Investigation of the therapeutic potential of recombinant bispecific bivalent anti-PD-L1/VEGF nanobody in inhibition of angiogenesis.

OBJECTIVE: Immunotherapy using monoclonal antibodies targeting programmed death ligand-1 (PD-L1) on cancer cells as a biomarker of escape from response to immune checkpoint has demonstrated efficacy in treating many solid tumors. In addition, some of the signals, such as vascular endothelial growth factor (VEGF), bind to receptors on the surface of normal endothelial cells and encourage angiogenesis, or the formation and survival of new blood vessels. METHODS: Due to the special features of nanobodies with high specificity and affinity as a powerful new tool in cancer therapy, here, a recombinant bispecific bivalent anti-PD-L1/VEGF nanobody was constructed and its functionality in inhibition of angiogenesis in vitro was investigated. RESULTS: Results demonstrated that bivalent anti-PD-L1/VEGF nanobody efficiently inhibited HUVEC and A431 cells proliferation and tube formation. In addition, bivalent anti-PD-L1/VEGF nanobody efficiently inhibited angiogenesis in an ex ovo Chick Chorioallantoic Membrane assay. DISCUSSION: The results indicate for the potential of bivalent anti-PD-L1/VEGF nanobody as a novel promising tool for cancer therapy.

In vivo solid tumor targeting with recombinant VEGF-diphtheria immunotoxin.

Objectives: A variety of signaling molecules have been identified that play a role in angiogenesis, of prime importance, vascular endothelial growth factor (VEGF) and its resceptor (VEGFR), which is highly expressed in most human solid tumors. Targeting VEGF or/and VEGFR with immunotoxin may be a promising approach to directly affect cancer cells. Immunotoxins are for targeted treatment comprising two functional moieties, an antibody that binds to target cells along with toxin that kills molecules. Materials and Methods: In this study, an immunotoxin comprising domain of diphtheria toxin subunit A (DT386) genetically fused to mouse VEGF (mVEGF-DT) was developed. The second construct, which contains the DT386 domain, was made to investigate the action of the DT386 domain on tumor cells. Both gene constructs were cloned, expressed, and were further purified. The biological activity of mVEGF-DT and DT386 proteins was assessed on the TC1 cell line bearing mouse model. Proteins were injected intra-tumoral in mice, in separate groups. Results: Tumors in the mVEGF-DT group started to dwindle after six injections, but tumor size in both control groups (DT386 and PBS), continued to grow. Conclusion: Successful targeting of solid tumor cells by mVEGF-DT immunotoxin demonstrates the therapeutic potential utility of these conjugates for tumor targeting.

In Vivo Tumor Therapy with Novel Immunotoxin Containing Programmed Cell Death Protein-1 and Diphtheria Toxin.

Immunotoxins, as a class of antitumor agents, consist of tumor-selective ligands linked to highly toxic protein molecules. This type of modified antibody has been designed for the therapy of cancers and a few viral infections. In this study, we designed immunotoxin consisting of mouse programmed cell death protein-1 (PD1), which genetically fused to diphtheria toxin (DT) subunit A (DT386). DNA construct was cloned, expressed in a bacterial system, purified, and confirmed by western blotting. The immunotoxin potency in the treatment of tumorous C57BL/6 mice was evaluated. Immunotoxin was injected intratumoral to mice, and through eight injections, 67% of the tumor volume of the test group started shrinking dramatically. On the contrary, the tumor size of the control group, treated with phosphate-buffered saline, continued its growth. The successful targeting of solid tumor cells by PD1-DT immunotoxin demonstrates the potential therapeutic utility of these conjugates.

Isolation and characterization of nanobodies against epithelial cell adhesion molecule as novel theranostic agents for cancer therapy.

Epithelial cell adhesion molecule (EpCAM) plays an important role in tumorigenesis. Camelids produce functional antibodies composed of heavy chains only that bind to their antigens via a single domain variable fragment known as nanobody. Nanobodies show multiple advantages over traditional monoclonal antibodies. Isolation of functional anti-EpCAM nanobodies (Nbs) was the main aim of this study. An immune nanobody library containing 108 members was constructed previously. Anti -EpCAM nanobodies were isolated from camel immune library using phage display. Four consecutive rounds of biopanning were performed on immobilized EpCAM. Four nanobodies (Nb4, Nb5, Nb22, and Nb23) with highest signal intensity in monoclonal phage ELISA were selected. Affinity of these selected nanobodies for EpCAM was in the nanomolar range. Selected nanobodies significantly inhibited proliferation of MCF-7 cells. The in vivo study revealed that a significant reduction in tumor size occurred when treated with nanobodies Nb4 and Nb5, after 14 days monitoring. Our data revealed that nanobodies Nb4 and Nb5 could be considered as attractive theranostic agents for EpCAM overexpressing cancers.

Selection and characterization of specific nanobody against neuropilin-1 for inhibition of angiogenesis.

Neuropilin-1 (NRP-1), non-tyrosine kinase receptor, was initially identified as axonal protein and later recognized as co-receptor for vascular endothelial growth factor (VEGF). Neuropilins (NRPs) are involved in vascular development and tumor angiogenesis. Over the last years, many studies have been accomplished to inhibit angiogenesis. In this study, the nanobody library was panned against immobilized NRP-1 antigen. High affinity and specificity nanobodies were selected through monoclonal ELISA. The selected nanobodies inhibited proliferation and tube formation of HUVEC and MCF-7 cells in vitro and ex vivo. The results highlight potential of anti-NRP1 nanobodies in inhibition of angiogenesis both in vitro and ex vivo and promises development of novel therapeutics against pathologic angiogenesis.