The influence of luminal pH on transport of neutral and charged dipeptides by rat small intestine, in vitro

Proton-coupled oligopeptide transporter family SLC15: physiological, pharmacological and pathological implications

Mammalian members of the proton-coupled oligopeptide transporter family (SLC15) are integral membrane proteins that mediate the cellular uptake of di/tripeptides and peptide-like drugs. The driving force for uphill electrogenic symport is the chemical gradient and membrane potential which favors proton uptake into the cell along with the peptide/mimetic substrate. The peptide transporters are responsible for the absorption and conservation of dietary protein digestion products in the intestine and kidney, respectively, and in maintaining homeostasis of neuropeptides in the brain. They are also responsible for the absorption and disposition of a number of pharmacologically important compounds including some aminocephalosporins, angiotensin-converting enzyme inhibitors, antiviral prodrugs, and others. In this review, we provide updated information on the structure-function of PepT1 (SLC15A1), PepT2 (SLC15A2), PhT1 (SLC15A4) and PhT2 (SLC15A3), and their expression and localization in key tissues. Moreover, mammalian peptide transporters are discussed in regard to pharmacogenomic and regulatory implications on host pharmacology and disease, and as potential targets for drug delivery. Significant emphasis is placed on the evolving role of these peptide transporters as elucidated by studies using genetically modified animals. Whenever possible, the relevance of drug-drug interactions and regulatory mechanisms are evaluated using in vivo studies.

The regulation of K- and L-cell activity by GLUT2 and the calcium-sensing receptor CasR in rat small intestine

Intestinal enteroendocrine cells (IECs) secrete gut peptides in response to both nutrients and non-nutrients. Glucose and amino acids both stimulate gut peptide secretion. Our hypothesis was that the facilitative glucose transporter, GLUT2, could act as a glucose sensor and the calcium-sensing receptor, CasR, could detect amino acids in the intestine to modify gut peptide secretion. We used isolated loops of rat small intestine to study the secretion of gluco-insulinotropic peptide (GIP), glucagon-like peptide-1 (GLP-1) and peptide tyrosine tyrosine (PYY) secretion stimulated by luminal perfusion of nutrients or bile acid. Inhibition of the sodium-dependent glucose cotransporter 1 (SGLT1) with phloridzin partially inhibited GIP, GLP-1 and PYY secretion by 45%, suggesting another glucose sensor might be involved in modulating peptide secretion. The response was completely abolished in the presence of the GLUT2 inhibitors phloretin or cytochalasin B. Given that GLUT2 modified gut peptide secretion stimulated by glucose, we investigated whether it was involved in the secretion of gut peptide by other gut peptide secretagogues. Phloretin completely abolished gut peptide secretion stimulated by artificial sweetener (sucralose), dipeptide (glycylsarcosine), lipid (oleoylethanolamine), short chain fatty acid (propionate) and major rat bile acid (taurocholate) indicating a fundamental position for GLUT2 in the gut peptide secretory mechanism. We investigated how GLUT2 was able to influence gut peptide secretion mediated by a diverse range of stimulators and discovered that GLUT2 affected membrane depolarisation through the closure of K+(ATP)-sensitive channels. In the absence of SGLT1 activity (or presence of phloridzin), the secretion of GIP, GLP-1 and PYY was sensitive to K+(ATP)-sensitive channel modulators tolbutamide and diazoxide. L-amino acids phenylalanine (Phe), tryptophan (Trp), asparagine (Asn), arginine (Arg) and glutamine (Gln) also stimulated GIP, GLP-1 and PYY secretion, which was completely abolished when extracellular Ca2+ was absent. The gut peptide response stimulated by the amino acids was also blocked by the CasR inhibitor Calhex 231 and augmented by the CasR agonist NPS-R568. GLUT2 and CasR regulate K- and L-cell activity in response to nutrient and non-nutrient stimuli.

Dipeptide monoester ganciclovir prodrugs for transscleral drug delivery: targeting the oligopeptide transporter on rabbit retina

PURPOSE

The overall aim of this research work was to evaluate a series of dipeptide monoester prodrugs of an antiviral agent, ganciclovir (GCV), for oligopeptide transporter-targeted transscleral drug delivery to rabbit retina.

