Development Of Chimeric Antigen Receptor Research Articles

Emerging Role of CAR-T Therapy in Acute Myeloid Leukemia

Acute myeloid leukemia (AML), a malignant clonal disease originating from hematopoietic stem cells. In the past few decades, AML treatment has been dominated by a "3+7" regimen (anthracyclines + cytarabine), and the survival curve has stagnated. However, these procedures are associated with serious adverse effects. The development of chimeric antigen receptor (CAR)-T cell treatment provides a viable alternative, with decreased non-relapse death rates. Despite its potential, CAR-T cell therapy for AML confronts significant obstacles due to the disease's heterogeneity and accompanying toxicity. Genetic alteration strategies are being investigated to improve its safety and efficacy. Engineering CAR-T cells to express inhibitory receptors or suicide genes can help regulate T cell activity and prevent excessive immune activation. In summary, while CAR-T cell treatment has promise for AML, overcoming its hurdles through genetic modification and target refining is crucial. This review focuses on the existing landscape and future directions of CAR-T cell treatment for AML.

Current Insights into CAR T-Cell-Based Therapies for Myelodysplastic Syndrome.

Myelodysplastic syndromes (MDS) are due to defective hematopoiesis in bone marrow characterized by cytopenia and dysplasia of blood cells, with a varying degree of risk of acute myeloid leukemia (AML). Currently, the only potentially curative strategy is hematopoietic stem cell transplantation (HSCT). Many patients are ineligible for HSCT, due to late diagnosis, presence of co-morbidities, old age and complications likely due to graft-versus-host disease (GvHD). As a consequence, patients with MDS are often treated conservatively with blood transfusions, chemotherapy, immunotherapy etc. based on the grade and manifestations of MDS. The development of chimeric antigen receptor (CAR)-T cell therapy has revolutionized immunotherapy for hematological malignancies, as evidenced by a large body of literature. However, resistance and toxicity associated with it are also a challenge. Hence, there is an urgent need to develop new strategies for immunological and hematopoetic management of MDS. Herein, we discuss current limitations of CAR T-cell therapy and summarize novel approaches to mitigate this. Further, we discuss the in vivo activation of tumor-specific T cells, immune check inhibitors (ICI) and other approaches to normalize the bone marrow milieu for the management of MDS.

Donor-derived cytomegalovirus-specific CD8+ T cells restricted to shared, donor-specific, or host-specific HLA after HLA mismatched hematopoietic stem cell transplantation

Immune reconstitution after human leukocyte antigen (HLA)-mismatched (haploidentical) hematopoietic stem cell transplantation (haplo-HCT) can significantly influence long-term outcomes. The three possible HLA haplotypes after transplantation are: one carried by both the patient and the donor (shared HLA), one by donor only (donor-specific HLA), and one by patient only (host-specific HLA), and the donor T cells remain restricted to one of these three haplotypes. Understanding the presence of donor T cells restricted to each haplotype may provide more detailed insights into post-transplant immune response and potentially provide valuable information for the development of chimeric antigen receptor T cell or T cell receptor T cell constructs. In this study, patients or donors with HLA-A24 or HLA-A2 were tested with HLA-A*24:02- and A*02:01-restricted cytomegalovirus (CMV)-specific tetramers for detecting the respective HLA-restricted T cells. Sixty-four samples from 40 patients were assayed. More than half of the patients at day 90 and all patients by day 900 had shared HLA-restricted T cells. After day 90, half of the patients had donor-specific HLA-restricted T cells, but no host-specific HLA-restricted T cells were found. In the comparative analysis of the transplant types, shared HLA-restricted T cells were positive in all three categories: haplo-HCT (50%), 2-haplo-mis-HCT (75%), and spousal HCT (67%). Furthermore, donor-specific HLA-restricted T cells demonstrated positivity in haplo-HCT at 57% and in 2-haplo-mis-HCT at 60%, with a threshold of 0.01%. Donor-specific HLA-restricted T cells for spousal HCT were not examined due to the lack of an appropriate HLA combination for the tetramers.The presence of shared HLA-restricted T cells explains the host defense after HLA-haploidentical transplantation, while the presence of donor-specific HLA-restricted T cells may account for host defense against hematotropic viruses, such as CMV. However, this study failed to detect host-specific HLA-restricted T cells, leaving the host defense against epitheliotropic viruses unresolved, thus requiring further investigation.

