Effect of Inhibitors on Alanine Transport in Isolated Rabbit Ileum

The effects of metabolic inhibitors and ouabain on alanine transport across rabbit ileum, in vitro, have been investigated. Net transport of alanine and Na across short-circuited segments of ileum is virtually abolished by cyanide, 2,4-dinitrophenol, iodoacetate, and ouabain. However, these inhibitors do not markedly depress alanine influx from the mucosal solution, across the brush border, into the intestinal epithelium, and they do not significantly affect the Na dependence of this entry process. The results of this investigation indicate that: (a) the Na dependence of alanine influx does not reflect a mechanism in which the sole function of Na is to link metabolic energy directly to the influx process; and (b) the inhibition of net alanine transport across intestine is, in part, the result of an increased rate coefficient for alanine efflux out of the cell across the brush border. Although these findings do not exclude a direct link between metabolic energy and alanine efflux, the increased efflux may be the result of the increased intracellular Na concentration in the presence of these inhibitors. The results of these studies are qualitatively consistent with a model for alanine transport across the brush border which does not include a direct link to metabolic energy.     

Dicarboxylic Amino Acid Influx across Brush Border of Rabbit Ileum : Effects of amino acid charge on the sodium-amino acid interaction

Glutamate and aspartate influxes across the brush border of rabbit intestine are saturable processes that are subject to competitive inhibition and are markedly influenced by the Na concentration in the mucosal solution. Lowering the Na concentration increases the amino acid concentration needed to elicit a half-maximal influx but does not significantly affect the maximal influx. The interaction between Na and anionic amino acid influx can be described by the same kinetic model that has been applied to the influxes of neutral amino acids and lysine. Comparison of the kinetic parameters for anionic, neutral, and cationic amino acids suggests that amino acid charge influences (a) the stability of the binary (amino acid-site) complex and (b) the affinity of this binary complex for the subsequent binding of Na. A mechanistic interpretation of these interactions is proposed.     

Alanine and sodium fluxes across mucosal border of rabbit ileum

Unidirectional influxes of L-alanine and Na from the mucosal solution into the epithelium of in vitro rabbit ileum have been determined. In the presence of 140 mM Na, alanine influx is approximately 2.2 µmoles/hr cm², but is inhibited if the NaCl in the mucosal solution is replaced by choline Cl, Tris-Cl, mannitol, LiCl, or KCl. Although alanine influx is strongly dependent upon Na in the mucosal solution, it is uninfluenced by marked reduction of intracellular Na pools. In addition, alanine influx is unaffected by intracellular alanine concentration. Na influx is markedly inhibited by the presence of Li. Evidence is presented that Na transport across the mucosal border cannot be attributed to simple diffusion even though the net flux across this surface is in the direction of the electrochemical potential difference.     

Kinetic relations of the Na-amino acid interaction at the mucosal border of intestine

The relation between unidirectional influxes of Na and amino acids across the mucosal border of rabbit ileum was studied under a variety of conditions. At constant Na concentration in the mucosal bathing solution, amino acid influx followed Michaelis-Menten kinetics permitting determination of maximal influx and the apparent Michaelis constant, K_t. Reduction in Na concentration, using choline as substitute cation, caused an increase in K_t for alanine but had no effect on maximal alanine influx. The reciprocal of K_t was a linear function of Na concentration. Similar results were obtained for valine and leucine and these amino acids competitively inhibited alanine influx both in the presence and in the absence of Na. These results lead to a model for the transport system which involves combination of Na and amino acid with a single carrier or site leading to penetration of both solutes. The model predicts that alanine should cause an increase in Na influx and the ratio of this extra Na flux to alanine flux should vary with Na concentration. The observed relation agreed closely with predicted values for Na concentrations from 5 to 140 mM. These results support the hypothesis that interactions between Na and amino acid transport depend in part on a common entry mechanism at the mucosal border of the intestine.     

