Monoclonal anti-idiotype antibodies against the murine B cell lymphoma 38C13: characterization and use as probes for the biology of the tumor in vivo and in vitro

The growth determinants and transport properties of tunneling nanotube networks between B lymphocytes

Tunneling nanotubes (TNTs) are long intercellular connecting structures providing a special transport route between two neighboring cells. To date TNTs have been reported in different cell types including immune cells such as T-, NK, dendritic cells, or macrophages. Here we report that mature, but not immature, B cells spontaneously form extensive TNT networks under conditions resembling the physiological environment. Live-cell fluorescence, structured illumination, and atomic force microscopic imaging provide new insights into the structure and dynamics of B cell TNTs. Importantly, the selective interaction of cell surface integrins with fibronectin or laminin extracellular matrix proteins proved to be essential for initiating TNT growth in B cells. These TNTs display diversity in length and thickness and contain not only F-actin, but their majority also contain microtubules, which were found, however, not essential for TNT formation. Furthermore, we demonstrate that Ca2+-dependent cortical actin dynamics exert a fundamental control over TNT growth-retraction equilibrium, suggesting that actin filaments form the TNT skeleton. Non-muscle myosin 2 motor activity was shown to provide a negative control limiting the uncontrolled outgrowth of membranous protrusions. Moreover, we also show that spontaneous growth of TNTs is either reduced or increased by B cell receptor- or LPS-mediated activation signals, respectively, thus supporting the critical role of cytoplasmic Ca2+ in regulation of TNT formation. Finally, we observed transport of various GM1/GM3+ vesicles, lysosomes, and mitochondria inside TNTs, as well as intercellular exchange of MHC-II and B7-2 (CD86) molecules which may represent novel pathways of intercellular communication and immunoregulation.

Stress conditioning in mice: alterations in immunity and tumor growth

The neuroendocrine and autonomic nervous systems are known regulators of brain-immune interaction. However, the functional significance of this interaction under stress is not fully understood. We investigated the effect of a stress paradigm by applying electric foot shock followed by three reminders, on behavior, immune parameters, and lymphoma tumor growth. Male C3H mice were divided into two groups: Group 1-exposed to electric foot shock followed by three reminders, and Group 2-untreated (controls). Sets of mice underwent the elevated plus maze, staircase, and hot plate tests. After foot shock, natural killer (NK) cell activity, and lymphocyte proliferation were measured. In addition, sets of mice were either vaccinated twice with B-cell lymphoma 38C-13 immunoglobulin for determination of anti-idiotype (Id) antibodies in sera, or inoculated with tumor cells and monitored for tumor development and survival time. Mice exposed to electric foot shock followed by the three reminders had higher NK cell activity, levels of anti-Id antibodies, and a higher proliferation rate of splenocytes in response to mitogens, than the control mice. The exposed mice also showed attenuated tumor growth. Thus, the stress paradigm inhibited tumor development and lead to some immune changes that were not accompanied by behavioral changes.

Generation of CD8+ T cell-mediated immunity against idiotype-negative lymphoma escapees

We investigated the ability of CpG-oligodeoxynucleotide to generate an anti-tumor CD8+ T-cell immune response and to synergize with passive antibody therapy. For these studies, we generated an antibody against the idiotype on the A20 B-cell lymphoma line. This antibody caused the regression of established tumors, but ultimately the tumors relapsed. The escaping surface IgG-negative tumor cells were resistant to both antibody-dependent cellular cytotoxicity and signaling-induced cell death. Addition of intratumoral CpG to antibody therapy cured large established tumors and prevented the occurrence of tumor escapees. The failure of the combination therapy in mice deficient for CD8+ T cells demonstrates the critical role of CD8+ T cells in tumor eradication. When mice were inoculated with 2 tumors and treated systemically with antibody followed by intratumoral CpG in just one tumor, both tumors regressed, indicating that a systemic immune response was generated. Although antibody therapy can eliminate tumor cells bearing the target antigen, it frequently selects for antigen loss variants. However, when a poly-specific T-cell response was generated against the tumor by intratumoral CpG, even large established tumors were cured. Such an immune response can prevent the emergence of antibody selected tumor escapees and provide long-lasting tumor protection.

Cell-free production of Gaussia princeps luciferase--antibody fragment bioconjugates for ex vivo detection of tumor cells

Antibody fragments (scFvs) fused to luciferase reporter proteins have been used as highly sensitive optical imaging probes. Gaussia princeps luciferase (GLuc) is an attractive choice for a reporter protein because it is small and bright and does not require ATP to stimulate bioluminescence-producing reactions. Both GLuc and scFv proteins contain multiple disulfide bonds, and consequently the production of active and properly folded GLuc-scFv fusions is challenging. We therefore produced both proteins individually in active form, followed by covalent coupling to produce the intended conjugate. We used an Escherichia coli-based cell-free protein synthesis (CFPS) platform to produce GLuc and scFv proteins containing non-natural amino acids (nnAAs) for subsequent conjugation by azide-alkyne click chemistry. GLuc mutants with exposed alkyne reactive groups were produced by global replacement of methionine residues in CFPS. Antibody fragment scFvs contained a single exposed azide group using a scheme for site-specific incorporation of tyrosine analogs. Incorporation of tyrosine analogs at specific sites in proteins was performed using an engineered orthogonal tRNA-tRNA synthetase pair from an archaebacterium. The unique azide and alkyne side chains in GLuc and the antibody fragment scFv facilitated conjugation by click chemistry. GLuc-scFv conjugates were shown to differentiate between cells expressing a surface target of the scFv and cells that did not carry this marker.

Depletion of the C3 component of complement enhances the ability of rituximab-coated target cells to activate human NK cells and improves the efficacy of monoclonal antibody therapy in an in vivo model

Growing evidence indicates antibody-dependent cellular cytotoxicity (ADCC) contributes to the clinical response to monoclonal antibody (mAb) therapy of lymphoma. Recent in vitro analysis suggests C3b can inhibit mAb-induced natural killer (NK)-cell activation and ADCC. Further studies were conducted to assess the effect of C3 depletion on mAb-induced NK activation and therapy of lymphoma. Normal human serum inhibited the ability of rituximab-coated lymphoma cells to activate NK cells as previously reported. Serum did not inhibit NK-cell activation when it was preincubated with cobra venom factor (CVF) to deplete C3. Similar results were found when transudative pleural fluid or nonmalignant ascites was used as surrogates for extravascular fluid, suggesting the inhibitory effect of complement may be present in the extravascular compartment, in which many malignant lymphocytes reside. In vivo, C3 was depleted before mAb treatment in a syngeneic murine model of lymphoma. Survival of lymphoma-bearing mice after treatment with CVF plus mAb and with a human C3 derivative with CVF-like functions (HC3-1496) plus mAb was both superior to that of mAb alone. These studies show that complement depletion enhances NK-cell activation induced by rituximab-coated target cells and improves the efficacy of mAb therapy in a murine lymphoma model.

