Leucine methyl ester is a powerful allosteric activator of the neutral amino acid cotransport system in Bombyx mori larval midgut.

We have identified three methyl esters that have a potent stimulatory effect on the cotransport system responsible for the absorption of most essential amino acids in the silkworm Bombyx mori. L-Leucine methyl ester, the most powerful activator, determined a large dose-dependent, K(+)-independent increase of leucine uptake into midgut brush border membrane vesicles. Kinetic experiments revealed non-essential mixed-type activation, with K(a) values of 27+/-2 and 47+/-8 microM in the presence and in the absence of K(+), respectively. The activation increased K(m) twofold, and V(max) up to 18-fold depending upon the experimental conditions. Leucine uptake mediated by the amino acid uniport appears to be unaffected by the activator.

Leucine transport in membrane vesicles from Chironomus riparius larvae displays a mélange of crown-group features.

Leucine uptake into membrane vesicles from larvae of the midge Chironomus riparius was studied. The membrane preparation was highly enriched in typical brush border membrane enzymes and depleted of other membrane contaminants. In the absence of cations, there was a stereospecific uptake of l-leucine, which exhibited saturation kinetics. Parameters were determined both at neutral (Km 33 +/- 5 microM and Vmax 22.6 +/- 6.8 pmol/7s/mg protein) and alkaline (Km 46 +/- 5 microM and Vmax 15.5 +/- 2.5 pmol/7s/mg protein) pH values. At alkaline pH, external sodium increased the affinity for leucine (Km 17 +/- 1 microM) and the maximal uptake rate (Vmax 74.0 +/- 12.5 pmol/7s/mg protein). Stimulation of leucine uptake by external alkaline pH agreed with lumen pH measurements in vivo. Competition experiments indicated that at alkaline pH, the transport system readily accepts most L-amino acids, including branched, unbranched, and alpha-methylated amino acids, histidine and lysine, but has a low affinity for phenylalanine, beta-amino acids, and N-methylated amino acids. At neutral pH, the transport has a decreased affinity for lysine, glycine, and alpha-methylleucine. Taken together, these data are consistent with the presence in midges of two distinct leucine transport systems, which combine characters of the lepidopteran amino acid transport system and of the sodium-dependent system from lower neopterans.

Substrate specificity of the brush border K+-leucine symport of Bombyx mori larval midgut.

L-leucine uptake into membrane vesicles from Bombyx mori larval midgut was tested for inhibition by 55 compounds, which included sugars, N-methylated, alpha-, beta-, gamma-, delta-, epsilon-amino acids, primary amines, alpha-amino alcohols, monocarboxylic organic acids and alpha-ketoacids. Based on cis-inhibition experiments performed at the high pH (10.8) characteristic of the midgut luminal content in vivo, we find that the carrier binding site interacts with molecules which possess a well-defined set of structural features. Amino acids are preferentially accepted as anions and the ideal inhibitor must have an hydrophobic region and a polar head constituted by a chiral carbon atom bearing two hydrophilic groups, a deprotonated amino-group and a dissociated carboxylic group. Binding is reduced if one of the two hydrophilic groups is removed. Lowering the pH to less alkaline value (8.8) only affects the affinity of delta- and epsilon-amino acids, which are excluded from binding because of their positively charged side-chain. Modifications of the potassium electrochemical gradient increased the affinity constant values of the molecules, but have little effect on the rank of specificity. Physiological implications of the data reported are discussed.

Interaction of the insecticidal crystal protein CryIA from Bacillus thuringiensis with amino acid transport into brush border membranes from Bombyx mori larval midgut.

