Gonococcal outer-membrane protein PIB: comparative sequence analysis and localization of epitopes which are recognized by type-specific and cross-reacting monoclonal antibodies.

Comparison of the inferred amino acid sequence of outer-membrane protein PIB from gonococcal strain P9 with those from other serovars reveals that sequence variations occur in two discrete regions of the molecule centred on residues 196 (Var1) and 237 (Var2). A series of peptides spanning the amino acid sequence of the protein were synthesized on solid-phase supports and reacted with a panel of monoclonal antibodies (mAbs) which recognize either type-specific or conserved antigenic determinants on PIB. Four type-specific mAbs reacted with overlapping peptides in Var1 between residues 192-198. Analysis of the effect of amino acid substitutions revealed that the mAb specificity is generated by differences in the effect of single amino acid changes on mAb binding, so that antigenic differences between strains are revealed by different patterns of reactivity within a panel of antibodies. The variable epitopes in Var1 recognized by the type-specific mAbs lie in a hydrophilic region of the protein exposed on the gonococcal surface, and are accessible to complement-mediated bactericidal lysis. In contrast, the epitope recognized by mAb SM198 is highly conserved but is not exposed in the native protein and the antibody is non-bactericidal. However, the conserved epitope recognized by mAb SM24 is centred on residues 198-199, close to Var1 , and is exposed for bactericidal killing.     

Characterization and epitope mapping of monoclonal antibodies directed against the beta' subunit of the Escherichia coli RNA polymerase.

Monoclonal antibodies (mAbs) raised against the beta' subunit of the Escherichia coli RNA polymerase were used to probe the structure and function of this subunit. Of the five anti-beta' monoclonal antibodies studied, only mAb 311G2 is a strong inhibitor of RNA polymerase activity. This antibody binds to an epitope which is exposed in both the assembled holoenzyme and isolated beta' subunit. In contrast, the null antibodies bind to the free beta' subunit but very weakly to native RNA polymerase. It would appear that the beta' domain in which their epitopes reside is either conformationally altered or blocked due to interaction with other subunits in native RNA polymerase. In order to locate the positions of the epitopes for these five monoclonal antibodies, a series of overlapping deletion mutants have been constructed by partial restriction and religation of the beta' gene present in pT7 beta' (Zalenskaya, K., Lee, J., Gujuluva, C. N., Shin, Y. K., Slutsky, M., nd Goldfarb, A. (1990) Gene 89, 7-12). The presence of the epitopes for each of the anti-beta' monoclonal antibodies was assessed by Western blotting. The results indicate that the epitopes for mAb 340F11, mAb 370F3, mAb 371D6, and mAb 372B2 are located between amino acids 817-876. This region may be important in enzyme assembly or subunit-subunit interaction. The epitope for the inhibitory antibody, mAb 311G2, is located between amino acids 1047-1093. This region may be involved in the catalytic function of RNA polymerase.     

Monoclonal antibodies against serotype specific and conserved epitopes in morphotype E Escherichia coli flagellins

Monoclonal antibodies (mAbs) were used to examine the interrelationships between morphologically identical flagellar filaments from Escherichia coli H serotype strains belonging to morphotype E. Serotype specific mAbs recognised epitopes exposed on the surface of flagellar filaments from H1, H7, H23, H49 and H51, but were inaccessible to immunolabelling in H45. Several mAbs which recognised conserved epitopes were also examined. mAb 7-56.1 recognised an epitope present in all morphotype E flagellins but not expressed on the filament surface. Similarly, mAb 1-5.1 recognised an internal epitope shared only by serotypes H1 and H12. Serotype H23 expressed a surface epitope which was present but not surface exposed in H7, H1 and H45 filaments.     

Localization of conserved B-cell epitopes among encapsulated and non-encapsulated Haemophilus influenzae P2 porin proteins using synthetic peptides.

