The mechanism of Na+-L-lactate cotransport by brush border membrane vesicles from horse kidney: analysis of rapid equilibrium kinetics in absence of membrane potential

Critical transporters of methionine and methionine hydroxyl analogue supplements across the intestine: What we know so far and what can be learned to advance animal nutrition

DL-methionine (DL-Met) and its analogue DL-2-hydroxy-4-(methylthio) butanoic acid (DL-methionine hydroxyl analogue or DL-MHA) have been used as nutritional supplements in the diets of farmed raised animals. Knowledge of the intestinal transport mechanisms involved in these products is important for developing dietary strategies. This review provides updated information of the expression, function, and transport kinetics in the intestine of known Met-linked transporters along with putative MHA-linked transporters. As a neutral amino acid (AA), the transport of DL-Met is facilitated by multiple apical sodium-dependent/-independent high-/low-affinity transporters such as ASCT2, B⁰AT1 and rBAT/b^0,+AT. The basolateral transport largely relies on the rate-limiting uniporter LAT4, while the presence of the basolateral antiporter y⁺LAT1 is probably necessary for exchanging intracellular cationic AAs and Met in the blood. In contrast, the intestinal transport kinetics of DL-MHA have been scarcely studied. DL-MHA transport is generally accepted to be mediated simply by the proton-dependent monocarboxylate transporter MCT1. However, in-depth mechanistic studies have indicated that DL-MHA transport is also achieved through apical sodium monocarboxylate transporters (SMCTs). In any case, reliance on either a proton or sodium gradient would thus require energy input for both Met and MHA transport. This expanding knowledge of the specific transporters involved now allows us to assess the effect of dietary ingredients on the expression and function of these transporters. Potentially, the resulting information could be furthered with selective breeding to reduce overall feed costs.

Na+-dependent transport of pyruvate in erythrocytes of the Pacific hagfish (Eptatretus stouti)

We investigated the mechanisms of pyruvate transport in the erythrocytes of an ancient marine agnathan, the Pacific hagfish (Eptatretus stouti), and a sedentary euryhaline teleost, the starry flounder (Platichthys stellatus). Uptake of [14C]pyruvate (50 µM, 10°C) by flounder erythrocytes was slow (t1/2 (half-life) ~ 30 min), nonconcentrative, and mediated by the band 3 Cl-/HCO-3 exchanger in combination with a process similar to the H+/monocarboxylate symporter present in freshwater teleosts and mammalian erythrocytes. In contrast, pyruvate uptake by hagfish erythrocytes (50 µM, 10°C) was rapid (t1/2 ~ 1.5 min) and, in 10 min, reached an intracellular concentration more than 20-fold higher than that present in the extracellular medium. Pyruvate accounted for almost 90% of the accumulated intracellular radioactivity, the remaining label being incorporated into tricarboxylic acid cycle intermediates and glutamate. Influx of pyruvate was saturable (apparent Km = 12 mM) and inhibited by p-chloromercuriphenylsulphonate (PCMBS) (Ki = 71 µM) and 4,4'-diisothiocyanatostilbene-2,2'-disulphonate (DIDS) (Ki = 0.49 mM). Transport was inhibited poorly by α-cyano-4-hydroxycinnamate (CIN) (Ki > 4 mM) and was not coupled to the movement of protons. Instead, the influx of pyruvate was Na+ dependent. A sigmoidal relationship between pyruvate transport and extracellular Na+ concentration was observed, suggesting a Na+:pyruvate coupling ratio greater than 1:1. In contrast with previously described Na+-dependent monocarboxylate transport activities in mammalian renal and intestinal epithelia, the hagfish erythrocyte system did not transport lactate.

Lactate transport in L6 skeletal muscle cells and vesicles: allosteric or multisite mechanism and functional membrane marker of differentiation

Membrane lactate transport was studied in skeletal muscle cells and membrane vesicles from the L6 line in relation to in vitro myogenesis. In myoblasts, lactate was transported by simple diffusion and insensitive to classical inhibitors: a positive correlation between onset of creatine kinase activity and lactate transport in differentiated myotubes was observed and could be considered to be a functional marker of cell differentiation. In myotubes, complete analysis of the velocity curves (direct coordinates, Eadie-Scatchard plots, Hill plots) gave parameters showing that lactate was carried by an allosteric or multisite system. This was confirmed by using sarcolemmal vesicles and specific inhibitors. In whole cells, alpha-cyano-4-hydroxycinnamic acid (CIN) and parachloromercuribenzylsulphonic acid (pCMBS) inhibited the maximal velocity without modifying the global cooperativity of the system. The weak effect of 4,4'-diisothiocyanostilbene-2,2'-disulphonic acid (DIDS), which has a low affinity constant (Ki = 22.5 microM), implicated the monocarboxylate system rather than the anionic exchanger as a carrier system in muscle cells. CIN and DIDS exhibited one type of interaction with lactate carriers, and the curvilinear shape of the lactate Hill plot with or without inhibitors suggested that inhibitors were active at the same family of interaction sites and had a common range of affinities. The apparent competitive inhibition of pyruvate (Ki = 3.2 mM) did not modify the transport pathway of lactate in L6 myotubes. In conclusion, kinetic analysis of lactate transport in the presence or absence of inhibitors gave evidence for a multisite lactate carrier activity in myotubes composed of two systems at least, related to two or three isoforms of lactate carriers.

