Targeted Delivery of Mannosylated Nanoparticles Improve Prophylactic Efficacy of Immersion Vaccine against Fish Viral Disease

Immersion vaccination is considered as the most effective method for juvenile fish in preventing viral disease, due to its convenience for mass vaccination and stress-free administration. However, immune responses following immersion vaccination are generally less robust and of shorter duration than those induced through intraperitoneal injection. Herein, to improve the efficacy of the immersion vaccine, we constructed a targeted single-walled carbon nanotubes-based immersion vaccine delivery system (CNTs-M-VP7), the surface of which are modified with mannose to allow antigen-presenting cells' (APCs) targeting. The targeting ability of CNTs-M-VP7 was confirmed in vivo and in vitro. Critically, this immersion CNTs-M-VP7 vaccine could cross into the fish body through mucosal tissues (skin, gill, and intestine), and then present to immune-related tissues. Moreover, CNTs-M-VP7 could significantly induce the maturation and presenting process of APCs, which would then trigger robust immune responses. Altogether, this study demonstrates that the single-walled carbon nanotubes (SWCNTs)-based targeted nanovaccine delivery system shows the potential to be an effective prophylactic against fish viral disease.

Bispecific Antibodies for Diagnostic Applications

Bispecific monoclonal antibodies (BsMAb) are unique engineered macromolecules that have two different pre-determined binding specificities. Their ability to simultaneously bind to a specific antigen and a given detection moiety enables them to function as excellent bifunctional immunoprobes in diagnostic assays. BsMAb are being exploited for the development of simple, rapid, and highly sensitive immunoassays for diagnosis of bacterial and viral infectious diseases. This chapter describes the use of BsMAb for the detection of Mycobacterium tuberculosis, Escherichia coli O157:H7, Bordetella pertussis, Severe Acute Respiratory Syndrome coronavirus, and Dengue virus. Further, BsMAb have been utilized for diagnosis of various types of cancers. The use of BsMAb in detection of prostate cancer and in cancer diagnostic imaging is also discussed.

Sequential affinity purification of peroxidase tagged bispecific anti-SARS-CoV antibodies on phenylboronic acid agarose

Hybrid hybridomas (quadromas) are derived by fusing at least two hybridomas, each producing a different antibody of predefined specificity. The resulting cell secretes not only the immunoglobulins of both parents but also hybrid molecules manifesting the binding characteristics of the individual fusion partners. Purification of the desired bispecific immunoprobe with high specific activity from a mixture of bispecific and monospecific monoclonal antibodies requires special strategies. Using a dual, sequential affinity chromatography (Protein-G chromatography followed by m-aminophenyleboronic acid agarose column), we have purified bispecific monoclonal antibodies (BsMAb) as a preformed HRPO (Horseradish Peroxidase) complex (BsMAb-HRPO). The quadroma culture supernatant was initially processed on a Protein-G column to isolate all the species of immunoglobulins. This pre-enriched fraction was subsequently passed through the aminophenyleboronic acid column super saturated with HRPO. The column matrix has the ability to bind to proteins such as HRPO with vicinal diols. The enzyme loaded column captures the desired bispecific anti-SARS-CoVxanti-HRPO species with the elimination of the monospecific anti-SARS-CoV MAb to result in a high specific activity diagnostic probe. The presence of anti-HRPO MAb is an acceptable impurity as it will not bind to the target SARS-CoV NP antigen and will get washed out during the ELISA procedure.

Bispecific monoclonal antibodies against a viral and an enzyme: utilities in ultrasensitive virus ELISA and phage display technology

