Oligopeptide transporter mediated uptake and transport of d-Asp(OBzl)-Ala, d-Glu(OBzl)-Ala, and d-Ser(Bzl)-Ala in filter-grown Caco-2 monolayers

Pharmaceutical and pharmacological importance of peptide transporters

Peptide transport is currently a prominent topic in membrane research. The transport proteins involved are under intense investigation because of their physiological importance in protein absorption and also because peptide transporters are possible vehicles for drug delivery. Moreover, in many tissues peptide carriers transduce peptidic signals across membranes that are relevant in information processing. The focus of this review is on the pharmaceutical relevance of the human peptide transporters PEPT1 and PEPT2. In addition to their physiological substrates, both carriers transport many β-lactam antibiotics, valaciclovir and other drugs and prodrugs because of their sterical resemblance to di- and tripeptides. The primary structure, tissue distribution and substrate specificity of PEPT1 and PEPT2 have been well characterized. However, there is a dearth of knowledge on the substrate binding sites and the three-dimensional structure of these proteins. Until this pivotal information becomes available by X-ray crystallography, the development of new drug substrates relies on classical transport studies combined with molecular modelling. In more than thirty years of research, data on the interaction of well over 700 di- and tripeptides, amino acid and peptide derivatives, drugs and prodrugs with peptide transporters have been gathered. The aim of this review is to put the reports on peptide transporter-mediated drug uptake into perspective. We also review the current knowledge on pharmacogenomics and clinical relevance of human peptide transporters. Finally, the reader's attention is drawn to other known or proposed human peptide-transporting proteins.

Conformational restrictions in ligand binding to the human intestinal di-/tripeptide transporter: implications for design of hPEPT1 targeted prodrugs

The aim of the present study was to develop a computational method aiding the design of dipeptidomimetic pro-moieties targeting the human intestinal di-/tripeptide transporter hPEPT1. First, the conformation in which substrates bind to hPEPT1 (the bioactive conformation) was identified by conformational analysis and 2D dihedral driving analysis of 15 hPEPT1 substrates, which suggested that psi(1) approximately 165 degrees , omega(1) approximately 180 degrees , and phi(2) approximately 280 degrees were descriptive of the bioactive conformation. Subsequently, the conformational energy required to change the peptide backbone conformation (DeltaE(bbone)) from the global energy minimum conformation to the identified bioactive conformation was calculated for 20 hPEPT1 targeted model prodrugs with known K(i) values. Quantitatively, an inverse linear relationship (r(2)=0.81, q(2)=0.80) was obtained between DeltaE(bbone) and log1/K(i), showing that DeltaE(bbone) contributes significantly to the experimentally observed affinity for hPEPT1 ligands. Qualitatively, the results revealed that compounds classified as high affinity ligands (K(i)<0.5 mM) all have a calculated DeltaE(bbone)<1 kcal/mol, whereas medium and low-affinity compounds (0.5 mM<K(i)<15 mM) have DeltaE(bbone) values in the range 1-3 kcal/mol. The findings also shed new light on the basis for the experimentally observed stereoselectivity of hPEPT1.

Pyrimidine and nucleoside gamma-esters of L-Glu-Sar: synthesis, stability and interaction with hPEPT1

The aim of the present study was to improve the synthetic pathway of bioreversible dipeptide derivatives as well as evaluate the potential of using l-Glu-Sar as a pro-moiety for delivering three newly synthesised nucleoside and pyrimidine l-Glu-Sar derivatives. l-Glu(trans-2-thymine-1-yl-tetrahydrofuran-3-yl ester)-Sar (I), l-Glu(thymine-1-yl-methyl ester)-Sar (II) and l-Glu(acyclothymidine)-Sar (III) were synthesised and in vitro stability was studied in various aqueous and biological media. Affinity to and translocation via hPEPT1 was investigated in mature Caco-2 cell monolayers, grown on permeable supports. Affinity was estimated in a competition assay, using [14C] labelled Gly-Sar (glycylsarcosine). Translocation was measured as pHi-changes induced by the substrates using the fluorescent probe BCECF and an epifluorescence microscope setup. All dipeptide derivatives released the model drugs quantitatively by specific base-catalysed hydrolysis at pH>6.0. II was labile in aqueous buffer solution, whereas I and III showed appropriate stability for oral administration. In 10% porcine intestinal homogenate, the half-lives of the dipeptide derivatives indicated limited enzyme catalyzed degradation. All compounds showed good affinity to hPEPT1, but the Compounds I and III showed not to be translocated by hPEPT1. The translocation of the l-Glu-Sar derivative of acyclovir, l-Glu(acyclovir)-Sar was also investigated and showed not to take place. Consequently, l-Glu-Sar seems to be a poor pro-moiety for hPEPT1-mediated transport.

