Anti-HLA-E mAb 3D12 mimics MEM-E/02 in binding to HLA-B and HLA-C alleles: Web-tools validate the immunogenic epitopes of HLA-E recognized by the antibodies

HLA-E shares several peptide sequences with HLA-class Ia molecules. Therefore, anti-HLA-E antibodies that recognize the shared sequences may bind to HLA-class Ia alleles. This hypothesis was validated with a murine anti-HLA-E monoclonal antibody (mAb) MEM-E/02, which reacted with microbeads coated with several HLA-B and HLA-C antigens. In this report, the hypothesis was reexamined with another mAb 3D12, considered to be specific for HLA-E. The antibody binding is evaluated by measuring mean fluorescence index [MFI] with Luminex Multiplex Flow-Cytometric technology. The peptide-inhibition experiments are carried out with synthetic shared peptides, most prevalent to HLA-E and HLA-Ia alleles. The results showed that mAb 3D12 simulated MEM-E/02 in recognizing several HLA-B and HLA-C antigens. Both 3D12 and MEM-E/02 did not bind to HLA-A, HLA-F and HLA-G molecules. As observed with MEM-E/02, binding of 3D12 to HLA-E is inhibited by the peptides sequences ¹¹⁵QFAYDGKDY¹²³ and ¹³⁷DTAAQI¹⁴². Decrease in binding of mAb 3D12 to HLA class Ia, after heat treatment of antigen coated microbeads, supports the contention that the epitope may be located at the outside of the “thermodynamically stable” α-helix conformations of HLA-E. Several sequence and structure-based web-tools were employed to validate the discontinuous epitopes recognized by the mAbs. The scores obtained by these web-tools distinguished the shared peptide sequences that inhibited the mAb binding to HLA-E. Furthermore, ElliPro web tool points out that both mAbs recognize the conformational discontinuous epitopes (the shared inhibitory peptide sequences) in the secondary structure of the HLA-E molecule. The study favors the contention that the domain of the shared inhibitory peptide sequences may be the most immunogenic site of HLA-E molecule. It also postulates and clarifies that amino acid substitution on or near the binding domains may account for the lack of cross reactivity of 3D12 and MEM-E/02 with HLA-A, HLA-F and HLA-G molecules.     

Human monoclonal HLA antibodies reveal interspecies crossreactive swine MHC class I epitopes relevant for xenotransplantation

Crossreactivity of anti-HLA antibodies with SLA alleles may limit the use of pig xenografts in some highly sensitized patients. An understanding of the molecular basis for this crossreactivity may allow better selection of xenograft donors. We have tested 68 human monoclonal HLA class I antibodies (mAbs) for reactivity with pig lymphocytes from SLA defined pigs and found nine to be crossreactive. Eight of nine were broadly HLA reactive IgM-mAbs. The putative HLA epitopes for seven mAbs. were conserved in the aminoacid sequence of the SLA alleles studied. The lack of reactivity of a large number of mAbs largely correlated with the absence of the putative epitopes in the SLA alleles studied. We conclude that most patients with anti-HLA class I antibodies should be able to find pig donors lacking SLA antigens that cross react with their antibodies and that many of the crossreacting epitopes can be defined by analysis of shared epitopes in the aminoacid sequence of human and pig MHC antigens.     

Two cytotoxic human-human hybridoma antibodies to HLA: TrAH10 (anti A3.1) and TrAG2 (anti B7,Bw42)

