Induction of cytotoxicity in human T cells coated with anti-glioma x anti-CD3 bispecific antibody against human glioma cells

Targeting therapy for glioma by LAK cells coupled with bispecific antibodies

Targeting of T cells or natural killer (NK) cells to tumours by using bispecific antibodies has attracted increasing interest in the past few years. We treated 31 patients with malignant glioma using adoptive transfer of lymphokine-activated killer (LAK) cells coupled to a bispecific antibody (anti-CD3+anti-glioma) as post-operative adjuvant therapy. Although this study excluded patients with deeply-seated tumours or a poor performance status, approximately 50% of the patients remained alive after 3 years, and 40% were free of recurrence. Serial CT scans revealed disappearance of remnant tumours in some patients. In addition, CT-guided stereotactic biopsy of the tumour in 3 patients showed extensive necrosis and degeneration after specific targeting therapy (STT). Five patients developed acute infection, and one of them died of bacterial meningitis. Our results suggest that antibody-targeted LAK therapy can achieve a higher response rate in patients with standard LAK therapy or any type of conventional treatment.

Targeting T cells with bispecific antibodies for cancer therapy

Bispecific antibodies (BiAbs) offer a unique opportunity to redirect immune effector cells to kill cancer cells. BiAbs combine the benefits of different binding specificities of two monoclonal antibodies (mAbs) into a single construct. This unique feature of BiAbs enables approaches that are not possible with single mAbs. Advances in antibody engineering and antigen profiling of malignant cells have led to the development of a number of BiAb formats and their combinations for redirecting effector cells to tumor targets. There have been significant advances in the design and application of BiAbs for intravenous and local injection.The initial barrier of cytokine storm has been partially overcome by more recent constructs that have improved clinical effectiveness without dose-limiting toxicities. Since the recent revival of BiAbs, there has been multiple, ongoing, phase I/II and III trials, and some promising clinical outcomes have been reported in completed clinical studies. This review focuses on arming T cells with BiAbs to create the 'poor man's cytotoxic lymphocyte'.

Development and prospects for bispecific antibody-based therapeutics in cancer and other applications

BACKGROUND

Progress in molecular biology for the production of bispecific antibodies (BiAbs) and the expanding knowledge on receptors on malignant and normal target cells provide the basis for developing new strategies using antibody- and/or receptor-based platform technology for the treatment of cancer and other diseases.

OBJECTIVE

This review provides a preclinical and clinical perspective on application of bispecific antibodies for the treatment of solid tumors, hematologic malignancies and other diseases.

METHODS

This review focuses on BiAb-based immunotherapy, clinical trials, alternative strategies, the challenges of technology and future applications.

RESULTS/CONCLUSION

The successful application of a particular BiAb will depend on a thorough evaluation of the expected functional application and thoughtful engineering of structure, affinity and number of binding sites based on the desired function.

Bispecific antibodies for the treatment of tumours and infectious diseases

Bispecific antibodies are in clinical and preclinical development for the treatment of various cancers and life-threatening infectious diseases. Designed to direct and enhance the body's immune response to specific tumours and pathogens, bispecific antibodies have shown promising results in Phase I and Phase II clinical trials, leading in some cases to complete or partial responses in cancer patients. These bispecific antibodies consist of a 'targeting' domain, typically a fragment of a monoclonal antibody that binds to a tumour, linked to a 'triggering' arm that is specific for a molecule capable of mediating a phagocytic or lytic response by macrophages, natural killer cells, T-cells or other effector cells. By mediating an immune assault on tumours or pathogens, bispecific antibodies may also lead to antigen presentation and a vaccine-like response in patients. Over the next few years, we expect several bispecific antibodies to enter the late stages of clinical trials and ultimately emerge as new pharmaceutical products.