Dendritic cell-based therapeutic vaccination against myeloma: vaccine formulation determines efficacy against light chain myeloma

Multiple myeloma is an incurable plasma cell malignancy. Immunotherapy in myeloma patients had limited success to date. We have previously demonstrated that dendritic cells (DCs) pulsed with autologous Ig Id induced Id-reactive CD8(+) T cells and protection against a myeloma tumor challenge. In this work, we studied the therapeutic efficacy of chemotherapy combined with different formulations of DC-based vaccines in mice bearing large plasma cell tumors. The comparative study demonstrated that s.c. injection of DCs loaded with Id coupled to keyhole limpet hemocyanin, s.c. injection of DCs loaded with irradiated tumor cells, and intratumoral injection of naive DCs were similarly effective in mediating tumor regression and long-term survival. However, whereas the Id-keyhole limpet hemocyanin-DC vaccine was inefficient against myeloma cells that lost expression of the Ig H chain, intratumoral injection of naive DCs and s.c. injection of DCs loaded with irradiated tumor cells were highly effective against cells producing L chains only. This may be of particular importance for patients with L chain myeloma. Given that T cells respond primarily to peptides derived from H chain CDRs, attempts to treat L chain disease with myeloma protein-pulsed DCs may be futile. Vaccination with tumor cell-loaded DCs may, however, induce an effective antitumor response.

Maleimide conjugation markedly enhances the immunogenicity of both human and murine idiotype-KLH vaccines

The collection of epitopes present within the variable regions of the tumor-specific clonal immunoglobulin expressed by B cell lymphomas (idiotype, Id) can serve as a target for active immunotherapy. Traditionally, tumor-derived Id protein is chemically conjugated to the immunogenic foreign carrier protein keyhole limpet hemocyanin (KLH) using glutaraldehyde to serve as a therapeutic vaccine. While this approach offered promising results for some patients treated in early clinical trials, glutaraldehyde Id-KLH vaccines have failed to induce immune and clinical responses in many vaccinated subjects. We recently described an alternative conjugation method employing maleimide-sulfhydryl chemistry that significantly increased the therapeutic efficacy of Id-KLH vaccines in three different murine B cell lymphoma models, with protection mediated by either CD8(+) T cells or antibodies. We now define in detail the methods and parameters critical for enhancing the in vivo immunogenicity of human as well as murine Id-KLH conjugate vaccines. Optimal conditions for Id sulfhydryl pre-reduction were determined, and maleimide Id-KLH conjugates maintained stability and potency even after prolonged storage. Field flow fractionation analysis of Id-KLH particle size revealed that maleimide conjugates were far more uniform in size than glutaraldehyde conjugates. Under increasingly stringent conditions, maleimide Id-KLH vaccines maintained superior efficacy over glutaraldehyde Id-KLH in treating established, disseminated murine lymphoma. More importantly, human maleimide Id-KLH conjugates were consistently superior to glutaraldehyde Id-KLH conjugates in inducing Id-specific antibody and T cell responses. The described methods should be easily adaptable to the production of clinical grade vaccines for human trials in B cell malignancies.

Sulfhydryl-based tumor antigen-carrier protein conjugates stimulate superior antitumor immunity against B cell lymphomas

Therapeutic vaccination of B cell lymphoma patients with tumor-specific Ig (idiotype, or Id) chemically coupled to the immunogenic foreign carrier protein keyhole limpet hemocyanin (KLH) using glutaraldehyde has shown promising results in early clinical trials, and phase III trials are underway. However, glutaraldehyde Id-KLH vaccines fail to elicit anti-Id immune and clinical responses in many patients, possibly because glutaraldehyde reacts with lysine, cysteine, tyrosine, and histidine residues, damaging critical immunogenic epitopes. A sulfhydryl-based tumor Ag-carrier protein conjugation system using maleimide chemistry was used to enhance the efficacy of Id-KLH vaccines. Maleimide Id-KLH conjugates eradicated A20 lymphoma from most tumor-bearing mice, whereas glutaraldehyde Id-KLH had little efficacy. Maleimide Id-KLH elicited tumor-specific IgG Abs and T cells, with CD8(+) T cells being the major effectors of antilymphoma immunity. Maleimide Id-KLH vaccines also demonstrated superior efficacy in 38C13 and BCL-1 lymphoma models, where Abs were shown to be critical for protection. Importantly, standard glutaraldehyde Id-KLH conjugation procedures could result in "overconjugation" of the tumor Ag, leading to decreased efficacy, whereas the heterobifunctional maleimide-based conjugation yielded potent vaccine product regardless of conjugation duration. Under lysosomal processing conditions, the Id-carrier protein linkage was cleavable only after maleimide conjugation. Maleimide KLH conjugation was easily performed with human Igs analogous to those used in Id-KLH clinical trials. These data support the evaluation of sulfhydryl-based Id-KLH vaccines in lymphoma clinical trials and possibly the use of tumor Ag-carrier protein vaccines for other cancers.

DNA vaccination with CD44 variant isoform reduces mammary tumor local growth and lung metastasis

We have shown recently that cDNA vaccination, using a virtual lymph node, ameliorates experimental allergic encephalomyelitis. Successful cure from mammary tumor requires resolution of local tumor growth and metastases. We have examined whether targeting of CD44 cell surface adhesion molecule by cDNA vaccination plays a role in resolving mammary tumor development. We show here that CD44 cDNA vaccination decreases the tumor mass and metastatic potential in experimental mammary tumor of BALB/c mice. Vaccination of mice, inoculated with the mammary tumors, by cDNA of CD44 variant (CD44v) but not by cDNA of standard CD44, markedly reduced local tumor development and lung metastasis. Concomitantly, transfection of CD44 antisense into a highly metastatic mammary tumor cell line disrupted the CD44 expression of the cells and reduced their ability to establish local tumors as well as metastatic colonies in the lung. Moreover, when CD44v, but not standard CD44 sense cDNA, was transfected into the poorly metastatic cell line, tumor development was markedly enhanced. It is possible therefore that DNA vaccination with a specific CD44v construct could induce an immune resistance to mammary tumor progression.

Models for lymphoma

This unit describes experimental procedures for development of therapeutic vaccines, particularly "second-generation" recombinant vaccines. Specifically, a general procedure for handling and culturing lymphoma cell lines in vitro and their subsequent challenge into syngeneic mice is described. Several protocols describe the production of various idiotype (Id)-based or cellular lymphoma vaccine formulations. In particular, the novel approach of rendering nonimmunogenic lymphoma-derived scFv or Id immunogenic by fusing it with a chemokine moiety is described. As an alternative, a protocol for expression and purification of these chemokine-fusion proteins from E. coli is included. A general procedure is included for cloning of cytokine genes, for example, murine GM-CSF, in A20 lymphoma cells. Support protocols are presented for chemically conjugating intact Ig protein with KLH to produce a prototype protein vaccine and using the Helios Gene Gun System to immunize mice with recombinant DNA tumor vaccines.

