Collaborative Enhancement of Antibody Binding to Distinct PECAM-1 Epitopes Modulates Endothelial Targeting

Antibodies to platelet endothelial cell adhesion molecule-1 (PECAM-1) facilitate targeted drug delivery to endothelial cells by “vascular immunotargeting.” To define the targeting quantitatively, we investigated the endothelial binding of monoclonal antibodies (mAbs) to extracellular epitopes of PECAM-1. Surprisingly, we have found in human and mouse cell culture models that the endothelial binding of PECAM-directed mAbs and scFv therapeutic fusion protein is increased by co-administration of a paired mAb directed to an adjacent, yet distinct PECAM-1 epitope. This results in significant enhancement of functional activity of a PECAM-1-targeted scFv-thrombomodulin fusion protein generating therapeutic activated Protein C. The “collaborative enhancement” of mAb binding is affirmed in vivo, as manifested by enhanced pulmonary accumulation of intravenously administered radiolabeled PECAM-1 mAb when co-injected with an unlabeled paired mAb in mice. This is the first demonstration of a positive modulatory effect of endothelial binding and vascular immunotargeting provided by the simultaneous binding a paired mAb to adjacent distinct epitopes. The “collaborative enhancement” phenomenon provides a novel paradigm for optimizing the endothelial-targeted delivery of therapeutic agents

Chemical Linkage to Injected Tissues Is a Distinctive Property of Oxidized Avidin

We recently reported that the oxidized avidin, named AvidinOX®, resides for weeks within injected tissues as a consequence of the formation of Schiff's bases between its aldehyde groups and tissue protein amino groups. We also showed, in a mouse pre-clinical model, the usefulness of AvidinOX for the delivery of radiolabeled biotin to inoperable tumors. Taking into account that AvidinOX is the first oxidized glycoprotein known to chemically link to injected tissues, we tested in the mouse a panel of additional oxidized glycoproteins, with the aim of investigating the phenomenon. We produced oxidized ovalbumin and mannosylated streptavidin which share with avidin glycosylation pattern and tetrameric structure, respectively and found that neither of them linked significantly to cells in vitro nor to injected tissues in vivo, despite the presence of functional aldehyde groups. The study, extended to additional oxidized glycoproteins, showed that the in vivo chemical conjugation is a distinctive property of the oxidized avidin. Relevance of the high cationic charge of avidin into the stable linkage of AvidinOX to tissues is demonstrated as the oxidized acetylated avidin lost the property. Plasmon resonance on matrix proteins and cellular impedance analyses showed in vitro that avidin exhibits a peculiar interaction with proteins and cells that allows the formation of highly stable Schiff's bases, after oxidation

Avidin attachment to biotinylated erythrocytes induces homologous lysis via the alternative pathway of complement

Noncovalent attachment of avidin to the membrane of prebiotinylated red blood cells (RBCs) induces lysis via the alternative pathway of complement (APC). Lysis is not species-dependent; RBCs from humans, rabbits, rats, and sheep were lysed with both autologous and all heterologous sera. Both biotinylated and native cells were not lysed. Lysis was observed at an avidin surface density of about 10(5) molecules per cell. Acylation of avidin prevents lysis and decreases the positive charge of the avidin. Lysis depends on the length of the cross-linking agent used for the biotin attachment to the membrane. An increase in the length of the cross-linking agent was accompanied by an enhancement of the lysis and the agglutination titer of biotinylated RBCs in a solution of avidin. It is suggested that avidin attachment induces some transformations of the cell membrane that lead to the conversion from “APC nonactivator” cells to “APC activator” cells. The interaction of avidin with membrane APC-restrictors (decay-accelerating factors, type 1 receptor for complement, homologous restriction factor, and others), the charge of avidin, and its cross-linking ability in lysis are discussed. It is proposed that membrane rearrangement induced by multipoint avidin attachment to biotinylated membrane is the main reason for avidin-induced elimination of APC restriction.</jats:p

Avidin attachment to biotinylated erythrocytes induces homologous lysis via the alternative pathway of complement

Abstract Noncovalent attachment of avidin to the membrane of prebiotinylated red blood cells (RBCs) induces lysis via the alternative pathway of complement (APC). Lysis is not species-dependent; RBCs from humans, rabbits, rats, and sheep were lysed with both autologous and all heterologous sera. Both biotinylated and native cells were not lysed. Lysis was observed at an avidin surface density of about 10(5) molecules per cell. Acylation of avidin prevents lysis and decreases the positive charge of the avidin. Lysis depends on the length of the cross-linking agent used for the biotin attachment to the membrane. An increase in the length of the cross-linking agent was accompanied by an enhancement of the lysis and the agglutination titer of biotinylated RBCs in a solution of avidin. It is suggested that avidin attachment induces some transformations of the cell membrane that lead to the conversion from “APC nonactivator” cells to “APC activator” cells. The interaction of avidin with membrane APC-restrictors (decay-accelerating factors, type 1 receptor for complement, homologous restriction factor, and others), the charge of avidin, and its cross-linking ability in lysis are discussed. It is proposed that membrane rearrangement induced by multipoint avidin attachment to biotinylated membrane is the main reason for avidin-induced elimination of APC restriction.</jats:p