Phenotypically and functionally distinct T-cell subsets in anti-tumor responses

Dendritic cell-based approaches to cancer immunotherapy

Immunologic approaches to the treatment of malignancies are currently enjoying a resurgence of enthusiasm due to the discovery of tumour-associated antigens and the requirements for stimulating a tumour antigen-specific immune response. The goal of the newer strategies is to stimulate immunity against specific tumour-associated antigens, rather than to broadly, but non-specifically, stimulate the immune system. Since dendritic cells, professional antigen-presenting cells, play a central role in stimulating immune responses in vivo, there is considerable interest in immunising patients with autologous dendritic cells loaded with tumour antigens of interest. Methods for generating large numbers of dendritic cells under clinically-applicable conditions have been developed and it has been shown that they may be loaded with antigen in many different forms including proteins or peptides, RNA or DNA and cellular extracts. Ongoing research is seeking to optimise the purity, antigen loading and maturation of the dendritic cells. Phase I clinical trials have been initiated in order to study the safety and feasibility of immunisations with dendritic cells in humans with various malignancies. Phase II studies will be performed to establish which tumours and clinical scenarios will be most relevant for dendritic cell immunotherapy. Although the commercial applicability of dendritic cell-based immunotherapy has been recognised by the biotechnology industry, commercial availability of dendritic cell vaccines await phase III studies.

Human autoreactive (Th0) CD4(+) T-cell clones with cytolytic activity recognizing autologous activated T cells as the target

In attempt to obtain a clue to understanding possible physiological roles played by autoreactive T cells, autoreactive T-cell clones originally derived from an allogeneic mixed lymphocyte culture have been analyzed for their target spectrum, lytic function and cytokine profiles. Five CD4(+) T-cell clones established from allogeneic MLR, in which the stimulator cells shared certain class II MHC antigens with the responder, turned out to be reactive to autologous PBL. Among these, three clones were cytolytic against autologous B-cell line. These three cytolytic autoreactive clones were shown to be capable of specifically lysing autologous activated T cells expressing class II MHC molecules, raising possibility that such autoreactive clones might play a role in negatively regulating T cell responses. Cytolysis by an autoreactive clone 21C5 was inhibited completely by concanamycin A (CMA) known as a specific inhibitor of perforin, suggesting an involvement of the perforin/granzyme system. T-cell clones derived from the same MLC showed distinct correlation between their specificity and lymphokine profiles. Thus, the three cytolytic autoreactive clones belonged to Th0, whereas the two noncytolytic autoreactive clones belonged to Th2 and three alloreactive CD4(+) clones derived from the same culture were of Th1 type.

Distinct role of antigen-specific T helper type 1 (Th1) and Th2 cells in tumor eradication in vivo

The role of T helper type 1 (Th1) and Th2 cells in tumor immunity was investigated using Th cells induced from ovalbumin (OVA)-specific T cell receptor transgenic mice. Although Th1 cells exhibited stronger cytotoxicity than Th2 cells, both cell types completely eradicated tumors when transferred into mice bearing A20 tumor cells transfected with the OVA gene (A20-OVA). Th1 cells eradicated the tumor mass by inducing cellular immunity, whereas Th2 cells destroyed the tumor by inducing tumor necrosis. Both Th1 and Th2 cells required CD8(+) T cells to eliminate tumors, and neither of these cells were able to completely eliminate A20-OVA tumors from T and B cell-deficient RAG2(-/-) mice. Mice cured from tumors by Th1 and Th2 cell therapy rejected A20-OVA upon rechallenge, but CD8(+) cytotoxic T lymphocytes were induced only from spleen cells prepared from cured mice by Th1 cell therapy. Moreover, we demonstrated that Th1 and Th2 cells used distinct adhesion mechanisms during tumor eradication: the leukocyte function-associated antigen (LFA)-1-dependent cell-cell adhesion step was essential for Th1 cell therapy, but not for Th2 cell therapy. These findings demonstrated for the first time the distinct role of antigen-specific Th1 and Th2 cells during eradication of established tumors in vivo.

