By building key structural features into hydrophilic drugs, they can be recognized by the PepT1 transporter system of the small intestine and rendered orally active. The model shown provides, for the first time, a 3D template for all known substrates of PepT1.
The binding affinities of a number of amino-acid and peptide derivatives by the mammalian intestinal peptide transporter PepT1 were investigated, using the Xenopus laevis expression system. A series of blocked amino acids, namely N-acetyl-Phe (Ac-Phe), phe-amide (Phe-NH 2 ), N-acetyl-Phe-amide (Ac-Phe-NH 2 ) and the parent compound Phe, was compared for efficacy in inhibiting the uptake of the peptideIn an equivalent set of experiments, the blocked peptides Ac-Phe-Tyr, Phe-Tyr-NH 2 and Ac-Phe-Tyr-NH 2 were compared with the parent compound Phe-Tyr. Comparing amino acids and derivatives, only Ac-Phe was an effective inhibitor of peptide uptake (K i 1.81^0.37 mm). Ac-Phe-NH 2 had a very weak interaction with PepT1 (K i 16.8^5.64 mm); neither Phe nor Phe-NH 2 interacted with PepT1 with measurable affinity. With the dipeptide and derivatives, unsurprisingly the highest affinity interaction was with Phe-Tyr (K i 0.10^0.04 mm). The blocked C-terminal peptide Phe-Tyr-NH 2 also interacted with PepT1 with a relatively high affinity (K i 0.94^0.38 mm). Both Ac-Phe-Tyr and Ac-Phe-Tyr-NH 2 interacted weakly with PepT1 (K i 8.41^0.11 and 9.97^4.01 mm, respectively). The results suggest that the N-terminus is the primary binding site for both dipeptides and tripeptides. Additional experiments with four stereoisomers of Ala-Ala-Ala support this conclusion, and lead us to propose that a histidine residue is involved in binding the C-terminus of dipeptides. In addition, a substrate binding model for PepT1 is proposed.
4-Aminophenylacetic acid (4-APAA), a peptide mimic lacking a peptide bond, has been shown to interact with a proton-coupled oligopeptide transporter using a number of different experimental approaches. In addition to inhibiting transport of labeled peptides, these studies show that 4-APAA is itself translocated.4-APAA transport across the rat intact intestine was stimulated 18-fold by luminal acidification (to pH 6.8) as determined by high performance liquid chromatography (HPLC); in enterocytes isolated from mouse small intestine the intracellular pH was reduced on application of 4-APAA, as shown fluorimetrically with the pH indicator carboxy-SNARF; 4-APAA trans-stimulated radiolabeled peptide transport in brush-border membrane vesicles isolated from rat renal cortex; and in Xenopus oocytes expressing PepT1, 4-APAA produced trans-stimulation of radiolabeled peptide efflux, and as determined by HPLC, was a substrate for translocation by this transporter.These results with 4-APAA show for the first time that the presence of a peptide bond is not a requirement for rapid translocation through the proton-linked oligopeptide transporter (PepT1). Further investigation will be needed to determine the minimal structural requirements for a molecule to be a substrate for this transporter.The rapid uptake of intact small peptides across the brushborder membrane of the small intestinal epithelium is the major route for absorption of dietary protein ␣-amino nitrogen (1). Hitherto, it has been thought that a number of chemical features, for example free amino and carboxyl termini, are essential in contributing to substrate interaction with, and translocation through, the intestinal peptide transporter.These features include the presence of a peptide bond within the substrate molecules. Indeed a major review (1) states that "it is the presence of peptide bonds which make di-and tripeptide acceptable to the peptide transport systems." Although previous work (e.g. Ref.2) has shown that molecules lacking this feature can inhibit transport of peptides (presumably by substrate binding), we describe here for the first time rapid transport of a small totally non-peptidic substrate through the intestinal peptide transporter. The substrate, 4-aminophenylacetic acid (4-APAA), 1 was selected on the basis of its chemical structure, it being a potential mimic of a dipeptide (D-Phe-LAla) (Fig. 1) which previously we have shown to be an excellent substrate for epithelial peptide transport (3, 4). EXPERIMENTAL PROCEDURESRat renal brush-border membrane vesicles were prepared as described previously (5), and initial rates of labeled peptide transport (influx, efflux) were determined by rapid filtration (4, 6). Rat intestinal loops in vitro and vascularly perfused small intestine in situ were used to measure transepithelial fluxes in the intact small intestine as described previously (3, 7). Luminal pH was changed using a previously published protocol (8). Isolated murine enterocytes were prepared by enzymatic digestion using haluronidase, and i...
