Covalent Chaotropic Membrane Transport for Biotherapeutic Delivery (CARAMEL)
โถSummary
Finding new synthetic compounds that facilitate membrane transport of impermeable bioactive molecules constitutes one of the grand scientific challenges in chemistry, biology, and medicine. Until today, the design principles of artificial transporters have been mainly restricted to membrane-targeting molecules with segregated hydrophilic and hydrophobic domains. We propose a disruptive strategy that uses boron clusters as membrane carriers that abandon the classical amphiphilic topology and exploit the (super)chaotropicity of boron cluster anions. Chaotropicity, historically associated with the salting-in effects of ions on proteins, has only recently been related to the affinity of large cluster ions to hydrophobic surfaces. In comparison to amphiphilic carriers, boron clusters are fully inorganic, highly water-soluble, globular in shape, and induce direct membrane transport despite being anionic in nature. The mere existence of these carriers defies all previous conceptual assumptions and biomimetic design criteria. Here, we introduce a new scenario for chaotropic membrane transport. A new chaotropic strategy will be introduced. A systematic transport screening will be carried out to study the fundamental physicochemical parameters and to generate a cargo-dependent predictive model for covalent chaotropic transport. Functional biomolecular hybrids will be validated to achieve proof-of-principle for the therapeutic potential. This proposal is aimed to fully unfold the potential of the new chaotropic scenario and intended to shake the very foundations of research in membrane transport.