Bispecific and bifunctional single chain recombinant antibodies

Bispecific and bifunctional monoclonal antibodies as second generation monoclonals, produced by conventional chemical or somatic methods, have proved useful in the immunodiagnosis and immunotherapy of cancer and other diseases. Recombinant antibodies produced by genetic engineering techniques have also become available for use in preclinical and clinical studies. Furthermore, through genetic engineering, it is possible to remove or add on key protein domains in order to create designer antibody molecules with two or more desired functions. This review summarizes the strategies for development of single chain variable fragment (scFv) bifunctional and bispecific antibodies. The advantages and disadvantages as well as the problems of generating the various bispecific and bifunctional antibody constructs are reported and discussed. Since conventionally prepared bispecific and bifunctional monoclonal antibodies have already shown promise in clinical trials and results from preclinical studies of recombinant bispecific antibodies are encouraging, clinical trials in humans of recombinant bispecific and bifunctional antibodies, as a new generation of biologicals, are likely to be the thrust in the next decade and beyond.     

Bivalent monoclonal IgY antibody formats by conversion of recombinant antibody fragments

Monoclonal IgY have the potential to become unique tools for diagnostic research and therapeutic purposes since avian antibodies provide several advantages due to their phylogenetic difference when compared to mammalian antibodies. The mechanism of avian immunoglobulin gene diversification renders chicken an excellent source for the generation of recombinant scFv as well as Fab antibody libraries of high diversity. One major limitation of these antibody fragments, however, is their monovalent format, impairing the functional affinity of the molecules and, thereby, their applicability in prevalent laboratory methods. In this study, we generated vectors for conversion of avian recombinant antibody fragments into different types of bivalent IgY antibody formats. To combine the properties of established mammalian monoclonal antibodies with those of IgY constant domains, we additionally generated bivalent murine/avian chimeric antibody constructs. When expressed in HEK-293 cells, all constructs yielded bivalent disulfide-linked antibodies, which exhibit a glycosylation pattern similar to that of native IgY as assessed by lectin blot analysis. After purification by one step procedures, the chimeric and the entire avian bivalent antibody formats were analyzed for antigen binding and interaction with secondary reagents. The data demonstrate that all antibody formats provide comparable antigen binding characteristics and the well established properties of avian constant domains.     

Recombinant polyclonal antibodies for cancer therapy

Although monoclonal antibodies are increasingly used for cancer therapy, remissions are only temporary due to emergence of tumor cell escape variants that are no longer affected by the antibody. The emergence of escape variants could be minimized by multi-targeting of tumor cells with polyclonal antibodies, which would also be more efficient than monoclonal antibodies at mediating effector functions for target destruction. A technology for generating recombinant polyclonal antibodies for cancer therapy has been developed based on the construction and selection of tumor-reactive Fab phage display libraries. The selected Fabs are mass-converted to full-length polyclonal antibody libraries (PCALs) of any isotype and any species. Prototypic PCALs generated against human colorectal cancer cell lines showed that libraries of diverse recombinant antibodies, enriched for reactivity to the cancer cells compared to normal human cells, can be obtained. The success of recombinant polyclonal antibodies as cancer therapeutics will depend on the ability to generate, characterize, and mass-produce PCALs with high ratios of cancer-to-normal reactivities that cross-react with many cancers of the same type.     

Comparative immunohistochemistry and histochemistry of dipeptidyl peptidase IV in rat organs during development

