Genetic removal of the CH1 exon leads to the production of hypofunctional heavy chain-only IgG2a in rats.

Despite great values in many applications, heavy chain-only antibodies (HcAbs) are naturally only produced in camelids and sharks, which are not easy to access and handle. Production of the type of antibodies in small laboratory animals would remarkably facilitate their applications. We previously reported a mouse line in which the CH1 exon of mouse γ1 was deleted that could express heavy chain-only IgG1 antibodies. However, these mice showed an extremely weak IgG1 response to specific antigens when immunized, and we could only achieve single VH domains with low affinity to antigens using these mice. One possibility is that the mouse germline VH repertoire was not sufficient to support the expression of functional heavy chain-only antibodies. In this study, we report the generation of a rat line in which the CH1 exon of the γ2a gene was removed and the γ1 and γ2b genes were silenced. Although the genetically modified rats expressed heavy chain-only IgG2a, they also exhibited a very weak IgG2a response to antigen immunization. Panning of a phage library constructed using IgG2a VH segments amplified from immunized rats identified antigen-specific single VH antibodies, which also exhibited much lower affinity than that of commercial mAbs. Together with our previous report, this study suggests that the simple genetic removal of the CH1 exon does not guarantee the successful expression of functional heavy chain-only antibodies.

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.

Use of the single cell gel electrophoresis (comet assay) for comparing apoptotic effect of conventional antibodies versus nanobodies.

The large molecular size of antibodies is considered one major factor preventing them from becoming more efficient therapeutically. It is well established that all camelids have unique antibodies circulating in their blood called heavy-chain antibodies (HcAbs). Unlike antibodies from other species, these HcAbs contain a single variable domain and two constant domains (CH2 and CH3). HcAbs are a novel type of immunoglobulin-like, antigen binding protein with beneficial pharmacokinetic properties that are ideally suited to targeting cellular antigens for molecular imaging or therapeutic purposes. Since the antigen-binding site of dromedary HcAb is comprised in one single domain, it was referred to as nanobody. In the present work, the different IgG subclasses from immunized camel (Camelus dromedairus) were purified employing their different affinity for protein A column (PA) and protein G column (PG). Characterization of IgG subclasses was done by using 12% SDS-PAGE under reducing conditions. Protein bands were visualized after staining with Coomassie Brilliant Blue, showing two bands at 50 kDa and 30 kDa in case of IgG1 while IgG2 and IgG3 produce only one band at 46 kDa and 43 kDa respectively. The induction of apoptosis by either conventional or nanobodies was evaluated on two different cell lines, Colon and Hepatic cancer cell (HCT116 and HepG2), using the comet assay. Induced apoptosis were confirmed by visualizing DNA fragmentation bands on 2% agarose gel, and the gel was photographed under UV light. This study demonstrates the successful targeting of human cancer colon cell lines by nanobodies in vitro. It may open perspectives for their future use as tumor target vehicle, due to their small size, soluble behavior and they interact with epitopes that are less antigenic for conventional antibodies.

Corrigendum: Genetic Removal of the CH1 Exon Enables the Production of Heavy Chain-Only IgG in Mice.

[This corrects the article DOI: 10.3389/fimmu.2018.02202.].

Genetic Removal of the CH1 Exon Enables the Production of Heavy Chain-Only IgG in Mice.

Nano-antibodies possess great potential in many applications. However, they are naturally derived from heavy chain-only antibodies (HcAbs), which lack light chains and the CH1 domain, and are only found in camelids and sharks. In this study, we investigated whether the precise genetic removal of the CH1 exon of the γ1 gene enabled the production of a functional heavy chain-only IgG1 in mice. IgG1 heavy chain dimers lacking associated light chains were detected in the sera of the genetically modified mice. However, the genetic modification led to decreased expression of IgG1 but increased expression of other IgG subclasses. The genetically modified mice showed a weaker immune response to specific antigens compared with wild type mice. Using a phage-display approach, antigen-specific, single domain VH antibodies could be screened from the mice but exhibited much weaker antigen binding affinity than the conventional monoclonal antibodies. Although the strategy was only partially successful, this study confirms the feasibility of producing desirable nano-bodies with appropriate genetic modifications in mice.

Nanobody-derived nanobiotechnology tool kits for diverse biomedical and biotechnology applications.

Owing to peculiar properties of nanobody, including nanoscale size, robust structure, stable and soluble behaviors in aqueous solution, reversible refolding, high affinity and specificity for only one cognate target, superior cryptic cleft accessibility, and deep tissue penetration, as well as a sustainable source, it has been an ideal research tool for the development of sophisticated nanobiotechnologies. Currently, the nanobody has been evolved into versatile research and application tool kits for diverse biomedical and biotechnology applications. Various nanobody-derived formats, including the nanobody itself, the radionuclide or fluorescent-labeled nanobodies, nanobody homo- or heteromultimers, nanobody-coated nanoparticles, and nanobody-displayed bacteriophages, have been successfully demonstrated as powerful nanobiotechnological tool kits for basic biomedical research, targeting drug delivery and therapy, disease diagnosis, bioimaging, and agricultural and plant protection. These applications indicate a special advantage of these nanobody-derived technologies, already surpassing the "me-too" products of other equivalent binders, such as the full-length antibodies, single-chain variable fragments, antigen-binding fragments, targeting peptides, and DNA-based aptamers. In this review, we summarize the current state of the art in nanobody research, focusing on the nanobody structural features, nanobody production approach, nanobody-derived nanobiotechnology tool kits, and the potentially diverse applications in biomedicine and biotechnology. The future trends, challenges, and limitations of the nanobody-derived nanobiotechnology tool kits are also discussed.