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Query: UMLS:C0023418 (
leukemia
)
93,477
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Ligation of CD28 on T cells with its natural ligands B7-1 (
CD80
) or B7-2 (CD86) provides a major costimulatory signal for T cells and is of potential importance for tumor rejection. We previously reported a strong expression of B7-1 on Reed-Sternberg cells and anaplastic large cell lymphoma cells. We report here our findings on B7-2 expression by malignant lymphomas (n = 70). B7-2 was present on the neoplastic cells of anaplastic large cell lymphoma in two of three cases studied, and on a subpopulation of the malignant cells in one out of four cases of follicular lymphoma. B7-2 was not expressed by the neoplastic cells of the other non-Hodgkin's lymphomas (n = 32), including T cell-rich B cell lymphoma. In contrast, Reed-Sternberg cells in lymph nodes affected by Hodgkin's disease are strongly positive for B7-2 (n = 31). Evidence for a functional correlate of this expression was obtained by our findings that the combination of anti-B7-1 and anti-B7-2 monoclonal antibodies was more effective than each separately in blocking allogeneic T cell activation (proliferation and cytokine secretion) by Hodgkin's disease-derived cell lines as stimulators. The possible role of B7-1 and B7-2 expression for the course and symptomatology of Hodgkin's disease is discussed.
Leukemia
1997 Jun
PMID:Expression of B7-2 (CD86) molecules by Reed-Sternberg cells of Hodgkin's disease. 917 39
B7 molecules provide an important costimulatory signal for T cell receptor/CD3-mediated T cell activation via binding to their cognate receptors, CD28 and CTLA-4. We have introduced B7-1 (
CD80
) into M1 cells, spontaneously-occurred mouse myelocytic leukemic cells and assessed its potential in the induction immunity to
leukemia
cells. Syngeneic, immunocompetent SL mice receiving polyclonal B7-1-transduced M1 cells showed prolonged survival than control mice. Two independent B7-1-transduced monoclonal sublines, M1-B7-1+ (F20) and M1-B7-1+ (F7), were rejected in 100% an 50% of SL mice, respectively. In vivo depletion of T cell subsets showed that both CD4+ and CD8+ T cells were indispensable for the B7-1-dependent anti-leukemic immunity. Although a single exposure to irradiated monoclonal M1-B7-1+ cells were not fully effective, multiple exposures induced protective immunity against subsequent challenge with M1 cells. Furthermore, hyperimmunization with irradiated monoclonal M1-B7-1+ (F7) cells could partly cure mice previously injected with a lethal number of M1 cells. Although other groups have demonstrated that live, proliferating B7-1-transduced leukemic cells can improve antitumor immunity, this is the first report which shows that irradiated B7-1-transduced myeloid leukemic cells can induce protective and therapeutic immunity against
leukemia
.
Leukemia
1997 Apr
PMID:Protective and therapeutic immunity against leukemia induced by irradiated B7-1 (CD80)-transduced leukemic cells. 920 59
In contrast to other neoplasms, antigen-specific autologous cytolytic T cells have not been detected in patients with human pre-B-cell leukemias. The absence of efficient B7 family (B7-1/
CD80
; B7-2/CD86) -mediated costimulation has been shown to be a major defect in tumor cells' capacity to function as antigen-presenting cells. We show here the generation of autologous anti-pre-B-cell
leukemia
-specific cytolytic T-cell lines from the marrows of 10 of 15 patients with pre-B-cell malignancies. T-cell costimulation via CD28 is an absolute requirement for the generation of these autologous cytolytic T cells (CTL). Although costimulation could be delivered by either bystander B7 transfectants or professional antigen-presenting cells (indirect costimulation), optimal priming and CTL expansion required that the costimulatory signal was expressed by the tumor cell (direct costimulation). These anti-pre-B-cell
leukemia
-specific CTL lysed both unstimulated and CD40-stimulated tumor cells from each patient studied but did not lyse either K562 or CD40-stimulated allogeneic B cells. Cytolysis was mediated by the induction of tumor cell apoptosis by CD8+ T cells via the perforin-granzyme pathway. Although we were able to generate anti-
leukemia
-specific CTL from the bone marrow, we were unable to generate such CTL from the peripheral blood of these patients. These studies show that antigen-specific CTL can be generated from the bone marrow of patients with pre-B-cell leukemias and these findings should facilitate the design of adoptive T-cell-mediated immunotherapy trials for the treatment of patients with B-cell precursor malignancies.
