Antigenic determinants on human choriogonadotropin alpha-subunit. I. Characterization of topographic sites recognized by monoclonal antibodies

Immunochemical studies were designed to localize antigenic regions recognized by two monoclonal antibodies directed against the alpha-subunit of human choriogonadotropin (hCG-alpha) and to provide information on the three-dimensional structure of hCG and its alpha-subunit. Monoclonal antibody HT13 bound to a region accessible on both hCG and the free alpha-subunit, whereas monoclonal antibody AHT20 recognized a site localized only on the free alpha-subunit. By studying the cross-reactivity of these antibodies to homologous proteins, we found that antibody HT13 did not bind to equine or ovine lutropin, whereas AHT20 was capable of binding to both subunits. This observation suggests that AHT20 recognized a structurally related antigenic determinant on alpha-subunits of different species. To delineate the portions of hCG-alpha contributing to the antigenic determinants of AHT20 and HT13, we performed competitive inhibition assays using reduced and carboxymethylated hCG-alpha, deglycosylated hCG-alpha, hCG-alpha minus the 5 COOH-terminal residues (hCG-alpha core 1), or disulfide-bridged peptides comprising residues 1-35 and 52-91 of hCG-alpha (hCG-alpha core 2). Reduced and carboxymethylated hCG-alpha did not inhibit the binding of 125I-labeled hCG-alpha to both antibodies, whereas deglycosylated hCG-alpha was as active as hCG-alpha, suggesting that antigenic determinants of both antibodies are mainly discontinuous and do not reside on the oligosacharide part of the alpha-subunit. hCG-alpha core 1 had the same capacity as intact hCG-alpha to inhibit the binding of 125I-hCG-alpha to both antibodies, indicating that the 5 COOH-terminal residues of hCG-alpha do not participate in the antigenic determinants. hCG-alpha core 1 was as potent as hCG-alpha in inhibition experiments performed with HT13, whereas, in striking contrast, hCG-alpha core 2 did not compete with 125I-hCG-alpha for binding to AHT20, suggesting that the peptides released after proteolysis of the alpha-subunit by trypsin participate in the epitope of AHT20 and are not included in the antigenic determinant of HT13. In an attempt to elucidate the amino acid residues constituting the antigenic sites of HT13 and AHT20, hapten inhibition experiments were carried out using as competitive inhibitors five different synthetic peptides spanning the primary structure of hCG-alpha. None of these peptides inhibited the binding of 125I-hCG-alpha to HT13. In contrast, two peptides analogous to regions 23-43 and 33-59 of hCG-alpha exhibited significant potency in competing with 125I-hCG-alpha for binding to AHT20.(ABSTRACT TRUNCATED AT 400 WORDS)     

Monomorphic anti-HLA-A,B,C monoclonal antibodies detecting molecular subunits and combinatorial determinants

Thirteen monoclonal antibodies that react with monomorphic determinants on the HLA-A,B,C-beta 2-microglobulin (beta 2m) molecule were characterized. Analysis of antibody activity included inhibition by papain-solubilized HLA antigens and free beta 2m, antibody binding to mouse-human somatic cell hybrids containing human chromosome 6 or 15, and antibody cross-reactivity with lymphocytes from nonhuman species. Two criteria for monomorphism were established: 1) equal inhibition or absorption of antibody activity by all papain-solubilized HLA antigens or cell lines of different HLA specificities tested; and 2) nonpolymorphic cross-reactivity within another species or subspecies. On the basis of soluble antigen inhibition and binding to somatic cell hybrids, 3 classes of antibodies were detected: anti-beta 2m, anti-heavy chain, and anti-complex (against a combinatorial determinant formed by heavy chain and beta 2m). Antibody cross-reaction patterns in nonhuman species were suggestive that these monomorphic antibodies detect a limited number of determinants, minimally one on each chain and 2 combinatorial determinants. Examination of the known primary sequences for HLA-A2, HLA-B7, H-2Kb, and mouse, rabbit and human beta 2m provides a molecular explanation for this limited mouse anti-HLA monomorphic antibody activity.     

