Enhancement of the enzymatic activity of activated coagulation factor IX by anti-factor IX antibodies.

BACKGROUND: Factor VIIIa (FVIIIa) binds to activated FIX and enhances the activation of FX by several orders of magnitude. Deficiency of FVIII causes the bleeding disorder hemophilia A and is treated by i.v. infusion of FVIII concentrates. OBJECTIVES: To explore whether or not FVIII activity can be supplied by alternative molecules, e.g. molecules with FIXa-binding activity. METHODS: Conventional hybdridoma technology was used to discover antibodies exhibiting FVIII-like activity. RESULTS: We identified a series of antibodies specific for human FIX that mimicked the stimulatory effect of FVIIIa on FIXa. Upon binding to human FIXa, these antibodies enhanced the protease activity of FIXa towards its natural substrate FX about tenfold. A similar enhancement was also achieved with 5 pm FVIIIa (i.e. 16 mU mL(-1) or 1.6% activated FVIII). Procoagulant activity of these anti-FIXa antibodies was observed in model systems containing purified proteins as well as in plasma. CONCLUSION: Our findings show that FVIII can, at least partially, be replaced by an unrelated molecule. Procoagulant antibodies might potentially aid the development of an FVIII substitute for hemophilia A treatment.

Improved detection of Beet necrotic yellow vein virus in a DAS ELISA by means of antibody single chain fragments (scFv) which were selected to protease-stable epitopes from phage display libraries.

The detection of Beet necrotic yellow vein virus (BNYVV) in stored sugar beets by means of monoclonal antibodies or antibody single chain fragments (scFv) often poses problems, because the immunodominant C-terminal epitope of the viral coat protein is readily lost due to proteolysis. Clones which produce scFv specific for protease-stable BNYVV epitopes were selected from two naive phage display libraries. Fusion proteins of the scFv with a human IgG kappa chain (expressed from the newly designed vector pCL) or with alkaline phosphatase,respectively, allow the ELISA detection of BNYVV even in stored sugar beets with a sensitivity which was comparable or often higher than that achieved with polyclonal antibodies.

Fully "Recombinant Enzyme-Linked Immunosorbent Assays" Using Genetically Engineered Single-Chain Antibody Fusion Proteins for Detection of Citrus tristeza virus.

ABSTRACT Recombinant single-chain variable fragment antibodies (scFv) that bind specifically to Citrus tristeza virus (CTV), which cause the most detrimental viral disease in the citrus industry worldwide, were obtained from the hybridoma cell lines 3DF1 and 3CA5. These scFv were genetically fused with dimerization domains as well as with alkaline phosphatase, respectively, and diagnostic reagents were produced by expressing these fusion proteins in bacterial cultures. The engineered antibodies were successfully used for CTV diagnosis in plants by tissue print enzyme-linked immunosorbent assay (ELISA) and double antibody sandwich-ELISA. The fully recombinant ELISAs were as specific and sensitive as conventional ELISAs performed with the parental monoclonal antibodies, showing the usefulness of recombinant antibodies for routine detection of a virus in woody plants for the first time.

Application of Phage Display in Selecting Tomato spotted wilt virus-Specific Single-Chain Antibodies (scFvs) for Sensitive Diagnosis in ELISA.

ABSTRACT A panel of recombinant single-chain antibodies (scFvs) against structural proteins of Tomato spotted wilt virus (TSWV) was retrieved from a human combinatorial scFv antibody library using the novel phage display technique. After subcloning the encoding DNA sequences in the expression vector pSKAP/S, which allowed the scFvs to be expressed as alkaline phosphatase fusion proteins, 17 different scFv antibodies were obtained. Of these, 12 scFvs were directed against the nucleoprotein (N) and 5, putatively, against the glycoproteins (G1 and G2). Five of the N-specific antibodies cross-reacted with two other tospoviruses (Tomato chlorotic spot virus and Groundnut ringspot virus), but none recognized the more distantly related tospoviruses Impatiens necrotic spot virus, Watermelon silverleaf mottle virus, Iris yellow spot virus, or Physalis severe mottle virus. The successful use of one of the antibodies as coating and detection reagent in a double-antibody sandwich enzyme-linked immunosorbent assay showed the potential of the phage display system in obtaining antibodies for routine TSWV diagnosis.

pSKAP/S: An expression vector for the production of single-chain Fv alkaline phosphatase fusion proteins.

