Mantle-cell Lymphoma Clinical Trial
Official title:
"Don't Eat me" Signal in Hematological Malignancies: CD24 as New Target to Improve Anti-cancer Immunity.
Mantle-cell Lymphoma (MCL) is a B-cell non-Hodgkin's lymphoma (NHL) with heterogeneous behavior,ranging from indolent phenotype to highly aggressive and drug resistant cases with dismal prognosis.Disease progression and drug resistance may be generated by Tumor Microenvironment (TME),owing that M2-like immunosuppressive tumor associated macrophages (TAM) are pathologically functional in providing survival signals to MCL cells-and TME is known to help mask tumoral cells from host immune system.Similarly, Chronic Lymphocytic Leukemia (CLL) is a B-cell malignancy characterized by increased circulating number of mature B lymphocytes that eventually reside into bone marrow and lymphoid tissues as well.Higher number of circulating abnormal B cells is secondary to a balance between increased proliferation and decreased apoptosis activities,sustained by signals also deriving from TME.As a matter of fact,TME harbors different cell compounds and monocyte-derived Nurse-like cells (NLCs) resemble the M2-like macrophage immunosuppressive profile and turned out to be an important component able to interact with CLL cells, providing improvement of proliferation and survival.Recently, cancer-expressed CD47 was found to be involved in tumor immune escape through interaction with Signal Regulatory Protein-α (SIRP-α) expressed by TAM,being able to quench phagocytosis. Interestingly,"Don't Eat Me" signal (DEMs) blockade with anti-CD47 monoclonal Antibody (mAb) showed promising activity in pretreated NHL,through increase of phagocytosis by TAM.CD24 was also demonstrated to be involved in DEMs in solid cancer.As a matter of fact, tumor-expressed CD24 promotes immune evasion through its interaction with the inhibitory receptor sialic-acid-binding Ig-like lectin10 (Siglec-10),expressed by TAM with immunosuppressive phenotype (M2-like).In a preclinical model of CD24+ solid tumors (ovarian and breast cancer) the blockade of CD24-Siglec-10 interaction with anti-CD24 mAb showed improvement of TAM-associated phagocytosis in vitro and TAM-dependent reduction of tumor growth and increase of survival in vivo.It is worth mentioning that CD24 can be expressed in some phases of B-cell differentiation and both MCL and CLL derives from a B-cell precursor with upregulated CD24.In this setting,CD24 might play a critical role in the anti-phagocytic signal, since MCL and CLL represents a subset of B-cell malignancies with a considerable hostile TME with M2-like TAM,able to jeopardize anti-cancer immunity.Therefore, the possibility to boost innate anti-cancer immunity through this DEMs blockade could provide new therapeutic options to previous heavily pretreated relapsed/refractory MCL and CLL patients.
MCL is an aggressive B-NHL with dismal prognosis with high probability of relapse after conventional immunochemotherapeutic regimen. CLL is instead an incurable chronic B-cell malignancy with higher probability of relapse after several lines of conventional therapies and a non-negligible risk of progression into an aggressive lymphoma. Further approaches are needed to provide valid alternatives for these relapsed and refractory diseases. In these two settings, TME is known to be involved in cancer cell survival and confers a negative impact on standard treatment efficacy and adoptive T cell immunity, for which new immunotherapeutic agents could be an alternative approach in case of poor prognostic settings. Within TME, TAM are involved in improving tumor growth survival in MCL and CLL, dampening immunotherapy as well. Anti-CD47 mAb turned out to be a consistent DEMs that, once blocked, is able to improve phagocytosis and clearance of tumor cells in blood cancer. CD24 has been recently validated as another DEMs in preclinical analysis in solid cancer. Since CD24 is expressed during early phase of B-cell differentiation, MCL and CLL might take advantage of the blockade of this signal, since TAM and NCLs are strictly interconnected with their corresponding tumoral cells, providing tumor cell proliferation and immune escape. To fulfill the purposes of this project, collection of leftover patient-derived samples will be routinary performed at the time of diagnosis and at the time of relapse of the disease, in this latter case with the aim to check any CD24, CD47 and CD20 surface expression modification on B-cell blasts (e.g., clone selection with CD24/CD47 upregulation after conventional regimen), SIRP-α and Siglec-10 expression on patient-derived Monocyte/Macrophage system (expressing higher levels of DEMs ligands as potential mechanism of resistance after conventional