CD19-Chimeric Antigen Receptor T Cells for Treatment of Chronic Lymphocytic Leukaemia and Acute Lymphoblastic Leukaemia.

Adoptive cell therapy (ACT) for cancer represents a promising new treatment modality. ACT based on the administration of cytotoxic T cells genetically engineered to express a chimeric antigen receptor (CAR) recognizing CD19 expressed by B cell malignancies has been shown to induce complete lasting responses in patients with chronic lymphocytic leukaemia (CLL) and acute lymphoblastic leukaemia (ALL). So far, eleven clinical trials including 99 CLL and ALL patients treated with CAR T cells targeting CD19 have been published, and the results from these trials are promising with impressive clinical responses in heavily pretreated patients. Thus, CAR T cell therapy has induced complete responses in both CLL and ALL, and surprisingly, current results indicate that patients with ALL are more prone to respond than are CLL patients. Importantly, the majority of CAR cell studies have observed severe therapy-associated toxicities, which needs attention. Herein we review current data and discuss key aspects of this powerful approach to treat and potentially cure B cell malignancies.

Characterization and comparison of 'standard' and 'young' tumour-infiltrating lymphocytes for adoptive cell therapy at a Danish translational research institution.

Adoptive cell therapy (ACT) with ex vivo expanded tumour-infiltrating lymphocytes (TILs) in combination with IL-2 is an effective treatment for metastatic melanoma. Modified protocols of cell expansion may allow the treatment of most enrolled patients and improve the efficacy of adoptively transferred cells. The aims of this study were to establish and validate the novel 'Young TIL' method at our institution and perform a head-to-head comparison of clinical-grade products generated with this protocol opposed to the conventional 'Standard TIL', which we are currently using in a pilot ACT trial for patients with melanoma. Our results confirm that 'Young TILs' display an earlier differentiation state, with higher CD27 and lower CD56 expression. In addition, CD8(+) TILs expressing CD27 had longer telomeres compared with the CD27(-). A recently described subset of NK cells, endowed with a high expression of CD56 (CD56(bright)), was detected for the first time in both types of cultures but at a higher frequency on Young TILs. Young and Standard TILs' reactivity against autologous tumours was similar, with significant expression of TNF-α/IFN-γ/CD107a by CD8(+) TILs detected in all cultures analysed. However, either slow expansion with high-dose IL-2 only or large numerical expansion with a rapid expansion protocol, which is required for current therapeutic protocols, significantly modified TIL phenotype by reducing the frequency of less differentiated, cancer-specific TILs. These studies further support the adoption of the Young TIL method in our current ACT trial and highlight the importance of continuous quality control of expansion protocols.

Induction of systemic CTL responses in melanoma patients by dendritic cell vaccination: cessation of CTL responses is associated with disease progression.

Two HLA-A2-positive patients with advanced stage IV melanoma were treated with monocyte-derived dendritic cells (DC) pulsed with either tumor peptide antigens from gp100, MART-1 and MAGE-3 alone or in combination with autologous oncolysates. Clinically, the rapid progression of disease was substantially stalled and both patients were alive for more than 15 months after initiation of therapy. Specific CTL reactivity against several tumor antigens was detectable in peripheral blood, which declined just before reactivation of disease progression. Furthermore, CD3 zeta-chain expression detected by Western lotting was decreased in PBL at this time. In summary, our data confirm that DC-based vaccinations induce peptide-specific T cells in the peripheral blood of advanced-stage melanoma patients. Although successful induction of systemic tumor antigen-specific CTL may not lead to objective clinical tumor regression, their presence are indicative of a prolonged survival.

Identification of a cytotoxic T lymphocyte response to the apoptosis inhibitor protein survivin in cancer patients.

During the last decade, a large number of human tumor-associated antigens have been identified that are recognized by CTLs in a MHC-restricted fashion. The apoptosis inhibitor protein survivin is overexpressed in most human cancers, and inhibition of its function results in increased apoptosis. Therefore, this protein may serve as a target for therapeutic CTL responses. Here, using CTL epitopes deduced from survivin, we describe specific T-cell reactivity against this antigen in peripheral blood from chronic lymphatic leukemia patients and in tumor-infiltrated lymph nodes from melanoma patients by ELISPOT analysis. CTL responses against two survivin-deduced peptide epitopes were detected in three of six melanoma patients and three of four chronic lymphatic leukemia patients. No T-cell reactivity was detected in peripheral blood lymphocytes from six healthy controls. Thus, survivin may serve as an important and widely applicable target for anticancer immunotherapeutic strategies.

T-cell receptor clonotype mapping using denaturing gradient gel electrophoresis : analysis of clonal T-cell responses in melanoma.

Melanoma cells are considered to be immunogenic because they express melanoma-associated antigens that are recognized by autologous T-cells. The role of T-lymphocytes in the host's immune response to cancer in general and to melanoma in particular has been studied intensively during the past decade, and an immense amount of data have strengthened the notion that a functional and specific antimelanoma T-cell response operates in melanoma patients (1,2). This assumption has been strongly reinforced by the demonstration of clonotypic T-cells in both primary and metastatic melanoma (3,4). Nevertheless, the prognosis of metastatic melanoma is one of the most unfavorable in medicine. The coexistence of tumor-specific immunity with a progressing tumor remains a major paradox of tumor immunology and highlights the urgency to reveal new insights into the biology of antitumor T-cells.

