Organic cation/carnitine transporter OCTN2 (Slc22a5) is responsible for carnitine transport across apical membranes of small intestinal epithelial cells in mouse

The organic cation/carnitine transporter OCTN2 is responsible for renal tubular reabsorption of its endogenous substrate, carnitine, although its physiological role in small intestine remains controversial. Here we present direct evidence for a predominant role of OCTN2 in small intestinal absorption of carnitine based on experiments with juvenile visceral steatosis (jvs) mice, which have a hereditary deficiency of the octn2 gene. Uptake of carnitine, assessed with an Ussing-type chamber system, from the apical surface of the small intestine was saturable and higher than that from the basal surface in wild-type mice, whereas carnitine uptake having these characteristics was almost absent in jvs mice. Saturable uptake of carnitine was also confirmed in isolated enterocytes obtained from wild-type mice, and the Km value obtained (approximately 20 microM) was close to that reported for carnitine uptake by human embryonic kidney 293 cells stably expressing mouse OCTN2 (Slc22a5). The carnitine uptake by enterocytes was decreased in the presence of various types of organic cations, and this inhibition profile was similar to that of mouse OCTN2, whereas uptake of carnitine was quite small and unsaturable in enterocytes obtained from jvs mice. Immunohistochemical and immunoprecipitation analyses suggested colocalization of OCTN2 with PDZK1, an adaptor protein that functionally regulates OCTN2. Immunoelectron microscopy visualized both OCTN2 and PDZK1 in microvilli of absorptive epithelial cells. These findings indicate that OCTN2 is predominantly responsible for the uptake of carnitine from the apical surface of mouse small intestinal epithelial cells, and it may therefore be a promising target for oral delivery of therapeutic agents that are OCTN2 substrates.     

Molecular and physiological evidence for multifunctionality of carnitine/organic cation transporter OCTN2

OCTN2 is an Na(+)-dependent transporter for carnitine, which is essential for fatty acid metabolism, and its functional defect leads to fatal systemic carnitine deficiency (SCD). It also transports the organic cation tetraethylammonium (TEA) in an Na(+)-independent manner. Here, we studied the multifunctionality of OCTN2, by examining the transport characteristics in cells transfected with mouse OCTN2 and in juvenile visceral steatosis (jvs) mice that exhibit a SCD phenotype owing to mutation of the OCTN2 gene. The physiological significance of OCTN2 as an organic cation transporter was confirmed by using jvs mice. The embryonic fibroblasts from jvs mice exhibited significantly decreased transport of [(14)C]TEA. Pharmacokinetic analysis of [(14)C]TEA disposition demonstrated that jvs mice showed decreased tissue distribution and renal secretory clearance. In transport experiments using OCTN2-expressing cells, TEA and carnitine showed mutual trans-stimulation effects in their transport, implying a carnitine/TEA exchange mechanism. In addition, Na(+) affected the affinity of carnitine for OCTN2, whereas Na(+) is unlikely to be involved in TEA transport. This is the first molecular and physiological demonstration of the operation of an organic cation transporter in renal apical membrane. The results are consistent with the physiological coupling of carnitine reabsorption with the secretion of organic cations.     

Involvement of carnitine/organic cation transporter OCTN2 (SLC22A5) in distribution of its substrate carnitine to the heart

This study was designed to clarify the pharmacological role of carnitine/organic cation transporter (Octn) family members in mouse heart. Immunohistochemical analysis revealed that Octn1 was exclusively expressed on endothelial cells in blood vessels. Octn2 was detected on the plasma membrane of cardiac muscle cells by immunoelectron microscopy. Octn3 was not detected in the heart. Integration plot analysis showed that coadministration of unlabeled L-carnitine reduced distribution of L-[3H]carnitine to the heart. L-[3H]Carnitine uptake in heart slices was reduced by carnitine analogs and various Octn2 substrates. L-[3H]Carnitine uptake by heart slices from juvenile visceral steatosis (jvs) mice, which have a hereditary octn2 gene deficiency, was negligible. Distribution of [3H]quinidine, another Octn2 substrate, to the heart was not reduced by L-carnitine, and [3H]quinidine uptake in heart slices was Na(-)-independent and inhibited by cationic drugs, but not carnitine analogs. [3H]Quinidine uptake by heart slices from jvs mice was similar to that of wild-type mice. These results demonstrate that OCTN2 is functionally expressed on the plasma membrane of muscle cells and is involved in distribution of carnitine to the heart. Some mechanism(s) other than OCTN2 is involved in the distribution of quinidine to the heart.     

