Serological and molecular characterization of mouse anti-idiotypic monoclonal antibodies elicited with the syngeneic anti-HLA-A2,28 monoclonal antibody CR11-351

The molecular basis of the differential specificity of seven mouse anti-id mAb elicited with the syngeneic anti-HLA-A2,28 mAb CR11-351 was analyzed by comparing their specificity with their heavy and light chain variable region sequences. Of the six mAb recognizing idiotopes within the antigen combining site of mAb CR11-351, mAb T10-352, T10-440 and T10-505 recognize the same (or spatially close) idiotope(s) since they cross-inhibit each other in their binding to mAb CR11-351 and elicit syngeneic anti-anti-id antibodies with similar specificity. On the other hand, mAb T10-421, T10-649 and T10-938 appear to recognize spatially close but distinct idiotopes since they cross-inhibit each other, but elicit anti-anti-id antibodies which inhibit only the binding of the respective immunizing anti-id mAb to mAb CR11-351. mAb T8-203 is the only anti-id mAb which recognizes an idiotope outside the antigen combining site of mAb CR11-351 since it does not inhibit the binding of the latter to target cells and binds to mAb CR11-351 coated B lymphoid cells. In addition, mAb T8-203 defines an idiotope which is shared by seven anti-HLA mAb, while the remaining six anti-id mAb recognize idiotopes which are not detectable on the panel of anti-HLA mAb. mAb T10-352, T10-440 and T10-505 are highly homologous in their VH and VL regions and in their V(D)J junctions suggesting that they may be clonally related. On the other hand, mAb T8-203, T10-649 and T10-938 share some degree of homology in their VH region as all of them use J558 VH genes but differ considerably in their VL regions. Finally, mAb T10-421 is the most unrelated mAb as it utilizes VH, D, JH, VK and JK gene segments different from those of all the other anti-id mAb. These findings indicate that in the HLA-A antigenic system defined by mAb CR11-351 the main mechanism underlying the differential target specificity of syngeneic anti-id mAb is the combinatorial diversity together with the differential pairing of heavy and light chains.     

Recognition of HLA-DR1/DRB1*0101 molecules presenting HLA-A2 derived peptides by a human recombinant antibody, Fab-5 A1

MHC molecules present peptides in their binding groove to T-cell receptors inducing proliferation or cytotoxicity of alloreactive T cells. A previously generated human monoclonal antibody (mAb) UL-5 A1, recognizing a conformational epitope formed by HLA DR1/DRB1*0101 molecules and HLA-A2 derived peptides, demonstrates T-cell-like recognition of the peptide/MHC complex (PMC). To study the genes of the antigen binding region, the nucleotide sequences of the rearranged genes in the variable regions of UL-5 A1 were determined and the V-gene usage (VH3, V lambda 2) was identified by comparison with published germlines. The genes encoding heavy (Fd) and light (L) chains of UL-5 A1 were linked and expressed in a bacterial system. Specificity of the recombinant Fab-5 A1 was determined with HLA-typed LCLs by flow cytometric analysis. As demonstrated in competitive inhibition assays, UL-5 A1 and Fab-5 A1 recognize the same PMC epitope on HLA-A2+, -DR1/DRB1*0101+ typed LCLs. Additionally, mAb UL-5 A1 and Fab-5 A1 both recognize HLA-A2-, -DR1/DRB1*0101+ LCLs exogenously loaded with HLA-A2 peptides (105-117, 103-117). UL-5 A1-like antibodies against peptide/MHC complexes could prove valuable tools for research on T-cell recognition and MHC function.     