Effects of monovalent cations on the sodium-alanine interaction in rabbit ileum. Implication of anionic groups in sodium binding

H, K, Rb, and Li inhibit Na-dependent alanine influx across the brush border of rabbit ileum. Kinetic analysis indicates that H and K behave as competitive inhibitors of influx so that increasing the concentration of H or K in the mucosal solution is kinetically indistinguishable from decreasing the Na concentration. In addition the coupling between alanine and Na influxes is markedly reduced at pH 2.5. With the exception of H and Li, none of these monovalent cations significantly affects carrier-mediated alanine influx in the absence of Na indicating that their inhibitory effects are largely restricted to the Na-dependent fraction of influx. Increasing H concentration from 0.03 to 3 mM does not affect influx in the absence of Na but markedly inhibits influx in the presence of Na. Li significantly enhances alanine influx in the absence of Na. Ag, UO₂, and La also inhibit the Na-dependent fraction of alanine influx. These findings suggest that anionic groups having a pK_a of approximately 4 are involved in the interaction between Na and the alanine-carrier complex; present evidence implicates carboxylate groups however, phosphoryl residues cannot be ruled out. The previously proposed kinetic model for the Na-alanine interaction has been extended to accommodate these effects of H and other monovalent cations. The mechanistic and physiological implications of these findings are discussed.     

Influx of neutral amino acids across the brush border of rabbit ileum: Stereospecificity and the roles of the α-amino and α-carboxylate groups

The influxes of the l- and d-stereoisomers of alanine, valine, serine, leucine, histidine, phenylalanine and tryptophan across the brush border of rabbit ileum and the roles of the α-carboxylate and α-amino groups in the influx process have been examined. Our results indicate that:

1.

1. The interactions between neutral amino acids and the influx mechanism(s) invovle the α-amino and α-carboxylate groups as well as the side chain.     

Effect of papain treatment on phenylalanine transport in rabbit ileum.

The unidirectional influx of phenylalanine across the mucosal brush border of rabbit ileum is reduced by pretreatment with papain. Phenylalanine influx is reduced to 10–15% of the control value by 60–90 minutes of preincubation with papain. Pretreatment with protease from $\text{Streptomyces griseus}$ has no effect on phenylalanine influx. Kinetic analysis of the effect of papain indicates that the maximum velocity is reduced with little change in the apparent Michaelis-constant for phenylalanine. The data suggest that papain attacks a membrane protein required for transport. This protein is unaffected by protease which indicates the susceptible region of the protein is shielded by the membrane or inaccessible to protease.     

Effects of inhibitors on 3-O-methylglycose transport in rabbit ileum

Summary Previous studies (Goldner, Schultz & Curran,J. Gen. Physiol. 1969,53:362) have suggested a direct coupling between influxes of sugars and Na across the brush border membrane of rabbit ileum. Effects of several inhibitors, ouabain, cyanide, dinitrophenol and iodoacetate on 3-O-methylglucose fluxes were examined in an effort to obtain information about coupling of sugar transport to metabolism. The inhibitors virtually abolished net active sugar transport across the whole tissue but had less striking effects on sugar influx across the brush border membrane, particularly when the cells were prevented from gaining Na as a result of inhibitor action. However, substantial but incomplete inhibition of influx was observed when the cells were permitted to gain Na. Mucosal strips incubated with ouabain to elevate cellular Na extruded sugar against a concentration gradient when cell Na concentration exceeded that in the medium. Conversely, a small extrusion of Na from ouabain-poisoned cells was observed in the presence of an outwardly directed concentration gradient for sugar. These results provide further evidence of coupling between Na and sugar movement. Additional direct coupling of sugar movement to metabolism cannot be ruled out.     

Characteristics of rat jejunal transport of tryptophan.

