Antigenic variation of Giardia lamblia in vivo.

A single Giardia lamblia trophozoite can give rise in vitro to G. lamblia with varying surface antigens. To determine whether antigenic variation also occurs in vivo, gerbils were inoculated with defined G. lamblia clones and the surface antigens of the intestinal trophozoites were studied at different times during the infection. The proportion of monoclonal antibody 6E7-reacting trophozoites from WB C1-6E7S-inoculated gerbils had decreased significantly by day 3 postinoculation, indicating the presence of a heterogeneous population. On day 7, the 170-kilodalton antigen was no longer present and was replaced by a variety of antigens, including a major protein of 92 kilodaltons. With the exception of isolates from gerbils inoculated with WB A6-6E7S, the banding patterns of G. lamblia isolated from gerbils on day 7 or later were the same regardless of the clones used for inoculation. These studies show that G. lamblia changes its surface antigen(s) in vivo within 7 days following inoculation and appears to maintain the same set of surface antigens during the course of infection.     

Characterization of cytohesin-1 monoclonal antibodies: expression in neutrophils and during granulocytic maturation of HL-60 cells

ADP-ribosylation factors (Arf) are small GTP-binding proteins involved in vesicular transport and the activation of phospholipase D (PLD). The conversion of Arf-GDP to Arf-GTP is promoted in vivo by guanine nucleotide exchange factors such as ARNO or cytohesin-1. In order to examine the expression of ARNO and cytohesin-1 in human granulocytes, we generated specific polyclonal and monoclonal antibodies (mAbs). We also overexpressed GFP-ARNO and GFP-cytohesin-1 in RBL-2H3 cells to characterize the specificity and the ability of cytohesin-1 mAbs to immunoprecipitate cytohesin-1. Among the hybridomas secreting cytohesin-1 mAbs, only the clones 2E11, 1E4, 3C8, 6F5, 4C7, 7A3 and 8F7 were found to be specific for cytohesin-1. Furthermore, mAb 2E11 immunoprecipitated GFP-cytohesin-1 but not GFP-ARNO under native conditions. In contrast, mAbs 5D8, 4C3, 2G8, 6G11, 4C3, 6D4, 7B4 and 6F8 detected both cytohesin-1 and ARNO as monitored by immunoblotting. Although mAb 6G11 detected both proteins, this antibody immunoprecipitated GFP-ARNO but not GFP-cytohesin-1 under native conditions. Another antibody, mAb 10A12, also selectively immunoprecipitated GFP-ARNO under native conditions, but the epitope recognized by this mAb is unlikely to be linear as no signal was obtained by immunoblotting. Immunoprecipitation with a cytohesin-1 polyclonal antibody and blotting with cytohesin-1 specific mAbs revealed that cytohesin-1 is highly expressed in neutrophils. Cytohesin-1 can be detected in HL-60 cells but the endogenous protein levels were low in undifferentiated cells. Using the specific cytohesin-1 mAb 2E11 we observed a marked increase in levels of cytohesin-1 expression during dibutyryl-cyclic AMP-induced granulocytic differentiation of HL-60 cells. These data suggest that cytohesin-1, which may have important functions in neutrophil physiology, can be useful as a potential marker for granulocytic differentiation.     

