Thus anti-CD33 antibodies eliminate malignant myeloid cells selectively while sparing normal stem cells [70]. The first humanized CD33 molecule approved by the Food and Drug Administration (FDA) was conjugated with calicheamycin (gemtuzumab). Trials exploring single-agent use of gemtuzumab have achieved
remission only in the in the range of 15%, but gemtuzumab used together with other agents to treat Apitolisib relapsed or refractory leukaemia are promising [71–77]. The most significant toxicity reported is liver injury, occurring most commonly when gemtuzumab is used in combination with thioguanine or in the setting of allogeneic stem cell transplantation [78]. Antibody treatment has been reviewed recently [79]. AML cells are weak stimulators of T cells and often possess mechanisms that prevent induction of T cell response and induce resistance to cytotoxicity (see above). Simple vaccination
with irradiated blasts with BCG or other cytokines resulted in prolongation of remission but with no improvement in survival [1]. To increase the susceptibility of AML to immune attack, investigators have sought to improve antigenicity of the leukaemia by transfection of genes for co-stimulatory molecules such as 4-1BB ligand [80], combinations of CD80 and IL-2 [81] or by differentiating the blasts into leukaemic DC. In a study of 22 AML patients, DC were generated successfully in five and used to treat patients in remission. However, only learn more two of these patients were long-term survivors [82]. Alternatively, DC have been generated from AML patients in remission and made more antigenic by Florfenicol fusion with AML blasts [83], exposure to AML lysates or peptide antigens or transfection
with RNA [84]. A clinical trial with a monocyte-derived DC loaded with mRNA for Wilms tumour-1 (WT1) antigen is under way [85]. Although immune responses to AML can be enhanced in vitro with these approaches, clinical data are scanty and clinical responses in small diverse patient series is still very preliminary (reviewed in [86]). A recent review listed more than 14 candidate leukaemia-associated antigens expressed by AML, some of which have formed the basis for developing antigen-specific vaccines using DNA or peptides [87]. Most widely researched and developed as peptide vaccines in clinical trials are the HLA-A2 peptide epitopes of WT1 (WT1126), proteinase 3 (PR1) and hyaluronan-mediated motility receptor (RHAMM)/CD168 (receptor for hyaluronic acid mediated motility), and an HLA A24-specific epitope of WT1 [88]. Vaccines have been combined with the BCG-based adjuvant, montanide, keyhole limpet haemocyanin (KLH) or incomplete Freund’s adjuvant, with or without concurrently administered GM–CSF [89]. All these peptides induce immune responses with increases in tetramer-positive T cells producing gamma-interferon after peptide stimulation.