Idiotypic determinants of monoclonal antibodies that bind to 3-fucosyllactosamine

Many monoclonal antibodies that react with the lacto-N-fucopentaose III (LNF III) antigenic determinant, Gal beta 1-4(Fuc alpha 1-3)GlcNAc beta 1-3Gal beta 1-4Glc, have been described recently. The terminal trisaccharide of this determinant, fucosyllactosamine, is present on glycolipids and glycoproteins and on the surface of granulocytes, monocytes, and other cells. To study the structural and genetic diversity of these antibodies, syngeneic anti-idiotypic monoclonal antibodies were produced in BALB/c mice against PMN 6, a monoclonal antibody directed against this sequence. Anti-idiotypic antibodies 6B1 and 6C4 reacted with 50% of a panel of 20 anti-LNF III monoclonal antibodies, whereas 6A3 reacted strongly only with PMN 6. This indicates that the determinants recognized by 6C4 and 6B1 represent major cross-reactive idiotopes of this family of antibodies. The binding of idiotypic antibodies to a glycolipid bearing this antigenic determinant was completely inhibited by the three anti-idiotypic antibodies, 6A3, 6B1, and 6C4. The idiotopes could be demonstrated on the heavy chain of the monoclonal antibodies by an antibody transfer technique when mild reducing conditions were employed, but a high concentration of reducing agent destroyed the idiotypic determinants. This suggests that the anti-idiotypic antibodies recognize conformational structures expressed on the heavy chain molecules. The binding of 18 monoclonal antibodies to two glycolipid antigens and to a fucosyllactosamine-bovine serum albumin conjugate was compared. Antibodies that possessed the 6C4 cross-reactive idiotope bound to fucosyllactosamine-bovine serum albumin more weakly than idiotype-negative antibodies (p = 0.001). This suggests that the 6C4-positive antibodies might represent germline structures.     

Epitope mapping of HLA-B27 and HLA-B7 antigens by using intradomain recombinants

To study the HLA-B7 and HLA-B27 antigenic determinants, hybrid genes between these two alleles were constructed by in vivo recombination in Escherichia coli. After transfection of these genes into P815 (high transfection efficiency recipient) murine cells, the bindings of Bw6, HLA-B7, and HLA-B27 allele-specific mAb were studied, as well as that of human anti-HLA-B7 and anti-HLA-B27 monospecific alloantisera. Most of the HLA-B7 antigenic determinants were assigned to the first external domain of the molecule. Four different epitopic areas could be defined: the Bw6 epitope was associated with residues 82 and 83; the BB7.1 epitope to amino acids 63, 67, and 70; the MB40.2 and MB40.3 epitope to amino acid sequence 177-180, and human alloantisera identified as an epitope associated with residue 9. HLA-B27 antigenicity studied by TM-1 mAb was found to involve residues 77 and 80 in the alpha-1 domain. Results obtained with human monospecific alloantisera allowed the definition of an additional allospecific site associated with the NH2 terminal part on the alpha-1 domain of HLA-B27. Epitope mapping fits with data obtained by sequence comparisons and is discussed with reference to the crystallographic three-dimensional structure of the HLA-A2 molecule.     

Monoclonal antibodies to rabbit and pig zonae pellucidae distinguish species-specific and shared antigenic determinants

Monoclonal antibodies against rabbit or porcine zonae pellucidae (ZP) demonstrate species-specific and shared antigenic determinants. In addition, these antibodies are used to characterize the biochemical nature of these determinants. All of six monoclonal antibodies developed against porcine ZP react with porcine but not with rabbit ZP. Only one of seven monoclonal antibodies developed against rabbit ZP cross-reacts with porcine ZP. None of these antibodies recognized antigens associated with other tissues tested. High-resolution, two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) followed by immunoblotting was used to demonstrate that the cross-reactive antibody recognizes an antigenic determinant which is associated with the major low molecular weight glycoprotein of both the pig and rabbit ZP. Since this antibody recognizes all charge species of this glycoprotein, it is apparent that the antigenic determinant recognized by this antibody involves protein. Further studies demonstrate that proteolytic digestion of ZP will destroy the antigenic determinant while glycosidic digestion of ZP has no effect on antibody binding. Although polyclonal antibodies to this glycoprotein inhibit sperm from binding to the zona pellucida, this monoclonal antibody does not affect sperm binding. None of the species-specific antibodies recognize ZP glycoproteins following 2D-PAGE. This is a property typical of antibodies directed against conformational antigenic determinants. The presence of common as well as unique zona antigenic determinants could explain why ZP proteins induce heteroantibodies which result in infertility while alloimmunization has no effect on fertility.     

