Seven novel single nucleotide polymorphisms in the human SLC22A1 gene encoding organic cation transporter 1 (OCT1)

Twenty genetic variations, including seven novel ones, were found in the human SLC22A1 gene, which encodes organic cation transporter 1, from 116 Japanese individuals. The novel variations were as follows: -94C>A in the 5'-untranslated region (A of the translation start codon is numbered +1 in the cDNA sequence; MPJ6_OC1001), 350C>T (MPJ6_OC1004), IVS1-35T>C (MPJ6_OC1006), 561G>A (MPJ6_OC1010), IVS6+75C>G (MPJ6_OC1014), IVS8+108A>G (MPJ6_OC1017), and 1671_1673delATG (MPJ6_OC1020). The frequencies were 0.082 for IVS1-35T>C, 0.022 for IVS6+75C>G, 0.009 for 561G>A, and 0.004 for the other 4 variations. Among them, 350C>T resulted in the amino acid substitution Pro117Leu, which is located in the large extracellular loop between transmembrane domains 1 and 2. Also, we detected the four previously reported nonsynonymous variations, 123C>G (Phe41Leu), 480C>G (Phe160Leu), 1022C>T (Pro341Leu), and 1222A>G (Met408Val) with frequencies of 0.004, 0.086, 0.168, and 0.810, respectively.     

Twelve novel single nucleotide polymorphisms in the CES2 gene encoding human carboxylesterase 2 (hCE-2)

Twelve novel single nucleotide polymorphisms (SNPs) were found in the CES2 gene from 153 Japanese individuals, who were administered irinotecan or steroidal drugs. The detected SNPs were as follows:1) SNP, MPJ6_CS2001; GENE NAME, CES2; ACCESSION NUMBER, NT_010498.13; LENGTH, 25 bases; 5'-CTGGAACAACTCG/CCTCCCCTCGGAA-3'. 2) SNP, MPJ6_CS2002; GENE NAME, CES2; ACCESSION NUMBER, NT_010498.13; LENGTH, 25 bases; 5'-AACCACCACCGCT/CGATCCTAGCAGG-3'. 3) SNP, MPJ6_CS2003; GENE NAME, CES2; ACCESSION NUMBER, NT_010498.13; LENGTH, 25 bases; 5'-AAATGTTTGTCAA/GGTGGATAAATGA-3'. 4) SNP, MPJ6_CS2004; GENE NAME, CES2; ACCESSION NUMBER, NT_010498.13; LENGTH, 25 bases; 5'-CCTCCTATCGATC/GCCCCAGCGCGCT-3'. 5) SNP, MPJ6_CS2005; GENE NAME, CES2; ACCESSION NUMBER, NT_010498.13; LENGTH, 25 bases; 5'-GCCAGTCCCATCC/TGGACCACACACA-3'. 6) SNP, MPJ6_CS2006; GENE NAME, CES2; ACCESSION NUMBER, NT_010498.13; LENGTH, 25 bases; 5'-GCTGGGCAACCCG/AGGCTGAGCGGGG-3'. 7) SNP, MPJ6_CS2007; GENE NAME, CES2; ACCESSION NUMBER, NT_010498.13; LENGTH, 25 bases; 5'-CAAGCACGCAACC/TGGCAACTGGGGC-3'. 8) SNP, MPJ6_CS2008; GENE NAME, CES2; ACCESSION NUMBER, NT_010498.13; LENGTH, 25 bases; 5'-CATGGAGAGTGGC/TGTGGCCCTCCTG-3'. 9) SNP, MPJ6_CS2009; GENE NAME, CES2; ACCESSION NUMBER, NT_010498.13; LENGTH, 25 bases; 5'-CCTGTTCTTGGCC/TAGGGCCTTGGGC-3'. 10) SNP, MPJ6_CS2010; GENE NAME, CES2; ACCESSION NUMBER, NT_010498.13; LENGTH, 25 bases; 5'-CCCATCCCCAGCT/AACAGACTCTCTC-3'. 11) SNP, MPJ6_CS2011; GENE NAME, CES2; ACCESSION NUMBER, NT_010498.13; LENGTH, 25 bases; 5'-TCCACCTGGGGTA/GGATGTTGCCTCC-3'. 12) SNP, MPJ6_CS2013; GENE NAME, CES2; ACCESSION NUMBER, NT_010498.13; LENGTH, 25 bases; 5'-GGACTGGGGACCG/AAGGTCTCGGGGG-3'The frequencies were 0.029 for MPJ6_CS2004 and CS2013, 0.026 for MPJ6_CS2009, 0.013 for MPJ6_CS2001, 0.007 for MPJ6_CS2003, and 0.003 for the other 7 SNPs. Among these SNPs, MPJ6_CS2005 (100C>T) resulted in an amino acid alteration (R34W), and MPJ6_CS2007 (579C>T) and MPJ6_CS2008 (765C>T) were synonymous (T193T and G255G, respectively). Furthermore, MPJ6_CS2011 (IVS8-2A>G) resulted in variation at ther 3' splice acceptor site.     