Activities of cytochrome p450 enzymes in liver and kidney microsomes from systemic carnitine deficiency mice with a gene mutation of carnitine/organic cation transporter

Juvenile visceral steatosis (jvs) mice, isolated from the C3H-H-2 degrees strain, exibit a systemic carnitine deficiency (SCD) phenotype and develop fatty liver, hyperammonemia and hypoglycemia. This phenotype is caused by a missense mutation (Leu352Arg) of a sodium-dependent carnitine/organic cation transporter, Octn2 (Slc22a5). The jvs mouse could be a useful model for pharmacokinetics and drug metabolism studies concerning Octn2 substrate drugs. In the present study, the effects of the SCD phenotype on the cytochrome P450 (P450 or CYP) dependent activities of four endobiotic and seven xenobiotic oxidations catalyzed by liver and kidney microsomes from jvs mice were investigated. The jvs-type mutation was genotyped by PCR-RFLP. The contents of total P450 and NADPH-P450 reductase were similar in the the liver microsomes from male or female mice of the wild-type and those heterozygous or homozygous for the jvs-type mutation. The 6beta-hydroxylation activities of testosterone and progesterone (marker for Cyp3a) based on the protein contents were 1.2- to 2.0-fold higher in liver microsomes from jvs/jvs-type mice compared to jvs/wt- or wt/wt-type mice. Coumarin 7-hydroxylation activities (marker for Cyp2a) were decreased to 0.7-fold in the male jvs/jvs-type mice. The activities of lauric acid 12-hydroxylation (a marker for Cyp4a) and aniline p-hydroxylation (a marker for Cyp2e1) in liver microsomes were increased 1.4- to 1.9-fold in female jvs/jvs-type mice. Genotoxic activation of 2-aminofluorene (a marker for Cyp4b1) by male and female mouse kidney microsomes were not affected by the SCD phenotype. These results demonstrated that the SCD phenotype affected the P450-dependent catalytic activities in liver microsomes. The jvs mouse could provide valuable information in drug interaction and drug metabolism studies of OCTN2 substrate drugs and new compounds in development.     

Biopharmaceutical studies on molecular mechanisms of membrane transport

By incorporating the transporter-mediated or receptor-mediated transport process in physiologically based pharmacokinetic models, we succeeded in the quantitative prediction of plasma and tissue concentrations of beta-lactam antibiotics, insulin, pentazocine, quinolone antibacterial agents, and inaperizone and digoxin. The author's research on transporter-mediated pharmacokinetics focuses on the molecular and functional characteristics of drug transporters such as oligopeptide transporter, monocarboxylic acid transporter, anion antiporter, organic anion transporters, organic cation/carnitine transporters (OCTNs), and the ATP-binding cassette transporters P-glycoprotein and MRP2. We have successfully demonstrated that these transporters play important roles in the influxes and/or effluxes of drugs in intestinal and renal epithelial cells, hepatocytes, and brain capillary endothelial cells that form the blood-brain barrier. In the systemic carnitine deficiency (SCD) phenotype mouse model, juvenile visceral steatosis (jvs) mouse, a mutation in the OCTN2 gene was found. Furthermore, several types of mutation in human SCD patients were found, demonstrating that OCTN2 is a physiologically important carnitine transporter. Interestingly, OCTNs transport carnitine in a sodium-dependent manner and various cationic drugs transport it in a sodium-independent manner. OCTNs are thought to be multifunctional transporters for the uptake of carnitine into tissue cells and for the elimination of intracellular organic cationic drugs.     

