Transport of Octanoate by Pseudomonas oleovorans

The properties of a system for octanoate transport in Pseudomonas oleovarans are described. Transport is inducible and energy dependent, shows saturation kinetics, and concentrates against a gradient. Optimal transport is at pH 6.0 and 28 C. Apparent K(m) and V(max) values are, respectively, 7.0 muM octanoate and 0.68 nmol of octanoate transported per min per mg (dry mass) of cells. Fatty acids from C(7) to C(12) are competitive inhibitors, whereas alkanes, alkenes, and esters of the same carbon chain lengths show no inhibition. The K(i) values for heptanoate, nonanoate, decanoate, undecanoate, and dodecanoate are 17, 3.4, 3.2, 1.2, and 2.4 muM, respectively. The molecular specificity of this transport system is a linear hydrocarbon chain of no less than 6 to at least 11 carbon atoms and a carboxyl group.     

Expression of alr gene from Corynebacterium glutamicum ATCC 13032 in Escherichia coli and molecular characterization of the recombinant alanine racemase

We constructed the high-expression system of the alr gene from Corynebacterium glutamicum ATCC 13032 in Escherichia coli BL 21 (DE3) to characterize the enzymological and structural properties of the gene product, Alr. The Alr was expressed in the soluble fractions of the cell extract of the E. coli clone and showed alanine racemase activity. The purified Alr was a dimer with a molecular mass of 78 kDa. The Alr required pyridoxal 5'-phosphate (PLP) as a coenzyme and contained 2 mol of PLP per mol of the enzyme. The holoenzyme showed maximum absorption at 420 nm, while the reduced form of the enzyme showed it at 310 nm. The Alr was specific for alanine, and the optimum pH was observed at about nine. The Alr was relatively thermostable, and its half-life time at 60 degrees C was estimated to be 26 min. The K(m) and V(max) values were determined as follows: l-alanine to d-alanine, K(m) (l-alanine) 5.01 mM and V(max) 306 U/mg; d-alanine to l-alanine, K(m) (d-alanine) 5.24 mM and V(max) 345 U/mg. The K(eq) value was calculated to be 1.07 and showed good agreement with the theoretical value for the racemization reaction. The high substrate specificity of the Alr from C. glutamicum ATCC 13032 is expected to be a biocatalyst for d-alanine production from the l-counter part.     

Mechanism of D-cycloserine action: transport systems for D-alanine, D-cycloserine, L-alanine, and glycine

The accumulation of d-alanine, l-alanine, glycine, and d-cycloserine in Escherichia coli was found to be mediated by at least two transport systems. The systems for d-alanine and glycine are related, and are separate from that involved in the accumulation of l-alanine. d-Cycloserine appears to be primarily transported by the d-alanine-glycine system. The accumulation of d-alanine, glycine, and d-cycloserine was characterized by two line segments in the Lineweaver-Burk analysis, whereas the accumulation of l-alanine was characterized by a single line segment. d-Cycloserine was an effective inhibitor of glycine and d-alanine accumulation, and l-cycloserine was an effective inhibitor of l-alanine transport. The systems were further differentiated by effects of azide, enhancement under various growth conditions, and additional inhibitor studies. Since the primary access of d-cycloserine in E. coli is via the d-alanine-glycine system, glycine might be expected to be a better antagonist of d-cycloserine inhibition than l-alanine. Glycine and d-alanine at 10(-5)m antagonized the effect of d-cycloserine in E. coli, whereas this concentration of l-alanine had no effect.     

Multiplicity of leucine transport systems in Escherichia coli K-12

The major component of leucine uptake in Escherichia coli K-12 is a common system for l-leucine, l-isoleucine, and l-valine (LIV-I) with a Michaelis constant (K(m)) value of 0.2 muM (LIV-I system). The LIV-binding protein appears to be associated with this system. It now appears that the LIV-I transport system and LIV-binding protein also serve for the entry of l-alanine, l-threonine, and possibly l-serine. A minor component of l-leucine entry occurs by a leucine-specific system (L-system) for which a specific leucine-binding protein has been isolated. A mutant has been obtained that shows increased levels of the LIV-I transport activity and increased levels of both of the binding proteins. Another mutant has been isolated that shows only a major increase in the levels of the leucine-specific transport system and the leucine-specific binding protein. A third binding protein that binds all three branched-chain amino acids but binds isoleucine preferentially has been identified. The relationship of the binding proteins to each other and to transport activity is discussed. A second general transport system (LIV-II system) with a K(m) value of 2 muM and a relatively low V(max) can be observed in E. coli. The LIV-II system is not sensitive to osmotic shock treatment nor to growth of cells in the presence of leucine. This high K(m) system, which is specific for the branched-chain amino acids, can be observed in membrane vesicle preparations.     

