Delta-aminolevulinic acid (ALA) is the precursor of porphyrin synthesis and has been recently used in vitro and in clinical studies as an endogenous photosensitizer for photodynamic therapy in the treatment of various tumors. For this purpose, ALA is given topically, systemically, or orally. When administered by the oral route, it shows excellent intestinal absorption. ALA is also efficiently reabsorbed in the renal proximal tubule after glomerular filtration. However, the pathways and mechanisms for its transmembrane transport into epithelial cells of intestine and kidney are unknown. Here we demonstrate that ALA uses the intestinal and renal apical peptide transporters for entering into epithelial cells. Kinetics and characteristics of ALA transport were determined in Xenopus laevis ooyctes and Pichia pastoris yeast cells expressing either the cloned intestinal peptide transporter PEPT1 or the renal form PEPT2. By using radiolabeled ALA and electrophysiological techniques in these heterologous expression systems, we established that: (a) PEPT1 and PEPT2 translocate 3H-ALA by saturable and pH-dependent transport mechanisms, (b) that ALA and di-/tripeptides, but not GABA or related amino acids, compete at the same substrate-binding site of the carriers, and (c) that ALA transport is electrogenic in nature as a consequence of H+/ALA cotransport. Reverse transcriptase-PCR analysis performed with specific primers for PEPT1 and PEPT2 in rabbit tissues demonstrates that, in particular, the PEPT2 mRNA is expressed in a variety of other tissues including lung, brain, and mammary gland, which have been shown to accumulate ALA. This suggests that these tissues could take up the porphyrin precusor via expressed peptide transporters, providing the endogenous photosensitizers for efficient photodynamic therapy.
The presence of a proton-coupled electrogenic high-affinity peptide transporter in the apical membrane of tubular cells has been demonstrated by microperfusion studies and by use of brush border membrane vesicles. The transporter mediates tubular uptake of filtered di-and tripeptides and aminocephalosporin antibiotics. We have used expression cloning in Xenopus laevis oocytes for identification and characterization of the renal high-affinity peptide transporter. Injection of poly(A)+ RNA isolated from rabbit kidney cortex into oocytes resulted in expression of a pH-dependent transport activity for the aminocephalosporin antibiotic cefadroxil. After size fractionation of poly(A)+ RNA the transport activity was identified in the 3.0-to 5.0-kb fractions, which were used for construction of a cDNA library. The library was screened for expression of cefadroxil transport after injection of complementary RNA synthesized in vitro from different pools of clones. A single clone (rPepT2) was isolated that stimulated cefadroxil uptake into oocytes "70-fold at a pH of 6.0. Kinetic analysis of cefadroxil uptake expressed by the transporter's complementary RNA showed a single saturable high-affinity transport system shared by dipeptides, tripeptides, and selected amino-f3-lactam antibiotics. Electrophysiological studies established that the transport activity is electrogenic and affected by membrane potential. Sequencing of the cDNA predicts a protein of 729 amino acids with 12 membrane-spanning domains. Although there is a significant amino acid sequence identity (47%) to the recently cloned peptide transporters from rabbit and human small intestine, the renal transporter shows distinct structural and functional differences.
Epithelial cells are exposed to a variety of mechanical forces, but little is known about the impact of these forces on epithelial ion channels. Here we show that mechanical activation of epithelial sodium channels (ENaCs), which are essential for electrolyte and water balance, occurs via an increased ion channel open probability. ENaC activity of heterologously expressed rat (rENaC) and Xenopus (xENaC) orthologs was measured by whole-cell as well as single-channel recordings. Laminar shear stress (LSS), producing shear forces in physiologically relevant ranges, was used to mechanically stimulate ENaCs and was able to activate ENaC currents in whole-cell recordings. Preceding pharmacological activation of rENaC with Zn2+ and xENaC with gadolinium and glibenclamide largely prevented LSS-activated currents. In contrast, proteolytic cleavage with trypsin potentiated the LSS effect on rENaC whereas the LSS effect on xENaC was reversed (inhibition of xENaC current). Further, we found that exposure of excised outside-out patches to LSS led to an increased ion channel open probability without affecting the number of active channels. We suggest that mechano-sensitivity of ENaC may represent a ubiquitous feature for the physiology of epithelia, providing a putative mechanism for coupling transepithelial Na+ reabsorption to luminal transport.
Proton-dependent electrogenic transporters for diand tripeptides have been identified in bacteria, fungi, plants, and mammalian cells. They all show sequenceindependent transport of all possible di-and tripeptides as well as of a variety of peptidomimetics. We used the mammalian intestinal peptide transporter PEPT1 as a model to define the molecular basis for its multisubstrate specificity. By employing computational analysis of possible substrate conformations in combination with transport assays using transgenic yeast cells and Xenopus laevis oocytes expressing PEPT1, the minimal structural requirements for substrate binding and transport were determined. Based on a series of medium chain fatty acids bearing an amino group as a head group (-amino fatty acids, -AFA), we show that electrogenic transport by PEPT1 requires as a minimum the two ionized head groups separated by at least four methylene groups. Consequently, a > 500 pm < 630 pm distance between the two charged centers (carboxylic carbon and amino nitrogen) is sufficient for substrate recognition and transport. Removal of either the amino group or the carboxyl group in -AFA maintained the affinity of the compound for interaction with the transporter but abolished the capability for electrogenic transport. Additional groups in the -AFA backbone that provide more hydrogen bonding sites appear to increase substrate affinity but are not essential. The information provided here does (a) explain the capability of the peptide carrier for sequence-independent transport of thousands of different substrates and (b) set the molecular basis for a rational drug design to increase the absorption of peptide-based drugs mediated by PEPT1.
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