Regulation of Octn2 transporter (SLC22A5) by peroxisome proliferator activated receptor alpha

The tissue distribution and disposition of carnitine, which plays an important role in the transport of long-chain fatty acids across the mitochondrial inner membrane for beta-oxidation, are well controlled by carnitine transporter organic cation/carnitine transporter 2 (OCTN2). Since little information is available on regulation of the expression of the OCTN2 gene, we examined the factors that affect the expression level of rat Octn2 (rOctn2), focusing on nuclear receptor peroxisome proliferator activated receptor alpha (PPARalpha), which regulates expression of genes associated with beta-oxidation of fatty acids. mRNA of rOctn2 was induced by the PPARalpha ligand fenofibrate in primary-cultured rat hepatocytes. Further, the PPARalpha ligand Wy14643 increased the expression of Octn2 in wild-type mice, but not in PPARalpha knockout mice. Analysis of the rOctn2 promoter region suggested the presence of putative cis elements of PPARalpha. Wistar rats treated with intraperitoneal fenofibrate administration showed increased expression of rOctn2 mRNA in liver, and uptake of [3H]carnitine by freshly isolated hepatocytes derived from those rats was also increased. In conclusion, our results indicate that the nuclear receptor PPARalpha directly up-regulates the expression of rOctn2 and increases the hepatic uptake of carnitine via rOctn2.     

Treatment with pharmacological peroxisome proliferator-activated receptor alpha agonist clofibrate causes upregulation of organic cation transporter 2 in liver and small intestine of rats.

Activation of PPARalpha by clofibrate has recently been shown to cause upregulation of carnitine transporter organic cation transporter (OCTN) 2 and elevated carnitine concentrations in rat liver. The present study has been conducted to further explore the effect of clofibrate on OCTN expression, carnitine biosynthesis, and carnitine accumulation in different rat tissues, and thus two groups of rats were fed diets containing 0.5% clofibrate or 0% clofibrate (control group). PPARalpha-responsive genes were markedly upregulated in the liver (P<0.05), moderately in small intestine, but only slightly in other extrahepatic tissues by clofibrate. Relative mRNA concentration of OCTN2 in liver and small intestine was increased in rats fed clofibrate (P<0.05), whereas in other extrahepatic tissues mRNA concentration of OCTN2 did not differ between treatment groups. Concentration of total carnitine was higher in liver and small intestine but lower in plasma, kidney, and brain of rats fed clofibrate (P<0.05). Moreover, concentration of the carnitine precursor trimethyllysine and mRNA concentrations of specific genes involved in carnitine biosynthesis were increased in livers of rats fed clofibrate (P<0.05). The present study shows that clofibrate causes not only upregulation of OCTN2 in the liver but also in small intestine, and thus suggests that an increased intestinal absorption of carnitine might also contribute to the clofibrate-induced increase in hepatic carnitine concentration. Furthermore, the present results also indicate that an increased carnitine biosynthesis also contributes to the clofibrate-induced increase in hepatic carnitine concentration.     

Functional regions of organic cation/carnitine transporter OCTN2 (SLC22A5): roles in carnitine recognition

The organic cation/carnitine transporter OCTN2 transports carnitine in a sodium-dependent manner, whereas it transports organic cations sodium-independently. To elucidate the functional domain in OCTN2, we constructed chimeric proteins of human OCTN2 (hOCTN2) and mouse OCTN3 (mOCTN3) and introduced mutations at several amino acids conserved among human, rat and mouse OCTN2. We found that transmembrane domains (TMD) 1-7 are responsible for organic cation transport and for sodium dependence in carnitine transport. Within TMD1-7, Q180 and Q207 of hOCTN2 are the critical amino acids for the sodium dependence, and double mutation of Q180 and Q207 resulted in minimal change in transport activity when sodium was removed from the uptake medium. We propose that sodium-dependent affinity for carnitine is dependent on sodium recognition by these critical amino acids in hOCTN2, whereas carnitine transport by OCTN2 requires functional linkage between TMD1-7 and TMD11.     

PDZ adaptor protein PDZK2 stimulates transport activity of organic cation/carnitine transporter OCTN2 by modulating cell surface expression.