Shared epitopes for HLA-A3-restricted melanoma-reactive human CTL include a naturally processed epitope from Pmel-17/gp100

Human CD8+ CTL recognize peptides bound to class I MHC molecules on the surface of melanoma cells. Several peptides derived from melanocyte lineage-specific proteins have been identified as epitopes for HLA-A2 restricted melanoma-reactive CTL. Because less than half of melanoma patients express HLA-A2, it is important to identify CTL epitopes restricted by other common MHC molecules including HLA-A1 and -A3. We have generated HLA-A3-restricted human CTL that recognize one or more shared melanoma Ags. All of the melanomas recognized by one of these CTL lines express Pmel-17/gp100, and those that fail to express this Ag are not lysed. This CTL line also specifically recognizes the lymphoblastoid line C1R-A3 following infection with a recombinant vaccinia encoding the melanocyte lineage-specific protein Pmel-17/gp100. Thus, at least one Pmel-17/ gp100 peptide is an epitope for this CTL line. We have identified ALLAVGATK (Pmel-17/gp100 residues 17-25) as an epitope for this CTL line and have shown that it is naturally processed and presented by HLA-A3 on melanoma cells. A second HLA-A3-restricted melanoma-reactive CTL line recognizes at least one additional shared epitope. These findings suggest that cellular immune responses directed against multiple shared melanoma epitopes exist in the 20 to 25% of melanoma patients who express HLA-A3. In addition, immunotherapy directed against Pmel-17/gp100 and other shared melanoma Ags may be useful in a large subset of these patients.     

Stringent allele/epitope requirements for MART-1/Melan A immunodominance: implications for peptide-based immunotherapy

The exclusiveness of the relationship between peptide and HLA alleles, combined with their extensive polymorphism, emphasizes the need for immunization strategies based on endogenous processing of full length proteins (containing multiple epitopic determinants) for presentation to T cells. This could allow vaccination regardless of the patient's HLA phenotype, assuming that individual molecules can be efficient T cell Ags in association with various HLA alleles. An endogenous system of Ag presentation was developed using dendritic cells infected with recombinant viral vectors expressing the melanoma-associated Ag MART-1/Melan A. CD8+ T cells from melanoma patients were activated in vitro by coincubation with infected dendritic cells and tested for recognition of HLA-A-matched melanoma targets. This allowed the analysis of T cell induction in association with any HLA-A allele of a given patient's phenotype. In this system, MART-1/Melan A could not efficiently immunize in association with HLA-A alleles other than A*0201, including the one residue variant from A*0201: HLA-A*0226. Clonal analysis of MART-1/Melan A-specific CTL confirmed that MART-1/Melan A immunodominance is strongly restricted to the AAGIGILTV/HLA-A*0201 combination. The stringent epitope/allele requirements for MART-1/Melan A/TCR interactions were not associated with limitations in the TCR repertoire. In conclusion, autologous induction of MART-1/Melan A CTL by whole Ag processing and presentation is restricted to a unique allele/ligand combination and is excluded by minimal changes in HLA structure. Thus, whole protein vaccination for small m.w. Ags may provide no further advantage over a peptide-based approach.     

The analysis of internal image-bearing anti-idiotypic monoclonal antibody in relation to carcinoembryonic antigen

Five anti-Id mAb (Ab2) were prepared from a BALB/c mouse immunized with anti-carcinoembryonic Ag (CEA) mAb MA208 (Ab1) in a syngeneic system. These anti-Id mAb appear to recognize unique idiotopes at the combining site of mAb MA208, because they were specifically reactive with mAb MA208 and showed the inhibitory activity against the binding of mAb MA208 to CEA. These anti-Id mAb were divided into three groups: group 1 (M7-625), group 2 (M7-413, M7-914), and group 3 (M7-049, M7-418), according to the analysis of anti-anti-Id antibodies (Ab3) induced with each anti-Id mAb (Ab2). Anti-anti-Id mAb M7-625 antisera (Ab3) reacted with purified CEA in binding assay and in Western blot analysis, and competed with Ab1 binding to CEA. Furthermore, the binding of anti-Id mAb M7-625 (Ab2) to mAb MA208 (Ab1) was inhibited with CEA, indicating that Ab2 mimicks the structure of the epitope in CEA which was recognized with Ab1. These serologic findings suggest that anti-Id mAb M7-625 carries the internal image of the Ag. According to the amino acid sequences of CDR 1, 2, and 3 of the mAb M7-625 variable region, there exists a homology of amino acid sequences between CDR2 in the H chain (5 amino acids of 10) and CDR3 in the L chain (3 amino acids of 9) of mAb M7-625 and domain III of CEA (545-554).     