Two cytotoxic human-human hybridoma IgM antibodies to HLA were generated by EBV transformation of PBMC from multiparous women and fusion of EBV transformed cells with the human fusion partners KR4 or KR12. Both mAbs required the sensitive immunomagnetic cytotoxicity method to display killing of freshly prepared PBMC. One mAb (TrAH10) was specific for HLA-A3. Strikingly, TrAH10 reacted much more strongly with lymphoblastoid cell lines of HLA-A3.1 than of the rare variant HLA-A3.2, previously detected by cytotoxic T cells. Thus, in the microcytotoxicity test, the titer of concentrated TrAH10 was approximately 2000 times higher for A3.1 as compared to A3.2, and a clear difference was also observed in radioimmunoassay. Since the two HLA-A3 variants differ by only two amino acids at positions 152 and 156 of the alpha 2-domain's alpha-helix, the epitopes defined by the mAb TrAH10 and HLA-A3.1 specific cytotoxic T cells must be closely related. The observations with TrAH10 suggest that the HLA polymorphism detected by human mAbs may turn out to be as extensive as the T-cell defined HLA polymorphism. The other mAb (TrAG2) bound B7 and Bw42 with equal strength, and in addition bound weakly to some cells that were Bw22 or B39. Magnetic polymerbeads coated with affinity purified human mAbs TrAH10 or TrAG2 formed rosettes with EBV transformed cells carrying relevant HLA antigens; however, rosette formation with freshly isolated PBMC was very weak and unsuitable as a typing assay.     

Structural aspects of human leukocyte antigen class I epitopes detected by human monoclonal antibodies

This study addresses the concept that human leukocyte antigen (HLA) class I–specific alloantibodies are specific for epitopes that correspond to HLAMatchmaker-defined eplets. Eplets are essential parts of so-called structural epitopes that make contact with the 6 complementarity determining regions of an antibody. From published molecular models of crystallized protein antigen–antibody complexes, we have calculated that contact residues on structural HLA epitopes should reside within a 15-Å radius of a mismatched eplet. This study addresses the structural basis of high-frequency HLA class I epitopes reacting with human monoclonal antibodies (mAbs) derived from women sensitized during pregnancy. All mAbs were tested in Luminex assays with single HLA allele panels. The HLAMatchmaker algorithm was used to determine their specificity in context with eplet sharing between the immunizing allele and antibody-reactive alleles. To assess the autoreactive B cell origin of these antibodies, we have applied the recently developed nonself–self paradigm of epitope immunogenicity to analyze residue differences between the immunizer and the alleles of the antibody producer. A total of 9 mAbs were specific for epitopes associated with the 41T, 80NRG, 163LW, 69AA, or 80ERILR eplets. In each case, the immunizing allele had within 15 Å of the mismatched eplet, no residue differences with 1 of the alleles of the antibody producer. This observation is consistent with the concept that these mAbs originated from B cells with self HLA immunoglobulin receptors. Eplet-carrying alleles exhibited different levels of reactivity, which, when compared with the immunizing allele, ranged from high to intermediate to very low. In many cases, lower reactivities were associated with differences from self to nonself residues in surface locations within 15 Å of the specific eplet. Apparently, such locations may serve as critical contact sites for the antibody. In other cases, other residue differences did not appear to affect binding with the antibody, suggesting that these locations do not play a major role in antibody binding. For these mAbs we did not obtain convincing evidence that residue differences in hidden positions below the molecular surface had significant effects on antibody binding. These findings have increased our understanding of the structural basis of the immunogenicity and antigenicity of HLA class I epitopes and provide a basis for interpreting HLA antibody reactivity patterns in Luminex assays with single alleles.     

Antigenicity of HLA-A2 and HLA-B7. Loss and gain of serologic determinants induced by site-specific mutagenesis at residues 62 to 80.

The contribution of the hypervariable region spanning amino acid residues 62 to 80 to the serologic determinants of HLA-A2 and HLA-B7 has been examined by site-directed mutagenesis. Three HLA-A2 mutants, having changes as in HLA-B7 at positions 62, 76, and at the complete 65-to-80 segment, respectively, were obtained and expressed on class I HLA-deficient human cells upon transfection. The reactivity of 19 monoclonal antibodies (mAbs) against both broad public and allospecific determinants on HLA-A2 and HLA-B7 was analyzed. The results indicate that: (1) the change at residue 62 abrogated recognition of the corresponding HLA-A2 mutant by mAb MA2.1 (anti-A2 + B17); (2) the change at residue 76 did not effect any of the determinants analyzed, although its side chain is easily accessible at the surface of the molecule; (3) the replacement of the whole 65-to-80 segment in HLA-A2 by that from HLA-B7 abrogated recognition by MA2.1 and by 108-2C5, a mAb recognizing a public determinant from the HLA-A locus. Such replacement led to gaining the determinants recognized by mAbs GS145.2 (anti-B7 + B27) and SFR8-B6 (anti-Bw6); and (4) the HLA-A2-reactive mAbs whose reactivity was known to be abrogated by changes in alpha 2 were unaffected by the changes introduced in alpha 1, underlining the frequent segregation of serologic determinants on class I antigens to single domains.     