Antigen-presenting cells pulsed with unfractionated tumor-derived peptides are potent tumor vaccines

Vaccination with peptides isolated from tumor cells circumvents the need for identifying specific tumor rejection antigens and extends the use of active immunotherapy to the majority of cancers where specific tumor antigens have not yet been identified. In this study, we examined the efficacy of tumor vaccines composed of unfractionated tumor peptides presented by antigen-presenting cells (APC) to induce cytotoxic T lymphocyte (CTL) responses and tumor immunity. RMA-S cells pulsed with peptides isolated from ovalbumin (OVA)-expressing tumor cells were highly effective at inducing primary, OVA-specific CTL responses in vitro and priming CTL responses in vivo. In addition, tumor peptide-pulsed RMA-S cells induced protective immunity in mice when challenged with OVA-expressing tumor cells. To enhance the clinical relevance of these studies, cells pulsed with tumor peptides were evaluated in the poorly immunogenic, B16/F10.9 melanoma post-surgical metastasis model. Treatment of tumor-bearing mice with peptide-pulsed RMA-S cells or with adherent splenocytes (enriched for professional APC) caused a significant reduction in lung metastases. The antimetastatic effect of peptide-pulsed splenocytes could be further enhanced by pretreating the cells with antisense oligonucleotides directed against the TAP-2 gene which was previously shown to increase the density of specific peptide/MHC class I complexes and thereby improve the APC function of the treated cells (Nair et el., J. Immunol. 1996. 156: 1772). This study suggests that APC loaded with unfractionated peptides derived from poorly immunogenic, highly metastatic tumor cells may represent a potent form of tumor vaccine.

Indirect allorecognition of HLA class I peptides by CD4+ cytolytic T lymphocytes

T-cell responses to alloantigens can occur either by "direct" recognition of donor MHC molecules, or "indirect" recognition of MHC peptides in association with self-MHC. To evaluate human T cells mediating indirect allorecognition, a CD4+ TCL and clones specific for HLA-A1 or HLA-B8 (residues 60-84) were generated from normal PBLs (A2,29 B62,- DR1,4 DQ3). Most clones were A1 specific (16 out of 17 tested), HLA-DR4 restricted (8 out of 8), and lysed targets pulsed with A1 peptide (16 out of 16). An amino acid substitution at position 86 of the DR4 beta chain (G -> V) abrogated the capacity of CD4+ CTLs to lyse target cells. Chloroquine treatment of A1-pulsed targets reduced their susceptibility to lysis, indicating a requirement for peptide processing. The TCL and clones were stimulated to proliferate by cells bearing intact HLA-A1 when autologous APCs were present, indicating that the epitope contained within the A1 60-84 peptide being recognized is produced when APCs process native HLA-A1. Furthermore, the clones and TCL did not recognize HLA-A1 on target cells carrying this allele plus self-HLA-DR4. These studies suggest a much wider role for CD4+ T cells in allograft immunity.

Regulatory mechanisms of antitumor T cell responses in the tumor-bearing state

Tumor-bearing hosts develop antitumor immune responses. However, a number of immunosuppressive mechanisms come into operation with the progression of tumor growth. This article will review the observations regarding the modulation of antitumor immune responses in the tumor-bearing state, and consider the mechanisms underlying tumor-induced immune defects, especially in the light of the induction of an abnormal cytokine network. We will also describe the restoration of suppressed antitumor immune responses by administration of a particular cytokine, interleukin-12.

Mechanism and biological significance of CD4-mediated cytotoxicity

It is now well established that CD4+ T cells can express cytotoxic activity. This type of cell-mediated cytotoxicity is associated with the Th1-, but not with the Th2-phenotype. While the activation of CD4+ CTL is MHC class II-restricted, the effector phase, i.e. the target cell killing is unrestricted and antigen non-specific. In analogy to CD8+ CTL, CD4-mediated target cell death is by DNA fragmentation. However, the molecular mechanism of killing differs from CD8-mediated lysis. Thus, CD4+ CTL preferentially lyse their targets via Fas-Fas ligand interaction, whereas the major cytotoxic effect of CD8+ CTL is by granule exocytosis, i.e. perforin and granzymes. Although CD8+ CTL can also express the FasL, their lytic activity through interaction with Fas is of less importance. Likewise, some CD4+ CTL may also kill by perforin/granzymes activity, but this pathway is of minor significance. The aims of CD8- or CD4-mediated lysis are also different. Thus, the major task of CD8+ CTL which recognize and kill their targets in the context of MHC class I molecules, is the lysis of virally infected cells and battling against tumor cells. CD4+ CTL, on the other hand, have an immunomodulatory role. Thus, they preferentially eliminate activated MHC class II-positive cells, i.e. APC, be they monocytes/macrophages, B cells or T cells. They may lyse these cells in order to prevent an overreaction of the ongoing immune response or in order to remove potentially hazardous cells upon completion of the immune response. The Fas-FasL pathway is particularly suitable for this task as myeloid or lymphoid cells express Fas only if activated, while FasL is preferentially expressed on activated CD4+ Th1 cells. Moreover, activated T cells eliminate themselves by the Fas-mediated pathway. Whether this happens by fratricide only, or also by suicide or both is open. Moreover, CD4+ CTL are particularly suitable for killing tumor cells as well, as they are efficient effectors in bystander lysis in contrast to CD8+ CTL. On the other hand, the non-specific killing via Fas-FasL interaction, which is an important reason for the bystander lysis, may have unwanted effects in that cells which should not be eliminated could be killed. Such reactions affecting various organs and cells, e.g. the liver, thyroid or islet cells of the pancreas could be an explanation for certain autoimmune diseases.