Retargeting T cells and immune effector cells with bispecific antibodies

The development of BiAbs for therapeutic applications in cancer shows promise. As our understanding of effector cell receptor biology for triggering of cytotoxic functions improves and the behavior of TAA and the targeting antibody engagement is elucidated, customized BiAb reagents can be engineered to optimize in vivo or ex vivo arming of T cells for targeting tumors. Additionally, other variables that require consideration in the equation for successful T cell immunotherapy include: the type of effector cells, their state of activation, the type of effector receptor being activated or tareeted. the presence of Tregs, the affinity of the anti-effector cell antibody and the anti-TAA antibody, the type of BiAb (mouse, humanized, or human), the number of binding sites for the T cells or TAA, the presence or absence of decoy antigen, whether the TAA modulates after being engaged by antibody, the type of tumor, the tumor burden, and last, but not least, the amount of 'immunologic' space available for the adoptively transferred cells to expand and function.

Specific targeting immunotherapy of cancer with bispecific antibodies

In order to enhance cell mediated cytotoxicity, bispecific antibodies (BsAbs), molecules combining two or more antibodies with different antigenic specificities, have been developed as new agents for immunotherapy. Our recent studies revealed that simultaneous administration of two kinds of BsAbs (anti-tumor x anti-CD3 plus anti-tumor x anti-CD28) together with lymphokine activated killer cells with a T cell phenotype (T-LAK cells) inhibited growth of human xenotransplanted tumors in severe combined immunodeficient (SCID) mice, while single BsAb was without effect. Three kinds of BsAbs (anti-tumor x anti-CD3, anti-tumor x anti-CD28, anti-tumor x anti-CD2) showed the highest cytotoxicity against tumor cells when given simultaneously with T-LAK cells or peripheral blood mononuclear cells in vitro and in vivo. BsAbs can be preserved for immediate application, while cytotoxic T lymphocytes (CTLs) must be made-to-order, and are time-consuming to prepare. Tumor associated antigens, such as MAGE antigens, SART antigens, MUC1 antigen, c-erbB 2 antigen or cancer/testis antigens can be served to target antigens for BsAb production. By conjugation with antibodies to effector cells (anti-CD3, anti-CD28, anti-CD16, anti-CD64, anti-CD89 or anti-CD2), many kinds of BsAbs can be produced to cover most types of cancers from different organs. Therefore this strategy might be ubiquitously applicable to most malignancies.

CD3xCD19 bispecific antibodies and CD28 bivalent antibodies enhance T-cell reactivity against autologous leukemic cells in pediatric B-ALL bone marrow

Bispecific CD3xCD19 antibodies and CD28 co-stimulating antibodies were used to activate T cells in bone marrow aspirates (n = 8) of children with B cell-derived acute lymphoblastic leukemia. Bone marrow specimens were incubated for 10 days with CD3xCD19 bispecific and CD28 antibodies. Changes in the numbers of T lymphocytes and tumoral B cells as well as surface expression of T cell-activation markers were determined by flow cytometry, and cytokines (human IFN-gamma, IL-2, IL-4 and IL-12) were measured in the cell culture supernatant. In 7 of 8 bone marrow samples, an increase in the number of CD4- and CD8-positive T lymphocytes was found, which correlated with an up-regulation of T cell-activation markers. Additionally, we demonstrated a decrease of tumoral B cells in 3 samples and enhanced cytotoxic T-cell activity against autologous malignant B cells. ELISpot analyses in an autologous Epstein-Barr virus model showed that bispecific antibodies (CD3xCD19+CD28) were more potent at generating T-cell responses against autologous and allogeneic tumoral targets than a combination of monospecific antibodies (CD3+CD28). Thus, T-cell targeting by CD3xCD19 bispecific and CD28 antibodies may be used to eliminate leukemic B cells ex vivo and reconstitute immunological control of residual malignant disease by the induction of anti-tumoral T-cell responses.