Characterization of sodium and pyruvate interactions of the two carrier systems specific of mono- and di- or tricarboxylic acids by renal brush-border membrane vesicles

The experiments reported in this paper aim at characterizing the carboxylic acid transport, the interactions of pyruvate and citrate with their transport sites and specificity. The study of these carriers was performed using isotopic solutes for the influx measurements in brush-border membrane vesicles under zero trans conditions where the membrane potential was abolished with KCl preloading with valinomycin or equilibrium exchange conditions and delta psi = 0. Under zero trans condition and delta psi = 0, the influence of pyruvate concentrations on its initial rates of transport revealed the existence of two families of pyruvate transport sites, one with a high affinity for pyruvate (Kt = 88 microM) and a low affinity for sodium (Kt = 57.7 mM) (site I), the second one with a low affinity for pyruvate (Kt = 6.1 mM) and a high affinity for sodium (Kt = 23.9 mM) (site II). The coupling factor [Na]/[pyruvate] stoichiometry were determined at 0.25 mM and 8 mM pyruvate and estimated at 1.8 for site I, and 3 when the first and the second sites transport simultaneously. Under chemical equilibrium (delta psi congruent to 0) single isotopic labeling, transport kinetics of pyruvate carrier systems have shown a double interaction of pyruvate with the transporter; the sodium/pyruvate stoichiometry also expressed according to a Hill plot representation was n = 1.7. The direct method of measuring Na+/pyruvate stoichiometry from double labeling kinetics and isotopic exchange, for a time course, gives a n = 1.67. Studies of transport specificity, indicate that the absence of inhibition of lactate transport by citrate and the existence of competitive inhibition of lactate and citrate transports by pyruvate leads to the conclusion that the low pyruvate affinity site can be attributed to the citrate carrier (tricarboxylate) and the high pyruvate affinity site to the lactate carrier (monocarboxylate).

Acetate transport in the S3 segment of the rabbit proximal tubule and its effect on intracellular pH

We monitored intracellular pH (pHi) in isolated perfused S3 segments of the rabbit proximal tubule, and studied the effect of acetate (Ac-) transport on pHi. pHi was calculated from the absorbance spectrum of 4',5'-dimethyl-5-(and 6) carboxyfluorescein trapped intracellularly. All solutions were nominally HCO3(-)-free. Removal of 10 mM Ac- from bath and lumen caused pHi to rapidly rise by approximately 0.2, and then to decline more slowly to a value approximately 0.35 below the initial one. Removal of only luminal Ac- caused pHi changes very similar to those resulting from bilateral removal of Ac-. When Ac- was removed from bath only, pHi rose rapidly at first, and then continued to rise more slowly. Readdition of Ac- to bath caused pHi to rapidly fall to a value slightly higher than the one prevailing before the removal of Ac- from the bath. In experiments in which Ac- was first removed from both bath and lumen, readdition of 10 mM Ac- to only lumen caused a rapid but small acidification, followed by a slower alkalinization that brought the pHi near the value that prevailed before the bilateral removal of Ac-. The alkalinizing effects caused by the readdition of 10 or 0.5 mM Ac- were indistinguishable. When Ac- was returned to only lumen in the absence of luminal Na+, there was a small and rapid pHi decrease, but no pHi recovery. Removal of Na+ from bath did not affect the pHi transients caused by the addition of Ac- to lumen. In experiments in which Ac- was first removed bilaterally, readdition of Ac- to only bath caused a large and sustained drop in pHi, whereas the subsequent removal of Ac- from the bath caused a slight alkalinization. These pHi changes caused by readdition or removal of Ac- from baths were unaffected by the absence of external Na+. We conclude that there is a Na+/Ac- cotransporter at the luminal membrane, and pathways for acetic acid transport at both luminal and basolateral membranes. The net effect of Ac- transport on pHi is to alkalinize the cell as a result of the luminal entry of Na+/Ac-, which is followed by the luminal and basolateral exit of acetic acid.