Synergistic antimetastatic effects of lentinan and interleukin 2 with pre- and post-operative treatments

The antimetastatic activity of a combination of lentinan and interleukin 2 (IL-2) was evaluated against spontaneously metastatic 3-methylcholanthrene-induced DBA/2.MC.CS.T fibrosarcoma. Although pre-operative treatment with either IL-2 or lentinan alone exerted little effect on the reduction of lung metastasis colony numbers (7.1% or 28.4% reduction, respectively), the combination exhibited a synergistic effect (85% reduction). Furthermore, 3 of 13 mice given the pre-operative combination treatment achieved complete cure, while no mice given saline did. Although the post-operative combination treatment also reduced the colony number (71% reduction), it caused little prolongation of survival and no mouse achieved complete cure. Synergistic effects were observed between pre- and post-operative treatments with lentinan and IL-2: 8 of 12 mice were completely cured. The anti-metastatic activity was abolished in mice treated simultaneously with antibodies to CD4 and CD8 antigens, whereas either CD4, CD8, or NK1.1 antibody alone was ineffective. Analysis of the cellular mechanism involved in the antimetastatic activity revealed the involvement of a tumor-associated antigen-specific delayed-type hypersensitivity response. These data suggest that the life-prolonging effect of the combination of lentinan and IL-2 is mediated by antigen-specific T cells and that the combination of pre- and post-operative therapy with lentinan and IL-2 may be effective to prevent cancer recurrence and metastasis after surgical resection.

Th1 type CD4+ T cells may be a potent effector against poorly immunogenic syngeneic tumors

We examined the possibility that Th1 type CD4+ T cells may be an effector against three kinds of syngeneic tumors such as highly immunogenic B16 melanoma (B16) and two poorly immunogenic lines of MCA fibrosarcoma (MCA) and 3LL carcinoma (3LL). In a proliferation assay, the Th1 type CD4+ T cell clone (MH2) recognized the purified protein derivatives (PPD) derived from Mycobacterium tuberculosis. In a tumor-neutralizing assay, MH2 showed anti-tumor activity against both B16 and MCA. In a model of pulmonary metastasis, MH2 also showed anti-tumor activity against both B16 and 3LL. In an assay of cytolysis, MH2 showed a moderate level of tumor necrosis factor-dependent cytolytic activity only against MCA. In a cytostasis assay, MH2 showed a high level of interferon gamma-dependent cytostatic activity against the three tumors in the presence of macrophages. The anti-tumor activity of MH2 against B16 and 3LL was suggested to be, at least in part, attributable to the augmented natural killer activity. Taken together, these findings suggest that we may potentially be able to utilize Th1 type CD4+ T cells as an effector for immunotherapy against poorly immunogenic tumors.

Reconstitution of anti-tumor effects of lentinan in nude mice: roles of delayed-type hypersensitivity reaction triggered by CD4-positive T cell clone in the infiltration of effector cells into tumor