Summary The occurrence of dipeptidyl peptidase (DPP) IV during development in Wistar rat organs was studied on day 10, 16 and 21 of gestation and on day 1, 4, 8, 13, 21, 26 and 60 after birth comparing immunohistochemistry and activity histochemistry. A polyclonal antibody, as well as monoclonal antibodies recognizing four different epitopes (A-D) of the DPP IV molecule, were employed for the immunohistochemical studies. In all investigated tissues, immunoreactivity with the polyclonal antibody appeared earlier than DPP IV activity and was already present on day 10 of gestation in the plasma membranes of embryonic and extraembryonic (decidual) cells. At these and other sites, e.g. brain capillary endothelium and tracheal or bronchial epithelium, immunoreactivity with the polyclonal antibody decreased or disappeared after birth and enzyme activity never developed. Immunoreactivity with the monoclonal antibodies appeared later than that with the polyclonal antibody, and mostly in those structures where DPP IV activity was subsequently found. The monoclonal antibody against epitope D showed a high reactivity in the epididymal duct, renal collecting ducts and in all domains of the hepatocyte plasma membrane, where neither DPP IV activity nor immunoreactivity with the other antibodies were observed. Our results also suggest that DPP IV might be present as a molecule before it becomes catalytically active and that immunoreactivity occurs at more sites than DPP IV activity. However, it cannot be excluded that the polyclonal antibody and the monoclonal antibody against the epitope D cross-react with as yet uncharacterized proteins, which express common epitopes during embryonic development, but are not present in the tissues of adult Wistar rats.     

Reduction of High Background Staining by Heating Unfixed Mouse Skeletal Muscle Tissue Sections Allows for Detection of Thermostable Antigens With Murine Monoclonal Antibodies

Antigen detection with indirect immunohistochemical methods is hampered by high background staining if the primary antibody is from the same species as the examined tissue. This high background can be eliminated in unfixed cryostat sections of mouse skeletal muscle by boiling sections in PBS, and several proteins including even the low abundant dystrophin protein can then be easily detected with murine monoclonal antibodies. However, not all antigens withstand the boiling procedure. Immunoreactivity of some of these antigens can be restored by subsequent washing in Triton X-100, whereas immunoreactivity of other proteins is not restored by this detergent treatment. When such thermolabile proteins are labeled with polyclonal primary antibodies followed by dichlorotriazinylaminofluorescein–conjugated secondary antibodies and boiled, the fluorescence signal persists, and sections can then be processed with a monoclonal antibody for double immunostaining of a protein unaffected by boiling. This stability of certain fluorochromes on heating can also be exploited for double immunofluorescence labeling of two different thermostable proteins with murine monoclonal antibodies as well as for combination with Y-chromosome fluorescence in situ hybridization. Our method should extend the range of monoclonal antibodies applicable to tissues derived from the same species as the monoclonal antibodies. (J Histochem Cytochem 56:969–975, 2008)     

Construction of dystrophin fusion proteins to raise targeted antibodies to different epitopes.

For the study of the structure and function relationship of dystrophin, defective in DMD, and for diagnostic purposes it is important to dispose of antibodies against different parts of the protein. We have made five different constructs for the expression of fusion proteins containing parts of the four domains of dystrophin. Two different recombinant expression vectors, pATH2 and pEX1, were used. Rabbits were immunized with the fusion products and several polyclonal antibodies were raised. At a later stage, monoclonal antibodies were also raised to some of the fusion proteins. One polyclonal antibody, named P20 AB, is directed against the region covering amino acid sequence 1749-2248 or the nucleotide sequence 5456-6953 of the mRNA, which corresponds to the major deletion-prone region of the DMD gene. We show the particular value, sensitivity and specificity of the P20 AB in dystrophin analysis.     

Manufacture of recombinant polyclonal antibodies

Polyclonal antibody therapy in the form of hyper-immune serum has for more than a century been used for treatment of many infectious diseases. However, with the emergence of first antibiotics and later recombinant monoclonal antibody therapy, the use of hyper-immune serum has declined. The main reason for this is that methods for consistent manufacturing of safe hyper immune immunoglobulin products have been lacking. In contrast, manufacturing processes of recombinant monoclonal antibodies follow a well established schedule and it appears obvious to use similar methods to produce recombinant polyclonal products. However, the methods for monoclonal antibody manufacturing are, for several reasons, not directly applicable to generation and manufacture of polyclonal recombinant antibodies. A new production strategy based on recombinant mammalian producer cells has recently been developed to support consistent generation of recombinant polyclonal antibodies for therapeutic use. This review describes aspects of this novel technology with emphasis on the generation, production and characterization procedures employed, and provides comparison with alternative polyclonal and monoclonal antibody manufacturing strategies.     