Functional characterization of human organic cation transporter OCTN1 single nucleotide polymorphisms in the Japanese population

The organic cation transporter OCTN1 (SLC22A4) is expressed ubiquitously, with strong expression in kidney, trachea, bone marrow, and fetal liver, and it mediates transport of organic cations in a pH-dependent manner. Recent studies have identified single nucleotide polymorphisms (SNPs) of OCTN1 in the Japanese population. Two SNPs present in the exon regions, c1063t and g1531a, cause amino acid mutation, Thr306Ile (T306I) and Gly462Glu (G462E), respectively. We examined the influence of these SNPs on the intracellular localization, protein expression, and transport activity of OCTN1. Immunocytochemical analysis showed similar localizations of OCTN1 in cellular membranes of HEK293 cells transiently transfected with an expression plasmid DNA for OCTN1 or its SNP allelic variants. The Km and Vmax values for tetraethylammonium (TEA) uptake by T306I were similar to those of the wild-type even when the Vmax value was normalized for the expression level of OCTN1 protein. In contrast, G462E had almost negligible transport activity, although the protein expression level of G462E was equivalent to that of the wild-type. We conclude that the SNP that causes the single amino acid mutation T306I does not affect TEA transport activity, whereas the mutation G462E abrogates the TEA transport activity, presumably affecting the physiological function of OCTN1 and/or the pharmacological characteristics of its substrates.     

Organic cation transporter OCT/SLC22A and H(+)/organic cation antiporter MATE/SLC47A are key molecules for nephrotoxicity of platinum agents

Platinum agents have been widely used in cancer chemotherapy for a long time. Cisplatin, carboplatin, oxaliplatin and nedaplatin have a common chemical structure consisting of platinum, carrier groups and leaving groups, and undergo the similar mechanism of cytotoxicity. However, each agent differs in its efficacy and adverse effects, although the molecular mechanism involved is unclear. Recently, it was reported that organic cation transporter OCT/SLC22A, and multidrug and toxin extrusion MATE/SLC47A play a role in the pharmacokinetics of platinum agents. Only cisplatin induces nephrotoxicity and the toxicity is kidney-specific. Kidney-specific OCT2 mediates the transport of cisplatin and is the determinant of cisplatin-induced nephrotoxicity. In addition, cisplatin and oxaliplatin are substrates for these transporters, but carboplatin and nedaplatin are not. Substrate specificity could regulate the features of platinum agents. In this commentary, we will discuss the characteristics of OCT and MATE, and demonstrate the recent topics about the relationship between the transport of platinum agents by organic cation transporters and their pharmacological characteristics.     

Recent advances in drug delivery via the organic cation/carnitine transporter 2 (OCTN2/SLC22A5)

Introduction: Transporters in the plasma membrane have been exploited successfully for the delivery of drugs in the form of prodrugs and nanoparticles. Organic cation/carnitine transporter 2 (OCTN2, SLC22A5) has emerged as a viable target for drug delivery. OCTN2 is a Na⁺-dependent high-affinity transporter for L-carnitine and a Na⁺-independent transporter for organic cations. OCTN2 is expressed in the blood-brain barrier, heart, liver, kidney, intestinal tract and placenta and plays an essential role in L-carnitine homeostasis in the body.

