Fine specificity and idiotype diversity of a murine anti-HLA-DQw3 monoclonal antibody elicited with a syngeneic antiidiotypic monoclonal antibody

A total of 469 hybridomas was generated from a BALB/c mouse immunized with the syngeneic antiidiotypic mAb KO3-34 that recognizes an idiotope within the Ag-combining site of the immunizing syngeneic anti HLA-DQw3 mAb KS13. One of the hybridomas, named S2B154, was shown with a number of serologic and immunochemical assays to mimic the specificity of anti HLA-DQw3 mAb KS13. This result was unexpected, because the antiidiotypic mAb had been classified as gamma because of the lack of detection of anti-HLA-DQw3 antibodies in sera from BALB/c mice immunized with the antiidiotypic mAb KO3-34. The antiidiotypic mAb S2B154, an IgG1, displays a lower affinity constant to HLA-DQw3 Ag-bearing lymphoid cells than mAb KS13, an IgG2b, but a higher one to antiidiotypic mAb KO3-34. Testing with a panel of antiidiotypic mAb elicited with the mAb KS13 showed that both antiidiotypic mAb S2B154 and mAb KS13 express in their Ag-combining site the idiotopes recognized by the antiidiotypic mAb KO3-256, KO3-335, and R1-38. However, the antiidiotypic mAb S2B154 does not react with the mAb R18-9 that recognizes an idiotope outside the Ag-combining site of mAb KS13. The results we have presented question the validity of the classification of antiidiotypic antibodies based on their ability to inhibit the binding of the corresponding antibodies to Ag and on the specificity of antisera elicited with antiidiotypic antibodies. Furthermore, the hybridomas we have developed in this Id cascade provide us the opportunity to analyze the structural basis of idiotypic Ag mimicry and to evaluate the regulatory properties of antiidiotypic antibodies in the immune response to HLA class II Ag.     

Enhancing effect of anti-HLA class I monoclonal antibodies on T cell proliferation induced via CD2 molecule

The mAb 131 to a determinant preferentially expressed on the gene products of the HLA-A locus, the mAb Q6/64 and 4E to determinants preferentially expressed on the gene products of the HLA-B locus, the anti-HLA-A2,A28 mAb CR11-351, HO-2, HO-3, HO-4, and KS1, and the anti-HLA-B7 cross-reacting group mAb KS4 enhanced proliferation of T cells in most, if not all, the PBMC preparations stimulated with the anti-CD2 mAb 9-1 + 9.6. The mAb CR10-215, W6/32, and 6/31 to distinct monomorphic determinants of HLA class I antigens enhanced CD2-induced T cell proliferation in at most 30% of the PBMC preparations tested. The anti human beta 2-microglobulin (beta 2-mu) mAb NAMB-1 displayed no detectable effect on the proliferation of T cells stimulated with the mAb 9-1 + 9.6. The enhancing effect of anti-HLA class I mAb is specific, is dose dependent, is not abrogated by the addition of exogenous IL-1 and IL-2 to the cultures, and reflects the interaction of anti-HLA class I mAb with T cells. Enhancement of CD2 mediated proliferation of T cells is not a unique property of anti-HLA class I mAb, since the anti-HLA class II mAb Q5/6 and Q5/13 also had a similar effect. Analysis of the kinetics of the enhancing effect of anti-HLA class I mAb suggests that they modulate an early event of T cell activation and may affect the interaction of T cells with mAb 9-1. Phenotyping of T lymphocytes activated by mAb 9-1 + 9.6 in the presence of anti-HLA class I mAb suggests that the enhancing effect of anti-HLA class I mAb may reflect the recruitment of a higher percentage of T cells. The present study has shown for the first time that certain, but not all, the determinants of the HLA class I molecular complex are involved in the proliferation of T cells stimulated with the anti-CD2 mAb 9-1 + 9.6. Furthermore, the inhibitory effect of mAb CR11-351, KS1, Q6/64, and W6/32 on the proliferation of T cells stimulated with mAb OKT3 or with mAb BMA 031 indicates that the same determinants of HLA class I antigens play a differential regulatory role in T cell proliferation induced via the CD2 and CD3 pathway.     