Principles of lymphogenic and hematogenous metastasis and metastasis classification

A subpopulation of rabbit polyclonal anti-idiotypic antibody (anti-Id) was previously produced to a murine monoclonal antibody (mAb) (M1875) specific for the bluetongue virus core protein VP7. In this report, mimicry of VP7 by this anti-Id (designated RAb2-A) was functionally analyzed through immunization of Balb/c mice with RAb2-A or purified VP7. Animals immunized with RAb2-A were able to produce an M1875-like Ab3 antibody response with idiotype and epitope specificity resembling that of M1875 without subsequent exposure to the nominal antigen. This conclusion was supported by experiments showing that the RAb2-A-induced Ab3 antibodies (i) reacted specifically with the immunizing anti-Id; (ii) were capable of binding VP7; (iii) inhibited M1875 from binding to VP7; and (iv) inhibited M1875 from binding to RAb2-A. Similarly, mice immunized with purified VP7 also produced antibodies that exhibited characteristics such as idiotype and epitope specificity in common with M1875. No antibody response to VP7 was detected in control groups of mice immunized with either normal rabbit IgG or BHK-21 cell components. Therefore, it can be concluded that rabbit anti-Id RAb-2-A mimics an M1875-defined VP7 epitope sufficiently to function as a surrogate antigen for inducing an anti-bluetongue virus response.     

CD94/NKG2 inhibitory receptor complex modulates both anti-viral and anti-tumoral responses of polyclonal phosphoantigen-reactive V gamma 9V delta 2 T lymphocytes

Viral, bacterial, protozoal, and cancer-associated Ags elicit strong responses in human gammadelta T lymphocytes. The majority of these cells in the peripheral blood express the Vgamma9Vdelta2-encoded TCR and recognize nonpeptidic phosphoantigens without an apparent MHC restriction. We have shown that Vgamma9Vdelta2 T cells express the inhibitory CD94/NKG2 receptor for HLA class I molecules. The anti-CD94 mAb inhibits 1) the Vgamma9Vdelta2 T cell proliferation in response mycobacterial phosphoantigens and 2) the HIV-induced Vgamma9Vdelta2 T cell expansion. Vgamma9Vdelta2 T cells stimulated with nonpeptidic mycobacterial antigens produce IFN-gamma and TNF-alpha. Signaling through the CD94/NKG2 receptor interferes with the synthesis of these cytokines. The CD94/HLA class I interaction is also involved in the cytotoxic activity of Vgamma9Vdelta2 T cells. The Vgamma9Vdelta2 T cell regulation through the CD94 receptor may be important for the potentially dual function in innate immunity, i.e., 1) NK-like and 2) TCR ligand-induced cytolytic activities.     

Autoimmune responses against acetylcholine receptor: T and B cell collaboration and manipulation by synthetic peptides

Myasthenia gravis (MG) and experimental autoimmune MG (EAMG) are induced by antibodies (Abs) against self acetylcholine receptor (AChR). We have mapped the T and B cell epitopes on AChR alpha subunit in human MG and in EAMG-susceptible (C57BL/6, B6) and nonsusceptible mouse strains. A T-cell epitope within residues alpha 146-162 (P14) of Torpedo californica (t)AChR plays an important role in EAMG pathogenesis of the auto Ab-induced disease. P14-specific T cell (P14Th) lines from tAChR-primed B6 mice activated, in vivo and in vitro, tAChR-primed B cells that secreted anti-AChR Abs directed against four other regions on the tAChR alpha-chain, but not against P14 itself. P14Th cells are pathogenic because they help B cells that make Abs against a conserved tAChR region (t alpha 122-150) involved in ACh binding. These Abs cross-react with region alpha 122-150 of mouse (m)AChR, thereby disrupting its normal physiological function. Thus, a T cell epitope not recognized by Abs plays an active role in B cell responses against other epitopes on the protein. We have found that in B6, the MHC region 62-76 of I-A beta(b) is involved in the presentation of P14 to T cells. Anti-peptide Abs, prepared in BALB/c, were found to inhibit in vitro the proliferation of P14-specific T-cells. Furthermore, this MHC peptide elicited Abs in B6 mice and we are investigating whether immunization of B6 with this peptide, before priming with tAChR, would suppress in vivo the T-cell response to the epitope in P14. Thus, these preliminary results would suggest that immunization with the MHC peptide might be employed for control of the autoimmune disease.     