HLA antibody responses in HLA class I transgenic mice

In a previous report we described how cross-immunizations of pairs of transgenic mice expressing different HLA class I antigens led to the production of antibodies directed exclusively at polymorphic epitopes. This was ascribed to self-tolerance of HLA that prevents immune responses to monomorphic epitopes and focuses responses on polymorphic ones. In the present report we extend our findings and demonstrate that immunizations of class I transgenic mice with HLA transfected mouse fibrosarcoma as well as with human lymphoblastoid cells also preferentially yield antibodies to polymorphic epitopes. This was the case whether or not immunizations were carried out across locus barriers [e.g., Tg (HLA-A *0201) or Tg (HLA-Cw*0301) transgenic mice immunized with HLA-B27 transfectants] or within the same locus [e.g., Tg (HLA-B*1302) transgenic mice immunized with HLA-B27 transfectants or B27-expressing lympho-blastoid cell]. Use of an extended immunization protocol with four or more booster injections favored antibodies of IgG isotype with affinities high enough to lyse normal peripheral blood lymphocytes (PBLs) in complement-dependent cytotoxicity assays and to immunoprecipitate HLA antigens. The specificities covered by the monoclonal antibodies (mAbs) could be either broad or narrow, depending on the genetic distance of the HLA antigens or alleles involved. For instance, a Tg(HLA-B*1302) transgenic mouse immunized with B27 produced both broad B7/B27-specific antibodies, Bw4-specific antibodies, and one antibody reacting with all B alleles except B13 and with some C alleles. On the other hand, a Tg(HLA-B*1302) transgenic mouse immunized with Bw47 transfectants responded narrowly with an antibody to Bw60 and Bw47. Thus it appears that by choosing appropriate recipient mice and closely related or more distant HLA antigens, antibodies of a programmed specificity can be generated. Address correspondence and offprint requests to: U. Hämmerling.     

Expression of an HLA-Bw6-related specificity by the HLA-Cw3 molecule

Radioimmunoassay of HLA-transformed mouse L cells expressing A3, A24, B7, or Cw3 HLA class I molecules with a set of monomorphic monoclonal antibodies distinguishes between A3–A24 and B7-Cw3 patterns of reactivity. Analyses with Bw6-specific monoclonal antibodies and a human alloantiserum demonstrate the expression by the HLA-Cw3 molecules of a Bw6 public specificity related to but not identical with that expressed by the HLA-B7 molecules. Exon-shuffling experiments and inhibition studies of monoclonal antibody cell-surface fixation indicate that similar parts of B7 and Cw3 molecules account for their serological cross-reactivity.Abbreviations used in this paper ₂-m beta-2 microglobulin - EBV Epstein-Barr virus - mAb monoclonal antibody - PBS-BSA phosphate-buffered saline supplemented with 0.2% bovine serum albumin - PBL peripheral blood lymphocyte - RIA radioimmunoassay     

IEF patterns of HLA-1313 antigens from Orientals and Caucasians

HLA-B 13 antigens were isolated from metabolically labeled cell extracts from Caucasian and Oriental donors by means of an HLA-B13-specific monoclonal antibody, SY1. Ethnic differences in B13 molecules were identified by one-dimensional isoelectric focusing in which the pI of desialated Oriental B13 molecules was found to be higher than that of Caucasians. An additional Caucasian variant pattern was detected by peptide mapping using limited proteolysis in sodium dodecyl sulfate analyzed by polyacrylamide gel electrophoresis. Dual allotypic determinants for B13 molecules were recognized by two HLA-B13-specific monoclonal antibodies, SY1 and TU110, as determined by their sensitivity to complement-dependent cell lysis. Whereas the SY1 target epitope was shared by both ethnic B13 molecules, the two ethnic B13 molecules carried different Tu110 target structures. The Caucasian variant molecules appear to carry altered allotypic determinants which are recognized by both SY1 and Tu110 antibodies. This study suggests that the HLA-1313 private structure may comprise two epitopes recognized by SY1 and Tü 110 antibodies, respectively, whose binding sites overlap. Present data also suggest that the private determinant was already present when the two racial groups diverged, and thus the mutations which gave rise to the variants may be of relatively recent origin.     