Listeriolysin O is an improved protein carrier for lymphoma immunoglobulin idiotype and provides systemic protection against 38C13 lymphoma

Follicular lymphoma (FL) is a disease that responds to current treatment regimens; however, patients in general relapse with increasingly refractory disease. Idiotype-based vaccines are currently under trial for the treatment of FL. These vaccines comprise the patient's BCR idiotype (Id) as the tumor antigen conjugated to the protein carrier Keyhole Limpet Hemocyanin (KLH); however, other protein carriers may enhance the immune response to the lymphoma Id. In this study we investigated whether an alternate carrier, Listeriolysin O (LLO), would amplify the immune response to Id protein and provide better protection against challenge by 38C13 murine lymphoma. The Id-LLO vaccine compared favorably against Id-KLH in tumor-protection studies and both vaccines provided systemic immunity against 38C13 lymphoma. However, the immune response to the two conjugates was different in that Id-LLO induced a more powerful Th1 response characterized by high titer IgG2a anti-Id antibodies after one immunization and the presence of CD4 cells secreting IFN-gamma. In vivo studies demonstrated that immune serum contributed to the anti-lymphoma efficacy seen following Id-LLO immunization. Interestingly, Id-LLO immunized mice, when challenged twice with 38C13 lymphoma provided better protection against challenge by the BCR loss variant 38C13-V2, suggesting that Id-LLO immunized mice have more potential to develop epitope spreading than Id-KLH. In conclusion, Id-LLO compared favorably against Id-KLH in its anti-lymphoma efficacy. Furthermore, Id-LLO induced a more potent humoral and cell-mediated immune response and promoted epitope spreading after lymphoma challenge. Thus, anti-Id vaccines incorporating LLO may be a better therapeutic option for treatment of B-cell lymphoma.

Dendritic cells loaded with apoptotic antibody-coated tumor cells provide protective immunity against B-cell lymphoma in vivo

The in vitro priming of tumor-specific T cells by dendritic cells (DCs) phagocytosing killed tumor cells can be augmented in the presence of antitumor monoclonal antibody (mAb). We investigated whether DCs phagocytosing killed lymphoma cells coated with tumor-specific antibody could elicit antitumor immunity in vivo. Irradiated murine 38C13 lymphoma cells were cocultured with bone marrow-derived DCs in the presence or absence of tumor-specific mAb. Mice vaccinated with DCs cocultured with mAb-coated tumor cells were protected from tumor challenge (60% long-term survival), whereas DCs loaded with tumor cells alone were much less effective. The opsonized whole tumor cell-DC vaccine elicited significantly better tumor protection than a traditional lymphoma idiotype (Id) protein vaccine, and in combination with chemotherapy could eradicate preexisting tumor. Moreover, the DC vaccine protected animals from both wild-type and Id-negative variant tumor cells, indicating that Id is not a major target of the induced tumor immunity. Protection was critically dependent upon CD8(+) T cells, with lesser contribution by CD4(+) T cells. Importantly, opsonized whole tumor cell-DC vaccination did not result in tissue-specific autoimmunity. Since opsonized whole tumor cell-DC and Id vaccines appear to target distinct tumor antigens, optimal antilymphoma immunity might be achieved by combining these approaches.

Environmental enrichment augments the efficacy of idiotype vaccination for B-cell lymphoma

Environmental enrichment is known to positively influence the organism's psychologic and physiologic well-being. However, the effects of environmental enrichment on immune responses and cancer prognosis have not been clearly established and its impact on cancer therapy is unknown. Here, we report that environmental enrichment mediated a statistically significant improvement of the outcome of immunotherapy in an experimental model of B-cell lymphoma. When mice were immunized with an idiotype-vaccine, those maintained under enriched environmental conditions produced statistically significant higher levels of anti-idiotype antibodies and revealed more attenuated tumor growth than those housed in standard environments. Most strikingly, enriched tumor-bearing mice had statistically significant prolonged survival, with 44% of them disease-free compared with 0% in the standard rearing tumor-bearing mice. The possible mechanisms for the enhancement of immunotherapy by environmental enrichment are cognitive, physical activity, and psychologic. The demonstration of synergistic effect of cancer therapy and environmental enrichment on tumor rejection has important implication for cancer treatment.

Cell-free production of scFv fusion proteins: an efficient approach for personalized lymphoma vaccines

The unique immunoglobulin (Ig) idiotype on the surface of each B-cell lymphoma represents an ideal tumor-specific antigen for use as a therapeutic vaccine. We have used an Escherichia coli-based, cell-free protein-expression system to produce a vaccine within hours of cloning the Ig genes from a B-cell tumor. We demonstrated that a fusion protein consisting of an idiotypic single chain Fv antibody fragment (scFv) linked to a cytokine (GM-CSF) or to an immunostimulatory peptide was an effective lymphoma vaccine. These vaccines elicited humoral immune responses against the native Ig protein displayed on the surface of a tumor and protected mice against tumor challenge with efficacy equal to that of the conventional Ig produced in a mammalian cell and chemically coupled to keyhole limpet hemocyanin. The cell-free E coli system offers a platform for rapidly generating individualized vaccines, thereby allowing much more efficient application in the clinic.

B-cell lymphoma and myeloma protection induced by idiotype vaccination with dendritic cells is mediated entirely by T cells in mice

Immunoglobulin idiotypes (Id) of malignant B cells are tumor-specific antigens that may be targeted for immunotherapy. Id-directed immunotherapy by immunization with autologous Id has been initiated in clinical trials to control residual disease in B-cell lymphoma and multiple myeloma. The effector mechanisms responsible for destruction of B-cell tumors are a controversial issue. The authors show that vaccination with Id-pulsed dendritic cells (DCs) or with soluble Id-KLH in adjuvant induced immune responses that eliminated both B-cell lymphoma and myeloma in tumor-bearing mice; however, the two vaccination regimens resulted in distinct immune responses. Whereas soluble Id plus adjuvant induced high levels of anti-Id antibodies, the Id-pulsed DCs did not induce anti-Id or any antitumor antibodies. Immunization with Id-pulsed DCs induced a significant increase in the frequency of Id-reactive T cells. Depletion studies in DC-vaccinated mice showed that the predominant effector cells responsible for tumor rejection were of the CD8 subset. The finding that DC-based Id vaccines elicit tumor protection, which is entirely based on cell-mediated effector mechanisms, is of particular importance for plasma cell tumors because these tumors do not express Id on the surface and hence do not bind anti-Id antibodies.

