Differentiation of adenovirus hexon epitopes with monoclonal antibodies by gel diffusion assays

Nine monoclonal antibodies (MAbs) directed against crystallized human adenovirus type 1 (Ad h 1) hexon were tested with purified homologous and heterologous hexon preparations by gel diffusion. Six MAbs formed a single line with the homologous hexon in a 2-well pattern, and 3 MAbs formed lines only in biclonal combinations with an appropriate MAb. All of the 6 precipitating MAbs formed a continuous line of complete identity when tested simultaneously against homologous and different heterologous hexons. With Ad h 1 hexon a line of double partial identity (double spur) was formed when some pair combinations of 2 MAbs were placed in 2 juxtaposed wells. Other MAbs in the adjacent wells formed a line of identity. The MAbs could be divided into 2 antibody groups (groups A and B) based on this phenomenon. Members of antibody groups A and B apparently identified 2 sterically distinct epitopes: one of them is presumably the genus-specific epitope of the hexons (group A) and the other(s) should be intertype-specific epitope(s). Thus, the gel diffusion method can be used for selecting pairs of MAbs for their specificity to sterically independent epitopes. Mixtures of 2 MAbs belonging to the different antibody groups formed double lines with Ad h 1 hexons. Members of group A showed some helper effect to the members of group B for their precipitin line formation.     

Isolation and characteristics of anti-adenovirus monoclonal antibodies in immunoenzyme and immunofluorescent reactions

New monoclonal antibodies (MAbs) to adenovirus hexon, highly active in ELISA and immunofluorescent analysis, were prepared. According to competitive ELISA, new MAbs differed in their blocking activity and were directed to 2 different hexon epitopes. MAb 3H8 did not modify antigen binding of the rest MAbs labeled with peroxidase (PAb x Pox), and none of unlabeled MAbs suppressed the reaction of MAb x Pox 3H8. MAbs 1E8 7F1, 1E11, and 3B1 reacted with each other but differed by the spectrum and level of competitive inhibition, which indicated that they were directed to different epitopes of adenovirus hexon. Comparison of the specific activity of MAbs 7F1 and 1E8 in direct immunofluorescent detection of adenovirus antigens in infected cell cultures and clinical materials from patients showed a good coincidence (90-97%) of the results with the IMAGEN Adenovirus test (Dako) and with polyclonal FITC conjugates to adenovirus hexon.     

Antigenic relationship between human and animal adenovirus hexons determined by means of monoclonal antibodies directed against bovine adenovirus type 2 hexon

Summary Eight monoclonal antibodies (MAbs) directed against bovine adenovirus (BAV) 2 subtype B hexon were studied with 12 different hexon types of human adenoviruses (AV) belonging to 5 different subgenera using indirect ELISA, passive hemagglutination (HA), and gel diffusion assays. Two hexon types of animal origin (BAV3 and SAV16) were investigated, too. The reactivity of the MAb IV.F3 was the broadest, i.e. in ELISA and HA experiments it reacted with all hexon types studied. Based on these results as well as on the results of gel diffusion assays, this MAb should recognize the genus specific epitope of adenovirus hexons. Three MAbs (CA12, III.B11, and A12) could recognize different epitopes showing intersubgenus or intertype specificities. In spite of the fact, that all the eight MAbs proved to be bound by the hexon of ORT/111 (BAV2 subtype B) blotted onto nitrocellulose filter, four of the eight MAbs (BB7, BH5, II.A9, and IV.F5) failed to react with any human, and animal hexon types used in the present experiments. The results suggest that a gradient of antigenic relationship may exist between BAV2 hexon and the hexons of human serotypes.     