A quadroma (hybrid-hybridoma) secreting bispecific antibodies with one paratope specific for M13 bacteriophage coat protein and another paratope specific for alkaline phosphatase (AP) was developed by electro-fusion of the two parental hybridomas and selected by a fluorescence activated cell sorter (FACS). The anti-phage M13/anti-AP bsMAbs were purified from anti-phage M13 monospecific MAb by a novel affinity method using Mimetic Blue A6XL as immune complexes with AP. The purified bsMAbs with potentially every molecule uniformly bound with AP generated an immuno-probe with the theoretical highest specificity. An ultrasensitive sandwich ELISA for detecting viruses was developed by using this bsMAb coupled with an amplified ELISA procedure. The sensitivity of the assay was increased 1000 times compared with conventional ELISA to achieve detection of 100 phage particles which is approximately 2.3 fg of phage coat protein. This type of bsMAb probe and ELISA format can be used to design new body fluid assays for viral load of HIV, hepatitis and other human pathogens as rapid and inexpensive alternatives to the PCR based method. This unique bispecific probe also allowed rapid and sensitive detection of bound M13/fd phage clones while panning for specific phages displaying peptide mimics against an antigen from a phage display peptide library. Furthermore, we demonstrate the principle virus purification using bsMAb as affinity ligand with a mild phosphate buffer elution. The results indicate that bsMAb could be used to develop affinity chromatography for purifying highly contagious and pathogenic viruses avoiding procedures employing prolonged high-speed centrifugation.

Affinity chromatography and co-chromatography of bispecific monoclonal antibody immunoconjugates

Bispecific monoclonal antibodies (bsMAb) are unique macromolecules functioning as cross-linkers with two different predetermined binding specificities. A wide range of potential applications employing these probes can be envisioned in immunodiagnostics and immunotherapy. One of the major limitations for the use of bsMAbs produced by hybrid-hybridomas is the production of parental monospecific antibodies along with bsMAbs. Hence, the purification of desired bsMAb free from both parental mAbs and other possible promiscuous combinations is essential. Purification of antibodies is the single greatest obstacle in obtaining an immunoprobe with high specific activity. This review describes the affinity purification and affinity co-purification techniques for the separation of bsMAb as a pre-formed immune complex or as a pure species. The use of immobilized ligands is the basis of affinity chromatography. Affinity chromatography can be classified into three different categories depending on the properties of the immobilized ligand. The ligand-specific affinity chromatography is based on the extremely specific immobilized ligand, directed towards the protein or antibody of interest. Using a dual, sequential affinity chromatography, bsMAb can be purified from a mixture of bispecific and monospecific monoclonal antibodies with a ligand specific for each antibody. Thiophilic adsorption is a group-specific affinity method that can be successfully used to separate monospecific forms from bispecific species by salt gradient elution. Affinity co-chromatography offers a convenient one-step method for purification of bulk amounts of immunoconjugates for diagnostic applications by exploiting several dye-ligands known to bind certain enzymes. The same method could be potentially used for quality control and quality assurance purposes in industrial biotechnology.

Analysis of the binding of bispecific monoclonal antibodies with immobilized antigens (human IgG and horseradish peroxidase) using a resonant mirror biosensor

The interaction between two monoclonal antibodies (mAbs) and their corresponding bispecific antibody (bAb) with immobilized antigens has been examined using a resonant mirror biosensor (IAsys). BAbs were produced by cell fusion. The analysed panel of affinity-purified antibodies included two parental mAbs, one specific to human IgG (hIgG), and another specific to horseradish peroxidase (HRP), and a bAb derived thereof (anti-hIgG/HRP). The real-time analysis showed the drastic differences in the avidity of bivalent anti-HRP mAbs and anti-HRP shoulder of bAbs. Thus, the observed equilibrium association constant (K(ass)) of anti-HRP mAbs was about 50 times higher that of anti-HRP shoulder of bAbs. The ratio of association rate constants (k(ass)) of mAbs and bAbs was about two, due to the statistical factor of two binding sites per bivalent antibody molecule. However, the dissociation rate constant (k(diss)) of anti-HRP shoulder of bAbs was 21 times higher k(diss) of anti-HRP mAbs. The comparison with the theoretical model shows that these observations are consistent only with a situation in which bivalent binding of mAbs with immobilized HRP predominates over monovalent binding. On the contrary, the second parental mAb (anti-hIgG) did not show the increase in avidity due to bivalent binding, compared to the anti-hIgG shoulder of bAbs, suggesting that this mAb was bound monovalently to immobilized hIgG. The K(ass) values determined by solid-phase radioimmunoassay (RIA) yielded figures almost overlapping with those obtained by IAsys. The results of the comparison of bAbs and mAbs are discussed from the viewpoint of the use of bAbs in heterogeneous systems. On the other hand, these data demonstrate that real-time analysis of antibody binding parameters in IAsys biosensor is valuable for the selection of mAbs and bAbs with desired features, for different fields of application.

