Virna Marin

Cytokine Induced Killer cells for cell therapy of acute myeloid leukemia: improvement of their immune activity by expression of CD33-specific chimeric receptors

Background Cytokine-induced killer cells are ex vivo-expanded cells with potent antitumor activity. The infusion of cytokine-induced killer cells in patients with acute myeloid leukemia relapsing after allogeneic hematopoietic stem cell transplant is well tolerated, but limited clinical responses have been observed. To improve their effector functions against acute myeloid leukemia, we genetically modified cytokine-induced killer cells with chimeric receptors specific for the CD33 myeloid antigen. Design and Methods SFG-retroviral vectors coding for anti-CD33-ζ and anti-CD33-CD28-OX40-ζ chimeric receptors were used to transduce cytokine-induced killer cells. Transduced cells were characterized in vitro for their ability to lyse leukemic targets (4-hour 51chromium-release and 6-day co-cultures assays on human stromal mesenchymal cells), to proliferate (3H-thymidine-incorporation assay) and to secrete cytokines (flow cytomix assay) after contact with acute myeloid leukemia cells. Their activity against normal CD34+ hematopoietic progenitor cells was evaluated by analyzing the colony-forming unit capacity after co-incubation. Results Cytokine-induced killer cells were efficiently transduced with the anti-CD33 chimeric receptors, maintaining their native phenotype and functions and acquiring potent cytotoxicity (up to 80% lysis after 4-hour incubation) against different acute myeloid leukemia targets, as also confirmed in long-term killing experiments. Moreover, introduction of the anti-CD33 chimeric receptors was accompanied by prominent CD33-specific proliferative activity, with the release of high levels of immunostimulatory cytokines. The presence of CD28-OX40 in chimeric receptor endodomain was associated with a significant amelioration of the anti-leukemic activity of cytokine-induced killer cells. Importantly, even though the cytokine-induced killer cells transduced with anti-CD33 chimeric receptors showed toxicity against normal hematopoietic CD34+ progenitor cells, residual clonogenic activity was preserved. Conclusions Our results indicate that anti-CD33 chimeric receptors strongly enhance anti-leukemic cytokine-induced killer cell functions, suggesting that cytokine-induced killer cells transduced with these molecules might represent a promising optimized tool for acute myeloid leukemia immunotherapy.

In vitro and in vivo model of a novel immunotherapy approach for chronic lymphocytic leukemia by anti-CD23 chimeric antigen receptor.

Chronic lymphocytic leukemia (CLL) is characterized by an accumulation of mature CD19(+)CD5(+)CD20(dim) B lymphocytes that typically express the B-cell activation marker CD23. In the present study, we cloned and expressed in T lymphocytes a novel chimeric antigen receptor (CAR) targeting the CD23 antigen (CD23.CAR). CD23.CAR(+) T cells showed specific cytotoxic activity against CD23(+) tumor cell lines (average lysis 42%) and primary CD23(+) CLL cells (average lysis 58%). This effect was obtained without significant toxicity against normal B lymphocytes, in contrast to CARs targeting CD19 or CD20 antigens, which are also expressed physiologically by normal B lymphocytes. Moreover, CLL-derived CD23.CAR(+) T cells released inflammatory cytokines (1445-fold more TNF-β, 20-fold more TNF-α, and 4-fold more IFN-γ). IL-2 was also produced (average release 2681 pg/mL) and sustained the antigen-dependent proliferation of CD23.CAR(+) T cells. Redirected T cells were also effective in vivo in a CLL Rag2(-/-)γ(c)(-/-) xenograft mouse model. Compared with mice treated with control T cells, the infusion of CD23.CAR(+) T cells resulted in a significant delay in the growth of the MEC-1 CLL cell line. These data suggest that CD23.CAR(+) T cells represent a selective immunotherapy for the elimination of CD23(+) leukemic cells in patients with CLL.

Comparison of different suicide-gene strategies for the safety improvement of genetically manipulated T cells.