DsdX is the second D-serine transporter in uropathogenic Escherichia coli clinical isolate CFT073

d-Serine is an amino acid present in mammalian urine that is inhibitory to Escherichia coli strains lacking a functional dsdA gene. Counterintuitively, a dsdA strain of E. coli clinical isolate CFT073 hypercolonizes the bladder and kidneys of mice relative to wild type during a coinfection in the murine model of urinary tract infection. We are interested in the mechanisms for uptake of d-serine in CFT073. d-Serine enters E. coli K-12 via CycA, the d-alanine transporter and d-cycloserine sensitivity locus. CFT073 cycA can grow on minimal medium with d-serine as a sole carbon source. The dsdX gene of the dsdCXA locus is a likely candidate for an additional d-serine transporter based on its predicted amino acid sequence similarity to gluconate transporters. In minimal medium, CFT073 dsdX can grow on d-serine as a sole carbon source; however, CFT073 dsdX cycA cannot. Additionally, CFT073 dsdXA cycA is not sensitive to inhibitory concentrations of d-serine during growth on glycerol and d-serine minimal medium. d-[(14)C]serine uptake experiments with CFT073 dsdX cycA harboring dsdX or cycA recombinant plasmids confirm that d-serine is able to enter E. coli cells via CycA or DsdX. In whole-cell d-[(14)C]serine uptake experiments, DsdX has an apparent K(m) of 58.75 microM and a V(max) of 75.96 nmol/min/mg, and CycA has an apparent K(m) of 82.40 microM and a V(max) of 58.90 nmol/min/mg. Only d-threonine marginally inhibits DsdX-mediated d-serine transport, whereas d-alanine, glycine, and d-cycloserine inhibit CycA-mediated d-serine transport. DsdX or CycA is sufficient to transport physiological quantities of d-serine, but DsdX is a d-serine-specific permease.     

Transport of L-methionine in human diploid fibroblast strain WI38

The transport of L-methionine in human diploid fibroblast strain WI38 was investigated. The uptake of L-methionine was measured in sparse cell cultures in a simple balanced salt solution buffered with either Tris.HCl of N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid (HEPES). Similar results were obtained with these two buffers. Cultures were allowed to equilibrate with the buffered saline before transport was measured. The presence of glucose in the buffered saline results in a slight reduction in the initial rate of transport for the first 2 h of equilibration in buffered saline. L-Methionine is actively transported in WI38 by saturable, chemicallly specific mechanisms which are temperature, pH and, in part Na+ dependent, and are reactive with both L- and D-stereoisomers. Kinetic analysis of initial rates of transport at substrate concentrations from 0.0005 to 100 mM indicated the presence of two saturable transport systems. System 1 has an apparent KM of 21.7 micrometer and an apparent V of 3.57 nmol/mg per min. System 2 has an apparent KM of 547 micrometer and an apparent V of 22.6 nmol/mg per min. Kinetic analysis of initial rates of transport in Na+-free media or after treatment with ouabain suggested that system 1 is Na+ independent and that system 2 is Na+ dependent. Preloading of cells with unlabeled L-methionine greatly increases the initial rate of uptake. Efflux of transported methionine is temperature dependent, and is greatly increased in the presence of unlabeled L- or D-methionine or L-phenylalanine, but not in the presence of L-arginine. L-Methionine transport is strongly inhibited by other neutral amino acids, and is very weakly inhibited by dibasic amino acids, dicarboxylic amino acids, proline or glycine.     