Production of an anti-prostate-specific antigen single-chain antibody fragment from Pichia pastoris

Prostate-specific antigen (PSA) is a widely used marker for screening and monitoring prostate cancer. Because PSA levels are normally quite low, an antibody-based assay must be used to detect PSA. However, not all PSA-specific antibodies bind equally well to PSA or to its different isoforms. Therefore, a better understanding of how PSA interacts with PSA-specific antibodies is of considerable clinical interest. B80.3 is a widely used murine monoclonal anti-PSA antibody (IgG), which has very high affinity for both free and alpha-anti-chymotrypsin complexed PSA. More importantly, its gene sequence is known-making it one of only two anti-PSA antibodies that has been fully cloned and sequenced. To better elucidate the interaction between PSA and B80.3, a single-chain antibody fragment, derived from the variable domain of B80.3 (scFvB80), was cloned into a pPIC9 vector and expressed in Pichia pastoris. The secreted protein was purified using a three-step protocol beginning with a 50% ammonium sulfate precipitation step, followed by a T-gel thio-affinity step and concluding with a simple anion-exchange (DE52) filtration step. NMR studies indicate the protein is correctly folded while competitive enzyme-linked immunosorbant assays show that the purified scFvB80 has approximately 20% of the activity of the full-length B80.3 antibody. The protocol described here provides a quick and convenient route to prepare large quantities of very pure anti-PSA antibody fragments (15-20 mg/L culture medium) for detailed structural and biophysical characterization.

The comparison of the ability of monoclonal antibodies directed to different proteins (human IgG, human myoglobin and HRP) and bispecific antibodies derived thereof to bind antigens immobilized on a surface of a solid phase

BACKGROUND

Bindings of mouse monoclonal antibodies (mAbs) and affinity purified bispecific antibodies (bAbs), derived thereof, to antigens adsorbed on immunoplates have been compared, using ELISA and RIA methods.

METHODS

The analysed panel of antibodies included mAbs specific to human myoglobin (Mb), human IgG (hIgG) and horseradish peroxidase (HRP) and biologically produced bAbs with double specificity to Mb and HRP, and to hIgG and HRP.

RESULTS

The degree of difference between different mAbs and corresponding bAbs varied markedly from antibody to antibody, depending on whether the parental mAbs could bind immobilized antigens bivalently. The observed equilibrium binding constant (K(obs)) for anti-HRP mAbs was 21-38 times higher that of anti-HRP site of bAbs (anti-hIgG/HRP or anti-Mb/HRP, respectively), due to bivalent binding of mAbs. Anti-Mb mAbs also bound bivalently with immobilized Mb. On the contrary, anti-hIgG mAbs bound monovalently with immobilized hIgG in the same conditions. The avidity of anti-Mb/HRP bAbs increased, if both antigens were simultaneously adsorbed on a solid phase.

CONCLUSIONS

The obtained data indicate that the use of bAbs in heterogeneous immunoassays instead of traditional mAb-enzyme conjugates hardly can provide the significant gain in assay performance if parental mAbs bind bivalently.

A general affinity method to purify peroxidase-tagged antibodies

Antibodies tagged with enzymes, e.g. horseradish peroxidase (HRPO) are used extensively in a broad range of immunoassay, immunohistochemical, and prodrug-based immunotherapeutic applications. These antibodies may be polyclonal, monoclonal, bispecific or genetically engineered in origin. Often, purification of the antibody is the single greatest obstacle to obtaining immunoprobes with high specific activity [Milstein and Cuello, Nature 305 (1983) 537]. We have circumvented this problem by utilising benzhydroxamic acid-agarose to purify the antibodies tagged with HRPO as a preformed immune complex. Benzhydroxamic acid has been shown to have affinity for the active site of HRPO [de Ropp et al., Biochemistry 38 (1999) 1077]. A preliminary ammonium sulfate precipitation of 250 ml of bispecific antibody supernatant was performed and the pellet resuspended and dialysed against phosphate buffer (pH 7.0). This fraction was incubated with HRPO, then loaded on the affinity column which was washed, and the labelled bispecfic monoclonal antibodies were eluted under mild conditions (borate buffer pH 9.0). The effective yield of this bispecific antibody-HRPO complex was 30 assay plates or 3000 wells. We have also successfully co-purified covalent polyclonal-HRPO conjugates and HRPO-labelled streptavidin using a similar strategy to obtain enzyme-labelled probes with high specific activities for a multitude of applications.