Anti-idiotypic antibody as a potential candidate vaccine for Neisseria meningitidis serogroup B

Sepsis and meningitis caused by Neisseria meningitidis serogroup B (NMGB) are serious diseases in infants and young adults, but no effective vaccine is available. The capsular polysaccharide (PS) of NMGB has poor immunogenicity and a structural similarity to polysialic acid (PSA) on neuronal tissue that may elicit autoantibodies. Using HmenB3, a protective and nonautoreactive monoclonal antibody (MAb) to NMGB capsular PS, we produced an anti-idiotypic MAb, Naid60, which mimics the capsular PS of NMGB. We produced an anti-anti-idiotypic MAb, MoB34, by using the immunogenic site on Naid60 responsible for inducing the anti-NMGB PS antibody response. MoB34 elicited the complement-mediated killing of representative strains of serogroup B meningococci. MoB34 did not bind to CHP-134, a neuroblastoma cell line expressing alpha(2-8) PSA, or to mouse brain cryosections at a high concentration. Naid60-keyhole limpet hemocyanin immunization inhibited the growth of live NMGB in intraperitoneally challenged mice; in contrast, three of five control mice developed bacteremia. Thus, Naid60 has an immunogenic site that elicits antibodies with bactericidal activity against NMGB and no autoimmunity to PSA. We suggest that the immunogenic region of Naid60 is a candidate for the development of a new vaccine against NMGB.

A new multi-parameter flow cytometric assay for monitoring lymphoma growth and spread in a pre-clinical murine model for human lymphoma

BACKGROUND

Mouse survival is commonly used as an indirect measure of lymphoma tumor response to anti-idiotype vaccine; however, this gives no information regarding residual lymphoma cells at primary or metastatic sites. We aimed to develop a method with which to monitor lymphoma tumor kinetics in the mouse as an independent measure of vaccine efficacy.

METHODS

We developed a multi-parameter flow cytometric (MPFC) assay for 38C13 mouse lymphoma cells using sequential gating to detect aberrant antigen expression and binding by an anti-idiotype antibody (S1C5). Subsequently, we tested the utility of the MPFC assay in a 38C13 tumor modeling study in the C3H/HeN mouse.

RESULTS

The MPFC assay was demonstrated in vitro to have both high specificity and sensitivity for 38C13 lymphoma cells. In tumor kinetic studies in the C3H/HeN mouse, as the tumor enlarged, the MPFC assay showed increasing prevalence of 38C13 cells at the inoculation site in addition to metastases to lymphoid organs and bone marrow. The latter findings were confirmed by both histology and immunohistochemistry.

CONCLUSIONS

The MPFC assay is an independent parameter for monitoring 38C13 lymphoma kinetics and could be used to monitor tumor response to individual vaccines or other lymphoma therapy prior to clinical trials.

RHAMM, a receptor for hyaluronan-mediated motility, compensates for CD44 in inflamed CD44-knockout mice: a different interpretation of redundancy

We report here that joint inflammation in collagen-induced arthritis is more aggravated in CD44-knockout mice than in WT mice, and we provide evidence for molecular redundancy as a causal factor. Furthermore, we show that under the inflammatory cascade, RHAMM (receptor for hyaluronan-mediated motility), a hyaluronan receptor distinct from CD44, compensates for the loss of CD44 in binding hyaluronic acid, supporting cell migration, up-regulating genes involved with inflammation (as assessed by microarrays containing 13,000 cDNA clones), and exacerbating collagen-induced arthritis. Interestingly, we further found that the compensation for loss of the CD44 gene does not occur because of enhanced expression of the redundant gene (RHAMM), but rather because the loss of CD44 allows increased accumulation of the hyaluronic acid substrate, with which both CD44 and RHAMM engage, thus enabling augmented signaling through RHAMM. This model enlightens several aspects of molecular redundancy, which is widely discussed in many scientific circles, but the processes are still ill defined.

Anti-idiotype x anti-CD44 bispecific antibodies inhibit invasion of lymphoid organs by B cell lymphoma

The demonstration that Abs to adhesion molecules can block tumor metastasis suggested their use for therapy. However, such Abs affect nonmalignant cells as well. To circumvent this adverse effect, we proposed the use of bispecific Abs that bind simultaneously to an adhesion receptor and to a tumor-specific Ag. Such bifunctional Abs bind more avidly to tumor cells that coexpress both target Ags than to normal cells. The Id of the surface Ig of malignant B lymphocytes is a tumor-specific Ag. Therefore, we produced bispecific Abs with specificity to the adhesion molecule, CD44, and to an idiotypic determinant of the murine B cell lymphoma, 38C-13. These anti-Id x anti-CD44 bispecific Abs blocked 38C-13 cell adhesion to hyaluronic acid, while not affecting adhesion of Id-negative cells. In vivo studies demonstrated that the bispecific Abs inhibited lymphoma cell dissemination to the lymph nodes, bone marrow, and spleen, and prolonged survival of tumor-bearing mice. Migration of 38C-13 cells to the lymphoid organs was inhibited by the bispecific Abs. Thus, the bispecific Ab-mediated reduction in metastasis resulted, at least in part, from reduced homing to these organs. In contrast to anti-CD44 monospecific Abs, the anti-Id x anti-CD44 bispecific Abs did not affect immune responses such as delayed-type hypersensitivity. Hence, bispecific Abs against adhesion molecules and tumor-specific Ags may selectively block tumor metastasis in a way which may leave at least part of the immune system intact.

The history, evolution, and clinical use of dendritic cell-based immunization strategies in the therapy of brain tumors

Despite advancements in therapeutic regimens, the prognosis remains poor for patients with malignant gliomas. Specificity has been an elusive goal for current modalities, but immunotherapy has emerged as a potential means of designing more tumor-specific treatments. Dendritic cells (DC) are the specialized antigen presenting cells of the immune system and have served now as a platform for therapeutic immunizations against such cancers as lymphoma, multiple myeloma, melanoma, prostate cancer, renal cell carcinoma, non-small cell lung carcinoma, colon cancer, and even malignant gliomas. DC-based immunizations offer a number of advantages over traditional immunotherapeutic approaches to brain tumors, approaches that have proved promising despite concerns over central nervous system immune privilege and glioma-mediated immunosuppression. The future success of clinical trials will depend on the optimization and standardizing of procedures for DC generation, loading, and administration.

A complicated relationship: fulfilling the interactive needs of the T lymphocyte and the dendritic cell

T cells recognize antigenic peptides displayed on the surface of MHC-bearing antigen-presenting cells (APCs), and with sufficient costimulation become activated. However, the ability of an APC (even bearing the correct peptide) to initiate and fulfill the requirements for T cell activation is not easily achieved. Naive T cells use multiple copies of a single receptor to survey the vast array of peptides presented on an APC, and require multiple receptor engagements to initiate T cell activation. Dendritic cells (DCs) are specialized cells with optimal capabilities for priming naive CD4+ T cells. Activation occurs, after initial antigen recognition by T cells, followed by a rapid dialogue between the T cells and the DCs. The resulting changes in both the cytoskeleton and the expression or regulation of cell-surface molecules on both cell types act to further strengthen engagement. In this report, we review the fundamentals of CD4+ T helper cell : DC interactions and discuss recent data concerning the molecular characteristics of this engagement.