Cytolysis of malignant glioma cells by lymphokine-activated killer cells combined with anti-CD3/antiglioma bifunctional antibody and tumor necrosis factor-alpha

With the aim of developing an effective immunotherapy for malignant glioma, glioma cells were incubated with tumor necrosis factor-alpha (TNF-alpha) to increase their susceptibility to lysis by lymphokine-activated killer (LAK) cells. Treatment with exogenous TNF-alpha induced the expression of intercellular adhesion molecule-1 (ICAM-1) on the surface of glioma cells. In addition, the cytolytic activity of LAK cells toward exogenous TNF-alpha treated glioma cells was significantly greater than LAK cell activity toward untreated glioma cells. This increase in cytolytic activity was blocked by anti-ICAM-1 monoclonal antibodies (MAb). Furthermore, co-treatment with a bifunctional antibody (BFA) composed of anti-CD3 (UCHT1) and antiglioma (G-22) antibodies synergistically increased the cytolytic activity of LAK cells towards TNF-alpha-treated glioma cells. These results indicate that a combination of exogenous TNF-alpha and anti-CD3/antiglioma BFA may provide an effective modified adoptive immunotherapy for patients with malignant glioma.

A new in vitro model of specific targeting therapy of cancer: retargeting of PWM-LAK cells with bispecific antibodies greatly enhances cytotoxicity to hepatocellular carcinoma

For the purpose of establishing a new in vitro model of adoptive immunotherapy, we synthesized two kinds of bispecific antibodies (BsAbs), i.e., (OK x L) BsAbs constructed with both OKT-3 (anti-CD3) and L-7-6 (anti-HCC), and (3G x L) BsAbs constructed with 3-G-8 (anti-CD16) and L-7-6 antibodies. These two BsAbs, having pairs of binding arms on their single molecule, showed similar binding to target cells as the parental monoclonal antibodies (OKT-3, 3-G-8 and L-7-6), when examined with FACS. Newly devised in vitro cytotoxicity tests revealed that LAK or PWM-stimulated LAK (PWM-LAK) cells did not show any significant cytotoxic activity to HCC cells, while both effector cells equally showed greatly enhanced cytotoxicity to HCC even at a low effector/target (0.3) in the presence of BsAbs (OK x L) for the efficient retargeting of the effector cells. Inasmuch as PWM-LAK cells proliferate in vitro 3-5 times faster than LAK cells, adoptive immunotherapy using PWM-LAK cells in combination with (OK x L) BsAbs should be very promising.

Performance of CD3xCD19 bispecific monoclonal antibodies in B cell malignancy

Bispecific monoclonal antibodies, with a dual specificity for tumor associated antigens on target cells and for surface markers on immune effector cells, have been shown (in vitro) to be effective in directing and triggering effector cells to kill target cells resulting in target cell lysis. Bispecific monoclonal antibodies (BsAb) against the CD3 antigen on T cells and the CD19 antigen on B cell were developed. Data obtained by in vitro experiments might indicate that clinical responses in BsAb immunotherapy, will only be obtained in patients with minimal tumor load, and may need additional T cell stimulation via cytokines such as IL-2. Although these experiments have shown us their limitations, they also include the promise of BsAb-directed immunotherapy in B cell malignancy as further demonstrated during a Phase I trail, showing little toxicity. Clearly, much remains to be done before this BsAb is routinely used for therapy, but, the results presented show that the CD3xCD19 BsAb has a potential as a therapeutic agent in B cell malignancy. This report describes the experiments performed to test a new immunotherapeutic approach for the treatment of B cell malignancy. Bispecific antibodies are described that can target cytotoxic T cells to tumor cells and elicit a cytolytic action towards these cancer cells.

Prognostic implications of the extent of surgical resection in patients with intracranial malignant gliomas

BACKGROUND

The goal of treating patients with malignant gliomas by intracranial surgery has been to remove as much tumor as possible without causing new neurologic deficits. However, it is still debatable whether the degree of surgical resection correlates with survival times of patients with supratentorial gliomas.

METHODS

One hundred and one patients with supratentorial malignant gliomas who underwent either a gross total resection, a subtotal resection, and/or a partial resection were examined. A correlation between their length of survival and the degree of surgical resection was determined.

