A kinetic analysis of d-xylose transport in rhodotorula glutinis

The kinetics of D-xylose transport were studied in Rhodotorula glutinis. Analysis of the saturation isotherm revealed the presence of at least two carriers for d-xylose in the Rhodotorula plasma membrane. These two carriers exhibited Km values differing by more than an order of magnitude. The low K_m carrier was repressed in rapidly growing cells and depressed by starvation of the cells.Several hexoses were observed to inhibit d-xylose transport. In the studies reported here, the inhibitions produced by d-galactose and 2-deoxy-d-glucose were examined in some detail in order to define the interactions of these sugars with the d-xylose carriers. 2-Deoxy-d-glucose competitively inhibited both of the d-xylose carriers. In contrast, only the low-K_m carrier was competitively inhibited by d-galactose.     

Carrier-mediated Uptake of Arginine and Urea by Chlamydomonas reinhardtii

Chlamydomonas reinhardtii possesses a high affinity, highly specific carrier involved in uptake of exogenous arginine. Carrier-mediated uptake of other amino acids cannot be detected, even in cultures maintained on amino acids as a nitrogen source or starved for nitrogen. This fact may contribute to the difficulty of isolating strains auxotrophic for amino acids other than arginine; conventional selection media may not supply adequate quantities of amino acids to permit growth of auxotrophs. A urea carrier is also present in C. reinhardtii but is readily distinguished from the arginine carrier on the basis of kinetic properties and sensitivity to a range of structural analogs. Ammonia appears to play a major role in regulating (depressing) activity of the arginine uptake system. Activity of the urea uptake system is elevated in nitrogen-starved cultures and elevated even further in the presence of urea or arginine. Extensive, independent fluctuations in the two uptake systems observed in semisynchronous cultures suggest that both are subject to modulation by a complex set of interacting endogenous and exogenous factors.     

Transport of arginine and aspartic Acid into isolated barley mesophyll vacuoles

The transport of arginine into isolated barley (Hordeum vulgare L.) mesophyll vacuoles was investigated. In the absence of ATP, arginine uptake was saturable with a K_m of 0.3 to 0.4 millimolar. Positively charged amino acids inhibited arginine uptake, lysine being most potent with a K_i of 1.2 millimolar. In the presence of free ATP, but not of its Mg-complex, uptake of arginine was drastically enhanced and a linear function of its concentration up to 16 millimolar. The nonhydrolyzable adenylyl imidodiphosphate, but no other nucleotide tested, could substitute for ATP. Therefore, it is suggested that this process does not require energy and does not involve the tonoplast ATPase. The ATP-dependent arginine uptake was strongly inhibited by p-chloromercuriphenylsulfonic acid. Furthermore, hydrophobic amino acids were inhibitory (I₅₀ phenylalanine 1 millimolar). Similar characteristics were observed for the uptake of aspartic acid. However, rates of ATP-stimulated aspartic acid transport were 10-fold lower as compared to arginine transport. Uptake of aspartate in the absence of ATP was negligible.     

Cellular uptake of cadmium and zinc

CHO mutants, resistant to over 100-fold of a normally toxic level of extracellular cadmium have been used to examine the mutually antagonistic effect of Cd and Zn on their uptake. Cadmium uptake in these mutants is only 7–10% that of the parental cells. Zinc uptake in these mutants is equal to or greater than that in the wild-type cells. Results of kinetic studies on uptake indicated that the two metals interact by competitive inhibition. TheK _m andK _i values for Cd and/or Zn were different in some of the mutants and indicate multiple carriers may be involved in the transport of these metals. The reduction in Cd uptake and concomitant increase in Zn uptake contribute to the increased Cd resistance in these mutants.     

Kinetic Characterization of Nitrite Uptake and Reduction by Chlamydomonas reinhardtii

Kinetics of nitrite uptake and reduction by Chlamydomonas reinhardtii cells growing phototrophically has been studied by means of progress curves and the Michaelis-Menten integrated equation. Both uptake and reduction processes exhibited hyperbolic saturation kinetics, the nitrite uptake system lacking a diffusion component. Nitrite uptake and reduction showed significant differences in K_s for nitrite at pH 7.5 (1.6 versus 20 micromolar, respectively), optimal pH, activation energy values, and sensitivity toward reagents of sulfhydryl groups. K_s values for nitrite uptake were halved in cells subjected to darkness or to nitrogen-starvation. Nitrate inhibited nitrite uptake by a partially competitive mechanism. The same inhibition pattern was found for nitrite uptake by C. reinhardtii mutant 305 cells incapable of nitrate assimilation. The results demonstrate that C. reinhardtii cells take up nitrite via a highly specific carrier, probably energy-dependent, kinetically responsive to environmental changes, distinguishable from the enzymic nitrite reduction and endowed with an active site for nitrite not usable for nitrate transport.     