Anti-idiotype x anti-LFA-1 bispecific antibodies inhibit metastasis of B cell lymphoma

Abs to adhesion molecules can block tumor metastasis. However, they may also block the function of normal cells. To circumvent this adverse effect, we proposed the use of bispecific Abs that bind simultaneously to an adhesion receptor and to a tumor-specific Ag. Such Abs bind more avidly to tumor cells that coexpress both target Ags than to normal cells. The Id of the surface Ig of malignant B lymphocytes is a tumor-specific Ag. We therefore produced a bispecific Ab with specificity to the adhesion molecule LFA-1 and to the Id of the murine B cell lymphoma 38C-13. Here we demonstrate that this Ab blocked liver metastasis in mice carrying primary s.c. tumors and partially inhibited lymph node metastasis. Migration of 38C-13 cells to liver and lymph nodes was inhibited by the bispecific Ab, while migration to spleen was not affected. Hence, the bispecific Ab-mediated reduction in liver and lymph node metastasis resulted at least in part from reduced homing to these organs. In contrast to anti-LFA-1 monospecific Abs, the anti-Id x anti-LFA-1 bispecific Ab did not affect immune responses such as delayed-type hypersensitivity. Hence, bispecific Abs against adhesion molecules and against tumor-specific Ags may selectively block tumor metastasis in a way that may leave much of the immune system intact.

Improved immunogenicity of a self tumor antigen by covalent linkage to CD40 ligand

The interaction between the CD40 ligand (CD40L) and CD40 on antigen-presenting cells (APCs) is critical in promoting humoral and cellular immune responses. Agonistic anti-CD40 monoclonal antibody and soluble CD40L can act as powerful adjuvants to promote vaccination, but usually require repeated high-dose treatment. In this study, we demonstrate that the adjuvant effect of CD40L can be greatly improved by directly linking the antigen to CD40L. We constructed a fusion protein (Id-CD40L) consisting of the extracellular domain of CD40L and the idiotype (Id) protein, a weakly immunogenic tumor-specific antigen derived from the murine 38C13 B-cell lymphoma. The soluble Id-CD40L fusion protein retained CD40 binding activity and stimulated CD80 and CD86 upregulation and interleukin (IL)-12 production by macrophages. Immunization of mice with Id-CD40L without adjuvants resulted in high titers of anti-Id Abs dominated by the IgG1 isotype and protected the mice from subsequent lethal tumor challenge. In a dose-response study, we demonstrated that Id-CD40L elicited anti-Id antibody (Ab) responses in all immunized animals, even at a dose as low as 0.5 microg. Immunization with free Id and an IgG-CD40L fusion protein, which was identical in structure to Id-CD40L but lost the Id determinant, resulted in significant lower anti-Id responses, indicating that physical linkage between the tumor antigen and CD40L was required for the optimal immune response. These results demonstrate that fusing CD40L to a candidate antigen can greatly improve the adjuvant activity of CD40L. This approach may be useful in developing vaccines for a variety of malignant and infectious diseases.

Antigen-specific regulatory T cells develop via the ICOS-ICOS-ligand pathway and inhibit allergen-induced airway hyperreactivity

Asthma is caused by T-helper cell 2 (Th2)-driven immune responses, but the immunological mechanisms that protect against asthma development are poorly understood. T-cell tolerance, induced by respiratory exposure to allergen, can inhibit the development of airway hyperreactivity (AHR), a cardinal feature of asthma, and we show here that regulatory T (T(R)) cells can mediate this protective effect. Mature pulmonary dendritic cells in the bronchial lymph nodes of mice exposed to respiratory allergen induced the development of T(R) cells, in a process that required T-cell costimulation via the inducible costimulator (ICOS-ICOS-ligand pathway. The T(R) cells produced IL-10, and had potent inhibitory activity; when adoptively transferred into sensitized mice, T(R) cells blocked the development of AHR. Both the development and the inhibitory function of regulatory cells were dependent on the presence of IL-10 and on ICOS-ICOS-ligand interactions. These studies demonstrate that T(R) cells and the ICOS-ICOS-ligand signaling pathway are critically involved in respiratory tolerance and in downregulating pulmonary inflammation in asthma.

Enhancing tumor targeting and apoptosis using noncovalent antibody homodimers

A rare type of antibody that spontaneously binds to each self (homodimerizes) has been described. This self-binding (autophilic) antibody provides stronger protection against bacterial infection than a non self-binding antibody with identical specificity and affinity due to increase of polymeric avidity. A peptide derived from the self-binding domain of the autophilic antibody was crosslinked to the Fc carbohydrate of two monoclonal antibodies specific for the B-cell receptor (BCR) of a murine and a human B-cell tumor. Peptide-crosslinked antibodies bind to themselves on solid phase ELISA as homodimer and establish in solution a monomer-dimer equilibrium. Autophilic antibodies bind to their respective tumor target cells with increased efficiency as determined by FACS analysis. They also induce twice the amount of apoptosis of target tumor cells than the control antibodies. Furthermore, the modified antibodies inhibit tumor growth in culture more efficiently than the control antibodies. Criss-cross protocols in FACS, apoptosis, and growth inhibition indicate the specificity of targeting the BCR with autophilic antitumor antibodies. The chemical approach of increasing the binding of antibodies without creating chemically crosslinked dimers mimics naturally occurring autophilic antibodies and represents a simple and attractive alternative to chemical dimerizing and antibody engineering techniques for improving their antitumor effect. Furthermore, these results provide a guide to incorporate the self-binding peptide into the structure of antibodies using modeling and molecular crafting techniques.

Developmental differences in B cell receptor-induced signal transduction

We have compared early signaling events at various stages of B cell differentiation using established mouse cell lines. Clustering of pre-B cell antigen receptor (BCR) or BCR induced the tyrosine phosphorylation of various proteins in all cells, although the phosphorylation pattern differed. In spite of the pre-BCR-induced tyrosine phosphorylation, we could not detect an intracellular Ca(2+) signal in pre-B cells. However, co-clustering of the pre-BCR with CD19 did induce Ca(2+) mobilization. In contrast to the immature and mature B cells, where the B cell linker protein (BLNK) went through inducible tyrosine phosphorylation upon BCR clustering, we observed a constitutive tyrosine phosphorylation of BLNK in pre-B cell lines. Both BLNK and phospholipase C (PLC)gamma were raft associated in unstimulated pre-B cells, and this could not be enhanced by pre-BCR engagement, suggesting a ligand-independent PLC gamma-mediated signaling. Further results indicate that the cell lines representing the immature stage are more sensitive to BCR-, CD19- and type II receptors binding the Fc part of IgG (Fc gamma RIIb)-mediated signals than mature B cells.

Carcinoembryonic antigen as a target for therapeutic anticancer vaccines: a review

PURPOSE

To describe the features of carcinoembryonic antigen (CEA) that are important for its use in vaccination approaches and review the clinical experience with therapeutic vaccines targeting CEA.