Properties of the inducible hydroxyproline transport system of Pseudomonas putida

Features of the transport system for hydroxyproline in a strain of Pseudomonas putida were studied. A mutant, lacking hydroxyproline-2 epimerase and unable to metabolize hydroxy-l-proline, was shown to transport and accumulate this compound after induction. Both entry and exit rates were examined, and kinetic constants for the reaction were determined. Increasing the induction time from 0.5 to 3 hr increased the entry rate three- to fourfold but had only a small and variable effect on the exit rate. Entry followed saturation kinetics. For hydroxy-l-proline, the K(m) and V(max) values were found to be 3 x 10(-5)m and 6 mumoles per g (dry weight) per min, respectively. The K(m) and V(max) for the epimer allohydroxy-d-proline were 10(-3)m and 0.1 mumole per g (dry weight) per min. Entry rates into "loaded" and "unloaded" cells were found to be the same. Exit was shown to be first order over the range of internal substrate concentrations measured. Exit rates were measured by several different methods and found to be independent of external substrate concentration. The first-order exit rate constant was computed to be 0.23 min(-1). Several metabolic inhibitors were examined for their effect on transport. The inhibitory action of N-ethyl maleimide was shown to be greatly reduced if cells were allowed to accumulate hydroxy-l-proline before exposure to the inhibitor. A number of other amino acids interfered with the transport of hydroxy-l-proline; the greatest effect was produced by l-alanine and l-proline.     

Mechanism of D-cycloserine action: transport mutants for D-alanine, D-cycloserine, and glycine

The accumulation of d-alanine and the accumulation of glycine in Escherichia coli are related and appear to be separate from the transport of l-alanine. The analysis of four d-cycloserine-resistant mutants provides additional support for this conclusion. The first-step mutant from E. coli K-12 that is resistant to d-cycloserine was characterized by the loss of the high-affinity line segment of the d-alanine-glycine transport system in the Lineweaver-Burk plot. This mutation, which is linked to the met(1) locus, also resulted in the loss of the ability to transport d-cycloserine. The second-step mutation that is located 0.5 min from the first-step mutation resulted in the loss of the low-affinity line segment for the d-alanine-glycine transport system. The transport of l-alanine was decreased only 20 to 30% in each of these mutants. A multistep mutant from E. coli W that is 80-fold resistant to d-cycloserine lost >90% of the transport activity for d-alanine and glycine, whereas 75% of the transport activity for l-alanine was retained. E. coli W could utilize either d- or l-alanine as a carbon source, whereas the multistep mutant could only utilize l-alanine. Thus, a functioning transport system for d-alanine and glycine is required for both d-cycloserine action and growth on d-alanine.     

l-[3H]Nitroarginine and l-[3H]Arginine Uptake into Rat Cerebellar Synaptosomes: Kinetics and Pharmacology

Abstract: Characteristics of the transport of the nitric oxide synthase substrate l -arginine and its inhibitor, N ^G-nitro- l -arginine ( l -NOARG), into rat cerebellar synaptosomes were studied. Uptake of both l -arginine and l -NOARG was linear with increasing amount of protein (up to 40 µg) and time of incubation (up to 5 min) at 37°C. Uptake of both compounds reached a steady state by 20 min. Maximal uptake of l -NOARG (650 pmol/mg of protein) was three to four times higher than that of l -arginine (170 pmol/mg of protein). l -NOARG uptake showed biphasic kinetics ( K _{m 1} = 0.72 m M , V _{max 1} = 0.98 nmol/min/mg of protein; K _{m 2} = 2.57 m M , V _{max 2} = 16.25 nmol/min/mg of protein). l -Arginine uptake was monophasic with a K _m of 106 µ M and a V _max of 0.33 nmol/min/mg of protein. l -NOARG uptake was selectively inhibited by l -NOARG, N ^G-nitro- l -arginine methyl ester, and branched-chain and aromatic amino acids. l -Alanine and l -serine also inhibited l -NOARG uptake but with less potency. Uptake of l -arginine was selectively inhibited by N ^G-monomethyl- l -arginine acetate and basic amino acids. These studies suggest that in rat cerebellar synaptosomes, l -NOARG is transported by the neutral amino acid carrier systems T and L with high affinity, whereas l -arginine is transported by the basic amino acid carrier system y⁺ with high affinity. These data indicate that the concentration of competing amino acids is an important factor in determining the rates of uptake of l -NOARG and l -arginine into synaptosomes and, in this way, may control the activity of nitric oxide synthase.     