Microneme antigens of Eimeria bovis recognized by two monoclonal antibodies

Two IgG1 monoclonal antibodies (mAbs 8-23F9 and 9-21G9) were developed after immunization of mice with homogenates of Eimeria bovis first-generation merozoites. Both mAbs reacted with antigens in the apical two-thirds of the parasites and immune electron microscopy determined the micronemes as targets. When tested by immunoblotting, mAb 8-23F9 failed to react with antigens separated under reducing conditions; under nonreducing conditions it recognized two components of >200 kDa. mAb 9-21G9 bound to antigens of 135 and 180 kDa after electrophoresis under reducing conditions and to a series of components when separated without reduction. The epitope of mAb 8-23F9 was destroyed by treatment of the antigen with endoglycosidase H and removal of phosphocholine (PC) by phospholipase C. Since mAb 8-23F9 does not recognize cytidine-linked PC, the data suggest that PC in combination with N-linked sugars and/or N-glycans is part of its epitope. In the case of mAb 9-21G9, endoglycosidase H did not alter the epitope. When E. bovis merozoite antigen was treated with phospholipase C the number of mAb 9-21G9-reactive constituents increased, suggesting that PC may otherwise mask the epitope. mAb 8-23F9 also bound to the apical area and the surface of E. bovis sporozoites and recognized a >200-kDa sporozoite component. When sporozoites invaded Vero cells in vitro, epitope-bearing components were released onto the host cell surface and became part of the early parasitophorous vacuole wall. At day 5 the binding of the mAb was again confined to the intracellular parasite. mAb 9-21G9 did not react with sporozoites but recognized the apical area of intra-cellular trophozoites on day 5 after invasion of host cells in vitro. When testing was done against a variety of other Apicomplexa in various assays, the only cross-reaction observed occurred with mAb 8-23F9, which bound to a conformationally determined 180-kDa component of Toxoplasma gondii cystozoites. Received: 20 November 1998 / Accepted: 18 January 1999     

Generation and characterization of monoclonal antibodies against Giardia muris trophozoites.

Mouse monoclonal antibodies (mAb) were produced against Giardia muris trophozoite surface antigens. To generate B-cell hybridomas, P3/NS1/1-Ag4-1 myeloma cells were fused with splenic lymphocytes from BALB/c mice that had been immunized parenterally with G. muris trophozoites. Hybridoma culture supernatants were screened for mAb by flow cytometry of G. muris trophozoites incubated with culture supernatant followed by fluorescein-conjugated anti-mouse IgG and IgM. Flow cytometry showed three types of trophozoite staining by mAb: (i) bright staining of greater than 90% of trophozoites, with aggregation of the organisms; (ii) bright staining of approximately 90% of trophozoites, with little or no aggregation; (iii) dull staining of approximately 20% of trophozoites, without aggregation. Western blotting of mAb on G. muris trophozoite antigens separated by polyacrylamide gel electrophoresis showed that a mAb exhibiting the third of these flow cytometry staining patterns recognized trophozoite antigens of MW approximately 31,000 and 35,000. Immunoprecipitation studies indicated that the same mAb specifically precipitated two 125I-labelled trophozoite surface antigens of MW approximately 30,000. Monoclonal antibodies generated in this study may facilitate the purification and biochemical characterization of trophozoite antigens that are targets for protective intestinal antibody in G. muris-infected mice.     

Isolate and epitope variability in susceptibility of Giardia lamblia to intestinal proteases.

The surface antigens of Giardia lamblia differ. To determine whether the unique surface antigens found in variants and isolates could differentially protect the parasite from digestion by intestinal protease, G. lamblia clones WB-2X (WB), GS/M-H7 (GS/M), and B6, each of which expresses a unique surface variant antigen, were exposed to alpha-chymotrypsin and trypsin at concentrations up to 20 mg/ml in culture medium. The number of surviving trophozoites and morphologic changes were assessed over time. After 24 h, there was a significant decrease in the number of surviving trophozoites of WB (80.5 and 94.2% for trypsin and alpha-chymotrypsin treatments, respectively, compared with controls) and B6 (78.9 and 95.5% for trypsin and alpha-chymotrypsin treatments, respectively, compared with controls) at 10 mg of enzyme per ml compared with culture medium alone. Cytotoxicity was prevented by the presence of soybean trypsin inhibitor, indicating the effects were due to protease activity. In contrast, there was no significant cytotoxicity after exposure of GS/M to either enzyme at the same enzyme concentration. After exposure to alpha-chymotrypsin, susceptible G. lamblia became rounded and then lysed, but after exposure to trypsin, G. lamblia appeared plastered onto the surface of the well and was intertwined and surrounded by finely granular material. Effects were concentration and time dependent; at least 6 h of treatment was required to observe changes 12 to 18 h later. Trophozoites surviving alpha-chymotrypsin or trypsin exposure became stably resistant to protease treatment. In vitro, the variant surface antigen of GS/M, but not those of WB or B6, resisted digestion by trypsin or alpha-chymotrypsin, suggesting that the variant surface antigens impart susceptibility or resistance to digestion. The initial surface variant antigens of WB and B6 were replaced in resistant cultures. Trophozoites differ in their ability to survive after exposure to intestinal proteases, which may enable certain G. lamblia isolates or isolates possessing certain surface variant antigens to survive in the small intestine.     