Acute lymphoblastic leukaemia.

Acute lymphoblastic leukaemia (ALL) is a haematological malignancy characterized by the uncontrolled proliferation of immature lymphoid cells. Over past decades, significant progress has been made in understanding the biology of ALL, resulting in remarkable improvements in its diagnosis, treatment and monitoring. Since the advent of chemotherapy, ALL has been the platform to test for innovative approaches applicable to cancer in general. For example, the advent of omics medicine has led to a deeper understanding of the molecular and genetic features that underpin ALL. Innovations in genomic profiling techniques have identified specific genetic alterations and mutations that drive ALL, inspiring new therapies. Targeted agents, such as tyrosine kinase inhibitors and immunotherapies, have shown promising results in subgroups of patients while minimizing adverse effects. Furthermore, the development of chimeric antigen receptor T cell therapy represents a breakthrough in ALL treatment, resulting in remarkable responses and potential long-term remissions. Advances are not limited to treatment modalities alone. Measurable residual disease monitoring and ex vivo drug response profiling screening have provided earlier detection of disease relapse and identification of exceptional responders, enabling clinicians to adjust treatment strategies for individual patients. Decades of supportive and prophylactic care have improved the management of treatment-related complications, enhancing the quality of life for patients with ALL.

Development of chimeric antigen receptor (CAR)-T cells targeting A56 viral protein implanted by oncolytic virus

To address the challenge of solid tumor targeting in CAR-T therapy, we utilized the A56 antigen, which is uniquely expressed on a diverse range of cancer cells following the systemic administration of an oncolytic vaccinia virus (OVV). Immunohistochemical assays precisely confirmed exclusive localization of A56 to tumor tissues. Invitro studies demonstrated a distinct superiority of A56-dependent CAR-T cytotoxicity across multiple cancer cell lines. Building on these invitro observations, we strategically administered A56 CAR-T cells, OVV, and hydroxyurea (HU) combination in HCT-116 tumor-bearing non-obese diabetic/severe combined immunodeficiency (NOD/SCID) mice, leading to a significant reduction in tumor size and an extended time to progression. Consequently, A56-targeting combinatorial immunotherapy provides the benefit of reducing inadvertent CAR-T effects on normal cells while preserving its effectiveness against cancer cells. Furthermore, our approach of implanting A56 via OVV on tumors facilitates a wide therapeutic application of CAR-T cells across various solid tumors.

Optical sensing and control of T cell signaling pathways.

T cells regulate adaptive immune responses through complex signaling pathways mediated by T cell receptor (TCR). The functional domains of the TCR are combined with specific antibodies for the development of chimeric antigen receptor (CAR) T cell therapy. In this review, we first overview current understanding on the T cell signaling pathways as well as traditional methods that have been widely used for the T cell study. These methods, however, are still limited to investigating dynamic molecular events with spatiotemporal resolutions. Therefore, genetically encoded biosensors and optogenetic tools have been developed to study dynamic T cell signaling pathways in live cells. We review these cutting-edge technologies that revealed dynamic and complex molecular mechanisms at each stage of T cell signaling pathways. They have been primarily applied to the study of dynamic molecular events in TCR signaling, and they will further aid in understanding the mechanisms of CAR activation and function. Therefore, genetically encoded biosensors and optogenetic tools offer powerful tools for enhancing our understanding of signaling mechanisms in T cells and CAR-T cells.

CRISPR in Targeted Therapy and Adoptive T Cell Immunotherapy for Hepatocellular Carcinoma.