The P2 outer membrane protein of Haemophilus influenzae belongs to a class of apparently ubiquitous proteins in Gram-negative bacteria that function as porins. Murine hybridomas raised to the P2 protein and synthetic peptides were used to investigate the structural and antigenic relationships among P2 proteins of encapsulated and non-encapsulated H. influenzae. Three monoclonal antibodies (mAbs), P2-17, P2-18 and P2-19, recognizing epitopes on the P2 protein, as shown by Western immunoblotting of outer membrane preparations, and purified and recombinant P2 proteins are described. The epitopes reactive with the mAbs were widely distributed among H. influenzae strains since 70-100% of strains of encapsulated and non-encapsulated isolates collected worldwide were recognized by individual mAbs. None of the mAbs reacted with H. parainfluenzae or other bacterial species. The peptide composition of P2 epitopes was determined by analysis of mAb reactivity with a series of overlapping synthetic peptides that covered the amino acid sequences of H. influenzae type b. The domains recognized by these mAbs were completely distinct. mAb P2-18, reactive with an epitope conserved among all H. influenzae P2 porin molecules which were screened, recognized a peptide corresponding to the N-terminal segment (residues 1-14). The P2-17- and P2-19-specific epitopes were located between residues 28 and 55, and 101 and 129, respectively. None of the epitopes were exposed on the cell surface since no mAbs bound to intact live bacteria.(ABSTRACT TRUNCATED AT 250 WORDS)     

Epitope mapping of Borrelia burgdorferi OspC protein in homodimeric fold

In current work, we used recombinant OspC protein derived from B. afzelii strain BRZ31 in the native homodimeric fold for mice immunization and following selection process to produce three mouse monoclonal antibodies able to bind to variable parts of up to five different OspC proteins. Applying the combination of mass spectrometry assisted epitope mapping and affinity based theoretical prediction we have localized regions responsible for antigen‐antibody interactions and approximate epitopes' amino acid composition. Two mAbs (3F4 and 2A9) binds to linear epitopes located in previously described immunogenic regions in the exposed part of OspC protein. The third mAb (2D1) recognises highly conserved discontinuous epitope close to the ligand binding domain 1.     

Chimeric fab fragments of antibodies to recombinant Ebola virus glycoprotein

Previously, we have determined the nucleotide and amino acid sequences of the variable domains of three mouse monoclonal antibodies specific to the individual epitopes of the Ebola virus glycoprotein: GPE118 (IgG), GPE325 (IgM) and GPE534 (IgG) [1]. In the present paper, chimeric Fab fragments of Fab118, Fab325, and Fab534 antibodies were obtained based on the variable domains of murine antibodies by attaching CH1 and CL constant regions of human kappa-IgG1 to them. The recombinant chimeric Fab fragments were synthesized in the heterologous expression system Escherichia coli, isolated and purified using metal chelate affinity chromatography. The immunochemical properties of the obtained Fab fragments were studied by immunoblotting techniques as well as indirect and competitive ELISA using recombinant Ebola virus proteins: EBOV rGPdTM (recombinant glycoprotein of Ebola hemorrhagic fever virus without the transmembrane domain), NP (nucleoprotein) and VP40 (structural protein). The identity of recombinant chimeric Fab fragments, as well as their specificity to the recombinant glycoprotein of Ebola hemorrhagic fever virus (EBOV GP) was proved. The results of indirect ELISA evidence the absence of immunological cross-reactivity to NP and VP40 proteins of Ebola virus. The dissociation constants of the antigen-antibody complex K _d equal to 5.0, 1.0 and 1.0 nM for Fab118, Fab325 and Fab534, respectively, were determined; they indicate high affinity of the obtained experimental samples to EBOV GP. The epitope specificity of Fab fragments was studied using a panel of commercial neutralizing antibodies. It was found that all studied antibodies to EBOV GP are targeted to different epitopes, while the epitopes of the recombinant chimeric Fab fragments and original murine monoclonal antibodies (mAbs) coincide. All the obtained and studied mAbs to EBOV GP are specific to epitopes that coincide or overlap the epitopes of three commercial neutralizing mAbs to Ebola virus: epitopes Fab118 and Fab325 overlap the epitope of the known commercial mAb h13F6; Fab325 epitope also overlaps mAb c6D8 epitope; Fab534 epitope is located near mAb KZ52 conformational epitope, in the formation of which amino acid residues of GP1 and GP2 domains of EBOV GP are involved.     