...
PMID:Ex vivo generation of human anti-pre-B leukemia-specific autologous cytolytic T cells. 922 54
CD80
(B7/BB-1, B7-1) and CD86 (B70, B7-2) take an important role in the interaction between T lymphocytes and antigen presenting cells (APCs) as co-stimulatory molecules. We analyzed the manifestation of adhesion molecules, including
CD80
and CD86, on some
leukemia
and lymphoma cells. Constitutive expression of
CD80
and/or CD86 was frequently observed on B cell
leukemia
/lymphoma cells, while it is rare on myeloid leukemia cells. Interferon-alpha (IFN-alpha) amplified the manifestation of MHC class I and interferon-gamma (IFN-gamma) did both class I and class II. We also showed
CD80
could be induced by IFN-alpha on K562 cells, which were originally negative for
CD80
. Our data implies the immunotherapy via
CD80
and CD86 for patients with hematological malignancies and the possibility to enhance it using interferons.
...
PMID:The heterogeneous expression of CD80, CD86 and other adhesion molecules on leukemia and lymphoma cells and their induction by interferon. 926 43
Leukemia
cells may express tumor specific antigens in association with Class I and II major histocompatability complex (MHC) molecules. However, lack of expression of conventional costimulator molecules means that these cells tend to induce specific T-cell anergy rather than activation. CD40 ligand (CD40L) is a costimulator molecule that directly activates T cells and may promote antigen presentation by CD40-expressing cells, which include professional antigen presenting cells and B-acute lymphoblastic leukemia (ALL) cells from many patients. We determined whether transgenic expression of CD40L could enhance an antileukemia immune response using a CD40+ murine lymphoblastic (A20)
leukemia
and a CD40- myeloblastic (WEHI-3)
leukemia
in a tumor treatment model. Injection of otherwise nonimmunogenic A20 cells in the presence of CD40L induced an immune response active against preexisting A20 tumor at a distant site. Moreover, concomitant local secretion of transgenic interleukin-2 (IL-2) further amplified the antileukemic response induced and increased protection against preexisting tumor. In ex vivo studies, CD40 activation of A20 cells enhances the antigen presenting potential of A20 cells by upregulating expression of B7.1 (
CD80
), Class I and II MHC molecules, and increases expression of fas antigens. The importance of CD40 activation to the resulting antitumor response is further emphasized by the failure of transgenic CD40L to protect against the CD40- WEHI myeloblastic
leukemia
. Depletion studies showed the protective effects against A20 cells to be mediated by a combination of CD4+ and CD8+ T lymphocytes and by natural killer (NK) cells. These results suggest a means by which CD40+
leukemia
cells may be rendered immunogenic in vivo.
...
PMID:CD40 ligand induces an antileukemia immune response in vivo. 929 26
B7 molecules provide an important co-stimulatory signal for T cell receptor/CD3-mediated T cell activation via binding to their cognate receptors, CD28 and CTLA-4. We have introduced B7-1 (
CD80
) into M1 cells, spontaneously occurring mouse myelocytic leukemic cells, and assessed its potential to induce antitumor immunity to
leukemia
cells. Syngeneic, immunocompetent SL mice receiving two independent B7-1-transduced monoclonal sublines, M1-B7-1/F/clone F20 and M1-B7-1/F/clone F7, were rejected in 57% and 43% of SL mice, respectively. In vivo depletion of T cell subsets showed that both CD4+ and CD8 T cells were indispensable for the B7-1-dependent anti-leukemic immunity. Although a single exposure of irradiated monoclonal M1-B7/1/F cells was not fully effective, multiple exposures induced protective immunity against subsequent challenge with parental M1 cells. Furthermore, multiple vaccinations with irradiated monoclonal M1-B7-1/F/clone F7 cells could cure 67% of mice previously injected with a lethal number of M1 cells. These results emphasize that multiple exposures of irradiated B7-1-transduced myeloid leukemic cells can induce protective and therapeutic immunity against
leukemia
and that B7-1-mediated gene therapy may have therapeutic efficacy for patients with acute myelocytic leukemia.
...
