% greater in diabetic (13.2 mumol/g) than control muscle, but muscle K+ (100 mumol/g) was similar. The accelerated rate of glutamine release from skeletal muscle and the lower muscle free glutamine concentration observed in diabetes may result from a combination of: (i), a diminished Na+ electrochemical gradient (i.e., the net driving force for glutamine accrual in muscle falls); (ii), a faster turnover of glutamine in muscle and (iii), an increased Vmax/Km for sarcolemmal glutamine efflux.     

Transport of 2-oxoisocaproate in isolated hepatocytes and liver mitochondria

The transport of 2-oxoisocaproate into isolated hepatocytes and liver mitochondria of rat was studied using [U-14C]2-oxoisocaproate and the silicone oil filtration procedure. 2-Oxoisocaproate uptake by hepatocytes was composed of: rapid adsorption, unmediated diffusion and carrier-mediated transport. The carrier-mediated transport was strongly inhibited by 4,4'-diisothiocyano-2,2'-stilbenedisulphonic acid and p-chloromercuribenzoate, was less sensitive to alpha-cyano-4-hydroxycinnamate and insensitive to p-chloromercuriphenylsulphonate. Other 2-oxo acids: pyruvate, 2-oxoisovalerate and 2-oxo-3-methylvalerate, were also inhibitory. The kinetic parameters of the carrier-mediated transport were Km 30.6 mM and Vmax 23.4 nmol/min per mg wet wt, at 37 degrees C. It is concluded that at its low, physiological, concentration, 2-oxoisocaproate penetrates the hepatocyte membrane mainly by unmediated diffusion. The uptake of 2-oxoisocaproate by isolated liver mitochondria was partly inhibited by alpha-cyano-4-hydroxycinnamate, the inhibitor of mitochondrial monocarboxylate carrier. The remaining uptake was linearly dependent on 2-oxoisocaproate concentration and represented unmediated diffusion. The carrier-mediated transport exhibited the following kinetic parameters: Km 0.47 mM, Vmax 1.0 nmol/min per mg protein at 6 degrees C; and Km 0.075 mM and Vmax about 8 nmol/min per mg protein at 37 degrees C.     

Preferential glutamine uptake in rat brain synaptic mitochondria

Glutamine uptake has been studied in purified rat brain mitochondria of synaptic or non-synaptic origin. It was taken up by an active saturable transport mechanism, with an affinity two-times higher in synaptic than in non-synaptic mitochondria (Km = 0.45 and 0.94 mM, respectively). Vmax of uptake was 7-times higher in synaptic mitochondria (Vmax = 9.2 and 1.3 nmol/min per mg protein, respectively). Glutamine transport was found to be inhibited by L-glutamate (IC50 = 0.64 mM) as well as thiol reagents (mersalyl, N-ethylmaleimide). It is suggested that differential uptake of glutamine in mitochondria of synaptic or non-synaptic origin may be a major mechanism in the regulation of the synthesis of the neurotransmitter glutamate.     

Synthesis and transport characteristics of photoaffinity probes for the hepatocyte bile acid transport system

In an effort to characterize the hepatocyte bile acid transport system, a photoreactive derivative of taurocholate, (7,7-azo-3 alpha,12 alpha-dihydroxy-5 beta-cholan-24-oyl)-2-aminoethanesulfonic acid (7-ADTC) has been synthesized and its transport properties compared to those of the natural substrate. Both the bile acid and its synthetic analog were shown to be transported against an electrochemical gradient as well as a chemical gradient. Transport as a function of concentration and the presence of sodium indicated that both substrates were taken up by a sodium-dependent and a sodium-independent route. Taurocholate had Km values of 26 and 57 microM and Vmax values of 0.77 and 0.15 nmol/mg of protein/min, respectively. In comparison, 7-ADTC had very similar kinetic properties with Km values of 25 and 31 microM and Vmax values of 1.14 and 0.27 nmol/mg of protein/min. Each compound was shown to inhibit competitively the transport of the other, suggesting that these substrates utilized a common membrane carrier. The transport properties of the photoreactive anion transport inhibitor, N-(4-azido-2-nitrophenyl)-2-aminoethylsulfonate (NAP-taurine) were also characterized in the hepatocyte system. Transport occurred via a sodium-dependent and a sodium-independent route with Km values of 210 and 555 microM and Vmax values of 0.57 and 1.62 nmol/mg of protein/min. As in the case of 7-ADTC, NAP-taurine and taurocholate were also shown to be mutual competitive inhibitors. In the absence of light, 7-ADTC was a reversible inhibitor of taurocholate uptake. Upon irradiation, irreversible photoinactivation of the taurocholate uptake system was observed. These results indicate that 7-ADTC and NAP-taurine can be utilized as photoaffinity probes for the identification of the bile acid carrier protein(s) in hepatocyte plasma membranes.     