Despite recent therapeutic advancements, outcomes for advanced hepatocellular carcinoma (HCC) remain unsatisfactory, highlighting the need for novel treatments. The CRISPR (Clustered Regularly Interspaced Short Palindromic Repeats) gene-editing technology offers innovative treatment approaches, involving genetic manipulation of either cancer cells or adoptive T cells to combat HCC. This review comprehensively assesses the applications of CRISPR systems in HCC treatment, focusing on in vivo targeting of cancer cells and the development of chimeric antigen receptor (CAR) T cells and T cell receptor (TCR)-engineered T cells. We explore potential synergies between CRISPR-based cancer therapeutics and existing treatment options, discussing ongoing clinical trials and the role of CRISPR technology in improving HCC treatment outcomes with advanced safety measures. In summary, this review provides insights into the promising prospects and current challenges of using CRISPR technology in HCC treatment, with the ultimate goal of improving patient outcomes and revolutionizing the landscape of HCC therapeutics.

Antitumor efficacy and safety of unedited autologous CD5.CAR T cells in relapsed/refractory mature T-cell lymphomas

AbstractDespite newer targeted therapies, patients with primary refractory or relapsed (r/r) T-cell lymphoma have a poor prognosis. The development of chimeric antigen receptor (CAR) T-cell platforms to treat T-cell malignancies often requires additional gene modifications to overcome fratricide because of shared T-cell antigens on normal and malignant T cells. We developed a CD5-directed CAR that produces minimal fratricide by downmodulating CD5 protein levels in transduced T cells while retaining strong cytotoxicity against CD5+ malignant cells. In our first-in-human phase 1 study (NCT0308190), second-generation autologous CD5.CAR T cells were manufactured from patients with r/r T-cell malignancies. Here, we report safety and efficacy data from a cohort of patients with mature T-cell lymphoma (TCL). Among the 17 patients with TCL enrolled, CD5 CAR T cells were successfully manufactured for 13 out of 14 attempted lines (93%) and administered to 9 (69%) patients. The overall response rate (complete remission or partial response) was 44%, with complete responses observed in 2 patients. The most common grade 3 or higher adverse events were cytopenias. No grade 3 or higher cytokine release syndrome or neurologic events occurred. Two patients died during the immediate toxicity evaluation period due to rapidly progressive disease. These results demonstrated that CD5.CAR T cells are safe and can induce clinical responses in patients with r/r CD5-expressing TCLs without eliminating endogenous T cells or increasing infectious complications. More patients and longer follow-up are needed for validation. This trial was registered at www.clinicaltrials.gov as #NCT0308190.

CAR-modified Cellular Therapies in Chronic Lymphocytic Leukemia: Is the Uphill Road Getting Less Steep?

The clinical development of chimeric antigen receptor (CAR) T-cell therapy has been more challenging for chronic lymphocytic leukemia (CLL) compared to other settings. One of the main reasons is the CLL-associated state of immune dysfunction that specifically involves patient-derived T cells. Here, we provide an overview of the clinical results obtained with CAR T-cell therapy in CLL, describing the identified immunologic reasons for the inferior efficacy. Novel CAR T-cell formulations, such as lisocabtagene maraleucel, administered alone or in combination with the Bruton tyrosine kinase inhibitor ibrutinib, are currently under investigation. These approaches are based on the rationale that improving the quality of the T-cell source and of the CAR T-cell product may deliver a more functional therapeutic weapon. Further strategies to boost the efficacy of CAR T cells should rely not only on the production of CAR T cells with an improved cellular composition but also on additional changes. Such alterations could include (1) the coadministration of immunomodulatory agents capable of counteracting CLL-related immunological alterations, (2) the design of improved CAR constructs (such as third- and fourth-generation CARs), (3) the incorporation into the manufacturing process of immunomodulatory compounds overcoming the T-cell defects, and (4) the use of allogeneic CAR T cells or alternative CAR-modified cellular vectors. These strategies may allow to develop more effective CAR-modified cellular therapies capable of counteracting the more aggressive and still incurable forms of CLL.