Use of adoptive T-cell therapy (ACT) is increasing; however, T-cell therapy can result in severe toxicity. Consequently, several suicide-gene strategies that allow selective destruction of the infused T cells have been described. We compared effectiveness of four such strategies in vitro in Epstein Barr virus (EBV)-cytotoxic T lymphocytes (CTLs). Herpes simplex virus thymidine kinase (HSV-TK), human inducible caspase 9 (iCasp9), mutant human thymidylate kinase (mTMPK), and human CD20 codon optimized genes were cloned in frame with 2A-truncated codon optimized CD34 (dCD34) in a retroviral vector. Codon-optimization considerably improved CD20 expression. EBV-CTLs could be efficiently transduced in all constructs, with transgene expression similar to the control vector containing dCD34 alone. Expression was maintained for prolonged cultures. Expression of the suicide genes was not associated with alterations in immunophenotype, proliferation, or function of CTLs. Activation of HSV-TK, iCasp9, and CD20 ultimately resulted in equally effective destruction of transduced T cells. However, while iCasp9 and CD20 effected immediate cell-death induction, HSV-TK-expressing T cells required 3 days of exposure to ganciclovir to reach full effect. mTMPK-transduced cells showed lower T-cell killing all time points. Our results suggest that the faster activity of iCasp9 might be advantageous in treating certain types of acutely life-threatening toxicity. Codon-optimized CD20 has potential as a suicide gene.

In vitro comparison of three different chimeric receptor-modified effector T-cell populations for leukemia cell therapy.

The identification of the optimal T-cell effector subtype is a crucial issue for adoptive cell therapy with chimeric receptor-modified T cells. The ideal T cell population must be able to home toward tumor site, exert prolonged antitumoral activity, and display minimal toxicity against normal tissues. Therefore, we characterized the in vitro antitumoral properties of three effector T-cell populations: Epstein-Barr virus-specific cytotoxic T lymphocytes (EBV-CTLs), cytokine-induced killer (CIK) cells, and &ggr;9&dgr;2 T (GDT) cells, after transduction with a chimeric receptor specific for the CD33 antigen, broadly expressed on acute myeloid leukemia cells. EBV-CTLs, CIK, and GDT cells were generated and transduced with high efficiency with a retroviral vector coding for an anti-CD33-&zgr; chimeric receptor without alterations of their native phenotype. Anti-CD33-&zgr; chimeric receptor-redirected T cells displayed analogous in vitro chemotactic activity toward CXCL12. In addition, anti-CD33-&zgr; chimeric receptor-expressing EBV-CTLs, CIK, and GDT cells showed potent and similar cytotoxicity against several CD33+ leukemic targets both in short-term 4-hours-51 Chromium-release assays (mean killing vs primary leukemic cells at effector:target ratio of 5:1; 50%, 61%, and 50% for EBV-CTLs, CIK, and GDT cells, respectively) and in long-term assays, where they were cocultured with leukemic cells for 6 days on stromal mesenchymal cells (mean survival of primary leukemic cells at effector:target ratio of 1:100; 18%, 16%, and 29% for EBV-CTLs, CIK, and GDT cells, respectively). Moreover, all effector cells acquired consistent capability to proliferate in vitro after contact with CD33+cells and to release high and comparable levels of immunostimulatory cytokines, while secreting similar low amount of immunoregulatory cytokines as the unmanipulated counterpart. Our results indicate that expression of an anti-CD33-&zgr; chimeric receptor potently and similarly increase the antileukemic functions of different effector T-cell subtypes, underlying the impossibility to identify a more potent T-cell population through in vitro analysis, and consistently with recent observations that have emerged from clinical trials with chimeric receptor-modified T cells, suggesting the need to perform such type of studies in the human setting.

T cells stimulated by CD40L positive leukemic blasts-pulsed dendritic cells meet optimal functional requirements for adoptive T-cell therapy

Adoptive T-cell immunotherapy may provide complementary therapy for childhood B-cell precursor acute lymphoblastic leukemia (BCP-ALL). In this study, we have analyzed the functional characteristics of anti-BCP-ALL effector T cells generated by co-culturing T lymphocytes and dendritic cells (DC) from allogeneic human stem cell transplantation (HSCT) donors. After 21-day co-culture with DC pulsed with CD40L+ apoptotic BCP-ALL blasts, T cells presented with both effector and central memory phenotype, and showed high and specific cytotoxic activity against leukemic cells (average lysis=77%), mostly mediated by CD8+ T cells. Noticeably, growth of CD4 T cells was maintained (45% of total cells), which actively produced Th1 cytokines (IFN-γ, TNF-α, IL-2), but not IL-4, IL-5 and IL-10. Anti-BCP-ALL T cells expressed CD49d and CXCR4 (implicated in the recruitment to bone marrow), and CD62L and CCR7 (involved in the migration to lymphoid organs). In accordance with this profile, T cells significantly migrated in response to the chemokines CXCL12 and CCL19. In conclusion, stimulation of T cells with CD40L+BCP-ALL cells-loaded DC not only elicited the generation of potent and specific anti-leukemic cytotoxic effectors, but also the differentiation of specific and functional Th-1 CD4 lymphocytes. These effectors are fully equipped to reach leukemia-infiltrated tissues and have characteristics to support and orchestrate the anti-tumor immune-response.