Glutamine transport by rat basolateral membrane vesicles

Glutamine, a neutral amino acid, is unlike most amino acids, has two amine moieties which underlies its importance as a nitrogen transporter and a carrier of ammonia from the periphery to visceral organs. The gastrointestinal tract utilizes glutamine as a respiratory substrate. The intestinal tract receives glutamine from the luminal side and from the arterial side through the basolateral membranes of the enterocyte. This study characterizes the transport of glutamine by basolateral membrane vesicles of the rat. Basolateral membranes were prepared by a well validated technique of separation on a percoll density gradient. Membrane preparations were enriched with Na+/K+-ATPase and showed no 'overshoot' phenomena with glucose under sodium-gradient conditions. Glutamine uptake represented transport into the intravesicular space as evident by an osmolality study. Glutamine uptake was temperature sensitive and driven by an inwardly directed sodium gradient as evident by transient accumulation of glutamine above the equilibrium values. Kinetics of glutamine uptake under both sodium and potassium gradients at glutamine concentrations between 0.01 and 0.6 mM showed saturable processes with Vmax of 0.39 +/- 0.008 and 0.34 +/- 0.05 nmol/mg protein per 15 s for both sodium-dependent and sodium-independent processes, respectively. Km values were 0.2 +/- 0.01 and 0.55 +/- 0.01 mM, respectively. pH optimum for glutamine uptake was 7.5. Imposition of negative membrane potential by valinomycin and anion substitution studies enhanced the sodium-dependent uptake of glutamine suggesting an electrogenic process, whereas the sodium-independent uptake was not enhanced suggesting an electroneutral process. Other neutral amino acids inhibited the initial uptake of glutamine under both sodium-dependent and sodium-independent conditions. We conclude that glutamine uptake by basolateral membranes occurs by carrier-mediated sodium-dependent and sodium-independent processes. Both processes exhibit saturation kinetics and are inhibited by neutral amino acids. The sodium-dependent pathway is electrogenic whereas the sodium-independent pathway is electroneutral.     

Characterization of glutamine transport into resting and concanavalin A-stimulated peripheral human lymphocytes

Characteristics of glutamine transport, its substrate specificity, and its pattern of competitive and non-competitive inhibition in response to amino acid analogues were determined in peripheral human lymphocytes, incubated with or without concanavalin A (Con A). Maximum capacity of transport (Vmax) at 37 degrees C and 136.9 mM Na+ was 30 pmol/10(6) cells/30 seconds, while the apparent Km was 142 microM. In cells exposed to 10 mM histidine, asparagine, serine, or leucine transport of glutamine declined to 28%, 15%, 17%, and 21%, respectively, of the rates in controls. Inhibition by histidine (Ki = 0.58 mM) and serine (Ki = 0.25 mM) was competitive, by leucine was non-competitive (Ki = 0.64), while alpha-methylamino-isobutyric acid and 2-amino carboxy-bicyclo (2.2.1)-heptane had no effect. In cells cultured for 24 hours with or without 10 micrograms/ml Con A, the apparent Km was 70 microM vs. 89 microM and Vmax 73 vs. 26 pmol/10(6) cells/30 seconds. Sodium depletion (9.0 mM NaCl) greatly diminished glutamine transport in resting and stimulated cells. Inhibition of glutamine transport by serine was sodium sensitive, while inhibition by histidine and asparagine was not. Serine had no competitive effect in sodium-depleted media. The data demonstrate what appear to be two carrier systems for glutamine, sodium sensitive and sodium insensitive. It is suggested that glutamine transport into lymphocytes occurs via processes similar to System N and System ASC described in other cells, with System ASC as the sodium-sensitive component. Con A augments the capacity rather than the affinity of glutamine transporting systems.     

Calcium transport in membrane vesicles of Bacillus subtilis.