Characterization of adenovirus hexons by their epitope composition

Summary For the investigation of epitope composition of different adenovirus hexon types sixty-one mouse ascitic fluids containing monoclonal antibodies (MAbs) developed in three different panels were used. The distinction and marking of the different epitopes recognized by the MAbs were carried out by the determination of the composite cross-reactivity pattern, the titer and the correlation coefficient of all the 61 MAbs with 21 different hexon types representing all the six human subgenera, as well as different bovine and simian adenoviruses. The distinct epitopes were marked by two numbers refering the homologous hexon type to which the MAbs were directed and the serial number of the epitope specified by the different members of the given panel of the MAbs. The three panels of MAbs recognized 22 epitopes on the 21 hexon types among them a genus and three type specific ones and 18 different bi- and multilateral intertype (IT) specific epitopes that grouped adenoviruses within the genus, independently from the subgenus they belong to. Considering that the type specific epitope could be present only on the homologous hexon type, the largest number of the different epitopes distinguishable by the MAbs used could be 20 on the homologous hexon and 19 on the heterologous ones. It was found that the total number of IT specific epitopes on the hexons varied between 2 and 18. The distribution of the distinct specific epitopes on the different hexon types was different, as expected. The antigenic structure of the individual hexon types were characterized by the determination of their IT specific epitope spectrum. By pairwise analysis ten human hexon types formed three epitope clusters (types 4 and 19; types 8, 9, 9/13 and 10; as well as all types of subgenus C) showing identical epitope spectra. No clustering was found with human type 7, 12, 13, 18, 26, 27, 35 and 41, as well as with bovine and simian adenovirus hexons studied. However, they displayed a closer or looser antigenic relationship among each other and to members of the epitope clusters. The degree of antigenic relationship could be expressed by the similarity/dissimilarity percentage calculated from the number of the identical and different epitopes present on any two given hexon types.     

Epitope mapping and characterization of a neutralizing monoclonal antibody against human adenovirus type 3

Human adenovirus serotype 3 (HAdV-3) has occurred as a global epidemic in recent years causing serious diseases such as pneumonia in pediatric and adult patients. Development of reliable diagnostic reagents and identification of neutralizing epitopes is important for the surveillance and control of infection. In this study, a neutralizing monoclonal antibody (MAb) MAb 1B6 was generated using the HAdV-3 virion. MAb 1B6 specially recognized the HAdV-3 virus particles and the HAdV-3 hexon protein, but not the virus particles or the hexon protein of HAdV-7 and HAdV-4 by western-blot analysis and indirect enzyme-linked immunosorbent assay (ELISA). Analysis using a series of peptides from the hexon protein and chimeric adenovirus (Ad) particles of epitope mutants revealed that MAb 1B6 bound to the exposed region (amino acid positions 414–424 of hexon) in hypervariable region 7 (HVR7). ELISA demonstrated that MAb 1B6 could recognize the corresponding regions of other HAdV-3 genotypes that have some residues substituted. The identification of the neutralizing epitope and the generation of MAb 1B6 may be useful for clinical serotype-specific diagnosis, subunit vaccine construction for HAdV-3 infection, and virion structural analysis.     

Monoclonal antibodies that recognize the P fimbriae F71, F72, F9, and F11 from uropathogenic Escherichia coli.

The Escherichia coli P fimbriae F71, F72, F9, and F11 from four cloned strains were purified, and polyclonal antisera were raised in rabbits. Cross-reactions of these antisera with eight different cloned and purified fimbriae were measured in an enzyme-linked immunosorbent assay. These antisera showed a reaction with the homologous fimbriae and also with most heterologous fimbriae. Monoclonal antibodies (MAbs) directed against the same four native fimbriae were produced by the fusion of spleen cells from immunized BALB/c mice with SP2/0 myeloma cells. The resulting four series of MAbs were also screened in an enzyme-linked immunosorbent assay with eight different cloned and purified fimbriae. Four different F71 hybridomas produced MAbs which recognized only epitopes on F71 fimbriae. Two F72 MAbs recognized epitopes on F72 and F9 fimbriae, whereas another F72 MAb recognized an epitope on only F72 fimbriae. Three MAbs raised against F9 reacted only with epitopes on F9 fimbriae. Six MAbs against F11 fimbriae could be divided into two groups: on the one hand two MAbs recognizing F11, pyelonephritis-associated pilus, Pap, and F72 fimbriae and on the other hand four MAbs recognizing F11 and "Clegg" fimbriae. None of the MAbs reacted with 1A or 1C fimbriae. In a hemagglutination inhibition assay it was shown that none of the MAbs produced inhibited the adhesive properties of homologous cloned strains.     

Monoclonal antibodies to surface antigens of Mycobacterium tuberculosis and their use in a modified enzyme-linked immunosorbent spot assay for detection of mycobacteria.