New advances in leukaemia immunotherapy by the use of Chimeric Artificial Antigen Receptors (CARs): state of the art and perspectives for the near future

Leukaemia immunotherapy represents a fascinating and promising field of translational research, particularly as an integrative approach of bone marrow transplantation. Adoptive immunotherapy by the use of donor-derived expanded leukaemia-specific T cells has showed some kind of clinical response, but the major advance is nowadays represented by gene manipulation of donor immune cells, so that they acquire strict specificity towards the tumour target and potent lytic activity, followed by significant proliferation, increased survival and possibly anti-tumour memory state. This is achieved by gene insertion of Chimeric T-cell Antigen Receptors (CARs), which are artificial molecules containing antibody-derived fragments (to bind the specific target), joined with potent signalling T-Cell Receptor (TCR)-derived domains that activate the manipulated cells. This review will discuss the main application of this approach particularly focusing on the paediatric setting, raising advantages and disadvantages and discussing relevant perspectives of use in the nearest future.

Exploration of the Lysis Mechanisms of Leukaemic Blasts by Chimaeric T-Cells

Adoptive transfer of specific cytotoxic T lymphocytes (CTL) and Cytokine Induced Killer Cells (CIK) following genetic engineering of T-cell receptor zeta hold promising perspective in immunotherapy. In the present work we focused on the mechanisms of anti-tumor action of effectors transduced with an anti-CD19 chimaeric receptor in the context of B-lineage acute lymphoblastic leukemia (B-ALL). Primary B-ALL blasts were efficiently killed by both z-CD19 CTL and z-CD19 CIK effectors. The use of death receptor mediated apoptosis of target cells was excluded since agonists molecules of Fas and TRAIL-receptors failed to induce cell death. Perforin/granzyme pathway was found to be the mechanism of chimaeric effectors mediated killing. Indeed, cytolytic effector molecules perforin as well as granzymes were highly expressed by CTL and CIK. CD19 specific stimulation of transduced effectors was associated with degranulation as attested by CD107 membrane expression and high IFN-γ and TNF-α release. Moreover inhibitors of the perforin-based cytotoxic pathway, Ca2+-chelating agent EGTA and Concanamycin A, almost completely abrogated B-ALL blast killing. In conclusion we show that the cytolysis response of z-CD19 chimaeric effectors is predominantly mediated via perforin/granzyme pathway and is independent of death receptors signaling in primary B-ALL.

Characterization of migratory activity and cytokine profile of helper and cytotoxic CMV-specific T-cell lines expanded by a selective peptide library

OBJECTIVE Reconstitution of cellular immunity by infusion of cytomegalovirus (CMV)-specific T lymphocytes is an attractive alternative to drugs currently used to control CMV reactivation in immunocompromised patients. For this purpose, we established a method for generating both anti-CMV CD4 and CD8 T cells following Good Manufacturing Practice indications, and we extensively characterized their immune functions. MATERIALS AND METHODS For generating CD4 and CD8 CMV-specific lymphocytes, T cells from 11 CMV-seropositive donors were stimulated three times with dendritic cells (DC) pulsed with a library of selected CMV peptides, recognized by >85% of the Caucasian population. At the end of the culture, T cells were analyzed for their specificity, cytotoxicity, chemotactic migration, proliferation, and cytokine production. RESULTS T cells were successfully expanded and enriched in CMV-specific subsets with an effector memory or an effector memory CD45 RA(+) phenotype. CMV-specific T-cell lines showed specific cytotoxicity (average lysis: 47%) against CMV peptides-pulsed DCs, and were depleted of auto- and alloreactivity. Moreover, the ability to proliferate following antigenic stimulation and the presence of functional CD4 lymphocytes producing Th1 and Th2 cytokines can ensure long-term antiviral immunity after in vivo injection. CMV-specific T lymphocytes also proved to be fully equipped to reach CMV-infected tissues, because they expressed CD49d and CCR1, CXCR3, CXCR4, necessary to recruit effector cells to inflamed sites. In accordance with this profile, they significantly migrated towards inflammatory chemokines and towards the supernatant collected from inflamed lung fibroblasts, frequently involved in CMV pathology. CONCLUSION This strategy allows expansion of effector T cells capable to exert CD8 and CD4-mediated immune functions and, thus, is suitable for clinical use.