Right-side-out membrane vesicles of Bacillus subtilis W23 grown on tryptone-citrate medium accumulated Ca2+ under aerobic conditions in the presence of a suitable electron donor. Ca2+ uptake was an electrogenic process which was completely inhibited by carbonyl cyanide m-chlorophenylhydrazone or valinomycin and not by nigericin. This electrogenic uptake of calcium was strongly dependent on the presence of phosphate and magnesium ions. The system had a low affinity for Ca2+. The kinetic constants in membrane vesicles were Km = 310 microM Ca2+ and Vmax = 16 nmol/mg of protein per min. B. subtilis also possesses a Ca2+ extrusion system. Right-side-out-oriented membrane vesicles accumulated Ca2+ upon the artificial imposition of a pH-gradient, inside acid. This system had a high affinity for Ca2+; Km = 17 microM Ca2+ and Vmax = 3.3 nmol/mg of protein per min. Also, a membrane potential, inside positive, drove Ca2+ transport via this Ca2+ extrusion system. Evidence for a Ca2+ extrusion system was also supplied by studies of inside-out-oriented membrane vesicles in which Ca2+ uptake was energized by respiratory chain-linked oxidation of NADH or ascorbate-phenazine methosulfate. Both components of the proton motive force, the pH gradient and the membrane potential, drove Ca2+ transport via the Ca2+ extrusion system, indicating a proton-calcium antiport system with a H+ to Ca2+ stoichiometry larger than 2. The kinetic parameters of this Ca2+ extrusion system in inside-out-oriented membranes were Km = 25 microM and Vmax = 0.7 nmol/mg of protein per min.     

Malate transport in Schizosaccharomyces pombe.

The transport of malate was studied in a Schizosaccharomyces pombe wild-type strain and in mutant strains unable to utilize malic acid. Two groups of such mutants, i.e., malic enzyme-deficient and malate transport-defective mutants, were differentiated by a 14C-labeled L-malate transport assay and by starch gel electrophoresis followed by activity staining for malic enzyme (malate dehydrogenase [oxaloacetate decarboxylating] [NAD+]; 1.1.1.38) and malate dehydrogenase (1.1.1.37). Transport of malate in S. pombe was constitutive and strongly inhibited by inhibitors of oxidative phosphorylation and of the formulation of proton gradients. Transport was a saturable function of the malate concentration. The apparent Km and Vmax values for transport by the parent were 3.7 mM and 40 nmol/min per mg of protein, respectively, while those of the malic enzyme-deficient mutant were 5.7 mM and 33 nmol/min per mg of protein, respectively. Malate transport was pH and temperature dependent. The specificity of transport was studied with various substrates, including mono- and dicarboxylic acids, and the possibility of a common transport system for dicarboxylic acids is discussed.     

Low- and high-Km transport of dinitrophenyl glutathione in inside out vesicles from human erythrocytes.

Kinetic studies on the low- and high-Km transport systems for S-2,4-dinitrophenyl glutathione (DNP-SG) present in erythrocyte membranes were performed using inside-out plasma membrane vesicles. The high-affinity system showed a Km of 3.9 microM a Vmax of 6.3 nmol/mg protein per h, and the low-affinity system a Km of 1.6 mM and a Vmax of 131 nmol/mg protein per h. Both uptake components were inhibited by fluoride, vanadate, p-chloromercuribenzoate (pCMB) and bis(4-nitrophenyl)dithio-3,3'-dicarboxylate (DTNB). The low-Km uptake process was less sensitive to the inhibitory action of DTNB as compared to the high-Km process. N-Ethylmaleimide (1 mM) inhibited the high-Km process only. The high-affinity uptake of DNP-SG was competitively inhibited by GSSG (Ki = 88 microM). Vice versa, DNP-SG inhibited competitively the low-Km component of GSSG uptake (Ki = 3.3 microM). The high-Km DNP-SG uptake system was not inhibited by GSSG. The existence of a common high-affinity transporter for DNP-SG and GSSG in erythrocytes is suggested.     

Effects of corticosteroid on the transport and metabolism of glutamine in rat skeletal muscle.