A part of the organic cation transporter families (OCT3, OCTN1, and OCTN2) has recently been identified to physically interact with PDZ (PSD95, Dlg, and ZO1) domain-containing proteins, although the physiological relevance of such interaction has not yet been fully examined. Here we have examined the stimulatory effect of PDZK2 [also named NaPi-Cap2 and intestinal and kidney-enriched PDZ protein (IKEPP)] on those cation transporters. In HEK293 cells, coexpression with PDZK2 increased the uptake of carnitine by OCTN2 with minimal effect on its substrate recognition specificity, but not for transport activity of OCT3 or OCTN1. The stimulatory effect of PDZK2 on OCTN2 was compatible with an approximately 2 times increase in transport capacity and can be accounted for by the increase in cell surface expression of OCTN2. Coexpression of PDZK2 did not affect carnitine transport activity of OCTN2 with deletion of the last four amino acids, which were found to be important for the interaction, suggesting involvement of physical interaction of the two proteins in the increase of cell surface expression of OCTN2. In mouse kidney, colocalization of PDZK2 and OCTN2 occurred predominantly in the region that was close to, but not the same as, the surface of apical membranes where OCTN2 alone was observed, suggesting the existence of OCTN2 in the subapical compartment that interacts with PDZK2. The present data have thus proposed an "intracellular pool" for OCTN2 that may be relevant to the stabilization of cell surface expression of OCTN2, thereby increasing transport activity for carnitine.     

Blood-brain barrier transport and brain distribution of morphine-6-glucuronide in relation to the antinociceptive effect in rats--pharmacokinetic/pharmacodynamic modelling.

1. The objective of this study was to investigate the contribution of the blood-brain barrier (BBB) transport to the delay in antinociceptive effect of morphine-6-glucuronide (M6G), and to study the equilibration of M6G in vivo across the BBB with microdialysis measuring unbound concentrations. 2. On two consecutive days, rats received an exponential infusion of M6G for 4 h aiming at a target concentration of 3000 ng ml(-1) (6.5 microM) in blood. Concentrations of unbound M6G were determined in brain extracellular fluid (ECF) and venous blood using microdialysis and in arterial blood by regular sampling. MD probes were calibrated in vivo using retrodialysis by drug prior to drug administration. 3. The half-life of M6G was 23+/-5 min in arterial blood, 26+/-10 min in venous blood and 58+/-17 min in brain ECF (P<0.05; brain vs blood). The BBB equilibration, expressed as the unbound steady-state concentration ratio, was 0.22+/-0.09, indicating active efflux in the BBB transport of M6G. A two-compartment model best described the brain distribution of M6G. The unbound volume of distribution was 0.20+/-0.02 ml g brain(-1). The concentration-antinociceptive effect relationships exhibited a clear hysteresis, resulting in an effect delay half-life of 103 min in relation to blood concentrations and a remaining effect delay half-life of 53 min in relation to brain ECF concentrations. 4. Half the effect delay of M6G can be explained by transport across the BBB, suggesting that the remaining effect delay of 53 min is a result of drug distribution within the brain tissue or rate-limiting mechanisms at the receptor level.     

Involvement of Carnitine/Organic Cation Transporter OCTN1/SLC22A4 in Gastrointestinal Absorption of Metformin

Metformin is a widely used oral anti-diabetic, but the molecular mechanism(s) of its gastrointestinal membrane permeation remains unclear. Here, we examined the role of carnitine/organic cation transporter OCTN1/SLC22A4, which is localized on apical membranes of small intestine in mice and humans, in metformin absorption. The maximum plasma concentration (C_max) after oral administration of metformin (50 mg/kg) in octn1 gene knockout mice (octn1^-/-) was higher than that in wild-type mice, with only a minimal difference in terminal half-life, but C_max in octn1is^-/- mice given a higher dose (175 mg/kg) was lower than that in wildtype mice. Systemic elimination of metformin after intravenous administration was similar in the two strains, suggesting the possible involvement of OCTN1 in the gastrointestinal absorption. OCTNl-mediated uptake of metformin was observed in human embryonic kidney 293 cells transfected with mouse OCTN1 gene, but much lower than the uptake of the typical substrate [³H]ergothioneine (ERGO). In particular, the distribution volume for OCTNl-mediated uptake increased markedly and then tended to decrease as the metformin concentration was increased. Efflux of metformin preloaded in intestinal epithelial cell line Caco-2 was inhibited by ERGO. Overall, the present findings suggest that OCTN1 transports metformin and may be involved in its oral absorption in small intestine.     