Human specific anti-type IV collagen monoclonal antibodies, characterization and immunohistochemical application

This paper describes two new monoclonal antibodies reactive with human specific type IV collagen epitopes in frozen as well as routinely fixed and processed tissue sections. The antibodies (1042 and 1043) were raised against human placental type IV collagen and were shown by immunoblotting and ELISA tests to react exclusively with type IV collagen determinants. Extensive immunohistochemical survey studies on panels of tissues from various species, using unfixed cryostat sections, demonstrated that antibody 1042 reacted only with human type IV collagen whereas antibody 1043 in addition reacted with rabbit type IV collagen. All tissues showed homogeneous staining of the basement membrane, indicating that the detected epitopes did not show organ-specific distribution. Tissue processing protocols for using these monoclonal antibodies on routinely processed paraffin embedded tissues were developed. It was found that whereas polyclonal anti-type IV collage antisera required pepsin digestion, our monoclonal antibodies required pronase or papain digestion to restore type IV collagen immunoreactivity in paraffin sections. It is concluded that these monoclonal anti-type IV collagen antibodies detect species specific epitopes which can be detected in routinely processed paraffin embedded tissues after appropriate enzyme pretreatment.     

Domain unfolding of monoclonal antibody fragments revealed by non-reducing SDS-PAGE

Monoclonal antibodies and derived fragments are used extensively both experimentally and therapeutically. Thorough characterization of such antibodies is necessary and includes assessment of their thermal and storage stabilities. Thus, assessment of the underlying conformational stabilities of the antibodies is also important. We recently documented that non-reducing SDS-PAGE can be used to assess both monoclonal and polyclonal IgG domain thermal unfolding in SDS. Utilizing this same h2E2 anti-cocaine mAb, in this study we generated and analyzed various mAb antibody fragments to delineate the structural domains of the antibody responsible for the observed discrete bands following various heating protocols and analysis by non-reducing SDS-PAGE. Previously, these domain unfolding transitions and gel bands were hypothesized to stem from known mAb structural domains based on the relative thermal stability of those CH2, CH3, and Fab domains in the absence of SDS, as measured by differential scanning calorimetry. In this study, we generated and analyzed F(ab’)₂, Fab, and Fc fragments, as well as a mAb consisting of only heavy chains, and examined the thermally induced domain unfolding in each of these fragments by non-reducing SDS-PAGE. The results were interpreted and integrated to generate an improved model of thermal unfolding for the mAb IgG in SDS. These results and the model presented should be generally applicable to many monoclonal and polyclonal antibodies and allow novel comparisons of conformational stabilities between chemically or genetically modified versions of a given antibody. Such modified antibodies and antibody drug conjugates are commonly utilized and important for experimental and therapeutic applications.     

Camel single-domain antibodies as modular building units in bispecific and bivalent antibody constructs

Single-domain antibodies against various antigens are isolated from the unique heavy-chain antibodies of immunized camels and llamas. These minimal sized binders are very robust and bind the antigen with high affinity in a monomeric state. We evaluated the feasibility to produce soluble, functional bispecific and bivalent antibodies in Escherichia coli with camel single-domain antibody fragments as building blocks. Two single-domain antibody fragments were tethered by the structural upper hinge of a natural antibody to generate bispecific molecules. This linker was chosen for its protease resistance in serum and its natural flexibility to reorient the upstream and downstream located domains. The expression levels, ease of purification, and the solubility of the recombinant proteins were comparable with those of the constituent monomers. The individual moieties fully retain the binding capacity and the binding characteristics within the recombinant bispecific constructs. The easy generation steps and the biophysical properties of these bispecific and bivalent constructs based on camel single-domain antibody fragments makes them particularly attractive for use in therapeutic or diagnostic programs.     