Intramuscular glutamine falls with injury and disease in circumstances associated with increases in blood corticosteroids. We have investigated the effects of corticosteroid administration (0.44 mg/kg dexamethasone daily for 8 days, 200 g female rats) on intramuscular glutamine and Na+, muscle glutamine metabolism and sarcolemmal glutamine transport in the perfused hindlimb. After dexamethasone treatment intramuscular glutamine fell by 45% and Na+ rose by 25% (the respective muscle/plasma distribution ratios changed from 8.6 to 4.5 and 0.12 to 0.15); glutamine synthetase and glutaminase activities were unchanged at 475 +/- 75 and 60 +/- 19 nmol/g muscle per min. Glutamine output by the hindlimb of anaesthetized rats was increased from 31 to 85 nmol/g per min. Sarcolemmal glutamine transport was studied by paired-tracer dilution in the perfused hindlimb: the maximal capacity (Vmax) for glutamine transport into muscle (by Na(+)-glutamine symport) fell from 1058 +/- 310 to 395 +/- 110 nmol/g muscle per min after dexamethasone treatment, accompanied by a decrease in the Km (from 8.1 +/- 1.9 to 2.1 +/- 0.4 mM glutamine). At physiological plasma glutamine concentration (0.75 mM) dexamethasone appeared to cause a proportional increase in sarcolemmal glutamine efflux over influx. Addition of dexamethasone (200 nM) to the perfusate of control rat hindlimbs caused acute changes in Vmax and Km of glutamine transport similar to those resulting from 8-day dexamethasone treatment. The reduction in muscle glutamine concentration after dexamethasone treatment may be primarily due to a reduction in the driving force for intramuscular glutamine accumulation, i.e., in the Na+ electrochemical gradient. The prolonged increase in muscle glutamine output after dexamethasone treatment (which occurs despite a reduction in the size of the intramuscular glutamine pool) appears to be due to a combination of (a) accelerated sarcolemmal glutamine efflux and (b) increased intramuscular synthesis of glutamine.     

Study on the effect of hypergravity stress on L-glutamate uptake by rat brain nerve endings

Using rat brain synaptosomes, we have investigated the effect of hypergravity on the kinetic parameters of Na(+)-dependent, high-affinity L-glutamate transport activity. The time-course of L-[14C]-glutamate uptake and dependence of L-[14C]-glutamate uptake velocity on glutamate concentrations were analyzed. K(m) and Vmax of this process have been determined. The hypergravity stress was created by centrifugation of rats for 1 hour at 10 g. We observed no differences in K(m) values between the control rats (10.7 +/- 2.5 microM) and animals exposed to hypergravity (6.7 +/- 1.5 microM). The similarity of this parameter for the two studied groups of animals showed that affinity of glutamate transporter to substrate was not sensitive to hypergravity stress. In contrast, the maximal velocity of glutamate uptake changed in hypergravity conditions. Vmax reduced from 12.5 +/- +/- 3.2 nmol/min per 1 mg of protein (control group) to 5.6 +/- 0.9 nmol/min per 1 mg of protein (animals, exposed to hypergravity stress). The possible mechanisms of attenuation of the glutamate transporter activity without modifying K(m) of glutamate uptake were discussed.     

Artificial gravity and functional plasticity of nerve system. L-[14C]-glutamate uptake by nerve terminals from rat cerebellum and cerebral hemispheres under hypergravity stress

We have investigated the effects of altered gravity on the kinetic parameters of glutamate transport activity. We observed no differences in Km values for cerebellum and cerebral hemisphere nerve terminals (synaptosomes) between control rats- 18,2 +/- 7,6 micromoles (cerebellum), 10,7 +/- 2,5 micromoles (cerebral hemispheres) and animals exposed to hypergravity- 23,3 +/- 6,9 micromoles (cerebellum), 6,7 +/- 1,5 micromoles (cerebral hemispheres). The similarity of this parameter for the two studied groups of animals showed that affinity of glutamate transporter to substrate in cerebellum and cerebral hemispheres was not sensitive to hypergravity stress. The maximal velocity of L-[14C]-glutamate uptake (Vmax) reduced for cerebellum synaptosomes from 9,6 +/- 3,9 nmol/min/mg of protein in control group to 7,4 +/- 2,0 nmol/min/mg of protein in animals, exposed to hypergravity stress. For cerebral hemisphere synaptosomes the maximal velocity significantly decreased from 12,5 +/- 3,2 nmol/min/mg of protein to 5,6 +/- 0,9 nmol/min/mg of protein, respectively.     

Pyruvate and ketone-body transport across the mitochondrial membrane. Exchange properties, pH-dependence and mechanism of the carrier.