The activities of three related Bacillus thuringiensis delta-endotoxins, designated CryIA(a), CryIA(b), and CryIA(c), as inhibitors of K(+)-dependent amino acid transport into membrane vesicles prepared from the anterior and posterior portions of Bombyx mori larval midgut were measured. Under experimental conditions similar to those occurring in vivo (membrane potential approximately -100 mV, inside negative; pH 7.2in/8.8out; an inwardly directed K+ gradient) CryIA(a) toxin produced a clear dose-dependent inhibitory effect on leucine uptake by both the anterior and the posterior gut membrane vesicles, giving half-maximal inhibition constants (IC50) of 2.6 +/- 0.3 and 2.1 +/- 0.2 microgram toxin/mg membrane protein, respectively. The other two delta-endotoxins were practically inactive. A dose-dependent inhibition of amino acid transport by CryIA(a) toxin was also observed on the carrier-mediated K(+)-independent component, i.e., the leucine-only form. This result strongly indicates that the activity of the K+/amino acid cotransporter is directly affected after binding of delta-endotoxin to the brush border membrane. When the extravesicular pH was lowered to pH 7.2, the interaction of CryIA(a) toxin with the brush border appeared more complex, as suggested by the Hill coefficient of the dose-response curves higher than 1. In conclusion, our data indicate that (i) CryIA(a) toxin specifically inhibited K+/leucine symport along the length of the midgut; (ii) the interaction between cotransporters and toxin is affected by the pH of the medium; and (iii) the K+/leucine cotransporter or a strictly associated protein may serve as membrane receptor for CryIA(a) delta-endotoxin in the B. mori larval midgut.

Effect of arginine modification on K(+)-dependent leucine uptake in brush-border membrane vesicles from the midgut of Philosamia cynthia larvae.

The effect of phenylglyoxylation on the midgut K(+)-dependent leucine transport was studied using lepidopteran brush-border membrane vesicles. The inhibition of leucine uptake by phenylglyoxal (PGO) showed a biphasic inactivation pattern. The second-order rate constant for the slow and fast phases were 0.0020 mM-1 min-1 and 0.0091 mM-1 min-1, respectively. However, substitution of borate buffer for Hepes-Tris buffer produced a mono-exponential inactivation pattern, suggesting modification of a single arginine group. The effect of PGO was dose-dependent and the concentration causing half-maximal inhibition of leucine uptake was 5.1 +/- 0.3 mM. Leucine transport was significantly inhibited also in the absence of a potassium electrochemical gradient (i.e., [K+]in = [K+]out = 100 mM), suggesting that inhibition was not related to a decrease in the driving force. Moreover, intravesicular volume remained unchanged after preincubation with PGO. Kinetic analysis of the interaction of PGO with the leucine cotransporter revealed that (i) inhibition was related to a decrease in the Vmax value and (ii) neither leucine nor K+ were able to prevent the inhibition. Our results suggest an important role for arginine residues in the molecular mechanism of K+/leucine cotransport in lepidopteran larvae midgut.

A rapid and sensitive in vitro assay for the activity of Bacillus thuringiensis delta-endotoxins.

1. Activated delta-endotoxins from Bacillus thuringiensis strains toxic to lepidopteran larvae inhibit K(+)-dependent accumulation of amino acids into brush border membrane vesicles (BBMV) from the midgut of the susceptible species Bombyx mori. 2. The activated toxins interfere with the K(+)-dependent uptake of histidine into BBMV only if they are effectively active in vivo. 3. To calculate IC50 values (the toxin concentration which determines 50% of the effect), dose-response curves were performed for each toxin. The values obtained correlate well with the LD50 determined by bioassay. 4. This amino acid inhibition test could represent a rapid (3-6 hr, compared to 3-4 days for bioassay) and sensitive method for the screening of larvicidal activity of known or new recombinant delta-endotoxins.

Kinetics of leucine transport in brush border membrane vesicles from lepidopteran larvae midgut.

The kinetics of K(+)-leucine cotransport in the midgut of lepidopteran larvae was investigated using brush border membrane vesicles. Initial rate (3 s) of leucine uptake was determined under experimental conditions similar to those occurring in vivo, i.e. in the presence of delta psi much greater than 0 (inside negative) and a delta pH of 1.4 units (7.4in/8.8out). Leucine and K+ bind to the carrier according to a sequential mechanism, and the binding of one substrate changed the dissociation constant for the other substrate by a factor of 0.15. Both trans-K+ and trans-leucine were mixed-type inhibitors of leucine uptake. Moreover, a portion of total leucine uptake was K+ independent, and it was competitively inhibited by trans-leucine. We interpret the trans inhibitory effects to mean that the partially loaded K+ only form is virtually unable to translocate across the membrane, whereas the binary complex carrier, leucine, can isomerize from the trans to the cis side of the membrane. However, the K(+)-independent leucine uptake occurs with a Keq greater than 1, i.e. the efflux route through the partially loaded leucine only form is slower than the rate of isomerization of the unloaded carrier from trans to cis side. Taken together, these results suggest a model in which transport occurs by an iso-random Bi Bi system. Since K+ does not act as a pure competitive activator, this model is different from that proposed for most of the Na(+)-linked solutes transport agencies and may be related to the broadening of the cation specificity of the amino acid transporters in lepidopteran larvae.