Optimization,validation, and identification of two reliable antibodies for immunodetection of WNT5A

WNT5A is a secreted, noncanonical WNT signaling protein that has been reported to promote progression of several types of cancer, including oral squamous cell carcinoma. Many WNT5A antibodies are available commercially for immunohistochemistry (IHC) and western blot analysis. Validation of the primary antibodies, however, is often neglected. We characterized antibodies for detecting WNT5A by IHC and western blot analysis. We evaluated one polyclonal and three monoclonal commercially available WNT5A antibodies. After optimization of the IHC assay, all four antibodies showed cytoplasmic WNT5A expression in tissue samples; in contrast, only one antibody detected WNT5A in western blots. A pre-absorption test with recombinant WNT5A showed that AF645 and 3A4 antibodies specifically detected WNT5A in different assays. We suggest that the monoclonal 3A4 antibody is the most appropriate for use with IHC, while the polyclonal AF645 antibody is the best for western blot analysis.     

Avian IgY antibodies and their recombinant equivalents in research, diagnostics and therapy

The generation and use of avian antibodies is of increasing interest in a wide variety of applications within the life sciences. Due to their phylogenetic distance, mechanisms of immune diversification and the way in which they deposit IgY immunoglobulin in the egg yolk, chickens provide a number of advantages compared to mammals as hosts for immunization. These advantages include: the one-step purification of antibodies from egg yolk in large amounts facilitates having a virtually continuous supply; the epitope spectrum of avian antibodies potentially grants access to novel specificities; the broad absence of cross-reactivity with mammalian epitopes avoids assay interference and improves the performance of immunological techniques. The polyclonal nature of IgY antibodies has limited their use since avian hybridoma techniques are not well established. Recombinant IgY, however, can be generated from mammalian monoclonal antibodies which makes it possible to further exploit the advantageous properties of the IgY scaffold. Moreover, cloning and selecting the immune repertoire from avian organisms is highly efficient, yielding antigen-specific antibody fragments. The recombinant approach is well suited to circumvent any limitations of polyclonal antibodies. This review presents comprehensive information on the generation, purification, modification and applications of polyclonal and monoclonal IgY antibodies.     

Human specific anti-type IV collagen monoclonal antibodies,characterization and immunohistochemical application

Summary This paper describes two new monoclonal antibodies reactive with human specific type IV collagen epitopes in frozen as well as routinely fixed and processed tissue sections. The antibodies (1042 and 1043) were raised against human placental type IV collagen and were shown by immunoblotting and ELISA tests to react exclusively with type IV collagen determinants. Extensive immunohistochemical survey studies on panels of tissues from various species, using unfixed cryosat sections, demonstrated that antibody 1042 reacted only with human type IV collagen whereas antibody 1043 in addition reacted with rabbit type IV collagen. All tissues showed homogeneous staining of the basement membrane, indicating that the detected epitopes did not show organ-specific distribution.Tissue processing protocols for using these monoclonal antibodies on routinely processed paraffin embedded tissues were developed. It was found that whereas polyclonal antitype IV collagen antisera required pepsin digestion, our monoclonal antibodies required pronase or papain digestion to restore type IV collagen immunoreactivity in paraffin sections.It is concluded that these monoclonal anti-type IV collagen antibodies detect species specific epitopes which can be detected in routinely processed paraffin embedded tissues after appropriate enzyme pretreatment.     