Diversity in the fine specificity and idiotypic profile of mouse anti-HLA-DR monoclonal antibody elicited with the syngeneic anti-idiotypic monoclonal antibody F5-830.

Four hundred and sixty-six hybridomas were generated from a BALB/c mouse immunized with the syngeneic anti-idiotypic mAb F5-830 that recognizes an idiotope in the Ag-combining site of mAb AC1.59. At an appropriate concentration, the latter reacts with a determinant expressed by HLA-DR1, DRw8, and DRw9 Ag and subtypes of HLA-DR4 and DRw6 allospecificities. Serologic and immunochemical assays identified eight anti-HLA-DR anti-anti-idiotypic mAb. They are heterogeneous in their reactivity with a panel of HLA-typed B lymphoid cells: like mAb AC1.59, the anti-anti-idiotypic mAb MA1/38, MA1/40, MA1/47, and MA1/98 recognize the determinant shared by HLA-DR1, DRw8, and DRw9 Ag and subtypes of HLA-DR4 Ag. On the other hand, the anti-anti-idiotypic mAb MA1/52, MA1/157, MA1/281, and MA1/285 have a more restricted reactivity, inasmuch as the corresponding determinant(s) is detectable on only some of the allospecificities recognized by mAb AC1.59. Each anti-anti-idiotypic mAb varies in its extent of reactivity with HLA-DR allospecificities. These results suggest differences in the fine specificity of anti-HLA-DR anti-anti-idiotypic mAb and in the structural characteristics of the mAb AC1.59 defined determinant shared by HLA-DR1, DRw8, and DRw9 Ag and subtypes of DR4 allospecificities. Furthermore, the anti-anti-idiotypic mAb are heterogeneous in terms of expression of idiotopes and of their spatial relationship with their Ag-combining site. The heterogeneity in the characteristics of anti-HLA-DR antibodies elicited with anti-idiotypic mAb F5-830 suggests that the Id cascade triggered by immunization with incompatible HLA allospecificities may account for the changes in the anti-HLA antibody specificity that have been observed in the course of an immune response to mismatched HLA alloantigens.     

Characterization by monoclonal antibodies of a target cell antigen complex recognized by nonspecific cytotoxic cells

Fish nonspecific cytotoxic cells (NCC)3 recognize and lyse a large variety of human and mouse transformed cells. In an effort to determine the Ag recognized by NCC on these targets, mAb were raised against NC-37 target cells. Four anti-NC-37 mAb were chosen for further characterization based on their effects on NCC lysis of target cells. Purified mAb 18C2 and 1E7 (IgM isotype) inhibited NCC killing of the following targets: U937, MOLT-4, K562, HL-60, DAUDI, NC-37, P815, and YAC-1. The dose-dependent inhibitory activity occurred at the target cell level and ranged from 50 to 70% at a concentration of 50 micrograms/well when compared to noninhibitory mAb 7C6 and 1D4 (IgG isotype). Similarly, mAb 18C2 protected the fish parasite Tetrahymena pyriformis from lysis by NCC when compared to mAb 7C6. Adsorption experiments demonstrated that the inhibitory effect on NC-37 lysis by NCC could be removed in a titratable fashion by incubation of mAb 1E7 with any one of the other target cell lines, but it could not be removed by incubation with effector cells. The inhibitory activity of mAb 1E7 and 18C2 was shown to be caused by the inhibition of conjugate formation between effector and NC-37 target cells. The relative membrane concentration of the antigenic determinants recognized by these mAb on the target cells was studied by flow cytometry using FITC-labeled mAb. These experiments showed that all four mAb bound to the surface of the cells tested. Biochemical analysis with Western blots and immunoprecipitation showed that mAb 18C2 and 1E7 recognize two Ag in NC-37 lysates: a larger protein of around 80 kDa and a smaller one of 42 kDa.     

Treatment of murine B cell lymphoma with bispecific monoclonal antibodies (anti-idiotype x anti-CD3).