The Simultaneous Estimation of the Influx and Efflux Blood-Brain Barrier Permeabilities of Gabapentin Using a Microdialysis-Pharmacokinetic Approach

Purpose. To determine the apparent bidirectional permeabilities of gabapentin (GBP) across the blood-brain barrier (BBB) using a novel microdialysis-pharmacokinetic approach. Methods. Rats were administered intravenous infusions of [¹⁴C]GBP to achieve clinically relevant steady-state plasma concentrations. Microdialysis was used to monitor GBP concentration in brain extracellular fluid (ECF) in conscious animals. Brain tissue GBP concentration was measured at termination. The BBB influx (CL₁) and efflux (CL₂) permeabilities of GBP were estimated with a hybrid pharmacokinetic model assuming that transport between intra-and extracellular space was more rapid than transport across the BBB. The time course of GBP concentration in brain tissue was determined independently to validate the model assumption. Results and Conclusions. Simulations of the concentration-time course of GBP in brain tissue based on this modeling correlated well with the time-course of brain tissue concentrations determined after intravenous bolus administration and validated this pharmacokinetic-microdialysis approach for estimation of BBB permeabilities. The values for CL₁ and CL₂ were 0.042 (0.017) and 0.36 (0.16) ml/min·g-brain, respectively, indicating that GBP was more efficiently transported from brain ECF to plasma. The total brain tissue concentration of GBP was significantly higher than the ECF concentration at steady-state due to intracellular accumulation and tissue binding, that if not considered, will lead to underestimated efflux BBB permeability using the tissue homogenate-pharmacokinetic approach.     

In Situ Transport of Vinblastine and Selected P-glycoprotein Substrates: Implications for Drug-Drug Interactions at the Mouse Blood-Brain Barrier

PURPOSE: To study the intrinsic parameters of P-glycoprotein (P-gp) transport and drug-drug interactions at the blood-brain barrier (BBB), as few quantitative in vivo data are available. These parameters could be invaluable for comparing models and predicting the in vivo implications of in vitro studies. METHODS: The brains of P-gp-deficient mice mdr1a(-/-) and wild-type mice were perfused in situ using a wide range of colchicine, morphine, and vinblastine concentrations. The difference between the uptake by the wild-type and P-gp-deficient mice gave the P-gp-linked apparent transport at the BBB. Drug-drug interactions were examined using vinblastine and compounds that bind to P-gp sites (verapamil, progesterone, PSC833) other than the vinblastine site to take into account the multispecific drug P-gp recognition. RESULTS: P-gp limited the brain uptake of morphine and colchicine in a concentration-independent way up to 2 mM. In contrast, vinblastine inhibited its own P-gp transport with an IC50 of approximately 56 microM and a Hill coefficient of approximately 4. The vinblastine efflux by P-gp was described by a Km at 16 microM and a maximal efflux velocity, Jmax, of approximately 8 pmol s(-1) g(-1) of brain. Similarly, vinblastine brain transport was increased by inhibiting P-gp as shown by the IC50 ranking, which was PSC833 < verapamil < vinblastine < progesterone. CONCLUSIONS: P-gp is responsible for both capacity-limited and -unlimited transport of P-gp substrates at the mouse BBB. In situ perfusion of mdr1a(-/-) and wild-type mouse brains could be used to predict drug-drug interactions for P-gp at the mouse BBB.     

Comparison of in vitro BBMEC permeability and in vivo CNS uptake by microdialysis sampling

The studies presented in this report were designed to assess the correlation of the bovine brain microvessel endothelial cell (BBMEC) apparent permeability coefficient (P_app) and in vivo BBB penetration using microdialysis sampling. A mathematical model was developed to describe the relationship of brain extracellular fluid (ECF) concentration to free drug in plasma. The compounds studied have a broad range of physico-chemical characteristics and have widely varying in vitro and in vivo permeability across the blood–brain barrier (BBB). BBMEC permeability coefficients vary in magnitude from a low of 0.9×10⁻⁵ cm/s to a high value of 7.5×10⁻⁵ cm/s. Corresponding in vivo measurements of BBB permeability are represented by clearance (CL_in) into the brain ECF and range from a low of 0.023 μl/min/g to a high of 12.9 μl/min/g. While it is apparent that in vitro data from the BBMEC model can be predictive of the in vivo permeability of a compound across the BBB, there are numerous factors both prior to and following entry into the brain which impact the ultimate uptake of a compound. Even in the presence of high BBB permeability, factors such as high plasma protein binding, active efflux across the BBB, and metabolism within the CNS can greatly limit the ultimate concentrations achieved. In addition, concentrations in the intracellular space may not be the same as concentrations in the extracellular space. While these data show that the BBMEC permeability is predictive of the in vivo BBB permeability, the complexity of the living system makes prediction of brain concentrations difficult, based solely on the in vitro measurement.     