Emerging trends in the synthesis and improvement of hapten-specific recombinant antibodies

A key requirement for successful immunotherapeutic and immunodiagnostic applications is the availability of antibodies with high affinity and specificity. In the past, polyclonal antibodies from hyperimmunized animals or monoclonal antibodies from hybridoma cell lines were used extensively and profitably in medicine and immunotechnology. Antibody-based diagnostics, such as immunoassays, are also widely accepted because of their high sensitivity and ease of use as compared to conventional chromatographic techniques. While immunoassays have been used to monitor organic chemical contaminants such as pesticides, food preservatives, antibiotics in agricultural and food industries, hapten-specific antibodies with the desired affinity and specificity are generally difficult to obtain. With the advent of recombinant DNA technology, antibody genes can be amplified and selected through phage display, cell surface display, or cell-free display systems. A particularly useful feature common to all these display systems is the linking of the phenotype and genotype of antibodies during selection. This allows easy co-selection of the desired antibodies and their encoding genes based on the binding characteristics of the displayed antibodies. The selected antibody DNA can be further manipulated for high-level expression, post-translation modification, and/or affinity and specificity improvement to suit their particular applications. Several hapten-specific antibodies, which were successfully selected and engineered to high specificity and affinity using display technologies, have been found to be amenable to conventional immunoassay development. In this review, we will examine different formats of immunoassays designed for hapten identification and various display technologies available for antibody selection and improvement.     

Immunohistochemical localization of glucagon-like peptide 1. Use of poly- and monoclonal antibodies

We report the use of poly- and monoclonal antibodies to study the immunohistochemical distribution of glucagon-like peptide-1 immunoreactivity (GLP-1-IR) in various tissues. The polyclonal antibodies against GLP-1 reacted with pancreatic A cells, enteroglucagon (L) cells in the gut, and some neurons in the central nervous system of all species tested. In pancreas and gut the monoclonal antibodies against GLP-1 exhibited a similar, but species specific distribution, relative to the polyclonal antibodies. The colocalization of GLP-1 and glucagon immunoreactivity in pancreatic, intestinal, and nervous tissues is in agreement with previously reported findings that both peptides are part of a single precursor molecule (preproglucagon).     

Regulated secretion and purification of recombinant antibodies in E. coli.

A plasmid for optimized protein expression of recombinant Fv antibodies (pOPE) in E. coli was used to express the variable domains of the murine monoclonal antibody HD39 specific for the human B-cell surface antigen CD22. The production of Fv antibodies by pOPE can be regulated over a wide range by varying the IPTG concentration. Antibodies that can discriminate between secreted and nonsecreted Fv antibody fragments were used to show that secretion is the limiting step for the production of functional Fv antibodies. IPTG concentrations above 20 microM increased the total antibody production, but did not yield larger amounts of secreted Fv antibodies. The addition of five histidines to the C terminus facilitates an easy single-step enrichment procedure based on immobilized metal affinity chromatography.     

Two monoclonal antibodies distinguish between human recombinant interferon-alpha 5s produced by Escherichia coli and by mouse cells

Two monoclonal antibodies against human IFN-alpha--one against natural leukocyte IFN-alpha and the other against recombinant human IFN-alpha 2 produced in E. coli--were prepared, and designated as HT-1, and 104-5-f, respectively. These monoclonal antibodies were used to examine the antigenicities of recombinant human IFN-alpha 5s produced by E. coli and by mouse cells. The HT-1 antibody could bind and neutralize recombinant human IFN-alpha 5 synthesized in mouse cells, but not recombinant human IFN-alpha 5 synthesized in E. coli. On the other hand, the 104-5-f antibody could bind and neutralize recombinant human IFN-alpha 5 synthesized in E. coli but not recombinant human IFN-alpha 5 synthesized in mouse cells. Then these monoclonal antibodies or sheep polyclonal antibody against human IFN-alpha were used to immunoprecipitate the radioactively labeled recombinant human IFN-alpha 5 synthesized either in E. coli or mouse cells, and analysed on polyacrylamide gel electrophoresis in the presence of NaDodSO4. The labeled recombinant human IFN-alpha 5 produced by mouse cells could be immunoprecipitated with the HT-1 monoclonal antibody or sheep anti-(human IFN-alpha) polyclonal antibody but not with the 104-5-f monoclonal antibody and showed a band of Mr. 17,500 on polyacrylamide gel electrophoresis in the presence of NaDodSO4. On the other hand, the labeled recombinant human IFN-alpha 5 produced by E. coli could be immunoprecipitated with the 104-5-f monoclonal antibody but not with the HT-1 monoclonal antibody and showed a band of similar Mr. on polyacrylamide gel electrophoresis.(ABSTRACT TRUNCATED AT 250 WORDS)     