Structural aspects of HLA class I epitopes reacting with human monoclonal antibodies in Ig-binding,C1q-binding and lymphocytotoxicity assays

This study addresses the reactivity patterns of human cytotoxic HLA class I epitope-specific monoclonal antibodies in Ig-binding and complement component C1q-binding Luminex assays in comparison with complement-dependent lymphocytotoxicity data reported at the 13th International HLA Workshop. Some monoclonal antibodies reacted similarly with epitope-carrying alleles in all three assays but others showed different reactivity patterns. These reactivity differences were analyzed with HLAMatchmaker and we incorporated the concept that eplets are essential parts of structural epitopes which can contact the six Complementarity Determining Regions (CDRs) of antibody. The data show that technique-dependent reactivity patterns are associated with distinct differences between polymorphic amino acid configurations on eplet-defined structural epitopes.     

HLA class I epitopes: recognition of binding sites by mAbs or eluted alloantibody confirmed with single recombinant antigens

Development of beads coated with single recombinant HLA antigens has permitted the confirmation and further definition of HLA class I epitopes. In this study, monoclonal antibodies (mAbs) or alloantibodies eluted from recombinant cell lines were tested for reactivity with Luminex beads individually coated with 79 recombinant HLA class I single antigen (rHLA SA). Published amino acid sequences were used to map epitopes common to sets of antigens reactive with each antibody. While several epitopes have already been demonstrated, this study confirmed them by adsorption of allosera with transfectants or SA beads having a single HLA antigen and specific binding of the eluted antibody on SA beads. The allosera and mAbs used in this study recognized a total of at least 58 HLA class I epitopes, as demonstrated by their different adsorption/reactivity patterns. Of these, 25 epitopes were characterized by a single unique common amino acid, 30 shared 2 signature amino acids in close proximity, and 3 epitopes involved 3 specific amino acids in a non-linear sequence. Since these epitopes may be targets for antibody-mediated allograft rejection, epitope analysis should complement HLA and CREG assignment for defining complex antibodies and identifying suitable donors for highly sensitized transplant patients.     

Epitope-specificities of HLA antibodies: The effect of epitope structure on Luminex technique-dependent antibody reactivity

The search of HLA antibodies is currently more accessible by solid-phase techniques (Luminex) in the immunized patients leading to an expansion of the antibody patterns. The aim of this study was to investigate low median fluorescence intensity value in unexpected reactivity patterns. Here, we performed HLAMatchmaker analyses to evaluate the potential functional epitopes that can elicit HLA-specific alloantibody responses in a pregnancy-sensitized woman with an epitope defined by the 82LR. Surprisingly, in according to the registry of HLA epitopes, we found that 82LR epitope covered all allelic specificities of our unexpected antibody patterns, shared between Bw4-positive HLA-B antigen and HLA-A23, -A24, -A25 and -A32. This finding is consistent with the verification of HLA ABC epitope recorded in the website-based HLA Epitope Registry and addresses the importance of determining HLA antibody epitope-specificities on Luminex technique-dependent antibody reactivity.     

