Abstract 1810: The effects of adoptive T cell transfer on the population of regulatory T cells in the mouse colorectal cancer transplant model

Abstract Abstract 4226 Several studies have demonstrated the clinical efficacy of adoptive T cell therapy for targeting cancer. Using HLA-A2.1 transgenic mice, we have demonstrated the feasibility of T-cell receptor (TCR) gene transfer into T cells to circumvent self-tolerance to the widely expressed human p53(264–272) tumor-associated antigen and developed approaches to generate high-affinity CD8-independent TCR. A safety concern of TCR gene transfer is the pairing of endogenous and introduced TCR chains resulting in the potential generation of self-reactive T cells (off-target autoimmunity). Several strategies to favor matched TCR chains pairing and thus enhancing TCR cell surface expression, including optimization of TCR encoding nucleotide sequences, introduction of an additional inter-chain disulfide bond between the TCR α and β chain constant domains, coexpression of both TCR α and β encoding-genes using self-cleaving 2A virus peptide-based retroviral vectors have been applied. However, adoptive transfer of mouse T cells transduced with modified p53-specific TCRs into p53-deficient humanized (A2Kb) mice was inducing lethal autoimmunity due to the formation of self-reactive TCRs infiltrating vital organs, such as spleen, liver and bone marrow. Therefore, an optimized single chain (sc) p53-specific TCR was engineered to avoid the formation of mismatched TCR heterodimers. The safety and therapeutic efficiency of this approach were evaluated in humanized mouse models of adoptive T cell transfer and successfully demonstrated that optimized p53-specific scTCR-redirected T cells (i) do not induce OFF-target autoimmunity and (ii) mediate antitumor reactivity. Importantly, because the expression of p53 antigen on normal tissues raises the concern of potential on-target toxicity, we performed adoptive T cell transfer experiments in humanized mice expressing the Human p53 protein (Hupki mice) and did not observe any sign of TCR gene transfer-mediated GvHD in this model. In conclusion, these mouse studies suggest that the optimized p53(264–272)-specific scTCR could represent a safe and efficient approach for TCR-based gene therapy. Disclosures: No relevant conflicts of interest to declare.

Download Full-text

The Promise of Personalized TCR-Based Cellular Immunotherapy for Cancer Patients

Frontiers in Immunology ◽

10.3389/fimmu.2021.701636 ◽

2021 ◽

Vol 12 ◽

Author(s):

Marion Arnaud ◽

Sara Bobisse ◽

Johanna Chiffelle ◽

Alexandre Harari

Keyword(s):

T Cells ◽

T Cell ◽

Gene Transfer ◽

Genetic Engineering ◽

T Cell Receptors ◽

Rapid Identification ◽

Cellular Immunotherapy ◽

Cell Transfer ◽

Adoptive T Cell Transfer ◽

T Cell Transfer

Mutation-derived neoantigens are now established as attractive targets for cancer immunotherapy. The field of adoptive T cell transfer (ACT) therapy was significantly reshaped by tumor neoantigens and is now moving towards the genetic engineering of T cells with neoantigen-specific T cell receptors (TCRs). Yet, the identification of neoantigen-reactive TCRs remains challenging and the process needs to be adapted to clinical timelines. In addition, the state of recipient T cells for TCR transduction is critical and can affect TCR-ACT efficacy. Here we provide an overview of the main strategies for TCR-engineering, describe the selection and expansion of optimal carrier cells for TCR-ACT and discuss the next-generation methods for rapid identification of relevant TCR candidates for gene transfer therapy.

Download Full-text

Adoptive Transfer of Hexon-Specific T-Cells as a Treatment of Adenovirus Reactivation Following Allogeneic Stem Cell Transplantation.

Blood ◽

10.1182/blood.v114.22.796.796 ◽

2009 ◽

Vol 114 (22) ◽

pp. 796-796

Author(s):

Kathrin Opherk ◽

Friedhelm R Schuster ◽

Wolfgang Andreas Bethge ◽

Peter Bader ◽

Johann Greil ◽

...

