Development and Characterization of New Species Cross-Reactive Anti-Sialoadhesin Monoclonal Antibodies.

Sialoadhesin (Sn) is a surface receptor expressed on a subset of macrophages in steady state conditions. During inflammation and diseases, Sn is highly upregulated on macrophages and blood monocytes. Therefore, therapies using monoclonal antibodies (mAbs) to target Sn-positive (Sn+) cells are a potential strategy for targeted treatment. It has been shown that Sn internalizes after binding with a mAb, though it is not clear whether this is species-specific. In this study, new Sn-specific mAbs were developed and analyzed for cross-reactivity between species. In addition, the newly developed mAbs were compared to mAbs used in previous research for their epitope recognition and other Sn-specific characteristics. Both species-specific and cross-reactive antibodies could be identified. Furthermore, sialic acid-binding of red blood cells (RBC) could be inhibited with mAbs recognizing different epitopes and all mAb showed internalization of Sn. The newly developed mAbs can be used as novel tools for Sn research and further analysis of Sn internalization in different species.

Von Willebrand factor: drug and drug target.

One of the key players in many thrombotic complications is von Willebrand factor (VWF), a large, multimeric glycoprotein that is present in plasma where it fulfils a crucial role in haemostasis. First, VWF recruits platelets to vascular lesions by acting as a linker molecule between the exposed collagen and free-flowing platelets in the circulation. Second, by serving as a carrier protein for the coagulation factor VIII, VWF protects this anti-haemophilic factor from rapid degradation. Quantitative or qualitative defects in VWF result in the most common bleeding disorder in man, known as von Willebrand disease, illustrating the central role of VWF in haemostasis. On the other hand, a thrombotic risk emerges when over-reactive VWF molecules can bind spontaneously to platelets. It is clear that because of its pivotal role in maintaining the fine balance between bleeding and thrombosis, VWF is an attractive but delicate drug target. This review focuses on the role of VWF in both haemostasis and thrombosis with special attention to the molecule as drug and drug target respectively.

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.