Effect of amiloride analogues on sodium transport in renal brush border membrane vesicles from Milan hypertensive rats.

The effect of ethylisopropyl-amiloride (EIPA) and phenamil on sodium uptake in renal brush border membrane vesicles from prehypertensive rats of the Milan strain (MHS) and their normotensive controls (MNS) was investigated. In the presence of both a membrane potential and a pH gradient a differential effect of EIPA and phenamil was evidenced between the two rat strains. In the absence of a pH gradient, but in the presence of a membrane potential, EIPA was about two-fold more potent than phenamil in inhibiting sodium transport in both rat strains, excluding the presence of epithelial sodium channels in our BBMV preparations. Taken together these results support the hypothesis that a structurally different Na+/H+ exchanger located on the brush border membrane may be involved in the increased tubular sodium reabsorption observed in vivo in hypertensive rats.

In vitro effect of ethanol on sodium and glucose transport in rabbit renal brush border membrane vesicles.

The effect of ethanol on sodium and glucose transport in rabbit renal brush border membrane vesicles was examined. When membrane vesicles were preincubated in the presence of ethanol the sodium-dependent D-glucose uptake was significantly inhibited. This effect, as suggested by O'Neill et al. (1986) FEBS Lett. 194, 183-188, may be due to a faster collapse of the Na+ gradient. As a matter of fact, the amiloride-insensitive sodium pathway was increased by ethanol in our brush border membrane preparation. However, sodium/D-glucose cotransport was inhibited by ethanol, although to a lesser degree, also in the absence of a sodium gradient. In addition, ethanol inhibited glucose-dependent sodium uptake, suggesting that a direct interaction with the translocator was involved. This conclusion was also supported by kinetic measurements showing a decrease of Vmax and an increase in Km for glucose in membrane vesicles treated with ethanol. Moreover, ethanol influenced the interaction of phlorizin with the cotransporter: uptake experiments performed in the presence of the two inhibitors demonstrated that phlorizin and ethanol behave as not mutually exclusive inhibitors of D-glucose transport. These data indicate that in rabbit renal brush border membranes ethanol not only affects the 'passive pathway', i.e. the sodium permeability, but it also directly interferes with carrier functions.

Increased Na pump activity in the kidney cortex of the Milan hypertensive rat strain.

The (Na+,K+)-ATPase activity from the kidney cortex of the Milan hypertensive rat strain (MHS) and the corresponding normotensive control (MNS) was measured both in active solubilized enzyme preparations and in isolated basolateral membrane vesicles. Kinetic analysis of the purified enzyme showed that the Vmax value was significantly higher in MHS rats. The difference between MHS and MNS was not linked to a different number of sodium pumps, but was related to the molecular activity of the enzyme. Using basolateral membrane vesicles, an increased ATP-dependent ouabain-sensitive sodium transport was also demonstrated in MHS rats. These results support the hypothesis that a higher tubular sodium reabsorption may be involved in the pathogenesis of hypertension in this rat strain.

Amino acid transport systems in intestinal brush-border membranes from lepidopteran larvae.