Analysis of the transport properties of side chain modified dipeptides at the mammalian peptide transporter PEPT1

This study was initiated to examine systematically the effect of side chain modifications at dipeptides on their transport via PEPT1. We synthesized a series of Xaa(R)-Ala and Ala-Xaa(R) dipeptides with the functional groups of the side chains modified by structurally different blocking groups R. Recognition and transport of these derivatives by PEPT1 was measured in Caco-2 cells, in transgenic Pichia pastoris cells and in Xenopus laevis oocytes expressing PEPT1. The dipeptide derivatives displayed K(i) values between 0.002 and 4 mM. Electrophysiological analyses showed that the Ala-Xaa(R) derivatives were transported by PEPT1. In contrast, most Xaa(R)-Ala derivatives--although recognized--did not show significant transport rates. Substitution of a terminal phenyl residue in the side chain blocking group by a p-nitrophenyl residue enhanced the affinity of several dipeptide derivatives for interaction with PEPT1. However, none of these compounds showed electrogenic transport in oocytes. With a K(i) value of 0.002 mM, Lys[Z(NO(2))]-Val displayed the highest affinity to PEPT1 ever reported. We conclude that the transport of side chain modified dipeptides into enterocytes depends (a) on the position of the modified trifunctional amino acid in the dipeptide, (b) the distance between its alpha-carbon and the side chain blocking group and (c) the hydrophobic character of the side chain modification.

The intestinal H+/peptide symporter PEPT1: structure–affinity relationships

Peptide transporter 1, PEPT1, of the mammalian enterocyte is presently under intense investigation in many laboratories because of its nutritional importance in the absorption of protein hydrolysis products and because more recent studies have shown that many drugs and prodrugs gain entry into the systemic circulation via PEPT1. Until the exact structural features of the substrate binding site of PEPT1 become available, for example by X-ray crystallography, determination of affinities followed by proof of actual membrane translocation will have to suffice when testing for possible new substrates for PEPT1. Affinity constants reflect the strength of their interaction with the binding site of the transporter. A review of the literature shows a wide range of affinity constants between 2 microM and 30 mM. We consider affinity constants for substrates or inhibitors of PEPT1 lower than 0.5 mM as high affinity, between 0.5 and 5.0 mM as medium affinity and above 5 mM as low affinity. Values above 15 mM we consider with great caution. In this mini-review we discuss affinities and structural determinants which affect affinities of a variety of substrates for PEPT1.

Transport of peptidomimetic drugs by the intestinal Di/tri-peptide transporter, PepT1

The apical membrane of small intestinal enterocytes possess an uptake system for di- and tripeptides. The physiological function of the system is to transport small peptides resulting from digestion of dietary protein. Moreover, due to the broad substrate specificity of the system, it is also capable of transporting a number of orally administered peptidomimetic drugs. Absorbed peptides may be hydrolysed in the cells due to the high peptidase activity present in the cytosol. Peptidomimetic drugs may, if resistant to the cellular enzyme activity, pass the basolateral membrane via a basolateral peptide transport mechanism and enter the systemic circulation. As the number of new peptide and peptidomimetic drugs are rapidly increasing, the peptide transport system has gained increasing attention as a possible drug delivery system for small peptides and peptide-like compounds. In this paper we give an updated introduction to the transport system and discuss the substrate characteristics of the di/tri-peptide transporter system with special emphasis on chemically modified substrates and prodrugs.

Model prodrugs designed for the intestinal peptide transporter. A synthetic approach for coupling of hydroxy-containing compounds to dipeptides

The human peptide transporter, hPepT1, situated in the small intestine, may be exploited to increase absorption of drugs or model drugs by attaching them to a dipeptide, which is recognised by hPepT1. A synthetic protocol for this kind of model prodrugs was developed, in which model drugs containing a hydroxy group were attached to enzymatically stable dipeptides by hydrolysable ester linkages. Furthermore, a number of benzyl alcohols with various substituents in the 4-position of the phenyl ring were coupled to D-Asp-Ala and D-Glu-Ala. Ideally, a prodrug should be stable in the upper small intestine and be converted to the parent drug during or after transport into the blood circulation. Therefore, we investigated the influence of the electronegativity of the substituent in the 4-position of the phenyl ring on stability in aqueous solution at pH 6.0 and 7.4, corresponding to pH in jejunum and blood, respectively. In addition, the influence of the electronegativity of the substituent on stability upon storage was examined. Model prodrugs containing electron donating substituents in the 4-position of the phenyl ring decomposed upon storage, while model prodrugs containing no substituents or electron withdrawing substituents in the 4-position were stable. In aqueous solution (pH 6.0 and 7.4), electron withdrawing substituents in the 4-position decreased the half-life of the model prodrug. These data provide important information on stability of this kind of model prodrugs upon storage and under aqueous conditions. The results may be applied in the rational design of oligopeptide ester prodrugs to obtain prodrugs, which are stable upon storage and have an optimal release profile of the drug.