It has previously been reported that T lymphocytes can be targeted by using bispecific antibodies consisting of anti-target antibody and anti-CD3. In the present study, a bispecific mAb was developed by somatic hybridization of mouse hybridomas, one producing a mAb against the Id determinant of the mouse B cell lymphoma 38C13 and the other a mAb against a polymorphic determinant on murine CD3. The bispecific antibody, anti-38C13 x anti-CD3, is bi-isotypic (IgG1 x IgG2a) and was purified by ion exchange and affinity chromatography. The dual specificity of the hybrid hybridoma-produced mAb could be demonstrated by flow cytometry, the induction of T cell proliferation, the induction of IL-2 secretion by polyclonal T cells, and redirected lysis of the relevant target cells. The hybrid (bi-isotypic) Fc part of the bispecific antibodies was nonfunctional in FcR-dependent redirected lysis. In vivo studies demonstrate that this bispecific mAb could efficiently target T cells towards the tumor cells, resulting in long term survival and cure of the lymphoma.     

Inhibition of cytotoxic T cell lysis by anti-CD8 monoclonal antibodies: studies with CD3-targeted cytolysis of nominal antigen-negative targets

The function of the CD8 molecule in lympholysis mediated by cytotoxic T cells was investigated by examining possible contributions of ligands on the target cell to the inhibition of lysis observed with CD8-specific mAb. In order to evaluate a variety of target cells, including those not expressing the nominal Ag (NA) for which the CTL was specific, lysis was effected by cross-linking the CTL and the target cells with anti-CD3 mAb. Such CD3 redirected cytotoxicity was demonstrated to be inhibited by anti-CD8 mAb when low anti-CD3 mAb concentrations were used. The possibility that inhibition by anti-CD8 mAb resulted for competition for the FcR between the anti-CD3 mAb and anti-CD8 mAb was eliminated by targeting TNP-modified cells with an antibody heteroconjugate prepared from Fab fragments of anti-CD3 and anti-DNP antibodies. Inhibition of the lysis of target cells not expressing NA including those deficient in class I expression, demonstrated that neither NA nor class I expression was required for anti-CD8 mAb inhibition. Whether the anti-CD8 mAb inhibition required CD8 Ag interaction with any ligand on the target cell was further investigated by measuring exocytosis of enzyme granule from CTL activated with CD3-coated poly-styrene beads. CD8-specific mAb inhibited such CTL activation in this target cell-free system. A CD8(+), MHC class II-specific CTL clone, was used to show differential inhibition by anti-CD8 mAb, depending on the target cell, therefore providing evidence that anti-CD8 mAb binding does not generate an absolute off signal. These data are consistent with the hypothesis that anti-CD8 mAb affect the lytic process independent of the recognition of a ligand on the target cell by CD8.     

Dissociation of alloantigen recognition from self major histocompatibility complex-restricted recognition of cytolytic T lymphocytes by monoclonal antireceptor antibodies

Two monoclonal antibodies (mAb) directed to the dual reactive cytolytic T lymphocyte clone OH8 (Db + H-Y and H-2d) were established. Analysis by cell surface staining and immunoprecipitation of radiolabeled surface molecules of OH8 followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that both mAb recognized an identical heterodimeric, clonotypic structure on OH8 cells, i.e., T cell receptor. However, although the MR3-2 mAb inhibited the lysis of either Db + H-Y or H-2d targets by OH8, the MR3-6 mAb inhibited the lysis of H-2d target cells, but not that of Db + H-Y target cells. Modulation of T cell receptor by either MR3-2 or MR3-6 mAb rendered the OH8 cytolytic T lymphocyte incapable of killing both Db + H-Y and H-2d target cells. These findings suggest that different epitopes of OH8 T cell receptor were involved for the recognition of self + antigen and alloantigen.     

Characterization of syngeneic antiidiotypic monoclonal antibodies to murine anti-human high molecular weight melanoma-associated antigen monoclonal antibodies

