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

A sensitive three-step protocol for fluorescence-based Western blot detection

Western blotting is widely used in protein analysis, classically using enhanced chemoluminescence for protein detection. Fluorescence-labelled secondary antibodies have emerged in recent years for detection of antigens, in order to improve the sensitivity and the linear range of detection. Here we show that the sensitivity can be further improved by an additional step in the detection procedure: the antigen is detected by successive incubations with a primary antibody, followed by a biotinylated secondary antibody and then a tertiary fluorescent conjugate. Using the detection of different antigens by CyDye-conjugated secondary antibodies in a two-step protocol as a reference, two tertiary fluorescent conjugates were evaluated: CyDye-conjugated streptavidin and CyDye-conjugated anti-biotin antibody. An four-fold increase in sensitivity was achieved with CyDye-conjugated streptavidin; numerous unspecific bands were also generated. CyDye-conjugated anti-biotin antibody did not generate any unspecific bands and led to a 30-fold increase in sensitivity, compared to detection with CyDye-conjugated secondary antibody.

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.

Development of homogeneous binding assays based on fluorescence resonance energy transfer between quantum dots and Alexa Fluor fluorophores

We studied the fluorescence resonance energy transfer (FRET) between quantum dots emitting at 565, 605, and 655 nm as energy donors and Alexa Fluor fluorophores with absorbance maxima at 594, 633, 647, and 680 nm as energy acceptors. As a first step, we prepared covalent conjugates between all three types of quantum dots and each of the Alexa Fluor fluorophores that could act as an energy acceptor. All of these conjugates displayed efficient resonance energy transfer. Then we prepared covalent conjugates of these quantum dots with biotin, fluorescein, and cortisol and established that the binding of these conjugates to suitable Alexa Fluor-labeled antibodies and streptavidin (in the case of biotin) can be efficiently detected by measuring the resonance energy transfer in homogeneous solutions. Finally, based on these observations, competitive binding assays for these three small analytes were developed. The performance of these assays as a function of the degree of labeling of the quantum dots was evaluated. It was found that decreasing the degree of loading of the quantum dots leads to decreases of the limits of detection. The results show the great potential of this FRET system for the development of new homogeneous binding assays.

Antigen targeting to dendritic cells with bispecific antibodies

We have developed a universal DC targeting vehicle that could be a convenient method to deliver any type of antigen to DC. P125, a quadroma (hybrid-hybridoma) secreting bispecific monoclonal antibodies (bsmAb), with one paratope specific for mouse DC DEC-205 and another paratope specific for biotin, was developed by PEG-fusion of the two parental hybridomas and selected by a fluorescence activated cell sorter. The bsmAb were purified using a biotin-Agarose column and the bsmAb activity was demonstrated using ELISA method employing mouse bone marrow DC and biotinylated BSA. Both confocal microscopy and ELISA studies have shown enhanced binding and internalization of biotinylated and FITC-labelled M13 to DC cell in the presence of bsmAb. In vivo studies in mice with biotinylated OVA has shown that in the presence of bsmAb and anti-CD40 mAb, both humoral and cell-mediated responses can be augmented. In addition, only a low concentration of antigen (500 fold less) is required using bsmAb to achieve a similar immune response in mice that were immunized using complete Freund's adjuvant. In the absence of traditional adjuvants, bsmAb targeting of biotinylated antigens to DC could be an alternative, convenient method to deliver antigens to DC. Moreover, this method could be an alternative method to ex vivo stimulation of DC to overcome DC defects and for treatment of cancer.

Bispecific antibody conjugates in therapeutics

Bispecific monoclonal antibodies have drawn considerable attention from the research community due to their unique structure against two different antigens. The two-arm structure of bsMAb allows researchers to place a therapeutic agent on one arm while allowing the other to specifically target the disease site. The therapeutic agent can be a drug, toxin, enzyme, DNA, radionuclide, etc. Furthermore, bsMAb may redirect the cytotoxicity of immune effector cells towards the diseased cells or induce a systemic immune response against the target. BsMAb holds great promise for numerous therapeutic needs in the light of: (1) recent breakthroughs in recombinant DNA technology, (2) the increased number of identified disease targets as the result of the completion of human genomic map project, and (3) a better understanding of the mechanism of human immune system. This review focuses on therapeutic applications and production of bsMAb while providing the up-to-date clinical trial information.