therapy). Furthermore, phagocytosis assays with samples obtained at the time of relapse will be compared with the equivalent experiments performed with the samples collected at the time of diagnosis to evaluate any potential differences. As previously described, phagocytosis analysis will be based on a co-culture process that involves the use of the anti-CD24 antibody (alone or in combination with other antibodies described in the secondary endpoint) incubating with macrophages (from healthy donor or from patient) and patient tumor cells (MCL or CLL), this latter labeled with a fluorescent substance (i.e., CFSE). Macrophage staining (with anti-CD11b-PE antibody) and subsequent flow cytometric analysis will be performed: the ratio between double stained macrophages (CD11b-PE+/CFSE+) and single stained macrophages (CD11b-PE+) will provide the entity of phagocytosis, which will be compared with the negative control and the other experimental conditions (antibody combinations described later in the secondary endpoints). The double staining of macrophages provides indirect results of phagocytosis (if the macrophage phagocytes CFSE+ cells, it will also acquire this staining in addition to that due to the anti-CD11b-PE antibody). Finally, donor-derived macrophages will be isolated from PBMC obtained from leftover peripheral blood which remained within the circuit used for plateletpheresis of healthy donors. As a matter of fact, residual blood (almost 15 ml) can be found in the reservoir of this circuit that is normally trashed after the procedure. Donors will sign informed consent for use of leftover material for research purposes and this project in particular. ;
| Status | Clinical Trial | Phase | |
|---|---|---|---|
| Terminated |
NCT00594308 -
In-Vivo Activated T-Cell Depletion to Prevent GVHD
|
N/A | |
| Completed |
NCT00407303 -
Safety and Efficacy of Obatoclax Mesylate (GX15-070MS) in Combination With Bortezomib for the Treatment of Relapsed or Refractory Mantle Cell Lymphoma (MCL)
|
Phase 1/Phase 2 | |
| Completed |
NCT03019666 -
Ph I Trial of NAM NK Cells and IL-2 for Adult Pts With MM and NHL
|
Phase 1 | |
| Active, not recruiting |
NCT02996773 -
Haploidentical BMT With Post-Transplant Cyclophosphamide and Bendamustine
|
Phase 1 | |
| Recruiting |
NCT02991638 -
Efficacy and Safety of Ibrutinib in Patients With CLL and Other Indolent B-cell Lymphomas Who Are Chronic Hepatitis B Virus Carriers or Occult Hepatitis B Virus Carriers
|
Phase 3 | |
| Active, not recruiting |
NCT02722668 -
UCB Transplant for Hematological Diseases Using a Non Myeloablative Prep
|
Phase 2 | |
| Completed |
NCT02661035 -
Allo HSCT Using RIC for Hematological Diseases
|
Phase 2 | |
| Recruiting |
NCT03314974 -
Myeloablative Allo HSCT With Related or Unrelated Donor for Heme Disorders
|
Phase 2 | |
| Active, not recruiting |
NCT00878254 -
Rituximab and Combination Chemotherapy in Treating Patients With Previously Untreated Mantle Cell Lymphoma
|
Phase 2 | |
| Active, not recruiting |
NCT02267915 -
Phase II of Efficacy and Toxicity of Maintenance Sub. Rituximab After Induction in Relapsed MCL and Non-eligible HSCT
|
Phase 2 | |
| Completed |
NCT00088205 -
Oral Enzastaurin in Participants With Relapsed Mantle Cell Lymphoma
|
Phase 2 | |
| Active, not recruiting |
NCT03112174 -
Study of Ibrutinib Combined With Venetoclax in Subjects With Mantle Cell Lymphoma (SYMPATICO)
|
Phase 3 | |
| Completed |
NCT00186628 -
Phase 2 Trial of Prophylactic Rituximab Therapy for Prevention of CGVHD
|
Phase 2 | |
| Completed |
NCT03010982 -
Open-Label, Multi-Center, Two-Part, Ph1 Study to Characterize the PKs of an Intravenous Micro-Dose of [14C]-Tazemetostat (EPZ 6438) and the ADME of an Oral [14C]-Labeled Dose of Tazemetostat in Subjects With B-Cell Lymphomas or Adv Solid Tumors
|
Phase 1 | |
| Completed |
NCT00783367 -
Combination Therapy Using Lenalidomide (Revlimid)- Low Dose Dexamethasone and Rituximab for Treatment of Rituximab-Resistant, Non-Aggressive B-Cell Lymphomas
|
Phase 2 | |
| Recruiting |
NCT00946374 -
Prospective Trial on Immunochemotherapy Plus Autologous Stem Cell Transplantation (SCT) and Allogenic SCT in Primary Mantle-Cell-Lymphoma
|
Phase 2 | |
| Completed |
NCT01474681 -
Safety and Tolerability of HSC835 in Patients With Hematological Malignancies
|
Phase 1/Phase 2 | |
| Active, not recruiting |
NCT02631044 -
Study Evaluating the Safety and Pharmacokinetics of JCAR017 in B-cell Non-Hodgkin Lymphoma (TRANSCEND-NHL-001)
|
Phase 1 | |
| Withdrawn |
NCT01163201 -
T-Regulatory Cell and CD3 Depleted Double Umbilical Cord Blood Transplantation in Hematologic Malignancies
|
Phase 1/Phase 2 | |
| Recruiting |
NCT05868395 -
Efficacy of Polatuzumab, Bendamustine and Rituximab in Patients With Relapsed/ Refractory Mantle Cell Lymphoma
|
Phase 2 |