Intersite helper function of T cells specific for a protein epitope that is not recognized by antibodies

Humoral responses to a protein require T-B cell communication for B cell activation by T cells. Previous studies from this laboratory have mapped the T and B cell recognition sites (epitopes) on sperm-whale myoglobin (Mb) and several other proteins. It was found that, five of six regions on Mb recognized by T cells are also recognized by B cells (i.e. antibodies). There is, however, one region (E6) residing within Mb residues 61-77, that is recognized only by T cells and to which no antibody (Ab) responses are detectable. To investigate the function of this exclusive T cell epitope, we established, from E6-primed BALB/c mice, an E6-specific T cell line (T(e6)) which comprised Th2-type cells. These T cells provided help in vitro to B cells from Mb-primed BALB/c mice and activated them to produce anti-Mb Abs of the IgM (58.2%) and IgG (41.8%) isotypes. The helper activity of T(e6) cells was dependent on the concentration of the challenging Ag (intact Mb or peptide E6) in culture. Action of soluble factors released from E6-activated T(e6) cells on B(mb) cells led to low production of anti-Mb Abs, suggesting that activation of the B cells was more dependent on their contact with T cells. Mapping of the epitope recognition of the anti-Mb Abs produced in vitro by B(mb) cells on activation by T(e6) revealed that this activation was not general to all antigenic regions recognized by anti-Mb Abs in BALB/c mice. E6-specific T cells caused in vitro activation and differentiation of B(mb) cells into plasma cells that secreted anti-Mb Abs directed, in decreasing order, against the following Mb regions: E4 (107-120) > E3 (87 - 100) > E1 (10 - 22). Little or no Ab responses could be detected against peptides E2 (50 - 62), E5 (141 - 153) and E6 (61 - 77). With B cells of peptide-primed BALB/c mice, T(e6) cells activated strongly E4-, E3- or E1, and only very slightly E2- or E6-, primed B cells to secrete Abs against the correlate peptide, but failed completely to activate E5-primed B cells. The results show that a protein T cell epitope, to which no Abs are detectable, plays an active role in B cell responses against other epitopes within the same protein.     

Molecular analysis of presentation by HLA-A2.1 of a promiscuously binding V3 loop peptide from the HIV-envelope protein to human cytotoxic T lymphocytes

P18(IIIB) is a highly immunogenic peptide from the V3 loop of the HIV-1 gp160 envelope protein that is presented promiscuously by multiple class I MHC molecules. Understanding the molecular basis for promiscuous presentation may have many practical applications. As the highly prevalent HLA-A2.1 class I molecule is known to present P18(IIIB) for recognition by cytotoxic T lymphocytes (CTL) found in peripheral blood mononuclear cells of HIV+ donors, a P18(IIIB)-specific CTL line was generated from and HLA-A2(+), HIV- donor in order to define the molecular basis for, and ultimately improve upon the binding of, this peptide to HLA-A2.1. The minimal epitope recognized by the line was a decamer, I10, with the sequence RGPGRAFVTI. Interestingly, this decamer is identical to the minimal epitope from P18(IIIB) seen by murine CTL restricted by H-2Dd. A panel of Ala-substituted peptides was employed in MHC-binding and T cell response studies to identify MHC- and TCR-binding residues. Notably, many of the agretopic and epitopic residues identified were identical to those involved in the corresponding interactions of I10 with the H-2Dd MHC molecule and murine I10-specific CTL. The I10 peptide does not contain the described HLA-A2.1 binding motif. Instead a Pro at P3, a Phe at P7 and an Ile at P10 are utilized for MHC binding. Agretopic residue similarities with the hepatitis B nucleocapsid decamer suggest that these residues may comprise an alternative motif of anchors utilized by decamers for binding to HLA-A2.1.     