RESULTS

The survival rates of patients who underwent total resections were significantly higher than those of patients who underwent subtotal or partial resections (P < 0.01). However, there was no significant difference in the survival rates between the subtotal and partial resection groups. These results also were confirmed by independent variables, such as age, location of the tumors, and histologic subtypes, with the exceptions of temporal gliomas and those younger than 60 years.

CONCLUSIONS

The favorable prognosis of patients with malignant gliomas depends upon the total resection of these tumors. These findings should be of help in designing preoperative surgical intervention strategies.

Bispecific monoclonal antibody therapy of B-cell malignancy

Bispecific monoclonal antibodies (bsAbs) that recognize CD3 with one arm and a tumor associated antigen with the other arm can retarget T-cells toward tumor cells in an MHC independent manner, thereby combining the specificity of monoclonal antibodies with the power of the cellular immune system. B-cell malignancies are particularly attractive as targets for anti-CD3-based bsAb therapy because of their sensitivity to other forms of antibody therapy, and the extent to which B-cells and T-cells communicate at the molecular level. BsAbs that recognize CD3 and a number of antigens on malignant B-cells have been shown in vitro to be capable of retargeting T-cells. In animal models of B-cell malignancy, bsAb can eliminate tumor loads that are resistant to unmodified monoclonal antibody therapy. Ongoing early clinical trials in advanced B-cell lymphoma indicate CD3-based bsAbs have significant biologic effects, and suggest they have anti-tumor activity as well. A number of significant questions relating to bsAb therapy of B-cell malignancies remain. It is unclear what role both endogenously produced and exogenously administered cytokines are likely to play. Further exploration of whether bsAb can induce T-cells to target to tumor will also be required before the true promise of this novel form of immunotherapy can be determined.

Cytotoxicity of cytokine-induced killer cells coated with bispecific antibody against acute myeloid leukemia cells

Various types of cytokines have been used in in vitro experiments to generate cytokine-induced killer (CIK) cells that are reactive to patient acute myeloid leukemia (AML) cells. Of these CIK cells, interleukin-2 (IL-2)-activated peripheral blood mononuclear cells, i.e., lymphokine-activated killer (LAK) cells, with the initial addition of the anti-CD3 monoclonal antibody (T3 LAK cells), are the most potent cytotoxic lymphocytes, and have marked proliferative capacity. The cytotoxicity of such T3 LAK cells against CD13+ AML cells is further enhanced by the addition of anti-CD3 x anti-CD13 bispecific antibody (BsAb) during the cytotoxicity assay. The combined use of T3 LAK cells and the BsAb can be used for ex vivo purging of CD13+ AML cells in autologous bone marrow transplantation. Other cytokines, such as IL-7 or IL-7 in combination with IL-2, or newly identified cytokines, will also be tested in attempts to obtain more specific and more potent effector cells. Studies of methods to increase the susceptibility of AML cells to CIK are also required.

Local antitumour treatment in carcinoma patients with bispecific-monoclonal-antibody-redirected T cells

In a pilot clinical study carcinoma patients with malignant ascites or pleural exudates have been treated locally with autologous lymphocytes activated ex vivo and redirected towards tumour cells with bispecific monoclonal antibodies. BIS-1, the bispecific monoclonal antibody used in this study, combines specificity against a tumour-associated antigen, AMOC-31, present on carcinomas, with a specificity against the CD3 complex on T lymphocytes. Patients selected for treatment had malignant pleural or peritoneal effusions. Treatment consisted of isolating autologous peripheral blood lymphocytes, ex vivo activation, incubation with bispecific monoclonal antibodies and injection at the effusion site of these BIS-1-redirected lymphocytes. To evaluate the effects of the bispecific monoclonal antibody, five patients received treatments with activated lymphocytes without bispecific antibodies. Effusion samples taken before and at various times after treatment were analysed by immunocytology and for the presence of the soluble factors carcinoembryonic antigen (CEA), interleukin-6 (IL-6), tumour necrosis factor (TNF), C-reactive protein and soluble CD8. In this way both immune activation and anti-tumour activity could be monitored. Conjugate formation between tumour cells and activated lymphocytes was seen as soon as 4 h after injection of BIS-1-redirected activated lymphocytes, followed by a disappearance or reduction of tumour cells after 24-48 h. In parallel with this, the soluble tumour marker CEA decreased in the effusion fluid following injection with the BIS-1-redirected lymphocytes. Furthermore, a steep increase in local granulocyte numbers was observed in the effusion fluid, which reached a maximum 24-48 h after the start of the treatment. Also levels of IL-6 and TNF were greatly elevated. The data suggest that the treatment induces both antitumour activity and a strong local inflammatory reaction. This is accompanied by no or only minor local and systemic toxicity, i.e. mild fever, which disappeared as the local inflammatory reaction diminished 48-72 h after treatment.