The uptake and metabolism of urea by Chara australis: IV. Symport with sodium—A slip model for the high and low affinity systems

We have previously investigated the electrogenic influx of urea in Chara, and the urea- and sodium-dependent membrane current. We have shown that there is a sodium-stimulated component of urea influx and a urea-stimulated component of sodium influx, and that these are of the same size. We conclude that the electrogenic inward transport of urea, and of its analogues acetamide and acrylamide, is by sodium symport, with a stoichiometric ratio of 1∶1. The kinetics of the fluxes and currents show two different K _M values for sodium in different cells and two different kinds of kinetics for the effect of urea on membrane current, one of which fits the Michaelis-Menten equation, while the other shows a maximum and fits the difference of two Michaelis-Menten terms, suggesting a phenomenon like cis-inhibition. Similarities in kinetic characteristics between the inhibitory site and the electrically silent uptake site (System II) lead us to suggest that the same protein may be responsible for both the low-K _M, electrogenic influx of urea (System I) and the high-K _M, electrically silent influx by System II. We suggest a “slip” model for urea uptake in Chara.     

AMINO ACID AND UREA UPTAKE IN TEN SPECIES OF CHLOROPHYTA1

The Uptake of radioartively-labelled mixed amino acids, arginine, lysine, leucine, glutamic acid and urea was examined in six species of Volvocales and four species of Chlarococcales grown in nitrate-containing medium. Nonradioactive amino acids in excess were used to estimate specificity of amino and carriers in selected cases. All ten species possess salurable (hence, carrier-mediated) systems for uptake of both arginine and urea. In all Volvacales and one Chlorococcales, the arginine-speciftc carrier (which also transported lysine with lower efficiency) was the only amino acid carrier detected. Three species of Chlororoccales appear to possess a separate carrier for lysine and two of these appear to possess at least one additional carrier that is involved in uptake of non-basic amino acids.     

Uptake of N-methyl-4-phenylpyridinium ion (MPP+) into PC12h pheochromocytoma cells

The uptake and accumulation of N-methyl-4-phenylpyridinium ion (MPP⁺), a neurotoxin produced by oxidation of N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), into PC12h pheochromocytoma cells were examined. Concentration gradients of MPP⁺ were established at its low concentrations of 10 to 100 nM. Uptake of MPP⁺ into PC12h cells was mediated by saturable, carrier mediated transport systems with two different kinetic properties; a high-affinity and low-capacity system and a low-affinity and high-capacity system. The apparent K_m values of these two systems were obtained to be 254.4 ± 96.5 nM and 23.1 ± 6.9 μM, respectively, and the maximal uptake velocity was obtained to be 8.47 ± 1.72 and 28.6 ± 5.2 pmol/min/mg protein, respectively. The uptake by a high-affinity system was mediated by a carrier system common to dopamine and noradrenalin and MPTP itself proved to be taken up by this system, which was further confirmed by the inhibition of the MPP⁺ uptake by nomifensine and mazindol. The uptake was inhibited by metabolic inhibitors, such as carbonyl cyanide m-chlorophenyl hydrazone, sodium cyanide and 2,4-dinitrophenol, and the uptake was inhibited by ouabain and nigercin. By subcellular fractionation, MPP⁺ taken up was found to be localized mainly in cytosol fraction, but a definite amount of MPP⁺ was found also in mitochondrial fraction.     

A kinetic analysis of d-xylose transport in rhodotorula glutinis

The kinetics of D-xylose transport were studied in Rhodotorula glutinis. Analysis of the saturation isotherm revealed the presence of at least two carriers for d-xylose in the Rhodotorula plasma membrane. These two carriers exhibited Km values differing by more than an order of magnitude. The low K_m carrier was repressed in rapidly growing cells and depressed by starvation of the cells.Several hexoses were observed to inhibit d-xylose transport. In the studies reported here, the inhibitions produced by d-galactose and 2-deoxy-d-glucose were examined in some detail in order to define the interactions of these sugars with the d-xylose carriers. 2-Deoxy-d-glucose competitively inhibited both of the d-xylose carriers. In contrast, only the low-K_m carrier was competitively inhibited by d-galactose.     