METHODS

The permeability and enzymatic hydrolysis of dipeptide monoester GCV prodrugs were evaluated using freshly excized rabbit retinal pigment epithelium (RPE)-choroidsclera (RCS) and sclera tissue preparations. Affinity and transport mechanism of these prodrugs and their translocation across RCS were investigated through competitive inhibition studies of [(3)H]glycylsarcosine with the prodrugs.

RESULTS

The transport of glycylsarcosine was found to be saturable (K(m) = 1.21 +/- 0.41 mM, V(max) = 15.89 +/- 1.54 pmoles/min/cm(2)), pH, temperature, and energy dependant. Dipeptides, angiotensin converting enzyme inhibitors, and a beta-lactum antibiotic strongly inhibited the transport of glycylsarcosine indicating the functional presence of oligopeptide transport (OPT) system on the RPE. Dipeptide prodrugs (valine-valine-GCV, glycine-valine-GCV, and tyrosine-valine-GCV), and valine-GCV demonstrate a high enzymatic stability and affinity toward the retinal OPT system. The transport of the prodrugs was significantly inhibited ( approximately 50%) in the presence of glycylsarcosine. The rank order of scleral permeability was Gly-Val-GCV approximately GCV>Val-GCV>Tyr-Val-GCV approximately Val-Val-GCV. The RCS permeability values of Val-GCV (3.29 +/- 0.09 x 10(6)cm/s), Val-Val-GCV (4.14 +/- 0.33 x 10(6)cm/s), Gly-Val-GCV (3.40 +/- 0.47 x 10(6)cm/s) and Tyr-Val-GCV (3.08 +/- 0.29 x 10(6)cm/s) were two-fold higher than that of GCV (1.61 +/- 0.06 x 10(6)cm/s).

CONCLUSIONS

The dipeptide monoester GCV prodrugs, owning to higher lipophilicity and OPT-mediated translocation across RPE, appear to be promising candidates in the treatment of ocular cytomegalovirus infections following an episcleral administration.

Functional characterization of a cloned pig intestinal peptide transporter (pPepT1)

Absorption of dietary protein can be mediated through the uptake of AA as free AA or small peptides. A H(+)-coupled, peptide transport protein, PepT1, is responsible for the absorption of small peptides arising from digestion of dietary proteins in the small intestine. The magnitude of peptide absorption and the nutritional significance of PepT1 are unknown for many food-producing animals; thus, the objective of this study was to clone and determine the functional characteristics of the pig PepT1 (pPepT1). Two cDNA-encoding pPepT1 were isolated, which contain alternative polyadenylation sites. The predicted pPepT1 is a 708-AA protein, which shows 82.8, 85.7, and 64.7% AA identity to human, sheep, and chicken PepT1, respectively. On northern blots, two pPepT1 mRNA of approximately 2.9 and 3.5 kb were detected in the duodenum, jejunum, and ileum of the small intestine and are presumed to result from alternative polyadenylation. Uptake of [(3)H]-Gly-Sar was measured in Chinese hamster ovary cells transiently transfected with a pPepT1 expression vector to study the functional expression of pPepT1. Peptide transport was H(+)-dependent, with an optimal pH of 6.0 to 6.5. The ability of pPepT1 to transport various peptides was assayed by calculating the concentration of unlabeled peptide that inhibited 50% of [(3)H]-Gly-Sar uptake (IC(50)) in transfected cells. Eleven dipeptides and two tripeptides had IC(50) values that ranged from 0.004 to 0.53 mM. Three peptides, Lys-Lys, Arg-Lys, and Lys-Trp-Lys, had IC(50) values greater than 1. 38 mM and seem to be poor substrates for pPepT1. For all three tetrapeptides examined, uptake of Gly-Sar was too small to measure, even at a concentration of 10 mM tetrapeptide; therefore, IC(50) values could not be calculated. These results demonstrate that pPepT1 can transport a variety of dipeptides and tripeptides but not tetrapeptides.