D-serine transport system in Escherichia coli K-12

The d-serine transport system in Escherichia coli K-12 was studied by use of a mutant unable to form d-serine deaminase, yet resistant to d-serine. The mutant is greatly impaired in its ability to accumulate d-serine, d-alanine, and glycine. Transport of l-alanine is partially affected but transport of l-serine is unaffected. The mutant is also resistant to d-cycloserine, indicating that d-serine is transported by the system responsible for uptake of d-cycloserine. The d-serine transport system is not inducible, but appears to be formed constitutively, as are the transport systems of most amino acids. The transport mutation appears to be multistep and maps to the right of malB on the E. coli linkage map.     

d-Glucose Transport System of Zymomonas mobilis

The properties of the d-glucose transport system of Zymomonas mobilis were determined by measuring the uptake of nonmetabolizable analogs (2-deoxy-d-glucose and d-xylose) by wild-type cells and the uptake of d-glucose itself by a mutant lacking glucokinase. d-Glucose was transported by a constitutive, stereospecific, carrier-mediated facilitated diffusion system, whereby its intracellular concentration quickly reached a plateau close to but not above the external concentration. d-Xylose was transported by the d-glucose system, as evidenced by inhibition of its uptake by d-glucose. d-Fructose was not an efficient competitive inhibitor of d-glucose uptake, indicating that it has a low affinity for the d-glucose transport system. The apparent K(m) of d-glucose transport was in the range of 5 to 15 mM, with a V(max) of 200 to 300 nmol min mg of protein. The K(m) of Z. mobilis glucokinase (0.25 to 0.4 mM) was 1 order of magnitude lower than the K(m) for d-glucose transport, although the V(max) values for transport and phosphorylation were similar. Thus, glucose transport cannot be expected to be rate limiting at concentrations of extracellular glucose normally used in fermentation processes, which greatly exceed the K(m) for the transport system. The low-affinity, high-velocity, nonconcentrative system for d-glucose transport described here is consistent with the natural occurrence of Z. mobilis in high-sugar environments and with the capacity of Z. mobilis for rapid conversion of glucose to metabolic products with low energetic yield.     

Glucose Transport in Brucella abortus

Brucella abortus British strain 19 transported glucose with an apparent K(m) of 0.16 mM and an apparent V(max) of 250 nmol per min per mg of N. The only common glucose analogue transported was 2-deoxyglucose (2-DOG), with an apparent K(i) of 0.73 mM. Alpha- or beta-methyl glucosides and 3-O-methylglucose were not transported. Transport was linear for 70 to 90 s, depending on the concentration of substrate used. 2-Deoxyglucose was transported as the free sugar and was not further metabolized once inside the cell. There was no glucose phosphoenolpyruvate phosphotransferase system (PEP-PTS) present, and there were no inhibitors present in Brucella cell-free extract that inhibited the Escherichia coli glucose PEP-PTS. N-Ethylmaleimide (NEM) and p-chloromercuribenzoate (pCMB) completely inhibited transport of glucose and 2-DOG. Glutathione, dithiothreitol, and beta-mercaptoethanol reversed the effects of pCMB but not of NEM. A pH optimum of 7.2 and a temperature optimum of 37 to 45 C were observed for both K(m) and V(max). The glucose transport system appeared to be constitutive for glucose transport in cells grown on fructose, galactose, erythritol, or glucose. The electron transfer inhibitors carbonyl cyanide, m-chlorophenylhydrazone, NaN(3), 2,4-dinitrophenol, and KCN inhibited 2-DOG transport to a greater extent than did the metabolic energy inhibitors NaAsO(4), iodoacetate, KF, and 2-heptyl-4-hydroxyquinoline-N-oxide. Dicyclohexylcarbodiimide, an inhibitor of membrane-bound adenosine triphosphatases, inhibited transport by 100%.     

Multiple transport pathways for dibasic amino acids in the larval midgut of the silkworm Bombyx mori