Three monoclonal antibodies (MAbs) were generated from splenocytes of a BALB/c mouse immunized with heat-killed Mycobacterium tuberculosis. All three MAbs bound to surface epitopes of M. tuberculosis as shown by whole-cell enzyme-linked immunosorbent assay (ELISA), indirect immunofluorescence, and immunoelectron microscopy. One immunoglobulin M (IgM) MAb bound to lipoarabinomannan, the second IgM MAb bound to mycolyl-arabinogalactan-peptidoglycan complex, and the third MAb, an IgG3, bound to a surface epitope of an uncertain nature. The MAbs demonstrated different cross-reactivity patterns with other mycobacteria. Two of the MAbs were used to develop a modified ELISA spot assay for the detection of mycobacteria.     

Development of a biotin-streptavidin-enhanced enzyme-linked immunosorbent assay which uses monoclonal antibodies for detection of group C rotaviruses.

A biotin-streptavidin-enhanced enzyme-linked immunosorbent assay (ELISA) which uses monoclonal antibodies (MAbs) for the detection of group C rotaviruses was developed. An assay in which plates were coated with three pooled MAbs and biotinylated polyclonal immunoglobulin G (IgG) (polyclonal antibody [PAb]) was used as the detector (MAb capture-PAb detector) was found to be the most sensitive and specific of the assays when it was compared with assays in which plates were coated with polyclonal antiserum and detection was done with either biotinylated polyclonal antiserum (PAb capture-PAb detector) or biotinylated pooled MAbs (PAb capture-MAb detector). The MAb capture-PAb detector ELISA detected 83% of samples confirmed to be positive for group C rotaviruses, whereas the PAb capture-PAb detector assay detected 63% of positive samples and the PAb capture-MAb detector assay detected 65% of positive samples. All three procedures detected both of the bovine and the two human group C rotaviruses, but none of the three procedures detected fecal samples containing group A and B rotaviruses or fecal samples negative for group C rotaviruses used in this study. The sensitivity of the MAb capture-PAb detector ELISA was determined by serially diluting fecal group C rotaviruses; antigens were detected in maximal positive dilution ranges of 1:1,000 to 1:3,000 for the samples tested. On the basis of the cell culture immunofluorescence assay infectivity titer of semipurified cell culture-passaged Cowden group C rotavirus, the sensitivity of the MAb capture-PAb detection ELISA for detection of homologous group C rotavirus was 53 fluorescent focus units per ml. Epitope mapping by use of the biotinylated MAbs in competition assay suggested that our MAbs may bind to three different but overlapping epitopes. These results suggest that the MAb capture-PAb detector ELISA can be used to study the epidemiology of group C rotaviruses in humans and animals.     

Characterization of monoclonal antibodies to adenovirus type 35 hexon

Twenty three monoclonal antibody-rich ascitic fluids (MIAFs) to human adenovirus (AV) type 35 hexon were studied by indirect ELISA using various tracer systems, passive haemagglutination (HA) as well as gel diffusion techniques. Eleven different human heterologous hexon types in addition to the homologous one, and two animal adenovirus (AV) hexons were used to determine the reactivity patterns (RPs) of the monoclonal antibodies (MoAbs). Based on the cross-reactivity with the different hexon types, the MoAbs exhibited genus, subgenus and type specificities; furthermore, a variety of intersubgenus and intertype specificities could be found. Fifteen of the MoAbs reacted in ELISA, but not in passive HA, suggesting that certain epitopes on the hexons bound to red blood cells were not available for the MoAbs in question. Four MoAbs were able to form a precipitin line with the hexon antigen in gel diffusion. Two of the four (MoAbs 35H10 and 35H51) formed with the homologous AV35 hexon a single confluent precipitin line only. In spite of the origin of these MoAbs from different hybrid cells (clones) their specificity was probably identical when recognizing the type-specific epitope of the AV35 hexon. The other two MoAbs (35H15 and 35H26) with a broad RPs were able to precipitate not only the homologous but also different heterologous hexon types.     

