Plasma Retention Research Articles

Activation peptides prolong the murine plasma half-life of human factor VII

AbstractCoagulation factors VII (FVII), IX (FIX), X (FX), and protein C share the same domain organization but display very different plasma half-lives. It is plausible that the half-life is influenced by the activation peptide, differing in length and glycosylation and missing in FVII. To test this hypothesis, the influence of activation peptides on the plasma half-life of human FVII was studied by administering human FVII variants containing activation peptide motifs to mice. Insertion of the activation peptide from FX gave 4-fold longer terminal half-life (5.5 hours vs 1.4 hours for FVII), whereas the activation peptide from FIX and protein C resulted in half-lives of 4.3 and 1.7 hours, respectively. Using FX's activation peptide we identified the N-linked glycans as structural features important for the half-life. The peptide location within the FVII molecule appeared not to be critical because similar prolongation was obtained with the activation peptide inserted immediately before the normal site of activation and at the C-terminus. However, only the latter variant was activatable, yielding full amidolytic activity and reduced proteolytic activity with preserved long half-life. Our data support that activation peptides function as plasma retention signals and constitute a new manner to extend the half-life of FVII(a).

Active targeting and safety profile of PEG-modified adenovirus conjugated with herceptin

PEGylation of adenovirus (Ad) increases plasma retention and reduces immunogenicity, but decreases the accessibility of virus particles to target cells. We tested whether PEGylated Ad conjugated to Herceptin (Ad-PEG-HER) can be used to treat Her2/neu-positive cells in vitro and in vivo to demonstrate the therapeutic feasibility of this Ad formulation. Ad-PEG-HER transduced Her2/neu-overexpressing cancer cells through a specific interaction between Herceptin and Her2/neu. Ad-PEG-HER treatment resulted in higher plasma retention and lower neutralizing antibody and IL-6 production than naked Ad. This formulation was extended to generate a Her2/neu-targeted, PEGylated oncolytic Ad (DWP418-PEG-HER). DWP418-PEG-HER specifically killed Her2/neu-positive cells and performed better than non-targeted and naked Ad in vivo. DWP418-PEG-HER showed a 10 10-fold increase in the liver to tumor biodistribution compared with naked Ad. Immunohistochemical staining confirmed accumulation of Ad E1A in tumors. These data suggest that targeted gene therapy with the PEGylated Ad conjugated with Herceptin might shed a light on its therapeutic application for metastatic cancer in the future.

Long-circulating delivery of bioactive polysaccharide from radix ophiopogonis by PEGylation

BackgroundRadix ophiopogonis polysaccharide (ROP) has been found to be effective against myocardial ischemia. One of main problems with its use is its short in-vivo half-life, which makes the development of an effective delivery system necessary. To achieve better therapeutic effects and patient compliance by prolonging its retention in plasma and increasing its distribution in targets, ROP was PEGylated (PEG, polyethylene glycol) in this study.MethodsThrough a moderate coupling reaction between hydroxyl-activated ROP and amino-terminated methoxy-PEG (mPEG) (30 or 40 kDa), together with a greater than 1 molar ratio of ROP to mPEG in reaction, long-circulating and potentially bioactive PEGylated ROPs, with PEG grafting number of ~1.0, were prepared, characterized, and the pharmacokinetics evaluated.ResultsRelative to ROP, whose half-life was approximately 0.7 hours, the two conjugates prepared, following intravenous administration, showed markedly prolonged retention in systemic circulation with half-lives in blood of 78.4 and 88.3 hours, respectively. When given subcutaneously, their in-vivo mean residence times were further markedly prolonged by the slow absorption phase. They were found to be well absorbed after subcutaneous administration, with absolute bioavailability being 75.4% and 43.9%, respectively.ConclusionWith apparent molecular masses not exceeding 43 kDa, the conjugates prepared have been and will be demonstrated to have prominent advantages for ROP delivery, such as: the good absorption following subcutaneous, intramuscular, or other ways of administration; the effective utilization of the enhanced permeability and retention effect caused by ischemia; and the rapid diffusion within target tissues.