Immunization with mutagen-treated (tum-) cells causes rejection of nonimmunogenic rat glioma isografts

The ethyl-N-nitrosourea-induced rat glioma N32 was treated with the mutagenic compound N-methyl-N'-nitro-N-nitrosoguanidine and the surviving cells cloned by limited dilution. Out of 20 clones tested 8 did not produce tumors subcutaneously even after challenge doses 3 log units above the minimal tumor dose for N32. All of 5 clones grew in a retarded manner intracerebrally but produced tumors in some animals. Preimmunizations with three of the rejected clones (tum-) gave protection against subcutaneous and intracerebral isografts of the unmutated N32. This effect could be enhanced if the cells used for immunizations were pretreated with interferon gamma (IFN gamma) for 48 h. If immunizations were started subsequent to challenge, only immunization with one of two tested tum- clones pretreated with IFN gamma induced significant rejection against intracerebral N32 isografts. Both N32 and its tum- clones were MHC class I positive and MHC class II negative. IFN gamma treatment enhanced the MHC class I expression with 20%-90% on the tum- clones and with 40% on N32. MHC class II expression could be induced on N32 cells after 7 days of IFN gamma treatment but not on any of the tum- clones tested. We conclude that the enhancing effect of IFN gamma treatment on tumor isograft rejection may depend on up-regulation of MHC class I but not of MHC class II. This investigation demonstrates that it is possible to induce rejection of weakly immunogenic intracerebral brain tumors by immunization with selected highly immunogenic tumor cell mutants. In conjunction with relevant cytokines, the cross-protective effect of these tum- variants might be further enhanced and serve as a model for immunotherapy against malignant human brain tumors.

Specific targeting of in vitro-activated human antitumour effector cells using anti-CD3 x anti-c-erbB-2 bispecific antibody

Bispecific antibody (BSAb) consisting of anti-CD3 plus anti-c-erbB-2 Fab fragments for the application to adoptive tumour immunotherapy was prepared. This bifunctional hetero-F(ab')2 antibody reacted with both human CD3+ T cells and c-erbB-2 positive human tumour cells. Human CD8+ T cells activated with immobilized anti-CD3 plus interleukin 2 showed marginal cytotoxicity against tumour cells. However, addition of the prepared BSAb into the culture resulted in a marked augmentation of the cytotoxicity by the activated CD8+ T cells in a dose-dependent manner. The enhanced cytotoxicity of CD8+ T cells in the presence of BSAb was specific for c-erbB-2 positive tumour cells. Moreover, it was demonstrated that anti-CD3 x anti-c-erbB-2 BSAb was also effective for the specific targeting of various kinds of in vitro-activated antitumour effector cells such as lymphokine-activated killer cells, CD4+ helper/killer cells, gamma delta T cells and activated tumour-infiltrating CD8+ T cells. These results indicated that BSAb consisted of anti-CD3 and anti-c-erbB-2 will become a useful tool for the adoptive tumour immunotherapy of human cancer expressing c-erbB-2 oncogene products.