The Hexose-Proton Cotransport System of Chlorella : pH-Dependent Change in Km Values and Translocation Constants of the Uptake System

The proton concentration in the medium affects the maximal velocity of sugar uptake with a K_m of 0.3 mM (high affinity uptake). By decreasing the proton concentration a decrease in high affinity sugar uptake is observed, in parallel the activity of a low affinity uptake system (K_m of 50 mM) rises. Both systems add up to 100%. The existence of the carrier in two conformational states (protonated and unprotonated) has been proposed therefore, the protonated form with high affinity to 6-deoxyglucose, the unprotonated form with low affinity. A plot of extrapolated V_max values at low substrate concentration versus proton concentration results in a K_m for protons of 0.14 µM, i.e. half-maximal protonation of the carrier is achieved at pH 6.85. The stoichiometry of protons cotransported per 6-deoxyglucose is close to 1 at pH 6.0–6.5. At higher pH values the stoichiometry continuously decreases; at pH 8.0 only one proton is cotransported per four molecules of sugar. Whereas the translocation of the protonated carrier is strictly dependent on sugar this coupling is less strict for the unprotonated form. Therefore at alkaline pH a considerable net efflux of accumulated sugar can occur. The dependence of sugar accumulation on pH has been measured. The decrease in accumulation with higher pH values can quantitatively be explained by the decrease in the amount of protonated carrier. The properties of the unprotonated carrier resemble strikingly the properties of carrier at the inner side of the membrane. The inside pH of Chlorella was measured with the weak acid 5,5-dimethyl-2, 4-oxazolidinedion (DMO). At an outside pH of 6.5 the internal pH was found to be 7.2. To explain the extent of sugar accumulation it has to be assumed that the membrane potential also contributes to active sugar transport in this alga.     

Carrier-Mediated Uptake of 1-(Malonylamino)cyclopropane-1-Carboxylic Acid in Vacuoles Isolated from Catharanthus roseus Cells

The uptake of 1-(malonylamino)cyclopropane-1-carboxylic acid (MACC), the conjugated form of the ethylene precursor, into vacuoles isolated from Catharanthus roseus cells has been studied by silicone layer floatation filtering. The transport across the tonoplast of MACC is stimulated fourfold by 5 millimolar MgATP, has a K_m of about 2 millimolar, an optimum pH around 7, and an optimum temperature at 30°C. Several effectors known to inhibit ATPase (N,N′-dicyclohexylcarbodiimide) and to collapse the transtonoplastic H⁺ electrochemical gradient (carbonylcyanide m-chlorophenylhydrazone, gramicidin, and benzylamine) all reduced MACC uptake. Abolishing the membrane potential with SCN⁻ and valinomycin also greatly inhibited MACC transport. Our data demonstrate that MACC accumulates in the vacuole against a concentration gradient by means of a proton motive force generated by a tonoplastic ATPase. The involvement of a protein carrier is suggested by the strong inhibition of uptake by compounds known to block SH—, OH—, and NH₂— groups. MACC uptake is antagonized competitively by malonyl-d-tryptophan, indicating that the carrier also accepts malonyl-d-amino acids. Neither the moities of these compounds taken separately [1-aminocyclopropane-1-carboxylic acid, malonate, d-tryptophan or d-phenylalanine] nor malate act as inhibitors of MACC transport. The absence of inhibition of malate uptake by MACC suggests that MACC and malate are taken up by two different carriers. We propose that the carrier identified here plays an important physiological role in withdrawing from the cytosol MACC and malonyl-d-amino acids generated under stress conditions.     

Inhibition of chloroplast coupling factor by naphthylglyoxal

The trypsin-activated Ca²⁺ -ATPase of spinach chloroplast membranes was completely inhibited by treatment with naphthylglyoxal, a fluorescent compound that should bind covalently to arginine residues. The inhibition followed apparent first-order kinetics. The apparent order of reaction with respect to inhibitor concentration gave values near unity, suggesting that inactivation is a consequence of modifying one arginine residue per active site. Partial protection against naphthylglyoxal was afforded by ADP and ATP, with either less or no protection by other nucleotide bases. At inhibition levels less than complete, the K_m for ATP was not affected but the V_max of the enzyme was diminished. The light-dependent exchange of tightly bound nucleotides on the membrane-bound enzyme was not inhibited by naphthylglyoxal treatment, indicating significant retention of the conformational response of the enzyme to the membrane high-energy state. Using [³H]naphthylglyoxal, the extent of inhibition was a linear function of the amount of naphthylglyoxal bound up to 60% inhibition. The curves extrapolated to 2 mol naphthylglyoxal bound, associated with complete inhibition of ATPase. The radioactive naphthylglyoxal was distributed equally between α- and β-subunits.     