Quantification of melanoma cell-specific MART-1 mRNA in peripheral blood by a calibrated competitive reverse transcription-PCR.

BACKGROUND: Reverse transcription-PCR (RT-PCR) amplification of melanoma cell-specific mRNA can detect melanoma cells in the peripheral blood of patients with malignant melanoma. We present a method to quantify mRNA coding for the melanoma-specific melanoma antigen recognized by T cells #1 (MART-1) in RNA isolated from peripheral blood. METHODS: To establish a calibration curve, we measured the concentration of MART-1 mRNA in SK-MEL-28 melanoma cells grown in vitro by competitive RT-PCR. Serial dilutions of these cells were used as calibrators in the assay. The assay was conducted by adding a fixed amount of a RNA internal standard to RNA isolated from either peripheral blood or the calibrators before RT-PCR amplification with MART-1 primers in a nested PCR design. The amount of MART-1 mRNA in blood samples was calculated from the calibration curve. RESULTS: Addition of melanoma cells grown in vitro to blood from healthy donors demonstrated that the method can detect a single SK-MEL-28 melanoma cell in 1 mL of blood (1.5 x 10(-21) mol MART-1 mRNA/mL). MART-1 mRNA was observed in 4 of 12 blood samples from patients with malignant melanoma, at concentrations of 3-18 x 10(-21) mol MART-1 mRNA/mL of blood. No MART-1 mRNA was detected in blood samples from 25 controls without malignant melanoma. Intra- and interassay CVs were 15% (n = 12; mean = 44 x 10(-21) mol MART-1 mRNA/mL) and 33% (15 samples analyzed in two different analytical runs; mean = 30 x 10(-21) mol MART-1 mRNA/mL), respectively. CONCLUSIONS: Our method is the first competitive RT-PCR assay for quantification of melanoma cells in blood samples that compensates for the variation of both the reverse transcription and PCR reactions. The method allows the inclusion of control samples for continuous quality assessment.

Expression of CD94/NKG2 subtypes on tumor-infiltrating lymphocytes in primary and metastatic melanoma.

Natural killer receptors are expressed both on natural killer populations and subpopulations of T cells, mainly alpha/beta TCR+CD8+ T cells. We have characterized the expression of the C-type lectin natural killer receptor CD94/NKG2 on tumor-infiltrating lymphocytes in primary and metastatic melanoma lesions. By immunohistochemistry, 5-10% of the tumor-infiltrating lymphocytes, both in primary and metastatic lesions, expressed CD94. More than 95% of these CD94+ cells coexpressed CD8 and the percentage of CD94 expression within the CD8+ cell population ranged from 5 to 20% with a higher expression in metastatic lesions. CD94/NKG2 exists both in an inhibitory and an activating form; thus, it was necessary to determine whether the inhibitory CD94/NKG2-A/B, the activating CD94/NKG2-C/E, or both were expressed on tumor-infiltrating lymphocytes. Reverse transcription-polymerase chain reaction using specific primers for NKG2-A/B and C/E mRNA revealed the presence of NKG2-C/E in all primary and metastatic lesions. In contrast, the inhibitory NKG2-A/B was only present in 50% of primary tumors whereas 80% of tumor-infiltrating lymphocytes in metastatic lesions expressed these transcripts. In healthy humans, the mean number of inhibitory natural killer receptors is higher than that of activating receptors, but the opposite was true for tumor-infiltrating lymphocytes in melanoma. The reversal of the ratio of inhibitory to activating natural killer receptors among tumor-infiltrating lymphocytes suggests a regulated event due to either specific factors within the tumor microenvironment, preferential homing of T cell subsets, or certain stages of T cell activation.

Accumulation of identical T cells in melanoma and vitiligo-like leukoderma.

The cloning of genes encoding melanoma antigens has opened new possibilities for the treatment of patients with cancer; however, most tumor rejection antigens recognized by tumor infiltrating lymphocytes are the products of genes that are also expressed by normal melanocytes. Hence, a large set of antigenic determinants of the self have not induced self-tolerance and these peptide determinants furnish target structures for immune responses directed against tumors. The notion that the immunotherapeutic targets involved in cancer regression comprise normal differentiation antigens is stressed by the association between vitiligo-like leukoderma, due to destruction of normal melanocytes, and melanoma regression, due to destruction of cancer cells. Nevertheless, this is the first report to demonstrate by means of a new technique based on reverse transcription polymerase chain reaction and denaturing gradient gel electrophoresis, the presence of clonally expanded T cells with identical BV regions in areas of destruction of both normal and neoplastic cells.

Somatic Fas mutations in non-Hodgkin's lymphoma: association with extranodal disease and autoimmunity.