Killing of human leukaemia/lymphoma B cells by activated cytotoxic T lymphocytes in the presence of a bispecific monoclonal antibody (alpha CD3/alpha CD19)

Bispecific antibodies (BsAb) can be used to retarget T cells irrespective of their specificity to certain target cells inducing target cell lysis. We have tested the efficacy of the BsAb SHR-1, directed against the T cell antigen CD3 and the B cell antigen CD19 to induce (malignant) B cell kill by T cells as measured in a 51Cr-release assay. Two cytotoxic T cell clones (CTL), expressing TCR alpha beta or TCR gamma delta, were effective in killing CD19 expressing B cell lines at different stages of differentiation in the presence, but not in the absence, of the BsAb. CD19- target cells were not killed. Fresh CD19+ leukaemia/lymphoma cells were also efficiently killed by SHR-1 preincubated CTL clones. In addition, phytohaemagglutinin (PHA) or CD3-activated IL-2 expanded peripheral blood mononuclear cells (PBMC) of normal donors did so after 2 weeks of stimulation. A concentration of 100 ng/ml of the BsAb was sufficient to obtain optimal lysis of all target cells tested. These results show that fresh human leukaemia/lymphoma cells, freshly derived from active lymphoblastic leukaemia (ALL) as well as non-Hodgkin's lymphoma (NHL) patients, can be effectively killed in the presence of this BsAb by activated T cells.

Augmentation by bispecific F(ab')2 reactive with P-glycoprotein and CD3 of cytotoxicity of human effector cells on P-glycoprotein positive human renal cancer cells

A bispecific F(ba')2 was constructed that was composed of two Fab fragments, one derived from anti-CD3 monoclonal antibody (mAb) (OKT3) and the other from anti P-glycoprotein mAb (MRK 16). This bispecific F(ab')2 enhanced the binding and cytotoxicity of human peripheral blood mononuclear cells (PBMCs) on P-glycoprotein-positive human kidney cancer cells (ADMHK/E). It had no effect on the cytotoxicity of PBMCs on P-glycoprotein-negative HK/E cells [long-term cultured HK/E (LCHK/E)]. Control F(ab')2 composed of OKT3 or MRK16 alone did not influence the cytotoxicity of PBMCs on ADMHK/E cells. These findings suggest that the MRK16-OKT3 bispecific F(ab')2 may be therapeutically beneficial in treatment of human multidrug-resistant cancers.

Large-scale culture system of human CD4+ helper/killer T cells for the application to adoptive tumour immunotherapy

A simple method for the rapid expansion of human CD4+ T cells with both helper and killer functions was established. CD4+ T cells separated from peripheral blood mononuclear cells using immunomagnetic beads were stimulated with immobilised OKT-3 monoclonal antibody (mAb) plus recombinant interleukin 2 (rIL-2) in 96 well culture plates. After 6 day-culture, the CD4+ T cells were restimulated by immobilised OKT-3 mAb for an additional 24 h, then inoculated into concentrated rotary-tissue culture bag and cultured for further 9 days. This procedure yielded a 3000-fold increase in cell number (about 3-5 x 10(9) per bag). Most of the cells (over 96%) continued to express CD4+ antigen and retained their capacity to produce IL-2. The activated CD4+ T cells showed marked cytotoxicity against Fc receptor positive tumour cells in the presence of OKT-3 mAb. Moreover, we succeeded in a specific targeting of the expanded CD4+ helper/killer T cells to c-erb B-2 positive tumour cells by means of anti-CD3 x anti-c-erb B-2 bispecific antibody. These results suggested that our established simple system will be available for the expansion of large number of CD4+ helper/killer T cells which may provide an efficient strategy for adoptive tumour immunotherapy.

Bispecific anti-human red blood Rhesus-D antigen x anti Fc gamma RI targeted antibody-dependent cell-mediated cytotoxicity and phagocytosis by mononuclear leucocytes

The Fc receptor mediated antibody-dependent cell-mediated cytotoxicity (ADCC) and phagocytosis induced by bispecific antibody (BsAb) to the high-affinity Fc receptor for IgG (Fc gamma RI) and to human red blood group antigen RhD were studied in vitro, using human mononuclear leucocytes as effector cells. The results were compared with those obtained by using a human monoclonal IgG1 anti-RhD used alone and a reference human polyclonal anti-RhD antibody. The effect of non-specific human IgG on FcR-mediated functions by mononuclear leucocytes was checked. The results demonstrate that BsAb presents a high resistance of Fc-mediated function to blockade by non-specific human IgG compared with that of both polyclonal and monoclonal anti-RhD antibodies. These results further encourage possible clinical application of bispecific antibody in passive immunotherapy.