Lentinan, an antitumor polysaccharide used clinically in Japan, requires the intact T cell compartment to manifest its antitumor effects. The aim of the current study was to clarify the mechanisms playing crucial roles in the T cell requirement in the expression of antitumor effects of lentinan. Lentinan treatment of BDF1 mice transplanted intradermally with FBL-3 induced complete tumor regression and a marked increase in survival time. The antitumor action of lentinan was abolished in mice treated simultaneously with antibodies to CD4 and CD8 antigens, whereas antibody to CD4, CD8 or NK1.1 alone was ineffective. The natural killer, cytotoxic T lymphocyte, and helper T cell activities were already augmented in this FBL-3/BDF1 system and thus further augmentation of these activities by lentinan was not observed. These activities did not correlate with the antitumor activity of lentinan, as was confirmed in lymphocyte subset depletion experiments. On the contrary, the delayed-type hypersensitivity (DTH) response against tumor-associated antigens was triggered by lentinan and was abrogated only in mice treated simultaneously with antibodies to CD4 and CD8 antigens. Furthermore, a non-cytolytic tumor-associated antigen-specific CD4+ T cell clone able to induce the DTH response in concert with lentinan reconstituted the antitumor effects in B6 nude mice when administered with lentinan. These results suggest that, in addition to the augmentation of immune effector cell activity against tumors, infiltration of these cells into the tumor burden initiated by the DTH responses at tumor sites may be involved in eradication of tumors by lentinan.

Superantigen-based tumor therapy: in vivo activation of cytotoxic T cells

We have recently demonstrated that the superantigen staphylococcal enterotoxin A (SEA) targets in vitro activated cytotoxic T lymphocytes against tumor cells expressing major histocompatibility complex (MHC) class II antigens. In this report we analyze the use of SEA as an immunoactivator in vivo. Treatment of mice with SEA activated a fraction of CD3+ T cells apparently as a function of their T cell receptor V beta expression. SEA induced interleukin-2 receptor expression and proliferation in both CD4+ and CD8+ T cells. This proliferative response was dose-dependent (0.1-100 micrograms/mouse), peaked during day 1 after treatment and declined to background levels within 4 days. The cytotoxic response, measured as cytotoxicity to SEA-coated MHC class II+ target cells (staphylococcal-enterotoxin-dependent cell-mediated cytotoxicity, SDCC), was maximal at a dosage of 1 microgram SEA/mouse. The SDCC was confined to the CD8+ T cell compartment, peaked 2 days after treatment and declined to background levels within 4 days. A second injection of SEA on day 5 after the first SEA treatment resulted in SDCC function with kinetics and magnitude identical to that seen after one injection. These results pave the way for the use of SEA in the treatment of MHC class II+ tumors.

Interactions between CD4+ T-cells and rat Schwann cells in vitro. 2. Cytotoxic effects of P2-specific CD4+ T-cell lines on Lewis rat Schwann cells

The cytotoxic effects of CD4+ P2-specific T-cell lines on Schwann cells were examined in vitro with 51Cr-release cytotoxicity assays. Only those P2-specific T-cell lines capable of inducing EAN when injected back into adult Lewis rats were cytotoxic to the Schwann cells. The addition of exogenous P2 protein was not necessary for the cytotoxic effect. The monoclonal antibody (mAb) OX6 directed against Major histocompatibility complex (MHC) class II molecules blocked cytotoxicity, indicating an essential role for MHC class II molecules in this interaction between CD4+ T-cell lines and Schwann cells.

Requirements for lysis of activated T cells by class-II-restricted cytolytic T-lymphocytes

In the present study, we explored the specific requirements for lysis of human activated T cells by CD4+ CTLs. This was achieved by using human CD4+ T cell lines or clones specific for a peptidic fragment of influenza virus as both CTL effectors and target T cells (TTCs). Our results further establish that human activated T cells expressing HLA-DR molecules can present Ag to and be lysed by CD4+ HLA-DR restricted CTLs. This killing is Ag specific and HLA-DR restricted. It can be observed whether TTCs are heterologous or autologous, CD4+ or CD8+. However, we find that in our model: (a) TTCs are able to present artificially processed peptidic fragments of Ag, but not the corresponding natural Ag in the context of class II determinants, even if they can process whole virus in the context of class I determinants; (b) TTCs must express high density of HLA-DR molecules on their membrane; (c) preincubation of TTCs with high concentrations of peptide is required; and (d) interestingly enough, addition of free peptide at similar concentration during the cytolytic assay to replace TTC preincubation inhibits TTC lysis by at least two different mechanisms, i.e., cold-target inhibition in which CTLs serve as their own cold targets and inhibition at the effector cell level. From these results, one can conclude that stringent conditions are required for lysis of activated T cells by class-II-restricted CTLs.

