CARRIER-MEDIATED HEPATIC UPTAKE OF THE CATIONIC CYCLOPEPTIDE, OCTREOTIDE, IN RATS: Comparison between In Vivo and In Vitro

Tadashi Yamada; Kayoko Niinuma; Michel Lemaire; Tetsuya Terasaki; Yuichi Sugiyama

Comparison between In Vivo and In Vitro

Abstract

The plasma concentration and biliary excretion profiles of a cationic cyclic octapeptide, octreotide, were compared between control rats and rats given an intravenous infusion of a bile acid, taurocholate (TCA), and an organic anion, dibromosulfophthalein (DBSP). Both TCA and DBSP reduced the plasma elimination and biliary excretion of octreotide after its intravenous bolus administration. Two mechanisms accounting for this phenomenon were considered a priori: decreased hepatic uptake from blood to liver and decreased biliary excretion from liver to bile. The tissue uptake clearance (CL_up) of octreotide in plasma and several tissues was determined, and extensive uptake of octreotide (0.20 ml/min/g liver) was observed only in liver. The kinetic analysis indicated that CL_up in liver fell to 10% of controls after administration of both TCA and DBSP. To compareCL_up between in vivo and in vitro, the initial velocity of octreotide uptake by isolated hepatocytes and primary cultured hepatocytes was measured. The estimated kinetic parameters K_M andV_max were ∼100 μM and 200 pmol/min/10⁶ cells in both systems, respectively. Hepatic uptake clearance estimated from the in vitro data was comparable with that observed in vivo. Biliary excretion of octreotide is reduced in Eisai hyperbilirubinemic rats (EHBRs), which have a heredity defect of multispecific organic anion transporter on the bile canalicular membrane, compared with that of Sprague-Dawley rats. The kinetic analysis demonstrated that the hepatic uptake was reduced in EHBRs. The uptake study using primary cultured hepatocytes suggested that a high level of unidentified endogenous substrate(s) in EHBR plasma may be responsible for the reduction of hepatic uptake of octreotide in EHBRs. In conclusion, we have demonstrated in vivo that carrier-mediated hepatic uptake of octreotide is inhibited by TCA and DBSP and that the CL_upobtained in vivo is comparable with theCL_up obtained in vitro in isolated hepatocytes and primary cultured hepatocytes.

Recently, a variety of small peptides—somatostatin analogs (1-3), endothelin antogonists (4, 5), and renin inhibitors (6)—have been developed as therapeutic agents. Despite of their stability to enzymatic degradation in the gastrointestinal tract and liver, the short half-lives in plasma hinder their development as therapeutic agents. This short half-life was the result of extensive hepatic uptake and biliary excretion (7-9). Bile acids and organic anions are known ligands taken up efficiently by the liver from blood. It has been shown that active transport is involved in their hepatic uptake. Organic anions such as DBSP¹ (10), benzylpenicillin (11), and HMG-CoA reductase inhibitor (pravastatin) (12) are transported by a Na⁺-independent multispecific organic anion transporter (13); whereas bile acids are transported both by a Na⁺-dependent bile acid transporter and by a Na⁺-independent organic anion transporter (14). Organic cations are taken up by a different system from that of organic anions (15). In addition, previous reports on isolated hepatocytes have demonstrated carrier-mediated transport in the hepatic uptake of small peptides, such as the somatostatin analog, octreotide (16-18), renin inhibitors (19-22), and endothelin antagonists (23). The hepatic uptake of these ligands is also inhibited by bile acids and organic anions. These results suggest that peptides may be transported by common transport systems for organic anions and bile acids (17, 19,24). However, analysis of the tissue distribution of peptides in vivo has received little detailed attention. The tissue distribution of drugs is governed by many biological and physiological factors, such as tissue volume, blood flow, protein binding in plasma and tissue, specific transport mechanisms, etc. In particular, there is a specific transport mechanism for organic anions in liver and kidney, organs involved in the metabolism and excretion of exogenous compounds, such as DBSP (liver) and PAH (kidney) (25). A transport system for organic cations is also known to exist in both organs (15).

In this study, analysis of the tissue distribution of the cyclooctapeptide, octreotide, was conducted using it as a model compound for peptides. More than 70% of an intravenous dose of octreotide is excreted into the bile in unchanged form, and 30% of the dose is excreted into urine (26). To investigate the initial tissue distribution of octreotide, the time profiles of [¹⁴C]octreotide in plasma and several tissues were determined to calculate the tissue uptake clearance of octreotidein vivo in several tissues, including the liver and kidney. The uptake clearances obtained were compared among the tissues. To determine whether specific transport exists in the tissue distribution of octreotide, the effects of organic anions (DBSP and PAH), bile acid (TCA), and unlabeled octreotide on the tissue uptake of [¹⁴C]octreotide were examined. The characteristics of octreotide uptake and the magnitude of the uptake and inhibition by another compound were compared in vivo and in vitro using isolated rat hepatocytes and primary cultured hepatocytes. In addition, biliary excretion was determined in EHBRs in which the ATP-driven canalicular transport system (cMOAT) for organic anions such as DBSP and dinitrophenylglutathione is genetically defective, whereas the biliary excretion system for bile acids is conserved (27).

Materials and Methods

Chemicals and Reagents.

Unlabeled octreotide and [¹⁴C]octreotide (specific activity: 46.2 mCi/mmol) were supplied by Sandoz Pharma Ltd. (Basel, Switzerland). [³H]Inulin was purchased from New England Nuclear (Boston, MA). DBSP was from the Société d’Etudes et de Recherches Biologiques (Paris, France). All other chemical and reagents were commercial products of analytical grade.

Analysis of the Time Profiles of the Plasma Disappearance and the Biliary Excretion of [¹⁴C]Octreotide.

Male SDRs (Nisseizai, Tokyo, Japan) and EHBRs (Eisai Laboratories, Gifu, Japan) weighing ∼220 g were used throughout the experiments. Under light ether anesthesia, both femoral arteries and veins were cannulated with polyethylene catheters (PE-50) for blood sampling and the bolus injection of octreotide and infusion of DBSP or TCA, respectively. The bile duct was cannulated with polyethylene catheters (PE-10) for bile collection.