Phage display technology: clinical applications and recent innovations

Phage display is a molecular diversity technology that allows the presentation of large peptide and protein libraries on the surface of filamentous phage. Phage display libraries permit the selection of peptides and proteins, including antibodies, with high affinity and specificity for almost any target. A crucial advantage of this technology is the direct link that exists between the experimental phenotype and its encapsulated genotype, which allows the evolution of the selected binders into optimized molecules. Phage display facilitates engineering of antibodies with regard to their size, valency, affinity, and effector functions. The selection of antibodies and peptides from libraries displayed on the surface of filamentous phage has proven significant for routine isolation of peptides and antibodies for diagnostic and therapeutic applications. This review serves as an introduction to phage display, antibody engineering, the development of phage-displayed peptides and antibody fragments into viable diagnostic reagents, and recent trends in display technology.

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.

Bispecific MAb aided liposomal drug delivery

We have developed a new method for specifically delivering liposomal model drugs to tumor cells. Bispecific monoclonal antibodies (bsMAb) (174H.64 x anti-biotin) which can bind tumor-specific antigen and biotin were developed and characterized. Biotinylated stealth liposome loaded with model drug 99mTc-DTPA can bind to the biotin-binding arm of bsMAb. This targeted liposomal delivery strategy was tested in mouse KLN-205 squamous carcinoma model. bsMAbs were administered 24h in advance into tumor allograft bearing mice, which allow them to bind to tumor cells through the anti-tumor binding arm. After clearance of circulating bsMAb, biotinylated stealth liposomes were introduced to specifically bind to the tumor sites where bsMAb localized earlier. The results show that pretargeted bsMAb can enhance liposomal drug targeting by four times, 3.61% dose/g vs. 0.89% dose/g. This bsMAb/liposome strategy show the broad possibilities of selective delivery of cytotoxic drugs or genes to the specific targets.

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.

Anti-TNP monoclonal antibodies as reagents for enzyme immunoassay (ELISA)

The aim of this study was to produce anti-TNP monoclonal antibodies (MAbs) that could be conjugated and used for the detection of antigen-antibody reactions, in which the antigen specific-antibody had been previously bound to trinitrophenyl (TNP). For hybridoma production, SP2/0-Ag14 cells were fused with spleen cells from mice previously immunized with TNP-ovalbumin (TNP-OVA). After 10 days, enzyme-linked immunoadsorbent assay (ELISA) was used to detect anti-TNP antibodies in the supernatants, and five cultures were found to be strictly positive for TNP. Three of these were subsequently cloned by limiting dilution, and 15 clones were chosen for expansion based on the criterion of high reactivity against TNP. Anti-TNP MAbs produced by those clones were isotyped as IgG1, and purified by Sepharose-protein G affinity cromatography from ascites developed in BALB/c mice. Two purified MAbs (1B2.1B6 and 1B2.1E12) were coupled to horseradish peroxidase (HRPO). The resulting conjugates were evaluated in ELISA tests for interferon-gamma and interleukin-4 detection, in which the secondary anti-cytokine antibodies were coupled either to TNP or biotin. The performance of anti-TNP conjugates in these assays were compared with a biotin-streptavidin/peroxidase system. Both types of conjugates were similarly able to detect cytokines with r2 (linear correlation coefficient) close to unity value. Growth studies of one of those hybridomas (1B2.1B6) yielded a specific growth rate of 0.042 h(-1) and a doubling time of 16.5 h. Data discussed here show that at least two MAbs against TNP raised in this work can be used as a reagent for enzyme immunoassays.