AML cells at presentation of disease show a number of abnormalities suggestive of immune pressure to select variants that evade immune surveillance. click here AML can express the ligand for the glucocorticoid-induced tumour necrosis factor-related protein (GITRL), which can block NK function through triggering GITR on the NK cell directly or through soluble GITRL [32]. AML blasts often weakly express co-stimulatory molecules which may favour their escape from T cell-mediated
killing, and the probability of remaining in remission is greatest in patients who express both CD80 and CD86 [4]. AML cells can shed ligands for co-stimulatory molecules such as the 4-1BB ligand, which may allow the leukaemia to block T cell attack by the binding of soluble ligand to the T cell [33]. The class II-associated invariant chain
self-peptide (CLIP) is expressed variably in AML. CLIP down-regulation can increase antigenicity of AML cells (by unblocking MHC class II loading with self-antigen) and increase CD4 responses. Patients whose AML blasts have less CLIP bound to HLA-DR molecules have prolonged remissions [34]. AML cells secrete soluble factors which may be responsible for a variety of defects observed in T cell and NK cell function [35,36]. Through their myeloid-lineage affinity, AML cells can generate leukaemic dendritic cells (DC) in vitro and in vivo which function as antigen-presenting PIK3C2G cells (APC). However, AML DC are distinctly abnormal [37]. see more They can inhibit the induction of CTL, inducing T cell anergy [38–40] and favouring the generation of regulatory T cells [41] which are increased
in AML [42]. Probably as a consequence of the leukaemia, T cells in AML show several abnormalities: recent thymic emigrants are reduced, suggesting defective thymic function [43]. In a detailed study of T cells in AML Le Dieu and colleagues found T cells with abnormal phenotypes and genotypes that formed defective immune synapses with AML blasts [44]. Finally, the AML microenvironment may favour AML survival – mesenchymal stromal cells in leukaemias can provide an immunosuppressive milieu [45] and the protective endosteal region of the marrow favours the survival of leukaemic stem cells [46]. Whether the goal of immunotherapy in AML is to boost the patient’s immune system or to confer immunity with T cells, NK cells or monoclonal antibodies, immune treatment is usually planned as a means of sustaining remission once the disease has been bulk-reduced with chemotherapy. Animal models of AML have proved useful in providing the basis for adoptive T cell and NK cell therapy [47], exploring the combination of immunotherapy with chemotherapy [48] and defining the role of regulatory T cells in preventing full efficacy of leukaemia-specific cytotoxic T cells in a mouse AML model [49].