Thirty minutes before administration of [¹⁴C]octreotide (40 μCi/kg), DBSP (1 and 2.5 μmol/min/kg in saline and 25 μmol/kg as a loading dose) or TCA (4 and 10 μmol/min/kg in 3% human serum albumin and 5% glucose) infusions were started and continued throughout the experiment. As a control experiment, an equivalent volume of saline was infused. Bile was collected in preweighed test tubes at 10-min intervals. Plasma was obtained by centrifugation of blood samples (Microfuge, Beckman, Fullerton, CA). Aliquots of plasma (100 μl) and bile (10 μl) were mixed with scintillation cocktail (Clear-sol I, Nacarai Tesque, Tokyo, Japan) and counted (LS 6000SE, Beckman Instruments, Fullerton, CA).

Determination of Kinetic Parameters.

Plasma concentration profiles were fitted with the following biexponential equation using the nonlinear iterative least squares method (28).Cp=Aexp(−αt)+Bexp(−βt). Equation 1AUC at t was calculated by integrating eq.1 from 0 tot.

Pharmacokinetic parameters were calculated according to the following equations: Equation 2CLbile,p=Xbile/AUC(0–120), Equation 3where CL_tot, AUC_(0–∞),CL_bile,p, Xbile, and AUC_(0–120) are the total body clearance of octreotide (ml/min/kg body weight), AUC for 0 to infinity (% of dose·min/ml/kg), the biliary excretion clearance defined by plasma concentration (ml/min/kg), amount of octreotide excreted into bile from 0 to 120 min (% of dose), and AUC for 0 to 120 min (% dose·min/ml/kg), respectively.

Analysis of Tissue Uptake after Intravenous Administration of [¹⁴C]Octreotide in SDRs and EHBRs.

After intravenous bolus administration of [¹⁴C]octreotide (8 μCi/kg) via the femoral vein, blood was collected from the femoral artery. At time 1, 3, or 5 min after administration of [¹⁴C]octreotide, rats were killed, and liver, kidney, intestine, pancreas, lung, muscle, spleen, and cerebrum were excised immediately, and a portion of each tissue was weighed and radioactivity counted. The tissue uptake rate can be described by the following differential equation during the relatively early phase when the efflux of [¹⁴C]octreotide is minimal:dX(t)/dt=CLup·Cp(t), Equation 4where X(t) is the amount of octreotide in the tissue at time t, CL_up is the tissue uptake clearance, and Cp(t) is the plasma concentration of octreotide. Integration of eq. 4 gives:X(t)=CLup·AUC(0–t)+X(0), Equation 5where AUC_(0–t) represents the area under the plasma concentration-time curve from 0 to t.

Equation 5 divided by Cp(t) gives:X(t)/Cp(t)=CLup·AUC(0–t)/Cp(t)+Ve, Equation 6where V_e represents the distribution volume that consists of the plasma space and the volume in which the drug concentration equilibrates instantaneously with that in plasma. The CL_up value can be obtained from the initial slope of a plot ofX(t)/Cp(t) vs.AUC_(0–t)/Cp(t), designated as an “integration plot” (12, 29, 30)

Inhibition of Octreotide Uptake by DBSP, TCA, PAH, and octreotide.

Thirty minutes before administration of the mixture of [¹⁴C]octreotide and [³H]inulin, DBSP (2.5 μmol/min/kg and 25 μmol/kg as loading dose), TCA (10 μmol/min/kg), PAH (23 μmol/min/kg and 700 μmol/kg as loading dose), or octreotide (250 nmol/min/kg) infusions were started and continued throughout the experiment. As a control experiment, an equivalent volume of saline was infused.

Plasma concentration-time profile and the amount in each tissue at 5 min after administration of [¹⁴C]octreotide (8 μCi/kg) were determined as described previously. In the case of liver, biopsy was performed at 1 min. For kidney, the tissue uptake clearance determined herein involved glomerular filtration. Thus, to obtain the exact uptake clearance for kidney via the basolateral membrane, a correction had to be made using the values of the unbound fraction of octreotide in plasma and the apparent uptake by GFR, estimated from the integration plot analysis of [³H]inulin as described previously.

Uptake of Octreotide by Isolated Hepatocytes.

Hepatocytes were isolated from male SDRs (250–280 g) by the procedure of Baur et al. (31). After isolation, hepatocytes were suspended (2 × 10⁶ cells/ml) at 0°C in Krebs-Henseleit buffer supplemented with 12.5 mM HEPES (pH 7.4) containing 2% BSA. Cell viability was checked by the trypan blue (0.4%) exclusion test.

Uptake of [¹⁴C]octreotide (1–1000 μM) was initiated by adding the ligand to the preincubated (37°C for 3 min) cell suspension (2 × 10⁶ cells/ml). After 0.5 or 2 min, the reaction was terminated by separating cells from the medium using a centrifugal filtration technique (32). Then 200 μl aliquots were transferred into 0.4 ml centrifuge tubes containing 50 μl of 2 N NaOH, covered by a 100 μl mixture of silicone and mineral oil (density: 1.015). Samples were then centrifuged for 10 sec in a bench microfuge (Beckman Instruments, Fullerton, CA).

Centrifugation drove the pelleted hepatocytes through the oil layer and into the concentrated solution (2 N NaOH). After cells were dissolved in the alkaline solution, the tube was sliced with a razor blade and both sections (medium portion and the bottom portion including cells) were transferred to scintillation vials. The bottom portion was neutralized with 50 μl of 2 N HCl. Then, 10 ml of counting solution was added to the vial, and both cell and medium radioactivities were determined in a liquid scintillation spectrophotometer (LS6000SE, Beckman Instruments). The initial uptake velocity was calculated applying linear regression to points taken at 30 and 120 sec.

Uptake of Octreotide by Primary Cultured Hepatocytes.