Theileria parva: CD4+ helper and cytotoxic T-cell clones react with a schizont-derived antigen associated with the surface of Theileria parva-infected lymphocytes

Theileria parva is a protozoan parasite which infects and transforms bovine lymphocytes, resulting in a fatal lymphoproliferative disease. There is evidence that immunity to the intralymphocytic schizont stage is mediated by T cells. We have previously reported derivation of CD4+ T-cell clones which recognize parasite-derived antigens presented on the surface of infected cells in conjunction with MHC molecules and partial characterization of the antigens. The present study further evaluated one of these antigens, demonstrating that it could be derived from cells infected with different parasite stocks as well as from purified theilerial schizonts and that it was recognized by primed, but not unprimed, bovine lymphocytes including cytolytic CD4+ T cells. Using a cloned CD4+ cytolytic cell line, lysis of schizont-infected cells was shown to be MHC-restricted but not parasite-strain restricted. In addition we demonstrated that T cells which respond to the HSS antigen preparation were generated in cattle immunized with parasites from any of the three subspecies of T. parva. The antigenic material was fractionated by sequential subjection to anion-exchange chromatography, hydroxylapatite chromatography, and gel filtration using HPLC, which resulted in recovery of approximately 20% of the antigenic material with more than 10(6)-fold purification in selected fractions. To assess the molecular size of the proteins in the highly purified antigenic fractions, the T. parva-infected lymphocytes were metabolically labeled before fractionation with 3H-amino acids and the material was analyzed by SDS-polyacrylamide gel electrophoresis and liquid scintillation counting of gel slices. The major protein in these fractions had a molecular mass of 9-10 kDa.

Update on tumor vaccines

Vaccination against tumor has always been an attractive idea for the treatment of patients bearing tumor. By harnessing the host's own immune response the attack on tumor cells would act on a continuing basis, with emerging tumor cells stimulating their own destruction. However, the approach has been hampered by our poor understanding of the nature of tumor antigens and of the pathways by which immune cells might operate against tumor growth. Recent developments in molecular biology and immunology are remedying this deficiency and bringing vaccination to the forefront of new approaches to treatment of a range of tumors. Results obtained in B-cell tumors, where the idiotypic immunoglobulin at the cell surface provides a well-defined tumor antigen, are already indicating exciting possibilities as well as delineating problems. There is considerable clinical evidence that patients have some intrinsic ability to control tumor growth and that certain tumors remain dormant for long periods. Attempts to understand and perhaps stimulate the mechanisms involved are being made through the use of biological modifiers and by manipulating potential effector cells in vitro. Ideally this approach, which may include non-specific and specific elements, could be combined with specific vaccination in order to combat the apparent ability of many tumor cells to evade host defences.

Recent observations regarding the pathogenesis of recurrent respiratory syncytial virus infections: implications for vaccine development

Respiratory syncytial virus (RSV) and influenza virus are common pathogens for all age groups. Currently licensed influenza virus vaccines generally provide protection from clinically detectable disease caused by antigenically matched challenging viruses. In contrast, vaccine development for RSV has been hampered by the inability of candidate vaccines to induce protective immunity to naturally occurring infection. The precise mechanism(s) responsible for the RSV vaccine failures have not been determined. We raise the possibility that infection by RSV is associated with attenuation of both proliferative and non-proliferative RSV-specific responses by human mononuclear leucocytes that results in the suppression or delay of host anamnestic defences, allowing development of recurrent clinical illness despite pre-existing immunity.

Comparison of the humoral and cytotoxic T-lymphocyte response to individual HLA class I alloantigens in highly immunized patients

In order to investigate the correlation between activation of cytotoxic T-lymphocyte precursor (CTLp) and the formation of antibodies to alloantigens, we studied 21 highly sensitized patients waiting for a kidney transplantation. Both antibody reactivity and CTLp frequencies of these patients were determined against 88 individual HLA class I alloantigens. A high or low CTLp frequency against a certain HLA-A or -B alloantigen was not correlated with the presence or absence of the antibodies to that antigen. Mismatched antigens, towards which the patient had not formed antibodies, can induce either a higher or a lower frequency of CTLp compared to mismatches towards which the patients had formed antibodies. The possible implications of this lack of correlation between the T- and B-cell allorepertoires with regard to donor selection for (highly immunized) patients is discussed.