Recognition of two Dermatophagoides pteronyssinus-specific epitopes on antigen P1 by using monoclonal antibodies: binding to each epitope can be inhibited by serum from dust mite-allergic patients

Monoclonal antibodies were raised against Antigen P1, the major allergen of the house dust mite (Dermatophagoides pteronyssinus). The majority were Antigen P1 specific, isotype IgG1, and did not react with a comparable D. farinae allergen. These antibodies bound 38 to 50% of 125I Antigen P1 in antigen-binding assays (titer greater than or equal to 1/1,000,000), and the quantities of IgG antibody in ascites were 2 to 4 logs greater than those in polyclonal mouse antiserum or in serum from a mite-allergic patient. Two IgM antibodies showed weak binding to Antigen P1 but reacted strongly with D. pteronyssinus in enzyme immunoassay (titer greater than or equal to 1/100,000). Assessments of the specificity of the IgG antibodies by using two inhibition radioimmunoassays suggested that they were directed against two different epitopes. Antibodies 10B9 F6 and 5H8 C12 were purified by preparative isoelectric focusing (isoelectric points of pI 6.25 and 7.4, respectively) and radiolabeled with 125I. Cross-inhibition experiments, using ascites dilutions to inhibit binding of each radiolabeled antibody to Antigen P1, confirmed that these antibodies recognized two distinct epitopes. Analysis of antibodies from 39 clones/hybrids showed that the majority were directed against the same epitopes as either 10B9 F6 or 5H8 C12 (3 out of 39 [8%] and 29 out of 39 [74%], respectively). None of the monoclonal antibodies significantly inhibited (greater than 10%) human IgE binding to Antigen P1 in the radioallergosorbent test. However, 12 of 14 sera from mite allergic patients inhibited binding by the monoclonal antibodies. One serum from a mite-allergic patient inhibited binding of both 10B9 F6 and 5H8 C12 by greater than 85% and showed parallel inhibition curves. The results suggest that these monoclonal antibodies could be used to assay Antigen P1 in both D. pteronyssinus and house dust extracts. It should also be possible to use monoclonal antibodies in inhibition assays to define the antigenic/allergenic determinants recognized by human IgG and IgE antibodies on this mite allergen.     

Topographic antigenic determinants recognized by monoclonal antibodies on human choriogonadotropin beta-subunit

We describe a first attempt to study the antibody-combining sites recognized by monoclonal antibodies raised against the beta-subunit of human choriogonadotropin (hCG). Two groups of antibodies were first defined by their ability to recognize only the free beta-subunit or the free and combined subunit. Antibodies FBT-11 and FBT-11-L bind only to hCG beta-subunit but not to hCG, whereas antibodies FBT-10 and D1E8 bind to both the beta-subunit and the hormone. In both cases, the antigenic determinants were localized to the core of the protein (residues 1-112), indicating the weak immunogenicity of the specific carboxyl-terminal extension of hCG-beta. Nine synthetic peptides spanning different regions of hCG-beta and lutropin-beta were assessed for their capacity to inhibit antibody binding. A synthetic peptide inclusive of the NH2-terminal region (residues 1-7) of the hCG beta-subunit was found to inhibit binding to the radiolabeled subunit of a monoclonal antibody specific for free hCG-beta (FBT-11). Further delineation of the antigenic site recognized by this antibody provided evidence for the involvement of fragment 82-92. Moreover, monoclonal antibody FBT-11 inhibited the recombination of hCG-beta to hCG-alpha, indicating that its antigenic determinant might be located nearby or in the hCG-beta portion interacting with the alpha-subunit. Binding of monoclonal antibody FBT-10, corresponding to the second antigenic determinant, was weakly inhibited by fragment 82-105 and did not impair the recombination of the hCG beta-subunit to the hCG alpha-subunit. Its combining site appeared to be located in a region of the intact native choriogonadotropin present at the surface of the hormone-receptor complex.     

Clustering of antigenic determinants on H-2 molecules

The spatial relationship of individual antigenic determinants on H-2Kk and H-2Db molecules was investigated with seven different monoclonal anti-H-2Kk and seven anti-H-2Db antibodies. In these studies the binding of radiolabeled monoclonal anti-H-2 to target cells was competed by addition of various cold anti-H-2 antibodies. The results indicate that on both H-2Kk and H-2Db molecules the antigenic determinants are arranged in two spatially separated clusters. Thus, antibodies to determinants within a cluster show mutual inhibition of binding but do not block the binding of antibodies to the other cluster, and vice versa. Furthermore, in the case of H-2Db antigens it was observed that binding of antibodies to one cluster would considerably enhance the binding of antibodies to the other cluster. A preliminary Scatchard analysis indicated that the enhancing antibody did not alter the affinity of the radiolabeled antibody, but led to an increase of available binding sites on the cell membrane. In addition, binding inhibition studies revealed that the conventional private specificity H-2.2 of H-2Db consists of at least two independent sites on the molecule.     