Hepatocytes were prepared from male SDRs (220–280 g) by the procedure of Kato and Sugiyama (33). After isolation, hepatocytes were suspended (5 × 10⁵ cells/well) in a 12-well plate (Corning, Corning, NY) in 5% calf serum, 1 nM insulin, and 1 nM dexamethasone containing William’s medium E. Cells were cultured for 4.5 hr at 37°C and 5% CO₂. Cell viability was checked by the trypan blue (0.4%) exclusion test.

Hepatocytes cultured for 4.5 hr were preincubated at 37°C for 10 min with 600 μl of Krebs-Henseleit buffer containing 2% BSA or 90% rat plasma. Uptake was started by adding an aliquot of octreotide solution to give a final concentration. Before stopping the uptake, 50 μl of medium was removed to determine the concentration of ligand in the medium. Uptake was stopped by adding cold buffer, and cells were washed. Then, 400 μl of buffer containing 0.4 N NaOH and 0.1% sodium dodecyl sulfate was added and incubated for 30 min at room temperature. Then, 350 μl of the cell solution was removed. Radioactivities in the medium and cells were determined in a liquid scintillation spectrophotometer (LS6000SE, Beckman Instruments). The initial uptake velocity was calculated by subtracting the uptake at 5 min from that at 1 min.

Estimation of In Vivo Uptake Clearance from In Vitro Data.

The kinetic parameters for octreotide uptake were estimated from the following equation:Vo=Vmax·S/(KM+S)+Pdiff·S, Equation 7where V_o is the initial uptake rate of octreotide (pmol/min/10⁶ cells), S is the octreotide concentration in the medium (μM),K_M is the Michaelis constant (μM),V_max is the maximum uptake rate (pmol/min/10⁶ cells), and P_diff is the nonspecific uptake clearance (μl/min/10⁶ cells). The aforementioned equation was fitted to the uptake data sets by an iterative nonlinear least squares method using a MULTI program (28) to obtain estimates of kinetic parameters. Input data were weighted as reciprocals of the square of the observed values, and the algorithm used for fitting was the Damping Gauss Newton Method.

The uptake clearance of octreotide in vivo was estimated from the following equation, considering that octreotide dose not distribute to blood cells.

Venous equilibrium model (34):CLup=Qhp·fp·PSinfluxQhp+fp·PSinflux. Equation 8Sinusoidal perfusion model (35):CLup=Qp·{1−exp(−fp·PSinflux/Qhp}, Equation 9where Q_hp is hepatic plasma flow (0.825 ml/min/g) (36), and f_p is the plasma unbound fraction (0.41). PS_influx is permeability-surface area product (ml/min/g liver). Based on the value (1 mg protein = 1 × 10⁶ cells and 1 g liver = 1.25 × 10⁸ cells),PS_influx is calculated from the observed value obtained from isolated hepatocytes (2.57 μl/min/mg protein) and primary cultured hepatocytes (2.46 μl/min/mg protein).

Results

Effect of DBSP and TCA on Plasma Elimination and Biliary Excretion of [¹⁴C]Octreotide.

The effects of an organic anion, DBSP, and a bile acid, TCA, on the plasma elimination and biliary excretion of [¹⁴C]octreotide were examined (fig. 1). Intravenous infusion of DBSP and TCA into rats was conducted at two infusion rates before and after bolus administration of [¹⁴C]octreotide. Biliary excretion rates of TCA after infusion at a rate of 4 or 10 μmol/min/kg were 3.9 or 7.1 μmol/min/kg from 20 to 30 min after initiation of infusion, respectively, and the plasma concentration after 30 min was 100 or 350 μM, respectively. Biliary excretion rates of DBSP after infusion at a rate of 1 or 2.5 μmol/min/kg were 0.9 or 1.7 μmol/min/kg, and plasma concentration was 60 and 300 μM, respectively. Biliary excretion of DBSP and TCA exhibited minimal increase by further increasing the infusion rates. Biliary excretion rates at the infusion rates of 10 μmol/min/kg for TCA and 2.5 μmol/min/kg for DBSP were then estimated as transport maximum (T_max). At 30 min after starting of infusion of TCA or DBSP, [¹⁴C]octreotide was administered by intravenous bolus injection, and plasma and biliary excretion profiles were examined. Plasma elimination and biliary excretion of [¹⁴C]octreotide were inhibited by both TCA and DBSP in a dose-dependent manner and the biliary excretion of [¹⁴C]octreotide was reduced to <10% of that of controls at the T_max of each compound. Moreover, the plasma elimination of [¹⁴C]octreotide was markedly delayed at T_max of TCA and DBSP. The biliary excretion clearance (CL_bile,p) defined with respect to the octreotide concentration in plasma was reduced to 0.5% by TCA and to 6.6% by DBSP, compared with controls (table 1).

Figure 1

Effect of TCA and DBSP on plasma elimination (A) and biliary excretion (B) of octreotide.

Thirty minutes before intravenous administration of [¹⁴C]octreotide (40 μCi/kg), DBSP (□, 1 μmol/min/kg; ▪, 2.5 μmol/min/kg) or TCA (□, 4 μmol/min/kg; ▴, 10 μmol/min/kg) infusion was started and continued throughout the experiment. As a control (○), an equivalent volume of saline was infused. Each point and vertical bar represents the mean ± SEM of three rats.

View this table:

Table 1

Comparison of CL_tot and CL_bile,p of octreotide among SDRs, EHBRs, and treated SDRs

Comparison of Plasma Elimination and Biliary Excretion of [¹⁴C]Octreotide between SDRs and EHBRs.

Plasma elimination and biliary excretion of [¹⁴C]octreotide in EHBR after intravenous bolus administration were compared with SDRs (fig. 2). Plasma elimination was delayed, compared with SDRs and the cumulative biliary excretion over 120 min was reduced to 40% of that in SDRs. TheCL_bile,p in SDRs and EHBRs was 7.4 ml/min/kg and 1.7 ml/min/kg, respectively, and theCL_bile,p in EHBRs was reduced to 23% of that in SDRs (table 1).