The parameters of rat jejunal transport of tryptophan have been examined. The interactions between tryptophan and lysine or methionine have been reexamined, and some aspects of the trans effects of cellularly accumulates amino acids have been studied. It has been demonstrated that: (1) The influx of tryptophan across the jejunal brush border (Jmc-Trp) can be accounted for by the carrier of alpha-aminomonocarboxylic acids alone. (2) Tryptophan competes with lysine for the carrier of basic amino acids across the brush border membrane without itself being transported by this carrier. (3) Lysine has neither cis nor trans effects on Jmc-Trp, whereas intracellular tryptophan is highly inhibitory to Jmd-Lys. (4) The intracellular concentration of lysine and of tryptophan, [Lys]c and [Trp]c, are unaffected by tryptophan and lysine, respectively, although the transmural fluxes, from the mucosal side to the serosal side, Jms, of lysine, Jms-Lys, and of tryptophan, Jms-Trp, are inhibited by tryptophan and lysine, respectively. The latter effects thus represent inhibitory interactions at the basolateral membrane. (5) Methionine is a potent cis and transinhibitor of Jmc-Trp, but stimulated Jms-Trp and reduces [Trp]c. (6) Methionine causes trans acceleration of the influx of lysine across the brush border membrane, Jmc-Lys, but has no effect on the influx of galactose, Jmc-Gal. (7) Leucine causes trans inhibition of Jmc-Leu. (8) Tryptophan does not cause cis inhibition of Jmc-Gal, but is a strongtransinhibitor of Jmc-Gal. (9) Cellularly accumulated tryptophan appears to accelerate the eventual decline in transepithelial potential difference and short-circuit current. These results are consistent with the conclusions that: (1) Tryptophan is transported across the brush border membrane by the carrier of neutral amino acids alone, but leaves the cell across the basolateral membrane by a mechanism used by lysine also. (2) Leucine, methionine and probably tryptophan have a transeffect on the transport of neutral amino acids across the brush border membrane which may represent a phenomenon which can appropriately be termed decelerating exchange diffusion. (3) Cellularly accumulated tryptophan has a strong and indiscriminate depressive effect on all transport functions of rat jejunal epithelium.     

Effects of Cold Periods on the Stimulus-Response System of Phycomyces

The interaction between Na transfer and alanine transfer across the mucosal border of rabbit ileum has been studied further by examining the effect of alanine on Na movement. Studies on strips of mucosa treated with ouabain showed that net Na movements against a Na concentration difference could be caused by a concentration difference of alanine. Na extrusion from mucosal cells was demonstrated when cellular alanine concentration exceeded that in the external medium. Conversely, the cells took up Na against a concentration difference when external alanine concentration was greater than cellular concentration. Unidirectional Na efflux from the cells toward the mucosal solution was increased by loading the cells with alanine. The relation between the increment in Na efflux and alanine efflux was approximately that predicted by the model of Curran et al. (reference 2) for the Na-alanine interaction at the mucosal border of the cells. The results offer further indication that the transport system is reversible and symmetrical.     

Studies on the electrical potential profile across rabbit ileum. Effects of sugars and amino acids on transmural and transmucosal electrical potential differences

When isolated strips of mucosal rabbit ileum are bathed by physiological electrolyte solution the electrical potential difference (PD) across the brush border (ψ_mc) averages 36 mv, cell interior negative. Rapid replacement of Na in the mucosal solution with less permeant cations, Tris or choline, results in an immediate hyperpolarization of ψ_mc. Conversely, replacement of choline in the mucosal solution with Na results in an abrupt depolarization of ψ_mc. These findings indicate that Na contributes to the conductance across the brush border. The presence of actively transported sugars or amino acids in the mucosal solution brings about a marked depolarization of ψ_mc and a smaller increase in the transmural PD (Δψ_ms). It appears that the Na influx that is coupled to the influxes of amino acids and sugars is electrogenic and responsible for the depolarization of ψ_mc. Under control conditions Δψ_ms can be attributed to the depolarization of ψ_mc together with the presence of a low resistance transepithelial shunt, possibly the lateral intercellular spaces. However, quantitatively similar effects of amino acids on ψ_mc are also seen in tissues poisoned with metabolic inhibitors or ouabain. Under these conditions Δψ_mc is much smaller than under control conditions. Thus, the depolarization of ψ_mc might not account for the entire Δψ_ms, observed in nonpoisoned tissue. An additional electromotive force which is directly coupled to metabolic processes might contribute to the normal Δψ_ms.     

