Claudin-1 Binder Enhances Epidermal Permeability in a Human Keratinocyte Model.

Tight junctions (TJs) are complex biochemical structures that seal the intercellular space and prevent the free movement of solutes across epithelial cell sheets. Modulating the TJ seal is a promising option for increasing the transdermal absorption of drugs. Within TJs, the binding of the claudin (CLDN) family of tetratransmembrane proteins through cis- and trans-interactions is an integral part of seal formation. Because epidermal TJs contain CLDN-1 and CLDN-4, a binder for these CLDNs may be a useful modulator of the permeability of the epidermal barrier. Here, we investigated whether m19, which can bind to CLDN-1/-4 (also CLDN-2/-5), modulates the integrity of epidermal TJs and the permeability of cell sheets to solutes. Treatment of normal human epidermal keratinocytes (NHEKs) with the CLDN binder reduced the integrity of TJs. A CLDN-1-specific binder (a monoclonal antibody, clone 7A5) also weakened the TJ seal in NHEKs. Although m19 attenuated the TJ barrier in human intestinal epithelial cells (Caco-2), 7A5 did not. Treatment of NHEKs with 7A5 enhanced permeation of a paracellular permeation marker. These findings indicate that CLDN-1 is a potential target for modulating the permeability of the epidermis, and that our CLDN-1 binder is a promising candidate molecule for development as a dermal absorption enhancer.

Monoclonal antibodies against extracellular domains of claudin-1 block hepatitis C virus infection in a mouse model.

UNLABELLED: Hepatitis C virus (HCV) entry into host cells is a complex process requiring multiple host factors, including claudin-1 (CLDN1). Safe and effective therapeutic entry inhibitors need to be developed. We isolated a human hepatic Huh7.5.1-derived cell mutant that is nonpermissive to HCV, and comparative microarray analysis showed that the mutant was CLDN1 defective. Four hybridomas were obtained, which produced monoclonal antibodies (MAbs) that interacted with the parental Huh7.5.1 cell but not with the CLDN1-defective mutant. All MAbs produced by these hybridomas specifically bound to human CLDN1 with a very high affinity and prevented HCV infection of Huh7.5.1 cells in a dose-dependent manner, without apparent cytotoxicity. Two selected MAbs also inhibited HCV infection of human liver-chimeric mice without significant adverse effects. CLDN1 may be a potential target to prevent HCV infection in vivo. Anti-CLDN1 MAbs may hence be promising candidates as novel anti-HCV agents. IMPORTANCE: Safe and effective therapeutic entry inhibitors against hepatitis C virus (HCV) are very useful for combination therapies with other anti-HCV drugs, such as direct-acting antivirals. In this study, we first showed an effective strategy for developing functional monoclonal antibodies (MAbs) against extracellular domains of a multimembrane-spanning target protein, claudin-1 (CLDN1), by using parental cells expressing the intact target membrane protein and target-defective cells. The established MAbs against CLDN1, which had a very high affinity for intact CLDN1, efficiently inhibited in vitro and in vivo HCV infections. These anti-CLDN1 MAbs are promising leads for novel entry inhibitors against HCV.

Discovery of anti-claudin-1 antibodies as candidate therapeutics against hepatitis C virus.

Claudin-1 (CLDN1), a known host factor for hepatitis C virus (HCV) entry and cell-to-cell transmission, is a target molecule for inhibiting HCV infection. We previously developed four clones of mouse anti-CLDN1 monoclonal antibody (mAb) that prevented HCV infection in vitro. Two of these mAbs showed the highest antiviral activity. Here, we optimized the anti-CLDN1 mAbs as candidates for therapeutics by protein engineering. Although Fab fragments of the mAbs prevented in vitro HCV infection, their inhibitory effects were much weaker than those of the whole mAbs. In contrast, human chimeric IgG1 mAbs generated by grafting the variable domains of the mouse mAb light and heavy chains inhibited in vitro HCV infection as efficiently as the parental mouse mAbs. However, the chimeric IgG1 mAbs activated Fcγ receptor, suggesting that cytotoxicity against mAb-bound CLDN1-expressing cells occurred through the induction of antibody-dependent cellular cytotoxicity (ADCC). To avoid ADCC-induced side effects, we prepared human chimeric IgG4 mAbs. The chimeric IgG4 mAbs did not activate Fcγ receptor or induce ADCC, but they prevented in vitro HCV infection as efficiently as did the parental mouse mAbs. These findings indicate that the IgG4 form of human chimeric anti-CLDN1 mAb may be a candidate molecule for clinically applicable HCV therapy.

Silica-installed redox nanoparticles for novel oral nanotherapeutics - improvement in intestinal delivery with anti-inflammatory effects.

Silica nanoparticles were synthesized via a sol-gel method in which tetraethyl orthosilicate was hydrolyzed by the alkaline core of the nitroxide radical-containing nanoparticle (RNP). The silica nanoparticles were successively captured in the RNP core to obtain silica/RNP nanocomposite (siRNP). Alternatively, siRNP was prepared using commercially available silica nanoparticles. The amount of elemental Si present in the siRNPs was controlled from 3 wt% to 12 wt%. Notably, the obtained siRNPs were stable in acidic media, whereas the starting RNP disintegrated immediately. Crosslinking of the RNP by the entrapped silica might improve stability of the siRNPs under such acidic conditions. Rebamipide was found to be stably encapsulated in the cores of the prepared siRNPs even under acidic conditions, probably due to the both basic environment of the cores and absorption tendencies of the entrapped silica. Under neutral to alkaline conditions, release of the rebamipide is accelerated, which is probably due to the repulsion between the anionic silica surface and the anionic rebamipide. Rebamipide-loaded siRNPs (rebamipide@siRNP) were orally administered to mice, and the plasma level of rebamipide was checked at predetermined time intervals, showing a significantly higher uptake of rebamipide in the plasma when compared to orally-administered free rebamipide. Because siRNP possesses nitroxide radicals in the core, it is confirmed that dextran sodium sulfate-induced colon inflammation was effectively suppressed by the oral administration of rebamipide@siRNP in mice.

Paratope and epitope mapping of the antithrombotic antibody 6B4 in complex with platelet glycoprotein Ibalpha.

The monoclonal antibody 6B4 has a potent antithrombotic effect in nonhuman primates by binding to the flexible loop, also known as the beta-switch region (amino acids 230-242), of glycoprotein Ibalpha (GPIbalpha). This interaction blocks, in high shear stress conditions, the specific interaction between GPIbalpha and von Willebrand factor suppressing platelet deposition to the damaged vessel wall, a key event in the pathogenesis of arterial thrombosis. To understand the interactions between this antibody and its antigen at the amino acid level, we here report the identification of the paratope and epitope in 6B4 and GPIbalpha, respectively, by using computer modeling and site-directed mutagenesis. The docking programs ZDOCK (rigid body docking) and HADDOCK (flexible docking) were used to model the interaction of 6B4 with GPIbalpha and to delineate the respective paratope and epitope. 6B4 and GPIbalpha mutants were constructed and assayed for their capacity to bind GPIbalpha and 6B4, respectively. From these data, it is found that the paratope of 6B4 is mainly formed by five residues: Tyr(27D), Lys(27E), Asp(28), and Glu(93) located in light chain CDR1 and -3, respectively, and Tyr(100C) of the heavy chain CDR3. These residues form a valley, where the GPIbalpha flexible loop can bind via residues Asp(235) and Lys(237). The experimental results were finally used to build a more accurate docking model. Taken together, this information provides guidelines for the design of new derivatized lead compounds with antithrombotic properties.