Nanoparticulate formulations of mithramycin analogs for enhanced cytotoxicity

Mithramycin (MTM), a natural product of soil bacteria from the Streptomyces genus, displays potent anticancer activity but has been limited clinically by severe side effects and toxicities. Engineering of the MTM biosynthetic pathway has produced the 3-side-chain-modified analogs MTM SK (SK) and MTM SDK (SDK), which have exhibited increased anticancer activity and improved therapeutic index. However, these analogs still suffer from low bioavailability, short plasma retention time, and low tumor accumulation. In an effort to aid with these shortcomings, two nanoparticulate formulations, poly(ethylene glycol)-poly(aspartate hydrazide) self-assembled and cross-linked micelles, were investigated with regard to the ability to load and pH dependently release the drugs. Micelles were successfully formed with both nanoparticulate formulations of each drug analog, with an average size of 8.36 ± 3.21 and 12.19 ± 2.77 nm for the SK and SDK micelles and 29.56 ± 4.67 nm and 30.48 ± 7.00 nm for the SK and SDK cross-linked micelles respectively. All of the drug-loaded formulations showed a pH-dependent release of the drugs, which was accelerated as pH decreased from 7.4 to 5.0. The micelles retained biological activity of SK and SDK entrapped in the micelles, suppressing human A549 lung cancer cells effectively.

Comparative tissue distributions of cadmium chloride and cadmium-based quantum dot 705 in mice: Safety implications and applications

Cadmium (Cd) is a component in quantum dot 705 (QD705). Whether QD705 behaves similar to Cd in vivo is of great concern. We compared the distributional kinetics of cadmium chloride (CdCl2) and QD705 in mice after intravenous injection. QD705 showed a longer plasma and body retention than CdCl2 and could be detected in the brain during early exposure. While both the liver and spleen demonstrated a constant Cd concentration for 28 days after QD705 injection, it is likely that this represents intact QD705 stored in mononuclear phagocytes. The kidneys showed a time-dependent accumulation of Cd in the QD705-exposed animals. By day 28, Cd in the kidneys from QD705 was 3-fold that of CdCl2. QD705 and CdCl2 have very different kinetics in distribution and metabolism. The long body retention of QD705 in the kidneys may mean that QD705 has even more renal toxicity than CdCl2.

Cannabinoid Administration Attenuates the Progression of Simian Immunodeficiency Virus

Δ(9)-Tetrahydrocannabinol (Δ(9)-THC), the primary psychoactive component in marijuana, is FDA approved to ameliorate AIDS-associated wasting. Because cannabinoid receptors are expressed on cells of the immune system, chronic Δ(9)-THC use may impact HIV disease progression. We examined the impact of chronic Δ(9)-THC administration (0.32 mg/kg im, 2 × daily), starting 28 days prior to inoculation with simian immunodeficiency virus (SIV(mac251); 100 TCID(50)/ml, iv), on immune and metabolic indicators of disease during the initial 6 month asymptomatic phase of infection in rhesus macaques. SIV(mac251) inoculation resulted in measurable viral load, decreased lymphocyte CD4(+)/CD8(+) ratio, and increased CD8(+) proliferation. Δ(9)-THC treatment of SIV-infected animals produced minor to no effects in these parameters. However, chronic Δ(9)-THC administration decreased early mortality from SIV infection (p = 0.039), and this was associated with attenuation of plasma and CSF viral load and retention of body mass (p = NS). In vitro, Δ(9)-THC (10 μm) decreased SIV (10 TCID(50)) viral replication in MT4-R5 cells. These results indicate that chronic Δ(9)-THC does not increase viral load or aggravate morbidity and may actually ameliorate SIV disease progression. We speculate that reduced levels of SIV, retention of body mass, and attenuation of inflammation are likely mechanisms for Δ(9)-THC-mediated modulation of disease progression that warrant further study.

Detection of Macrophages Via Paramagnetic Vesicles Incorporating Oxidatively Tailored Cholesterol Ester: An Approach for Atherosclerosis Imaging