Hybridization with murine myeloma cells P3-X63-Ag8.653 of splenocytes from BALB/c mice immunized with syngeneic anti-human high molecular weight melanoma-associated Ag (HMW-MAA) mAb 149.53, 225.28, 763.74, and TP41.2 has resulted in the formation of antiidiotypic antibody-secreting hybridomas with a frequency ranging between 1.2% and 5.2%. No marked difference was detected in the frequency of antibody secreting hybridomas in the fusions generated from mice immunized with the four anti-HMW-MAA mAb, suggesting that the idiotopes expressed by each of them display similar immunogenicity in a syngeneic combination. The number of antiidiotypic mAb that did not inhibit the binding of immunizing mAb to melanoma cells was higher than that of those that died, suggesting that idiotopes not associated with the Ag-combining site are more immunogenic than those that are. The idiotopes recognized by mAb were not detected on a large panel of anti-HLA Class I mAb, anti-HLA Class II mAb, and anti-human melanoma-associated Ag mAb. The latter included also mAb that cross-inhibit the immunizing anti-HMW-MAA mAb. The idiotopes recognized by mAb were not detected on the isolated H and L chain of the immunizing anti-HMW-MAA mAb. Cross-blocking experiments with a selected number of antiidiotypic mAb identified three distinct idiotopes on mAb 149.53, 225.28, and TP41.2 and two on mAb 763.74. Three, 5, 2, and 5 antiidiotypic mAb to idiotopes within the Ag-combining site of mAb 149.53, 225.28, 763.74, and TP41.2, respectively, were tested for their ability to induce anti-HMW-MAA antibodies. Serological and immunochemical assays detected anti-HMW-MAA antibodies only in sera from BALB/c mice immunized with mAb MK2-23. Therefore, mAb MK2-23 can be classified as beta, while the remaining 14 can be classified as gamma.     

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.     

Identification of a human natural killer cell target cell antigen with monoclonal antibodies

mAb have been derived against NK cell-sensitive target cells in an effort to identify the target cell structure involved in Ag recognition by NK cells. Several mAb were selected for further study based on their preliminary target cell binding characteristics. Flow cytometry demonstrated that each of these mAb bound to a series of NK-sensitive target cells of various origins (e.g., K562 and Molt-4) while having little or no reactivity with several NK-resistant target cell lines (e.g., SB and Daudi). Functional studies revealed that two of the mAb were able to inhibit the lysis of NK-sensitive K562 target cells by freshly isolated, endogenous NK cells in a dose-dependent fashion. Further, these mAb also could inhibit the killing of K562 target cells by both activated NK cells and cultured lymphokine-activated killer cells, as well as the cytolysis of other NK-sensitive target cells by each of these effector cell populations. Control experiments with another mAb which bound to the target cells but did not inhibit lysis implied that the effects of these mAb on NK cell function was not the result of steric hindrance. Single cell conjugate assays demonstrated that the mAb inhibited NK cell lysis via the inhibition of binding (recognition). Biochemical analysis of this target cell structure revealed that it was a molecule of approximately 42 kDa which may exist as a homodimer in its native state. Thus, it appears that the mAbs identify an unique Ag on the surface of NK cell-sensitive target cells which is involved in NK cell Ag recognition.     

Differential regulatory role of monomorphic and polymorphic determinants of histocompatibility leukocyte antigen class I antigens in monoclonal antibody OKT3-induced T cell proliferation

Monoclonal antibodies (mAb) to monomorphic and polymorphic determinants on the heavy chain of histocompatibility leukocyte antigen (HLA) class I antigens inhibit mAb OKT3-induced T cell proliferation, whereas the anti-beta 2-microglobulin mAb NAMB-1 does not affect it. The inhibitory effect of anti-HLA class I mAb is specific, is not an Fc-mediated phenomenon, does not require accessory cells, and does not involve early stages of T cell activation. Distinct determinants of HLA class I antigens regulate T cell proliferation by different mechanisms, because the anti-HLA-A2, A28 mAb CR11-351, and the mAb W6/32 to a framework determinant of HLA class I antigens block interleukin 2 (IL-2) secretion and IL-2 receptor expression, whereas the mAb CR10-215 to a monomorphic determinant blocks only IL-2 receptor expression. The mAb CR10-215 and W6/32 induced a 50% of maximal inhibition of T cell proliferation, when added after 27 and 12 hr, respectively, of incubation of peripheral blood mononuclear cells with mAb OKT3. On the other hand, the mAb CR11-351 inhibited T cell proliferation even when added after 38 hr of incubation of peripheral blood mononuclear cells with mAb OKT3 and was the only one to inhibit proliferation of cycling T lymphocytes. It is suggested that HLA class I antigens regulate T cell proliferation by interacting with cell-surface molecules involved in T cell activation. The differential inhibitory activity of the anti-HLA class I monoclonal antibodies tested may reflect the different ability of the corresponding determinants to interact with activation molecules.     