METHODS

A PubMed search was performed on CEA, along with various qualifiers such as cancer vaccines, epitopes, and function. Relevant articles were reviewed.

RESULTS

CEA is a member of the immunoglobulin supergene family and may play a role in tumorigenesis. CEA protein is processed and presented on major histocompatibility complex (MHC) proteins for multiple alleles, including HLA A2, A3, and A24. T lymphocytes from healthy volunteers and cancer patients can recognize the processed epitopes of CEA and can become activated to lyse CEA-expressing tumors. Therapeutic vaccination approaches that have targeted CEA include vaccination with recombinant CEA protein, CEA anti-idiotype antibodies, and dendritic cells pulsed with agonist epitopes of CEA. Humoral responses have predominantly been induced with the first two approaches, whereas CD4 and CD8 responses, disease stabilization, and even objective clinical responses have been seen with the dendritic cell approach. Recently, CEA-poxvirus vectors encoding CEA and costimulatory molecules such as B7.1 have been shown to be safe and to induce increases in the frequency of T-cell precursors that recognize processed epitopes of CEA presented on MHC class 1 molecules. Disease stabilization has been seen in up to 37% of patients treated with these vaccines.

CONCLUSION

Tolerance to CEA in patients with cancer can be overcome with several different vaccination approaches, and such vaccinations are safe and immunologically active. Poxvirus-based vaccines can reproducibly generate T-cell responses to CEA and to tumors expressing CEA. Clinical activity has been seen with poxvirus or dendritic cell approaches. Other approaches are also being explored.

CD44 co-stimulates apoptosis in thymic lymphomas and T cell hybridomas

Thymic lymphomas and hybridomas vary in their sensitivity to dexamethasone (DEX). Identical variance has been demonstrated in our laboratory for apoptosis of such cells by primary thymic epithelial cells or a cell line (TEC). We have also shown that apoptosis induced by TEC was partially mediated by TEC-derived glucocorticoids (GC). We studied the responses of various thymic lymphomas and hybridomas to TEC and DEX. Of these cells, PD1.6 and 2B4 were sensitive whereas B10 were relatively resistant to either inducer. In the present study we found that TEC and DEX synergize in inducing B10 cell apoptosis. B10 cells could also undergo apoptosis by TEC, conditional upon the presence of a TEC-sensitive cell (PD1.6 or 2B4). Contact between TEC and B10 was essential for apoptosis to occur. Thus, TEC may provide two signals, one mediated by GC and the other requiring cell to cell contact. We then analyzed the involvement of co-stimulatory or adhesion molecules in the TEC-induced apoptosis of thymic lymphoma cells. Soluble anti-CD44 antibodies but not anti-CD18, CD2 or CD28, inhibited TEC-induced apoptosis of PD1.6. Dimerization of CD44 by immobilized antibodies augmented DEX-induced apoptosis of all the lymphomas tested. CD44 cross-linkage up-regulated expression of the pro-apoptotic protein Bax, and down-regulated the anti-apoptotic protein, Bclx(L), in the presence of DEX. Taken together, the data suggest that CD44 enhances the apoptotic response of T lymphoma cells to DEX, and that CD44 modulates TEC-induced apoptosis of thymic lymphomas.

The development of a bicistronic plasmid DNA vaccine for B-cell lymphoma

Tumor vaccines are a promising alternative to chemotherapy for the treatment of metastatic cancer. To be effective and safe, a therapeutic cancer vaccine should specifically target antigens expressed only on metastatic tumor cells. A vaccine directed against the unique surface immunoglobulin or idiotype expressed on non-Hodgkin's B-cell lymphoma fulfills these criteria, as both primary and metastatic tumor cells express tumor specific immunoglobulins. Using the murine 38C13 B-cell lymphoma tumor as a model system, a plasmid DNA vaccine was designed to express a bicistronic mRNA encoding both the light and heavy tumor immunoglobulin (idiotype) proteins expressed on the surface of the 38C13 tumor. To increase the immunogenicity of the plasmid DNA vaccine, each of the murine variable domains (light and heavy) were fused to their respective human immunoglobulin constant domains. In addition, a eukaryotic expression cassette was constructed to effect both high-level expression of the mouse/human chimeric immunoglobulin, and to elicit a protective immune response in vivo. Unique Sfi I restriction sites were used for the rapid cloning of any tumor specific immunoglobulin idiotype domains and a series of plasmid constructs were made to test changes to the J domain and/or the human C domain to insert the Sfi I restriction sites. Such changes were found to have significant effects on both expression and immunogenicity. Vaccination of mice with prototype idiotype vaccines was found to generate a protective immune response to the 38C13 tumor. This study indicates that a novel bicistronic plasmid DNA-based vaccine can be used to develop a tumor specific vaccine against B-cell lymphoma.

Critical role for IL-13 in the development of allergen-induced airway hyperreactivity

Airway hyperresponsiveness to a variety of specific and nonspecific stimuli is a cardinal feature of asthma, which affects nearly 10% of the population in industrialized countries. Eosinophilic pulmonary inflammation, eosinophil-derived products, as well as Th2 cytokines IL-13, IL-4, and IL-5, have been associated with the development of airway hyperreactivity (AHR), but the specific immunological basis underlying the development of AHR remains controversial. Herein we show that mice with targeted deletion of IL-13 failed to develop allergen-induced AHR, despite the presence of vigorous Th2-biased, eosinophilic pulmonary inflammation. However, AHR was restored in IL-13(-/-) mice by the administration of recombinant IL-13. Moreover, adoptive transfer of OVA-specific Th2 cells generated from TCR-transgenic IL-13(-/-) mice failed to induce AHR in recipient SCID mice, although such IL-13(-/-) Th2 cells produced high levels of IL-4 and IL-5 and induced significant airway inflammation. These studies definitively demonstrate that IL-13 is necessary and sufficient for the induction of AHR and that eosinophilic airway inflammation in the absence of IL-13 is inadequate for the induction of AHR. Therefore, treatment of human asthma with antagonists of IL-13 may be very effective.

CD44-dependent lymphoma cell dissemination: a cell surface CD44 variant, rather than standard CD44, supports in vitro lymphoma cell rolling on hyaluronic acid substrate and its in vivo accumulation in the peripheral lymph nodes

Cell motility is an essential element of tumor dissemination, allowing organ infiltration by cancer cells. Using mouse LB lymphoma cells transfected with standard CD44 (CD44s) cDNA (LB-TRs cells) or with the alternatively spliced CD44 variant CD44v4-v10 (CD44v) cDNA (LB-TRv cells), we explored their CD44-dependent cell migration. LB-TRv cells, but not LB-TRs or parental LB cells, bound soluble hyaluronic acid (HA) and other glycosaminoglycans (GAGs), and exclusively formed, under physiological shear force, rolling attachments on HA substrate. Furthermore, LB-TRv cells, but not LB-TRs cells or their parental LB cells, displayed accelerated local tumor formation and enhanced accumulation in the peripheral lymph nodes after s.c. inoculation. The aggressive metastatic behavior of i.v.-injected LB-TRV cells, when compared with that of other LB-transfectants, is attributed to more efficient migration to the lymph nodes, rather than to local growth in the lymph node. Injection of anti-CD44 monoclonal antibody or of the enzyme hyaluronidase also prevented tumor growth in lymph nodes of BALB/c mice inoculated with LB-TRv cells. The enhanced in vitro rolling and enhanced in vivo local tumor growth and lymph node invasion disappeared in LB cells transfected with CD44v cDNA bearing a point mutation at the HA binding site, located at the distal end of the molecule constant region. These findings show that the interaction of cell surface CD44v with HA promotes cell migration both in vitro and in vivo, and they contribute to our understanding of the mechanism of cell trafficking, including tumor spread.