Areas covered: In recent years, several studies have been reported in the literature describing the utility of OCTN2 to enhance the delivery of drugs, prodrugs and nanoparticles. Here we summarize the salient features of OCTN2 in terms of its role in the cellular uptake of its physiological substrate L-carnitine in physiological and pathological context; the structural requirements for recognition and the recent advances in OCTN2-targeted drug delivery systems, including prodrugs and nanoparticles, are discussed.

Expert opinion: This transporter has great potential to be utilized as a target for drug delivery to improve oral absorption of drugs in the intestinal tract. It also has potential to facilitate the transfer of drugs across the biological barriers such as the blood-brain barrier, blood-retinal barrier, and maternal-fetal barrier.     

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.     

Species specificity profiling of rat and human organic cation/carnitine transporter Slc22a5/SLC22A5 (Octn2/OCTN2)

The purpose of this study was to characterize the uptake of carnitine, the physiological substrate, and the uptake of 3-(2,2,2-trimethylhydrazinium)propionate, a consensus substrate by rat Octn2 and human OCTN2 transporters as well as to characterize drug-mediated inhibition of l-carnitine uptake by the rat and human orthologs overexpressed in CHO-K1 cells. l-carnitine and 3-(2,2,2-trimethylhydrazinium)propionate were found to be a lower affinity substrate for rat Octn2 (K_M = 32.66 ± 5.11 μM and 23.62 ± 4.99 μM respectively) than for human OCTN2 (K_M = 3.08 ± 0.74 μM and 7.98 ± 0.63 μM). The intrinsic clearance (CL_int) value for carnitine was higher for the human than for the rat transporter (22.82 ± 5.57 ml/min*mg vs 4.008 ± 0.675 ml/min*mg). For 3-(2,2,2-trimethylhydrazinium)propionate, in contrast, the CL_int value for rat Octn2 was higher than for human OCTN2 (323.9 ± 72.8 ml/min*mg vs 65.11 ± 5.33 ml/min*mg).Furthermore, many pharmacologically important drugs were shown to affect l-carnitine transport by Octn2/OCTN2. The correlation between the IC₅₀ datasets for the rat and human transporter resulted in an r value of 0.47 (p > 0.05). However, the greatest difference was less than seven-fold and 13 of 15 compounds yielded a difference less than 3-fold.Thus, the transporters from these two species showed an overlapping but somewhat different substrate and inhibitor specificity.     

Differential transport of platinum compounds by the human organic cation transporter hOCT2 (hSLC22A2)

Background:

Solute carriers (SLCs), in particular organic cation transporters (OCTs), have been implicated in the cellular uptake of platinum-containing anticancer compounds. The activity of these carriers may determine the pharmacokinetics and the severity of side effects, including neuro- and nephrotoxicity of platinum-based chemotherapy. As decreased drug accumulation is a key mechanism of platinum resistance, SLCs may also contribute to the development of resistance. Here, we define the role of hSLC22A2 (OCT2) in the cellular uptake of platinum compounds.

Experimental approach:

Human embryonic kidney (HEK) 293 cells stably expressing the hSLC22A2 gene (HEK293/hSLC22A2) were used in platinum accumulation studies. Following a 2 h exposure to various platinum compounds (100 µM), intracellular platinum levels were determined by flameless atomic absorption spectrometry.

Key results:

HEK293/hSLC22A2 cells, compared with HEK293/Neo control cells, displayed significant increases in oxaliplatin (28.6-fold), Pt[DACH]Cl₂ (20.6-fold), ormaplatin (8.1-fold), tetraplatin (4.5-fold), transplatin (3.7-fold) and cisplatin (1.3-fold), but not carboplatin. SLC22A2-mediated transport could be inhibited by 1-methyl-4-phenylpyridinium. Furthermore, hSLC22A2-mediated oxaliplatin and cisplatin accumulation was time- and concentration-dependent, but non-saturable. Expression of hSLC22A2 in HEK293 cells resulted in enhanced sensitivity to oxaliplatin (12-fold) and cisplatin (1.8-fold). Although, hSLC22A2 mRNA expression was frequently found in ovarian cancer cell lines, its expression in clinical ovarian cancer specimens (n= 80) was low and did not correlate with the treatment outcome of platinum-based regimens.

Conclusions and implications:

The hSLC22A2 drug transporter is a critical determinant in the uptake and cytotoxicity of various platinum compounds, particularly oxaliplatin.     