Partial Characterization of K and Ca Uptake Systems in the Halotolerant Alga Dunaliella salina

The uptake of K⁺ and Ca²⁺ in Dunaliella salina is mediated by two distinct carriers: a K⁺ carrier with a high selectivity against Na⁺, Li⁺, and choline⁺ but not towards Rb⁺, K⁺, Cs⁺, or NH₄⁺, and a Ca²⁺ carrier with a high selectivity against Mg²⁺. The latter is specifically blocked by La³⁺ and by Cd²⁺. Apparent K_m values for K⁺ and Ca²⁺ uptake are 2.5 and 0.8 millimolar, respectively, and their maximal calculated fluxes are 22 and 0.8 nanomoles per square meter per second, respectively. Effects of permeable ions and ionophores on K⁺ and Ca²⁺ uptake suggest that the driving force for their uptake is the transmembrane electrical potential. Inhibitors of ATP production, typical inhibitors of plasma membrane H⁺-ATPases and protonionophores inhibit K⁺ and Ca²⁺ uptake and accelerate K⁺ efflux. The results suggest that an H⁺-ATPase in the cell membrane provides the driving force for K⁺ and Ca²⁺ uptake. Efflux measurements from ⁸⁶Rb⁺ and ⁴⁵Ca²⁺ loaded cells suggest that part of the intracellular K⁺ and most of the intracellular Ca²⁺ is nonexchangeable with the extracellular pool. Correlations between phosphate and K⁺ contents and the effect of phosphate on K⁺ efflux suggest intracellular associations between K⁺ and polyphosphates. On the basis of these results, it is suggested that: (a) K⁺ and Ca²⁺ uptake in D. salina is driven by the transmembrane electrical potential which is generated by the action of an H⁺-ATPase of the plasma membrane. (b) Part of the intracellular K⁺ is associated with polyphosphate bodies, while most of the intracellular Ca²⁺ is accumulated in intracellular organelles in the algal cells.     

Urea uptake by the scleractinian coral Stylophora pistillata

Urea can be one of the major sources of nitrogen for phytoplankton, but little is known about its importance for corals. Experiments were therefore designed to assess the uptake rates of urea by the scleractinian coral Stylophora pistillata; ¹⁵N-urea was used to follow the incorporation of nitrogen into the zooxanthellae and animal tissue. The uptake kinetics of urea in the tissue of S. pistillata showed that there is a concentration-dependent uptake of urea. The transport of urea was composed of a linear component (diffusion) at concentrations higher than 6 μmol N-urea l^− 1 and an active carrier-mediated component, at lower concentrations. The value of the carrier affinity (K_m = 1.05 μmol urea l^− 1) indicates a good adaptation of the corals to low levels of urea in seawater. At the in situ concentration of ca. 0.2 μmol N-urea l^− 1, the uptake rate was equal to 0.1 nmol N h^− 1 cm^− 2. Urea uptake was at least four times higher in the animal than in the algal fraction, and five times higher when corals were incubated in the light than in the dark. These results could be explained by the involvement of urea in the calcification process, which is also enhanced by light. Comparison of urea uptake rates with nitrate or ammonium uptake rates for the same S. pistillata species, at in situ concentrations, showed that urea is preferred to nitrate and may therefore be an important source of nitrogen for scleractinian corals.     

Transport and metabolism of 1'-fluorosucrose, a sucrose analog not subject to invertase hydrolysis

The novel sucrose derivative 1′-fluorosucrose (α-d-glucopyranosyl-β- d-1-deoxy-1-fluorofructofuranoside) was synthesized in order to help define mechanisms of sucrose entry into plant cells. Replacement of the 1′-hydroxyl by fluorine very greatly reduces invertase hydrolysis of the derivative (hydrolysis at 10 millimolar 1′-fluorosucrose is less than 2% that of sucrose) but does not reduce recognition, binding, or transport of 1′-fluorosucrose by a sucrose carrier. Transport characteristics of 1′-fluorosucrose were studied in three different tissues. The derivative is transported by the sucrose carrier in the plasmalemma of developing soybean cotyledon protoplasts with a higher affinity than sucrose (K_m 1′-fluorosucrose 0.9 millimolar, K_m sucrose 2.0 millimolar). 1′-Fluorosucrose is a competitive inhibitor of sucrose uptake with an apparent K_i also of 0.9 millimolar, while the K_i of sucrose competition of 1′-fluorosucrose uptake was 2.0 millimolar. Thus, both sugars are recognized at the same binding site in the plasmalemma. Both sucrose and 1′-fluorosucrose show very similar patterns of phloem translocation from an abraded leaf surface through the petiole indicating that recognition of 1′-fluorosucrose by sucrose carriers involved in phloem loading is likely as well.     