Characterization of IL-6 receptor expression by monoclonal and polyclonal antibodies

mAb and polyclonal antibodies against human IL-6R were prepared by using a murine transfectant cell line expressing the human IL-6R and a synthetic oligopeptide made on the basis of the deduced amino acid sequence as immunogens. Immunoprecipitation of radiolabeled IL-6R with these antibodies showed that the Mr of a mature IL-6R was 80 kDa and its value was reduced to 50K after treatment with O- and N-glycanase and neuraminidase, indicating that IL-6R is a glycoprotein. Two mAb recognizing different epitopes were prepared. One, PM1 inhibited the binding of 125I-IL-6 to the receptor and blocked the IL-6-dependent growth of a T lymphoma line, KT3. PM1 could not bind to IL-6R when it was saturated with IL-6, indicating that this antibody recognizes the IL-6 binding or the adjacent site on IL-6R. The other, MT18 was not inhibited by IL-6 for its recognition of IL-6R, therefore, this could be used for cytofluorometric staining of normal cells. Nonstimulated B cells expressed undetectable amount of IL-6R regardless of the expression of surface IgD. However, after the stimulation with PWM, IL-6R was observed on IgD- B cells with a relatively large size, but subtly on IgD- small B cells and not on IgD+ B cells, fitting the function of IL-6 which acts on activated B cells to induce Ig production. In contrast, IL-6R was detected on non-stimulated CD4+/CD8- and CD4-/CD8+ T cells. The level of IL-6R on both T cell subpopulations was not significantly changed after stimulation with phytohemagglutinin.     

Anti-HLA class I antibodies inhibit the T cell-independent proliferation of human B lymphocytes

The role of major histocompatibility complex-encoded class I molecules in the proliferation of human B lymphocytes is presently unclear. This question was addressed by investigating the effect of three individually derived anti-HLA class I monoclonal antibodies (mAb) on purified human B cells (less than 1.5% T cells) stimulated by either the T-independent mitogen Staphylococcus aureus or the phorbol ester, phorbol-12-myristate-13-acetate. The three anti-HLA class I antibodies, whether specific for gene products of the HLA-A locus (mAb 131), HLA-B locus (mAb 4E), or HLA-A, -B, and -C locus (mAb W6/32), inhibited S. aureus-induced proliferation by 70 to 90%. This inhibition was significant over a 5-day culture period, was not altered by the addition of exogenous interleukin 2 or B cell growth factor, and was not due to nonspecific cytotoxicity. In addition, the inhibition of proliferation was unchanged when the mAb were added 12 hr after the initiation of culture. The proliferative response was not affected by either of the control antibodies OKB7 and R3-367. In contrast with S. aureus-stimulated B cells, phorbol-12-myristate-13-acetate-induced proliferation was resistant to the inhibitory activity of HLA class I-specific antibodies. These results suggest that HLA class I molecules are involved in human B lymphocyte proliferation and may regulate a critical event preceding the upregulation of protein kinase C activity.     

Identification of a putative antigen receptor on fish nonspecific cytotoxic cells with monoclonal antibodies