Receptor-mediated abeta amyloid antibody targeting to Alzheimer's disease mouse brain

The goal of this work is the reduction in the Abeta amyloid peptide burden in brain of Alzheimer's disease (AD) transgenic mice without the concomitant elevation in plasma Abeta amyloid peptide. An anti-Abeta amyloid antibody (AAA) was re-engineered as a fusion protein with a blood-brain barrier (BBB) molecular Trojan horse. The AAA was engineered as a single chain Fv (ScFv) antibody, and the ScFv was fused to the heavy chain of a chimeric monoclonal antibody (mAb) against the mouse transferrin receptor (TfR), and this fusion protein was designated cTfRMAb-ScFv. The cTfRMAb-ScFv protein penetrates mouse brain from blood via transport on the BBB TfR, and the brain uptake is 3.5% of injected dose/gram brain following an intravenous administration. Double transgenic APPswe,PSEN1dE9 mice were studied at 12 months of age. The mice were shown to have extensive Abeta amyloid plaques in cerebral cortex based on immunocytochemistry. The mice were treated every 3-4 days by intravenous injections of either saline or the cTfRMAb-ScFv fusion protein at an injection dose of 1 mg/kg for 12 consecutive weeks. The brain Aβ1??2 concentration was reduced 40% in the fusion protein treated mice, without any elevation in plasma Aβ1??2 concentration. No cerebral microhemorrhage was observed in the treated mice. These results show that brain-penetrating antibody pharmaceutics can be developed for brain disorders such as AD following the re-engineering of the antibody as a fusion protein that is transported across the BBB via receptor-mediated transport.     

Carnitine and γ‐Butyrobetaine Stimulate Elimination of Meldonium due to Competition for OCTN2‐mediated Transport

Meldonium (3‐(2,2,2‐trimethylhydrazinium)propionate) is the most potent clinically used inhibitor of organic cation transporter 2 (OCTN2). Inhibition of OCTN2 leads to a decrease in carnitine and acylcarnitine contents in tissues and energy metabolism optimization‐related cardioprotective effects. The recent inclusion of meldonium in the World Anti‐Doping Agency List of Prohibited Substances and Methods has raised questions about the pharmacokinetics of meldonium and its unusually long elimination time. Therefore, in this study, the rate of meldonium washout after the end of the treatment was tested with and without administration of carnitine, γ‐butyrobetaine (GBB) and furosemide to evaluate the importance of competition for OCTN2 transport in mice. Here, we show that carnitine and GBB administration during the washout period effectively stimulated the elimination of meldonium. GBB induced a more pronounced effect on meldonium elimination than carnitine due to the higher affinity of GBB for OCTN2. The diuretic effect of furosemide did not significantly affect the elimination of meldonium, carnitine and GBB. In conclusion, the competition of meldonium, carnitine and GBB for OCTN2‐mediated transport determines the pharmacokinetic properties of meldonium. Thus, due to their affinity for OCTN2, GBB and carnitine but not furosemide stimulated meldonium elimination. During long‐term treatment, OCTN2‐mediated transport ensures a high muscle content of meldonium, while tissue clearance depends on relatively slow diffusion, thus resulting in the unusually long complete elimination period of meldonium.     