Figure 2

Plasma elimination and biliary excretion of [¹⁴C]octreotide in SDRs and EHBRs.

After intravenous administering of [¹⁴C]octreotide (40 μCi/kg) to SDRs (○) and EHBRs (•), plasma elimination (A) and cumulative biliary excretion (B) were monitored. Each pointand vertical bar represents the mean ± SEM of three rats.

Analysis of Early-Phase Tissue Distribution of [¹⁴C]Octreotide in SDRs.

The early-phase tissue distribution of [¹⁴C]octreotide was examined (fig. 3). The time profiles of [¹⁴C]octreotide concentrations in plasma and several tissues 1, 3, and 5 min after intravenous bolus injection were determined to calculate CL_up of octreotidein vivo. The CL_up values in the liver and kidney were 0.2 ml/min/g and 0.58 ml/min/g, respectively, and were much higher than other organs, such as spleen, pancreas, lung, muscle, intestine, and brain. K_p of [₁₄C]octreotide was similar to that of [³H]inulin as an extracellular space marker in muscle, intestine, and brain, whereas slightly higher K_pvalues were observed in the spleen, lung, and pancreas (table2). To determine the contribution of glomerular filtration to the uptake of octreotide by the kidney, theCL_up of [³H]inulin at 5 min was determined to be 1.02 ± 0.16 ml/min/g kidney. The glomerular filtration clearance of octreotide in kidney estimated using the unbound fraction of octreotide in plasma (0.41) and theCL_up of inulin (1.02 ml/min/g kidney) was 0.42 ml/min/g kidney, as indicated by a broken line in fig.3B. This value was similar to theCL_up of octreotide (0.58 ml/min/g) in the kidney. These results suggest that most of the apparent uptake of octreotide by the kidney is mainly due to the glomerular filtration (fig. 3B).

Figure 3

Early-phase tissue uptake of [¹⁴C]octreotide (8 μCi/kg) after intravenous administration to rats (integration plot).

[¹⁴C]Octreotide plasma concentration-time profiles and uptake by each tissue after 1, 3, and 5 min were measured and data were expressed as integration plots. Initial slope represents theCL_up for each tissue. The broken linerepresents nonspecific uptake of [¹⁴C]octreotide by glomerular filtration (f_p multiplied by GFR) in the kidney. (A) ○, liver; •, lung; ▪, pancreas; ▴, cerebrum. (B) •, kidney.

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Table 2

Effects of DBSP, TCA, octreotide, and PAH on K_p values in SDRs and K_p values in EHBRs of [¹⁴C]octreotide and [³H]inulin 5 min after intravenous bolus injection of [¹⁴C]octreotide and [³H]inulin

Inhibition of [¹⁴C]Octreotide Hepatic Uptake by Taurocholic Acid and Organic Anions in SDRs.

The effects of coinfusion of TCA, DBSP, PAH, and unlabeled octreotide on the initial hepatic uptake clearance of [¹⁴C]octreotide were examined 5 min after intravenous bolus injection of [¹⁴C]octreotide (fig. 4, table2). The CL_up was reduced to 10% of controls by coinfusion of TCA and DBSP, but PAH had no effect. In addition, the CL_up was reduced to 40% of controls by coinfusion of excess unlabeled octreotide, when the estimated octreotide concentration in plasma was 30 μM. A decrease inK_p value at 5 min after administration, which reflects the early-phase distribution to each tissue, was observed not only in liver but also in the lung and intestine with coinfusion of TCA and DBSP. However, the reduction in the K_p value in the lung and intestine was <15%, compared with that in liver.

Figure 4

Effect of DBSP, TCA, PAH, and octreotide on the hepatic uptake of [¹⁴C]octreotide in SDRs and hepatic uptake in EHBRs.

Thirty minutes before administration of the mixture of [¹⁴C]octreotide and [³H]inulin, DBSP (2.5 μmol/min/kg and 25 μmol/kg as a loading dose), TCA (10 μmol/min/kg), PAH (23 μmol/min/kg and 700 μmol/kg as a loading dose), or octreotide (250 nmol/min/kg) infusion was started and continued throughout the experiment. As a control, an equivalent volume of saline was infused. Plasma concentration-time profile and the amount in each tissue were determined at 1 and 5 min after administration of [¹⁴C]octreotide. Each value and barrepresents the mean ± SEM of three rats.

Comparison of [¹⁴C]Octreotide Hepatic Uptake between SDR and EHBRs.

The CL_up of [¹⁴C]octreotide observed in EHBRs under the same condition was 0.05 ml/min/g liver (fig. 4). The CL_up in EHBRs thus decreased to 25% of SDRs. The K_p value in the liver 5 min after administration of octreotide in EHBRs also decreased to one-third that in SDRs (table 2). A change of K_p value in other tissues was minimal (table 2).

In Vitro Uptake Study.

The concentration dependence of octreotide by isolated hepatocytes was investigated (fig. 5 and table 3). A marked concentration dependence was observed and the estimated parameters (K_M , V_max, andP_diff) were 108 ± 37 μM, 223 ± 75 pmol/min/10⁶ cells, and 0.51 ± 0.14 μl/min/10⁶ cells, respectively. Similar experiments were also conducted using primary cultured hepatocytes, and a similar concentration dependence was observed. The estimated parameters (K_M , V_max, andP_diff) were 97 ± 8 μM, 185 ± 11 pmol/min/10⁶ cells, and 0.55 ± 0.04 μl/min/10⁶ cells, respectively. The PS product for hepatic uptake (PS_influx), which represents the membrane permeability clearance—calculated from the equation,V_max/(K_M +P_diff) was 2.57 μl/min/10⁶ cells for isolated hepatocytes and 2.46 μl/min/10⁶ cells for primary cultured hepatocytes.

Figure 5

Concentration dependency of octreotide uptake by isolated hepatocytes and primary cultured hepatocytes.

