Abstract
A facile chemical approach integrating supramolecular chemistry, site‐selective protein chemistry, and molecular biology is described to engineer synthetic multidomain protein therapeutics that sensitize cancer cells selectively to significantly enhance antitumor efficacy of existing chemotherapeutics. The desired bioactive entities are assembled via supramolecular interactions at the nanoscale into structurally ordered multiprotein complexes comprising a) multiple copies of the chemically modified cyclic peptide hormone somatostatin for selective targeting and internalization into human A549 lung cancer cells expressing SST‐2 receptors and b) a new cysteine mutant of the C3bot1 (C3) enzyme from Clostridium botulinum, a Rho protein inhibitor that affects and influences intracellular Rho‐mediated processes like endothelial cell migration and blood vessel formation. The multidomain protein complex, SST3‐Avi‐C3, retargets C3 enzyme into non‐small cell lung A549 cancer cells and exhibits exceptional tumor inhibition at a concentration ≈100‐fold lower than the clinically approved antibody bevacizumab (Avastin) in vivo. Notably, SST3‐Avi‐C3 increases tumor sensitivity to a conventional chemotherapeutic (doxorubicin) in vivo. These findings show that the integrated approach holds vast promise to expand the current repertoire of multidomain protein complexes and can pave the way to important new developments in the area of targeted and combination cancer therapy.
Highlights
A facile chemical approach integrating supramolecular chemistry, site-selecto overcome chemoresistance in oncotherapy.[1,2] Therapeutic antibodies and tive protein chemistry, and molecular biology is described to engineer syntoxin enzymes are eminent candidates for thetic multidomain protein therapeutics that sensitize cancer cells selectively to significantly enhance antitumor efficacy of existing chemotherapeutics
Naturally occurring human antiavidin antibodies can be present in human serum, it has been established with oncology patients that this does not hamper the safety and efficacy, rendering it suitable for therapeutic application.[50]
In order to avoid a broad distribution of products, the optimal stoichiometry of somatostatin with terminal biotin (B-SST) bound to Avi was characterized by displacing 2-(4-hydroxyphenylazo)benzoic acid (HABA)[54] from the biotin-binding sites
Summary
This effect only occurred when the intact multiprotein complex SST3-Avi-C3 was applied and it did not occur when the individual components, namely the SST3-Avi transporter or B-C3, were applied (Figures S11 and S12, Supporting Information) These results clearly indicate that SST3-Avi-C3-mediated inhibition of neoangiogenesis depends on both, (1) the somatostatin to address SSTR-expressing target cells and induce efficient cellular uptake and (2) the Rho-modulating C3 toxin moiety to affect intracellular mechanisms. Co-administration of antiangiogenic SST3-Avi-C3 and DOX was tested in vivo in the CAM xenotransplantation model, and significantly reduced bioluminescence of luciferase-transfected lung cancer xenografts was observed when compared to either monotherapy (Figure 6f,g)
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