Macrophages play a key role in the initiation, progression and complications of atherosclerosis. In this article we describe the synthesis of biocompatible, paramagnetic, fluorescent phosphatidylserine vesicles containing cholesterol ester with a free carboxylic acid function and its use for targeted imaging of macrophages. We synthesized anionic vesicles containing a combination of phosphatidylserine and a novel synthetic oxidized cholesterol ester derivative (cholesterol-9-carboxynonanoate [9-CCN]). In vitro studies to characterize particle size, MRI relaxation times and stability were performed. Vesicles containing 9-CCN demonstrated enhanced ability to bind human low-density lipoprotein and to be internalized by macrophages. Experiments in cultured macrophages with 9-CCN vesicles, alone and in the presence of low-density lipoprotein, indicated uptake of vesicles through scavenger receptor and integrin-dependent pathways. In vivo MRI using 9-CCN vesicles containing gadolinium in a rabbit model of atherosclerosis revealed protracted enhancement of 9-CCN vesicles and colocalization with arterial macrophages not seen with control vesicles. Pharmacokinetic experiments demonstrated prolonged plasma residence time of 9-CCN vesicles, perhaps due to its capacity to bind to low-density lipoprotein. Vesicles containing 9-CCN demonstrate prolonged plasma and plaque retention in experimental atherosclerosis. Such a strategy may represent a simple yet clinically relevant approach for macrophage imaging.

Improved anti‐tumor activity of stabilized anthracycline polymeric micelle formulation, NC‐6300

Anthracyclines have long been considered to be among the most active agents clinically available for the treatment of breast cancer despite their toxicity. To improve their pharmacological profiles, a new macromolecular prodrug, denoted NC-6300, was synthesized. NC-6300 comprises epirubicin covalently bound to polyethylene-glycol polyaspartate block copolymer through an acid-labile hydrazone bond. The conjugate forms a micellar structure spontaneously in aqueous media with a diameter of 60-70 nm. The block copolymers are partially substituted with hydrophobic benzyl groups to stabilize the micellar structure. The present study was designed to confirm that polymeric micelles incorporating epirubicin through an acid-labile linker improve the therapeutic index and achieve a broad range of therapeutic doses. Pharmacokinetic studies in rats showed highly enhanced plasma retention of NC-6300 compared with native epirubicin. The maximal tolerated doses in mice of NC-6300 and native epirubicin were 25 and 9 mg/kg, respectively, when administered three times with a 4-day interval between each dose. NC-6300 at 15 and 20 mg/kg with the same administration schedule regressed a Hep3B human hepatic tumor with slight and transient bodyweight loss. Remarkably, NC-6300 also inhibited growth of an MDA-MB-231 human breast tumor at the same dosage. In contrast, native epirubicin at 7 mg/kg administered three times with a 4-day interval was only able to slow tumor growth. Tissue distribution studies of NC-6300 showed efficient free epirubicin released in the tumor at 74% by area under the concentration-time curve (AUC) evaluation, supporting the effectiveness of NC-6300. In conclusion, NC-6300 improved the potency of epirubicin, demonstrating the advantage of NC-6300 attributable to the efficient drug release in the tumor.

Superior Plasma Retention of a Cross-Linked Human Serum Albumin Dimer in Nephrotic Rats as a New Type of Plasma Expander

Human serum albumin (HSA) is used clinically as a plasma expander in patients with hypoalbuminemia and can also function as a drug carrier. However, the administered HSA is readily eliminated from the blood circulation under pathological conditions, especially the nephrotic syndrome. In this study, we present data on the pharmacokinetics of a structurally defined HSA dimer [two HSA molecules that are cross-linked by reaction with 1,6-bis(maleimido)hexane via Cys34] in nephrotic rats and its superior circulation persistence, owing to the molecular size effect. The half-time (t(1/2)) of the HSA dimer persisted in the circulation 1.3 times longer than that of monomeric HSA in normal rats, primarily because of the suppression of the accumulation of the HSA dimer in the skin and muscle. In nephrotic rats, the t(1/2) of the HSA monomer decreased considerably, whereas the HSA dimer remained unaltered in the blood stream, similar to that for normal rats. As a result, the t(1/2) of the HSA dimer was 2-fold longer than that of the HSA monomer. This longer t(1/2) can be attributed to the fact that accumulation in the kidney and urinary excretion of the HSA dimer were significantly suppressed. The cross-linked HSA dimer shows a longer blood circulation than native HSA monomer in nephrotic rats, which can be attributed to the suppression of renal filtration and leakage into the extravascular space. This HSA dimer has the potential for use as a drug carrier, new plasma expander, and an artificial albumin-based oxygen carrier under a high glomerular permeability condition such as nephrosis.

