Harjeet Singh

Effect of Mutational Inactivation of Tyrosine Kinase Activity on BCR/ABL-Induced Abnormalities in Cell Growth and Adhesion in Human Hematopoietic Progenitors

Chronic myelogenous leukemia (CML) results from transformation of a primitive hematopoietic cell by the BCR/ABL gene. The specific BCR/ABL signaling mechanisms responsible for transformation of primitive human hematopoietic cells are not well defined. Previous studies have suggested that constitutively activated tyrosine kinase activity plays an important role for in abnormal proliferation of CML progenitors but has not clearly defined its role in abnormal adhesion and migration. We established a human progenitor model of CML by ectopic expression of BCR/ABL in normal CD34+ cells using retrovirus-mediated gene transfer. CD34+ cells expressing BCR/ABL demonstrated several features characteristic of primary CML progenitors including increased proliferation in committed and primitive progenitor culture, reduced adhesion to fibronectin, and reduced chemotaxis to stroma-derived factor-1α. We expressed a kinase-inactive BCR/ABL gene to directly investigate the role of kinase activity in abnormal progenitor function. Abnormalities in proliferation were completely reversed, whereas defects in adhesion and migration were significantly improved but not completely reversed in cells expressing a kinase-inactive BCR/ABL. Furthermore, the BCR/ABL kinase inhibitor imatinib mesylate markedly inhibited proliferation of BCR/ABL-expressing progenitors but did not fully correct the adhesion and migration defects. Expression of BCR/ABL genes with deletions of either the COOH-terminal actin binding or proline-rich domains resulted in enhanced adhesion and chemotaxis compared with wild-type BCR/ABL but did not affect progenitor proliferation. We conclude that abnormal kinase activity is essential for abnormal proliferation and survival of CML progenitors but that abnormal adhesion and migration result from both kinase-dependent and -independent mechanisms.

BCR-tyrosine 177 plays an essential role in Ras and Akt activation and in human hematopoietic progenitor transformation in chronic myelogenous leukemia.

Chronic myelogenous leukemia (CML) results from the transformation of a primitive hematopoietic cell by the BCR/ABL gene. BCR/ABL signaling has been studied in cell lines and murine models, but the transforming effects of BCR/ABL are highly dependent on cellular context, and mechanisms responsible for the transformation of primitive human hematopoietic cells remain poorly understood. Current targeted therapies fail to eliminate malignant CML progenitors, and improved understanding of crucial molecular mechanisms of progenitor transformation may facilitate the development of improved therapeutic approaches. We investigated the role of BCR/ABL tyrosine 177 (BCR/ABL-Y177) in CML progenitor transformation by comparing the effects of expression of Y177-mutated BCR/ABL, wild-type BCR/ABL, or green fluorescent protein alone on normal CD34(+) cells. We show that BCR/ABL-Y177 plays a critical role in CML progenitor expansion, proliferation, and survival. BCR/ABL expression results in enhanced Ras and Akt activity but reduced mitogen-activated protein kinase activity in human hematopoietic cells, which is reversed by BCR/ABL-Y177 mutation. Blocking BCR/ABL-Y177-mediated signaling enhances targeting of CML progenitors by imatinib mesylate. Our studies indicate that BCR/ABL-Y177 plays an essential role in Ras and Akt activation and in human hematopoietic progenitor transformation in CML.

Clinical application of Sleeping Beauty and artificial antigen presenting cells to genetically modify T cells from peripheral and umbilical cord blood.

The potency of clinical-grade T cells can be improved by combining gene therapy with immunotherapy to engineer a biologic product with the potential for superior (i) recognition of tumor-associated antigens (TAAs), (ii) persistence after infusion, (iii) potential for migration to tumor sites, and (iv) ability to recycle effector functions within the tumor microenvironment. Most approaches to genetic manipulation of T cells engineered for human application have used retrovirus and lentivirus for the stable expression of CAR1-3. This approach, although compliant with current good manufacturing practice (GMP), can be expensive as it relies on the manufacture and release of clinical-grade recombinant virus from a limited number of production facilities. The electro-transfer of nonviral plasmids is an appealing alternative to transduction since DNA species can be produced to clinical grade at approximately 1/10th the cost of recombinant GMP-grade virus. To improve the efficiency of integration we adapted Sleeping Beauty (SB) transposon and transposase for human application4-8. Our SB system uses two DNA plasmids that consist of a transposon coding for a gene of interest (e.g. 2nd generation CD19-specific CAR transgene, designated CD19RCD28) and a transposase (e.g. SB11) which inserts the transgene into TA dinucleotide repeats9-11. To generate clinically-sufficient numbers of genetically modified T cells we use K562-derived artificial antigen presenting cells (aAPC) (clone #4) modified to express a TAA (e.g. CD19) as well as the T cell costimulatory molecules CD86, CD137L, a membrane-bound version of interleukin (IL)-15 (peptide fused to modified IgG4 Fc region) and CD64 (Fc-γ receptor 1) for the loading of monoclonal antibodies (mAb)12. In this report, we demonstrate the procedures that can be undertaken in compliance with cGMP to generate CD19-specific CAR+ T cells suitable for human application. This was achieved by the synchronous electro-transfer of two DNA plasmids, a SB transposon (CD19RCD28) and a SB transposase (SB11) followed by retrieval of stable integrants by the every-7-day additions (stimulation cycle) of γ-irradiated aAPC (clone #4) in the presence of soluble recombinant human IL-2 and IL-2113. Typically 4 cycles (28 days of continuous culture) are undertaken to generate clinically-appealing numbers of T cells that stably express the CAR. This methodology to manufacturing clinical-grade CD19-specific T cells can be applied to T cells derived from peripheral blood (PB) or umbilical cord blood (UCB). Furthermore, this approach can be harnessed to generate T cells to diverse tumor types by pairing the specificity of the introduced CAR with expression of the TAA, recognized by the CAR, on the aAPC.