Production of mouse monoclonal antibodies to Pasteurella multocida type A and the immunological properties of a protective anti-lipopolysaccharide antibody

Eight monoclonal antibodies (MAbs) were produced from mice immunised with whole cells of heat-killed Pasteurella multocida type A which had been cultured under iron-restricted conditions. The MAbs were selected by an enzyme-linked immunosorbent assay (ELISA) in which the antigen consisted of whole bacteria of the immunising strain. Their reactivity was investigated further by immunoblotting, indirect haemagglutination, a complement-mediated bactericidal assay and passive protection of mice. One of the eight MAbs was shown by immunoblotting to react with lipopolysaccharide (LPS), was bactericidal, and completely protected mice against homologous challenge with 10 LD50 of live bacteria. This MAb was selected for further study. Its reaction with LPS of 17 type-A strains and of single strains of types B, D and E was investigated by immunoblotting. Strains that reacted with the anti-LPS MAb in immunoblots were susceptible to its bactericidal activity and gave high ELISA absorbances. Those that did not react were not susceptible to its bactericidal activity and gave low ELISA readings. The relation between bactericidal activity and ELISA absorbance was highly significant (p less than 0.001). Five of the strongly reacting heterologous strains and one non-reacting strain were selected as challenge organisms in a passive protection experiment: only the mice receiving the reacting strains were protected.     

Detection of Vibrio cholerae with monoclonal antibodies specific for serovar O1 lipopolysaccharide.

Six hybridoma cell lines, each of which produced a monoclonal antibody (MAb) against Vibrio cholerae O1 lipopolysaccharide (LPS), were established. Each MAb was active serologically by both enzyme-linked immunosorbent assay (ELISA) and the slide agglutination test. In the ELISA, each MAb was tested against 7 O1 and 9 non-O1 LPS preparations. Three MAbs reacted with both Inaba and Ogawa serovars (A antigen), two MAbs reacted with the Ogawa serovars only (B antigen), and one MAb reacted with the Inaba serovars only (C antigen). Each MAb was also tested in the ELISA against whole-cell preparations of 37 O1 and 52 non-O1 V. cholerae serovars, 20 heterologous Vibrio species, and 37 heterologous bacterial species. The MAbs reacted with V. cholerae O1 cells only, except for one anti-A antigen MAb which reacted weakly with five V. cholerae non-O1 serovars and Serratia marcescens. Each anti-A antigen MAb was labeled with fluorescein isothiocyanate (FITC) and tested by direct immunofluorescence against selected O1 and non-O1 serovars. Each MAb-FITC conjugate, when tested alone, exhibited O1-specific fluorescence; however, mixtures of the MAb-FITC dramatically enhanced fluorescence intensity on O1 cells. This finding was also visualized by immunoelectron microscopy on both thin-sectioned and negatively stained O1 cells by using an anti-mouse immunoglobulin-colloidal gold conjugate. These results suggest that the A antigen can be described by more than one epitope and that a superior serotyping reagent can be prepared from a defined mixture of MAbs.     

A monoclonal antibody-based antigen capture enzyme-linked immunosorbent assay for identification of infectious bronchitis virus serotypes

An antigen-capture enzyme-linked immunosorbent assay (C-ELISA) was developed for detection and identification of infectious bronchitis virus (IBV) serotypes Arkansas, Connecticut, and Massachusetts using monoclonal antibodies (MAbs) specific to the S1 glycoprotein of the respective serotype. The assay (designed as a double-antibody sandwich assay) gave the best results when the S1-specific MAb, antigen, and chicken serum were of the same serotype. However, when a group-specific (M glycoprotein-specific) MAb was used for antigen capture, a distinctive pattern of cross-reactivity was observed between the antigens and heterologous chicken sera, suggesting a complex distribution of epitopes on the IBV M glycoproteins. Treatment of antigen with NP40 enhanced the ELISA signal only when the M glycoprotein-specific MAb was used for antigen capture. Although C-ELISA was inconsistent in detecting IBV in chicken tissue homogenates, it was highly effective in detecting the virus in allantoic fluid after the homogenates were given one chicken embryo passage.     