Stability‐indicating ultra‐performance liquid chromatography method for the estimation of thymoquinone and its application in biopharmaceutical studies

Thymoquinone (THQ) is known for its neuroprotective and anti-convulsant properties in preclinical studies. We herewith describe a simple, rapid, selective, sensitive and stability-indicating UPLC method for the estimation of THQ and its application to biopharmaceutical studies such as in vitro release from nanoparticulate system and in vivo pharmacokinetic study. The method employed gradient elution using a Waters Acquity HSS-T3 C(18) (100 × 2.1 mm, 1.8 µm) UPLC column. The mobile phase consisted of water and acetonitrile, pumped at a flow rate of 0.5 mL/min. The injection volume was 5 µL and THQ was monitored at 294 nm wavelength with a total run time of 6 min. In solution as well as in plasma, the method was found to be linear (r ≥ 0.998), precise (CV ≤ 2.45%) and accurate (recovery ≥ 84.8%) in the selected concentration range of 0.1-0.8 µg/mL. Forced degradation studies revealed that THQ undergoes degradation under acidic, basic, oxidation and UV light stress conditions. However, the developed UPLC method could effectively resolve degradation product peaks from THQ. Further, no interference was found at the retention time of THQ from any plasma components, indicating selectivity of the developed method. For solutions, the limits of detection and quantitation of the method were found to be 0.001 and 0.0033 µg/mL, respectively; while in plasma they were 0.006 and 0.02 µg/mL, respectively. The validated method was successfully applied to quantify THQ in dissolution medium as well as oral in vivo pharmacokinetic study of THQ suspension and THQ- solid lipid nanoparticle (THQ-SLN) formulation. A 2-fold increase in the relative bioavailability was observed with the THQ-SLN compared with THQ. The results indicate that the SLN significantly increased plasma concentrations and retention within the systemic circulation.

Poly(ethylene glycol)-Radix Ophiopogonis polysaccharide conjugates: Preparation, characterization, pharmacokinetics and in vitro bioactivity

Radix Ophiopogonis polysaccharide (ROP), a natural graminan-type fructan with Mw of ∼5 kDa, had been found to have an excellent anti-myocardial ischemic activity. However, its rapid renal excretion following administration remarkably limits its efficacy and clinical use, which makes necessary the development of an effective delivery system. In this article, the feasibility of PEGylation to solve this problem was examined. A moderate coupling reaction between the hydroxyl-activated ROP and the amino-terminated mPEG was chosen to PEGylate ROP. Five different mPEG-ROP conjugates (with mPEG of molecular mass 2, 5 or 20 kDa) were prepared, purified, characterized and evaluated in pharmacokinetics and in vitro bioactivity. Results showed that only when the apparent molecular weight of the conjugate approached to a certain value, would its plasma elimination reduce abruptly. In general, the conjugation caused the reduction in the bioactivity of ROP; however, well-preserved bioactivity was observed when the grafting degree of the conjugate was lower. Among the five conjugates studied, the one with an average 1.3 mPEG (20 kDa) residues per single ROP was found to be satisfactory both in plasma retention and in bioactivity. It had a 47.4-fold increased elimination half-life and preserved approximately 74% of the bioactivity of ROP; moreover, the decrease in bioactivity is not significant. These findings demonstrate that PEGylation would be a promising approach for improving the clinical efficacy of ROP by prolonged retention in plasma.

Synthesis of a New Tri-Branched PEG-IFNα2 and Its Impact on Anti Viral Bioactivity

Efficacy of proteins can be enhanced by using polyethylene glycol (PEG) conjugation (PEGylation) to the protein molecules. Mobile non-toxic PEG chains conjugated to bio-therapeutics increase their hydrodynamic volume and in turn can prolong their plasma retention time and increase their solubility. An important aspect of PEGylation is the selection of PEG molecule with suitable structure and molecular weight. In this study, conceiving the idea that branched PEG-conjugates show superior efficacy over the linear PEG-conjugates, a tri-branched PEG-interferon (mPEG3L2-IFN) was synthesized by reacting a 30 KDa tri-branched mPEG3L2-NHS reagent with IFN to improve its pharmacokinetic properties and reduce the loss of in vitro bioactivity (which is generally exhibited by PEGylation) of the conjugated protein to some extent. The PEGylation procedure was optimized in terms of concentration and molar ratios of reactants, reaction time, temperature and pH conditions of the reaction mix. The conjugate was purified by cation exchange chromatography and characterized by SDS-PAGE and SE-HPLC. Trypsin digestion of mPEG3L2-IFN indicated a single site specificity of PEGylation. Anti viral bioactivity of mPEG3L2-IFN was found to be 2.38 × 107 IU/mg which is approximately 9.52% of native IFNα2 (2.5 × 108 IU/mg) and better than PEGasys from Roche Pharma. Therefore, it is reported that the tri-branched mPEG3L2-NHS reagent has the potential to be used to conjugate proteins for the promising therapeutic results.