The effects of exchangeable ions and pH on the efflux of pyruvate from preloaded mitochondria are reported. Efflux obeys first-order kinetics, and the stimulation of efflux by exchangeable ions such as acetoacetate and lactate obeys Michaelis--Menten kinetics. The apparent Km value +/- S.E. for acetoacetate was 0.56 +/- 0.14 mM (n = 5) and that for lactate 12.3 +/- 2.3 mM (n = 6). The Vmax. values +/- S.E. at 0 degrees C were 16.2 +/- 2.0 and 21.9 +/- 2.7 nmol/min per mg of protein. The exchange of a variety of other substituted monocarboxylates was also studied. Efflux was also stimulated by increasing the external pH. The data gave a pK for the transport process of 8.35 and a Vmax. of 3.31 +/- 0.14 nmol/min per mg. The similarity of the Vmax. values for various exchangeable ions but the difference of this from the Vmax. in the absence of exchangeable ions may indicate that transport of pyruvate occurs with H+ and not in exchange for an OH- ion. The inhibition of transport by alpha-cyano-4-hydroxycinnamate took several seconds to reach completion at 0 degrees C. It is proposed that inhibition occurs by binding to the substrate site and subsequent reaction with an -SH group on the inside of the membrane. The inhibitor can be displaced by substrates that can also enter the mitochondria independently of the carrier and so compete with the inhibitor for the substrate-binding site on the inside of the membrane. A mechanism for transport is proposed that invokes a transition state of pyruvate involving addition of an -SH group to the 2-carbon of pyruvate. Evidence is presented that suggests that ketone bodies may cross the mitochondrial membrane either on the carrier or by free diffusion. The physiological involvement of the carrier in ketone-body metabolism is discussed. The role of ketone bodies and pH in the physiological regulation of pyruvate transport is considered.     

Subcellular distribution of ATP-dependent calcium transport in rat duodenal epithelium

Subcellular fractionation studies were performed to delineate plasma membrane and intracellular membrane populations which might be involved in intracellular Ca2+-homeostasis of rat small intestinal epithelial cells. After a low-speed supernatant fraction had been suspended in 5% sorbitol and subjected to equilibrium centrifugation in a zonal rotor, the Golgi and endoplasmic reticulum markers, galactosyltransferase and NADPH-cytochrome -c reductase, were concentrated in a density region designated Window II. The basal-lateral membrane marker (Na+-K+)-ATPase was concentrated in a higher-density region designated Window III. ATP-dependent Ca2+ transport was equally distributed between the two windows. Several membrane populations could be resolved from each window with good recovery of Ca2+-transport activity by a second density gradient centrifugation step. Second density gradient fractions were subjected to counter-current partitioning in an aqueous polymer two-phase system. Basal-lateral membranes, characterized by an 11-fold enrichment of (Na+-K+)-ATPase, contained ATP-dependent Ca2+-transport activity with Vmax = 3.7 nmol/mg per min and Km = 0.5 microM. A major Golgi-derived population exhibited Ca2+-transport activity with Vmax and Km values similar to those of the basal-lateral membranes. One membrane population, presumed to have been derived from the endoplasmic reticulum, contained Ca2+-transport activity with Vmax = 4 nmol/mg per min and Km = 0.5 microM. In addition to demonstrating that ATP-dependent Ca2+-transport activity has a complex distribution within enterocytes, this study raises the possibility that the basolateral plasma membranes might account for a relatively minor portion of the cell's Ca2+-pumping ability.     

Developmental changes in glutamine transport by rat jejunal basolateral membrane vesicles

The ontogeny of glutamine uptake by jejunal basolateral membrane vesicles (BLMV) was studied in suckling and weanling rats and the results were compared with adult rats. Glutamine uptake was found to represent a transport into an osmotically active space and not mere binding to the membrane surface. Temperature dependency indicated a carrier-mediated process with optimal pH of 7.0. Transport of glutamine was Na+ (out greater than in) gradient dependent with a distinct "overshoot" phenomenon. The magnitude of the overshoot was higher in suckling compared with weanling rats. The uptake kinetics and inhibition profile indicated the existence of two major transport pathways. A Na(+)-dependent system correlated with System A showed tolerance to System N and System ASC substrates, and a Na(+)-independent system similar to the classical L system that favors leucine and BCH. The Vmax for the Na(+)-dependent system was higher in suckling compared with weanling and adult rats. The Vmax for the Na(+)-dependent system was 0.86 +/- 0.17, 0.64 +/- 0.8, and 0.41 +/- 0.9 nmol.mg protein-1.10 sec-1 for suckling, weanling, and adult rats, respectively. The Vmax for the Na(+)-independent system was 0.68 +/- 0.08, 0.50 +/- 0.03, and 0.24 +/- 0.03 nmol.mg protein-1.10 sec-1 for suckling, weanling, and adult rats, respectively. We conclude that glutamine uptake undergoes developmental changes consistent with more activity and/or number of glutamine transporters during periods of active cellular proliferation and differentiation.     