Identification of HLA class II-restricted determinants of Mycobacterium tuberculosis-derived proteins by using HLA-transgenic, class II-deficient mice

T helper 1 cells play a major role in protective immunity against mycobacterial pathogens. Since the antigen (Ag) specificity of CD4(+) human T cells is strongly controlled by HLA class II polymorphism, the immunogenic potential of candidate Ags needs to be defined in the context of HLA polymorphism. We have taken advantage of class II-deficient (Ab0) mice, transgenic for either HLA-DRA/B1*0301 (DR3) or HLA-DQB1*0302/DQA*0301 (DQ8) alleles. In these animals, all CD4(+) T cells are restricted by the HLA molecule. We reported previously that human DR3-restricted T cells frequently recognize heat shock protein (hsp)65 of Mycobacterium tuberculosis, and only a single hsp65 epitope, p1-20. DR3.Ab0 mice, immunized with bacillus Calmette-Guérin or hsp65, developed T cell responses to M. tuberculosis, and recognized the same hsp65 epitope, p1-20. Hsp65-immunized DQ8.Ab0 mice mounted a strong response to bacillus Calmette-Guérin but not to p1-20. Instead, we identified three new DQ8-restricted T cell epitopes in the regions 171-200, 311-340, and 411-440. DR3.Ab0 mice immunized with a second major M. tuberculosis protein, Ag85 (composed of 85A, 85B, and 85C), also developed T cell responses against only one determinant, 85B p51-70, that was identified in this study. Importantly, subsequent analysis of human T cell responses revealed that HLA-DR3+, Ag85-reactive individuals recognize exactly the same peptide epitope as DR3.Ab0 mice. Strikingly, both DR3-restricted T cell epitopes represent the best DR3-binding sequences in hsp65 and 85B, revealing a strong association between peptide-immunodominance and HLA binding affinity. Immunization of DR3.Ab0 with the immunodominant peptides p1-20 and p51-70 induced T cell reactivity to M. tuberculosis. Thus, for two different Ags, T cells from DR3.Ab0 mice and HLA-DR3+ humans recognize the same immunodominant determinants. Our data support the use of HLA-transgenic mice in identifying human T cell determinants for the design of new vaccines.     

Limited diversity of human scFv fragments isolated by panning a synthetic phage-display scFv library with cultured human melanoma cells

To broaden the specificity of the Abs recognizing human melanoma-associated Ags (MAAs), we have isolated human single-chain fragment of the V region (scFv) fragments by panning the synthetic phage Ab library (#1) with the human melanoma cell lines S5 and SK-MEL-28. All of the isolated scFv fragments reacted with the mouse mAb defined high molecular weight melanoma-associated Ag (HMW-MAA). scFv #70 immunoprecipitates the two characteristic subunits of HMW-MAA, while scFv #28 only immunoprecipitates its large subunit. These results challenge the current view regarding the structure of HMW-MAA and indicate that it consists of two independent subunits. The human scFv fragments share some similarities with the mouse anti-HMW-MAA mAb. Like mAb 149.53 and 225.28, scFv #28 reacts with rat B49 neural cells that express a homologue of HMW-MAA. scFv #70 reacts with a determinant that is spatially close to the one identified by mAbs 149.53, VT68.2, and VT86. Besides suggesting similarities in the recognition of human melanoma cells by the mouse and human Ab repertoire, these results indicate that the Abs isolated from synthetic Ab libraries resemble those that are found in natural Ab repertoires. The restricted diversity of the scFv fragments that were isolated by panning synthetic Ab libraries with different melanoma cell lines suggests that certain Ags, like HMW-MAA, are immunodominant in vitro. This phenomenon, which parallels the in vivo immunodominance of certain Ags, implies that the antigenic profile of the cells used for panning determines the specificity of the preponderant population of isolated Abs.     