The vector pSKAP/S was constructed to enable overexpression of single-chain variable fragment antibody (scFv)-alkaline phosphatase fusion proteins. In pSKAP/S, the scFv were genetically fused to the mutated Escherichia coli PhoA/S gene that encodes an alkaline phosphatase with increased specific activity. The restriction sites incorporated into pSKAP/S allowed the scFv genes to be easily transferred from pUC119-derived phagemid vectors that are used frequently in phage display antibody library technology. Strong transcriptional control of expression was achieved using the tetracycline promoter, and induction of different individual clones with anhydrotetracycline resulted in secretion of most of the scFv-alkaline phosphatase fusion proteins into the culture medium. Although some of the clones secreted fusion proteins that were retained in the periplasm, these proteins could be isolated with a simple extraction procedure. Increased amounts of a scFv-alkaline phosphatase fusion protein were obtained when expressed in the pSKAP/S vector compared with expression in a vector incorporating the lac promoter. Testing for binding of the scFv-alkaline phosphatase fusion proteins to antigen was possible in an ELISA without the need for additional enzyme-conjugated antibodies. The pSKAP/S vector was successfully used to obtain scFv fragments from a preparation of phage-antibody clones after subcloning and expression of individual clones as scFv-alkaline phosphatase fusions, whereas fewer clones (and clones with different properties) were obtained from the same phage-antibody preparations when expressed as soluble scFv fragments. Therefore, the pSKAP/S vector was shown to be useful in extending the range of scFv obtained from phage display libraries.

Single-chain Fv fusion proteins suitable as coating and detecting reagents in a double antibody sandwich enzyme-linked immunosorbent assay.

A recombinant enzyme-linked immunosorbent assay (ELISA) system, entirely based on antibody fragments, is described here as an attractive alternative to assays using polyclonal antisera or monoclonal antibodies. Two expression vectors have been developed for cloning and production of single-chain Fv (scFv) fusion proteins suitable as coating and detecting reagents, respectively, in a highly sensitive double antibody sandwich ELISA. The coating reagent is produced from the vector pZIP1, as a bivalent miniantibody with a leucine zipper for dimerization. The detection reagent is a fusion protein, in which a modified Escherichia coli alkaline phosphatase with increased specific activity is attached to the carboxy-terminus of the scFv. This conjugate is produced using pDAP2/S as cloning and expression vector. Optimized bacteria expression and simple one-step purification by hexahistidine tag-mediated metal chelate affinity chromatography yielded milligrams of ELISA reagent per liter of bacterial culture in both cases. A double antibody sandwich ELISA for the detection of beet necrotic yellow vein virus, the causal agent of sugarbeet rhizomania, was developed using fusion proteins obtained by means of pZIP1 and pDAP2/S. The plant pathogen was detected with a sensitivity higher than that reached in a conventional ELISA employing polyclonal antisera. Both plasmid vectors are compatible to phage display vectors such as pHEN1, pCOCK, and the pCANTAB series, allowing simple subcloning after isolation of scFv from phage display libraries. It is therefore easy to develop and produce an ELISA entirely by using bacterial recombination and expression techniques.

A scFv-alkaline phosphatase fusion protein which detects potato leafroll luteovirus in plant extracts by ELISA.

A single chain Fv antibody fragment (scFv) was obtained from a synthetic phage-antibody library after four rounds of selection against purified preparations of potato leafroll luteovirus (PLRV). Nucleotide sequence analysis showed that the scFv belongs to the human V(H)3 family. DNA encoding the scFv was sub-cloned into pDAP2 such that a scFv-alkaline phosphatase fusion protein was produced by transformed bacteria following induction by isopropyl-beta-D-thiogalactopyranoside (IPTG). The fusion protein was obtained at concentrations of 10 mg/l of Escherichia coli culture medium and these fusion protein preparations were used directly in ELISA to detect PLRV in sap extracts from infected plants. Our work is the first report of the selection of a scFv specific for a luteovirus from a synthetic phage-display library and the production of a fusion protein with alkaline phosphatase for the detection of PLRV in infected plants. The results demonstrate the potential of scFv and enzyme-scFv fusion proteins in routine testing for plant virus infection.

pDAP2: a vector for construction of alkaline phosphatase fusion-proteins.

BACKGROUND: Expression of enzymatically active protein fusions in Escherichia coli could facilitate the analysis of proteins and even replace some reagents frequently used in immunology such as chemically produced antibody-enzyme conjugates. For this purpose there is up to now no system of general utility available. OBJECTIVES: The vector pDAP2 has been designed for simplified fusion of single-chain Fv fragments to the N-terminus of E. coli alkaline phosphatase. The resulting immunoconjugates can be produced by expression in E. coli and purified in a single step via metal affinity chromatography. STUDY DESIGN: Several different single-chain Fv genes as well as peptide coding oligonucleotides have been cloned into pDAP2 and tested for expression levels, purification properties and usefulness in ELISA and immunowestern blotting. RESULTS: The fusion proteins from pDAP2 can be prepared at levels of several milligrams per liter culture from the periplasma of the cells. The proteins work well in different immunoassay formats such as ELISA or western blotting. CONCLUSION: pDAP2 is compatible to phage display vectors such as pHEN1, pCOCK and the pCANTAB-series (Pharmacia, Sweden). Genes of single-chain antibody fragments can be simply swapped from these vectors into pDAP2. Furthermore, we demonstrate that it is possible to produce alkaline phosphatase-active peptides with this vector by inserting synthetic coding oligonucleotides. This allows simple analysis of the binding properties of peptides and may have some advantages over other systems such as fusion to glutathione-S-transferase.