Redirecting T-Cell Specificity to EGFR Using mRNA to Self-limit Expression of Chimeric Antigen Receptor.

Potential for on-target, but off-tissue toxicity limits therapeutic application of genetically modified T cells constitutively expressing chimeric antigen receptors (CARs) from tumor-associated antigens expressed in normal tissue, such as epidermal growth factor receptor (EGFR). Curtailing expression of CAR through modification of T cells by in vitro-transcribed mRNA species is one strategy to mitigate such toxicity. We evaluated expression of an EGFR-specific CAR coded from introduced mRNA in human T cells numerically expanded ex vivo to clinically significant numbers through coculture with activating and propagating cells (AaPC) derived from K562 preloaded with anti-CD3 antibody. The density of AaPC could be adjusted to affect phenotype of T cells such that reduced ratio of AaPC resulted in higher proportion of CD8+ and central memory T cells that were more conducive to electrotransfer of mRNA than T cells expanded with high ratios of AaPC. RNA-modified CAR+ T cells produced less cytokine, but demonstrated similar cytolytic capacity as DNA-modified CAR+ T cells in response to EGFR-expressing glioblastoma cells. Expression of CAR by mRNA transfer was transient and accelerated by stimulation with cytokine and antigen. Loss of CAR abrogated T-cell function in response to tumor and normal cells expressing EGFR. We describe a clinically applicable method to propagate and modify T cells to transiently express EGFR-specific CAR to target EGFR-expressing tumor cells that may be used to limit on-target, off-tissue toxicity to normal tissue.

526. Innovative Dual CAR-T Cells to Target B-Cell Leukemia and Opportunistic Fungal Agents

Clinical-grade T cells genetically modified to express chimeric antigen receptors (CARs) are used to redirect their specificity to target tumor-associated antigens in vivo. CD19-specific CAR+ T cells have shown promising results in clinical settings against B-cell leukemias and lymphomas. These data provide the foundation for implementing adoptive immunotherapy for other disease states. Opportunistic invasive fungal infections (IFI) cause significant morbidity and mortality in immuno-compromised patients, including those being treated for CD19+ malignancies. Aspergillus and Candida species are the major pathogens account for causing mycosis in high risk patients. In patients with hematologic cancer, the efficacy of current antifungal therapy is limited due to fungal resistance, toxicity and importantly poor immunity of the host against fungi. Adoptive T cell therapy is a viable option to control fungal diseases. We have developed novel gene therapy approach to render genetically modified T cells able to target both fungal infections such as Aspergillus and Candida and B-cell malignancies. To target these fungal pathogens, we adapted the pattern-recognition receptor Dectin-1 to activate T cells via intracellular chimeric CD28 and CD3-ζ (designated D-CAR) upon binding to carbohydrate present in the cell wall of Aspergillus germlings. D-CAR+ T cells exhibited the specificity for β-1,3-glucan and damaged hyphae by secreting perforin and thus inhibited hyphal growth of Aspergillus. To target B-cell malignancies, we co-expressed D-CAR with a CD19-specific CAR, which is currently in use (http://www.nature.com/nrclinonc/journal/v10/n5/fig_tab/nrclinonc.2013.46_T3.html). This was achieved by synchronous electro-transfer of DNA plasmids from the Sleeping Beauty system coding for D-CAR and CD 19-specific CAR. The resultant genetically modified T cells can kill both Candida and Aspergillus as well as CD19+ malignant B cells. Thus, we report a clinically-appealing strategy to develop dual specific CAR+ T cells to control both B-cell malignancies and two of the most medically important fungi affecting in this patient population.