Uptake of [¹⁴C]octreotide (1–1000 μM) by isolated hepatocytes prepared from SDRs (•) was initiated by adding the ligand to the preincubated (37°C for 3 min) cell suspension (2 × 10⁶ cells/ml). At 0.5 or 2 min, reaction was terminated by separating cells from the medium using a centrifugal filtration technique. Initial uptake velocity V_o ) was calculated by linear regression of points taken at 30 and 120 sec. Eachpoint represents the mean ± SEM of six determinations. The primary hepatocytes (○) cultured for 4.5 hr were preincubated at 37°C for 10 min with 600 μl of Krebs-Henseleit buffer. Initial uptake velocity (V_o ) was calculated by linear regression of points taken at 1 and 5 min. Each point andbar represent mean ± SEM of three determinations.

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Table 3

Comparison of the uptake clearances of [¹⁴C]octreotide determined in vivo and in vitro

Effect of Plasma Prepared from SDRs and EHBRs on [¹⁴C]Octreotide Uptake by Primary Cultured Hepatocytes.

To examine the cause of the reduced CL_up EHBRsin vivo, the effects of plasma obtained from SDRs and EHBRs on the uptake of [¹⁴C]octreotide were investigated using primary cultured hepatocytes prepared from SDRs (fig.6). The addition of EHBR plasma reduced the uptake clearance to 75% that prepared from SDRs. Part of the decrease ofCL_up observed in EHBRs is thus supposed to be due to an endogenous substance (not identified yet) in the plasma of EHBRs.

Figure 6

Uptake of [¹⁴C]octreotide by primary cultured rat hepatocytes in the presence of plasma prepared from SDRs and EHBRs.

Cultured cells were preincubated at 37°C for 10 min with 2% BSA containing buffer (○), 90% (v/v) SDR plasma (•), or 90% (v/v) EHBR plasma (▪). Uptake was started by the addition of [¹⁴C]octreotide to give a final concentration of 6 μM. Each point and vertical bar represent mean ± SEM of three experiments.

Discussion

Recently, cyclic and linear small peptides consisting of 5 to 10 amino acids have been developed as therapeutic agents: the somatostatin analog octreotide (17), endothelin antagonists (4, 5), and renin inhibitors (10). Efficient hepatic uptake followed by rapid biliary excretion of unchanged compound is a common characteristic of these small peptides. This short plasma half-life caused by them has hindered their development as therapeutic agents. Several recent studies have demonstrated that a specific active transport system for the uptake of peptide exists on the sinusoidal hepatocyte membrane using isolated hepatocytes in vitro (17-21). We have already examined the hepatic uptake of an anionic pentapeptide, the endothelin antagonist BQ-123 (23). Pharmacokinetic and biochemical analyses have demonstrated that there is carrier-mediated transport in the hepatic uptake of peptides, and this transport consists of both Na⁺-dependent and -independent uptake. The former is the same transport system for bile acids and latter shares the uptake system with the multispecific anion transporter (23). Moreover, we have demonstrated that the biliary excretion of BQ-123 from liver to bile is by primary active transport and BQ-123 is excreted by cMOAT (37). Decreased biliary excretion of BQ-123 was demonstrated in EHBRs, which have a defect of cMOAT (27,38-40).

In this study, the distribution of a peptide into organs, including liver and kidney, was examined in vivo using the cationic octapeptide, octreotide, in contrast to the anionic BQ-123. Moreover, the uptake of octreotide was examined using isolated hepatocytes and primary cultured hepatocytes in vitro, and uptake clearance observed was compared with that obtained in vivo. Previous studies have reported that the uptake of octreotide is by carrier-mediated transport and is competitively inhibited by bile acids and organic anions (16, 17). In this study, the effects of organic anions and bile acids on the hepatic uptake of octreotide were examined, and saturation of the uptake of octreotide was also investigated in vivo. Both the biliary excretion andCL_bile,p of octreotide were reduced to <10% of that of controls by TCA and DBSP at theirT_max (fig. 1 and table 1). From a pharmacokinetic point of view, decreasedCL_bile,p is brought by the decrease in the hepatic uptake from blood to liver and/or the decrease in biliary excretion from liver to bile. Thus, to determine how far the hepatic uptake, as the first process of hepatobiliary transport, is influenced by TCA and DBSP, the early-phase tissue distribution of octreotide was determined in vivo (figs. 3 and 4). A highCL_up was observed in the liver and kidney (0.2 ml/min/g liver and 0.58 ml/min/g kidney), compared with other organs (fig. 3). The apparent CL_up in the kidney involves amount of octreotide remaining in the lumen after being excreted by glomerular filtration. Thus, to obtain the exact uptake clearance for kidney via the basolateral membrane, a correction was made using the values of the unbound fraction of octreotide in plasma [0.41 (26)] and GFR (1.02 ml/min/g) estimated from the renal uptake clearance of [³H]inulin (fig.3B). The glomerular filtration clearance of octreotide, estimated at 0.42 ml/min/g, demonstrated that 70% of the apparent uptake of octreotide by kidney was accounted for by glomerular filtration. This result demonstrates that octreotide is specifically taken up mostly by the liver during the early distribution phase. The hepatic uptake thus evaluated was reduced to <15% of controls by TCA and DBSP (fig. 4). On the other hand, PAH had no effect on the uptake of octreotide by the liver. Uptake of [¹⁴C]octreotide was reduced to 40% of controls by 30 μM octreotide in plasma resulting from infusion of unlabeled octreotide, thus indicating saturation of hepatic uptake of octreotide in vivo. Inhibition by TCA and DBSP in vivo confirmed the previous study (17) that reported inhibition of octreotide uptake by TCA and bromosulfophthalein using isolated hepatocytes. Although a significant but slight decrease inK_p at 5 min was observed in the intestine and lung after DBSP and TCA administration (table 2), the mechanism of the inhibitory effect is not known yet. TheK_p value of octreotide at 5 min in the kidney was significantly reduced to 3.8 by PAH, compared with 5.3 in controls. However, the K_p value of inulin in the kidney reflecting glomerular filtration showed a similar decrease from 9.2 to 6.9. Considering that glomerular filtration contributes 70% of the uptake clearance of octreotide in the kidney, the decrease in uptake clearance of octreotide in kidney after administration of excess PAH may not be due to inhibition of the uptake process via basolateral membrane.