A proteomics approach for the identification and cloning of monoclonal antibodies from serum

We describe a proteomics approach that identifies antigen-specific antibody sequences directly from circulating polyclonal antibodies in the serum of an immunized animal. The approach involves affinity purification of antibodies with high specific activity and then analyzing digested antibody fractions by nano-flow liquid chromatography coupled to tandem mass spectrometry. High-confidence peptide spectral matches of antibody variable regions are obtained by searching a reference database created by next-generation DNA sequencing of the B-cell immunoglobulin repertoire of the immunized animal. Finally, heavy and light chain sequences are paired and expressed as recombinant monoclonal antibodies. Using this technology, we isolated monoclonal antibodies for five antigens from the sera of immunized rabbits and mice. The antigen-specific activities of the monoclonal antibodies recapitulate or surpass those of the original affinity-purified polyclonal antibodies. This technology may aid the discovery and development of vaccines and antibody therapeutics, and help us gain a deeper understanding of the humoral response.     

Immunohistochemical localization of glucagon-like peptide 1

Summary We report the use of poly-and monoclonal antibodies to study the immunohistochemical distribution of glucagon-like peptide-1 immunoreactivity (GLP-1-IR) in various tissues. The polyclonal antibodies against GLP-1 reacted with pancreatic A cells, enteroglucagon (L) cells in the gut, and some neurons in the central nervous system of all species tested. In pancreas and gut the monoclonal antibodies against GLP-1 exhibited a similar, but species specific distribution, relative to the polyclonal antibodies. The colocalization of GLP-1 and glucagon immunoreactivity in pancreatic, intestinal, and nervous tissues is in agreement with previously reported findings that both peptides are part of a single precursor molecule (preproglucagon).Supported by the DFG, SFB 90     

Production of Polyclonal Antibodies to the Recombinant Coat Protein of Citrus tristeza virus and their Effectiveness for Virus Detection

Citrus tristeza virus (CTV) is distributed worldwide and causes the most economically important virus diseases of citrus. Enzyme‐linked immunosorbent assay (ELISA) and/or immunoprinting have become an indispensable tools for large‐scale diagnosis of CTV worldwide. Several CTV detection kits are commercially available, based on either polyclonal or monoclonal antibodies developed against purified virus preparations. We have developed polyclonal antibodies to recombinant p25 CTV coat proteins (rCP) and determined their effectiveness for both trapping and as the intermediate antibody in double‐antibody sandwich indirect (DASI) ELISA. The p25 coat protein gene of three CTV isolates was amplified by RT‐PCR and further cloned and expressed in Escherichia coli cells. The rCP was injected into rabbits and goats for antibody production. Western blotting assays with the rCP CTV‐specific antibodies reacted positively with the homologous and heterologous rCP of the three CTV isolates and with the corresponding native coat protein present in crude sap extracts of CTV‐infected citrus tissue, but not with extracts from healthy tissue. The rCP antibodies from goat and rabbit reacted as both plate trapping and intermediate antibodies in DASI‐ELISA, discriminating healthy and CTV‐infected citrus, with optical density (OD₄₀₅) values in the range of 0.151–2.415 for CTV‐infected samples and less than 0.100 for healthy tissue. Commercially available anti‐CTV antibodies were used as a reference. Previous reports indicate that antibodies developed to recombinant antigens, including those of CTV, may not be functional for trapping the target antigens under non‐denaturing conditions. Our results showed the feasibility of CTV antibodies developed to the rCP for use as both trapping and intermediate antibodies in DASI‐ELISA, when the recombinant antigen was fractioned with polyacrylamide electrophoresis gel and further extensively dialysed against phosphate buffer saline prior to its use as immunogen.