Development of Chimeric Antigen Receptor (CAR) T Cells Targeting MET in Lymphomas and Solid Tumors

Currently, multiple versions of CAR T cells targeting the cell surface protein CD19 are approved by the FDA to treat refractory B-cell malignancies. However, durable remissions range from 60% in B-cell leukemias to 40% in B-cell lymphomas. Major reasons for resistance to CD19-CAR treatment relate to heterogeneous or loss of CD19 expression. In addition, CD19-CAR leads to B-cell depletion which increases the risk for infection. These limiting factors necessitate research into alternative targets for CAR therapy against B-cell lymphomas. While HGF/MET signaling has been extensively studied in solid tumors, studies have also shown important roles of HGF/MET in hematologic malignancies. Approximately 30-70% of diffuse large B-cell lymphomas (DLBCL) express MET with moderate to strong intensity; as do other lymphomas such as classic Hodgkin lymphoma, Burkitt lymphoma, primary effusion lymphoma, and multiple myeloma. We hypothesize that these MET-positive B-cell lymphomas can potentially be targeted with chimeric antigen receptor (CAR) T-cells against MET receptor. We first looked at the DepMap database and found that a significant subset of aggressive and large B-cell lymphoma cell lines express MET such as Raji, Karpas-422, OCI-LY3, and OCI-LY132. Of note, some of them, like OCI-LY3 and OCI-LY132, lack detectable CD19. Flow cytometry using anti-MET antibody confirmed MET expression in these cell lines. Further analysis of RNAseq data from 500 CD19-CAR T-naïve primary patient samples (GSE125966) revealed MET expression in 62% (294/474) of CD19-positive and 61% (15/26) of CD19-low to negative DLBCL . We then constructed a second-generation anti-MET-CAR by fusing the scFv fragment of an anti-MET monoclonal antibody with the human CD28 hinge/transmembrane/cytoplasmic domain and CD3z cytoplasmic domain. Stable MET-CAR Jurkat T cells were incubated with various target lymphoma cells for 16-24 hours, and the percentage of Jurkat T cells expressing the activation marker CD69 was determined by flow cytometry. MET-CAR Jurkat showed increased CD69 expression in MET-positive lymphoma cell lines such as Karpas-422 and OCI-LY3. Karpas-422 demonstrated dose dependent activation of MET-CAR Jurkat cells, with higher CD69 expression in response to increasing amounts of MET antigen. OCI-LY3, a lymphoma cell line negative for CD19 but positive for MET, led to only basal level of CD69 expression in CD19-CAR Jurkat but elevated CD69 level in MET-CAR Jurkat. After showing MET-CAR Jurkat T cell activation by lymphoma cell lines, we tested cytotoxicity using primary human CD3+ T-cells against A549, a lung cancer cell line with known high level of MET expression, as a positive control for MET-CAR mediated cytotoxicity. Activated primary human T cells were electroporated with MET-CAR mRNA. Twelve hours post electroporation, the reprogrammed T cells were mixed with A549 cells at a 5:1 effector: target ratio (E:T). CellCyte proliferation analysis showed reduced A549 cell proliferation in the presence of MET-CAR T cells, in comparison to mock electroporated CD3+ T cells. We further demonstrated that the same mRNA MET-CAR T-cell was able to mediate substantial cytotoxicity against DLBCL cell lines such as Karpas-422 and OCI-LY3 ( Figure 1). At varying E:T ratio, MET-CAR T cell exhibited significant cytotoxicity against Karpas-422. Also, consistent with the CD69 expression data, while CD19-CAR T cell showed only low level of cytotoxicity against the CD19-/MET+ OCI-LY3 cell line, MET-CAR T cell was able to mediate substantial tumor cell lysis. In vivo testing against a xenograft model is currently underway. In summary, the preliminary data demonstrate that MET-CAR is capable of mediating cytotoxicity against MET-positive DLBCL. Some cell lines such as OCI-LY3 are negative for CD19 but positive for MET expression, and MET-CAR is capable of mediating cell lysis while CD19-CAR is ineffective. These results suggest that some large B-cell lymphomas negative for CD19, either intrinsic or secondary to loss of CD19 as a result of resistance mechanism, may show MET expression and will likely benefit from MET-targeted immunotherapy. Figure caption: Figure 1. Cytotoxicity of MET-CAR T cell against DLBCL cell lines. (A) MET-CAR against Karpas-422 at various E:T ratio. (B) Cytotoxicity of MET-CAR against OCI-LY3 which is positive for MET but negative for CD19.E:T ratio is 10:1.