The transport pathways for dibasic amino acids were investigated in brush border membrane vesicles (BBMV) from the anterior-middle (AM) and posterior (P) regions of Bombyx mori midgut. In the absence of K(+), a low-affinity saturable transport of arginine in both AM- and P-BBMV (K(m) 1.01 mM, V(max) 4.07 nmol/7s/mg protein and K(m) 1.38 mM, V(max) 2.26 nmol/7s/mg protein, respectively) was detected. Arginine influx was dependent on the membrane electrical potential (Deltapsi) and increased raising the alkalinity of the external medium from pH 7.2 to 10.6. Competition experiments indicated the following order of substrate affinity: arginine, homoarginine, N(G)-monomethylarginine, N(G)-nitroarginine>lysine>ornithine>cysteine>methionine. Leucine, valine and BCH (2-amino-2-norbornanecarboxylic acid) did not inhibit arginine influx. In the presence of external K(+), the influx of arginine as a function of arginine concentration fitted to a complex saturation kinetics compatible with both a low-affinity and a high-affinity component. The latter (K(m) 0.035 mM, V(max) 2.54 nmol/7s/mg protein) was fully characterized. The influx rate had an optimum at pH 8.8, was strongly affected by Deltapsi and was homogeneous along the midgut. The substrate affinity rank was: homoarginine>arginine, N(G)-monomethylarginine>cysteine, lysine>N(G)-nitroarginine>ornithine>methionine. Leucine and amino acids with a hydrophobic side chain were not accepted. This system is also operative in the absence of potassium, with the same order of specificity but a very low activity. Lysine influx is mediated by two more transport systems, the leucine uniport and the K(+)/leucine symport specific for amino acids with a hydrophobic side chain that recognizes lysine at extravesicular pH values (pH(out)) exceeding 9. Both the uniport and the symport differ from the cationic transport systems so far identified in mammals because they are unaffected by N-ethylmaleimide, have no significant affinity for neutral amino acids in the presence of the cation and show a striking difference in their optimum pH.     

New fluorescent bile acids: synthesis, chemical characterization, and disastereoselective uptake by Caco-2 cells of 3-deoxy 3-NBD-amino deoxycholic and ursodeoxycholic acid

Deoxycholic acid (DCA), a secondary bile acid (BA), and ursodeoxycholic acid (UDCA), a tertiary BA, cause opposing effects in vivo and in cell suspensions. Fluorescent analogues of DCA and UDCA could help investigate important questions about their cellular interactions and distribution. We have prepared a set of isomeric 3α- and 3β-amino analogues of UDCA and DCA and derivatised these with the discrete fluorophore, 4-nitrobenzo-2-oxa-1,3-diazol (NBD), forming the corresponding four fluorescent adducts. These absorb in the range 465-470 nm and fluoresce at approx. 535 nm. In order to determine the ability of the new fluorescent bile acids to mimic the parents, their uptake was studied using monolayers of Caco-2 cells, which are known to express multiple proteins of the organic anion-transporting peptide (OATP) subfamily of transporters. Cellular uptake was monitored over time at 4 and 37°C to distinguish between passive and active transport. All four BA analogues were taken up but in a strikingly stereo- and structure-specific manner, suggesting highly discriminatory interactions with transporter protein(s). The α-analogues of DCA and to a lesser extent UDCA were actively transported, whereas the β-analogues were not. The active transport process was saturable, with Michaelis-Menten constants for 3α-NBD DCA (5) being K(m)=42.27±12.98 μM and V(max)=2.8 ± 0.4 nmol/(mg protein*min) and for 3α-NBD UDCA (3) K(m)=28.20 ± 7.45 μM and V(max)=1.8 ± 0.2 nmol/(mg protein*min). These fluorescent bile acids are promising agents for investigating questions of bile acid biology and for detection of bile acids and related organic anion transport processes.     

Functional characterization of human and cynomolgus monkey UDP-glucuronosyltransferase 1A6 enzymes

UDP-glucuronosyltransferase 1A6 (UGT1A6) is a major isoform in the human liver that glucuronidates numerous drugs, environmental chemicals and endogenous substrates. In this study, human and cynomolgus monkey UGT1A6 cDNAs (humUGT1A6 and monUGT1A6, respectively) were cloned, and the corresponding proteins were heterologously expressed in yeast cells to identify the functions of primate UGT1A6s. The enzymatic properties of UGT1A6 proteins were characterized by the kinetic analysis of serotonin (5-hydroxytryptamine, 5-HT) and 4-methylumbelliferone (4-MU) glucuronidation. humUGT1A6 and monUGT1A6 showed 96% identity in their nucleotide and amino acid sequences. Immunoblotting analysis using an antibody raised against human UGT1A6 showed that protein staining intensities were different between human and cynomolgus monkey UGT1A6 enzymes in microsomal fractions from livers and yeast cells, although both enzymes were detectable. The apparent K(m) value (15 mM) for 5-HT glucuronidation of cynomolgus monkey liver microsomes was significantly higher than that (8.6mM) of human liver microsomes, whereas V(max) values were lower in cynomolgus monkeys (2.8 nmol/min/mg protein) than in humans (8.6 nmol/min/mg protein). No significant species difference was observed in K(m) (approximately 90 microM) or V(max) (approximately 25 nmol/min/mg protein) values for liver microsomal 4-MU glucuronidation. In yeast cell microsomes, K(m) values (approximately 6mM) for 5-HT glucuronidation by recombinant UGT1A6s were similar, while a V(max) value (0.1nmol/min/mg protein) of monUGT1A6 was significantly lower than that (0.7 nmol/min/mg protein) of humUGT1A6. In 4-MU glucuronidation, both K(m) (210 microM) and V(max) (3.5 nmol/min/mg protein) values of monUGT1A6 were significantly higher than those of humUGT1A6 (K(m), 110 microM; V(max), 1.5nmol/min/mg protein). These findings suggest that the enzymatic properties of UGT1A6 were extensively different between humans and cynomolgus monkeys, although humUGT1A6 and monUGT1A6 showed high homology at the amino acid level. The information gained in this study should help with in vivo extrapolation and to assess the toxicity of xenobiotics.     