Mechanism of corneal permeation of L-valyl ester of acyclovir: targeting the oligopeptide transporter on the rabbit cornea

PURPOSE

To delineate mechanisms associated with the corneal transport of a L-valine prodrug of an antiviral agent, acyclovir.

METHOD

The permeability and enzymatic hydrolysis of L-Val-ACV were evaluated using freshly excised rabbit cornea. Transport mechanism across rabbit cornea was investigated through a competitive inhibition study of L-Val-ACV with other substrates of human peptide transporter (hPepT1).

RESULTS

L-Valyl ester of Acyclovir (L-Val-ACV) was approximately threefold more permeable across the intact rabbit cornea than acyclovir (ACV). Dipeptides, beta-lactam antibiotics, and angiotensin converting enzyme (ACE) inhibitors, strongly inhibited the transport of L-Val-ACV indicating that a carrier mediated transport system specific for peptides is primarily responsible for the corneal permeation of L-Val-ACV. L-Val-ACV transport was found to be saturable (Km = 2.26 +/- 0.34 mM, Jmax = 1.087 +/- 0.05 nmoles cm(-2) min(-1)), energy and pH dependent. CONCLUSIONS Functional evidence of an oligopeptide transport system present on the rabbit cornea has been established. The peptide transporter on the corneal epithelium may be targeted to improve the ocular bioavailability of poorly absorbed drugs.

Effect of buffer media composition on the solubility and effective permeability coefficient of ibuprofen

The effect of perfusion medium composition on the two important biopharmaceutical parameters drug solubility and permeability was determined for ibuprofen. Eight commonly used buffers were examined. Equilibrium solubility, buffer capacity profiles and permeability coefficients, using the in situ rat gut perfusion model, were determined for each medium at 37 degrees C. The solubility of ibuprofen differed sixfold over the range of buffer systems studied. The differences in solubility were associated with different pHs of the buffers when saturated with drug and also the presence of micelles and divalent ions. The solubility of ibuprofen in FeSSIF was significantly higher than predicted from the pH due to micellisation, while that in Krebs was significantly lower due to ibuprofen-calcium salt formation. Buffer capacities varied over a 40-fold range. The pK(a) values of the buffer components were determined from the buffer capacity versus pH profiles and were in good agreement with the thermodynamic values when corrected for temperature and ionic strength. Smaller, but statistically significant differences in P(app) values for ibuprofen were also observed between some of the buffers. During perfusion, pHs of the perfusate samples gradually changed over time towards a median value of approximately 6.5. HBSS gave a P(app) approximately 50% greater than that observed in PBS 7.4. Physicochemical factors such as medium pH, buffer capacity and osmolarity should be considered when determining the P(app) values of ionisable compounds. Care needs to be exercised when comparing P(app) values from different laboratories as buffer composition can have a significant effect on both solubility and permeability of a drug, whose ionisation is substantially changed over the pH range of the buffers. Despite the high amount ionised, ibuprofen appears to be well absorbed and it can be classified as a highly permeable drug.

Interactions of the dipeptide ester prodrugs of acyclovir with the intestinal oligopeptide transporter: competitive inhibition of glycylsarcosine transport in human intestinal cell line-Caco-2

The oligopeptide transporter may be exploited to enhance the absorption of drugs by synthesizing their dipeptide ester prodrugs, which may be recognized as its substrates. Various dipeptide esters of acyclovir (ACV), an antiviral nucleoside analog, were synthesized. Enzymatic hydrolysis and affinity of the prodrugs toward the human intestinal peptide transporter hPEPT1 were studied using the human intestinal Caco-2 cell line. Affinity studies were performed by inhibiting the uptake of [(3)H]glycylsarcosine by the prodrugs. The uptake of glycylsarcosine was found to be saturable at higher concentrations and was competitively inhibited by the prodrugs of ACV. All prodrugs except Tyr-Gly-ACV demonstrated a higher affinity (1.41-4.96 mM) toward hPEPT1 than cephalexin (8.19 +/- 2.12 mM), which was used as a positive control. Two prodrugs, Gly-Val-ACV and Val-Val-ACV, showed comparable affinity to Val-ACV, an amino acid prodrug of ACV recognized by PEPT1/PEPT2. The permeability of Gly-Val-ACV (2.99 +/- 0.59 x 10(-6) cm/s) across Caco-2 was comparable with that of Val-ACV (3.01 +/- 0.21 x 10(-6) cm/s) and was significantly inhibited (63%) in presence of glycylsarcosine. The transport of GVACV across Caco-2 was saturable at higher concentrations, and the parameters were calculated as K(m) 3.16 +/- 0.31 mM and V(max) 0.014 +/- 0.00058 nmol cm(-2) min(-1). Overall, the results suggest that the dipeptide prodrugs of ACV have a high affinity toward the intestinal oligopeptide transporter hPEPT1 and therefore seem to be promising candidates in the treatment of ocular and oral herpesvirus infections, because cornea and intestinal epithelia seem to express the oligopeptide transporters.