Overexpression of SMAD7 improves the function of EGFR-targeted human CAR-T cells against non-small-cell lung cancer.

Recent advancements in immunotherapy led to the development of Chimeric antigen receptor (CAR) T-cell therapy. CAR-T cell therapy in non-small cell lung cancer (NSCLC) is hindered by overexpression of transforming growth factor (TGFβ) in the cancer cells that have a negative regulatory role on T-cells activity. This study characterized CAR-T with overexpression of mothers against decapentaplegic homologue 7 (SMAD), a negative regulator of TGFβ downstream signalling. We have generated three types of CAR-T: epidermal growth factor receptor (EGFR)-CAR-T, EGFR-dominant-negative TGFbeta receptor 2 (DNR)-CAR-T, and EGFR-SMAD7-CAR-T by transducing human T-cells with the lentivirus constructs. We characterized the proliferation, expression of proinflammatory cytokines, activation profile, and lysis capacity in co-cultures with A549 lung carcinoma cells with and without TGFβ neutralizing antibodies. We also tested the therapeutic potential of EGFR-SMAD7-CAR-T in the A549 cells tumour-bearing mice model. Both EGFR-DNR-CAR-T and EGFR-SMAD7-CAR-T demonstrated a higher proliferation rate and lysis capacity to A549 than traditional EGFR-CAR-T. Neutralization of TGFβ by the antibodies resulted in increased performance of EGFR-CAR-T. In vivo, both EGFR-DNR-CAR-T and EGFR-SMAD7-CAR-T resulted in complete tumour resorption by day 20, whereas conventional CAR-T only has a partial effect. We demonstrated the high efficacy and resistance to negative TGFβ regulation of EGFR-SMAD7-CAR-T comparable with EGFR-DNR-CAR-T and without the systemic effect of TGFβ inhibition.

Real-world Experience of Approved Chimeric Antigen Receptor T-cell Therapies Compared to Clinical Trials Data.

Real-world Experience of Approved Chimeric Antigen Receptor T-cell Therapies Compared to Clinical Trials Data.

Engineering tandem CD33xCD146 CAR CIK (cytokine-induced killer) cells to target the acute myeloid leukemia niche.

In acute myeloid leukemia (AML), malignant stem cells hijack the normal bone marrow niche where they are largely protected from the current therapeutic approaches. Thus, eradicating these progenitors is the ultimate challenge in the treatment of this disease. Specifically, the development of chimeric antigen receptors (CARs) against distinct mesenchymal stromal cell subpopulations involved in the maintenance of leukemic stem cells within the malignant bone marrow microenvironment could represent a new strategy to improve CAR T-cell therapy efficacy, which is still unsuccessful in AML. As a proof of concept, we generated a novel prototype of Tandem CAR, with one specificity directed against the leukemic cell marker CD33 and the other against the mesenchymal stromal cell marker CD146, demonstrating its capability of simultaneously targeting two different cell types in a 2D co-culture system. Interestingly, we could also observe an in vitro inhibition of CAR T cell functionality mediated by stromal cells, particularly in later effector functions, such as reduction of interferon-gamma and interleukin-2 release and impaired proliferation of the CAR+ effector Cytokine-Induced Killer (CIK) cells. Taken together, these data demonstrate the feasibility of a dual targeting model against two molecules, which are expressed on two different target cells, but also highlight the immunomodulatory effect on CAR CIK cells exerted by stromal cells, confirming that the niche could be an obstacle to the efficacy of CAR T cells. This aspect should be considered in the development of novel CAR T cell approaches directed against the AML bone marrow niche.