Modelling of dust grain formation in a low-temperature plasma reactor used for simulating parasitic discharges expected under tokamak divertor domes

The presence of nanostructured dust particles has been reported in thermonuclear fusion reactors with carbon plasma-facing components. These particles contribute to tritium retention and pollution of the edge plasma. Understanding the way these particles can grow in the plasma phase is necessary for designing engineering solutions that avoid or at least limit their formation. As a first step towards this goal, this paper presents a numerical study of the formation of dust in a simple model laboratory electrical discharge: a dc discharge generated in argon with a graphite electrode. The aim here is to investigate whether carbon sputtering through ion and fast neutral bombardment of the cathode and subsequent molecular growth of carbon clusters and particle nucleation and development can explain dust formation in this model discharge. Results show that field reversal effects and negative cluster formation and trapping can fully explain dust formation in such a dc discharge.

Demonstration of in vivo stability and lack of immunogenicity of a polyethyleneglycol-conjugated recombinant CHO-derived butyrylcholinesterase bioscavenger using a homologous macaque model

Human serum and recombinant butyrylcholinesterase (rHuBChE) are the most advanced prophylactics against organophosphate (OP) toxicity due to nerve agent or insecticide exposure. For ethical reasons, such potential multi-use treatments cannot be tested in humans and will require extensive testing in animal models and the “Animal Rule” 21 (21 CFR 601.90) for regulatory approval. This will involve multiple injections of rHuBChE into heterologous animals, e.g. macaques, rodents with inevitable immunogenicity and subsequent elimination of the enzyme on repeat injections. In order to accurately assess pharmacokinetics, efficacy and safety of a candidate rBChE in an “antibody free” system, a homologous macaque (Ma) model has been developed. In these studies, macaques received single or multiple intravenous injections of native MaBChE as well as unmodified or PEG-conjugated forms of rMaBChE produced in CHO cells. Compared to the poor plasma retention of unmodified rBChE (MRT: <10 h), three injections of 1.5–2.3 mg/kg of PEG-conjugated tetrameric rBChE resulted in high circulatory stability (MRT: >134 h) and lack of immunogenicity similar to native MaBChE. PEG-conjugation of the monomeric rMaBChE form also exhibited pharmacokinetic profiles comparable to the tetrameric form (MRT: >113 h). However, despite the increased bioavailability of PEG-rBChE, antigenicity studies using sandwich ELISA showed that while macaque BChE was not immunogenic in macaques, PEGylation of rMaBChE did not prevent binding to anti-BChE antibodies, suggesting PEGylation may not be sufficient to mask non-human epitopes on rBChE. This homologous model can provide necessary preclinical protection data for the use of PEG-rHuBChE in humans and bodes well for a safe and efficacious CHO-derived rHuBChE therapeutic.

Preclinical evaluation of a monoclonal antibody targeting the epidermal growth factor receptor as a radioimmunodiagnostic and radioimmunotherapeutic agent