Development of a bispecific monoclonal antibody as a universal immunoprobe for detecting biotinylated macromolecules

Bispecific monoclonal antibody (BsMab) combining two different antigen binding sites, anti-biotin and anti-HRPO paratopes, could be used as a universal immunoprobe for detecting all biotinylated macromolecules. First, a mouse hybridoma cell line secreting monospecific anti-biotin Mab was generated and characterized. Second, a quadroma cell line which could continuously secrete bsMab (anti-biotin x anti-HRPO) was developed by a nonselective microelectrofusion method. The supernatant containing bsMab was collected from tissue culture medium and purified with two affinity columns. This bsMab has comparable avidity to commercial streptavidin-HRPO when tested against biotinylated macromolecules. Compared to streptavidin, this bsMab can bind the enzyme and thus eliminate the need for chemical conjugation. This bsMab can be used as a promising immunoprobe for detecting many macromolecules bearing biotin markers, such as protein, phage, liposome and DNA in different bioassay systems.

Efficient bispecific monoclonal antibody purification using gradient thiophilic affinity chromatography

Bispecific monoclonal antibodies (bsMAbs), due their unique design, have a wide range of potential applications in immunodiagnostics and immunotherapy. One of the major limitations for the use of bsMAbs produced by hybrid-hybridomas is the concomitant production of parental monospecific antibodies. The relative amount of bsMAb secreted may vary between different hybrid-hybridomas. Hence, the purification of the desired bispecific molecule from other forms is crucial. Current purification methods include anion-exchange, HPLC on different matrices, and dual affinity methods. Most of those methods include multiple steps and have limitations on the purity or yield of the desired species. We report here a simple single-step purification method, using inexpensive thiophilic chromatography. This new method can potentially be scaled up, for industrial proposes. Finally, based on the amino acid sequences and assembly of the two heavy chains we attempt to explain the possible mechanism by which thiophilic chromatography was able to resolve the bsMAbs from the monospecific species.

A new method to generate quadromas by electrofusion and FACS sorting

Bispecific monoclonal antibodies (bsMAbs) are unique molecules incorporating two different paratopes in a single antibody molecule. BsMAbs can be useful in different areas of research as well in clinical applications. Traditionally, bsMAbs are produced by hybrid-hybridomas that are generated by the fusion of two pre-established hybridomas. The development of such hybrid-hybridomas can be difficult and time-consuming. Here, we introduce a new technique to generate such hybrids, electro-FACS-fusion. In this procedure, before the electrofusion, one of the hybridomas is labeled with fluorescein isothiocyanate (FITC) and the other with tetramethylrhodamine isothiocyanate (TRITC). The mixture of cells is then electrofused, and cells exhibiting dual fluorescence are selected by fluorescence activated cell sorting (FACS). The fused cells are directly plated in microplates for clonal growth. Using this technique, we produced three new hybrid-hybridomas secreting bsMAb that could be used for the next generation of immunoassays.

Mimetic ligand-based affinity purification of immune complexes and immunoconjugates

We developed a simple purification method to purify alkaline phosphatase/anti-alkaline phosphatase IgG as immune complexes using mimetic affinity chromatography wherein the antibody was either a monospecific antibody, a bispecific antibody or a commercial polyclonal IgG conjugated with alkaline phosphatase (AP-IgG) covalently. The immune complexes or conjugates were efficiently bound on the mimetic Blue A6XL column and eluted under mild conditions (5-20 mM phosphate buffer). A similar strategy of purifying peroxidase/anti-peroxidase antibody complexes was also successfully demonstrated using the mimetic Red 3 column. Mimetic affinity chromatography thus appears to be a simple method to purify the desired monospecific or bispecific antibodies from the respective hybridomas and quadromas.