Effect of ionization on the variable uptake of valacyclovir via the human intestinal peptide transporter (hPepT1) in CHO cells

Carrier-mediated transport of valacyclovir (vacv), the L-valyl ester prodrug of acyclovir (acv), via the human peptide transporter (hPepT1) has been shown in Xenopus laevis oocytes and in cell lines such as Chinese hamster ovary (CHO) and Caco-2 transfected with the hPepT1 gene. However, significant differences in vacv uptake were observed in those models as extracellular pH varied. The purpose of this work was to characterize the interactions of various ionic species of vacv with the peptide transporter by overexpressing the transporter gene, hPepT1, in CHO cells. Based on the pK(a) values of vacv, it was determined that vacv exists as four different ionic species (di-cationic, cationic, neutral and anionic) with a predominance of cationic and neutral species at physiologically relevant pH conditions. Vacv uptake was shown to increase with increasing pH of the extracellular medium from 5.5 to 7.2. The uptake value was maximal at around pH 7.2 and did not vary for studies done at higher pH. Vacv uptake was concentration dependent and saturable at all pH conditions (5.5, 6.2, 6.8, 7.5 and 7.9) with apparent Michaelis-Menten constants, mean (S.D.), of 7.42(0.32), 6.64(1.20), 5.38(0.88), 2.69(0.23) and 2.23(0.33) mM, respectively. The current results demonstrate that the estimated affinities of the cationic and the neutral species of vacv with hPepT1 are significantly different (7.4 versus 1.2 mM, respectively). Given the axial and radial (microclimate) pH gradients known to exist in the intestine, the greater than six-fold difference in affinity constants suggests that intestinal pH fluctuations may significantly impact upon the variability of vacv uptake.

H(+)-coupled uphill transport of the dipeptide glycylsarcosine by bovine intestinal brush-border membrane vesicles

In monogastric species, a considerable portion of amino acid nitrogen is absorbed across the brush-border membrane of the small intestine as small peptides (e.g., tripeptides and dipeptides). In ruminants, however, this process is less clear. Therefore, we investigated the uptake of radioactively labeled glycylsarcosine as a model dipeptide across the intestinal brush-border membrane using brush-border membrane vesicles prepared from the bovine small intestine. Uphill transport of glycylsarcosine was energized by a transmembrane H+ gradient and was further stimulated by an electrical potential difference across the membrane. Transport mediated by a carrier contributes to total glycylsarcosine transport across the brush-border membrane. Comparison of the apparent kinetic constants between brush-border membranes prepared from the proximal jejunum or ileum revealed similar half-saturating substrate concentrations (1.28 and 0.93 mmol/L for proximal jejunum and ileum, respectively), but maximal transport rates appeared to be somewhat higher in the proximal small intestine (2.15 and 1.20 nmol/mg of protein per 3 s for proximal jejunum and ileum, respectively). Uptake of glycylsarcosine was strongly inhibited by other dipeptides, but the amino acids glycine and sarcosine did not affect transport. Inhibition of glycylsarcosine uptake by cephalexin indicated an affinity of the carrier for cephalosporin antibiotics. Transport of intact dipeptides across the brush-border membrane of the small intestine might be of physiological importance in ruminants because the microbial and dietary proteins resistant to rumen degradation are digested and absorbed in the small intestine.

Peptide mimics as substrates for the intestinal peptide transporter

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.