Keyword(s):

T Cells ◽

T Cell ◽

Adoptive Immunotherapy ◽

Therapeutic Option ◽

T Cell Responses ◽

Cell Transfer ◽

Adoptive T Cell Transfer ◽

Cell Responses ◽

T Cell Transfer

Abstract Abstract 796 In pediatric patients human adenovirus (HAdV) was identified as a common viral pathogen responsible for significant morbidity and mortality post allo SCT. Antiviral chemotherapy is often insufficient. Given that T-cell immunity is crucial for protection against adenoviral infection/reactivation, cellular immunotherapy is a promising therapeutic option. The capsid protein Hexon has been shown to contain immunodominant T-cell epitopes, with T-cell responses in the majority of the healthy population. Therefore a prospective phase I/II clinical study was performed analysing safety and feasibility of adoptive Hexon-specific T-cell transfer in patients after allogeneic SCT and HAdV infection refractory to Cidofovir treatment. Hexon-specific T-cells were isolated from the SCT-donor by using the IFNγ secretion system and small T-cell populations were immediately infused, without in vitro expansion steps. Fourty pediatric and adult patients with a mean age of 15 years were treated according to the study protocol after haploidentical, matched unrelated and matched sibling donor SCT between day 11 and 327 post SCT. The T-cell dose varied from 300-25000 T-cells/kg. No acute toxicitiy was observed. In two patients GvHD °I-°II of the skin occured within two weeks after administration of specific T-cells, one patient also developed GvHD of the gut. In vivo T-cell responses were absent in all patients before adoptive T-cell transfer and detectable in 70% of evaluable patients within the first weeks after adoptive transfer, associated with a clinical and/or virological response to the adoptive T-cell transfer. However, in patients with adenoviral disease response rate was lower and 6 of 14 evaluable patients succumbed with the infection within few days, in spite of adoptive immunotherapy. This lead to the assumption, that adoptive treatment in patients with severe infection related morbidity was to late during the course of infection. In conclusion we could show that adoptive immunotherapy is safe, feasible and a promising therapeutic option in patients with HAdV infection. Infusion of small IFNγ producing Hexon-specific T-cells populations resulted in an in vivo expansion of specific T-cells in the majority of cases. Emergence of in vivo T-cell responses was closely associated with a clearance or reduction of the viral load. Disclosures: No relevant conflicts of interest to declare.

Download Full-text

Phase I/II Clinical Trial of CpG-Activated Whole Cell Vaccine in Mantle Cell Lymphoma (MCL): Results in Safety and Efficacy from Planned Interim Analysis

Blood ◽

10.1182/blood.v126.23.1536.1536 ◽

2015 ◽

Vol 126 (23) ◽

pp. 1536-1536 ◽

Cited By ~ 1

Author(s):

Michael P. Chu ◽

Joshua Brody ◽

Holbrook E Kohrt ◽

Matthew J. Frank ◽

Michael Khodadoust ◽

...

Keyword(s):