Analysis of T cell receptor beta and gamma genes from peripheral blood, regional lymph node and tumor-infiltrating lymphocyte clones from melanoma patients

A total of 199 T cell clones from two melanoma patients were derived from progenitor T cells from recurrent melanoma, regional lymph nodes (either involved or uninvolved with malignancy) and peripheral blood by inoculating single cells directly into the wells of microtiter plates before in vitro expansion. The surface marker phenotype of most clones was CD4+CD8-, although some were CD4-CD8+. Genomic DNA prepared from all clones was analyzed by Southern blot hybridization using T cell receptor (TCR) beta and gamma gene probes, seeking clones with identical TCR gene rearrangement patterns as direct evidence for in vivo progenitor T cell clonal amplification. Probing HindIII-digested DNA with TCR beta and TCR gamma probes revealed several clones with identical TCR gene rearrangement patterns. These clones had subsequent probing of BamHI-digested DNA with TCR beta and TCR gamma probes, which showed all but 2 clones to have distinct rearrangement patterns. These analyses provide clear molecular evidence for in vivo polyclonal CD4+ T cell populations in each of several separate immune compartments in these patients.

Ambient level ozone effects on subpopulations of thymocytes and spleen T lymphocytes

The effects of ozone on thymocyte and spleen T lymphocyte subpopulations were studied. Balb/c mice were exposed to clean air or to 0.3 +/- 0.05 ppm ozone for 1-3 wk. Thymocytes and spleen T cells were stained with fluorochrome conjugated monoclonal antibodies against surface differentiation markers and/or propidium iodide for deoxyribonucleic acid (DNA). The cells were then analyzed by fluorescence activated cell sorter. The percentages of certain thymocyte and spleen T lymphocyte subtypes and DNA synthesizing spleen T cells were lower following 1 wk of ozone exposure. After 3 wk exposure, the thymocyte percentages were higher in ozone-exposed mice, whereas the absolute number remained lower, and spleen T lymphocytes showed no changes. The findings suggest that short-term ozone inhalation can affect the T cell immune system adversely, particularly the CD4+ cells.

T-cell clones that react against autologous human tumors

T cells (derived from peripheral blood lymphocytes [PBL], lymph nodes or tumor tissues and restimulated with autologous tumor cells and expanded in interleukin-2 [IL-2]), when cloned, produce three functional classes of clone. Class I T-cell clones exhibit the phenotype of alpha/beta cytotoxic T lymphocytes (CD3+, CD8+, CD4-, WT31+), use their CD3-alpha/beta complexes for cognate function, and lyse the autologous tumor cells specifically in a major histocompatibility complex (MHC) Class I-restricted manner. The second class of T cell clone expresses identical phenotype but exhibits a rather broad cytotoxic profile against the autologous and allogeneic tumor cells derived from tumors with similar and/or dissimilar histologies. Although these CTL clones can, at times, show MHC Class I-restricted killing and use their T-cell receptors (TCR) complexes for function, activation via certain accessory molecules, particularly lymphocyte-function associated (LFA-1) antigens, might induce their broad cytotoxic behavior. The nature of the tumor antigen recognized by the Class I antigen-specific CTL clones remains unknown. It is evident, however, that more than one antigen can be associated with a given tumor and they are recognized by different CTL clones from individual patients. The third class of T-cell clone is usually of CD4+ alpha/beta T cells (CD3+, CD4+, CD8-, WT31) and these T-cell clones exhibit no cytotoxicity toward the autologous or allogeneic target cells. When tested for potential regulatory property, one type of CD4+ T-cell clone exhibits the characteristics of helper T cells. This type induces or amplifies cytotoxic response in fresh PBL by elaborating interleukin-2 (IL-2) and interferon-gamma). These helper T-cell clones can proliferate against the autologous tumor cells and demonstrate functional specificity for the autologous tumor cells. The other type of CD4+ T-cell clone exhibits the phenotype of the helper T-cell clone (CD3+, CD4+, CD8-, WT31+) but suppresses the cytotoxic response of the autologous PBL in co-culture in the presence of the autologous tumor cells and exogenous IL-2. In some situations, these CD4+ suppressor T-cell clones exhibit considerable specificity for the autologous tumor cells. They do not suppress the cytotoxic response against allogeneic targets or against EBV-infected autologous lymphoblastoid cells. Furthermore, they specifically up-regulate their IL-2 receptors (IL-2R) when stimulated by the autologous tumor cells or with autologous tumor cell-pulsed antigen-presenting cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Mechanisms of tumour rejection in the murine DBA/2-SL2 concomitant immunity system