In the present study mAb were derived against flow cytometry (FCM) purified fish (Ictalurus punctatus) nonspecific cytotoxic cells (NCC). mAb 5C6.10.4 and 6D3.2.10 produced 60 to 65% inhibition of lysis of NC-37 target cells (a human B-lymphoblastoid cell line) by unfractionated NCC. mAb 2B2.4.9 and 6D3.4.4 were noninhibitors of cytotoxicity. All mAb were the same isotype (IgM) and were cloned by limiting dilution (2x). Inhibitory activity was specific for the effector cells because the mAb had no effect on NCC cytotoxicity when only the target cells were treated. Inhibition could be produced by preincubation of the mAb with NCC or by no preincubation, and inhibition was not reversible. Killing by FCM-sorted NCC of NC-37 target cells was inhibited almost 100% by mAb 5C6.10.4. Inhibitor mAb also significantly reduced NCC killing of MOLT-4, K562, P815, U937, Daudi, YAC-1, and HL-60 cells. Experiments also were conducted to determine at which stage of the lytic cycle the mAb acted. Both inhibitor mAb significantly inhibited conjugate formation between effector and NC-37 target cells. The technique of FCM was combined with competitive binding experiments to determine that the Ag recognized by both inhibitor and noninhibitor mAb was found on the membranes of the same cells. These results were confirmed by demonstrating (by using FCM) that FITC-labeled inhibitor and biotinylated noninhibitor mAb bound to the same cells. FCM also was next used to determine mAb binding to various effector cell populations. Inhibitor and noninhibitor mAb bound to approximately 25% (5C6.10.4) and 39% (6D3.4.4) of fish anterior kidney cells; to 42% (5C6.10.4) and 54% (6D3.4.4) of fish spleen cells; and to 2.5% (5C6.10.4 and 6D3.4.4) of fish peripheral blood. mAb were used to purify the target cell binding structure found on NCC. Con A-Sepharose purified mAb were used as the fixed ligand for Affi-Gel-10 affinity chromatography experiments. FCM-purified NCC were solubilized and the receptor was purified by using this technique. Analysis of the NCC-purified receptor by 12% SDS-PAGE indicated that the mAb purified structure may be composed of a dimeric molecule consisting of 41 kDa and 38 kDa proteins. The same dimer was purified by using either inhibitory (6D3.2.10) or noninhibitory (6D3.4.4) mAb. Similar results were obtained with immunoprecipitation experiments by using mAb 5C6.10.4. These studies demonstrate that the Ag-binding receptor structure on fish NCC may be comprised of a dimeric complex.     

Inhibition by anti-CD2 monoclonal antibodies of anti-CD3-induced T cell-dependent B cell activation

Anti-CD3 mAb can activate T cells to help in B cell activation as detected by late events, such as maturation of B cells into Ig-secreting cells (IgSC), or by early events, such as B cell surface expression of the activation marker CD23. Two different anti-CD2 mAb each inhibited anti-CD3-induced T cell-dependent B cell activation in a dose-dependent fashion. Neither irradiation of the T cells prior to culture nor depletion of CD8+ cells abrogated the inhibitory effects of anti-CD2 mAb. Despite the ability of these anti-CD2 mAb to inhibit anti-CD3-induced IL2 production, addition of exogenous IL2 to anti-CD2 mAb-containing cultures could not fully reverse the inhibitory effects on IgSC generation. Furthermore, addition of various combinations of IL1, IL2, IL4, and IL6 or crude PBMC or monocyte culture supernatants also could not reverse anti-CD2-driven inhibition. In T cell-depleted cultures, anti-CD2 mAb had no effect on the ability of IL4 to induce B cell CD23 expression, confirming that anti-CD2 mAb had no direct effect on B cells. However, in cultures containing T+ non-T cells, anti-CD2 mAb did partially inhibit IL4-induced B cell CD23 expression. Taken together, these observations demonstrate that certain CD2 ligands can modulate T cell-dependent B cell activation by a mechanism which, at least in part, involves a direct effect by the CD2 ligand on the T cell itself.     

Induction of T cell-dependent B cell differentiation by anti-CD3 monoclonal antibodies

Three monoclonal antibodies (mAb) recognizing the CD3 (T3) surface complex each induced B cell differentiation (as measured by PFC generation) in cultures containing T + non-T cells. Irradiation of the T cells before culture usually augmented the PFC response. An IgG2a mAb (454) induced PFC in all donors tested, whereas two IgG1 mAb (147 and 446) induced PFC in only 80% of the donors tested. This heterogeneity in PFC response to IgG1 anti-CD3 mAb strictly paralleled the heterogeneity in proliferative response to IgG1 anti-CD3 mAb and was governed by cells within the non-T population. In IgG1 anti-CD3 high responders (HR), all anti-CD3 mAb tested induced Tac expression. In IgG1 anti-CD3 low responders (LR), mAb 454 induced Tac expression, but mAb 147 did not. However, when the cultures were supplemented with exogenous interleukin 2, Tac expression and PFC generation in response to mAb 147 was similar to the response to mAb 454 in both HR and LR. The addition of anti-Tac to the cultures partially inhibited anti-CD3-induced PFC generation. These studies indicate that anti-CD3 mAb can lead to B cell differentiation under appropriate experimental conditions and may be valuable in studying polyclonal T cell-dependent B cell differentiation in normal and disease states.     