Functional characterization of nonsynonymous single nucleotide polymorphisms in the human organic anion transporter 4 (hOAT4)

Background and purpose:

The human organic anion transporter (hOAT) family of transmembrane carrier proteins mediate the cellular flux of anionic substances, including certain hormones and anti-cancer drugs. hOAT4 is highly expressed at the apical membrane of the renal tubular cell and facilitates drug re-absorption in the kidney. In the present study, the impact of 10 nonsynonymous single nucleotide polymorphisms (SNPs) of hOAT4 on transport function in COS-7 cells was characterized.

Experimental approach:

Transport uptake assay was used to assess the function of the variant transporters. Cell surface biotinylation and western blot analysis were used to investigate the expression characteristics of the transporter proteins. Comparative modelling was used to interpret the influence of nonsynonymous changes in terms of hOAT4 structure.

Key results:

Four naturally occurring hOAT4 variants (L29P, R48Y, V155G and T392I) exhibited a significant loss of function. Substitution of leucine-29, which is a conserved residue in OATs, with a proline residue, impaired the synthesis or the apparent stability of the transporter and membrane insertion was disrupted in the R48Y variant. In the case of the V155G and T392I variants, impaired function was due to decreased affinity of the transporter for oestrone sulphate and impaired transporter-substrate turnover respectively. The T392I variant was inhibited more extensively than the wild-type transporter by the cationic substrate tetraethyl ammonium.

Conclusions and implications:

Several naturally occurring SNPs encode variant hOAT4s that may impair the renal tubular re-absorption of important drug substrates.     

Thirty novel genetic variations in the SLC29A1 gene encoding human equilibrative nucleoside transporter 1 (hENT1)

Thirty-nine genetic variations, including thirty novel ones, were found in the human SLC29A1 gene, which encodes equilibrative nucleoside transporter 1, from 256 Japanese cancer patients administered gemcitabine. The found novel variations included -8,166G>A, -81,10A>G, -7,947G>A, -7,789T>C, -5,595G>A, -3,803_-3,783delTCGGGGAGGTGGCAGTGGGCG, -3,548G>C, -3,414G>A, -1355T>C, -34C>G, IVS1+141G>A, IVS1+260C>T, IVS1-82C>T, 177C>G, IVS3-6C>T, 564C>T, IVS8+44T>C, IVS8+90T>C, IVS8+97T>C, IVS8+131C>T, IVS8+169G>A, 933T>C, 954C>T, IVS11-52G>C, IVS11-46G>A, 1,288G>A, 1,641C>G, 1,703_1,704delGT, 1812C>T, and 1861C>T. The frequencies were 0.051 for IVS8+169G>A, 0.012 for -7,947G>A, 0.006 for IVS1+141G>A and 1,703_1,704delGT, 0.004 for -8,166G>A, -8,110A>G, -3,548G>C, -1,355T>C, -34C>G, IVS8+44T>C, and 1,812C>T, and 0.002 for the other 19 variations. Among them, 177C>G and 1,288G>A resulted in amino acid substitutions Asp59Glu and Ala430Thr, respectively. Using the detected polymorphisms, linkage disequilibrium analysis was performed, and 28 haplotypes were identified or inferred. Our findings would provide fundamental and useful information for genotyping SLC29A1 in the Japanese and probably other Asian populations.     

Genetic variants of organic cation transporter 1 (OCT1) and OCT2 significantly reduce lamivudine uptake

