Sequential ordered mechanism for the sodium-glutamate transport in intestinal brush border membrane vesicles

The kinetic mechanism of the glutamate-aspartate carrier in rat intestinal brush-border membrane vesicles: the role of potassium

The sodium dependent transport system for L-glutamate and L-aspartate localized in the apical part of rat enterocytes has previously been kinetically characterized (Prezioso, G., and Scalera, V. (1996). Biochim. Biophys. Acta 1279, 144-148). In this paper the mechanism by which the potassium cation specifically activates the L-glutamate-sodium cotransport process is investigated. Potassium has been found to act as an activator when it is present inside the membrane vesicles, while its presence outside is ineffective, and the effect is saturable. The kinetic parameters with respect to sodium and glutamate have been compared in the presence and in the absence of the activator. The results indicate that the ordered sodium-sodium glutamate mechanism is not altered by potassium, and that the activation is probably exerted on both the rate determining steps of the transport process. It is proposed that (1) a specific binding site for potassium is present on the inside hydrophilic part of the membrane carrier, (2) the binding of the effector accelerates the intramembrane rearrangement steps of both the disodium glutamate-carrier complex and the free carrier, (3) the affinity of the carrier is lowered with respect to sodium whereas it is increased for glutamate, and (4) K+ antiport is not performed by this carrier.

EAAT1 is involved in transport of L-glutamate during differentiation of the Caco-2 cell line

Little is known concerning the expression of amino acid transporters during intestinal epithelial cell differentiation. The transport mechanism of L-glutamate and its regulation during the differentiation process were investigated using the human intestinal Caco-2 cell line. Kinetic studies demonstrated the presence of a single, high-affinity, D-aspartate-sensitive L-glutamate transport system in both confluent and fully differentiated Caco-2 cells. This transport was clearly Na(+) dependent, with a Hill coefficient of 2. 9 +/- 0.3, suggesting a 3 Na(+)-to-1 glutamate stoichiometry and corresponding to the well-characterized X(A,G)(-) system. The excitatory amino acid transporter (EAAT)1 transcript was consistently expressed in the Caco-2 cell line, whereas the epithelial and neuronal EAAT3 transporter was barely detected. In contrast with systems B(0) and y(+), which have previously been reported to be downregulated when Caco-2 cells stop proliferating, L-glutamate transport capacity was found to increase steadily between day 8 and day 17. This increase was correlated with the level of EAAT1 mRNA, which might reflect an increase in EAAT1 gene transcription and/or stabilization of the EAAT1 transcript.

Mechanism of the inhibitory effect of imipramine on the Na+-dependent transport of L-glutamic acid in rat intestinal brush-border membrane

The mechanism of the inhibitory effect of imipramine, a lipophilic organic cation on the Na+-dependent transport of L-glutamic acid across intestinal brush-border membrane was investigated. The uptake of L-glutamic acid by intestinal brush-border membrane vesicles was dependent on the concentration of Na+. Fitting of the uptake data in the presence of various concentrations of Na+ using Hill equation yielded a Hill coefficient of 2.18. This result suggest that the carrier system of L-glutamic acid has at least two sites for Na+-binding. By the analysis of double reciprocal plot and Dixon-type plot, it was found that imipramine inhibits the transport of L-glutamic acid by interacting competitively with the binding sites of Na+, but not inhibit L-glutamic acid binding site. Moreover, the effect of imipramine on the transport of L-alanine and D-glucose which are co-transported with only one Na+ molecule was also suggestive of interaction with the Na+-binding sites on the carrier. These results indicate that the mechanism of the inhibitory effect of imipramine on the Na+-dependent carrier systems is common for all systems regardless of the stoichiometry or substrates.

Sodium-dependent and -independent transport of L-glutamate in the rat intestinal crypt-like cell line IEC-17

Mechanisms of L-glutamate transport in intestinal crypts were investigated using the rat intestinal crypt-like cell line IEC-17. Kinetic analysis and competition experiments run in the presence or in the absence of extracellular sodium indicate that L-glutamate uptake occurs through three different transport components: (1) a high affinity Na+-independent component also carrying cystine, similar to system x(c)-; (2) a high affinity Na+-dependent component inhibited by D- and L-aspartate corresponding to the ubiquitous system X(A,G)-; and (3) a low affinity Na+-dependent system resembling the neutral amino acid transport system ASC. The simultaneous presence of these three components suggest that crypt cells are ready to face potential high variations of L-glutamate concentration in the intestinal villus environment.