Pulmonary dendritic cells producing IL-10 mediate tolerance induced by respiratory exposure to antigen

Respiratory exposure to allergen induces T cell tolerance and protection against the development of airway hyperreactivity and asthma. However, the specific mechanisms by which tolerance is induced by respiratory allergen are not clear. We report here that pulmonary dendritic cells (DCs) from mice exposed to respiratory antigen transiently produced interleukin 10 (IL-10). These phenotypically mature pulmonary DCs, which were B-7(hi) as well as producing IL-10, stimulated the development of CD4(+) T regulatory 1--like cells that also produced high amounts of IL-10. In addition, adoptive transfer of pulmonary DCs from IL-10(+/+), but not IL-10(-/-), mice exposed to respiratory antigen induced antigen-specific unresponsiveness in recipient mice. These studies show that IL-10 production by DCs is critical for the induction of tolerance, and that phenotypically mature pulmonary DCs mediate tolerance induced by respiratory exposure to antigen.

Chemical engineering of cell penetrating antibodies

Antibodies, being exquisitely specific tools in biology, are routinely used to detect and identify intra-cellular structures. However, current intra-cellular application of antibodies requires that the membrane be rendered leaky, resulting in the death of cells. Here, we present a novel method to allow antibodies to penetrate the cellular membrane of living cells without affecting cell viability. A peptide (MTS, membrane transport sequence) that facilitates transport across membranes has been site-specifically attached to antibodies. MTS-antibodies enter the living cells in culture and can be detected by immunofluorescence and ELISA after extraction. Cellular structures are visualized in living cells using a specific MTS-antibody. Antibodies with membrane penetrating properties can become an important tool for the study of intra-cellular processes in living cells. Furthermore, such membrane penetrating antibodies can be used to selectively stimulate or suppress functions of the cellular machinery.

Il-18 gene transfer by adenovirus prevents the development of and reverses established allergen-induced airway hyperreactivity

We examined the role of IL-18 in preventing the development of and in reversing established allergen-induced airway inflammation and airway hyperreactivity (AHR), the cardinal features of asthma. IL-18, which potently induces IFN-gamma, was administered into the respiratory tract as cDNA in a replication-deficient adenovirus (Adv). Treatment of OVA-sensitized mice with the IL-18-expressing Adv reduced allergen-specific IL-4 production, airway eosinophilia, and mucus production, increased IFN-gamma production, and prevented the development of AHR. The effects of the IL-18 Adv treatment were dependent on the presence of IFN-gamma and IL-12. Moreover, administration of the IL-18 Adv to mice with established AHR greatly reduced AHR and IL-4 production and increased IFN-gamma production. These results demonstrate that IL-18, when administered by Adv into the respiratory tract, effectively reduces AHR and replaces an established Th2-biased immune response with a Th1-biased response.

Idiotype-encoding recombinant adenoviruses provide protective immunity against murine B-cell lymphomas

Vaccination with tumor-specific immunoglobulin or idiotype (Id) is a promising new form of immunotherapy for B-cell malignancies. Id protein vaccination has demonstrated clinical activity in B-cell lymphomas, yet it requires the laborious and time-consuming procedures of tumor-myeloma cell hybridization, large-scale in vitro culture, and protein purification. Recombinant adenoviruses are highly efficient and immunogenic gene transfer vehicles from which individualized vaccines can be rapidly assembled using polymerase chain reaction-amplified tumor Id genes. Id-encoding adenoviruses were evaluated as vaccines in 2 murine B-cell lymphoma models. A single injection of recombinant Id adenovirus provided protection from subsequent tumor challenge that was equivalent or superior to that afforded by Id protein vaccination. Protected mice had substantial serum titers of Id-specific antibodies. When used in conjunction with chemotherapy, vaccination also prolonged the survival of mice bearing pre-existing tumor. Mechanistic studies demonstrated that tumor protection was not dependent upon T cells. Importantly, in mice prevaccinated with an irrelevant adenovirus, tumor protection following vaccination with Id adenovirus was not significantly impaired. These findings have implications for the design of future lymphoma immunotherapy trials.

Enhanced antitumor immunity by fusion of CTLA-4 to a self tumor antigen

The idiotypic determinant (Id) of the immunoglobulin expressed by a B-cell malignancy can serve as an effective tumor-specific antigen but is only weakly immunogenic. This study demonstrates that the immunogenicity of the tumor Id protein can be dramatically increased by directing it to antigen-presenting cells (APCs). Cytotoxic T-lymphocyte antigen 4 (CTLA-4) present on activated T cells has a strong binding affinity to both B7-1 and B7-2 molecules, which are primarily expressed on APCs. After construction of a fusion protein consisting of Id and CTLA-4 (Id-CTLA4), mice immunized with the fusion protein induced high titers of Id-specific antibody and T-cell proliferative responses without adjuvants and were protected from lethal tumor challenge. The Id-CTLA4 fusion protein was so potent that even low doses (down to 0.1 μg) of the immunogen were able to elicit strong antibody responses. By using an Id-CTLA4 mutant protein, the ability to bind B7 molecules on APCs was shown to be required for the enhanced immunogenicity of Id-CTLA4. These findings demonstrate that fusing CTLA-4 to a potential tumor antigen represents an effective approach to prime antitumor immunities in vivo and may be applicable to the design of vaccines for a variety of other diseases.

Enhanced antitumor immunity by fusion of CTLA-4 to a self tumor antigen

The idiotypic determinant (Id) of the immunoglobulin expressed by a B-cell malignancy can serve as an effective tumor-specific antigen but is only weakly immunogenic. This study demonstrates that the immunogenicity of the tumor Id protein can be dramatically increased by directing it to antigen-presenting cells (APCs). Cytotoxic T-lymphocyte antigen 4 (CTLA-4) present on activated T cells has a strong binding affinity to both B7-1 and B7-2 molecules, which are primarily expressed on APCs. After construction of a fusion protein consisting of Id and CTLA-4 (Id-CTLA4), mice immunized with the fusion protein induced high titers of Id-specific antibody and T-cell proliferative responses without adjuvants and were protected from lethal tumor challenge. The Id-CTLA4 fusion protein was so potent that even low doses (down to 0.1 μg) of the immunogen were able to elicit strong antibody responses. By using an Id-CTLA4 mutant protein, the ability to bind B7 molecules on APCs was shown to be required for the enhanced immunogenicity of Id-CTLA4. These findings demonstrate that fusing CTLA-4 to a potential tumor antigen represents an effective approach to prime antitumor immunities in vivo and may be applicable to the design of vaccines for a variety of other diseases.

