Malignant transformation of cells depends on accumulation of DNA damage. Over the past years we have learned that the T cell–based immune system frequently responds to the neoantigens that arise as a consequence of this DNA damage. Furthermore, recognition of neoantigens appears an important driver of the clinical activity of both T cell checkpoint blockade and adoptive T cell therapy as cancer immunotherapies. Here we review the evidence for the relevance of cancer neoantigens in tumor control and the biological properties of these antigens. We discuss recent technological advances utilized to identify neoantigens, and the T cells that recognize them, in individual patients. Finally, we discuss strategies that can be employed to exploit cancer neoantigens in clinical interventions.
Human cytomegalovirus (CMV) infections and relapse of disease remain major problems after allogeneic stem cell transplantation (allo-SCT), in particular in combination with CMV-negative donors or cordblood transplantations. Recent data suggest a paradoxical association between CMV reactivation after allo-SCT and reduced leukemic relapse. Given the potential of Vδ2-negative γδT cells to recognize CMV-infected cells and tumor cells, the molecular biology of distinct γδT-cell subsets expanding during CMV reactivation after allo-SCT was investigated. Vδ2(neg) γδT-cell expansions after CMV reactivation were observed not only with conventional but also cordblood donors. Expanded γδT cells were capable of recognizing both CMV-infected cells and primary leukemic blasts. CMV and leukemia reactivity were restricted to the same clonal population, whereas other Vδ2(neg) T cells interact with dendritic cells (DCs). Cloned Vδ1 T-cell receptors (TCRs) mediated leukemia reactivity and DC interactions, but surprisingly not CMV reactivity. Interestingly, CD8αα expression appeared to be a signature of γδT cells after CMV exposure. However, functionally, CD8αα was primarily important in combination with selected leukemia-reactive Vδ1 TCRs, demonstrating for the first time a co-stimulatory role of CD8αα for distinct γδTCRs. Based on these observations, we advocate the exploration of adoptive transfer of unmodified Vδ2(neg) γδT cells after allo-SCT to tackle CMV reactivation and residual leukemic blasts, as well as application of leukemia-reactive Vδ1 TCR-engineered T cells as alternative therapeutic tools.
Summary Human Vγ9Vδ2 T cells respond to tumour cells by sensing elevated levels of phosphorylated intermediates of the dysregulated mevalonate pathway, which is translated into activating signals by the ubiquitously expressed butyrophilin A1 (BTN3A1) through yet unknown mechanisms. Here, we developed an unbiased, genome-wide screening method that identified RhoB as a critical mediator of Vγ9Vδ2 TCR activation in tumour cells. Our results show that Vγ9Vδ2 TCR activation is modulated by the GTPase activity of RhoB and its redistribution to BTN3A1. This is associated with cytoskeletal changes that directly stabilize BTN3A1 in the membrane, and the subsequent dissociation of RhoB from BTN3A1. Furthermore, phosphoantigen accumulation induces a conformational change in BTN3A1, rendering its extracellular domains recognizable by Vγ9Vδ2TCRs. These complementary events provide further evidence for inside-out signaling as an essential step in the recognition of tumor cells by a Vγ9Vδ2TCR.