Clinical Trial ◽

T Cells ◽

T Cell ◽

Interim Analysis ◽

Research Funding ◽

Patient Specific ◽

Cell Transfer ◽

Adoptive T Cell Transfer ◽

Safety And Efficacy ◽

T Cell Transfer

Abstract Introduction MCL has a poor prognosis. In eligible patients, intensifying frontline, CHOP-like regimens (e.g., cytarabine) as well as high-dose chemotherapy and autologous stem cell transplant (HDT/ASCT) consolidation in first remission have improved progression free survival (PFS) but less so, overall (OS). Preclinical animal models show benefits of adding tumor-specific T-cells to ASCT. CpG (PF-3512676) is a toll-like receptor 9 (TLR9) agonist and an effective vaccine adjuvant that induces costimulatory molecule expression on both antigen-presenting and MCL cells. This phase I/II clinical trial (NCT00490529) adds autologous T-cell transfer, harvested from patients after vaccination with CpG-activated autologous MCL cells - a maneuver termed immunotransplant. This is a planned interim analysis for safety and efficacy triggered by the first 20 patients reaching 1 year post ASCT. Methods Prior to therapy, subjects' tumor cells are collected by biopsy or apheresis and patient-specific vaccine is created by incubating fresh tumor cells with CpG (3 mcg/mL PF-3512676, 72-hr culture), then irradiated and cryopreserved. Patients receive induction chemoimmunotherapy of physician's choice. Patients achieving at least partial response (PR) then receive 3 subcutaneous autologous tumor vaccinations (1 x 108 cells/dose) mixed with CpG (18 mg) every 4-7 days. Primed T-cells (≥ 1 x 1010 CD3 cells) were collected by apheresis 2-4 weeks following vaccine 3 and a rituximab (375 mg/m2) B-cell purge. After standard HDT/ASCT (conditioning = BCNU, cyclophosphamide, etoposide), primed T-cells and a 4th vaccination are given on day+1. A 5th CpG-MCL vaccination followed 3 months post ASCT. The primary endpoint of this study is freedom from minimal residual disease (MRD) at 1 year post ASCT, measured by presence of patient-specific, malignant B-cell VDJ sequence in peripheral blood (ClonoSeq™, analyzed at a sensitivity of ≥ 1 clone/10,000 leukocytes) -an endpoint previously shown to be highly prognostic. Secondary endpoints include PFS, OS, and immune response to vaccine. 59, transplant-eligible, MCL patients are targeted for accrual in this 2-stage design. Results In this interim analysis of 24 patients accrued, 20 have surpassed 1 year post ASCT. All patients had Stage IV disease. Median values included (range): follow-up 43.5 months (11.5-60.1), age 60 years (47-70), and MIPI score 5.9 (5.1-7.8). Vaccine was made from biopsy alone (n=12), apheresis alone (n=9), or both (n=1). Frontline therapy included R-CHOP (n=7), R-hyperCVAD (n=14), alternating R-CHOP/R-DHAP (n=2), and R-EPOCH (n=1). 19 patients achieved complete response while another 3 had PR. All responding patients were vaccinated, able to yield sufficient T-cells for adoptive transfer, and proceeded through standard HDT/ASCT. At 1-year post ASCT, freedom from MRD was 90.5% (n=21). 2 patients did not reach 1-year post ASCT. One died from an ASCT complication (metapneumovirus) while the other relapsed 6 months following ASCT (included in MRD analysis). The most common toxicity due to CpG-MCL vaccine was erythematous rash at injection site (90.9%, n=20, each grade 1). No serious adverse events were seen related to vaccines or adoptive T-cell transfer. All patients had successful hematopoietic recovery, but two were delayed and received backup stem cell infusions with eventual recovery. Though median PFS and OS have not been reached, 3-year PFS and OS at interim analysis are 54.5% and 63.6%, respectively (intention to treat). In this data set, higher expression of co-stimulatory molecules (such as CD40, CD80, and CD86) on a subject's MCL in response to CpG was associated with freedom from MRD (p =0.02). Post-ASCT, higher peripheral T-cell granzyme and perforin response to ex vivo re-challenge with autologous MCL cells was also associated with freedom from MRD (p =0.01). Conclusions The addition of CpG-activated, whole MCL vaccination and autologous, adoptive T-cell transfer to standard therapy appears both feasible and safe. At interim analysis, the 1-year freedom from MRD surpasses rates previously reported in other studies and warrants further investigation. To date, 46 patients have either completed and/or are continuing to undergo study treatment and the study remains open to accrual for patients newly diagnosed with MCL. Disclosures Miklos: Pharmacyclics: Research Funding. Rezvani:Pharmacyclics: Research Funding. Faham:Adaptive Biotechnologies: Employment. Levy:Immune Design: Research Funding; Dynavax: Research Funding.

Download Full-text