To compare the hepatic uptake clearance in vitro andin vivo, the uptake clearance of octreotide was also measured using isolated hepatocytes and primary cultured hepatocytes (fig. 5 and table 3). Similar results were obtained in both experimental systems. The estimated parameters (K_M , V_max, andP_diff) were ∼100 μM, 200 pmol/min/10⁶ cells, and 0.5 μl/min/10⁶ cells. A similar uptake clearance under a linear condition (V_max/K_M +P_diff) was obtained in both systems: 2.57 μl/min/10⁶ cells (isolated hepatocytes) and 2.46 μl/min/10⁶ cells (primary cultured cell). The uptake clearance for octreotide in vivo was estimated from eq. 8(venous equilibrium model) and eq. 9 (sinusoidal perfusion model). The uptake clearance in vivo was calculated from in vitro data to be 0.23 ∼ 0.26 ml/min/g liver (isolated hepatocytes) and 0.22 ∼ 0.26 ml/min/g liver (primary cultured hepatocytes). These values were comparable with the uptake clearance (0.20 ml/min/g) obtained in vivo (table 3). Thus, the carrier-mediated transport system detected in vitro using isolated hepatocytes and primary cultured hepatocytes is considered to be largely responsible for the hepatic uptake in vivo.

We have already compared hepatobiliary transport of octreotide in SDRs with that in EHBRs (41). In this study, the steady-state concentration in plasma and liver and the biliary excretion rate were monitored after intravenous infusion. Comparing SDRs and EHBRs, differences were observed in CL_bile,p, but not in biliary excretion clearance defined in respect to the concentration in liver. In addition, the liver-to-plasma concentration ratio (K_p ) in EHBRs (1.15) was half that of SDRs (2.20) (41). This result suggests that the decrease inCL_bile,p is not caused by a decrease in biliary excretion via the bile canalicular membrane, but rather a decrease in hepatic uptake via the sinusoidal membrane. In fact, we have already determined the primary active ATP-dependent uptake of octreotide by bile canalicular membrane vesicles, which is maintained in EHBRs (41), as well as in SDRs. To determine the mechanism of the reduced K_p in EHBRs, the hepatic uptake clearance in EHBRs was compared with that in SDRs in vivo using integration plot analysis. As shown in fig. 4, the hepatic uptake clearance in EHBRs was ∼25% of that in SDR. However, considering that only the transporter (cMOAT) on the bile canalicular membrane has been believed to be deficient in EHBRs, it is unlikely that the transport carrier on the sinusoidal membrane is also deficient in EHBRs. To examine the mechanism for the decrease in the hepatic uptake in EHBRs, the uptake of octreotide by primary cultured hepatocytes from SDRs was monitored in the presence of plasma prepared from SDRs and EHBRs, and compared with that in the absence of plasma (fig. 6). The uptake clearance in the presence of plasma prepared from EHBRs was reduced to 75% that from SDRs. The bilirubin glucuronide concentration was reported to increase in EHBR plasma to 49 μM from 1 μM in the normal plasma (38). This suggested that an endogenous substance, such as bilirubin glucuronide, elevated in EHBR plasma may play a role in part of the decreased hepatic uptake in EHBRs. Thus, we should be careful not to conclude easily from the observation of reduced biliary excretion of ligands in EHBRs that the ligands are excreted into bile by cMOAT, which is deficient in EHBRs.

In conclusion, the existence of a carrier-mediated transport for the hepatic uptake of octreotide and its inhibition by organic anions and bile acids were investigated in vivo. Kinetic analysis demonstrated that the decreased biliary excretion of octreotide observed in EHBR and the marked decreased biliary excretion caused by bile acids and organic anions were due to reduced hepatic uptake rather than biliary excretion.

Footnotes

Send reprint requests to: Dr. Yuichi Sugiyama, Faculty of Pharmaceutical Sciences, University of Tokyo, Hongo, Bunkyo-Ku, Tokyo 113, Japan.
Abbreviations used are::
DBSP
dibromosulfophthalein
PAH
p-aminohippurate
TCA
taurocholic acid
EHBR
Eisai hyperbilirubinemic rat
cMOAT
canalicular multispecific organic anion transporter
SDR
Sprague-Dawley rat
Cp(t)
plasma concentration of octreotide
AUC
area under the plasma concentration-time curve
CL_tot
total body clearance
CL_bile,p
biliary excretion clearance defined with respect to the concentration in plasma
Xbile
amount of octreotide excreted into bile
X(t)
amount of octreotide in the tissue at time t
CL_up
the tissue uptake clearance
GFR
glomerular filtration rate
BSA
bovine serum albumin
V_max
maximal uptake rate
K_M
Michaelis constant
P_diff
nonspecific uptake clearance
Q_hp
hepatic plasma flow
f_p
plasma unbound fraction
T_max
transport maximum
K_p
the tissue-to-plasma concentration ratio
- Received June 3, 1996.
- Accepted January 28, 1997.

The American Society for Pharmacology and Experimental Therapeutics

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[1] ↵
Bauer W.,
Briner U.,
Doepfner W.,
Haller R.,
Huguenin R,
Marbach P.,
Petcher T. J.,
Pless J.
(1982) SMS 201-995: a very potent and selective octapeptide analogue of somatostatin with prolonged action. Life Sci. 32:1133–1140.

[2] Bauer W.,

[3] Briner U.,

[4] Doepfner W.,

[5] Haller R.,

[6] Huguenin R,

[7] Marbach P.,

[8] Petcher T. J.,

[9] Pless J.

[10] ↵
Lamberts S. W. J.,
Utterlinden P.,
Verschoor L.,
Van Dogen K. J.,
del Pozo E.
(1985) Long-term treatment of acromegaly with the somatostatin analogue SMS 201–995. N. Engl. J. Med. 313:1576–1580.
OpenUrl PubMed

[11] Lamberts S. W. J.,

[12] Utterlinden P.,

[13] Verschoor L.,

[14] Van Dogen K. J.,

[15] del Pozo E.

