Sensitive immunoassay of Legionella using multivalent conjugates of engineered VHHs.

VHH antibodies or nanobodies, which are antigen-binding domains of heavy chain antibodies from camelid species, have several advantageous characteristics, including compact molecular size, high productibility in bacteria and easy engineering for functional improvement. Focusing on these advantages of VHHs, we attempted to establish an immunoassay system for detection of Legionella, the causative pathogen of Legionnaires' disease. A VHH phage display library was constructed using cDNA from B cells of alpacas immunized with Legionella pneumophila serogroup1 (LpSG1). Through biopanning, two specific VHH clones were isolated and used to construct a Legionella detection system based on the latex agglutination assay. After engineering the VHHs and improving the assay system, the sensitive detection system was successfully established for the LpSG1 antigen. The immunoassay developed in this study should be useful in easy and sensitive detection of Legionella, the causative agent of Legionnaires' disease, which is a potentially fatal pneumonia.

Prediction of antigen-responding VHH antibodies by tracking the evolution of antibody along the time course of immunization.

Antibody maturation is the central function of the adaptive immune response. This process is driven by the repetitive selection of mutations that increase the affinity toward antigens. We hypothesized that a precise observation of this process by high-throughput sequencing along the time course of immunization will enable us to predict the antibodies reacting to the immunized antigen without any additional in vitro screening. An alpaca was immunized with IgG fragments using multiple antigen injections, and the antibody repertoire development was traced via high-throughput sequencing periodically for months. The sequences were processed into clusters, and the antibodies in the 16 most abundant clusters were generated to determine whether the clusters included antigen-binding antibodies. The sequences of most antigen-responsive clusters resembled those of germline cells in the early stages. These sequences were observed to accumulate significant mutations and also showed a continuous sequence turnover throughout the experimental period. The foregoing characteristics gave us >80% successful prediction of clusters composed of antigen-responding VHHs against IgG fragment. Furthermore, when the prediction method was applied to the data from other alpaca immunized with epidermal growth factor receptor, the success rate exceeded 80% as well, confirming the general applicability of the prediction method. Superior to previous studies, we identified the immune-responsive but very rare clusters or sequences from the immunized alpaca without any empirical screening data.

Isolation and characterization of antigen-specific alpaca (Lama pacos) VHH antibodies by biopanning followed by high-throughput sequencing.

The antigen-binding domain of camelid dimeric heavy chain antibodies, known as VHH or Nanobody, has much potential in pharmaceutical and industrial applications. To establish the isolation process of antigen-specific VHH, a VHH phage library was constructed with a diversity of 8.4 × 10(7) from cDNA of peripheral blood mononuclear cells of an alpaca (Lama pacos) immunized with a fragment of IZUMO1 (IZUMO1PFF) as a model antigen. By conventional biopanning, 13 antigen-specific VHHs were isolated. The amino acid sequences of these VHHs, designated as N-group VHHs, were very similar to each other (>93% identity). To find more diverse antibodies, we performed high-throughput sequencing (HTS) of VHH genes. By comparing the frequencies of each sequence between before and after biopanning, we found the sequences whose frequencies were increased by biopanning. The top 100 sequences of them were supplied for phylogenic tree analysis. In total 75% of them belonged to N-group VHHs, but the other were phylogenically apart from N-group VHHs (Non N-group). Two of three VHHs selected from non N-group VHHs showed sufficient antigen binding ability. These results suggested that biopanning followed by HTS provided a useful method for finding minor and diverse antigen-specific clones that could not be identified by conventional biopanning.

Highly efficient production of VHH antibody fragments in Brevibacillus choshinensis expression system.

Anti-IZUMO1PFF VHH (variable domain of camelid heavy chain antibody) clones, N6 and N15, from immunized alpaca (Lama pacos) phage library were efficiently expressed and their VHH products were secreted into the culture medium of Brevibacillus choshinensis HPD31-SP3, e.g., at a level of 26-95mg in 100ml conventional flask culture. With a 3-L scale fed-batch culture for 65h, the N15 VHH protein with C-terminal His-tag was produced at ∼3g/l culture medium. The N6 and N15 proteins were easily purified to apparent homogeneity by cation exchange and Ni-affinity chromatographies. Both proteins showed specific antigen-binding activity by ELISA and high antigen binding affinity, KD=6.0-8.6nM, by surface plasmon resonance analysis. Size exclusion chromatography-multi-angle laser light scattering analysis revealed that N6 and N15 proteins purified were exclusively monomeric form in phosphate buffered saline. CD spectrum showed beta-sheet rich structure, consistent with a typical antibody structure and also suggested aromatic-aromatic interactions, as indicated by a positive peak at 232nm. Thermal melting analysis of the N15 protein with C-terminal His-tag demonstrated a clear thermal transition with a Tm at 67°C. The heat-denatured sample recovered antigen binding activity upon cooling, indicating a reversible denaturation.

Selection and characterization of human serum albumin-specific porcine scFv antibodies using a phage display library.

A new single-chain variable fragment (scFv) antibody library was generated and human serum albumin (HSA)-specific clones were characterized to investigate the usefulness of porcine antibodies. Phage libraries were developed from pigs immunized with the model antigen HSA. The library size was 1.5 × 10(7) for kappa (VL) and 1.4 × 10(7) for lambda fragments. Eight HSA-specific clones from the kappa library and one clone from the lambda library were isolated using affinity selection. The binding specificity of these clones was confirmed using a phage enzyme-linked immunosorbent assay (ELISA). The scFvs were expressed in Escherichia coli and purified from the periplasm fraction for further investigation. Based on the results of ELISA and Western blot analysis, four scFv clones with high activity and high yield were selected and purified. The purified scFvs from four of the nine clones exhibited an approximate KD of 10(-8) M. This is the first report describing isolation of HSA-specific porcine scFv antibodies from an antibody phage library and characterization of their binding properties.