Antigenic homogeneity among the adenovirus hexon types of subgenus C

Summary Antigenic relationships of hexons of human adenovirus (Ad h) types 1, 2, 5 and 6 of subgenus C were studied with 61 monoclonal antibodies (MAbs) raised against human Ad h1, Ad h35 and bovine adenovirus 2. The reactivity pattern (RP) and the titers of the MAbs were determined in indirect ELISA. In previous experiments with hexons of different subgenera 49 MAbs displayed numerous different intertype specificities besides genus specific and type specific ones. With the four hexon types of subgenus C all MAbs gave identical RPs except the type specific ones. Data reveal the existence of a remarkable homogeneity in the antigenic structure among the hexon types of subgenus C defined by the presence of identical or closely related intertype specific epitopes on the surface of the hexons. The possible significance of the results in the experimental gene therapy is discussed.     

Monoclonal antibodies to an Indian strain of type A foot-and-mouth disease virus

A set of five neutralizing monoclonal antibodies (MAbs) to an Indian strain (IND17/77) of type A (subtype A22) foot-and-mouth disease (FMD) virus (FMDV) was used in the study. Four of the MAbs (27S, 37S, 85S, and 143S) identified a trypsin-sensitive (TS) epitope(s) and were specific for VP1, while the remaining MAb (145S) reacted with a trypsin-resistant (TR) epitope and was specific for VP3 in Western blot analysis. Both the epitopes (TS and TR) were conformation-independent in nature. Results obtained in MAb-competition enzyme-linked immunosorbent assay (ELISA), and profiling of the (MAb) neutralization-escape mutants in ELISA and cross-neutralization test revealed two overlapping TS epitopes (27S/37S and 85S/143S) on the virus. Variation at both these epitopes was observed in some field isolates of serotype A. Comparison of deduced amino acid sequence in the VP1 region (aa 140-213) between the parent virus and the mutants identified Gly148 and Arg153 as critical for the formation of both the TS epitopes. Substitution of R153 by Gly or Ser was observed in mutants with no reactivity for the MAbs 85S/143S. However, these mutants maintained partial reactivity with MAbs 27S/37S, and substitution of Gly148 by Glu eliminated both the epitopes. No amino acid substitution was observed in the VP1 region of aa 200-213. Efficient neutralization of the MAb neutralization escape mutants (MAb-resistant (MAR) mutants) by bovine vaccinate serum (BVS) indicated involvement of other epitopes on the virion surface in eliciting neutralizing antibodies following vaccination.     

Identification of the immunogenic outer membrane protein A antigen of Haemophilus parasuis by a proteomics approach and passive immunization with monoclonal antibodies in mice

Monoclonal antibodies (MAbs) against Haemophilus parasuis were generated by fusing spleen cells from BALB/c mice immunized with whole bacterial cells with SP2/0 murine myeloma cells. Desirable hybridomas were screened by enzyme-linked immunosorbent assay (ELISA). Neutralizing MAb 1D8 was selected in protection assays. ELISA results demonstrated that 1D8 can react with all 15 serotypes of H. parasuis and field isolate H. parasuis HLJ-018. Passive immunization studies showed that mice inoculated intraperitoneally with 1D8 had significantly reduced prevalence of H. parasuis colonization in the blood, lung, spleen, and liver and had prolonged survival time compared to that of the control group. Furthermore, the passive transfer experiment indicated that MAb 1D8 can protect mice from both homologous and heterologous challenges with H. parasuis. Using two-dimensional gel electrophoresis (2-DE), the immunoreactive protein target for MAb 1D8 was identified. The data presented confirm the protective role of MAb 1D8 and identify OmpA as the target of the protective monoclonal antibody. The data suggest that OmpA is a promising candidate for a subunit vaccine against H. parasuis.     

Identification and characterization of outer membrane proteins of Pasteurella multocida serotype D by using monoclonal antibodies.

Monoclonal antibodies (MAbs) against Pasteurella multocida serotype D were obtained by fusion of spleen cells from BALB/c mice immunized with outer membrane proteins (OMPs) with SP2/0-Ag 14 murine myeloma cells. Desirable MAbs were selected by enzyme-linked immunosorbent assay (ELISA) with OMP as the antigen. MAbs MT1 and MT2 identified two different proteins (H [heavy] and W [weak]), each with a molecular mass of 32 kDa, in Western blots (immunoblots). Treatment of the OMPs with proteolytic enzymes and sodium periodate indicated that the binding sites of MAbs MT1 and MT2 are of protein and glycoprotein natures, respectively. The epitopes reactive with MAbs were surface exposed, as visualized by immunoelectron microscopy. Among field isolates of P. multocida serotype D, two distinct OMP patterns were recognized by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and these patterns were designated types I and II. In both the ELISA and the Western blot, MAb MT1 recognized only type I isolates, whereas MAb MT2 recognized both type I and II isolates. Neither MAb MT1 nor MAb MT2 reacted with either reference strains of capsular serotypes A, B, E, and F or field isolates of capsular serotype A of P. multocida. This is the first report of MAbs identifying the serotype D-specific OMP of P. multocida.     