The studies described here are the first to evaluate the in vitro and in vivo properties of (111)In-CHX-A''-panitumumab for radioimmunotherapy (alpha- and beta(-)-emitters) and radioimmunoimaging (single photon emission computed tomography and positron emission tomography). Twenty-seven human carcinoma cell lines were analysed for expression of epidermal growth factor receptors by flow cytometry. Panitumumab was conjugated with CHX-A''-DTPA (diethylenetriamine-pentaacetic acid) and radiolabelled with (111)In. Immunoreactivity of the CHX-A''-DTPA-panitumumab and (111)In-CHX-A''-DTPA-panitumumab was evaluated by radioimmunoassays. Tumour targeting was determined in vivo by direct quantitation of tumour and normal tissues and by gamma-scintigraphy. For 26 of 27 human tumour cell lines, 95% of the cells expressed epidermal growth factor receptors over a range of intensity. Immunoreactivity of panitumumab was retained after modification with CHX-A''-DTPA. Radiolabelling of the immunoconjugate with (111)In was efficient with a specific activity of 19.5 +/- 8.9 mCi.mg(-1) obtained. Immunoreactivity and specificity of binding of the (111)In-panitumumab was shown with A431 cells. Tumour targeting by (111)In-panitumumab was demonstrated in athymic mice bearing A431, HT-29, LS-174T, SHAW or SKOV-3 s.c. xenografts with little uptake observed in normal tissues. The (111)In-panitumumab was also evaluated in non-tumour-bearing mice. Pharmacokinetic studies compared the plasma retention time of the (111)In-panitumumab in both non-tumour-bearing and A431 tumour-bearing mice. Tumour targeting was also visualized by gamma-scintigraphy. Panitumumab can be efficiently radiolabelled with (111)In with high labelling yields. Based on the efficiency in tumour targeting and low normal tissue uptake, panitumumab may be an effective targeting component for radioimmunodiagnostic and radioimmunotherapeutic applications.

Abstract: P1393 ANTHOCYANIN SUPPLEMENTATION IMPROVES THE SERUM LDL-C AND HDL-C LEVELS ASSOCIATED WITH CETP INHIBITION IN DYSLIPIDEMIC SUBJECTS

Cell-free hemoglobin, suitably modified to confer a physiological oxygen affinity and prolonged plasma retention, is a candidate for a temporary substitute for red blood cells. Such a solution would probably find wide clinical acceptance because the risks of disease transmission from banked human blood are significant. This chapter discusses the pilot-scale preparation of hemoglobin solutions. The production facility is housed in four separate, but connected, rooms: one contains the system for generation of pyrogen-free water (PFW), the second is used for reagent preparation, the third contains the filtration assemblies and the bioreactor, and the fourth is a 4° cold room that houses the preparative high-performance liquid chromatography (HPLC) equipment. An additional large walk-in cold room is available to store large tanks of buffers. The apparatus used for hemoglobin preparation consists of several components, including a manifold for emptying bags of outdated blood; cross-flow filtration devices for washing, lysis, and purification; a bioreactor for cross-linking hemoglobin; a preparative-scale HPLC apparatus; and a hood for final filling of product into sterile bags.

Experimental non-alcoholic fatty liver disease results in decreased hepatic uptake transporter expression and function in rats

Non-alcoholic fatty liver disease (NAFLD) encompasses a spectrum of diagnoses ranging from simple fatty liver (SFL), to non-alcoholic steatohepatitis (NASH). This study aimed to determine the effect of moderate and severe NAFLD on hepatic transporter expression and function in vivo. Rats were fed a high-fat diet (SFL model) or a methionine-choline-deficient diet (NASH model) for eight weeks. Hepatic uptake transporter function was determined by bromosulfophthalein (BSP) disposition. Transporter expression was determined by branched DNA signal amplification assay and western blotting; inflammation was identified by immunostaining of liver slices for interleukin 1 beta (IL-1β). MC− rats showed significant retention of BSP in the plasma when compared to control rats. Hepatic NTCP, OATP1a1, 1a4, 1b2 and 2b1; and OAT 2 and 3 mRNA levels were significantly decreased in high-fat and MC− diet rats when compared to control. Protein expression of OATP1a1 was significantly decreased in high-fat animals, while OATP1a1 and OATP1b2 expressions were significantly lower in MC− rats when compared to control. Liver tissue from high-fat and MC− rats stained positive for IL-1β, a pro-inflammatory cytokine known to decrease expression of NTCP, OATP and OAT transporters, suggesting a plausible mechanism for the observed transporter alterations. These data suggest that different stages of NAFLD result in altered hepatic uptake transporter expression that can lead to a functional impairment of xenobiotic uptake from the blood. Furthermore, NAFLD may alter the plasma retention time of clinically relevant drugs that are reliant on these transporters and may increase the potential drug toxicity.