The mapping and reconstitution of a conformational discontinuous B-cell epitope of HIV-1

A method for the discovery of the structure of conformational discontinuous epitopes of monoclonal antibodies (mAbs) is described. The mAb is used to select specific phages from combinatorial phage-display peptide libraries that in turn are used as an epitope-defining database that is applied via a novel computer algorithm to analyze the crystalline structure of the original antigen. The algorithm is based on the following: (1) Most contacts between a mAb and an antigen are through side-chain atoms of the residues. (2) In the three-dimensional structure of a protein, amino acid residues remote in linear sequence can juxtapose to one another through folding. (3) Tandem amino acid residues of the selected phage-displayed peptides can represent pairs of juxtaposed amino acid residues of the antigen. (4) Contact residues of the epitope are accessible to the antigen surface. (5) The most frequent tandem pairs of amino acid residues in the selected phage-displayed peptides can reflect pairs of juxtaposed amino acid residues of the epitope. Application of the algorithm enabled prediction of epitopes. On the basis of these predictions, segments of an antigen were used to reconstitute an antigenic epitope mimetic that was recognized by its original mAb.     

Structure-function relationships of human apolipoprotein D an immunochemical analysis

Apolipoprotein D (apoD), a 169 amino acid member of the lipocalin family, is thought to be a transporter of small, hydrophobic ligands. A panel of 10 anti-apoD monoclonal antibodies (mAbs) was prepared and characterized in order to define apoD structure-function relationships. An apoD epitope map was constructed based on reactivity of the mAbs with apoD fragments. Three mAbs react with epitopes between apoD residues 7-78, seven mAbs with epitopes between residues 128-169, one mAb recognizes an epitope that straddles residues 99-102 and one mAb is specific for an epitope composed of non-contiguous apoD residues. Several pairs of mAbs whose respective epitopes are widely separated in apoD primary structure can compete for binding to immobilized apoD. This would be consistent with the compact beta-barrel tertiary structure that apoD is thought to adopt. None of the mAbs block the interaction of apoD with pregnenolone, a putative physiological ligand for apoD.     

Identification of an epitope of type 1 streptococcal M protein that is shared with a 43-kDa protein of human myocardium and renal glomeruli.

The localization of opsonic and tissue-cross-reactive epitopes within the amino terminus of type 1 streptococcal M protein was investigated by using murine mAb raised against synthetic peptides of type 1 M protein. Two mAb (IIIA2 and IIIB8) reacted with epitopes located within amino acid residues 1-12 of type 1 M protein. These antibodies opsonized type 1 streptococci and did not cross-react with human kidney and heart tissue. Another mAb (IC7) reacted with mesangial cells of renal glomeruli and human myocardium. The cross-reactive epitope of mAb IC7 was localized to position 13-19, indicating that it is not the same epitope as the previously described vimentin-cross-reactive epitope at position 23-26 of type 1 M protein. In Western blots of mesangial cell and myocardial proteins, mAb IC7 cross-reacted with a 43-kDa protein. Neither vimentin nor actin inhibited the binding of mAb IC7 to the cross-reactive protein, as determined by Western blot or immunofluorescence inhibition tests. These results provide evidence that type 1 M protein contains at least one autoimmune epitope shared with both human glomeruli and myocardium.     

Epitope structures recognised by antibodies against the major coat protein (g8p) of filamentous bacteriophage fd (Inoviridae).

To map the accessible surface of filamentous bacteriophage fd particles, the epitope structures of polyclonal rabbit serum and three mouse monoclonal antibodies raised against complete phage were analysed. Western blot analysis confirmed the major coat protein, gene VIII product (g8p or pVIII), to be the antigen. Overlapping peptides were synthesised by spot synthesis on cellulose membranes, covering the whole sequence of g8p. Each of the three tested monoclonal antibodies, B62-FE2, B62-GF3/G12 and B62-EA11, reacted with a core epitope covering ten amino acid residues at or near the amino terminus of g8p. The epitope recognised by B62-FE2 consists of the ten N-terminal amino acid residues of g8p. Extension of the amino terminus by various sequences did not inhibit binding, indicating that a terminal amino group is not essential for the interaction. Both B62-GF3/G12 and B62-EA11 recognise internal epitopes covering amino acid residues 3 to 12 of g8p. The epitopes of the polyclonal rabbit serum were also confined to the 12 N-terminal amino acid residues. The contribution of individual amino acid residues to the binding was analysed by a set of peptides containing individual amino acids exchanged by glycine. Accessible residues were Glu2, Asp4, Asp5, Pro6, Lys8, Phe11 and Asp12. The positions of the essential amino acid residues within the epitope are in accordance with a helical conformation of the amino-terminal region of g8p. Further, the results suggest new designs of phage display screening vectors to improve their performance in analysing non-linear epitopes.     