Immunotherapy with innate immune cells has recently evoked broad interest as a novel treatment option for cancer patients. ␥9␦2T cells in particular are emerging as an innate cell population with high frequency and strong antitumor reactivity, which makes them and their receptors promising candidates for immune interventions. However, clinical trials have so far reported only limited tumor control by adoptively transferred ␥9␦2T cells. As a potential explanation for this lack of efficacy, we found unexpectedly high variability in tumor recognition within the physiologic human ␥9␦2T-cell repertoire, which is substantially regulated by the CDR3 domains of individual ␥9␦2TCRs. In the present study, we demonstrate that the reported molecular requirements of CDR3 domains to interact with target cells shape the physiologic ␥9␦2T-cell repertoire and, most likely, limit the protective and thera- IntroductionImmunotherapy with innate immune cells has become widely used because this approach obviates the need to match a cellular product to a defined HLA haplotype, allowing adoptive immunotherapies to be used in virtually any cancer patient without extensive in vitro selection or manipulation of the cellular product. 1-4 ␥9␦2T cells are promising as an innate cell population for this purpose because they are usually observed at high frequencies in the human peripheral blood and provide a strong antitumor reactivity against various solid and hematologic cancers. 5 However, within ␥9␦2T-cell populations, individual clones display great diversity in the repertoire because of the activating or inhibitory receptors expressed. 6 Selecting innate cell products for certain cell types, such as those with a low level of inhibitory receptors, therefore seems plausible, especially considering the limited efficacy of adoptively transferred innate immune cells in clinical trials. 7,8 An alternative proposal is to engineer cells to express defined activating innate receptors that mediate strong antitumor reactivity, such as a defined ␥9␦2TCR, 9 which could pave the way for readily available and more effective cellular products. However, the molecular details of how a ␥9␦2TCR interacts with its target are not fully understood, making it challenging to select defined ␥9␦2T cells or to engineer T cells with defined ␥9␦2TCRs.In "classic" immunoreceptors such as ␣TCRs or Igs, the complementary determining regions (CDRs) determine affinity and specificity for a specific (peptide) epitope. V(D)J recombination allows the creation of a highly variable CDR repertoire ensuring recognition of an immense collection of antigens. ␥9␦2T cells also possess a rearranged TCR that mediates recognition. The phosphoantigen isopentenyl pyrophosphate (IPP) has been suggested to be a key player in ␥9␦2TCR-mediated activation, 5,10,11 but no direct interaction between a ␥9␦2TCR and IPP or any other phosphoantigen has ever been demonstrated. It was previously suggested that positively charged residues within the ␥9␦2TCR are crucial for the response to negatively...
Allogeneic stem cell transplantation (allo-SCT) has so far been the most effective immunotherapy for hematological malignancies. However, it is becoming increasingly clear that the immunotherapeutic concepts underlying allo-SCT as well as the traditional dissection of the immune system into innate and adaptive arms need substantial refinement. More and more cell types migrate into the interface between innate and adaptive immunity, creating new terms such as innate-like lymphocytes. These innate-like cells, which include natural killer (NK) cells and γδT cells, could provide unique advantages to therapeutic interventions aimed at treating hematological malignancies, including protection against tumor relapse and viral infections without causing harmful graft-versus-host disease (GVHD). Recent molecular and conceptual insights into these subpopulations have opened new avenues to exploit their exciting features for the development of new compounds and to revisit current therapeutic standards in the treatment of hematological cancers. This review therefore aims to discuss the rapid progress in the understanding of molecular mechanisms by which NK cells and γδT cells recognize malignancies and viral infections, and the value of this increasing knowledge to complement the battle against life-threatening complications of current strategies to treat cancer.
Key Points We describe a novel allo-tumor–reactive and CD8α-dependent Vγ5Vδ1TCR. The molecular interface with proximity to the peptide-binding groove of HLA-A*24:02 is an essential determinant of recognition.
Pluripotent stem cells are basic cells with an indefinite self-renewal capacity and the potential to generate all the cell types of the three germinal layers. So far, the major source for pluripotent stem cells is the inner cell mass of the blastocysts: embryonic stem (ES) cells. Potential clinical application of ES cells is faced with many practical and ethical concerns. So, a major breakthrough was achieved in 2006, when it was shown that pluripotent stem cells could be obtained by transducing mouse embryonic and adult fibroblasts with a limited set of defined transcription factors. These reprogrammed cells, named induced pluripotent stem (iPS) cells, resembled ES cells in many of their characteristics. Since this initial study, iPS cell research has taken an incredible flight, and to date iPS cells have been generated from cells from several species using different sets of reprogramming factors. Given the potential to generate patient-specific cell populations without the need for human embryonic cells, iPS cell technology has been received with great excitement by research and medical communities. However, many questions regarding the actual molecular process of induced reprogramming remain unanswered and need to be addressed before iPS cells can go to the clinic. In this review, we start by summarizing recent advances in iPS cell research and inventory the hurdles that still need to be taken before safe clinical application. Our major aim, however, is to review the available data on the molecular processes underlying pluripotency reprogramming and present a two-stage switch model.
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