Hierarchal Contribution of N- and C-Terminal Sequences to the Differential Localization of Homologous Sodium-Dependent Vitamin C Transporters, SVCT1 and SVCT2, in Epithelial Cells

Human sodium-dependent vitamin C transporters, SVCT1 and SVCT2, share 66% sequence identity yet localize in the apical and basolateral membranes of epithelial cells, respectively. This pair thus serves as a model for studying multipass membrane protein targeting. Domain swaps, deletions, insertions, and point mutations were performed on EGFP-tagged hSVCT1 and hSVCT2 plasmids. Mutant proteins stably expressed in MDCK cells were analyzed by confocal microscopy and Transwell ascorbate transport assays. These studies identified an SVCT2 basolateral targeting sequence (BTS) in the N-terminus, which is conserved among mammalian SVCT2 forms. The less conserved N-terminus of SVCT1 is not required for apical localization. The destruction of SVCT2 BTS led to apical localization of the protein in a manner independent of the C-terminal sequence. A C-terminal sequence present in both SVCTs appears to be required for plasma membrane incorporation and retention as its deletion led to an increased level of intracellular appearance of both apically and basolaterally targeted SVCTs in the absence or presence of BTS. Nevertheless, all C-terminal deletion mutants showed preferential apical transport activity, suggesting a greater importance of this sequence for basolateral targeting. Our results collectively suggested a default apical targeting of SVCT, which is consistent with the evolution-based prediction. The SVCT sorting model with a hierarchal contribution of N- and C-terminal sequences was compared to the observations made for other multipass membrane proteins. The involvement of both intracellularly localized termini of multipass membrane proteins in the sorting pathway suggests a more complex sorting mechanism compared to that for single-pass proteins.

Pharmacokinetics and pharmacodynamics of norfluoxetine in rats: Increasing extracellular serotonin level in the frontal cortex

Norfluoxetine is the most important active metabolite of the widely used antidepressant fluoxetine. Although the pharmacokinetics/pharmacodynamics (PK/PD) relationship and neurochemical profile of fluoxetine is well characterized in human and in animals, little is known about the effect of its metabolite. The aim of this study was to characterize extracellular level of serotonin (5-hydroxytryptamine, 5-HT)-time profile of norfluoxetine after acute administration over 18 h post dose and to establish the relationship between this pharmacodynamic (PD) profile and its pharmacokinetic (PK) properties. Following subcutaneous administration of fluoxetine in rats, plasma and brain PK of fluoxetine and norfluoxetine were monitored respectively by liquid chromatography/tandem mass spectrometry (LC/MS/MS). The extracellular level of 5-HT in the frontal cortex was measured by microdialysis as a PD endpoint. Norfluoxetine when directly administrated to rats caused a significant increase in extracellular level of 5-HT in the frontal cortex and maintained for 18 h. This result is correlated well with higher plasma and brain concentration and longer plasma and brain retention time of norfluoxetine. Our results showed that norfluoxetine contributes to 5-HT transporter inhibition and extends fluoxetine efficacy.

Tumor Regression in Mice by Delivery of Bcl-2 Small Interfering RNA with Pegylated Cationic Liposomes

The pharmacokinetics and antitumor activity of pegylated small interfering RNA (siRNA)/cationic liposome complexes were studied after systemic administration to mice. We designed pegylated-lipid carriers for achieving increased plasma concentrations of RNA and hence improved accumulation of RNA in tumors by the enhanced permeability and retention effect. We compared the pharmacokinetics of siRNA complexed with liposomes incorporating pegylated lipids with longer (C-17 or C-18), shorter (C-12 to C-16), or unsaturated (C-18:1) acyl chains. When longer acyl chains were used, the plasma concentrations of siRNA obtained were dramatically higher than when shorter or unsaturated chains were used. This may be explained by the higher gel-to-liquid-crystalline phase-transition temperature (Tc) of lipids with longer acyl chains, which may form more rigid liposomes with reduced uptake by the liver. We tested a siRNA that is sequence specific for the antiapoptotic bcl-2 mRNA complexed with a pegylated liposome incorporating a C-18 lipid (PEG-LIC) by i.v. administration in a mouse model of human prostate cancer. Three-fold higher accumulation of RNA in the tumors was achieved when PEG-LIC rather than nonpegylated liposomes was used, and sequence-specific antitumor activity was observed. Our siRNA/PEG-LIC complex showed no side effects on repeated administration and the strength of its antitumor activity may be attributed to its high uptake by the tumors. Pegylation of liposomes improved the plasma retention, uptake by s.c. tumors, and antitumor activity of the encapsulated siRNA. PEG-LIC is a promising candidate for siRNA cancer therapy.