CAR-modified immune cells as a rapidly evolving approach in the context of cancer immunotherapies

Nowadays, one of the main challenges clinicians face is malignancies. Through the progression of technology in recent years, tumor nature and tumor microenvironment (TME) can be better understood. Because of immune system involvement in tumorigenesis and immune cell dysfunction in the tumor microenvironment, clinicians encounter significant challenges in patient treatment and normal function recovery. The tumor microenvironment can stop the development of tumor antigen-specific helper and cytotoxic T cells in the tumor invasion process. Tumors stimulate the production of proinflammatory and immunosuppressive factors and cells that inhibit immune responses. Despite the more successful outcomes, the current cancer therapeutic approaches, including surgery, chemotherapy, and radiotherapy, have not been effectiveenough for tumor eradication. Hence, developing new treatment strategies such as monoclonal antibodies, adaptive cell therapies, cancer vaccines, checkpoint inhibitors, and cytokines helps improve cancer treatment. Among adoptive cell therapies, theinteraction between the immune system and malignancies and using molecular biology led tothe development of chimeric antigen receptor (CAR) T cell therapy. CAR-modified immune cells are one of the modern cancer therapeutic methods with encouraging outcomes in most hematological and solid cancers. The current study aimed to discuss the structure, formation, subtypes, and application of CAR immune cells in hematologic malignancies and solid tumors.

Systematic Review on CAR-T Cell Clinical Trials Up to 2022: Academic Center Input.

The development of Chimeric Antigen Receptor T cells therapy initiated by the United States and China is still currently led by these two countries with a high number of clinical trials, with Europe lagging in launching its first trials. In this systematic review, we wanted to establish an overview of the production of CAR-T cells in clinical trials around the world, and to understand the causes of this delay in Europe. We particularly focused on the academic centers that are at the heart of research and development of this therapy. We counted 1087 CAR-T cells clinical trials on ClinicalTrials.gov (Research registry ID: reviewregistry1542) on the date of 25 January 2023. We performed a global analysis, before analyzing the 58 European trials, 34 of which sponsored by academic centers. Collaboration between an academic and an industrial player seems to be necessary for the successful development and application for marketing authorization of a CAR-T cell, and this collaboration is still cruelly lacking in European trials, unlike in the leading countries. Europe, still far behind the two leading countries, is trying to establish measures to lighten the regulations surrounding ATMPs and to encourage, through the addition of fundings, clinical trials involving these treatments.

CARs and Drugs: Pharmacological Ways of Boosting CAR-T-Cell Therapy.

The development of chimeric antigen receptor T cells (CAR-T cells) has marked a new era in cancer immunotherapy. Based on a multitude of durable complete remissions in patients with hematological malignancies, FDA and EMA approval was issued to several CAR products targeting lymphoid leukemias and lymphomas. Nevertheless, about 50% of patients treated with these approved CAR products experience relapse or refractory disease necessitating salvage strategies. Moreover, in the vast majority of patients suffering from solid tumors, CAR-T-cell infusions could not induce durable complete remissions so far. Crucial obstacles to CAR-T-cell therapy resulting in a priori CAR-T-cell refractory disease or relapse after initially successful CAR-T-cell therapy encompass antigen shutdown and CAR-T-cell dysfunctionality. Antigen shutdown predominately rationalizes disease relapse in hematological malignancies, and CAR-T-cell dysfunctionality is characterized by insufficient CAR-T-cell proliferation and cytotoxicity frequently observed in patients with solid tumors. Thus, strategies to surmount those obstacles are being developed with high urgency. In this review, we want to highlight different approaches to combine CAR-T cells with drugs, such as small molecules and antibodies, to pharmacologically boost CAR-T-cell therapy. In particular, we discuss how certain drugs may help to counteract antigen shutdown and CAR-T-cell dysfunctionality in both hematological malignancies and solid tumors.