Characterization of threonine transport into a kidney epithelial cell line (BSC-1). Evidence for the presence of Na(+)-independent system asc [corrected

The transport routes for threonine in a primate kidney epithelial cell line (BSC-1) grown as monolayer in continuous cell culture were studied. We discovered at least four different transport systems for threonine uptake. The Na(+)-dependent route shows biphasic kinetics with a low and high affinity parameter. The apparent kinetic constants for Km1 and Km2 were 0.3 and 36 mM with apparent Vmax values of 6.3 and 90 nmol/mg protein/min, respectively. The high affinity, low Km component resembles system ASC activity, with respect to substrate selectivity. The Na(+)-independent route also exhibits biphasic kinetics. A high affinity component (apparent Km of 1.0 mM, and apparent Vmax of 7.2 nmol/mg protein/min) is sensitive to inhibition by leucine and the aminoendolevo-rotatory isomer of 2-aminobicyclo[2,2,1]heptane-2-carboxylic acid, suggesting participation by system L. The low affinity component (apparent Km of 10.2 mM, and apparent Vmax of 71 nmol/mg protein/min) was specifically inhibited by threonine, serine, and alanine and could be assigned to system asc. The discrimination between system L and asc is based upon differences in pH sensitivity, trans stimulation, and Ki values. In addition, the effects of harmaline, a suspected sodium transport site inhibitor, have been studied. Harmaline noncompetitively inhibited Na(+)-dependent threonine uptake but had no effect on Na(+)-independent transport of threonine. This report is the first to present evidence for the presence of system asc in renal epithelial cells. The physiological and biochemical significance of our findings are discussed.     

Gender related differences in ATP-dependent transport of dinitrophenyl-glutathione conjugate across murine canalicular liver plasma membrane

The present study reports gender related differences in ATP-dependent transport of dinitrophenyl-glutathione (GSH) conjugate (DNP-SG), a model GSH xenobiotic conjugate, across murine canalicular liver plasma membrane (cLPM). ATP-dependent transport of DNP-SG across female A/J mouse cLPM was mediated by two components, a high-affinity and a low-affinity component, with corresponding Km of 18 microM (Vmax 0.02 nmol/min.mg) and 500 microM (Vmax 0.23 nmol/min.mg), respectively. On the other hand, only one component for the ATP-dependent transport of DNP-SG was observed in male mouse cLPM (K(m) 130 microM; Vmax 0.18 nmol/min.mg). Moreover, the rate of ATP-dependent transport of DNP-SG was markedly higher in the cLPM fraction of male mouse compared with that of the female. Presence of two transport components in female mouse cLPM, but only one system in the cLPM fraction of male mouse, was confirmed by measuring DNP-SG mediated stimulation of ATP hydrolysis (DNP-SG ATPase activity). To the best of our knowledge, the present study is the first report on gender related differences in ATP-dependent murine canalicular transport of GSH conjugates.     

Uptake of C4 dicarboxylates and pyruvate by Rhodopseudomonas spheroides.

The uptake of C4 dicarboxylates by cells from exponential cultures of Rhodopseudomonas spheroides followed saturation kinetics at concentrations below 100 muM with Km values for succinate, malate, and fumarate of 2.7, 2.3, and 0.8, respectively. Corresponding Vmax values of 50, 52, and 67.5 nmol/min per mg of protein at 20 C were obtained. Each of these compounds interfered competitively with uptake of the others, and a common transport system appears to be involved. Fructose-grown cells took up C4 dicarboxylates only at very low rates, and pyruvate-grown cells took up C4 dicarboxylates at one-third the rates found with succinate-grown cultures. Malonate and maleate inhibited uptake less severely, and aspartate and alpha-ketoglutarate had no effect at 100-fold excess. Divalent metals stimulated uptake. Light or respiration was required for uptake, and entered materials were rapidly converted to other metabolities, notably amino acids. Pyruvate entry appeared to be mediated by several systems, of which only one could be resolved kinetically. This system had a Km of 13 muM and Vmax of 5.6 nmol/min per mg of protein at 20 C. A number of related mono- and dicarboxylates interfered with pyruvate uptake. The pyruvate uptake system was distinguishable from the C4 dicarboxylate system by the absence of divalent cation stimulation and by substrate and inhibitor specificity.