Dissociation of beta 2-microglobulin from HLA class I heavy chains correlates with acquisition of epitopes in the cytoplasmic tail

A rabbit antiserum "ABR2" was raised against a peptide with sequence identity to 10 amino acids of the cytoplasmic tail of HLA class I heavy chains. Western blotting and immunoprecipitation analyses demonstrate that ABR2 reacts with HLA class I heavy chains. The antiserum reacts poorly with beta 2-microglobulin (beta 2-m)-associated heavy chains and reacts strongly with free heavy chains. ABR2 reacts with immature heavy chains from the endoplasmic reticulum that have yet to bind beta 2-m and mature heavy chains that have dissociated from beta 2-m at the plasma membrane. Comparison with HC10, a mAb that recognizes an epitope defined by polymorphism at residue 62 of the alpha 1 helix of free HLA class I heavy chains, shows that ABR2 reacts with overlapping populations of free heavy chains (for those allotypes that react with both Abs), but it also identifies populations that bind to one Ab and not the other. ABR2 induces dissociation of beta 2-m from HLA-B38 molecules expressed by the human B cell line "TEM," a phenomenon not detected with other allotypes or with the same allotype in a different cell line. This study shows that association of beta 2-m with the extracellular domains of HLA class I heavy chains can cause a change in the cytoplasmic tail that prevents binding of Abs present in the ABR2 antiserum. Similar findings have been made for mouse H-2 class I molecules, which suggests that this is a general property of class I MHC molecules.     

Negative signaling by anti-HLA class I antibodies is dependent upon two triggering events

mAb with specificity for the alpha3 domain of HLA class I antigens, such as mAb TP25.99 and W6/32, are capable of inhibiting the proliferation of stimulated T cells in vitro by binding to their surface HLA class I antigens. The inhibitory potential of another HLA class I alpha3 domain-specific mAb, A1.4, was evaluated. In contrast to mAb TP25.99 and W6/32, which routinely inhibited superantigen (SEB) stimulation of T cells by >90%, mAb A1.4 at equivalent concentrations demonstrated only 20-50% inhibition. Univalent Fab fragments of all three mAb lacked inhibitory activity. Interestingly, however, by combining univalent W6/32 (or TP25.99) Fab fragments with intact, bivalent mAb A1.4 (at a non-inhibitory, sub-threshold concentration of 1 microg/ml), significant inhibition of SEB-driven T cell proliferation was obtained. Inhibition by the anti-HLA class I mAb W6/32 and TP25.99 was evident even when SEB was used in conjunction with paraformaldehyde-fixed HLA class I-, class II+ Daudi cells, suggesting that the inhibitory activity of these mAb results from direct HLA class I epitope engagement on the T cell. These findings suggest that effective antibody-mediated induction of the HLA class I inhibitory pathway within T cells is dependent upon two separable molecular triggers at the T cell surface. The first can be delivered by univalent mAb derivatives that engage one or more critical HLA class I epitope(s). The second requires intact mAb, though seems to be less selective as to the HLA class I specificity. This model may explain why some, but not all, anti-HLA class I mAb are inhibitory when used singly. Achieving synergies between a wider array of anti-HLA class I mAb and their derivatives may provide a path for more effectively tapping into the HLA class I inhibitory pathway in a therapeutic context.     

Modulation of the immune response in multiple sclerosis: production of monoclonal antibodies specific to HLA/myelin basic protein

Monoclonal Abs to the complex formed between human MHC class II molecules (DR7 and DRw11) and myelin basic protein (MBP) were produced. The specificity of these Abs was established by both FACS analysis and complement-mediated cytotoxicity of MBP- or OVA-pulsed human APC of the same or of different DR restriction. These Abs bound to and lysed only MBP-pulsed human APC of the same DR restriction (DR7 or DRw11) but not to APC of different DR restriction or pulsed with a different Ag (OVA). The physiologic role of these Abs was further investigated. They blocked the in vitro proliferative response to MBP-specific T cell clones isolated from multiple sclerosis patients in an antigen-specific and DR-restricted manner. However, the Abs did not affect the response of MBP-specific T cell clones of other DR restriction nor did they interfere with the response to other Ags (purified protein derivative or copolymer 1) presented on APC with the same DR restriction. These Abs may be useful for treating multiple sclerosis in which reactivity to MBP is implicated. Moreover, this approach may be extended to other autoantigens and their counterpart autoimmune diseases.     