Selective monomorphic and polymorphic HLA class I antigenic determinant loss in surgically removed melanoma lesions

The analysis of human leukocyte antigen (HLA) class I allospecificity expression in malignant lesions has been hampered by the limited availability of HLA class I allospecificity-specific monoclonal antibodies (mAbs) which stain tissues in immunohistochemical (IHC) reactions. During the 12th International Histocompatibility Workshop, the HLA and cancer component made available a panel of mAbs capable of detecting monomorphic, locus- and allo-specific HLA class I antigenic determinants in surgically removed frozen tissue sections by IHC staining. In the present study, we have utilized this panel of mAbs to analyze the expression of HLA class I allospecificities in 33 primary and in 11 metastatic lesions surgically removed from HLA-typed patients with malignant melanoma, as this information contributes to determine the extent of HLA class I antigen abnormalities in melanoma lesions. HLA class I antigens were downregulated in six (18.2%) of the primary lesions and in six (54.5%) of the metastatic lesions. Selective loss of HLA-A and HLA-B antigens was detected in two (6.1%) and in one (3.0%), respectively, of the primary lesions, but in none of the metastases. HLA-A and HLA-B antigens were downregulated in three (9.1%) and four (36.4%) of the primary and metastatic lesions, respectively. Selective loss of one or more HLA class I allospecificities was found in 10 (33.0%) and two (18.0%) of the 33 primary and 11 metastatic melanoma lesions analyzed, respectively. HLA class I antigen abnormalities were present in 16 (48.5%) of the 33 primary lesions analyzed (i.e. six lesions demonstrating abnormal reactivity with HLA class I monomorphic-specific mAb, two lesions demonstrating selective abnormal reactivity with HLA-B locus-specific mAb, one lesion demonstrating selective abnormal reactivity with HLA-A and HLA-B locus-specific mAbs, and seven lesions demonstrating selective abnormal reactivity with HLA class I allele-specific mAb). Furthermore, HLA class I antigen abnormalities were present in nine (81.8%) of the 11 metastatic lesions analyzed (i.e. six lesions demonstrating abnormal reactivity with HLA class I monomorphic-specific mAb, one lesion demonstrating selective abnormal reactivity with HLA-A locus-specific mAb, and two lesions demonstrating selective abnormal reactivity with HLA class I allele-specific mAb). It cannot be ruled out that the frequency of HLA class I allospecificity abnormalities is higher, as the expression of several HLA class I allospecificities could not be investigated because of the lack of appropriate probes. The frequency of HLA class I antigen defects in primary lesions was significantly correlated with primary lesion thickness, an important prognostic marker in melanoma, arguing for a potential clinical significance of HLA class I antigen abnormalities in melanoma. In conclusion, the results of the present study (i) demonstrate that the frequency of HLA class I allospecificity abnormalities in primary melanoma lesions is markedly higher than that of total HLA class I antigen downregulation described in the literature; (ii) corroborate our previous findings that staining of melanoma lesions with mAb to monomorphic determinants of HLA class I antigens does not detect selective HLA class I allospecificity loss; and (iii) demonstrate for the first time selective loss of antigenic determinants expressed on HLA class I molecules in melanoma lesions. The latter finding indicates that at least two mAbs recognizing distinct antigenic determinants on the HLA molecule being investigated should be used for IHC staining of tissue sections in order to prove that lack of immunostaining reflects actual loss of the corresponding HLA molecule and not selective loss of antigenic determinants.     

Production of two human hybridomas secreting antibodies to HLA-DRw11 and--DRw8+w12 specificities.

In this study we describe the production of two human monoclonal antibodies (mAbs) HMP12 and HMP14, that recognize polymorphic HLA-DR specificities. These mAbs have been produced by hybridization of antibody-secreting Epstein-Barr virus-transformed cells with SHM-D33 human-mouse heteromyeloma. By microcytotoxicity assay HMP12 mAb was found to react with all DRw11-positive cells and HMP14 mAb with all cells bearing the DRw8 or the DRw12 specificity. Cytotoxic activity of HMP14 was completely removed after absorption with DRw8- or DRw12-positive cells and unaffected by absorption with cells carrying different DR specificities. The HLA specificity was further analyzed by cytofluorometry on mouse transfectant cells. The reactivity of the two mAbs was correlated with the presence of a particular polymorphic amino acid residue in the DR beta chain and by this approach the epitopes possibly involved in the antibody binding sites were predicted.     