A monoclonal antibody-purified soluble target cell antigen inhibits nonspecific cytotoxic cell activity.

We have previously reported the characterization of mAb derived against NC-37 target cells. mAb 18C2 and 1E7 inhibit fish cytotoxicity by binding to target cells and thus preventing the formation of conjugates with fish nonspecific cytotoxic cells (NCC). It was therefore presumed that these inhibitory mAb were specific for the target cell Ag necessary for effector cell recognition. mAb 1D4 and 7C6 bind to NC-37 cells but do not inhibit fish cytotoxic activity. We now report the isolation and purification of the Ag recognized by mAb 18C2 (inhibitor) and 1D4 (noninhibitor) by affinity chromatography of solubilized NC-37 target cell extracts. The 18C2-purified soluble target Ag (STAg) caused inhibition of cytotoxicity when preincubated with fish NCC. This inhibitory activity was reversible and dose-dependent ranging from 20 to 70% inhibition with 25 to 100 micrograms 18C2 purified STAg/10(6) NCC. STAg purified by 1D4 affinity chromatography had no effect on fish cytotoxicity. mAb 18C2 and 1E7 preabsorbed with 18C2 STAg lost their inhibitory activity when tested in the fish NCC cytotoxicity assay. Preabsorption of the same mAb with 1D4 STAg had no effect on their activity.     

Detection of function-associated molecules on rat leukemic NK cells: activation by monoclonal antibody or phorbol ester

In the present study a rat leukemia NK cell line designated CRC- (derived from RNK-16 cells) was shown to spontaneously transform into a noncytolytic (NL) line referred to as CRC-/NL cells. CRC- and CRC-/NL cells were utilized to study pathways of NK activation by phorbol esters, calcium ionophore (A23187), and monoclonal antibody (mAb). 10(-6)-10(-7) M phorbol myristate acetate (PMA) but not phorbol didecanoate or 4-beta-phorbol activated CRC-/NL to lyse YAC-1 targets. Activated CRC-/NL cells produced 20-90% specific cytotoxicity compared to 0-5% for nonactivated cells. 10(-7) M PMA inhibited normal CRC- cytotoxicity. The optimum concentration of PMA for activation was 10(-6)-10(-7) M and 3-6 h treatment time. Augmentation of cytotoxicity by PMA occurred at different E:T ratios. The time required to reverse the PMA activation of CRC-/NL cells was approximately 9-10 h posttreatment. In an effort to attempt to differentiate pathways which initiated activation, CRC-/NL cells were treated with FAM binding mAb, or with combinations of mAb and ionophore, mAb and PMA, or PMA and A23187. mAb singly or in combination with 10(-7) M PMA increased cytotoxicity. However, A23187 either singly or when combined with PMA or mAb did not produce an augmented lysis of YAC-1 target cells. Additional experiments were conducted to determine if PMA activation was associated with FAM binding. This was accomplished by analyzing redirected killing of various FAM mAb-producing myeloma cells in the presence of 10(-7) M PMA. PMA treatment of the CRC-/NL cells caused a significant increase in the lysis of myeloma/mAb-producing cells compared to control cells. Further evidence that FAM binding was associated with cytotoxicity was presented by demonstrating specific inhibition of redirected lysis by homologous mAb. Phenotype analysis of CRC- and CRC-/NL cells demonstrated that OX-7 and OX-1 expression on CRC-/NL cells was increased by 71.8 and 86.8% respectively compared to CRC-. FAM expression (78-83% positives) by CRC- and CRC-/NL cells was not different. These experiments indicated at the functional level that rat NK cells can be activated for increased cytotoxicity by FAM-specific mAb binding and/or by treatment with the diacylglycerol analogue PMA. This implies that protein kinase C mobilization either singly or in concert with inositol-1,4,5-trisphosphate activation following FAM mAb binding may play important roles in NK cell cytotoxicity.     