Distribution of antigenic determinants recognized by three monoclonal antibodies (Q2/70, Q5/6 and Q5/13) on human Ia-like alloantigens and on their subunits

The distribution of antigenic determinants recognized by the anti-Ia-like antigen monoclonal antibodies (MoAb) Q2/70, Q5/6 and Q5/13 on molecules coded for by the DR locus and by non-DR loci was investigated using a binding assay with 125I-labeled Ia-like antigens isolated from four B lymphoid cell lines. The determinants reacting with the MoAb Q2/70 and Q5/13 are expressed on all DR alloantigens tested and on BR4X7 specificities, while those reacting with the MoAb Q5/6 are not detectable on DRw7 and BR4X7 molecules. None of the monoclonal antibodies reacted with DC1 molecules. The MoAb Q5/6 and Q5/13 reacted with the isolated beta subunit of the Ia-like antigenic complex, while the MoAb Q2/70 did not react with the isolated chains.     

Apolipoprotein A-I from normal human plasma: definition of three distinct antigenic determinants

We have prepared, selected and cloned four mouse hybridomas that secreted monoclonal antibodies against human plasma apolipoprotein A-I. These antibodies are all of the IgG-I subclass, and were named anti-A-I 6B8, 5G6, 3D4 and 5A6. We characterized the specificity of the antibodies, finding that all four of them reacted similarly, and with only the major proteins having the molecular weight and isoelectric focusing characteristics of apolipoprotein A-I. The antibodies reacted with all known charge-polymorphs of apolipoprotein A-I and pro apolipoprotein A-I. Thus, the polymorphs of apolipoprotein A-I are alike in that they all contain the antigenic sites of these four antibodies. In a solid-phase, antibody competition radioimmunoassay we found inhibition or enhancement of antibody binding to apolipoprotein A-I, according to the pair of antibodies tested. Antibodies 6B8, 5G6 and 3D4 were different from one another and reacted with different antigenic determinants, but 5A6 was similar to 3D4 and reacted at the same site. We compared the reactions of the four antibodies with CNBr-cleaved fragments of apolipoprotein A-I separated by polyacrylamide gel electrophoresis. We found three different patterns of reaction with the apolipoprotein A-I fragments; 6B8, 5G6 and 3D4 were different, but 5A6 resembled 3D4. Thus, the four antibodies reacted with at least three different antigenic sites in apolipoprotein A-I, which were present in different CNBr fragments of apolipoprotein A-I, but not on fragment 4 which forms the carboxy-terminal segment.     

Complexity of the supertypic HLA-DRw53 specificity: two distinct epitopes differentially expressed on one or all of the DR beta-chains depending on the HLA-DR allotype

The supertypic HLA-DRw53 specificity is associated with three allelic class II specificities defined by alloantisera: HLA-DR4, -DR7, and DRw9. The present study demonstrates the complexity of this supertypic DR specificity by comparing two DRw53-related determinants defined by the monoclonal antibodies PL3 and 109d6. For every HLA-DR4 cell line tested, both monoclonal antibodies were found to bind to the same subpopulation of DR molecules. This PL3+, 109d6+ DR subpopulation is also found on most, but not all, DR7+ cell lines with a beta-chain pattern that is identical to the beta-chain pattern of the PL3+, 109d6+ subpopulation on DR4 cell lines. However, some DR7+ cells which carry the HLA haplotype Bw57, DR7, DRw53, DQw3 were also found which completely lack the expression of the 109d6 determinant, but continue to express the PL3 determinant and some of the DRw53 determinants recognized by alloantisera. This results from the fact that the PL3 determinant is expressed on all of the DR molecules found on DR7 cells, including the distinct subpopulation of molecules that carry the HLA-DR7 determinant recognized by the monoclonal antibody SFR16-DR7. This PL3+, SFR16-DR7+ subpopulation does not carry the 109d6 determinant, demonstrating that the PL3 and 109d6 DRw53-related determinants are distinct and can be expressed on a different number of DR molecules, depending on the allotype of the cells. Blocking studies were also performed by using these monoclonal antibodies with alloreactive HLA-DR7-specific cytotoxic T cell clones. In these studies, the T cell-defined HLA-DR7 determinants were found to be carried by the same subpopulation of DR molecules recognized by the HLA-DR7-specific monoclonal antibody and not carried by the DR molecules recognized by 109d6. The DR7+ cell lines which do not express the 109d6 determinant also fail to express another supertypic determinant recognized by the monoclonal antibody IIIE3 carried on this molecule. Furthermore, no additional allelic forms of this unique DR beta-chain were found associated with the nonpolymorphic DR alpha-chain on these cells, suggesting that this DR beta-chain gene is not expressed. These cells also behave as homozygous typing cells for the Dw11 subtype of DR7 in HLA-D typing in the mixed lymphocyte culture assay. This suggests that the lack of expression of a specific class II gene may contribute additional genetic polymorphism within the known HLA-DR allotypes.     