GMP-Based Isolation of Full-Term Human Placenta-Derived NK Cells for CAR-NK Cell Therapy in Malignant Melanoma.

Melanoma, a severe type of skin cancer, poses significant management challenges due to its resistance to available treatments. Despite this obstacle, the high immunogenicity of melanoma renders it amenable to immune therapy, and NK cells have been identified as possessing anti-tumor properties in immunotherapy. The development of chimeric antigen receptor (CAR)-modified NK cells, or CAR-NK cells, has shown potential in enhancing immunotherapeutic regimens. To achieve this, researchers have explored various sources of NK cells, including those derived from the placenta, which offers benefits compared to other sources due to their limited ex vivo expansion potential. Recent studies have indicated the capacity to expand functional NK cells from placenta-derived cells in vitro that possess anti-tumor cytolytic properties. This chapter discusses the isolation of full-term human placenta-derived NK cells using Good Manufacturing Practice-based methods for CAR-NK cell therapy in melanoma.

ANTIBODY-FREE CHIMERIC FLT3-CAR RECEPTOR FOR TARGETING THE FLT3 RECEPTOR, A MARKER OF POOR PROGNOSIS IN ACUTE MYELOID LEUKEMIA

Therapy in acute myeloid leukemia (AML) usually begins with a course of induction chemotherapy using anthracyclines and cytarabine to eliminate blast cells. Chemotherapy is a necessary step in preparing a patient for transplantation of donor hematopoietic stem cells (HSCs). However, leukemia stem cells often show their chemoresistance and initiate the AML recurrence. Specific elimination of the leukemic stem cells during the preparation of a patient for HSC transplantation may reduce the probability of recurrence. For this purpose, an active development of chimeric antigen receptors (CAR) to address various markers of AML is being in progress.