The kinetics of transport of lactate and pyruvate into rat hepatocytes. Evidence for the presence of a specific carrier similar to that in erythrocytes

Time courses of L-lactate and pyruvate uptake into isolated rat hepatocytes were measured in a citrate-based medium to generate a pH gradient (alkaline inside), by using the silicone-oil-filtration technique at 0 degrees C to minimize metabolism. At low concentrations of lactate and pyruvate (0.5 mM), transport was inhibited by over 95% by 5 mM-alpha-cyano-4-hydroxycinnamate, whereas at higher concentrations (greater than 10 mM) a significant proportion of transport could not be inhibited. The rate of this non-inhibitable transport was linearly related to the substrate concentration, was less with pyruvate than with L-lactate, and appeared to be due to diffusion of undissociated acid. Uptake of D-lactate was not inhibited by alpha-cyano-4-hydroxycinnamate and occurred only by diffusion. Kinetic parameters for the carrier-mediated transport process were obtained after correction of the initial rates of uptake of lactate and pyruvate in the absence of 5 mM-alpha-cyano-4-hydroxycinnamate by that in the presence of inhibitor. Under the conditions used, the Km values for L-lactate and pyruvate were 2.4 and 0.6 mM respectively and the Ki for alpha-cyano-4-hydroxycinnamate as a competitive inhibitor was 0.11 mM. Km values for the transport of L-lactate and pyruvate into rat erythrocytes under similar conditions were 3.0 and 0.96 mM. The Vmax. of lactate and pyruvate transport into hepatocytes at 0 degrees C was 3 nmol/min per mg of protein. Carrier-mediated transport of 0.5 mM-L-lactate was inhibited by 0.2 mM-p-chloromercuribenzenesulphonate (greater than 90%), 0.5 mM-quercetin (80%), 0.6 mM-isobutylcarbonyl-lactyl anhydride (70%) and 0.5 mM-4,4'-di-isothiocyanostilbene-2,2'-disulphonate (50%). A similar pattern of inhibition of lactate transport is seen in erythrocytes. It is suggested that the same or a similar carrier protein exists in both tissues. The results also show that L-lactate transport into rat hepatocytes is very rapid at physiological temperatures and is unlikely to restrict the rate of its metabolism. Differences between our results and those of Fafournoux, Demigne & Remesy [(1985) J. Biol. Chem. 260, 292-299] are discussed.

Mechanisms of uptake of ketone bodies by luminal-membrane vesicles

The energetics and location of renal transport of acetoacetate, beta-hydroxybutyrate, alpha-hydroxybutyrate and gamma-hydroxybutyrate by luminal-membrane vesicles from either whole cortex or pars convoluta or pars recta of rabbit proximal tubule were studied. Addition of either acetoacetate or beta-hydroxybutyrate or its analogues to dye-membrane-vesicle suspensions in the presence of Na+ gradient (extravesicular greater than intravesicular) resulted in absorbance changes indicative of depolarizing event(s). Valinomycin enhanced the Na+-dependent uptake of monocarboxylic acids, provided a K+ gradient (intravesicular greater than extravesicular) was present. By contrast, Na+-dependent uptake of these compounds was nearly abolished by ionophores that permit Na+ to pass through the luminal-membrane via another channel, either electrogenically (e.g. gramicidin D) or electroneutrally (e.g. nigericin). These results established that the Na+-dependent transport of ketone bodies and analogues by luminal-membrane vesicles is an electrogenic process. Eadie-Hofstee analysis of saturation kinetic data suggested the presence of multiple transport systems in vesicles from whole cortex for these compounds. Tubular localization of the transport systems was studied by the use of vesicles derived from pars convoluta and pars recta. In pars recta uptake of all these compounds was mediated by means of a single high affinity common transport system. Uptake of these compounds by vesicles from pars convoluta was carried out via a relatively low affinity but common transport system. The physiological importance of the transport systems is discussed.

Renal transport of monocarboxylic acids. Heterogeneity of lactate-transport systems along the proximal tubule

The characteristics of D- and L-lactate transport in luminal-membrane vesicles derived from whole cortex, from the pars convoluta and from the pars recta of rabbit kidney proximal tubule were studied. It was found that uptake of both isomers in vesicles from whole cortex occurred by means of dual electrogenic transport systems, namely a low-affinity system and a high-affinity system. Uptake of both isomers in vesicles from the pars recta was strictly Na+-dependent and is mediated via a single high-affinity common transport system. Vesicles from the pars convoluta contained a cation-dependent but Na+-unspecific low-affinity common transport system for these compounds. The physiological importance of this system is briefly discussed.