HLA epitopes – Empirically defined as conformational amino acids sequences of the HLA antigen and are likely to be part of the binding sites of anti-HLA antibodies

Antibodies against HLA antigens are ubiquitous in the sera of transplant patients. Analysis of anti-HLA antibodies specificity has gone through a long history of development using assays like agglutination and lymphocytotoxicity, which utilize lymphocytes, and flow cytometry, which utilize multiplex beads coupled with single antigens. Hundreds of HLA antigens are identified to date, and the realization that antibody reactivity against the antigens is multispecific presented difficulties in accurately defining antibody specificity. Although Cross Reacting Groups (CREG), describing cross reactivity among HLA antigens, were helpful with determining specificity, they proved to be inadequate for the highly sensitized patients. Amino acid sequencing and three-dimensional modeling of the HLA molecules significantly advanced our understating of the HLA antigens and their epitopes. Although sensitive assays for antibody testing advanced analysis, they unmasked additional specificities undetectable by traditional methods, and the presence of naturally occurring anti-HLA antibodies in sera further complicated analysis and underscored the need to understand antibody reactivity and their epitopes. Hundreds of HLA class-I and class-II epitopes were defined by the Tekasaki and Duquesnoy groups and their usefulness in organ transplants were further advanced by a great number of transplant centers. Alloantibody specificities, CREGs, and nondonor specific antigens (NDSA) are now explained by public epitopes     

Suppression of allo‐human leucocyte antigen (HLA) antibodies secreted by B memory cells in vitro: intravenous immunoglobulin (IVIg) versus a monoclonal anti‐HLA‐E IgG that mimics HLA‐I reactivities of IVIg

B memory cells remain in circulation and secrete alloantibodies without antigen exposure > 20 years after alloimmunization postpartum or by transplantation. These long‐lived B cells are resistant to cytostatic drugs. Therapeutically, intravenous immunoglobulin (IVIg) is administered to reduce allo‐human leucocyte antigen (HLA) antibodies pre‐ and post‐transplantation, but the mechanism of reduction remains unclear. Recently, we reported that IVIg reacts with several HLA‐I alleles and the HLA reactivity of IVIg is lost after its HLA‐E reactivity is adsorbed out. Therefore, we have generated an anti‐HLA‐E monoclonal antibody that mimics the HLA‐reactivity of IVIg to investigate whether this antibody suppresses IgG secretion, as does IVIg. B cells were purified from the blood of a woman in whose blood the B memory cells remained without antigen exposure > 20 years after postpartum alloimmunization. The B cells were stimulated with cytokines using a well‐defined culture system. The anti‐HLA‐E monoclonal antibody (mAb) significantly suppressed the allo‐HLA class‐II IgG produced by the B cells, and that this suppression was far superior to that by IVIg. These findings were confirmed with HLA‐I antibody secreted by the immortalized B cell line, developed from the blood of another alloimmunized woman. The binding affinity of the anti‐HLA‐E mAb for peptide sequences shared (i.e. shared epitopes) between HLA‐E and other β2‐microglobulin‐free HLA heavy chains (open conformers) on the cell surface of B cells may act as a ligand and signal suppression of IgG production of activated B memory cells. We propose that anti‐HLA‐E monoclonal antibody may also be useful to suppress allo‐HLA IgG production in vivo.     

Rapid assessment of the antigenic integrity of tetrameric HLA complexes by human monoclonal HLA antibodies

The ability of tetrameric major histocompatibility complex (MHC) class I-peptide complexes (tetramers) to detect antigen-specific T lymphocyte responses has yielded significant information about the generation of in vivo immunity in numerous antigenic systems. Here we present a novel method for rapid validation of tetrameric HLA molecules based on the presence of allodeterminants. Human monoclonal antibodies (mAbs) recognizing polymorphic determinants on HLA class I were immobilized on polystyrene microparticles and used to probe the structural integrity of tetrameric HLA class I molecules by flow cytometry. A total of 22 tetramers, based on HLA-A1, A2, A3, A24, B7 and B8 were reactive with their counterpart mAbs, thus confirming their antigenic integrity. A positive outcome of this mAb test ensures that tetrameric HLA class I can be used with greater confidence in subsequent functional assays.     