HumanC-ERBB-2 proto-oncogene product as a target for bispecific-antibody-directed adoptive tumor immunotherapy

To develop an efficient strategy for the targeting of anti-tumor effector cells, we prepared bispecific antibody (BsAb) containing anti-CD3 and an anti-c-erbB-2 proto-oncogene product. The prepared BsAb specifically reacts with both c-erbB-2-positive tumor cells and CD3+ CTL. Human CD4+ helper/killer T cells, induced from peripheral-blood mononuclear cells by activation with immobilized anti-CD3 monoclonal antibody (MAb) plus IL-2, showed no significant cytotoxicity against tumor cells. However, treatment of human CD4+ helper/killer cells with the BsAb caused the induction of specific cytotoxicity against c-erbB-2-positive tumor cells. CD4+ helper/killer cells also produced significant amounts of IL-2 during co-culture with c-erbB-2-positive tumor cells in the presence of the BsAb. Moreover, by combination with the BsAb, CD4+ helper/killer cells showed a strong in vivo anti-tumor effect against c-erbB-2 transfectant or human colon-cancer cells implanted in nude mice. Our results strongly suggest that the c-erbB-2 proto-oncogene product on human tumor cells may be a good target for BsAb-directed adoptive tumor immunotherapy.

Bispecific antibody-directed antitumor activity of human CD4+ helper/killer T cells induced by anti-CD3 monoclonal antibody plus interleukin 2

Freshly isolated human CD4+ T cells can not respond to recombinant interleukin 2 (rIL-2) because of their lack of p75 IL-2 receptor expression. However, we succeeded in inducing a marked proliferation of purified CD4+ T cells by activation with rIL-2 plus anti-CD3 monoclonal antibody (mAb) cross-linked to a plastic plate. The proliferated CD4+ T cells produced a significant amount of IL-2 upon stimulation with phorbol ester plus A23187. Interestingly, CD4+ T cells activated with anti-CD3 mAb plus rIL-2 revealed a strong cytotoxic activity against Fc receptor (FcR)-positive tumor cells in the presence of anti-CD3 mAb. Moreover, the CD4+ T cells could lyse FcR-negative glioma cells by targeting with bispecific mAb containing anti-CD3 mAb and anti-glioma mAb. Thus, we demonstrated that rIL-2 and immobilized anti-CD3 mAb allowed the rapid generation of human CD4+ helper/killer T cells, which may be useful for the development of a new adoptive tumor immunotherapy.

Interleukin-2 activated T cells (T-LAK) express CD16 antigen and are triggered to target cell lysis by bispecific antibody

Human PBMCs from healthy donors were cultured with 100 U/ml rIL-2 for up to 5 weeks and tested at short and long activation times for the ability to mediate CD3 and CD16 targeted cytotoxicity using chemically cross-linked bispecific antibodies. At each period, LAK activity was augmented with the use of bispecific antibodies (BA), whereas interestingly enough, at later periods (4-5 weeks) when CD16 positive lymphocytes are not present by flow cytometry, CD16 targeted cytotoxicity was induced. We suspected the possibility of CD16 expression on activated T cells and have purified the T cell subpopulations to see the targeted cytotoxicity. Populations enriched for T cells by Percoll density centrifugation, treatment with anti-CD16 plus complement or sorting for CD5+ cells, were all able to mediate CD16 targeted cytotoxicity following activation with rIL-2. These data suggest that IL-2 activated T cells express CD16 in addition to CD3.

The treatment of primary malignant brain tumours

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Neurological stamp. Mandragora

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