The characterization of two monoclonal antibodies which react with high molecular weight antigens of asexual Plasmodium falciparum.

We prepared rat monoclonal antibodies (mAb) specific for very large Plasmodium falciparum proteins to assist in their characterization. Hybridomas prepared from rats immunized with parasitized erythrocyte (PE) proteins of greater than 200 kDa exhibited two patterns of Western blot reactivity with PE SDS extracts: one represented by clone 41E11 (IgM, kappa), the other by clone 12C11 (IgM, lambda). MAb 41E11 reacted by Western blotting with at least 15 antigens, most of which comigrated with antigens identified by the 33G2 human IgM mAb. The stage specificity of mAb 41E11 reactivity and indirect immunofluorescence (IFA) pattern closely resemble those previously described for antigens that share the EEXXEE sequence motif. Unlike mAb 33G2, MAb 41E11 immunoprecipitated a biosynthetically radiolabeled protein of 320 kDa. MAb 41E11 did not immunoprecipitate any cell surface 125I proteins. MAb 12C11 reacted on Western blotting with a different group of malarial antigens of approximately 44, 95, 117, 145, and 310 kDa, as well as with some low-molecular-weight, uninfected erythrocyte antigens. MAb 12C11 did not immunoprecipitate any cell surface 125I or biosynthetically labeled proteins. The 310-kDa antigen recognized by mAb 12C11 (denoted Ag 12A) does not correspond to PfEMP2 or the 320-kDa antigen recognized by mAbs 33G2 or 41E11. With trophozoites and more mature stages, fixed IFA reactivity of mAb 12C11 was at the parasite and in antigen aggregates in the host cell cytoplasm that extended to the PE plasma membrane. Indirect results suggest that Ag 12A does not correspond to cell surface-exposed PfEMP1 and is most likely a hitherto unidentified malarial protein.     

Production and characterization of monoclonal antibodies against binary ethylenimine inactivated Nipah virus

Nipah virus, a zoonotic paramyxovirus which emerged recently was chemically inactivated using binary ethylenimine (BEI). The inactivated virus was concentrated and purified by sucrose gradient centrifugation. The gradient fractions were examined by electron microscopy and Western immunoblot, and gradient fraction containing mainly Nipah matrix (M) and nucleocapsid (N) proteins was used for immunizing BALB/c mice to generate hybridomas. Screening of the resultant hybridoma clones identified five strongly positive clones producing IgG monoclonal antibodies (mAbs) reactive to the Nipah virus antigen. The protein specificity of these mAbs was determined by Western immunoblot using Nipah virus and recombinant Nipah virus proteins expressed in mammalian cells. Four mAbs reacted with Nipah N protein and one reacted with Nipah M protein. None of the mAbs neutralized Nipah virus infectivity in vitro. However, all mAbs recognized Nipah virus in ELISA and immunofluorescence assay. F45G2 mAb was most suitable for immunohistochemistry on long term formalin-fixed Nipah virus infected swine tissues. Three of the anti-nucleocapsid mAbs (F45G2, F45G3 and F45G6) showed cross-reactivity with closely related Hendra virus N protein in both immunofluorescence and Western Immunoblot assays. Two of the mAbs were specific for the Nipah virus only, F45G4 (anti-N) and F45G5 (anti-M), and could be used in the primary identification of Nipah virus. The use of these immunoreagents to develop new diagnostic assays is discussed.     

Generation and application of new rat monoclonal antibodies against synthetic FLAG and OLLAS tags for improved immunodetection