[16] ↵
Wood S. M.,
Kraenzlim M. E.,
Adrian T. E.,
Bloom S. R.
(1985) Treatment of patients with pancreatic endocrine tumors using a new long-acting somatostatin analogue. Symptomatic and peptide responses. Gut 26:438–444.
OpenUrl Abstract/FREE Full Text

[17] Wood S. M.,

[18] Kraenzlim M. E.,

[19] Adrian T. E.,

[20] Bloom S. R.

[21] ↵
Nirei H.,
Hamada K.,
Shoubo M.,
Sogabe K.,
Notsu Y.,
Ono T.
(1993) An endothelin ETA receptor antagonist, FR139317, ameliorates cerebral vasospasm in dog. Life Sci. 52:1869–1874.
OpenUrl CrossRef PubMed

[22] Nirei H.,

[23] Hamada K.,

[24] Shoubo M.,

[25] Sogabe K.,

[26] Notsu Y.,

[27] Ono T.

[28] ↵
Nisikibe M.,
Tsuchida S.,
Okada M.,
Fukuroda T.,
Shimamoto K.,
Yano M.,
Ishikawa K.,
Ikemoto F.
(1993) Antihypertensive effect of a newly synthesized endothelin antagonist, BQ-123, in a genetic hypertensive model. Life Sci. 52:717–724.
OpenUrl CrossRef PubMed

[29] Nisikibe M.,

[30] Tsuchida S.,

[31] Okada M.,

[32] Fukuroda T.,

[33] Shimamoto K.,

[34] Yano M.,

[35] Ishikawa K.,

[36] Ikemoto F.

[37] ↵
Ondetti A.,
Cushman D. W.
(1981) Inhibition of the renin-angiotensin system. A new approach to the therapy of hypertension. J. Med. Chem. 24:355–361.
OpenUrl CrossRef PubMed

[38] Ondetti A.,

[39] Cushman D. W.

[40] ↵
Berelowitz M.,
Kronheim S.,
Pimstone B.,
Shapiro B.
(1978) Somatostatin-like immunoreactivity in rat blood: characterization, regional differences, and responses to oral and intravenous glucose. J. Clin. Invest. 61:1410–1414.

[41] Berelowitz M.,

[42] Kronheim S.,

[43] Pimstone B.,

[44] Shapiro B.

[45] ↵
Cathapermal S. M.,
Foegh M. L.,
Rau C. S.,
Ramwell P. W.
(1991) Disposition and tissue distribution of angiopeptin in rat. Drug Metab. Dispos. 19:735–739.
OpenUrl Abstract

[46] Cathapermal S. M.,

[47] Foegh M. L.,

[48] Rau C. S.,

[49] Ramwell P. W.

[50] ↵
Greenfield J. C.,
Cook K. J.,
O’Leary I. A.
(1989) Disposition, metabolism, and excretion of U-71038, a novel renin inhibitor peptide, in the rat. Drug Metab. Dispos. 17:518–525.
OpenUrl Abstract

[51] Greenfield J. C.,

[52] Cook K. J.,

[53] O’Leary I. A.

[54] ↵
Blom A.,
Keulemans K.,
Meijer D. K. F.
(1981) Transport of dibromosulfophthalein by isolated rat hepatocytes. Biochem. Pharmacol. 30:1809–1816.
OpenUrl CrossRef PubMed

[55] Blom A.,

[56] Keulemans K.,

[57] Meijer D. K. F.

[58] ↵
Tsuji A.,
Terasaki T.,
Takanosu T.,
Tamai I.,
Nakashima E.
(1986) Uptake of benzylpenicillin, cefpiramide and cefazolin by freshly isolated rat hepatocytes. Biochem. Pharmacol. 35:151–158.
OpenUrl CrossRef PubMed

[59] Tsuji A.,

[60] Terasaki T.,

[61] Takanosu T.,

[62] Tamai I.,

[63] Nakashima E.

[64] ↵
Yamazaki M.,
Suzuki H.,
Hanano M.,
Tokui T.,
Komai T.,
Sugiyama Y.
(1993) Na⁺-independent multispecific anion transporter mediates active transport of pravastatin into rat liver. Am. J. Physiol. 264:G36–G44.
OpenUrl Abstract/FREE Full Text

[65] Yamazaki M.,

[66] Suzuki H.,

[67] Hanano M.,

[68] Tokui T.,

[69] Komai T.,

[70] Sugiyama Y.

[71] ↵
Meier P. J.
(1988) Transport polarity of hepatocytes. Semin. Liver Dis. 8:293–307.
OpenUrl PubMed

[72] Meier P. J.

[73] ↵
Zimmerli B.,
Valantians J.,
Meier P. J.
(1989) Multispecificity of Na⁺-dependent taurocholate uptake in basolateral (sinusoidal) rat liver plasma membrane vesicles. J. Pharmacol. Exp. Ther. 250:301–308.
OpenUrl Abstract/FREE Full Text

[74] Zimmerli B.,

[75] Valantians J.,

[76] Meier P. J.

[77] ↵
Meijer D. K. F.,
Mol W. E. M.,
Muller M.,
Kurz G.
(1990) Carrier-mediated transport in the hepatic distribution and elimination of drugs with special reference to the category of organic cations. J. Pharmacokinet. Biopharmacol. 18:35–70.
OpenUrl CrossRef PubMed

[78] Meijer D. K. F.,

[79] Mol W. E. M.,

[80] Muller M.,

[81] Kurz G.

[82] ↵
Fricker G.,
Dubst V.,
Schwab D.,
Brouns C.,
Thiele C.
(1994) Heterogeneity in hepatic transport of somatostatin analog octapeptides. Hepatology 20:191–200.
OpenUrl CrossRef PubMed

[83] Fricker G.,

[84] Dubst V.,

[85] Schwab D.,

[86] Brouns C.,

[87] Thiele C.