Induction of autoantibody responses to GM-CSF by hyperimmunization with an Id-GM-CSF fusion protein

Fusion proteins consisting of an Ig containing xenogenic constant regions and granulocyte-macrophage colony stimulating factor (Id-GM-CSF) are potent immunogens capable of inducing anti-idiotypic Abs after two immunizations, without the usual need for adjuvants or carrier proteins. In this study, we investigated the effects of hyperimmunization with Id-GM-CSF and found that it induces anti-GM-CSF Abs that could bind to GM-CSF and neutralize its bioactivity in vitro. However, no detrimental effects of the anti-GM-CSF activity were apparent on the general health of the animals or on their base line white blood cell counts. Mice with the anti-GM-CSF activity reconstituted their peripheral white blood cells with identical kinetics as control mice after high dose cyclophosphamide treatment, sublethal irradiation, or lethal irradiation followed by syngeneic bone marrow transplantation. Primary and secondary Ab responses to a variety of protein Ags, including an unrelated Ig Id, were not affected. However, the anti-Id response induced by an unrelated GM-CSF fusion protein that is dependent upon the GM-CSF bioactivity was impaired. To avoid any potential problems associated with inducing anti-GM-CSF Abs, we show that priming with the Id-GM-CSF protein and boosting with the Id protein alone were sufficient to induce comparable anti-Id titers without inducing anti-GM-CSF Abs. We conclude that although hyperimmunization of mice with the GM-CSF fusion protein induced neutralizing anti-GM-CSF Abs, this was of little consequence to the animals. Nevertheless, we have devised a strategy to overcome this potential limitation on the use of GM-CSF fusion proteins for immunization.     

The cytoplasmic and the transmembrane domains are not sufficient for class I MHC signal transduction

Class I MHC molecules deliver activation signals to T cells. To analyze the role of the cytoplasmic and the transmembrane (TM) domains of class I MHC molecules in T cell activation, Jurkat cells were transfected with genes for truncated class I MHC molecules which had only four intracytoplasmic amino acids and no potential phosphorylation sites or native molecules or both. Cross-linking either the native or the truncated molecules induced IL-2 production even under limiting stimulation conditions of low engagement of the stimulating mAb. Moreover, direct comparison of transfected truncated and native class I MHC molecules expressed on the same cell revealed significant stimulation induced by cross-linking the truncated molecules, despite low expression. In addition, truncated class I MHC molecules were as able to synergize with CD3, CD2, or CD28 initiated IL-2 production as native molecules. In further experiments, hybrid constructs made of the extracellular portion of the murine CD8 alpha chain and of the TM and the intracytoplasmic domains of H-2Kk class I MHC molecule were transfected into Jurkat T cells. The expression of the transfected hybrid molecules was comparable to that of the native HLA-B7 molecules. Cross-linking the intact monomorphic HLA-A,B,C epitope or the polymorphic HLA-B7 epitope induced IL-2 production upon costimulation with PMA. In contrast, cross-linking the hybrid molecules generated neither an increase in intracellular calcium concentration ([Ca2+]i) nor stimulated IL-2 production. By contrast, cross-linking intact murine class I MHC molecules induced [Ca2+]i, signal and IL-2 production in transfected Jurkat cells. The data therefore indicate that unlike many other signaling molecules, signaling via class I MHC molecules does not involve the cytoplasmic and the TM portions of the molecule, but rather class I MHC signal transduction is likely to be mediated by the extracellular domain of the molecule.     