Previously, we prepared monoclonal antibodies (mAbs) by immunizing rats with the recombinant fusion proteins of mouse Langerin/CD207, which contained a flexible linker sequence from E. coli OmpF and a FLAG epitope. We found many of new rat mAbs were not reactive to mouse Langerin, and here we identify the epitopes of two of these IgG mAbs, L2 and L5, and assess their efficacy in various immunodetection methods. MAb L5 is a rat IgG mAb against the FLAG epitope, which detected both N-terminal and C-terminal FLAG tagged protein 2 to 8 times better than the conventional anti-FLAG mAb M2 by Western blot. For mAb L2, we found its epitope to be a 14 amino acid sequence SGFANELGPRLMGK which consisted of both sequences from the OmpF derived linker and mouse Langerin. This epitope sequence was named OLLAS (E. coliOmpF Linker and mouse Langerin fusion Sequence), and mAb L2 as mAb OLLA-2. When the OLLAS sequence was inserted into recombinant proteins at N-terminal, C-terminal, or internal sites, the OLLAS tag was detected by mAb OLLA-2 with very high sensitivity compared to other conventional epitope tags and anti-tag mAbs. MAb OLLA-2 recognized OLLAS tagged proteins with at least 100-fold more sensitivity than anti-FLAG M2 and anti-V5 mAbs in Western blot analyses. We also find the OLLAS epitope to be superior in immunoprecipitation and other immunodetection methods, such as fluorescent immunohistochemistry and flow cytometry. In the process, we successfully utilized the OLLAS epitope sequence as an internal linker for fusion between the engineered mAb and the antigen, and thus achieved improved immunodetection.     

Size heterogeneity among antigenically related Giardia lamblia variant-specific surface proteins is due to differences in tandem repeat copy number.

Giardia lamblia undergoes antigenic variation by modulating the expression of the different genes that comprise the trophozoite's variant-specific surface protein (VSP) repertoire. We studied an epitope that is conserved among VSPs expressed by cloned trophozoite lines derived from the independent G. lamblia isolates WB, G3M, Be-2, and CAT. The epitope recognized by monoclonal antibody 6E7 lies entirely within the region of tandemly repeated 65-amino-acid units that is characteristic of these size-variant VSPs. Northern (RNA) hybridization, cDNA cloning, and DNA sequence analysis indicate that size heterogeneity among these VSPs is due to differences in the number of repetitive units.     

Variant surface antigens of Giardia lamblia are associated with the presence of a thick cell coat: thin section and label fracture immunocytochemistry survey.

Giardia lamblia undergoes surface antigenic variation. The ultrastructural location of antigens on four different variants was studied by label fracture and immunocytochemistry with four monoclonal antibodies (MAbs), each of which recognized the predominant variant in a particular clone. Each Giardia clone and its reacting MAb showed similar findings. The entire surface of the organism was covered by a surface coat which contained the variant surface protein. The surface coat was densely and uniformly labeled. Unreacting MAbs failed to label the surface. Label-fractured Giardia trophozoites exposed to reactive MAb revealed a planar distribution of reactivity with no discernible relationship to visualized intramembranous particles. Unexpectedly, some Giardia trophozoites lacked a surface coat and consequently failed to react with the appropriate MAb. The biological relevance of coatless Giardia trophozoites is unknown. These findings localize the variant antigens to the surface coat of the parasite and identify a minority of the population which lacks a surface coat.     

Two HLA-DQ-specific human-human hybridoma antibodies (TrG6;TrC5) define epitopes also expressed by a transcomplementing hybrid DQ molecule (DQw7 alpha/DQw4 beta)

We have generated two IgG human-human hybridoma Abs, TrG6 and TrC5, that define subsets of HLA-DQ. TrG6 combined selectively with lymphoblastoid cell lines that expressed DQw1 or DQw4. By sequential immunoprecipitation, competition with other mAbs of defined specificity for binding to antigen, and experiments where HLA antigens from cell lysates crosslinked pairs of mAbs, it was established that TrG6 bound a DQ-molecule. mAb TrC5 specifically recognized DQw2+DR3+ and DQw7+DR5+ cells. The reaction pattern of TrC5 with HLA-loss mutants indicated that TrC5 bound to DQw2 of the DQw2+DR3+ haplotype. Antigens in lysate from DQw7+DR5+ cells crosslinked TrC5 to the murine mAbs Tü22 (anti-DQ monomorphic) and IVD-12 (anti-DQw7 + DQw8 + DQw9), demonstrating that on these cells the TrC5 epitope is located on DQw7 molecules. Lysates from DQw7+DR5+/DQw4+DRw8+ heterozygous cells crosslinked TrG6 and TrC5, and available evidence indicated that the epitopes defined by these two mAbs were expressed by the transcomplementing DQ-molecule DQw7 alpha/DQw4 beta, where the DQw7 alpha chain specifies epitope TrC5 and the DQw4 beta chain specifies epitope TrG6. Taken together with published nucleotide sequences of DQ alpha and beta genes, our data are consistent with the conclusion that the amino acids at positions 69 and/or 75 of the DQ alpha chain of DQw2+DR3+ and DQw7+DR5+ haplotypes are critical for epitope TrC5. The previously reported human-human hybridoma Ab TrB12 reacts with DQw6, DQw8, and DQw9. The specificity of the murine mAb IIB3 is similar to that of TrB12, but, unlike TrB12, IIB3 also binds DQw4+ cells.     