Murine H-2Dd-reactive monoclonal antibodies recognize shared antigenic determinant(s) on human HLA-B7 or HLA-B27 molecules or both

We have evaluated the serological relationships between the murine H-2Dd and human HLA molecules using four H-2Dd-reactive monoclonal antibodies (mAbs) produced in the A.BY (KbIbDb) anti-A.TL (KsIkDd) combination. In the mouse, these reagents exhibited three distinct reactivity patterns: Dd, Ks, and H-2u (mAb 81.L); Dd, H-2p, and H-2u (mAb 81.R); and Dd, Kd, H-2p, H-2u, and H-2v (mAbs 97.G and 97.H). Sequential immunoprecipitation and cross-competitive mAb binding experiments revealed that these mAbs recognized determinants in two spatially distinct polymorphic domains on the H-2Dd molecule of B10.A(5R) cells (defined by mAbs 81.L and 81.R, 97.H, and 97.G, respectively). MAbs 81.R, 97.G, and 97.H, but not 81.L, also defined an HLA-linked polymorphism in the human, the main characteristics of which can be summarized as follows: (i) on B lymphoblastoid cell lines, mAbs 81.R and 97.H bound to cells expressing the HLA-B7, HL-B27 or Bw40 cross-reacting specificities, (ii) on peripheral blood lymphocyte (PBL) panel mAb 81.R exerted C dependent cytotoxicity to 118 of 400 cells tested, including almost all HLA-B7 or HLA-B27 cells or both (r: 0.952), (iii) the expression of the 81.R cross-reacting determinant segregated in an informative family with the parental haplotype carrying the HLA-B7 allele, and (iv) mAbs 81.R, 97.G, and 97.H recognized topologically related determinants on the same class I molecule(s) of the human B lymphoblastoid cells JY (HLA-A2,2, -B7,7). These data support the view that some, but not all H-2Dd allotopes have been conserved throughout evolution and are associated in the human with the HLA-B7, -B27 cross-reacting specificities.     

HLA-Bw22: a family of molecules with identity to HLA-B7 in the alpha 1-helix.

Various HLA-B molecules exhibit serologic cross-reactions with HLA-B7, including HLA-B27, B40, Bw42, and Bw22. Of this group, primary structures for the three serologic subdivisions of HLA-Bw22, HLA-Bw54, Bw55, and Bw56, have yet to be determined. Here, we describe the nucleotide sequences of five distinctive HLA-Bw22 alleles isolated from cells of different ethnic origins typed either for Bw54, Bw55, or Bw56. Heterogeneity in molecules typed as Bw55 and Bw56 was defined. The five HLA-Bw22 alleles form a closely related family that appears to have evolved by a series of simple gene conversion events, all of which alter the antigen recognition site of the encoded proteins. Of note, HLA-Bw54 is the product of a gene conversion between HLA-B and C alleles. All the Bw22 alleles encode an alpha 1-helix identical in amino acid sequence to that of HLA-B7 and Bw42, a feature almost certainly responsible for the serologic cross-reactivity of these molecules. Shared substitutions in the alpha 1-helix can also explain the cross-reactivity of Bw22 and B7 with B27. Patterns of amino acid substitution in the alpha 2-domain of Bw22 heavy chains correlate with certain antibody and T cell cross-reactivities, thereby implicating particular amino acids in their target epitopes.     