The study sought to investigate the effect of genetic variants of OCT1 (OCT1-P283L and -P341L) and OCT2 (OCT2-T199I, -T201M and -A270S), which were identified in a Korean population, on the transport of lamivudine in vitro and to compare the substrate dependent effects of OCT1 and OCT2 variants with 1-methyl-4-phenylpyridinium (MPP+), tetraethyl ammonium (TEA), metformin and lamivudine as substrates for these transporters. When the transport kinetics of lamivudine uptake in oocytes overexpressing OCT1 and OCT2 wild-type (WT) and variant proteins were measured, lamivudine uptake mediated by OCT1-WT was saturable, and uptake was decreased in oocytes expressing OCT1-P283L and -P341L variants compared with that in OCT1-WT. The Clint of lamivudine in oocytes expressing OCT1-P283L was decreased by 85.1% compared with OCT1-WT, whereas it was decreased by 48.7% in oocytes expressing OCT1-P341L. The Clint of lamivudine in oocytes expressing OCT2-T199I, -T201M and -A270S was decreased by 86.2%, 88.9% and 73.6%, respectively, compared with OCT2-WT. When comparing various substrates such as MPP+, TEA, metformin and lamivudine, the effects of the OCT1 genetic polymorphisms on their uptake were not identical. However, contrary to the case of OCT1, the uptake of MPP+, TEA, metformin and lamivudine in oocytes expressing OCT2-T199I, -T201M and -A270S variants was decreased significantly compared with that in oocytes expressing OCT2-WT. In conclusion, the effect of genetic variations of OCT1 and OCT2 on the uptake of MPP+, TEA, metformin and lamivudine was substrate-dependent.     

Five novel single nucleotide polymorphisms in the EPHX1 gene encoding microsomal epoxide hydrolase

Five novel single nucleotide polymorphisms (SNPs) were found in the EPHX1 gene from 96 Japanese epileptic patients. The detected SNPs were as follows: 1) SNP, MPJ6_EX1009; GENE NAME, EPHX1 ACCESSION NUMBER, NT_004525.12; LENGTH, 25 bases; 5'-CCTCACTTCAGTG/ACTGGGCTTTGCC-3'. 2) SNP, MPJ6_EX1013; GENE NAME, EPHX1; ACCESSION NUMBER, NT_004525.12; LENGTH, 25 bases; 5'-TCCGCAGCCAGGG/CAGGACGACAGCA-3'. 3) SNP, MPJ6_EX1026; GENE NAME, EPHX1; ACCESSION NUMBER, NT_004525.12; LENGTH, 25 bases; 5'-GTTCTCCCTGGAC/TGACCTGCTGACC-3'. 4) SNP, MPJ6_EX1028; GENE NAME, EPHX1; ACCESSION NUMBER, NT_004525.12; LENGTH, 25 bases; 5'-AGGCAGGGGGACG/AGCCAGTCTTGGG-3'. 5) SNP, MPJ6_EX1030; GENE NAME, EPHX1; ACCESSION NUMBER, NT_004525.12; LENGTH, 25 bases; 5'-TGAAAAGTGGGTG/AAGGTTCAAGTAC-3'.The frequencies were 0.016 for MPJ6_EX1028 (IVS8+54G>A) and 0.005 for the other SNPs. The SNP MPJ6_EX1013 (130G>C) results in an amino acid alteration (E44Q). The other three SNPs in the coding region, MPJ6_EX1009 (30G>A), MPJ6_EX1026 (1056C>T), and MPJ6_EX1030 (1239G>A) result in synonymous changes (V10V, D352D, and V413V, respectively).     

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.     

Genetic variants of organic cation transporter 2 (OCT2) significantly reduce metformin uptake in oocytes

1. The authors sought to evaluate the contribution of organic cation transporters (OCTs) to the renal tubular transport of metformin using LLC-PK1 cells as an in vitro model for the renal proximal tubule, and to investigate the effects of three non-synonymous genetic variants of OCT2 on the transport activity of metformin in vitro using an oocyte over-expression system. 2. The basolateral-to-apical transport of metformin was significantly greater than the apical-to-basolateral transport and showed concentration dependency with the kinetic parameters: maximum transport rate (V(max)), 922 pmol min(-1) per 5 x 10(5) cells; Michaelis-Menten constant (K(m)), 393 microM; intrinsic clearance (CL(int)), 2.35 microl min(-1) per 5 x 10(5) cells; and diffusion constant (K(d)), 0.33 microl min(-1) per 5 x 10(5) cells. The basolateral-to-apical transport of metformin was inhibited by phenoxybenzamine, an inhibitor of OCTs, but not by cyclosporine A, MK571, or fumitremorgin C, which are inhibitors of P-glycoprotein, multidrug resistance proteins (MRPs), and breast cancer resistance protein (BCRP), respectively, suggesting that OCTs play a role in renal tubular secretion of metformin. 3. Metformin uptake was much greater in oocytes expressing OCT2-wild type (OCT2-WT) than OCT1-WT compared with uptake in water-injected oocytes. Uptake was significantly decreased in oocytes expressing OCT2-T199I, -T201M, and -A270S compared with that in OCT2-WT, suggesting that metformin is a better substrate for OCT2 than for OCT1 and that the amino acid-substituted variants of OCT2 cause a functional decrease in metformin uptake. 4. In conclusion, the genetic variants of OCT2 (OCT2-T199I, -T201M, and -A270S) decreased the transport activity of metformin and thus may contribute to the inter-individual variation in metformin disposition as OCT2 plays a pivotal role in renal excretion, the major disposition route of metformin.     