Anti-idiotypic antibodies elicited by pterin recognize active site epitopes in dihydrofolate reductases and dihydropteridine reductase

Monoclonal antibodies (mAbs) against antipterin immunoglobulin and dihydropteridine reductase (DHPR) and also polyclonal antibodies against human dihydrofolate reductase (DHFR) were obtained. The anti-idiotypic mAbs and anti-DHPR mAbs bind specifically to human DHFR, Escherichia coli DHFR, soybean seedling DHFR, and human DHPR in solid-phase immunoassays. Further, the mAbs bind to the native but not to the denatured forms of DHFRs. The monoclonal antibodies also inhibit the enzymatic activity of human DHFR but not that of human DHPR. Competitive solid-phase immunoassays show stoichiometric inhibition by methotrexate and partial inhibition by NADPH of mAb binding to human DHFR. Cyanogen bromide fragments derived from human DHFR (residues 15-52 and 53-111), containing several active site residues, bind partially to some of the monoclonal antibodies. Accordingly, polyclonal antibodies to peptide 53-111 of human DHFR cross-react to some extent with human DHPR. Data from competitive immunoassays in which the binding of the various mAbs was tested singly and in combination with other mAbs suggest that these antibodies bind to a common region on human DHFR. The results also indicate that the mAbs display some heterogeneity with respect to specific epitopes. These data suggest that despite the absence of significant amino acid sequence homologies among the various DHFRs and DHPR, they have a fundamentally similar topography at the site of binding of the pterin moiety that is recognized by the anti-idiotypic mAbs generated by pterin. In the relatively simple structure of the pterin ring system there are different substituent groups at positions C4 and C6 in methotrexate, 7,8-dihydrofolate, and 7,8-dihydrobiopterin, suggesting that these antibodies are specific for regions on various proteins that interact with the remainder of the pterin moiety. These mAbs and similar mAbs specified by substituent groups on pterin may thus be used as specific probes or inhibitors of various folate-dependent enzymes and transport proteins. They should also provide insights into some of the general features of antibody recognition of protein antigens.     

Human and murine antibodies cross-reactive with streptococcal M protein and myosin recognize the sequence GLN-LYS-SER-LYS-GLN in M protein

Molecular mimicry or epitope similarity between group A streptococcal M proteins and myosin may contribute to the presence of heart reactive antibodies in acute rheumatic fever. In our study overlapping synthetic peptides copying the entire sequence of PepM5 protein were used to map the myosin cross-reactive epitopes of streptococcal M protein recognized by mouse and human mAb and affinity purified myosin-specific antibodies from acute rheumatic fever and rheumatic heart disease sera. Overlapping M protein peptides SM5(164-197)C and SM5(184-197)C inhibited the murine mAb reactions with PepM5 protein. The human mAb and affinity purified myosin-specific antibodies reacted exclusively with SM5(184-197)C. However, one of the five different purified myosin-specific antibodies not only reacted with SM5(184-197)C but also reacted with SM5(84-116)C. The synthetic subpeptides SM5(175-184)C and SM5(188-197C) did not react with any of the antibodies to PepM5 and myosin demonstrating a requirement of the 184-188 amino acid sequence for antibody recognition. A heptapeptide containing the sequence SM5(183-189) was also found to inhibit selected human myosin-specific antibodies and a human antimyosin mAb. Therefore, the majority of mouse and human myosin crossreactive antibodies recognized an epitope within the 14 residue carboxy terminus of PepM5 which appeared to involve the GLN-LYS-SER-LYS-GLN sequence.     