Analysis of the neutralization breadth of the anti-V3 antibody F425-B4e8 and re-assessment of its epitope fine specificity by scanning mutagenesis

The identification of cross-neutralizing antibodies to HIV-1 is important for designing antigens aimed at eliciting similar antibodies upon immunization. The monoclonal antibody (mAb) F425-B4e8 had been suggested previously to bind an epitope at the base of V3 and shown to neutralize two primary HIV isolates. Here, we have assessed the neutralization breadth of mAb F425-B4e8 using a 40-member panel of primary HIV-1 and determined the epitope specificity of the mAb. The antibody was able to neutralize 8 clade B viruses (n = 16), 1 clade C virus (n = 11), and 2 clade D viruses (n = 6), thus placing it among the more broadly neutralizing anti-V3 antibodies described so far. Contrary to an initial report, results from our scanning mutagenesis of the V3 region suggest that mAb F425-B4e8 interacts primarily with the crown/tip of V3, notably Ile³⁰⁹, Arg³¹⁵, and Phe³¹⁷. Despite the somewhat limited neutralization breadth of mAb F425-B4e8, the results presented here, along with analyses from other cross-neutralizing anti-V3 mAbs, may facilitate the template-based design of antigens that target V3 and permit neutralization of HIV-1 strains in which the V3 region is accessible to antibodies.     

应用噬菌体展示技术筛选、鉴定抗汉滩病毒单克隆抗体的模拟表位

目的 :应用噬菌体 12肽文库筛选抗汉滩病毒单抗 (mAb)F3、B11的模拟配体肽 ,并对其免疫学特性进行初步分析。方法 :以纯化的mAb为筛选配基 ,进行噬菌体肽库的生物亲和淘选。用ELISA法鉴定筛选克隆的结合活性 ,对阳性克隆进行序列测定和分析。用动物免疫试验初步分析噬菌体颗粒展示的抗原肽的免疫特性。结果 :通过 3～ 4轮生物淘选 ,ELISA显示筛选到的多数噬菌体克隆均可与mAb特异性结合 ;与mAbF3结合的阳性克隆的氨基酸序列高度一致 ,均为 MHGP TKNQMWHT ,与HTNV/SEOVM蛋白G2区第 75 0～ 75 9位氨基酸具有较高的同源性 ;而mAbB11特异性的结合肽在氨基酸水平上表现出一定的多态性 ,其序列的基序尚未能确定 ;动物免疫试验表明 ,噬菌体肽抗原具有良好的免疫反应性和免疫原性 ,是天然病毒抗原较好的免疫原模拟物。结论 :获得了具有良好结合活性的模拟表位肽 ,为基于表位的HFRSV多肽疫苗及DNA疫苗的研制奠定了基础。     

Serological and immunochemical characterization of monoclonal antibodies to Toxoplasma gondii.