Arizona cypress (Cupressus arizoniea) pollen allergens. Identification of crossreactive periodate-resistant and -sensitive epitopes with monoclonal antibodies

Species of the Cupressaceae family are a worldwide cause of respiratory allergies. We used monoclonal antibodies (mAbs) to investigate the presence and the nature of cross-reacting epitopes shared by various components within Cupressus arizoniea pollen extract (CaE) or by CaE and pollen extract from C. sempervirens (CsE). mAbs were produced in mice immunized with whole CaE (4A6 and 5E6) or with the major allergen components (2D5). Their reactivity was investigated by ELISA and immunoblotting before and after CaE periodate treatment. Cross-reactivity was evaluated by ELISA inhibition and immunoblotting. mAbs 2D5 and 4A6 recognized periodate-resistant epitopes, whereas the mAb 5E6 reacted with a periodate-sensitive determinant. The former mAbs recognized epitopes present on CaE major allergen and also shared by other components. mAb 5E6 showed a spread reactivity on CaE, with exclusion of the major allergen. When the three mAbs were tested with CsE, a restricted pattern of reactivity to mAbs 2D5 and 4A6 was obtained, whereas mAb 5E6 maintained a spread reactivity. The CaE major allergen is represented by two components recognized by human IgE and sharing common epitopes, as proven by mAbs reactivity. The use of these mAbs demonstrates that cross-reactivity within CaE components and between CaE and CsE is due to the presence of periodate-sensitive as well as -resistant epitopes.     

A unique murine monoclonal antibody recognizing HLA-B53, B37, B51, B52, +/-B44.

Monoclonal antibodies have played an important role in studying the biochemistry of the HLA-Class I molecules. Some murine anti-HLA mAbs can identify configurations of HLA epitopes that have never been reported in human allosera. One of these configurations is identified by an IgM mAb designated as: BHA-1441. This antibody was produced using a lymphoblastoid cell line typed as: A*02, A*25; B*38, B*4402/4405; C*0501, C*07, BW4, as the immunogen. A lymphocytotoxicity test of this mAb over a panel of 109 frozen, 452 fresh and, later, 44 DNA typed T cells revealed its specificity as B53, 37, 51, 52, +/- 44. All of the antigens recognized by this mAb share the Bw4 motif at positions 81-83, except for the HLA-B37, which shares only 82L and 83R. Furthermore, while B37 and B44 cross-react due to the aspartic acid (D) substitution at position 156, the reactivity with B53, B5 (51,52), B37 and 60% of B44 cells, makes it unlikely that the target epitope could be due only to the primary amino-acid sequence. The antibody-binding site might involve changes in tertiary structure and peptides bound by the MHC. BHA-1441 is an interesting tool to study and type the HLA-B53 antigen and its cross-reactive epitopes.     

Identification of the amino acid residues contributing to monoclonal antibody-defined DQw1 epitopes.

The reactivity of monoclonal antibodies (mAbs) R1, S1, and S5, shown previously to recognize polymorphic epitopes on HLA-DQ molecules, have been found to correlate with the presence of certain DQB1 alleles. mAb S5 reacts with cells expressing DQB1*0503, 0601, 0602, 0603, or 0604 alleles while R1 and S1 react with all DQB1 alleles except *0201 and 0301. In the case of R1 and S1, sequence comparison of these chains suggests the involvement of residues 45-47 (GVY) in formation of the epitopes. This prediction has been confirmed by showing that a G----E mutation in position 45 of the DQB1*0302 gene eliminates binding of both mAbs.     