Monoclonal antibodies to conformational epitopes of the surface glycoprotein of caprine arthritis-encephalitis virus: potential application to competitive-inhibition enzyme-linked immunosorbent assay for detecting antibodies in goat sera

Four immunoglobulin G1 monoclonal antibodies (MAbs) to the gp135 surface envelope glycoprotein (SU) of the 79-63 isolate of caprine arthritis-encephalitis virus (CAEV), referred to as CAEV-63, were characterized and evaluated for their ability to compete with antibody from CAEV-infected goats. Three murine MAbs (MAbs GPB16A, 29A, and 74A) and one caprine MAb (MAb F7-299) were examined. All MAbs reacted in nitrocellulose dot blots with native CAEV-63 SU purified by MAb F7-299 affinity chromatography, whereas none reacted with denatured and reduced SU. All MAbs reacted in Western blots with purified CAEV-63 SU or the SU component of whole-virus lysate following denaturation in the absence of reducing agent, indicating that intramolecular disulfide bonding was essential for epitope integrity. Peptide-N-glycosidase F digestion of SU abolished the reactivities of MAbs 74A and F7-299, whereas treatment of SU with N-acetylneuraminate glycohydrolase (sialidase A) under nonreducing conditions enhanced the reactivities of all MAbs as well as polyclonal goat sera. MAbs 29A and F7-299 were cross-reactive with the SU of an independent strain of CAEV (CAEV-Co). By enzyme-linked immunosorbent assay (ELISA), the reactivities of horseradish peroxidase (HRP)-conjugated MAbs 16A and 29A with homologous CAEV-63 SU were <10% of that of HRP-conjugated MAb 74A. The reactivity of HRP-conjugated MAb 74A was blocked by sera from goats immunized with CAEV-63 SU or infected with CAEV-63. The reactivity of MAb 74A was also blocked by sera from goats infected with a CAEV-Co molecular clone, although MAb 74A did not react with CAEV-Co SU in Western blots. Thus, goats infected with either CAEV-63 or CAEV-Co make antibodies that inhibit binding of MAb 74A to CAEV-63 SU. A competitive-inhibition ELISA based on displacement of MAb 74A reactivity has potential applicability for the serologic diagnosis of CAEV infection.     

Rapid grouping of monoclonal antibodies based on their topographical epitopes by a label-free competitive immunoassay

Topography of epitopes of monoclonal antibodies (MAbs), identified as the mutual competition of the MAbs, can be valuable indicators for the biological functions of MAbs. However, the determination of topographical epitopes is not performed before the functional screening of MAbs, because the requirement for purifying and labeling of MAbs makes the mapping experiment difficult, particularly in the early stage of MAb production. Here we describe a new label-free competitive enzyme-linked immunosorbent assay (LFC-ELISA) for the rapid grouping of MAbs based on the topography of their epitopes. In the LFC-ELISA, the immune complex formed by a competitor, MAb#2, and an antigen is challenged by an indicator, MAb#1 that had been captured on the ELISA plate through a secondary antibody. The MAb#2-antigen immune complex is trapped by MAb#1 only if MAb#1 reacts with an epitope different from that of MAb#2. The immune complex (MAb#2-antigen-MAb#1) is detected with an enzyme-labeled reagent specific to a tag on the antigen. Our experiments using different anti-CD30 MAbs and a CD30-Fc fusion protein as the antigen revealed that the LFC-ELISA performed well with MAbs of different isotypes (IgG1, IgG2a, and IgG2b), and in a practical range of MAb concentrations (0.3-10 microg/ml) and affinities (0.9-13 nM of Kd). We obtained pairwise competition data from all 26 anti-CD30 MAbs. We then utilized a cluster analysis and a bootstrap method to analyze the competition data for grouping of the MAbs. This objective and automated analysis identified eight distinct topographical epitopes on CD30. The reactivity of the anti-CD30 MAbs in immunoblot, and their inhibiting activity on CD30-CD30-ligand binding correlated with the topographical epitopes. The results show that the LFC-ELISA combined with cluster analysis is a useful new method for grouping MAbs based on their topographical epitopes and can be used in the early stage of MAb production. One useful application is to identify MAbs reacting with different epitopes from a large number of MAbs so that the most appropriate MAbs can be selected for therapeutic use.     