Inhibition of binding of anti-PLA1 antibodies to platelets with monoclonal antibody LK-4. Evidence for multiple PLA1 receptor sites on platelet GPIIIa

The PLA1 epitope on platelet GPIIIa has a sulfhydryl-dependent conformation and is dependent on a leucine 33/proline33 polymorphism. Monoclonal antibody LK-4 differentiates PLA1/PLA1 from PLA2/PLA2 platelet lysates on solid phase enzyme-linked immunosorbent assay (ELISA), as well as immunoblot. To determine whether LK-4 reacts at or near the binding site(s) for human anti-PLA1, nine such antibodies (Abs) (six neonatal; three posttransfusion) were examined in the presence and absence of LK-4 for binding to platelets, as well as rGPIIIa 1-66, a recombinant glutathione S-transferase fusion peptide. All nine human Abs bound to rGPIIIa 1-66, as well as platelets, in a saturation-dependent manner, employing both solid phase ELISA, as well as flow cytometry. Binding of all nine Abs to rGPIIIa 1-66 or platelets was inhibited by LK-4. IC50's for inhibition of binding of anti-PLA1 to rGPIIIa 1-66 varied from 8 to 160 micrograms/mL (5 x 10(-8)- 1 x 10(-6) mol/L). However, IC50's for LK-4 inhibition of binding to platelets was strikingly different. Six of the nine Abs had IC50's of 1 to 10 micrograms/mL (8-fold to 16-fold greater inhibition than with rGPIIIa 1-66), whereas three neonatal Abs had IC50's of 380 to 1,013 micrograms/mL (6-fold to 48-fold less inhibition than with rGPIIIa 1-66). Similar results were noted with intact GPIIIa, rGPIIIa 1-66 blocked the binding of anti-PLA1 Abs to platelets and served to segregate the nine patients into two groups: a sensitive group of anti-PLA1 Abs from six patients in which binding to platelets was progressively inhibited by increasing concentrations of rGPIIIa 1-66 with inhibition at 1 micrograms/mL of 18% and inhibition at 256 micrograms/mL of 78%; a second resistant group of three anti-PLA1 Abs from three patients in which inhibition was first noted at 16 micrograms/mL of 4% with 35% inhibition at 256 micrograms/mL. Thus, LK-4 binds to GPIIIa at the 1-66 N-terminal region, inhibits binding of anti-PLA1 Ab to platelets, and segregates, anti-PLA1 Abs into two groups. These data are compatible with two or more receptor sites for anti-PLA1 Ab: one that is present on rGPIIIa 1-66 and sensitive to LK-4 inhibition, another that is present on rGPIIIa 1-66, as well as other site(s) on platelet GPIIIa and insensitive to inhibition.     

Generation of human cytolytic T lymphocyte lines directed against prostate-specific antigen (PSA) employing a PSA oligoepitope peptide

Prostate-specific Ag (PSA), which is expressed in a majority of prostate cancers, is a potential target for specific immunotherapy. Previous studies have shown that two 10-mer PSA peptides (designated PSA-1 and PSA-3) selected to conform to human HLA class I-A2 motifs can elicit CTL responses in vitro. A longer PSA peptide (30-mer) designated PSA-OP (oligoepitope peptide), which contains both the PSA-1 and PSA-3 HLA-A2 epitopes and an additional potential CTL epitope (designated PSA-9) for the HLA-class I-A3 allele, was investigated for the ability to induce cytotoxic T cell activity. T cell lines from different HLA-A2 and HLA-A3 donors were established by in vitro stimulation with PSA-OP; the CTL lines lysed PSA-OP as well as PSA-1- or PSA-3-pulsed C1R-A2 cells, and PSA-OP and PSA-9-pulsed C1R-A3 cells, respectively. The CTL lines derived from the PSA-OP peptide also lysed PSA-positive prostate cancer cells. PSA-OP-derived T cell lines also lysed recombinant vaccinia-PSA-infected targets but not targets infected with wild-type vaccinia. PSA-OP did not bind HLA-A2 and HLA-A3 molecules. The decrease in cytotoxicity in the presence of protease inhibitors suggests that the PSA-OP is cleaved into shorter peptides, which in turn can interact with HLA-class I molecules and, as a consequence, induce CTL-mediated lysis. We have also demonstrated that it is possible to induce CTL responses in HLA-A2.1/Kb transgenic mice by immunization with PSA-OP with adjuvant. These studies thus provide evidence that oligopeptides such as PSA-OP may be useful candidates for peptide-based cancer vaccines.