New substrates for the dicarboxylate transport system of Sinorhizobium meliloti

The dicarboxylate transport (Dct) system of Sinorhizobium meliloti, which is essential for a functional nitrogen-fixing symbiosis, has been thought to transport only dicarboxylic acids. We show here that the permease component of the Dct system, DctA, can transport orotate, a monocarboxylic acid, with an apparent K(m) of 1.7 mM and a V(max) of 163 nmol min(-1) per mg of protein in induced cells. DctA was not induced by the presence of orotate. The transport of orotate was inhibited by several compounds, including succinamic acid and succinamide, which are not dicarboxylic acids. The dicarboxylic acid maleate (cis-butenedioic acid) was not an inhibitor of orotate transport, which suggests that it was not recognized by DctA. However, maleate was an excellent inducer of DctA expression. Our evaluation of 17 compounds as inducers and inhibitors of transport suggests that substrates recognized by S. meliloti DctA must have appropriately spaced carbonyl groups and an extended conformation, while good inducers are more likely to have a curved conformation.     

Serine and glycine transport in fetal ovine hepatocytes

The role of hepatic serine and glycine transport in the regulation of the biosynthesis of serine by the fetal liver has not been studied. The goal of this study was to characterize serine and glycine transport and utilization at physiologic concentrations in primary cultures of fetal ovine hepatocytes. Primary culture of hepatocytes from mid gestation ( approximately 90 days) and term ( approximately 135 days) fetal sheep were studied after overnight serum free culture. At both gestational ages, the initial rate for sodium dependent 300 microM serine transport (1697+/-131 pmoles/min/mg protein at mid, 1765+/-544 at term) was fourfold greater than sodium dependent 300 microM glycine transport (309+/-54 at mid, 579+/-252 at term). At physiologic concentrations (300 microM), 69+/-7% of serine and 49+/-8% of glycine transport was sodium dependent. At term, sodium dependent serine transport has a V(max) of 1751+/-348 pmoles/min/mg protein and a K(m) of 159+/-111 microM. Sodium independent serine transport has a V(max) of 904+/-185 and a K(m) of 416+/-188 microM. Sodium dependent glycine transport has a V(max) of 410+/-69 and a K(m) of 2290+/-895 microM while sodium independent glycine transport exhibits non-saturable kinetics. Glycine (300 microM) sodium dependent transport was not inhibited by methyl-AIB while sodium dependent 300 microM serine transport was inhibited (31%). n-Ethylmaleimide inhibited sodium dependent serine and glycine transport by 36+/-9% and 37+/-2% respectively in term hepatocytes. Cysteine inhibited sodium dependent serine transport by 37%. Sodium independent glycine transport at 300 microM was higher in low glucose (1.1 mM) medium (881+/-76 pmoles/min/mg protein) compared to high glucose (5.5 mM) medium (510+/-60 P=0.004). There were no significant differences in serine or glycine incorporation into RNA, DNA, glycogen or lipid and protein. The predominance of serine transport over glycine at physiologic concentrations suggests that inward cellular amino acid transport of serine and glycine is not likely to be a regulatory mechanism that would favor serine biosynthesis in fetal ovine hepatocytes.     