Production and characterization of human anti-V3 monoclonal antibodies from the cells of HIV-1 infected Indian donors

ABSTRACT: BACKGROUND: Analysis of human monoclonal antibodies (mAbs) developed from HIV-1 infected donors have enormously contributed to the identification of neutralization sensitive epitopes on the HIV-1 envelope glycoprotein. The third variable region (V3) is a crucial target on gp120, primarily due to its involvement in co-receptor (CXCR4 or CCR5) binding and presence of epitopes recognized by broadly neutralizing antibodies. METHODS: Thirty-three HIV-1 seropositive drug naive patients (18 males and 15 females) within the age range of 20--57 years (median = 33 years) were recruited in this study for mAb production. The mAbs were selected from EBV transformed cultures with conformationally constrained Cholera-toxin-B containing V3C (V3C-CTB) fusion protein. We tested the mAbs for their binding with HIV-1 derived proteins and peptides by ELISA and for neutralization against HIV-1 viruses by TZM-bl assays. RESULTS: We isolated three anti-V3 mAbs, 277, 903 and 904 from the cells of different individuals. The ELISA binding revealed a subtype-C and subtype-A specific binding of antibody 277 and 903 while mAb 904 exhibited cross reactivity also with subtype-B V3. Epitope mapping of mAbs with overlapping V3 peptides showed exclusive binding to V3 crown. The antibodies displayed high and low neutralizing activity against 2/5 tier 1 and 1/6 tier 2 viruses respectively. Overall, we observed a resistance of the tier 2 viruses to neutralization by the anti-V3 mAbs, despite the exposure of the epitopes recognized by these antibodies on two representative native viruses (Du156.12 and JRFL), suggesting that the affinity of mAb might equally be crucial for neutralization, as the epitope recognition. CONCLUSIONS: Our study suggests that the anti-V3 antibodies derived from subtype-C infected Indian patients display neutralization potential against tier 1 viruses while such activity may be limited against more resistant tier 2 viruses. Defining the fine epitope specificities of these mAbs and further experimental manipulations will be helpful in identification of epitopes, unique to clade C or shared with non-clade C viruses, in context of V3 region.     

Identification of a cytoplasmic region of the Torpedo nicotinic acetylcholine receptor alpha-subunit by epitope mapping.

Analysis of the binding of monoclonal antibodies (mAbs) by Torpedo nicotinic acetylcholine receptor (AChR) has demonstrated that a region of the alpha-subunit between alpha-156 and alpha-179 is exposed on the cytoplasmic surface of the nicotinic post-synaptic membrane. A panel of mAbs was produced that recognized sodium dodecyl sulfate-denatured subunits of the Torpedo AChR. Antibodies recognizing alpha-subunit were distinguished in terms of their ability to bind alpha-subunit fragments generated by Staphylococcus aureus V8 protease: an 18-kDa fragment beginning at Val-46, a 20-kDa fragment beginning at Ser-173/Ser-162, and a 10 kDa fragment beginning at Asn-339. Three mAbs, selected for binding to each of the V8-protease alpha-subunit fragments, respectively, were characterized in detail. The location of epitopes recognized by both anti-V8-18 and anti-V8-20 mAbs was determined to be within alpha-156 to alpha-179 by isolation of small immunoreactive peptides from proteolytic digests of the alpha-subunit, while the mAb reactive to V8-10 was bound to an epitope within alpha-339 to alpha-386. Quantitative evaluation of binding of the anti-V8-18 and anti-V8-20 mAbs to overlapping synthetic peptides corresponding to alpha-147 to alpha-179 localized the epitopes to distinct portions of this region. Further screening of the panel of mAbs using these synthetic peptides revealed three additional mAbs that bind in this region. The mAbs that bound the three distinct V8-protease alpha-subunit fragments were shown to bind to native AChR by indirect immunofluorescence on frozen sections of Torpedo electric organ. Binding to the native AChR was to the cytoplasmic surface of the AChR since the mAbs could bind to AChR in native vesicles, in which the AChR is oriented right-side-out, only after permeabilization of the vesicles by alkaline treatment or after scrambling of the orientation of the AChR by solubilization and reconstitution into liposomes. The location of the mAb-binding sites at the cytoplasmic surface of the AChR was visualized directly by freeze-etch immunoelectron microscopy. The identification of alpha-156 and alpha-179 as containing a cytoplasmic exposed sequence implies the existence of two non-hydrophobic transmembrane sequences between the site of N-glycosylation (Asn-141) and Cys-192, a site alkylated by the cholinergic affinity labels.     