Amino Acid and Sugar Transport in Rabbit Ileum

L-Alanine and 3-O-methyl-D-glucose accumulation by mucosal strips from rabbit ileum has been investigated with particular emphasis on the interaction between Na and these transport processes. L-Alanine is rapidly accumulated by mucosal tissue and intracellular concentrations of approximately 50 mM are reached within 30 min when extracellular L-alanine concentration is 5 mM. Evidence is presented that intracellular alanine exists in an unbound, osmotically active form and that accumulation is an active transport process. In the absence of extracellular Na, the final ratio of intracellular to extracellular L-alanine does not differ significantly from unity and the rate of net uptake is markedly inhibited. Amino acid accumulation is also inhibited by 5 x 10^-5 M ouabain. 3-O-methyl-D-glucose accumulation by this preparation is similarly affected by ouabain and by incubation in a Na-free medium. The effects of amino acid accumulation, of ouabain, and of incubation in a Na-free medium on cell water content and intracellular Na and K concentrations have also been investigated. These results are discussed with reference to the two hypotheses which have been suggested to explain the interaction between Na and intestinal nonelectrolyte transport.     

Cytoskeletal control of alanine transport across the rat and turtle small intestine

Procaine inhibited significantly (P less than 0.01) alanine accumulation in the rat intestinal strips in a concentration-dependent pattern, whereas it showed no effect on alanine uptake by the turtle intestinal cells. Colchicine and Vinca alkaloids at 5 X 10(-4) and 1.5 X 10(-6) M respectively caused a significant inhibition (P less than 0.01) of intracellular alanine concentration in the rat with no effect noticed in the turtle. Unidirectional influx of alanine across the brush border membrane of the rat was significantly (P less than 0.01) reduced in the presence of procaine, colchicine and vincristine in the preincubation medium. The same drugs did not show any effect on alanine influx into the turtle small intestine. Electron microscopy showed major structural alterations in the cytoskeletal organization of the turtle intestine in response to procaine, colchicine or vincristine treatment. It is proposed that microtubular system may participate in the overall transport mechanism of alanine across the small intestine.     

Choline influx across the brush border of guinea pig jejunum

Choline uptake across the mucosal border of guinea pig jejunum was measured to determine the characteristics of this step in intestinal absorption. Unidirectional influx of [¹⁴C]choline appears to proceed primarily by a saturable, carrier-mediated process at low mucosal choline concentrations; at high concentrations (>4 mM) the influx rate is approximately linearly related to the mucosal choline concentration, suggesting that absorption by passive diffusion predominates. Influx was only minimally reduced by elimination of Na⁺ from the mucosal test solution or by reduction of the intracellular Na⁺ concentration. Preincubation of tissue samples with metabolic inhibitors or with ouabain did not markedly reduce influx. These results are consistent with a model of choline transport across the brush border membrane by a carrier-mediated mechanism which is similar to that involved in fructose absorption but different from the Na⁺-dependent mechanism which participates in active transport of sugar and amino acids. At low lumenal choline concentrations, influx into colonic mucosa is slower than in jejunum and appears to be attributed solely to simple diffusion.     

D-galactose accumulation in rabbit ileum. Effects of theophylline on serosal permeability.