Experiments with intestinal brush-border membrane vesicles from lepidopteran larvae disclosed the occurrence of unique cotransporter proteins that use K+ as the driver cation for the transmembrane transfer of amino acids across the luminal border of midgut enterocytes. Six apical membrane amino acid transport systems have been identified. These systems are 1) a neutral amino acid transporter with a broad spectrum of interactions with most neutral amino acids, which is highly concentrative, strongly K+- and electrical potential-dependent, poorly stereospecific, and recognizes histidine, but not proline, glycine, or alpha-(methylamino)isobutyric acid (MeAIB); 2) a specific system for L-proline; 3) a specific system for glycine with a higher affinity for Na+ than for K+; 4) a specific system for L-lysine, which is dependent on membrane potential, is highly sensitive to external K+, and does not interact with L-arginine or neutral amino acids; 5) a specific K+-dependent process for glutamic acid, which does not recognize aspartic acid; and last, 6) an apparently unique K+- driven mechanism for D-alanine, which is potential-dependent and strongly stereospecific.

A new implemented version of program MIR (MIR II): analysis and identification of mathematical models in enzyme and transport kinetic studies.

The computer program MIR previously described (R. Bianchi, G.M. Hanozet and M. Pilone Simonetta, Comput. Prog. Biomed. 16 (1983) 189) that fits trial rate laws to enzyme and transport steady-state kinetic data by the least-squares method has been enhanced. The new version MIR II is an interactive program and it consists of five major routines and a larger number of smaller program elements to perform the linear (three different functional forms) and non-linear (eleven mathematical models) regression analysis of kinetic data from enzyme and transmembrane transport experiments, also in the presence of inhibitors. Other features of the new program include a set of statistics and tests useful for the model building process, for the development of the mathematical model and for its validation and maintenance. An algorithm for fitting a straight line taking into account errors in both x and y is also provided.

Sodium and glucose transport across renal brush border membranes of Milan hypertensive rats.

Sodium transport across luminal membranes of proximal tubules isolated from the kidney cortex of young, prehypertensive rats of the Milan hypertensive strain (MHS) and their corresponding normotensive controls, the Milan normotensive strain (MNS), was measured. A higher sodium uptake was observed in vesicles from MHS, although membrane preparations from both strains behaved similarly as far as enzyme profile and sodium-dependent glucose transport were concerned. In the presence of an inwardly directed sodium gradient, sodium uptake depended on the relative permeability of the counterion: in the presence of 100 mM NaCl, sodium transport in MHS was 26% higher than that in normotensive controls (p less than 0.05). Also, a significantly faster sodium uptake by membrane vesicles from MHS was observed when a pH gradient and an electrical potential difference (inside-negative) were imposed across the membrane. In this condition, sodium uptake by membrane vesicles from MHS was up to 39% higher than that in control MNS (p less than 0.01). Therefore, the difference in sodium transport observed between preparations of luminal membrane from the proximal tubule of MNS and MHS seems to be due to a higher rheogenic sodium pathway in the MHS. The present results are in keeping with previous data showing an increased sodium transport across renal tubules of the MHS and support the hypothesis that the abnormality in sodium and water handling by kidneys from MHS can be related to an alteration in sodium transport across the luminal membrane of the proximal tubule cells.

Steady-state kinetic analysis of isocitrate lyase from Lupinus seeds: considerations on a possible catalytic mechanism of isocitrate lyase from plants.

Isocitrate lyase catalyzes the reversible cleavage of isocitrate into glyoxylate and succinate. The kinetic mechanism of bacterial isocitrate lyase has been reported to be ordered uni-bi. Moreover, it has been proposed that isocitrate lyase in higher plants may be switched on and off by a succinylation/desuccinylation mechanism. Similarly to bacterial citrate lyase, in which an acetylation/deacetylation mechanism is operative, succinylation might also play a role in the catalytic mechanism of plant isocitrate lyase. We have investigated the kinetic mechanism of isocitrate lyase from Lupinus seeds. The results reported in this paper show that the system follows a preferentially ordered uni-bi pathway in which the succinate is released first. On the basis of our results and some other recently reported data, we conclude that it is unlikely that bacterial and plant isocitrate lyases have different catalytic mechanisms.

Inactivation and degradation of yeast glucose-6-phosphate dehydrogenase selectively modified by pyridoxal-5-phosphate.