Dendritic cells in cancer immunotherapy

The potential to harness the potency and specificity of the immune system underlies the growing interest in cancer immunotherapy. One such approach uses bone marrow-derived dendritic cells, phenotypically distinct and extremely potent antigen-presenting cells, to present tumor-associated antigens and thereby generate tumor-specific immunity. Support for this strategy comes from animal studies that have demonstrated that dendritic cells, when loaded ex vivo with tumor antigens and administered to tumor-bearing hosts, can elicit T cell-mediated tumor destruction. These observations have led to clinical trials designed to investigate the immunologic and clinical effects of antigen-loaded dendritic cells administered as a therapeutic vaccine to patients with cancer. In the design and conduct of such trials, important considerations include antigen selection, methods for introducing the antigen into MHC class I and II processing pathways, methods for isolating and activating dendritic cells, and route of administration. Although current dendritic cell-based vaccination methods are cumbersome, promising results from clinical trials in patients with malignant lymphoma, melanoma, and prostate cancer suggest that immunotherapeutic strategies that take advantage of the antigen presenting properties of dendritic cells may ultimately prove both efficacious and widely applicable to human tumors.

Secondary V(D)J rearrangements and B cell receptor-mediated down-regulation of recombination activating gene-2 expression in a murine B cell line

It has recently become clear that recombination of Ig genes is not restricted to B cell precursors but that secondary rearrangements can also occur under certain conditions in phenotypically immature bone marrow and peripheral B cells. However, the nature of these cells and the regulation of secondary V(D)J recombination in response to B cell receptor (BCR) stimulation remain controversial. In the present study, we have analyzed secondary light chain gene rearrangements and recombination activating gene (RAG) expression in the surface IgM+, IgD- murine B cell line, 38C-13, which has previously been found to undergo kappa light chain replacement. We find that 38C-13 cells undergo spontaneous secondary Vkappa-Jkappa and RS rearrangements in culture, with recombination occurring on both productive and nonproductive alleles. Both 38C-13 cells and the Id-negative variants express the RAG genes, indicating that the presence of RAG does not depend on activation via the 38C-13 BCR. Moreover, BCR cross-linking in 38C-13 cells leads to a rapid and reversible down-regulation of RAG2 mRNA. Therefore, 38C-13 cells resemble peripheral IgM+, IgD- B cells undergoing light chain gene rearrangement and provide a possible in vitro model for studying peripheral V(D)J recombination.

CpG oligodeoxynucleotides enhance monoclonal antibody therapy of a murine lymphoma

Bacterial DNA and synthetic oligodeoxynucleotides containing unmethylated cytosine-guanine dinucleotides known as cytosine phosphorothioate guanine oligodeoxynucleotides (CpG ODN) can activate various immune-cell subsets, including cells that participate in antibody-dependent cell-mediated cytotoxicity (ADCC). Studies have shown that CpG ODN enhance the efficacy of antitumor monoclonal antibody (MoAb) therapy in the 38C13 murine B-cell lymphoma. We performed a series of in vivo experiments using this tumor model to better characterize combination therapy with MoAb and CpG ODN. CpG ODN enhanced the efficacy of MoAb therapy of lymphoma in a dose-dependent manner. This effect was seen whether the CpG ODN was given before or after the MoAb therapy, but was decreased when CpG ODN was given more than 2 days after MoAb therapy. Three doses of CpG ODN and MoAb were more effective than single doses. There was no obvious toxicity with multiple dosing. These studies confirm that immunostimulatory CpG ODN enhance the efficacy of MoAb therapy, and that multiple courses of combination therapy with CpG ODN can serve as an effective therapy for lymphoma. Further exploration of this potentially potent combination of treatments, including clinical evaluation, is indicated.

Activation of lymphocytes by anti-CD3 single-chain antibody dimers expressed on the plasma membrane of tumor cells

Activation of cytotoxic T cells without MHC restriction was attempted by expressing single-chain antibodies (scFv) against CD3 on the surface of tumor cells. A chimeric protein consisting of a scFv of mAb 145.2C11, the hinge-CH2-CH3 region of human IgG1, and the transmembrane and cytosolic domains of murine CD80 formed disulfide-linked dimers on the plasma membrane of cells and specifically bound lymphocytes. Anti-CD3 scFv dimers expressed on the cell surface induced CD25 (IL-2 receptor alpha-chain) expression and proliferation of splenocytes. CT26 tumor cells engineered to express surface scFv dimers (CT26/2C11) also induced potent lymphocyte cytotoxicity with or without addition of exogenous IL-2. Splenocytes activated by CT26/2C11 cells also killed wild-type CT26 cells, indicating that activated splenocytes could kill bystander tumor cells. Immunization of BALB/c mice with irradiated CT26/2C11 cells did not protect against a lethal challenge of CT26 cells, suggesting that systemic immunity was not induced. However, the growth of CT26 tumors containing 50% CT26/2C11 cells was significantly retarded compared with CT26 tumors, whereas CT26/2C11 tumors did not grow in syngeneic mice. These results suggest that expression of anti-CD3 scFv dimers on tumors may form the basis for a novel therapeutic strategy for tumors that exhibit defects in antigen processing or presentation. Gene Therapy (2000) 7, 339-347.

Induction of resistance to diabetes in non-obese diabetic mice by targeting CD44 with a specific monoclonal antibody

Inflammatory destruction of insulin-producing beta cells in the pancreatic islets is the hallmark of insulin-dependent diabetes mellitus, a spontaneous autoimmune disease of non-obese diabetic mice resembling human juvenile (type I) diabetes. Histochemical analysis of diabetic pancreata revealed that mononuclear cells infiltrating the islets and causing autoimmune insulitis, as well as local islet cells, express the CD44 receptor; hyaluronic acid, the principal ligand of CD44, is detected in the islet periphery and islet endothelium. Injection of anti-CD44 mAb 1 hr before cell transfer of diabetogenic splenocytes and subsequently on alternate days for 4 weeks induced considerable resistance to diabetes in recipient mice, reflected by reduced insulitis. Contact sensitivity to oxazolone was not influenced by this treatment. A similar antidiabetic effect was observed even when the anti-CD44 mAb administration was initiated at the time of disease onset: i.e., 4-7 weeks after cell transfer. Administration of the enzyme hyaluronidase also induced appreciable resistance to insulin-dependent diabetes mellitus, suggesting that the CD44-hyaluronic acid interaction is involved in the development of the disease. These findings demonstrate that CD44-positive inflammatory cells may be a potential therapeutic target in insulin-dependent diabetes.