PMID:Protective and therapeutic immunity against leukemia induced by irradiated B7-1 (CD80)-transduced leukemic cells. 929 32
In an attempt to explore novel treatment modalities in acute myeloid leukemia (AML), we studied the role of costimulatory and cytokine gene immunotherapy in murine AML. We have previously shown that leukemic mice can be cured with
CD80
transfected leukemic cells (B7. 1-AML vaccine) administered early in the course of the disease and that the failure B7.1-AML vaccines administered late cannot be attributed to immunosuppression induced by tumor growth. CD8+ T cells, which are necessary for tumor rejection, are activated rather than suppressed during the first half of the leukemic course in nonvaccinated mice. In this report, we question whether CD86 (B7.2) or the cytokines granulocyte-macrophage colony-stimulating factor (GM-CSF), interleukin-4 (IL-4), or tumor necrosis factor-alpha (TNF-alpha) can improve the vaccination potential of AML cells. The choice of cytokines was based on their combined and alone as well ability to direct the differentiation of CD34+ cells into potent antigen-presenting dendritic cells in vitro. Our studies show that (1) mice vaccinated with a leukemogenic number of AML cells engineered to express B7.2 (B7.2-AML) or to secrete GM-CSF, IL-4, or TNF-alpha (GM-, IL-4-, TNF-alpha-AML) do not develop
leukemia
; (2) GM-AML cells are tumorigenic in sublethally irradiated SJL/J mice but not in Swiss nu/nu mice, indicating that killing of tumor cells is not T-cell-dependent; (3) vaccines with irradiated GM-AML, but not B7.2-, IL-4-, or TNF-alpha-AML cells, can elicit
leukemia
-specific protective and therapeutic immunity; and (4) in head-to-head comparison experiments, vaccination with irradiated GM-AML is more potent than B7.1-AML, curing 80% and providing 20% prolonged survival of the leukemic mice at week 2, as opposed to cures only up to 1 week with B7.1-AML vaccines. These preclinical data emphasize that GM-CSF gene immunotherapy deserves clinical evaluation in AML.
...
PMID:Gene immunotherapy in murine acute myeloid leukemia: granulocyte-macrophage colony-stimulating factor tumor cell vaccines elicit more potent antitumor immunity compared with B7 family and other cytokine vaccines. 941 88
Various clinical and laboratory observations suggest that the
leukaemia
cells in chronic myeloid leukaemia (CML) are potentially immunogenic. Whilst the ability of the
leukaemia
cells to elicit an anti-leukaemic immune response in the allogeneic setting is established, it remains unclear why such anti-leukaemic response does not occur in vivo in the autologous setting. We previously demonstrated the presence of
leukaemia
-reactive T cells in a patient with CML. However, we found that the T cells were normally anergic unless pre-incubated in vitro in high-dose recombinant interleukin-2. We speculated that the T cell anergy was the result of a lack of the appropriate immune costimulatory molecules on the
leukaemia
cell surface. In this study, we confirm the absence of immune costimulatory molecules,
CD80
(B7-1) and CD86 (B7-2), on
leukaemia
cells and demonstrated that these costimulatory molecules on the
leukaemia
cells can be upregulated by a combination of GM-CSF and IL-4. There was an associated restoration of
leukaemia
cell immunogenicity to autologous T cells in mixed lymphocyte
leukaemia
reactions, suggesting a possible enhancement of anti-leukaemic reaction. More importantly, T cells primed with 'activated'
leukaemia
cells were able to recognise fresh cytokine-naive
leukaemia
cells. Furthermore,
leukaemia
cells expressing the dendritic cell marker, CD1a, were also generated. Our findings therefore suggest the opportunity in future to use these combination cytokines in vivo or these
leukaemia
cells which have been activated in vitro for
leukaemia
immunotherapy.