Mechanism of action of anti-IL-2R monoclonal antibodies. ART-18 prolongs cardiac allograft survival in rats by elimination of IL-2R+ mononuclear cells

ART-18, a mouse IgG1 mAb recognizing the IL-2 binding domain of the rat p55 subunit IL-2R molecule, prevents graft rejection in various experimental models, although its mechanism of action in vivo, like that of anti-IL-2R mAb generally, remains elusive. These studies were designed to define whether IL-2R+ T effector cells were actually eliminated or their function merely inhibited by comparing directly the in vitro and in vivo efficacy of intact ART-18 and its F(ab)/F(ab')2 fragments. Addition of each mAb preparation profoundly suppressed MLR set up between naive LEW responders and x-radiated BN stimulators, suggesting that mAb fragments retained Ag binding functions in vitro. However, both ART-18 F(ab) and F(ab')2 were ineffectual in vivo as judged by their inability to affect acute (8 days) rejection of (LEW X BN)F1 cardiac allografts in LEW recipients (graft survival ca. 11 and 9 days, respectively, compared to ca. 21 days after therapy with intact ART-18, p less than 0.001). The sera levels of ART-18 and ART-18 F(ab')2 were 4 to 5 micrograms/ml, but only less than 0.5 micrograms/ml of F(ab) could be detected. The therapeutic failure of ART-18 fragments was unrelated to potential host sensitization, as rat antimouse F(ab) or F(ab')2 serum IgG titers remained in the same range as those against intact ART-18. The role of the Fc portion of Ig in the mode of action of ART-18 was then tested further by flow microfluorimetry analysis of host mononuclear spleen cells and immunoperoxidase stains of the graft infiltrate. IL-2R+ cells were abundant in rats treated with ART-18 fragments, comparable to acutely rejecting controls. In contrast, IL-2R expression was abolished in animals undergoing ART-18 therapy. The elimination of IL-2R+ cells is required to prolong cardiac allograft survival in rats after IL-2R targeted treatment with ART-18 mAb.     

Modification of monoclonal antibody carbohydrates by oxidation,conjugation, or deoxymannojirimycin does not interfere with antibody effector functions

Site-specific attachment of metal chelators or cytotoxic agents to the carbohydrate region of monoclonal antibodies results in clinically useful immunoconjugates [Doerr et al. (1991) Ann Surg 214: 118, Wynant et al. (1991) Prostate 18: 229]. Since the capacity of monoclonal antibodies (mAb) to mediate tumor cell lysis via antibody-dependent cellular cytotoxicity (ADCC) or complement-dependent cytotoxicity (CDC) may accentuate the therapeutic effectiveness of immunoconjugates, we determined whether site-specific modification of mAb carbohydrates interfered with these functions. The chemical modifications examined consisted of periodate oxidation and subsequent conjugation to either a peptide linker/chelator (GYK-DTPA) or a cytotoxic drug (doxorubicin adipic dihydrazide). mAb-associated carbohydrates were also modified metabolically by incubating hybridoma cells in the presence of a glucosidase inhibitor deoxymannojirimycin to produce high-mannose antibody. All four forms (unaltered, oxidized, conjugated and high-mannose) of murine mAb OVB-3 mediated tumor cell lysis via CDC. Similarly, equivalent ADCC was observed with native and conjugated forms of mAb OVB-3 and EGFR.1. ADCC was achieved with different murine effector cells such as naive (NS), poly (I^*C)- and lipopolysaccharide-stimulated (SS) spleen cells, orCorynebacterium-parvum-elicited peritoneal cells (PEC). All murine effector cell types mediated tumor cell lysis but differed in potency such that PEC>SS>NS. Excellent ADCC activity was also demonstrable by human peripheral blood mononuclear cells with OVB-3-GYK-DTPA and high-mannose OVB-3 mAb. ADCC activity was detectable in vivo: both native and conjugated OVB-3 inhibited growth of OVCAR-3 xenografts in nude mice primed withC. parvum. In conclusion, modification of mAb carbohydrates did not compromise their in vivo or in vitro biological functions. Therefore, combination therapy using immunomodulators to enhance the effector functions of site-specific immunoconjugates could be seriously contemplated.