Phage display as a tool for identifying HIV-1 broadly neutralizing antibodies.

Combinatorial biology methods offer a good solution for targeting interactions of specif ic molecules by a high-throughput screening and are widely used for drug development, diagnostics, identif ication of novel monoclonal antibodies, search for linear peptide mimetics of discontinuous epitopes for the development of immunogens or vaccine components. Among all currently available techniques, phage display remains one of the most popular approaches. Despite being a fairly old method, phage display is still widely used for studying protein-protein, peptide-protein and DNA-protein interactions due to its relative simplicity and versatility. Phage display allows highly representative libraries of peptides, proteins or their fragments to be created. Each phage particle in a library displays peptides or proteins fused to its coat protein and simultaneously carries the DNA sequence encoding the displayed peptide/protein in its genome. The biopanning procedure allows isolation of specif ic clones for almost any target, and due to the physical link between the genotype and the phenotype of recombinant phage particles it is possible to determine the structure of selected molecules. Phage display technology continues to play an important role in HIV research. A major obstacle to the development of an effective HIV vaccine is an extensive genetic and antigenic variability of the virus. According to recent data, in order to provide protection against HIV infection, the so-called broadly neutralizing antibodies that are cross-reactive against multiple viral strains of HIV must be induced, which makes the identif ication of such antibodies a key area of HIV vaccinology. In this review, we discuss the use of phage display as a tool for identif ication of HIV-specif ic antibodies with broad neutralizing activity. We provide an outline of phage display technology, brief ly describe the design of antibody phage libraries and the affinity selection procedure, and discuss the biology of HIV-1-specif ic broadly neutralizing antibodies. Finally, we summarize the studies aimed at identif ication of broadly neutralizing antibodies using various types of phage libraries.

shp-2 gene knockout upregulates CAR-driven cytotoxicity of YT NK cells.

In Russia, cancer is the second leading cause of death following cardiovascular diseases. Adoptive transfer of NK cells is a promising approach to fight cancer; however, for their successful use in cancer treatment, it is necessary to ensure their robust accumulation at tumor foci, provide resistance to the immunosuppressive tumor microenvironment, and to engineer them with higher cytotoxic activity. NK lymphocytes are known to kill cancer cells expressing a number of stress ligands; and the balance of signals from inhibitory and activating receptors on the surface of the NK cell determines whether a cytotoxic reaction is triggered. We hypothesized that stronger cytotoxicity of NK cells could be achieved via gene editing aimed at enhancing the activating signaling cascades and/or weakening the inhibitory ones, thereby shifting the balance of signals towards NK cell activation and target cell lysis. Here, we took advantage of the CRISPR/Cas9 system to introduce mutations in the coding sequence of the shp-2 (PTPN11) gene encoding the signaling molecule of inhibitory pathways in NK cells. These shp-2 knock-out NK cells were additionally transduced to express a chimeric antigen receptor (CAR) that selectively recognized the antigen of interest on the target cell surface and generated an activating signal. We demonstrate that the combination of shp-2 gene knockout and CAR expression increases the cytotoxicity of effector NK-like YT cells against human prostate cancer cell line Du-145 with ectopic expression of PSMA protein, which is specifically targeted by the CAR.

Characteristics of Artificial Immunogens Containing Peptide Mimotopes of HIV-1 Epitopes Recognized by Monoclonal Antibodies 2F5 and 2G12.

The paper describes construction of TBI-based recombinant proteins TBI-2F5 and TBI-2G12 that contain peptide mimotopes of HIV-1 epitopes recognized by broadly neutralizing antibodies 2F5 and 2G12, respectively. The capacity of the immunogens to induce neutralizing antibodies was evaluated. The sera of BALB/c mice immunized with recombinant proteins TBI, TBI-2F5, and TBI-2G12 neutralized HIV-1 env-pseudoviruses. Moreover, pooled serum from mice immunized with TBI-2F5 and TBI-2G12 neutralized env-pseudoviruses of HIV-1 subtype B more effectively than individual sera.

[The impact of the antibody 2F5 biotinylation on the selection of the peptides from combinatorial phage library].

The impact of monoclonal antibodies (mAb) biotinylation on the output and the repertoire of selected peptides in the biopanning procedure were tested. A comparative analysis of the peptides selected from phage library using the biotinylated and non-biotinylated mAb 2F5 was performed. It was shown that the output of peptides homologous to the native epitope was 1.7-fold higher for biotinylated antibodies, whereas the binding capacity of the selected phages with mAb 2F5 in ELISA was higher in the case of using non-biotinylated antibodies. It should be noted that the phages exposing peptides, which have 4-5 amino acid sequence similarity with the native epitope, demonstrate the highest binding affinity. The phages that expose peptides with 3 amino acid sequence similarity demonstrate different binding affinity: from the smallest to the largest. Based on the obtained data, it is safe to suggest that the rational biopanning may proceed in accordance with the task.