Biochemical and functional evidence that an MT3 supertypic determinant defined by a monoclonal antibody is carried on the DR molecule on HLA-DR7 cell lines

A cytotoxic monoclonal antibody, PL3, was produced by immunizing mice with a cell line homozygous for the HLA class II antigenic specificity DR7. The serologic specificity of PL3 was completely concordant with the MT3 supertypic specificity, which is tightly associated with HLA-DR4, -DR7, and -DRw9. This was confirmed by the finding that F(ab')2 fragments of PL3 blocked the cytotoxicity of anti-MT3 alloantisera. Although PL3 bound to each of the MT3-positive cell lines, it showed significantly weaker binding to HLA-DR4 and -DRw9 cells relative to -DR7 cells, both in titration and in quantitative absorption assays. This differential pattern of binding was not found for the polyclonal MT3 alloantisera, suggesting that the PL3 determinant may be one of several closely related determinants that comprise the MT3 allospecificity. To identify which of the subpopulations of class II molecules carry the PL3 determinant, several approaches have been used. F(ab')2 fragments of PL3 which block the anti-MT3 alloantisera were also tested with anti-MB2 and anti-DR7 sera. Binding of the PL3 F(ab')2 fragments to DR7 homozygous target cells had no effect on the anti-MB2 sera, but significantly enhanced the cytotoxic reactivity of some anti-DR7 sera. This finding suggested that the PL3 determinant is distinct from the DR7 determinant, but is carried on the same molecule. PL3 was also used in blocking studies with allocytotoxic T cell clones which only recognize DR7-positive cell lines. Binding of PL3 to the DR7-positive target cells was found to completely inhibit these T cell clones. Complete blocking was also found with a monoclonal antibody, PL8, which recognizes a monomorphic determinant found on the DR subpopulation of class II molecules. This finding suggested that the PL3 determinant is carried on the same molecule that carries these T cell-defined DR7 allodeterminants. In biochemical studies with DR7-positive cell lines, PL3 and PL8 were found to immunoprecipitate the same subpopulation of class II molecules recognized by other DR-specific antibodies, SG157 and TAL-1B5. Two-dimensional gel analysis demonstrated that the pattern of alpha- and beta-chains immunoprecipitated by PL3, PL8, and TAL-1B5 were identical. In sequential immunoprecipitation studies, both PL3 and TAL-1B5 were capable of removing the same DR subpopulation of molecules recognized by PL3, PL8, TAL-1B5, or SG157 while leaving the additional class II molecules (DS) recognized by SG171 on DR7 cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Topographical analysis of antigenic determinants on envelope glycoprotein V3 (E) of Japanese encephalitis virus, using monoclonal antibodies.

Ten monoclonal antibodies directed against envelope glycoprotein V3 (E) of Japanese encephalitis virus were obtained. They were characterized by hemagglutination inhibition (HI), neutralization, and enzyme-linked immunosorbent assay and divided into four types: flavivirus-cross-reactive HI and non-neutralizing antibody (group 1), subgroup-specific HI and non-neutralizing antibody (group 2), low HI and neutralizing antibody (group 3), and non-HI and neutralizing antibody (groups 4 and 5, respectively). Competitive binding assays were performed to analyze the topography of antigenic determinants by enzyme-linked immunosorbent assay. The results of the competitive binding assay separated non-HI and neutralizing antibody into groups 4 and 5, respectively, and demonstrated the existence of at least five distinct antigenic determinants on V3. The site of group 1 was distinct from any other site. The sites of groups 2 and 3 seemed to be located close together. Our results suggest the following relationship between HI and neutralization: (i) The HI sites are separated from the neutralization sites, and (ii) there are two distinct HI sites, one of which is flavivirus cross-reactive, the other subgroup specific.     

Structural and functional analysis of monomorphic determinants recognized by monoclonal antibodies reacting with the HLA class I alpha 3 domain.

