A high affinity and specificity anti-HER2 single-domain antibody (VHH) that targets trastuzumab's epitope with versatile biochemical, biological, and medical applications.

In the past decade, various single-domain antibodies from llamas, also known as VHH or nanobody, have been discovered with applications in tumor imaging and cancer therapy. However, the potential application of anti-HER2 VHHs as a diagnostic tool suitable for ELISA, flow cytometry, cell imaging, bispecific antibody engineering, and immunohistochemistry has not been fully elucidated. To investigate this potential, HER2 antigen was expressed in HEK293 F cells, purified, and used to immunize llama. Using phage display, anti-HER2 VHHs with high affinity and specificity were isolated, sequenced, and constructed with a Histag and c-Myc tag. The constructed anti-HER2 VHHs were then expressed in E. coli, purified, and evaluated for their use in ELISA, flow cytometry, cell imaging, and immunohistochemistry. The affinities of the anti-HER2 VHHs toward the HER2 antigen were determined using biolayer interferometry. Furthermore, the binding sites of the anti-HER2 VHHs were evaluated by epitope mapping and in silico modeling and docking. Here, we report the sequence of an anti-HER2 VHH with high affinity (sub-nanomolar), specificity, and selectivity. This VHH binds to the same epitope as trastuzumab and can be utilized to generate bispecific antibodies or used as a diagnostic tool to differentiate HER2+ from HER2- antigens on plates, cells, and tissues. This discovery has broad applications in biochemical, biological, and medical sciences.

Bispecific killer cell engager with high affinity and specificity toward CD16a on NK cells for cancer immunotherapy.

Introduction: The Fc region of monoclonal antibodies (mAbs) interacts with the CD16a receptor on natural killer (NK) cells with "low affinity" and "low selectivity". This low affinity/selectivity interaction results in not only suboptimal anticancer activity but also induction of adverse effects. CD16a on NK cells binds to the antibody-coated cells, leading to antibody-dependent cell-mediated cytotoxicity (ADCC). Recent clinical data have shown that the increased binding affinity between mAb Fc region and CD16a receptor is responsible for significantly improved therapeutic outcomes. Therefore, the objective of this study was to develop a bispecific killer cell engager (BiKE) with high affinity and specificity/selectivity toward CD16a receptor for NK cell-based cancer immunotherapy. Methods: To engineer BiKE, a llama was immunized, then high binding anti-CD16a and anti-HER2 VHH clones were isolated using phage display. ELISA, flow cytometry, and biolayer interferometry (BLI) data showed that the isolated anti-CD16a VHH has high affinity (sub-nanomolar) toward CD16a antigen without cross-reactivity with CD16b-NA1 on neutrophils or CD32b on B cells. Similarly, the data showed that the isolated anti-HER2 VHH has high affinity/specificity toward HER2 antigen. Using a semi-flexible linker, anti-HER2 VHH was recombinantly fused with anti-CD16a VHH to create BiKE:HER2/CD16a. Then, the ability of BiKE:HER2/CD16a to activate NK cells to release cytokines and kill HER2+ cancer cells was measured. As effector cells, both high-affinity haNK92 (CD16+, V176) and low-affinity laNK92 (CD16+, F176) cells were used. Results and discussion: The data showed that the engineered BiKE:HER2/CD16a activates haNK92 and laNK92 cells to release cytokines much greater than best-in-class mAbs in the clinic. The cytotoxicity data also showed that the developed BiKE induces higher ADCC to both ovarian and breast cancer cells in comparison to Trazimera™ (trastuzumab). According to the BLI data, BiKE:HER2/CD16 recognizes a different epitope on CD16a antigen than IgG-based mAbs; thus, it provides the opportunity for not only monotherapy but also combination therapy with other antibody drugs such as checkpoint inhibitors and antibody-drug conjugates. Taken together, the data demonstrate the creation of a novel BiKE with high affinity and specificity toward CD16a on NK cells with the potential to elicit a superior therapeutic response in patients with HER2+ cancer than existing anti-HER2 mAbs.

Active-Site Protonation States in an Acyl-Enzyme Intermediate of a Class A ß-Lactamase with a Monobactam Substrate.

The monobactam antibiotic aztreonam is used to treat cystic fibrosis patients with chronic pulmonary infections colonized by Pseudomonas aeruginosa strains expressing CTX-M extended-spectrum ß-lactamases. The protonation states of active-site residues that are responsible for hydrolysis have been determined previously for the apo form of a CTX-M ß-lactamase but not for a monobactam acyl-enzyme intermediate. Here we used neutron and high-resolution X-ray crystallography to probe the mechanism by which CTX-M extended-spectrum ß-lactamases hydrolyze monobactam antibiotics. In these first reported structures of a class A ß-lactamase in an acyl-enzyme complex with aztreonam, we directly observed most of the hydrogen atoms (as deuterium) within the active site. Although Lys 234 is fully protonated in the acyl intermediate, we found that Lys 73 is neutral. These findings are consistent with Lys 73 being able to serve as a general base during the acylation part of the catalytic mechanism, as previously proposed.