The fusion of mouse NS-1 myeloma cells with spleen cells from mice chronically infected with Toxoplasma gondii resulted in eight clones of hybridomas producing monospecific antibodies against membrane or cytoplasmic antigens of Toxoplasma tachyzoites. One of the antibodies to a cytoplasmic determinant was an IgM; the others directed to membrane or cytoplasmic antigens belonged to the IgG2 or IgG3 isotypes. Antibodies of clones 1E11 (IgG3), 2G11, and 3E6 (IgG2) directed to membrane antigens, bound complement and were reactive in the complement-dependent cytotoxicity assay of Sabin-Feldman. These IgG2 antibodies were strongly agglutinating to parasites, whereas the IgG3 was relatively weak. Another IgG2 antibody (5B6), possibly recognizing a shared antigen of membrane and cytoplasm, exhibited a low titre in the cytotoxicity assay as well as in the agglutination assay. Two other antibodies to membrane antigens (2B7 and 2F8) as well as an antibody to a cytoplasmic antigen (3G3) did not bind complement and did not cause agglutination. The pattern of parasite staining produced by monoclonal antibodies to membrane antigens in an IFA test was different from that of polyvalent antisera. A strictly localized or 'beaded' staining was observed, as well as a smooth, rim fluorescence. Toxoplasma tachyzoites were surface radio-iodinated and the solubilized membrane proteins were immunoprecipitated with monoclonal antibodies and analysed by two-dimensional polyacrylamide gel electrophoresis. Two independently arising monoclonal antibodies to membrane antigens (2G11 and 3E6) consistently precipitated both the solubilized 35,000 and 14,000 mol. wt proteins, while 1E11 precipitated the 27,000 mol. wt protein.     

Identification of antigenic epitopes in the haemagglutinin protein of H7 avian influenza virus

ABSTRACT

The H7 subtype avian influenza virus (AIV) has been reported to infect not only poultry but also humans. The haemagglutinin (HA) protein is the major surface antigen of AIV and plays an important role in viral infection. In this study, five monoclonal antibodies (mAbs, 2F8, 3F6, 5C11, 5E2 and 5C12) against the HA protein of H7 virus were produced and characterized. Epitope mapping indicated that ¹⁰³RESGSS¹⁰⁷ was the minimal linear epitope recognized by the mAbs 2F8/3F6/5C11, and mAbs 5E2/5C12 recognized the epitope 103-145aa. The protein sequence alignment of HA indicated that the two epitopes were not found in other subtypes of AIV, and none of the five mAbs cross-reacted with other subtypes, suggesting these mAbs are specific to H7 virus. The epitope ¹⁰³RESGSS¹⁰⁷ was highly conserved among Eurasian lineage strains of H7 AIV, whereas three amino acid substitutions (E104R, E104K and E104G) in the epitope occurred in 98.44% of North-American lineage strains. Any of these single mutations prevented the mutated epitope from being recognized by mAbs 2F8/3F6/5C11; thus, these mAbs can distinguish between Eurasian and North-American lineages of H7 strains. Furthermore, the mAbs 2F8, 3F6 and 5C11 could be highly blocked with H7-positive serum in blocking assays, revealing that ¹⁰³RESGSS¹⁰⁷ may be a dominant epitope stimulating the production of antibodies during viral infection. These results may facilitate future investigations into the structure and function of HA protein, as well as surveillance and detection of H7 virus.

RESEARCH HIGHLIGHTS

• Five mAbs against HA protein of H7 AIV were generated and characterized.

• Two novel epitopes ¹⁰³RESGSS¹⁰⁷ and 103-145aa were identified.

• The epitope ¹⁰³RESGSS¹⁰⁷ differs between Eurasian and North-American lineages.

• The mAbs 2F8, 3F6 and 5C11 could distinguish two lineages of H7 strains.

     

The therapeutic action of monoclonal antibodies against a surface glycoprotein of Giardia muris.

Twenty-three monoclonal antibodies (mAbs) against Giardia muris were obtained in two fusions using spleen cells of immunized mice. Similarly, the fusion of mesenteric lymph node (MLN) cells of an infected mouse yielded 15 mAbs. Three mAbs arising from spleen cells and two from MLN (all five were IgM) were able to kill trophozoites in the presence of guinea-pig complement (GPC). They can agglutinate trophozoites and also impair the movement of the flagella in the absence of GPC. I.p. treatment of mice with mAb 45C on Days -1, 1, 3 and 5 of infection significantly reduced the intestinal parasite burden. Indirect immunofluorescence assays on live and fixed trophozoites revealed that the cytotoxic mAbs were directed against antigens located on the periphery of the body, the sucking disc, the flagella and the ventro-lateral flange. In Western blots, our mAbs recognized major 36,200 and 30,300 MW glycoproteins located on the surface of the parasite.     

Monoclonal antibodies defining shared human macrophage-endothelial antigens.