Leukemia
1997 Dec
PMID:Cytokine enhancement of immunogenicity in chronic myeloid leukaemia. 944 20
Clinical data and animal models afford evidence for anti-
leukemia
immunity in humans, but the interactions critical for blast cell recognition are unresolved. Expression of B7 molecules by antigen-presenting cells (APC) provides co-stimulatory signals to T lymphocytes via CD28 and CTLA-4 which prevent the induction of alloantigen-specific tolerance. Conversely, expression of CD40 ligand by stimulated T cells activates APC via CD40. In human hematological B cell malignancies (follicular lymphoma and chronic lymphocytic leukemia), the defect in alloantigen presentation of tumoral cells can be repaired by up-regulation of B7 and other co-stimulatory molecules via CD40. We studied the role of B7 molecules in alloimmune recognition and the various ways to improve the antitumoral response on peripheral blood leukemic cells from 20 patients with a diagnosis of primary acute myeloid leukemia (AML). We focused on myelo/monocytic M4/M5 French-American-British classification subtypes which are considered as the neoplastic counterpart of normal monocytes, a prototypic APC. In one-way mixed lymphocyte reaction of CD4+ T cells against leukemic cells, differences in B7-1, B7-2 or CD40 expression by AML cells did not induce specific cytokine secretion; interleukin (IL)-2 and interferon (IFN)-gamma were detected but not IL-4, corresponding to a Th1 pattern. Blockade experiments showed that proliferation and IFN-gamma secretion only partially depended on B7 molecules, which in contrast had a pivotal role in IL-2 synthesis. In contrast with murine models which suggest a pivotal role for
CD80
/B7-1 in the immune response against AML, our data support a greater role for CD86/B7-2, in line with the baseline expression of CD86/B7-2 and lack of
CD80
/B7-1 on most M4/M5 AML cells. AML cell stimulation via CD40: (1) significantly improved IL-2 secretion but not proliferation of responding T lymphocytes, (2) increased CD54/ICAM-1 expression in three quarters of cases, (3) failed in most cases to induce CD40-specific
CD80
/B7-1 up-regulation, and (4) had a weak effect on CD86/B7-2 expression. These data contrast with the very efficient up-regulation of both B7 co-stimulatory molecule expression and tumoral cell alloimmune recognition following CD40 stimulation in B cell malignancy models. The role of the defective B7 molecule up-regulation by the CD40 pathway in inefficient tumor immunogenicity of primary AML cells has to be further investigated, in particular using transfection experiments of
CD80
/B7-1-deficient AML cell lines. From our in vitro data we conclude that B7 molecules play an important role in the alloimmune surveillance of AML as suggested by the high B7 molecule dependency of IL-2 secretion. Nonetheless, the contribution of B7 molecules to alloimmune T cell proliferation against primary AML cells in human and the way to improve it--regulation via CD40 in particular--differ from B cell malignancies and murine models, suggesting the requirement for specific strategies in the development of antitumor immunity.
...
PMID:Regulation of CD80/B7-1 and CD86/B7-2 molecule expression in human primary acute myeloid leukemia and their role in allogenic immune recognition. 948 89
Despite sufficient levels of HLA class I and class II expression, acute myeloid leukemia (AML) cells usually fail to induce a significant T-cell response in vitro. Therefore, we investigated whether in vitro modifications could enhance the T-cell stimulatory properties of AML cells. AML cells were either cultured with granulocyte-macrophage colony-stimulating factor (GM-CSF), interleukin-4 (IL-4), and tumor necrosis factor-alpha (TNF-alpha), or transfected with the
CD80
(B7.1) gene and used as stimulator cells for primed and unprimed allogeneic T cells. Cytokine treatment increased HLA class I and II expression, but did not induce
CD80
on AML cells. Cytokine-treated AML cells efficiently presented nominal and allo-antigens to primed T-cell clones, induced strong T-cell proliferation in HLA mismatched mixed lymphocyte reactions (MLR), but failed to induce primary T-cell responses from an HLA identical bone marrow donor in MLR. In contrast,
CD80
-transfected AML cells induced T-cell proliferation of HLA-identical bone marrow donor peripheral blood mononuclear cell (PBMC) in primary MLR, allowing the generation of
leukemia
reactive CD4(+) T-cell lines and clones. The majority of the generated oligoclonal (25 of 35) T-cell cultures showed patient specific reactivity that did not discriminate between patient's leukemic cells and Epstein-Barr virus (EBV)-transformed B cells (EBV-LCL). The remaining 10 oligoclonal T-cell cultures recognized only leukemic cells. One of these latter
leukemia
reactive oligoclonal T cells was cloned. The majority of the clones (25 of 29) reacted against both leukemic cells and patient's EBV-LCL. A minority of the T-cell clones with the CD4 phenotype (four of 29) showed strong HLA-DP restricted reactivity against leukemic cells, but not against patient's EBV-LCL or against HLA-matched nonleukemic cells, indicating that their target antigens are preferentially expressed by leukemic cells. In conclusion, our study shows that the in vitro allogeneic T-cell response induced by
CD80
-transfected AML cells is mainly directed against patient's specific minor histocompatibility antigens, while antigens preferentially expressed by leukemic cells can also trigger T-cell responses.
...
PMID:CD80-Transfected acute myeloid leukemia cells induce primary allogeneic T-cell responses directed at patient specific minor histocompatibility antigens and leukemia-associated antigens. 971 96
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