Abstract
The interest for developing antibody-driven therapeutic interventions has exponentially grown over the last few decades. Even though there have been promising leaps in the development of efficacious antibody therapies, problems revolving around production and site-directed delivery of these large macromolecules persist. This is especially pertinent when it comes to designing and producing antibodies to penetrate the blood-brain barrier (BBB) to tackle neurodegenerative diseases. One of the most effective approaches to alleviating this problem is to employ a "Trojan Horse" approach, using receptor-mediated transcytosis, such as those governed by the transferrin receptor (TfR)-mediated pathways, to deliver large protein payloads into the brain. Even though this method is effective, ideal limiting factors, related to how the antibody binds to the TfR, need to be elucidated to improve BBB penetrance. With this said, we have designed and produced a single-chain Fc antibody, conjugated to an scFv8D3 TfR binding motif, creating a single-chain monovalent BBB transporter (scFc-scFv8D3). This recombinant protein is easy to produce and purify, demonstrates monovalent binding to the TfR and is structurally stable at physiologically relevant temperatures. Using an in vitro BBB model system, we show a positive correlation between the concentration of administered antibody and transcytosis efficacy, with scFc-scFv8D3 demonstrating significantly higher transcytosis levels compared with scFv8D3-conjugated bivalent antibodies at elevated administered concentrations. Furthermore, in vivo studies recapitulate the in vitro results, with the scFc-scFv8D3 demonstrating an elevated brain uptake at higher therapeutic doses in wild-type mice, comparable with that of the scFv8D3-conjugated bivalent antibody control. In addition, the half-life of the single-chain monovalent BBB transporter is comparable with that of standard IgG antibodies, indicating that the scFc format does not exacerbate physiological degradation. Our results lead us to the conclusion that valency and affinity are important variables to consider when discerning optimal transport across the BBB using TfR-mediated transcytosis pathways. In addition, we believe the single-chain Fc antibody we have described, which can easily be manipulated to accommodate a bispecific target tactic, provides a simple and efficacious approach for delivering therapeutic payloads to the brain milieu.