We have selected several monoclonal antibodies (mAbs) producing using human rheumatoid arthritis (RA) synovial macrophages (m phi s) as immunogen. Of these, mAbs 8H2, 10G7 and 10G9 showed cross reactivity with endothelium, suggesting common antigens between these cell types. We have determined the spectrum of reactivity of these mAbs on hematopoietic cell lines, peripheral blood cells, and inflammatory and non-inflammatory tissues by immunohistochemistry. MAb 8H2 does not react with the myeloid cell lines HL60 (myelocytic), U937 (histiocytic lymphoma), and K562 (erythroleukemia), or with peripheral blood cells. In normal and inflamed tissue sections, mAb 8H2 reacts with m phi s and endothelial cells. In contrast, mAb 10G7 does not react with peripheral blood cells, but reacts with HL60, U937, and K562 cell lines, as well as with m phi s and endothelial cells in inflamed and noninflamed tissues. MAb 10G9 does not react with myeloid cell lines, but reacts with monocytes and platelets in peripheral blood. In both normal and inflamed tissues, mAb 10G9 reacts with m phi s and endothelial cells. The antigens identified by these three mAbs were characterized biochemically, by enzymatic digestion of RA synovial tissue m phi s followed by a cellular ELISA, as well as by reactivity of the mAbs with NIH-3T3 cells genetically engineered to express known myeloid antigens. These mAbs reacted with protein or glycoprotein antigens distinct from the known myeloid antigens CD13, CD14, CD33, CD34, CD36, and c-fms. These mAbs should prove to be a valuable tool for studying m phi s and endothelial cells and their shared antigenic determinants.     

Mapping of B-cell epitopes of hemagglutinin protein of rinderpest virus

Monoclonal antibodies (mAbs) against secreted hemagglutinin (H) protein of rinderpest virus (RPV) expressed by a recombinant baculovirus were generated to characterize the antigenic sites on H protein and regions of functional significance. Three of the mAbs displayed hemagglutination inhibition activity and these mAbs were unable to neutralize virus infectivity. Western immunoblot analysis of overlapping deletion mutants indicated that three mAbs recognize antigenic regions at the extreme carboxy terminus (between amino acids 569 and 609) and the fourth mAb between amino acids 512 and 568. Using synthetic peptides, aa 569-577 and 575-583 were identified as the epitopes for E2G4 and D2F4, respectively. The epitopic domains of A12A9 and E2B6 mAbs were mapped to regions encompassing aa 527-554 and 588-609. Two epitopes spanning the extreme carboxy terminal region of aa 573 to 587 and 588 to 609 were shown to be immunodominant employing a competitive ELISA with polyclonal sera form vaccinated cattle. The D2F4 mAb which recognizes a unique epitope on RPV-H is not present on the closely related peste des petits ruminant virus HN protein and this mAb could serve as a tool in the seromonitoring program after rinderpest vaccination.     

Comparative reactivity of different HLA-G monoclonal antibodies to soluble HLA-G molecules

Different HLA-G monoclonal antibodies (mAbs) were first evaluated for their capability to identify soluble HLA-G (sHLA-G) in ELISA. Three of them, namely 87G, BFL.1 and MEM-G/9, when used as coating mAbs together with W6/32 capture mAb, identified beta2-microglobulin (beta2m)-associated-sHLA-G but not soluble HLA-B7 (sHLA-B7) in cell culture supernatants from transfected cells. By comparison, the anti-HLA class I mAb 90 did recognize both sHLA-G and sHLA-B7. By using these HLA-G mAbs, sHLA-G was identified in amniotic fluids as well as in culture supernatants of first trimester and term placental explants but not in cord blood. Intron 4-retaining sHLA-G isoforms were identified in some amniotic fluids by the use of an intron 4-specific mAb (16G1). Reactivity of these different HLA-G mAbs was then compared to determine their respective binding sites on soluble and membrane-bound HLA-G. Using both ELISA and flow cytometry analysis, we showed that they did not compete with each other, which suggested that they did not recognize the same determinants. Finally, we report that two mAbs directed against the alpha1 domain of HLA class I heavy chain (mAb 90 and YTH 862) did compete with 87G, therefore demonstrating that this latter mAb recognized an epitope localized on this external domain of HLA-G.