CD72 Is a Pan-Tumor Antigen Associated with Childhood Acute Leukemia

Immunotherapy has recently gained increasing attention as a new paradigm shift in cancer and has revolutionized the course of cancer treatment. The identification of ideal tumor-associated antigens (TAA) is a challenging process, since antigens have to be specific for the target cells and assure no off-target effects. We exploited a gene expression dataset of acute leukemias previously generated in our lab to identify potentially interesting TAAs. Among the most interesting hyper- and over-expressed genes with respect to normal bone marrow (BM) and with a surface protein localization, the CD72 was selected because of its specific association with childhood B-cell precursor acute lymphoblastic leukemias (BCP-ALL) and with a large proportion of pediatric acute myeloid leukemias (AML) cases. Based on the findings described below, we here propose CD72 as a novel and robust pan-acute leukemia TAA. Even though CD72 is known to be expressed by B-lineage cells, we profiled its expression in a variety of cell lines and primary samples, providing a map of its expression. CD72 was expressed by BCP-ALL cell lines (NALM-6, SEM, RS-4;11, RHC-ACV) and various AML cell lines (SHI-1, SKNO-1, MV4;11, MOML-13). Conversely, T-ALL cell lines (DND-41, TALL-1, RPMI-8402, ALL-SIL, JURKAT) and non-hematopoietic tumor cell lines (DAOY, NB-1, HT-29, A549, HeLa, MCF7) did not express the antigen. This supports the idea that CD72 is specific for hematopoietic tumors. Furthermore, we tested CD72 expression on major populations within normal BM specimens and on other healthy tissues: skin fibroblasts, mesenchymal stromal cells, skeletal myoblasts, endothelial cells. We confirmed that the antigen is expressed on B-lineage cells, whereas in other cell types we did not detect any signal. Then, to assess the interest of CD72 for the development of chimeric antigen receptor (CAR)-based immunotherapy approaches, we documented that CD72 was not expressed on CD34-positive/CD38-negative hematopoietic stem and progenitor cells (HSPCs) from both mobilized peripheral blood cells and healthy-regenerating BM samples (Figure 1). We profiled CD72 expression by flow-cytometry on 289 pathological pediatric BM samples, including: 93 BCP-ALL at diagnosis and 44 at relapse; 38 T-ALL at diagnosis and 3 at relapse; 68 AML at diagnosis and 12 at relapse; blast cells from 6 myelodysplastic syndromes; 14 non-hematopoietic solid tumors invading BM (4 rhabdomyosarcomas, 6 neuroblastomas, 4 Ewing's sarcomas); blast cells from 3 T-cell Lymphoblastic Lymphomas and 8 B-lineage Non-Hodgkin Lymphomas (NHL) with BM involvement. Data from clinical samples confirmed the in silico and in vitro prediction. CD72 was positive in 134/137 (98%) of the examined BCP-ALL cases and in all B-lineage NHL and 52/80 (65%) of AML cases. Conversely, CD72 was expressed only in 2/44 (4%) of T-ALL cases and was absent in T-cell NHL and in non-hematopoietic solid tumors. Notably, CD72 was expressed by all 12 BCP-ALL patients that were previously treated with CD19-directed immunotherapies, including four patients who lost CD19 expression. Moreover, CD72 was positive on two rare cases of CD19-negative BCP-ALL at diagnosis (Figure 2). Within our AML cohort, we did not detect any difference in CD72 expression across AML genetic subgroups. Taken together, the preliminary data here reported highlight the potential clinical usefulness of CD72 for advanced diagnostics, including the ability to identify blast cells in case of CD19 loss, and provide support for developing novel immunotherapy approach directed at CD72 that may be endowed with the unique potential of targeting both acute lymphoid and myeloid leukemia. Figure 1. CD72 expression by flow-cytometry on healthy CD34+ and CD34+/CD38- cells from healthy-regenerating bone marrow. CD72 expression was evaluated according to AIEOP-BFM Consensus guidelines, comparing the fluorescence shift and distribution pattern of the cells to the appropriate negative control. Figure 2. CD72 expression on CD19-negative BCP-ALL by flow-cytometry at first diagnosis and at time of relapse after CD19-directed immunotherapy. B-lineage was assigned with the contribution of other antigens relevant in immunophenotyping of acute leukemia. Figure 1View largeDownload PPTFigure 1View largeDownload PPT Close modal

Switchable targeting of solid tumors by BsCAR T cells

The development of chimeric antigen receptor (CAR) T cell therapy has become a critical milestone in modern oncotherapy. Despite the remarkable invitro effectiveness, the problem of safety and efficacy of CAR T cell therapy against solid tumors is challenged by the lack of tumor-specific antigens required to avoid on-target off-tumor effects. Spatially separating the cytotoxic function of CAR T cells from tumor antigen recognition provided by protein mediators allows for the precise control of CAR T cell cytotoxicity. Here, the high affinity and capability of the bacterial toxin-antitoxin barnase-barstar system were adopted to guide CAR T cells to solid tumors. The complementary modules based on (1) ankyrin repeat (DARPin)-barnase proteins and (2) barstar-based CAR (BsCAR) were designed to provide switchable targeting to tumor cells. The alteration of the DARPin-barnase switches enabled the targeting of different tumor antigens with a single BsCAR. A gradual increase in cytokine release and tunable BsCAR T cell cytotoxicity was achieved by varying DARPin-barnase loads. Switchable BsCAR T cell therapy was able to eradicate the HER2+ ductal carcinoma invivo. Guiding BsCAR T cells by DARPin-barnase switches provides a universal approach for a controlled multitargeted adoptive immunotherapy.