[88] ↵
Terasaki T.,
Mizukuchi H.,
Itoho C.,
Tamai I.,
Lemaire M.,
Tsuji A.
(1995) Hepatic uptake of octreotide, a long-acting somatostatin analogue, via a bile acid transport system. Pharm. Res. 12:11–16.
OpenUrl

[89] Terasaki T.,

[90] Mizukuchi H.,

[91] Itoho C.,

[92] Tamai I.,

[93] Lemaire M.,

[94] Tsuji A.

[95] ↵
Ziegler K.,
Seeberger A.
(1991) Hepatocellular transport of cyclosomatostatins: evidence for a carrier system related to the multispecific bile acid transporter. Biochem. Biophys. Acta 1061:287–296.
OpenUrl PubMed

[96] Ziegler K.,

[97] Seeberger A.

[98] ↵
Bertrams A.,
Ziegler K.
(1991) Hepatocellular uptake of peptide by bile acid transporter: relationship of carrier-mediated transport of linear peptides with renin-inhibiting activity to multispecific bile acid carriers. Biochem. Biophys. Acta 1091:337–348.
OpenUrl PubMed

[99] Bertrams A.,

[100] Ziegler K.

[101] ↵
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CARRIER-MEDIATED HEPATIC UPTAKE OF THE CATIONIC CYCLOPEPTIDE, OCTREOTIDE, IN RATS

Comparison between In Vivo and In Vitro

Comparison between In Vivo and In Vitro

Abstract

Materials and Methods

Chemicals and Reagents.

Analysis of the Time Profiles of the Plasma Disappearance and the Biliary Excretion of [¹⁴C]Octreotide.

Determination of Kinetic Parameters.

Analysis of Tissue Uptake after Intravenous Administration of [¹⁴C]Octreotide in SDRs and EHBRs.

Inhibition of Octreotide Uptake by DBSP, TCA, PAH, and octreotide.

Uptake of Octreotide by Isolated Hepatocytes.

Uptake of Octreotide by Primary Cultured Hepatocytes.

Estimation of In Vivo Uptake Clearance from In Vitro Data.

Results

Effect of DBSP and TCA on Plasma Elimination and Biliary Excretion of [¹⁴C]Octreotide.

Comparison of Plasma Elimination and Biliary Excretion of [¹⁴C]Octreotide between SDRs and EHBRs.

Analysis of Early-Phase Tissue Distribution of [¹⁴C]Octreotide in SDRs.

Inhibition of [¹⁴C]Octreotide Hepatic Uptake by Taurocholic Acid and Organic Anions in SDRs.

Comparison of [¹⁴C]Octreotide Hepatic Uptake between SDR and EHBRs.

In Vitro Uptake Study.

Effect of Plasma Prepared from SDRs and EHBRs on [¹⁴C]Octreotide Uptake by Primary Cultured Hepatocytes.

Discussion

Footnotes

References

In this issue

CARRIER-MEDIATED HEPATIC UPTAKE OF THE CATIONIC CYCLOPEPTIDE, OCTREOTIDE, IN RATS

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CARRIER-MEDIATED HEPATIC UPTAKE OF THE CATIONIC CYCLOPEPTIDE, OCTREOTIDE, IN RATS

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Search

CARRIER-MEDIATED HEPATIC UPTAKE OF THE CATIONIC CYCLOPEPTIDE, OCTREOTIDE, IN RATS

Comparison between In Vivo and In Vitro

Comparison between In Vivo and In Vitro

Abstract

Materials and Methods

Chemicals and Reagents.

Analysis of the Time Profiles of the Plasma Disappearance and the Biliary Excretion of [14C]Octreotide.

Determination of Kinetic Parameters.

Analysis of Tissue Uptake after Intravenous Administration of [14C]Octreotide in SDRs and EHBRs.

Inhibition of Octreotide Uptake by DBSP, TCA, PAH, and octreotide.

Uptake of Octreotide by Isolated Hepatocytes.

Uptake of Octreotide by Primary Cultured Hepatocytes.

Estimation of In Vivo Uptake Clearance from In Vitro Data.

Results

Effect of DBSP and TCA on Plasma Elimination and Biliary Excretion of [14C]Octreotide.

Comparison of Plasma Elimination and Biliary Excretion of [14C]Octreotide between SDRs and EHBRs.

Analysis of Early-Phase Tissue Distribution of [14C]Octreotide in SDRs.

Inhibition of [14C]Octreotide Hepatic Uptake by Taurocholic Acid and Organic Anions in SDRs.

Comparison of [14C]Octreotide Hepatic Uptake between SDR and EHBRs.

In Vitro Uptake Study.

Effect of Plasma Prepared from SDRs and EHBRs on [14C]Octreotide Uptake by Primary Cultured Hepatocytes.

Discussion

Footnotes

References

In this issue

CARRIER-MEDIATED HEPATIC UPTAKE OF THE CATIONIC CYCLOPEPTIDE, OCTREOTIDE, IN RATS

Citation Manager Formats

CARRIER-MEDIATED HEPATIC UPTAKE OF THE CATIONIC CYCLOPEPTIDE, OCTREOTIDE, IN RATS

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ASPET's Other Journals

Analysis of the Time Profiles of the Plasma Disappearance and the Biliary Excretion of [¹⁴C]Octreotide.

Analysis of Tissue Uptake after Intravenous Administration of [¹⁴C]Octreotide in SDRs and EHBRs.

Effect of DBSP and TCA on Plasma Elimination and Biliary Excretion of [¹⁴C]Octreotide.

Comparison of Plasma Elimination and Biliary Excretion of [¹⁴C]Octreotide between SDRs and EHBRs.

Analysis of Early-Phase Tissue Distribution of [¹⁴C]Octreotide in SDRs.

Inhibition of [¹⁴C]Octreotide Hepatic Uptake by Taurocholic Acid and Organic Anions in SDRs.

Comparison of [¹⁴C]Octreotide Hepatic Uptake between SDR and EHBRs.

Effect of Plasma Prepared from SDRs and EHBRs on [¹⁴C]Octreotide Uptake by Primary Cultured Hepatocytes.