Monoclonal antibodies to HLA‐E bind epitopes carried by unfolded β2m‐free heavy chains

Since HLA‐E heavy chains accumulate free of their light β₂‐microglobulin (β₂m) subunit, raising mAbs to folded HLA‐E heterodimers has been difficult, and mAb characterization has been controversial. Herein, mAb W6/32 and 5 HLA‐E‐restricted mAbs (MEM‐E/02, MEM‐E/07, MEM‐E/08, DT9, and 3D12) were tested on denatured, acid‐treated, and natively folded (both β₂m‐associated and β₂m‐free) HLA‐E molecules. Four distinct conformations were detected, including unusual, partially folded (and yet β₂m‐free) heavy chains reactive with mAb DT9. In contrast with previous studies, epitope mapping and substitution scan on thousands of overlapping peptides printed on microchips revealed that mAbs MEM‐E/02, MEM‐E/07, and MEM‐E/08 bind three distinct α1 and α2 domain epitopes. All three epitopes are linear since they span just 4–6 residues and are “hidden” in folded HLA‐E heterodimers. They contain at least one HLA‐E‐specific residue that cannot be replaced by single substitutions with polymorphic HLA‐A, HLA‐B, HLA‐C, HLA‐F, and HLA‐G residues. Finally, also the MEM‐E/02 and 3D12 epitopes are spatially distinct. In summary, HLA‐E‐specific residues are dominantly immunogenic, but only when heavy chains are locally unfolded. Consequently, the available mAbs fail to selectively bind conformed HLA‐E heterodimers, and HLA‐E expression may have been inaccurately assessed in some previous oncology, reproductive immunology, virology, and transplantation studies.     

Variant specific epitopes of Giardia lamblia.

Giardia lamblia undergoes surface antigenic variation. The capability of different isolates to express certain epitopes on the surfaces of trophozoites from different isolates and clones was determined using 4 surface-reacting monoclonal antibodies (mAbs) to variants derived from WB or WB-like Giardia (mAbs 6E7, 5C1, and 3F6) and GS/M (mAb G10/4). Of 28 isolates, 11 possessed trophozoites reactive with mAbs 6E7, 5C1 and 3F6, 6 with mAb 3F6, 2 with Mab G10/4, 1 with mAb 6E7, and 8 showed no reactivity as determined by direct or indirect immunofluorescence. Newly established clones from different isolates generated small numbers of reactive trophozoites similar to their parents. Only one epitope was found on any single trophozoite. Southern blots hybridized to a probe encoding for the epitope recognized by mAb 6E7 revealed that the inability to express the antigen in most isolates was due to lack of the gene. Analysis of the surface antigens of mAb 6E7 reactive clones from 3 isolates revealed that mAb 6E7 reacted with surface antigens of different molecular masses.     

Monoclonal antibodies to a CD4 peptide derivative which includes the region corresponding to an immunoglobulin CDR3: evidence of the involvement of pre-CDR3-related region in HIV-1 and host cell interaction.

A CD4 peptide of amino acid residues 68-130 [CD4(68-130)], which had the capacities to inhibit HIV-1 replication and HIV-1-induced syncytium formation, was used as an immunogen for the preparation of mAb. The mAbs prepared were classified into at least five types (I-V) in terms of their recognition sites by ELISA using various kinds of smaller CD4 peptides. Among them, the type I mAb no. 35 recognizing amino acid residues 72-84, which lies just before the region corresponding to an immunoglobulin third complementarity-determining region (CDR3), showed the strongest effects in reducing both HIV-1 infection and HIV-1-induced syncytium formation, although a large amount of no. 35 mAb was necessary to reduce such HIV-1 activities compared with those of anti-Leu-3a and OKT4A mAbs which recognize CD4 epitopes near a portion corresponding to an immunoglobulin CDR2. Western blot analysis showed that the reactivities of CD4 molecule in CD4-positive cells or sCD4 molecule with types I-V mAbs were stronger than that with anti-Leu-3a mAb. Flow cytometry showed that no. 35 mAb was faintly reactive with native CD4 molecule on cell surface at the concn showing the inhibitory effects on HIV-1 infection and syncytium formation. In addition, a smaller peptide CD4(66-92), one of the good epitope peptides for no. 35 mAb, also showed strong inhibitory effect on HIV-1 infection as well as a weaker inhibitory effect on syncytium formation. These results suggest that, in addition to the CD4 CDR2-related region, the pre-CDR3-related region is also involved in the early events of the interactions between the host cell and HIV-1.