Anti-immunoglobulin binding and activation of snapper (Pagrus auratus) leucocytes

Potential Applications of Fluorescence-Activated Cell Sorting (FACS) and Droplet-Based Microfluidics in Promoting the Discovery of Specific Antibodies for Characterizations of Fish Immune Cells

Akin to their mammalian counterparts, teleost fish possess a complex assortment of highly specialized immune cells that are capable of unleashing potent innate immune responses to eradicate or mitigate incoming pathogens, and also differentiate into memory lymphocytes to provide long-term protection. Investigations into specific roles and functions of fish immune cells depend on the precise separation of each cell type. Commonly used techniques, for example, density gradient centrifugation, rely on immune cells to have differing sizes or densities and thus fail to separate between similar cell types (e.g. T and B lymphocytes). Furthermore, a continuously growing database of teleost genomic information has revealed an inventory of cellular markers, indicating the possible presence of immune cell subsets in teleost fish. This further complicates the interpretation of results if subsets of immune cells are not properly separated. Consequently, monoclonal antibodies (mAbs) against specific cellular markers are required to precisely identify and separate novel subsets of immune cells in fish. In the field of fish immunology, mAbs are largely generated using the hybridoma technology, resulting in the development of mAbs against specific cellular markers in different fish species. Nevertheless, this technology suffers from being labour-intensive, time-consuming and most importantly, the inevitable loss of diversities of antibodies during the fusion of antibody-expressing B lymphocytes and myeloma cells. In light of this, the focus of this review is to discuss the potential applications of fluorescence-activated cell sorting and droplet-based microfluidics, two emerging technologies capable of screening and identifying antigen-specific B lymphocytes in a high-throughput manner, in promoting the development of valuable reagents for fish immunology studies. Our main goal is to encourage the incorporation of alternative technologies into the field of fish immunology to promote the production of specific antibodies in a high-throughput and cost-effective way, which could better allow for the precise separation of fish immune cells and also facilitate the identification of novel immune cell subsets in teleost fish.

Monoclonal antibodies recognising serum immunoglobulins and surface immunoglobulin-positive cells of puffer fish, torafugu (Takifugu rubripes)

Immunoglobulin of the torafugu, Takifugu rubripes, was purified by a combination of precipitation by low ionic strength dialysis and gel filtration. The Ig was used to immunise mice for the production of monoclonal antibody (MAb). Supernatants of hybridoma cultures were screened by enzyme-linked immunosorbent assay using purified-torafugu Ig-coated plates, and two stable hybridomas producing MAbs against torafugu Ig were obtained. Sodium dodecyl sulphate-polyacrylamide gel electrophoresis under reducing conditions and Western blotting indicated that one MAb (16F3) was specific for the deglycosylated heavy chain of torafugu, and the other MAb (4H5) did not bind to the reduced Ig, suggesting that 4H5 recognised the higher-order structure of Ig. Under non-reduced conditions, both MAbs recognised mainly a 750 kDa band and also minor bands of 672, 410 and 205 kDa. MAb 16F3- and 4H5-primed magnetic beads (Dynabeads) adsorbed 84.9+/-3.3% and 63.6+/-4.4% of the torafugu Ig, respectively. The Ig adsorbed by MAb 16F3-primed Dynabeads was reactive to 4H5 on immunoblotting, and vice versa, indicating that the epitopes for both MAbs are held on the same Ig molecule. Both of these MAbs cross-reacted extensively with the Ig of other Takifugu species, but not with other genus. The MAbs were used to identify surface Ig-positive lymphocytes in the spleen, pronephros, peripheral blood and thymocytes of torafugu by flow cytometry. Flow cytometric analysis of the cells in the lymphocyte-enriched fraction revealed that 50.2+/-6.9% in the PBL, 11.8+/-1.7% in the mesonephros, 13.3+/-2.1% in the pronephros, 42.5+/-4.3% in the spleen and 3.2+/-0.6% in thymus were reactive to 4H5 or 16F3.