Characterization of 3-[(123)I]iodo-L-alpha-methyl tyrosine transport in astrocytes of neonatal rats

3-[(123)I]Iodo-L-alpha-methyl tyrosine ((123)I-IMT) is used for diagnosis and monitoring of brain tumours by means of single-photon emission tomography. As recently shown, (123)I-IMT is predominantly mediated into rat C6 glioma cells by sodium-independent system L for large neutral amino acids. Until now, (123)I-IMT transport in non-neoplastic glial cells has not been examined. Therefore, the aim of this study was to examine the cellular pathways and precise transport kinetics of (123)I-IMT uptake into astrocytes of neonatal rats. In particular sodium-independent (123)I-IMT transport into neonatal astrocytes was compared with sodium-independent (123)I-IMT uptake into neoplastic rat C6 glioma cells. Competitive inhibition experiments showed that (123)I-IMT is exclusively transported via sodium-independent system L into the neonatal astrocytes (92%). Kinetic analysis of sodium-independent (123)I-IMT uptake into neonatal astrocytes and into C6 glioma cells revealed apparent Michaelis constants K(M) = 13.9 +/- 0.5 microM and K(M) = 33.9 +/- 4.1 microM, respectively, which are in the same range of K(M) values as those recently determined for amino acid transport into neoplastic and non-neoplastic glial cells. Indeed, the K(M) values in the micromolar range correspond to the expression of the LAT-1 subunit of system L both in the neonatal astrocytes and in C6 glioma cells. However, sodium-independent maximum transport velocities (V(max)) differed significantly between neonatal astrocytes and C6 glioma cells (11.1 +/- 0.3 and 39.9 +/- 3.3 nmol/mg protein/10 min, respectively).     

Basic and neutral amino acid transport in Aspergillus nidulans.

Arginine and methionine transport by Aspergillus nidulans mycelium was investigated. A single uptake system is responsible for the transport of arginine, lysine and ornithine. Transport is energy-dependent and specific for these basic amino acids. The Km value for arginine is 1 X 10(-5) M, and Vmax is 2-8 nmol/mg dry wt/min; Km for lysine is 8 X 10(-6) M; Kt for lysine as inhibitor of arginine uptake is 12 muM, and Ki for ornithine is mM. On minimal medium, methionine is transported with a Km of 0-I mM and Vmax about I nmol/mg dry wt/min; transport is inhibited by azide. Neutral amnio acids such as serine, phenylalanine and leucine are probably transported by the same system, as indicated by their inhibition of methionine uptake and the existence of a mutant specifically impaired in their transport. The recessive mutant nap3, unable to transport neutral amino acids, was isolated as resistant to selenomethionine and p-fluorophenylanine. This mutant has unchanged transport of methionine by general and specific sulphur-regulated permeases.     

Na+-dependent transport of glycine in renal brush border membrane vesicles: Evidence for a single specific transport system

The uptake of glycine in rabbit renal brush border membrane vesicles was shown to consist of glycine transport into an intravesicular space. An Na⁺ electrochemical gradient (extravesicular>intravesicular) stimulated the initial rate of glycine uptake and effected a transient accumulation of intravesicular glycine above the steady-state value. This stimulation could not be induced by the imposition of a K⁺, Li⁺ or choline⁺ gradient and was enhanced as extravesicular Na⁺ was increased from 10 mM to 100 mM. Dissipation of the Na⁺ gradient by the ionophore gramicidin D resulted in diminished Na⁺-stimulated glycine uptake. Na⁺-stimulated uptake of glycine was electrogenic. Substrate-velocity analysis of Na⁺-dependent glycine uptake over the range of amino acid concentrations from 25 μM to 10 mM demonstrated a single saturable transport system with apparent K_m = 996 μM and V_max = 348 pmol glycine/mg protein per min. Inhibition observed when the Na⁺-dependent uptake of 25 μM glycine was inhibited by 5 mM extravesicular test amino acid segregated dibasic amino acids, which did not inhibit glycine uptake, from all other amino acid groups. The amino acids d-alanine, d-glutamic acid, and d-proline inhibited similarly to their l counterparts. Accelerative exchange of extravesicular [³H]glycine was demonstrated when brush border vesicles were preloaded with glycine, but not when they were preloaded with l-alanine, l-glutamic acid, or with l-proline. It is concluded that a single transport system exists at the level of the rabbit renal brush border membrane that functions to reabsorb glycine independently from other groups of amino acids.