Characterization and application of monoclonal antibodies against N protein of SARS-coronavirus

Severe acute respiratory syndrome-coronavirus (SARS-CoV) causes an infectious disease through respiratory route. Diagnosing the disease effectively and accurately at early stage is essential for preventing the disease transmission and performing antiviral treatment. In this study, we raised monoclonal antibodies (mAbs) against the nucleocapsid (N) protein of SARS-CoV and mapped epitopes by using different truncated N protein fragments. The mapping of those epitopes was valuable for constructing pair-Abs used in serological diagnosis. The results showed that all of the six raised mAbs were divided into two groups recognizing the region of amino acids 249-317 (A group) or 317-395 (B group). This region spanning amino acids 249-395 contains predominant B cell epitopes located at the C-terminus of N protein. One pair-Abs, consisting of N protein-specific rabbit polyclonal antibody and SARS-CoV N protein-specific mAb, was selected to construct a sandwich ELISA-kit. The kit was able to specifically detect SARS-CoV N proteins in serum samples.     

Monoclonal antibodies that inhibit the transport function of the 190-kDa multidrug resistance protein, MRP. Localization of their epitopes to the nucleotide-binding domains of the protein.

Multidrug resistance in tumor cells is often accompanied by overexpression of multidrug resistance protein (MRP), a 190-kDa transmembrane protein that belongs to the ATP-binding cassette superfamily of transport proteins. MRP mediates ATP-dependent transport of a variety of conjugated organic anions and can also transport several unmodified xenobiotics in a glutathione-dependent manner. To facilitate structure-function studies of MRP, we have generated a panel of MRP-specific monoclonal antibodies (mAbs). Four of these mAbs, QCRL-2, -3, -4, and -6, bind intracellular conformation-dependent epitopes, and we have shown that they can inhibit the transport of several MRP substrates. Binding competition and immunoprecipitation assays indicated that mAbs QCRL-4 and -6 probably recognize the same detergent-sensitive epitope in MRP, whereas mAbs QCRL-2, -3, and -4 each bind distinct, non-overlapping epitopes. Fab fragments inhibit transport as effectively as the intact mAbs, suggesting that inhibition results from direct interactions of the mAbs with MRP. Immunodot blot and immunoprecipitation analyses revealed that the minimal regions of MRP sufficient for full reactivity of mAbs QCRL-2 and -3 are amino acids 617-858 and 617-932, respectively, which encompass the NH2-proximal nucleotide-binding domain (NBD). In contrast, the epitope bound by mAb QCRL-4 localized to amino acids 1294-1531, a region that contains the COOH-proximal NBD. However, none of the mAbs inhibited photolabeling of intact MRP with 8-azido-[alpha-32P]ATP. This suggests that rather than preventing nucleotide binding, the mAbs inhibit transport by interfering with substrate binding or by trapping MRP in a conformation that does not allow transport to occur. Our results also demonstrate for the first time that the NBDs of MRP can be expressed as soluble polypeptides that retain a native conformation.     

Evolutionarily conserved sequences of striated muscle myosin heavy chain isoforms. Epitope mapping by cDNA expression

A cDNA expression strategy was used to localize amino acid sequences which were specific for fast, as opposed to slow, isoforms of the chicken skeletal muscle myosin heavy chain (MHC) and which were conserved in vertebrate evolution. Five monoclonal antibodies (mAbs), termed F18, F27, F30, F47, and F59, were prepared that reacted with all of the known chicken fast MHC isoforms but did not react with any of the known chicken slow nor with smooth muscle MHC isoforms. The epitopes recognized by mAbs F18, F30, F47, and F59 were on the globular head fragment of the MHC, whereas the epitope recognized by mAb F27 was on the helical tail or rod fragment. Reactivity of all five mAbs also was confined to fast MHCs in the rat, with the exception of mAb F59, which also reacted with the beta-cardiac MHC, the single slow MHC isoform common to both the rat heart and skeletal muscle. None of the five epitopes was expressed on amphioxus, nematode, or Dictyostelium MHC. The F27 and F59 epitopes were found on shark, electric ray, goldfish, newt, frog, turtle, chicken, quail, rabbit, and rat MHCs. The epitopes recognized by these mAbs were conserved, therefore, to varying degrees through vertebrate evolution and differed in sequence from homologous regions of a number of invertebrate MHCs and myosin-like proteins. The sequence of those epitopes on the head were mapped using a two-part cDNA expression strategy. First, Bal31 exonuclease digestion was used to rapidly generate fragments of a chicken embryonic fast MHC cDNA that were progressively deleted from the 3' end. These cDNA fragments were expressed as beta-galactosidase/MHC fusion proteins using the pUR290 vector; the fusion proteins were tested by immunoblotting for reactivity with the mAbs; and the approximate locations of the epitopes were determined from the sizes of the cDNA fragments that encoded a particular epitope. The epitopes were then precisely mapped by expression of overlapping cDNA fragments of known sequence that covered the approximate location of the epitopes. With this method, the epitope recognized by mAb F59 was mapped to amino acids 211-231 of the chicken embryonic fast MHC and the three distinct epitopes recognized by mAbs F18, F30, and F47 were mapped to amino acids approximately 65-92. Each of these epitope sequences is at or near the ATPase active site.     