新疆维吾尔族人群SLC22A1基因的单核苷酸多态性研究

目的：研究有机阳离子转运体SLC22A1基因单核苷酸多态性（SNP）rs2282143位点（P341L,1022C>T）基因型和等位基因在中国新疆维吾尔族人群中的分布频率,并比较其与不同种族间的分布差异。方法：通过SNaPshot SNP分型技术检测276例新疆维吾尔族健康人群的SLC22A1基因SNP rs2282143位点的基因型,并与国际人类基因组单倍型图谱计划（HapMap）中不同国家或地区就该位点的SNP分型数据进行比较,分析基因型频率和等位基因频率间的差异。结果：在新疆维吾尔族健康人群中,SLC22A1基因rs2282143位点中CC基因型最常见,分布频率为90.9%;CT和TT基因型分布频率分别为8.4%、0.7%;最小等位基因T的分布频率为4.9%。新疆维吾尔族SLC22A1基因rs2282143位点的基因型频率和等位基因频率分布与黄种人群存在显著差异;而与高加索人群和黑人不存在显著差异,其中与约鲁巴人群的基因型频率存在显著差异,但与该人群的等位基因分布频率分布不存在显著差异。结论：新疆维吾尔族人群SLC22A1基因具有显著的基因多态性,其SNP rs2282143位点基因型和等位基因的分布频率与部分国家或地区人群存在较大差异,该差异对于有机阳离子转运体SLC22A1基因相关的疾病诊断、药物基因组学以及人类进化史方面的研究可能起重要作用。     

Genetic variants of organic cation transporter 2 (OCT2) significantly reduce metformin uptake in oocytes

1.?The authors sought to evaluate the contribution of organic cation transporters (OCTs) to the renal tubular transport of metformin using LLC-PK1 cells as an in vitro model for the renal proximal tubule, and to investigate the effects of three non-synonymous genetic variants of OCT2 on the transport activity of metformin in vitro using an oocyte over-expression system.

2.?The basolateral-to-apical transport of metformin was significantly greater than the apical-to-basolateral transport and showed concentration dependency with the kinetic parameters: maximum transport rate (V_max), 922 pmol min^?1 per 5 × 10⁵ cells; Michaelis–Menten constant (K_m), 393 µM; intrinsic clearance (CL_int), 2.35 µl min^?1 per 5 × 10⁵ cells; and diffusion constant (K_d), 0.33 µl min^?1 per 5 × 10⁵ cells. The basolateral-to-apical transport of metformin was inhibited by phenoxybenzamine, an inhibitor of OCTs, but not by cyclosporine A, MK571, or fumitremorgin C, which are inhibitors of P-glycoprotein, multidrug resistance proteins (MRPs), and breast cancer resistance protein (BCRP), respectively, suggesting that OCTs play a role in renal tubular secretion of metformin.

3.?Metformin uptake was much greater in oocytes expressing OCT2-wild type (OCT2-WT) than OCT1-WT compared with uptake in water-injected oocytes. Uptake was significantly decreased in oocytes expressing OCT2-T199I, -T201M, and -A270S compared with that in OCT2-WT, suggesting that metformin is a better substrate for OCT2 than for OCT1 and that the amino acid-substituted variants of OCT2 cause a functional decrease in metformin uptake.

4.?In conclusion, the genetic variants of OCT2 (OCT2-T199I, -T201M, and -A270S) decreased the transport activity of metformin and thus may contribute to the inter-individual variation in metformin disposition as OCT2 plays a pivotal role in renal excretion, the major disposition route of metformin.