To identify mAb reacting with the HLA class I alpha 3 domain, 14 mAb recognizing monomorphic determinants expressed on HLA-A, B, and C Ag or restricted to HLA-B Ag were screened in indirect immunofluorescence with mouse L cells expressing HLA-B7/H-2Kb chimeric Ag. mAb CR1S63, CR10-215, CR11-115, and W6/32 were found to react with the HLA class I alpha 3 domain in addition to the alpha 2 domain. mAb Q1/28 and TP25.99 were found to react only with the HLA class I alpha 3 domain. The determinants recognized by the six mAb were mapped on the HLA class I alpha 3 domain by indirect immunofluorescence staining of L cells expressing H-2Kb Ag containing different segments of the HLA-B7 alpha 3 domain chimerized with the H-2Kb alpha 3 domain. mAb TP25.99 reacts with chimeric Ag containing the HLA-B7 184 to 199 stretch, mAb CR10-215 and CR11-115 react with chimeric Ag containing the HLA-B7 184 to 246 stretch, mAb CR1S63 and Q1/28 react with chimeric Ag containing the HLA-B7 184 to 256 stretch, and mAb W6/32 reacts with chimeric Ag containing the whole HLA-B7 alpha 3 domain. Functional analysis using human CD8 alpha-bearing mouse H-2Kb-specific T cell hybridoma cells (HTB-Leu2) showed that only mAb TP25.99 inhibited IL-2 production by HTB-Leu2 cells stimulated with L cells expressing KbKbB7 Ag. This inhibition may occur because of the spatial proximity of the determinant defined by mAb TP25.99 to the CD8 alpha binding loop and/or because of change(s) in the conformation of the CD8 alpha binding loop induced by the binding of mAb TP25.99 to the HLA class I molecule. Furthermore, mAb TP25.99 inhibited the cytotoxicity of CD8-dependent and CD8-independent CTL clones. These results indicate that mAb TP25.99 has unique specificity and functional characteristics. Therefore it represents a valuable probe to characterize the role of the HLA class I alpha 3 domain in immunologic phenomena.     

Antigenic determinants on human choriogonadotropin alpha-subunit. II. Immunochemical mapping by a monoclonal antipeptide antibody

In order to study antigenic site(s) present in the carboxyl-terminal part of the alpha-subunit of human choriogonadotropin (hCG-alpha), we attempted to produce site-specific antibodies directed against a 34-residue synthetic peptide analogous to region 59-92 of hCG-alpha. From a fusion experiment performed with a mouse injected with hCG-alpha-(59-92)-peptide conjugated to tetanus toxoid as immunogen, we selected a monoclonal antipeptide antibody (designated FA36) which has high binding activity for 125I-hCG-alpha but not for 125I-hCG in a radioimmunoassay. This antibody is of the IgG1 subclass and displays an affinity constant for 125I-hCG-alpha of 3.1 x 10(8) M-1. Hapten inhibition experiments performed by either radioimmunoassay or enzyme-linked immunosorbent assay with synthetic peptides spanning different portions of the region (59-92) demonstrated that the binding site of FA36 resides on (minimally) the six COOH-terminal amino acids of hCG-alpha, namely Cys-Tyr-Tyr-His-Lys-Ser, and that FA36 binds preferentially to peptides containing a carboxyl group on the COOH-terminal residue. Monoclonal immunoradiometric assays were established to determine the location of antigenic regions recognized by FA36, by antibody AHT20 (which binds only to hCG-alpha), and by antibody HT13 (which binds to both hCG and hCG-alpha). FA36 has the capacity to bind to hCG-alpha bound to either AHT20 or HT13, demonstrating that both AHT20 and HT13 antibodies are directed against antigenic regions distinct from the epitope of FA36. Monoclonal immunoradiometric assays were also carried out to study the binding of FA36 to hCG, the ovine and equine lutropin alpha-subunit, or hCG-alpha minus the 5 COOH-terminal residues (hCG-alpha core). Whereas significant binding of 125I-FA36 was observed with the ovine lutropin alpha-subunit, no binding was found with the equine lutropin alpha-subunit. As expected, FA36 did not bind to hCG-alpha core. Binding was also not detected with hCG, confirming that FA36 is specific for free hCG-alpha and that the COOH-terminal part of hCG-alpha is either weakly or (more likely) not at all accessible in the alpha/beta-dimer for antibody binding. Finally, immunoblots performed on hCG-alpha-(59-62)-peptide and various denatured alpha-subunits indicated that, with the exception of the equine lutropin alpha-subunit, FA36 detected various denatured alpha-subunits and particularly the alpha-subunit of carp gonadotropin-thyrotropin. This latter observation suggests a high degree of homology between the COOH-terminal regions of the alpha-subunits of fish gonadotropin and analogous mammalian hormones.(ABSTRACT TRUNCATED AT 400 WORDS)