Quantitative proteomics of transporter expression in brain capillary endothelial cells isolated from P-glycoprotein (P-gp), breast cancer resistance protein (Bcrp), and P-gp/Bcrp knockout mice

The objective of this study was to quantitatively examine the protein expression of relevant transporters and other proteins in the brain capillary endothelial cells isolated from wild-type mice and P-glycoprotein (P-gp), breast cancer resistance protein (Bcrp), and P-gp/Bcrp knockout mice. After the isolation of brain capillary endothelial cells, a highly sensitive liquid chromatography-tandem mass spectrometry method with multiple reaction monitoring was used to determine the quantitative expression of membrane transporters at the blood-brain barrier (BBB) of the various mouse genotypes. Quantitative expression of 29 protein molecules, including 12 ATP-binding cassette transporters, 10 solute carrier transporters, five receptors, and two housekeeping proteins, was examined by quantitative proteomics in the four mouse genotypes. There was no significant difference in the expression of P-gp between the wild-type and Bcrp1(-/-) mice. Likewise, Bcrp expression was not significantly different between the wild-type and Mdr1a/b(-/-) mice. There was no significant difference in the expression of any of the measured proteins in the brain capillary endothelial cells across the genotypes, except for the lack of expression of the corresponding protein in the mice that had a genetic deletion of P-gp or Bcrp. In conclusion, using a quantitative proteomic approach, we have shown that there are no changes in the expression of several relevant transporters in brain capillary endothelial cells isolated from single and combination knockout mice. These data suggest that the mechanism behind the functional compensation between P-gp and Bcrp at the BBB is not related to compensatory changes in transporter expression.     

Modelling of the blood-brain barrier transport of morphine-3-glucuronide studied using microdialysis in the rat: involvement of probenecid-sensitive transport

The objective of this study was to investigate the impact of probenecid on the blood-brain barrier (BBB) transport of morphine-3-glucuronide (M3G). Two groups of rats received an exponential infusion of M3G over 4 h to reach a target plasma concentration of 65 microM on two consecutive days. Probenecid was co-administered in the treatment group on day 2. Microdialysis was used to estimate unbound M3G concentrations in brain extracellular fluid (ECF) and blood. In vivo recovery of M3G was calculated with retrodialysis by drug, preceding the drug administration. The BBB transport was modelled using NONMEM. In the probenecid group, the ratio of the steady-state concentration of unbound M3G in brain ECF to that in blood was 0.08+/-0.02 in the absence and 0.16+/-0.05 in the presence of probenecid (P=0.001). In the control group, no significant difference was found in this ratio between the 2 days (0.11+/-0.05 and 0.10+/-0.02, respectively). The process that appears to be mainly influenced by probenecid is influx clearance into the brain (0.11 microl min(-1) g-brain(-1) vs 0.17 microl min(-1) g-brain(-1), in the absence vs presence of probenecid, P:<0.001). The efflux clearance was 1.15 microl min(-1) g-brain(-1). The half-life of M3G was 81+/-25 min in brain ECF vs 22+/-2 min in blood (P<0.0001). Blood pharmacokinetics was not influenced by probenecid. In conclusion, a probenecid-sensitive transport system is involved in the transport of M3G across the BBB.     

Treatment with pharmacological peroxisome proliferator-activated receptor alpha agonist clofibrate increases intestinal carnitine absorption in rats

Activation of PPARalpha by clofibrate has recently been shown to cause upregulation of the high-affinity carnitine transporter novel organic cation transporter (OCTN) 2 in small intestine. This strongly suggests that PPARalpha activation in response to clofibrate treatment improves the absorption of carnitine from the diet. To test this hypothesis, we performed an experiment with rats which were fed diets with or without 5gclofibrate/kg diet and with or without 5gl-carnitine/kg diet. PPARalpha was significantly activated by clofibrate in small intestine as evidenced by increased relative mRNA concentrations of the PPARalpha target gene acyl-CoA oxidase (P<0.05). Relative mRNA concentration of OCTN2 in small intestine was significantly increased by clofibrate (P<0.05) but not the carnitine supplementation, whereas relative mRNA concentrations of other carnitine transporters (OCTN1, ATB(0+)) in small intestine were not influenced by either clofibrate or carnitine. The absorption rate of carnitine in small intestine was markedly higher in rats treated with clofibrate than in those treated without clofibrate (P<0.05). In conclusion, the present study shows that administration of clofibrate to rats increases carnitine absorption in small intestine which is probably due to the observed upregulation of OCTN2 mediated by activation of PPARalpha.