The effects of theophylline and dibutyryl cyclic AMP, on in vitro unidirectional galactose fluxes across the mucosal and serosal borders of rabbit ileum have been studied. 1. When Ringer [galactose] = 2mM, theophylline and dibutyryl cyclic AMP reduce both mucosal-serosal and serosal-mucosal galactose flux by approx. 50%. The K1 for theophylline inhibition of flux in both directions is 2 mM. 1 mM dibutyryl cyclic AMP elicits a maximal inhibitory response. Concurrent with the inhibition in transmural galactose fluxes, theophylline and dibutyryl cyclic AMP increase the tissue accumulation of [galactose] and the specific-activity ratio R of 3H : 14C-labelled galactose coming from the mucosal and serosal solutions respectively. It is deduced that theophylline and dibutyryl cyclic AMP are without effect on the mucosal unidirectional permeability to galactose but cause a symmetrical reduction in serosal entry and exit permeability. 2. Reduction in the asymmetry of the mucosal border to galactose by reducing Ringer [Na], raising Ringer [galctose] or adding ouabain reduces the theophylline-dependent increase in galactose accumulation. 3. Hypertonicity in the serosal solution increases the permeability of the serosal border to galactose and reduces tissue galactose accumulation. Serosal hypertonicity partially reverses the theophylline-depedent effects on galactose transport. Replacing Ringer chloride by sulphate abolishes the theophylline-dependent effects on galactose transport. 4. It is considered that the theophylline-dependent increase in galactose accumulation results from the reduction in serosal permeability. This is shown to be a quantitatively consistent inference. 5. Further support for the view that the asymmetric transport of galactose in rabbit ileum results from convective-diffusion is presented.     

Sugar transport by intestine. Escape of galactose from preloaded mucosa of hamster jejunum

Everted hamster jejunum was loaded with d-galactose and then escape into an initially galactose-free mucosal solution was followed. Mucosal anaerobiosis greatly increased the rate of escape, an effect which might have been caused by inhibiting reuptake from the unstirred layer and/or by augmenting the ease of unidirectional efflux across the brush border membrane. The former effect was expected because of our previous results from influx studies, and the main object here was to find out if the ease of efflux is affected by anaerobiosis. With phlorizin present in the mucosal solution during escape, information about unidirectional efflux was obtainable. We estimated that 10^?4 M phlorizin inhibited the ease of efflux via the phlorizin-sensitive pathway by about 65%. Apparently the reason why mucosal phlorizin accelerates escape of sugar from loaded mucosa, an effect which has been reported previously by others, is that it inhibits unidirectional efflux less effectively than it inhibits reuptake from the unstirred layer. Residual efflux via the phlorizin-sensitive pathway was markedly increased by mucosal anaerobiosis. This increase did not require an elevation of intracellular Na⁺ concentration. These results, together with those of our previous study, show that mucosal anaerobiosis abolishes uphill transport of galactose across the brush border of hamster jejunum by inhibiting unidirectional influx and by increasing the ease of unidirectional efflux. Neither of these effects requires a rise in intracellular Na⁺ concentration.     

Na+-independent Lysine Transport in Human Intestinal Caco-2 Cells

The nature of transepithelial and cellular transport of the dibasic amino acid lysine in human intestinal epithelial Caco-2 cells has been characterized. Intracellular accumulation of lysine across both the apical and basolateral membranes consists of a Na⁺-independent, membrane potential-sensitive uptake. Na⁺-independent lysine uptake at the basolateral membrane exceeds that at the apical membrane. Lysine uptake consists of both saturable and nonsaturable components. Na⁺-independent lysine uptake at both membranes is inhibited by lysine, arginine, alanine, histidine, methionine, leucine, cystine, cysteine and homoserine. In contrast, proline and taurine are without inhibitory effects at both membranes. Fractional Na⁺-independent lysine efflux from preloaded epithelial layers is greater at the basolateral membrane and shows trans-stimulation across both epithelial borders by lysine, arginine, alanine, histidine, methionine, and leucine but not proline and taurine. Na⁺-independent lysine influx (10 μm) in the presence of 10 mm homoserine shows further concentration dependent inhibition by lysine. Taken together, these data are consistent with lysine transport being mediated by systems b^o,+, y⁺ and a component of very low affinity (nonsaturable) at both membranes. The relative contribution to lysine uptake at each membrane surface (at 10 μm lysine), normalized to total apical uptake (100%), is apical b^o,+ (47%), y⁺ (27%) and the nonsaturable component (26%), and basal b^o,+ (446%), y⁺ (276%) and the nonsaturable component (20%). Northern analysis shows hybridization of Caco-2 poly(A)⁺RNA with a human rBAT cDNA probe. Received: 3 July 1995/Revised: 6 February 1996