Model prodrugs for the intestinal oligopeptide transporter: model drug release in aqueous solution and in various biological media

The human intestinal di/tri-peptide carrier, hPepT1, has been suggested as a target for increasing intestinal transport of low permeability compounds by creating prodrugs designed for the transporter. Model ester prodrugs using the stabilized dipeptides D-Glu-Ala and D-Asp-Ala as pro-moieties for benzyl alcohol have been shown to have affinity for hPepT1. Furthermore, in aqueous solution at pH 5.5 to 10, the release of the model drug seems to be controlled by a specific base-catalyzed hydrolysis, indicating that the compounds may remain relatively stable in the upper small intestinal lumen with a pH of approximately 6.0, but still release the model drug at the intercellular and blood pH of approximately 7.4. Even though benzyl alcohol is not a low molecular weight drug molecule, these results indicate that the dipeptide prodrug principle is a promising drug delivery concept. However, the physico-chemical properties such as electronegativity, solubility, and log P of the drug molecule may also have an influence on the potential of these kinds of prodrugs. The purpose of the present study is to investigate whether the model drug electronegativity, estimated as Taft substitution parameter (sigma*) may influence the acid, water or base catalyzed model drug release rates, when released from series of D-Glu-Ala and D-Asp-Ala pro-moieties. Release rates were investigated in both aqueous solutions with varying pH, ionic strength, and buffer concentrations as well as in in vitro biological media. The release rates of all the investigated model drug molecules followed first-order kinetics and were dependent on buffer concentration, pH, ionic strength, and model drug electronegativity. The electronegativity of the model drug influenced acid, water and base catalyzed release from D-Asp-Ala and D-Glu-Ala pro-moieties. The model drug was generally released faster from D-Asp-Ala- than from the D-Glu-Ala pro-moieties. In biological media the release rate was also dependent on the electronegativity of the model drug. These results demonstrate that the model drug electronegativity, estimated as Taft (sigma*) values, has a significant influence on the release rate of the model drug.

Stability and in vitro metabolism of dipeptide model prodrugs with affinity for the oligopeptide transporter

One approach to increase drug stability and to facilitate oral absorption of low bioavailability drugs may be to design oligopeptide ester prodrugs which are stable in the gastrointestinal tract, are transported via the oligopeptide transporter, and finally release the parent drug molecule into the blood circulation and/or by its site of action. In these kinds of prodrugs the ester linkage may be broken by pH dependent and/or enzyme catalyzed hydrolysis. The objective of the present study was to investigate the degradation mechanism and rate of the model compounds Glu(OBzl)-Sar, D-Glu(OBzl)-Ala and Asp(OBzl)-Sar in aqueous solution and in relevant biological media and to compare these results with those of our previous study of D-Asp(OBzl)-Ala. Furthermore, the resulting aqueous stability and in vitro metabolism data are related to our previous affinity data to evaluate if Glu-Sar, D-Glu-Ala, and Asp-Sar have potential as pro-moieties in these kinds of prodrugs. The degradation rates follow first-order kinetics, show maximun stability at pH 4-5 with maximum half-lives for Asp(OBzl)-Sar, Glu(OBzl)-Sar, and D-Glu(OBzl)-Ala of 115 h, 30 days and 152 days, respectively. The stability was dependent on buffer concentration, temperature, pH, and ionic strength. In biological media such as 80% human plasma, human gastric juice and intestinal fluid, and 10% rat jejunal homogenate at 37 degrees C, the half-lives were greater than 1 h except for the hydrolysis of Glu(OBzl)-Sar in 10% rat jejunal homogenate, where the half-life was approximately 16 min. All the stabilized dipeptides may have potential as drug carriers targeting hPepT1.

Stability, metabolism and transport of D-Asp(OBzl)-Ala--a model prodrug with affinity for the oligopeptide transporter

The model prodrug D-Asp(OBzl)-Ala has previously been shown to have affinity and to be transported by the oligopeptide transporter PepT1 expressed in Caco-2 cells. The main objective of the present study was to investigate the aqueous stability of D-Asp(OBzl)-Ala and its in vitro metabolism in different gastrointestinal media arising from rats and humans, as well as in human plasma. The second major aim of the study was to evaluate our previous study in Caco-2 cell culture, by determining the effective intestinal permeability (Peff) of D-Asp(OBzl)-Ala in situ using the single-pass rat perfusion model. The aqueous stability studies show water, general buffer, as well as specific acid and base catalysis of D-Asp(OBzl)-Ala. The degradation of the model prodrug was independent of ionic strength. The half-lives in rat jejunal fluid and homogenate were >3 h. In human gastric and intestinal fluids, the half-lives were >3 h and 2.3+/-0. 03 h, respectively. Using the rat single-pass perfusion technique, the effective jejunal permeability (Peff) of D-Asp(OBzl)-Ala was determined to be high (1.29+/-0.5.10-4 cm/s). The 32 times higher Peff value found in the perfusion model compared to Caco-2 cells is most likely due to a higher functional expression of the oligopeptide transporter. Rat jejuna Peff was reduced by approximately 50% in the presence of well known oligopeptide transporter substrates, such as Gly-Sar and cephalexin. It may be that D-Asp(OBzl)-Ala is primarily absorbed intact by the rat jejunal oligopeptide transporter, since the stability in the intestinal homogenate and fluids was rather high (t1/2>2.3 h).