1. 4-Aminomethylbenzoic acid, a molecule which mimics the special configuration of a dipeptide, competitively inhibits peptide influx in both Xenopus Laevis oocytes expressing rabbit PepT1 and through PepT1 in rat renal brush border membrane vesicles. 2. This molecule is not translocated through PepT1 as measured both by direct HPLC analysis in PepT1-exp ressing oocytes and indirectly by its failure to trans-stimulate labelle d peptide efflux through PepT1 in oocytes and in renal membrane vessicle s. 3. However 4-aminiomethylbenzoic acid does reverse trans-stimulation through expressed PepT1 of labelled peptid efflux induced by unlabelled peptide. Quantitatively this reversal is compatible with 4-aminomethyl benzoic acid competitively binding to the external surface of PepT1. 4. 4-Aminomethylbenzoic acid (the first molecule discovered to be a non-translocated competitive inhibitor of proton-coupled oligopeptide transport) and its derivatives may thus be particularly useful as experimental tools.
1. Kinetics of influx (mediated through peptide-proton cotransport) of two labelled dipeptides has been studied in apical membrane vesicles isolated from rat renal cortex. The substrates (neutral D-Phe-L-Ala and anionic D-Phe-L-Glu) have previously been shown to be transported through a single system but with different stoichiometry of proton coupling. 2. The initial rate of influx of both peptides was determined under a set of defined conditions allowing extravesicular pH, intravesicular pH, transmembrane pH and membrane potential (Em) to be varied systemically and independently. From this data the kinetic constants Km and Vmax were derived for each condition. Very substantial effects of pH, pH gradient and membrane potential were found; there were consistent quantitative differences when the substrates were compared. 3. Efflux of the two peptides from preloaded vesicles was also determined. At pH 5-5 (intraand extravesicular), but not at pH 7 4, the rate constants for efflux of the two peptides were similar and addition to the extravesicular medium of unlabelled D-Phe-L-Glu (but not D-Phe-L-Ala) trans-stimulated efflux of both peptides to a similar extent; the extent of this transstimulation was insensitive to alterations in membrane potential. 4. A model based on a combination of classical carrier theory (the carrier being negatively charged) and of two sequential protonation steps (both to external sites predicted to be in the membrane electrical field) is described. Qualitatively this adequately accounts for all the observations made and allows for the dependence of the stoichiometry of proton-peptide coupling on the net charge carried by the substrate. Quantitatively a 50-fold greater rate of reorientation of the free carrier when unprotonated is predicted to be responsible for the coupling of proton and peptide transport. 5. Our results and the model are discussed with respect to the recently elucidated primary structure of mammalian peptide transporters.The analysis of transport systems has been critically dependent on the development of appropriate (i.e. specific, stable and hydrolysis resistant) model substrates; this has been true for example in both the amino acid and sugar transport field. The absence of appropriate model substrates has impeded the analysis of peptide transport (a process of very substantial physiological importance in many epithelia, Matthews, 1991; Meredith & Boyd, 1995a). However, the systematic studies of Lister, Sykes, Bailey, Boyd & Bronk (1995) have shown that the presence of a D-amino acid at the N-terminal of an oligopeptide confers hydrolysis resistance but does not substantially reduce transepithelial transport across rat small intestine in vitro. As a direct consequence of these studies we have used two such labelled molecules (the neutral D-Phe-L-Ala and the anionic D-Phe-L-Glu) to probe the mechanisms of peptide transport. Our studies have been carried out on isolated apical membrane vesicles from mammalian renal cortex, a preparation which is very well-characterized m...
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.