The mechanisms of rejection of secondary tumours were studied in concomitant immunity using transplants of standard-size solid SL2 tumours in syngeneic DBA/2 mice. In such a system primary tumor implants are not rejected, in contrast to secondary tumour implants. The second tumour was mainly rejected 2-4 days after implantation. Both primary tumour and secondary tumour implants (which are rejected) contained hardly any lymphocyte infiltrate, whereas, 2-4 days after implantation they contained 40%-50% macrophages, which were cytotoxic in vitro. Transfer (s.c.) of these tumours to naive mice showed that cellular infiltrates in the secondary implants did not always cause tumour rejection. Serum collected on day 4 after implantation of the secondary tumour was cytotoxic to SL2 tumour cells in vitro, whereas serum from mice with only primary implants was not cytotoxic on day 4 after implantation. Preliminary characterization of this cytotoxic factor showed that it was heat-labile, as cytotoxicity disappeared after 30 min at 56 degrees C, the molecular mass of the factor was higher than 100 kDa, and it was not IgG. We hypothesize that secondary tumours in the DBA/2-SL2 concomitant immunity system are rejected mainly between 2 and 4 days after implantation as a result of the combined action of cytotoxic serum and the presence of 40%-50% cytotoxic macrophages. The primary tumour is not rejected at 2-4 days after implantation as there is no cytotoxic factor.

Antigen processing: current issues, exceptional cases (Thy 1 alloantigen, MHC class-II-restricted cytolytic T cells), and implications for vaccine development

A dogmatic view of antigen processing is presented in outline, followed by a survey of unresolved issues in the subject. The activity of Thy 1 as an alloantigen, and allospecific MHC Class-II-restricted cytolytic T cells offer examples of exceptional cases of antigen presentation. Implications for the design of vaccines are drawn.

Delayed-type hypersensitivity to tumor antigens co-expressed with immunogenic determinants induced by xenogenization

Previous work has shown that murine lymphoma cells antigenically altered ("xenogenized") by drug treatment elicit strong in vivo resistance to the original cells. Moreover, splenocytes immune to a drug-treated variant (L5178Y/DTIC) of a murine lymphoma exert anti-parental tumor activity in an adoptive transfer system, an effect mediated by L3T4+ lymphocytes and associated with the detection of an anti-L5178Y delayed-type hypersensitivity (DTH) response. We now report that the in vivo activity of the tumor-immune L3T4+ lymphocytes is a radio-sensitive (2,500 rad in vitro) phenomenon that requires collaboration with radio-resistant, silica-sensitive syngeneic cells in the host, and is inhibited by treatment of recipient mice with monoclonal antibodies (MAbs) to the L3T4 antigen or murine interferon-gamma (IFN-gamma). In vitro, the tumor-immune L3T4+ lymphocytes produce interleukin 2 (IL-2), lymphotoxin (LT) and IFN-gamma activities on incubation with L5178Y cells and spleen-adherent cells. These results suggest that the mechanisms of anti-parental tumor protection by xenogenized cells involve specific induction of a DTH response mediated by the "inflammatory" (THI) subset of L3T4+ T lymphocytes and IFN-gamma activated macrophages.

Prospects for the treatment of B cell tumors using idiotypic vaccination

Manipulation of the immune system in order specifically to attack autologous tumor cell has been a distant goal, largely due to the poor definition of tumor-associated antigens. By focussing on B cell lymphomas which express a molecularly defined clonal marker, the idiotypic immunoglobulin, it has been possible to generate autologous anti-idiotypic responses which suppress individual tumors. Studies of the components of these responses are providing insight into host effector mechanisms which can be activated against tumors, and also into the many strategies adopted by the target cells in order to avoid such attack. Promising results in various animal models where tumor bearers can be treated by idiotypic immunization have led to the point where application of this approach to the treatment of certain categories of human B cell lymphoma can be considered.