Mechanisms of citrate transport and exchange in corn mitochondria

Previous work (Birnberg, Jayroe, Hanson 1982 Plant Physiol 70: 511-516) demonstrated that corn mitochondria (Zea mays L.) can accumulate citrate by a malate- and phosphate-independent proton symporter. This uptake and symport of other ions were investigated. Passive swelling experiments indicated that corn mitochondria can accumulate several other anions by proton symport, but only isocitrate is taken up nearly as effectively as citrate. At the optimal pH (4.5), active uptake of carrier-free [¹⁴C]citrate in 50 micromolar mersalyl is inhibited by fourteen anions, but only the I₅₀ (the concentration of inhibitor required to reduce uptake of carrier-free [¹⁴C]citrate by 50%) values of citrate (0.08 millimolar) and d-and l-isocitrate (0.5 millimolar) are less than 4 millimolar. Isocitrate is a competitive inhibitor of citrate uptake and [¹⁴C]isocitrate is accumulated with a K_m similar similar to its I₅₀. Valinomycin reduces net active citrate accumulation at pH 7.5, consistent with the relatively low V_max for citrate uptake. At pH 4.5, mersalyl reduces the rate of citrate uptake without changing the affinity of the carrier for citrate. Thus, the corn mitochondria have a high-affinity, mersalyl-insensitive carrier selective for citrate that also transports isocitrate.     

Uptake of L-leucine by Trout Red Blood Cells and Peripheral Lymphocytes

The uptake of l-leucine by trout red blood cells and peripheral lymphocytes has been analyzed. The present study shows two functionally different Na⁺-independent systems for apolar branched-chain amino acids. They are designated as L systems because they share some properties with the mammalian L system. The carrier present in red blood cells has low K _m values, is trans-stimulable and not stereospecific for leucine uptake; on the other hand, the system present in lymphocytes is stereospecific for leucine uptake and trans-inhibitable. Both carriers are pH sensitive in a similar fashion at low pHs, but there are important differences at higher pH values (above neutrality). These properties are compared with these of the asc systems previously reported in these cells. Received: 2 June 1995/Revised: 7 March 1996     

Sodium-dependent uptake of nitrate and urea by a marine diatom

Uptake of nitrate and urea by Phaeodactylum tricornutum is shown to be a sodium dependent process inhibited by lithium or potassium. The half-saturation constant for sodium (K_Na) was 2.6 mM for nitrate uptake and 71 mM for urea uptake. It is suggested that sodium dependent uptake mechanisms may be characteristic of marine plants.     

Modulation of an Active-Site Cysteine pKa Allows PDI to Act as a Catalyst of both Disulfide Bond Formation and Isomerization

Protein disulfide isomerase (PDI) plays a central role in disulfide bond formation in the endoplasmic reticulum. It is implicated both in disulfide bond formation and in disulfide bond reduction and isomerization. To be an efficient catalyst of all three reactions requires complex mechanisms. These include mechanisms to modulate the pK_a values of the active-site cysteines of PDI. Here, we examined the role of arginine 120 in modulating the pK_a values of these cysteines. We find that arginine 120 plays a significant role in modulating the pK_a of the C-terminal active-site cysteine in the a domain of PDI and plays a role in determining the reactivity of the N-terminal active-site cysteine but not via direct modulation of its pK_a. Mutation of arginine 120 and the corresponding residue, arginine 461, in the a′ domain severely reduces the ability of PDI to catalyze disulfide bond formation and reduction but enhances the ability to catalyze disulfide bond isomerization due to the formation of more stable PDI-substrate mixed disulfides. These results suggest that the modulation of pK_a of the C-terminal active cysteine by the movement of the side chain of these arginine residues into the active-site locales has evolved to allow PDI to efficiently catalyze both oxidation and isomerization reactions.     

An algebraic model for the kinetics of covalent enzyme inhibition at low substrate concentrations

This article describes an integrated rate equation for the time course of covalent enzyme inhibition under the conditions where the substrate concentration is significantly lower than the corresponding Michaelis constant, for example, in the Omnia assays of epidermal growth factor receptor (EGFR) kinase. The newly described method is applicable to experimental conditions where the enzyme concentration is significantly lower than the dissociation constant of the initially formed reversible enzyme–inhibitor complex (no “tight binding”). A detailed comparison with the traditionally used rate equation for covalent inhibition is presented. The two methods produce approximately identical values of the first-order inactivation rate constant (k_inact). However, the inhibition constant (K_i), and therefore also the second-order inactivation rate constant k_inact/K_i, is underestimated by the traditional method by up to an order of magnitude.