Production and characterization of monoclonal antibodies to type 8 lipooligosaccharide of Neisseria meningitidis.

Eight monoclonal antibodies (MAbs) to lipooligosaccharides (LOSs) of Neisseria meningitidis were produced by immunizing mice with purified LOS from group A meningococcal strain A1. The specificities of the MAbs were examined by enzyme-linked immunosorbent assay (ELISA), immunodot assay, and ELISA inhibition by using the homologous A1 LOS, 12 immunotype LOSs of N. meningitidis (L1 through L12), and LOSs or lipopolysaccharides from other gram-negative bacteria. Two of the MAbs, 4385G7 (immunoglobulin G2b [IgG2b]) and 4387A5 (IgG2a), had the strongest reactivities with the homologous A1 LOS, moderate reactivities with the M978 (L8) LOS, but no reactivity with other LOSs. The other six MAbs (4 IgM and 2 IgG3) reacted with the A1 LOS and with several or many of the 12 LOSs. ELISA inhibition at 50% showed that the inhibitory activities of the LOSs from strains A1 and BB431 (a group B strain) to the specific MAb 4387A5 were about 10 to 20 times greater than that of the M978 (L8) LOS. When compared with MAb 2-1-L8 (L8) by Western blot (immunoblot) analysis and ELISA inhibition, the two specific MAbs recognized a different epitope in the 3.6-kDa LOSs of strains A1 and BB431. We propose that the new epitope is L8a, since the MAbs also reacted with the M978 (L8) LOS. The expression of the L8a epitope in the A1 LOS requires a few monosaccharide residues in its oligosaccharide moiety, and the fatty acid residues in its lipid A moiety also play a role. In a whole-cell ELISA, the two specific MAbs bound specifically to the homologous strain A1 and the L8 prototype strain M978 but not to any other LOS prototype strains. These results suggest that the two specific MAbs can be used for LOS typing of N. meningitidis.     

Characterization of intertype specific epitopes on adenovirus hexons

Summary.  The specification and differentiation of eighteen intertype specific (IT) epitopes of adenovirus hexons defined by monoclonal antibodies are given by two groups of hexon types: on which they are andon which they are not present. The close specificity relationship among some groups of epitopes determined by pairwise analysis according to their presence on the hexon types indicate that they could be continuous (sequential), overlapping or discontinuous (topographic) epitopes. Based on the identification of the hydrophilic regions and the localization of β-turns sixteen IT epitope sites were predicted on human adenovirus (HAdV) type 2 and nineteen on HAdV-41 hexon’s amino acid (aa) sequences beside the type and genus specific ones. The 16 predicted IT epitopes on HAdV-2 hexon show good coincidency with the 14 IT epitopes demonstrated with monoclonal antibodies (MAbs) on this hexon type. The predicted number of common epitopes between HAdV types 2 and 41 also corresponds well with the eight IT epitopes determined by MAbs, but the 17 predicted non-common epitopes indicate the possibility of the existence of more epitopes on these hexon types. The location of the predicted epitopes of HAdV-2 were determined by alignment of their sequence numbers on the three dimensional ribbon representation of the hexon subunit. Most of the predicted IT epitopes were found between the type and genus specific epitopes i.e. in the “upper” regions of pedestal domains P1 and P2 orientated toward the virion surface and in the “lower” part of loop 1 region orientated inside the virion. Two peptides representing potential IT epitopes were synthesized corresponding to residues 309–320 from the “lower” part of loop 1 and 399–408 from the “upper” part of P1 region of HAdV-2 hexon. Antibodies raised against the peptide-carrier conjugates recognized different purified native hexon types in ELISA. Received November 3, 1997 Accepted April 24, 1998