Cancer patients' lymphocytes contain CD3+ CD4+ cells that proliferate in response to autologous tumor cells in the presence of exogenous low-dose interleukin-2 and autologous accessory cells

To see whether cancer patients possess CD3+ CD4+ lymphocytes able to proliferate in response to autologous tumor cells (Auto-Tu), this lymphocyte subset was isolated either by positive or negative selection, both methods resulting in highly enriched CD4+ populations. Unseparated and isolated CD3+ CD4+ lymphocytes were then assayed for proliferating activity in the presence or absence of various amounts of Auto-Tu, with or without recombinant interleukin-2 (IL-2) (1.5-15 U/ml) and DR+ adherent cells or E- lymphocytes as autologous accessory cells (Auto-AC). Isolated CD3+ CD4+ lymphocytes were stimulated by Auto-Tu alone in only 1 out of 12 cases. CD3+ CD4+ cells failed to proliferate significantly in response to low doses of IL-2 alone but the addition of Auto-Tu caused stimulation in 8 out of 12 cases (67%). The further addition of Auto-AC to Auto-Tu + IL-2 resulted in enhanced response of isolated CD3+ CD4+ lymphocytes in 6 out of 8 cases tested. When reactivities to Auto-Tu in the presence of IL-2 and IL-2 + Auto-AC were considered together, positive responses of CD3+ CD4+ lymphocytes were seen in 11 out of 12 cases (92%). On the other hand, unseparated lymphocytes were stimulated by Auto-Tu alone in none out of 12 cases. Unseparated lymphocytes, however, responded to IL-2 in 11 out of 12 cases; such a response was increased by the addition of Auto-Tu in only 2 cases. Moreover, the IL-2 proliferation of unseparated lymphocytes was suppressed in 4 and in 3 out of 12 cases tested when Auto-Tu or Auto-Tu + Auto-AC were added respectively. These data indicate that lymphocytes of cancer patients contain CD3+ CD4+ cells that are usually unable to proliferate in response to Auto-Tu only. This proliferation, however, occurs when low doses of exogenous IL-2 are present and can be further amplified by the addition of Auto-AC. No response of CD4+ cells is observed in the presence of DR+ Auto-AC + IL-2 except in 2 out of 7 cases tested (28%), suggesting an Auto-Tu-restricted reactivity of CD3+ CD4+ lymphocytes in the majority of cases.

Proliferative and/or cytotoxic activity of lymphocyte clones to autologous human melanoma

Peripheral blood lymphocytes (PBL) of a patient with metastatic melanoma were cultured with autologous melanoma cells (Auto-Me) and recombinant interleukin 2 (IL-2) (MLTC-PBL). Thirty-five days later, when no cytotoxicity against Auto-Me or K562 was detectable, MLTC-PBL were cloned in the presence of Auto-Me, IL-2 (25 U/ml) and Daudi cells as feeder. Eighty-one growing clones were simultaneously screened for proliferative and cytotoxic activity to Auto-Me. Twenty-two clones proliferated in the presence of Auto-Me only, 29 in the presence of IL-2 only and 41 in the presence of Auto-Me plus IL-2; 12 clones showed cytotoxic activity against Auto-Me. Six clones expressed both cytotoxic and proliferative activity to Auto-Me. The phenotype of 6 proliferative clones tested was CD3+, CD4+, WT31+, CD8-, CD16-, Leu19-, whereas that of 2 cytotoxic-proliferative clones tested was CD3+, CD8+, Leu19+, WT31+, CD4-, CD16-. Specificity analysis of proliferative response of 6 clones and of cytotoxicity of 7 clones, tested on a panel of 14 different target cells, revealed a complex pattern of reactivity, each clone expressing a peculiar specificity. Our results suggest the possibility of isolating, from melanoma patients' PBL, T-cell clones with proliferative activity to Auto-Me and Auto-Me plus IL-2, and T-cell clones which apparently express both proliferative and cytotoxic activity to Auto-Me.

Induction of tumor suppression and delayed-type footpad reaction by transfer of lymphocytes sensitized to a xenogenized tumor variant

Splenocytes immune to a highly immunogenic ("xenogenized", L5178Y/DTIC) variant of a murine lymphoma exert anti-parental-tumor activity in a systemic adoptive transfer system, the effect being apparently associated with the Lyt-2- fraction of the lymphocyte population. During investigation of the mechanisms of this protection, we found that the L5178Y/DTIC tumor-immune lymphocytes exhibited an appreciable anti-L5178Y delayed-type hypersensitivity (DTH) response. Enrichment of those lymphocytes in L3T4+ cells significantly enhanced the protective effect as well as the DTH reaction, whereas the use of an anti-L3T4 but not anti-Lyt-2 reagent blocked both activities. In vitro, lymphocyte proliferation against L5178Y cells occurred and was apparently associated with the Lyt-2- fraction of a population of L5178Y/DTIC immune splenocytes.