Characteristics of Monoclonal Antibodies to Lucerne Transient Streak Sobemovirus and Their Use in Epitope Localization

Murine monoclonal antibodies (mAbs) to lucerne transient streak sobemovirus (LTSV) were used as probes for examining the virion capsid organization. A panel of nine mAbs from approximately 100 hybridomas were chosen for this study. All of these mAbs interacted effectively with sites on intact capsid and isolated coat protein sub-units (i.e. metatopes) in ELISA and Western blots. Only one of these mAbs reacted with virions in gel diffusion test producing a visible precipitin band. Competitive binding assays showed that these mAbs recognized the same or very similar metatopes. None of the mAbs neutralized LTSV virion infectivity but rabbit polyclonal antibodies drastically reduced infectivity. Treatment of virions with EDTA (swollen LTSV). protein crosslinking reagents or sodium dodecyl sulphate caused no detectable alterations in their reactivities with these mAbs, The binding sites for monoclonal and polyclonal antibodies were located on denatured 5.5 kDa fragments resulting from partial trypsinization of LTSV coat protein and 8 kDa fragments formed with chymopapain proteolysis. These results indicate that these LTSV epitopes are of linear (or sequential) configuration and are located on the exposed, structurally stable domain of the virion capsid.     

Mapping of linear epitopes recognized by monoclonal antibodies with gene-fragment phage display libraries

Epitope mapping with mono- or polyclonal antibodies has so far been done either by dissecting the antigens into overlapping polypeptides in the form of recombinantly expressed fusion proteins, or by synthesizing overlapping short peptides, or by a combination of both methods. Here, we report an alternative method which involves the generation of random gene fragments of approximately 50–200 by in length and cloning these into the 5 terminus of the protein III gene of fd phages. Selection for phages that bind a given monoclonal antibody and sequencing the DNA inserts of immunopositive phages yields derived amino acid sequences containing the desired epitope. A monoclonal antibody (mAb 215) directed against the largest subunit of Drosophila RNA polymerase II (RPB215) was used to map the corresponding epitope in a fUSE5 phage display library made of random DNA fragments from plasmid DNA containing the entire gene. After a single round of panning with this phage library, bacterial colonies were obtained which produced fd phages displaying the mAb 215 epitope. Sequencing of single-stranded phage DNA from a number of positive colonies (recognized by the antibody on colony immunoblots) resulted in overlapping sequences all containing the 15mer epitope determined by mapping with synthetic peptides. Similarly, we have localized the epitopes recognized by a mouse monoclonal antibody directed against the human p53 protein, and by a mouse monoclonal antibody directed against the human cytokeratin 19 protein. Identification of positive colonies after the panning procedure depends on the detection system used (colony immunoblot or ELISA) and there appear to be some restrictions to the use of linker-encoded amino acids for optimal presentation of epitopes. A comparison with epitope mapping by synthetic peptides shows that the phage display method allows one to map linear epitopes down to a size only slightly larger than the true epitope. In general, our phage display method is faster, easier, and cheaper than the construction of overlapping fusion proteins or the use of synthetic peptides, especially in cases where the antigen is a large polypeptide such as the 215 kDa subunit of eukaryotic RNA polymerase II.