Fas (APO-1/CD95) is a cell-surface receptor involved in cell death signaling. Germline mutations in the Fas gene have been associated with autoimmune lymphoproliferative syndrome, and somatic Fas mutations have been found in multiple myeloma. We have examined the entire coding region and all splice sites of the Fas gene in 150 cases of non-Hodgkin's lymphoma. Overall, mutations were identified in 16 of the tumors (11%). Missense mutations within the death domain of the receptor were associated with retention of the wild-type allele, indicating a dominant-negative mechanism, whereas missense mutations outside the death domain were associated with allelic loss. Fas mutations were identified in 3 (60%) MALT-type lymphomas, 9 (21%) diffuse large B-cell lymphomas, 2 (6%) follicle center cell lymphomas, 1 (50%) anaplastic large cell lymphoma, and 1 unusual case of B-cell chronic lymphocytic leukemia with a marked tropism for skin. Among the 16 patients with somatic Fas mutations, 15 showed extranodal disease at presentation, and 6 relapsed in extranodal areas. Ten of 13 evaluable patients showed features suggestive of autoreactive disease. Our data indicate that somatic disruption of Fas may play a role in the pathogenesis of some lymphomas, and suggest a link between Fas mutation, cancer and autoimmunity.

Activation of preexisting T cell clones by targeted interleukin 2 therapy.

The induction of an immunological antitumor response capable of eradicating metastatic tumors is the ultimate goal of immunotherapy. We have recently shown that this can be achieved by interleukin 2 (IL-2) therapy directed to the tumor microenvironment by a recombinant antibody-IL-2 fusion protein. It is not known, however, whether this curative treatment is associated with a predominance of T cells carrying specific T cell receptor variable beta regions (TCRBV) or the presence of clonally expanded T cells. To address this question, we have used a quantitative reverse transcriptase-coupled PCR method to analyze the TCRBV region repertoire in tumor-infiltrating lymphocytes of treated and untreated animals. As controls the TCRBV region repertoire was analyzed in blood and skin from disease-free animals. The results indicate an overexpression of TCRBV5 in the tumors of all treated mice and an additional overexpression of individual regions in each tumor. Direct sequencing of these TCRBV regions did not reveal any evidence of clonal expansions. However, since clonal expansions could exist as subpopulations in highly expressed regions, not detectable by direct sequencing, a denaturing gradient gel electrophoresis assay was used for clonal analysis of TCRBV PCR products. Denaturing gradient gel electrophoresis analysis of selected TCRBV regions revealed the presence of clonotypic T cells in tumors from both treated and untreated animals. These data indicate that targeted IL-2 therapy in this model does not induce clonal T cell responses de novo, rather it acts as an activator for an already existing population of clonotypic T cells.

Analysis of T cell receptor alpha beta variability in tumor-infiltrating lymphocytes in primary and metastatic melanoma.

The T cell receptor (TCR) alpha beta variable (V) gene family usage of tumor-infiltrating lymphocytes (TIL) in different primary human malignant melanomas and corresponding metastatic lesions were characterized using a recently developed method using the reverse transcription coupled polymerase chain reaction (RT-PCR). This semiquantitative RT-PCR method could be adapted to analysis of formalin-fixed, paraffin-embedded histopathological samples of primary tumor material and demonstrated to be reproducible and to be useful for the assessment of V alpha- and V beta-gene family usage in tumor samples. The TIL in primary tumors were observed to preferentially express certain TCR V alpha- and V beta-gene families: V alpha 4, and V beta 8 were highly expressed in several of the primary tumors analyzed using this method. With respect to V alpha 22 and V beta 8, the preferential expression of these V-gene families was demonstrated to be due in situ clonal expansion of T cells by means of cloning and sequencing of the CDR3 regions (V-J or V-D-J, respectively) corresponding to the RT-PCR products from one of the primary tumors. The observed preferential usage of certain TCR V alpha and V beta-genes strongly suggest the in situ clonal expansion of specific populations of T cells in accordance with recent results from others. These clonal T cell populations probably react with certain melanoma-associated peptides presented by specific HLA molecules. The preferential usage of certain V alpha- and V beta-gene families observed in several tumors further supports the involvement of a limited number of shared melanocyte or melanoma-associated peptides. Since the HLA status of the patients is obviously important to interpret these results, some of the patients were typed for HLA-A1 and -A2, the two most well-characterized restriction elements for melanoma-associated antigens, either serologically or by a newly developed RT-PCR method which similarly could by applied directly to the tumor material. In TIL in primary melanomas, a possible correlation was suggested between HLA-A2 and the preferential usage of the TCR V-gene families V alpha 4, V alpha 5, V alpha 22 and V beta 8, whereas the V beta 3-gene family appeared to be expressed together with HLA-A1. The V-gene families which were highly expressed in the primary tumors were generally not, or only very weakly, expressed in the corresponding metastases and vice versa, possibly reflecting a substantial change in the phenotype of the metastatic melanoma target cells. Continued studies of larger patient materials will be necessary to extend and validate these conclusions and of obvious interest for the further analysis of the T cell response in melanoma.