Modification by pyridoxal-5-phosphate of glucose-6-phosphate dehydrogenase (EC 1.1.1.49) purified from Saccharomyces cerevisiae produces an inactivation effect, partially reversible by dilution in the presence of substrates. Spectroscopic analysis of the enzyme pyridoxal-5-phosphate complex reduced with NaBH4 provides the values expected for the binding of the aldehydic group to Lys residue. One Lys residue appears to be responsible for the observed enzyme inactivation, and the presence of the phosphate group is required for the effect. Besides the change of activity, the binding of pyridoxal-5-phosphate to the enzyme causes an increase in susceptibility to degradation by the intracellular yeast proteinase A at pH 7.6.

Presence of a potential-sensitive Na+ transport across renal brush-border membrane vesicles from rats of the Milan hypertensive strain.

Sodium transport was measured in brush-border membrane vesicles prepared from kidney cortex of the Milan hypertensive strain (MHS) rats and the corresponding normotensive controls. In the presence of an outwardly directed proton gradient, 22Na was transiently accumulated in the vesicles. When a transmembrane electrical potential was imposed across membrane vesicles, both the accumulation ratio and the initial uptake were increased, indicating the presence of an electrogenic pathway for sodium in these membranes. The potential-dependent sodium uptake was significantly higher in MHS rats. Kinetic analysis give simple Michaelis Menten curves in the presence and in the absence of a membrane potential. In both conditions Jmax was significantly increased in MHS rats, whereas Km was the same for the two rat strains. Sodium uptake was inhibited by amiloride at concentrations that inhibit Na+-H+ exchange. The presence of the higher, potential-sensitive, sodium uptake in MHS is in agreement with studies on renal physiology which support the hypothesis that an increase in tubular sodium reabsorption may be the primary cause for the development of hypertension in this rat strain.

Purification of phosphoenolpyruvate carboxykinase from Saccharomyces cerevisiae and its use for bicarbonate assay.

Electrophoretically homogeneous phosphoenolpyruvate carboxykinase (EC 4.1.1.49) from Saccharomyces cerevisiae was obtained in high yields by means of a two-step purification procedure consisting of ion-exchange chromatography and affinity chromatography on adenosine 5'-monophosphate-Sepharose 4B. In the latter step the binding of the enzyme to the resin specifically required the presence of Mn2+. The enzyme was eluted when Mn2+ was removed by addition of ethylenediaminetetraacetate to the elution buffer. Homogeneity, molecular weight, and subunit composition of phosphoenolpyruvate carboxykinase were checked by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and gel filtration. A factor which caused an underestimation of the enzyme activity in crude extracts was identified as adenylate kinase. Finally, a method is proposed for the enzymatic assay of bicarbonate using a purified phosphoenolpyruvate carboxykinase preparation.

L- and D-alanine transport in brush border membrane vesicles from lepidopteran midgut: evidence for two transport systems.

In brush border membrane vesicles from the midgut of Philosamia cynthia larvae (Lepidoptera) the L- and D-alanine uptake is dependent on a potassium gradient and on transmembrane electrical potential difference. Each isomer inhibits the uptake of the other form: inhibition of L-alanine uptake by D-alanine is competitive, whereas inhibition of D-alanine uptake by L-alanine is noncompetitive. Transstimulation experiments as well as the different pattern of specificity to cations suggest the existence of two transport systems. Kinetic parameters for the two transporters have been calculated both when Kout greater than Kin and Kout = Kin. D-alanine is actively transported also by the whole midgut, but it is not metabolized by the intestinal tissue.

MIR: a versatile program for the statistical analysis of enzyme kinetic data.

We have developed a package program for the estimation of Michaelis-Menten parameters for enzymes that conform to different kinetic mechanisms. Data from different experimental schemes can be fitted with appropriate weighing factors to any of 6 mathematical models, corresponding to 5 kinetic mechanisms: ordered bi-bi, Theorell-Chance, rapid equilibrium random bi-bi, rapid equilibrium ordered bi-bi and ping pong bi-bi. The program also performs a significance test to discriminate between different candidate models. To illustrate the performance of the program, real data from kinetic experiments with glucose 6-phosphate from Leuconostoc mesenteroides have been fitted to different mathematical models, and the results are discussed. The program can be easily implemented for the fitting of kinetic data to any other model.