Abstract
Relapse has become the most frequent cause of treatment failure after HSCT (Horowitz et al.
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1 Introduction
Relapse has become the most frequent cause of treatment failure after HSCT (Horowitz et al. 2018). Because outcome after relapse remains poor, major effect is focused on prevention of relapse. Beside adoptive cell-based options, such as DLI, the availability of novel effective pharmacological compounds has opened new avenues in clinical research to use those drugs early after HSCT in order to prevent relapse (Kroger et al. 2014). The optimal pharmacological compound should have a safe toxicity profile, an antitumor effect to the underlying disease, and an immune profile which can be used to booster the graft-versus-leukemia (GVL) effect and to reduce the risk of GVHD.
2 Tyrosine Kinase Inhibitors (TKI) Targeting BCR/ABL
Beside a direct antitumor effect, TKIs are considered to induce also immunomodulating effects by inducing effect on T-cell cytolytic function, reducing T-cell PD-1 expression, and reducing myeloid-derived suppressor cells. TKIs targeting BCR/ABL such as imatinib induce more than 60% molecular remission in CML patients who relapsed after allograft. Smaller studies have investigated second-generation TKI successful as maintenance therapy after allo-HSCT for CML (Olavarria et al. 2007).
TKIs as maintenance therapy for Ph + ALL led to nonconclusive results. The CIBMTR did not find a difference in Ph + ALL patients who received post transplant TKIs regarding relapse at 3 years, while in an EBMT study, Ph + ALL patients who received TKIs post transplant had lower relapse incidence and an improved LFS. In a small randomized study comparing TKI prophylactically or preemptive in Ph + ALL, no difference in survival was observed (Pfeifer et al. 2013). In a position statement, EBMT recommended in MRD-negative patients after allo-HSCT either prophylactic or preemptive treatment (Giebel et al. 2016).
3 TKI Targeting FLT3-ITD
TKIs in the setting of FLT3-ITD-positive AML are of clinical relevance because a higher risk of relapse has been described for FLT3-ITD-positive patients who received allo-HSCT CR1 (30% vs. 16%). Animal experiences had shown that sorafenib stimulated immunogenicity by induction of IL-15 which enhanced T-cell activation and GVL effect (Mathew et al. 2018).
Midostaurin which is approved in the treatment of FLT3-positive AML has been tested in a phase II study as maintenance therapy in FLT-3-ITD-positive patients with a low relapse rate at 12 months of only 9.2%. A retrospective study which compared sorafenib with a historical control showed improved outcome if TKI was used prophylactically (Brunner et al. 2016). Currently under investigation are randomized trials with quizartinib, gliteritinib, and crenolanib.
For relapsed FLT3-ITD-positive patients, sorafenib can induce long-lasting CR, and retrospective data show better outcome of sorafenib plus DLI in comparison to DLI alone (Mathew et al. 2018; Metzelder et al. 2012).
4 Checkpoint Inhibitors
Checkpoint inhibitors blocking CTLA-4 and PD-1 are now widely used in solid tumors and also in hematological malignancies such as Hodgkin’s disease (Ansell et al. 2015). Because of reversal of T-cell exhaustion by checkpoint inhibitors which may enhance a graft-versus-malignancy effect, this compound has also raised interest to be investigated after HSCT. After auto-HSCT PD-1 antibody pidilizumab as maintenance therapy in DLBCL was well tolerated in a phase II study and nivolumab has shown high response rate in patients with HL who relapsed after auto-HSCT (Younes et al. 2016).
There is concern about a higher risk of GVHD after checkpoint inhibition post-allograft, but ipilimumab did not induce high incidence of GVHD in phase I and phase II trials although the efficacy was limited with an overall response rate of less than 30% (Davids et al. 2016). PD-1 blockade investigated in a European trial was reported for 20 patients with HL who relapsed after allograft. The remission rate was high with 95% and 30% developed GVHD which was fatal in one patient. In a similar trial including 31 lymphoma patients who relapsed after allograft, the response rate was 77%, but 54% developed acute GVHD and eight patients died from GVHD-related complications (Haverkos et al. 2017).
5 Hypomethylating Agents
Methylation has a crucial role in epigenetic regulation of gene expression and malignant cells using hypermethylation to switch off a variety of genes which are responsible for growth inhibition and apoptosis. DNA methyltransferase inhibitors such as azacytidine or decitabine are active in MDS and AML, and according to their toxicity profile, they can be used after allo-HSCT. Beside their effect on gene modification for differentiation and cell growth, hypomethylating agents (HMA) lead also to an upregulation of HLA and tumor-associated antigen which may be targeted by donor T cells (Hambach et al. 2009; Goodyear et al. 2010). Furthermore, CD4 and CD8 T cells were strongly suppressed by HMA while an increase of regulatory T cells has been described.
Azacytidine and decitabine either as single agent or in combination with DLI have been reported and up to 28% CR could be achieved including long-lasting remission (Schroeder et al. 2013). In a large EBMT study, an ORR of 25% with 15% CR and a 2-year OS of 12% has been reported for azacytidine in after allo-HSCT-relapsed AML/MDS patients. Overall the incidence of acute GVHD was low and the addition of DLI did not improve response or OS. Smaller studies also reported efficiency of azacytidine to convert decreasing donor cell chimerism into full donor cell chimerism (Platzbecker et al. 2012).
Treating patients with HMA prophylactically to prevent relapse has been tested (de Lima et al. 2010) and is currently investigated in prospective randomized clinical trials.
6 Immunomodulating Drugs (IMiDs)
After auto-HSCT thalidomide has been tested alone and with glucocorticoids as maintenance to prevent relapse/progression. Most of these phase III trials demonstrated an improved PFS or EFS with variable improvement in OS, but due to toxicity, the drug has not become a standard care of treatment (Barlogie et al. 2008; Spencer et al. 2009). Lenalidomide is approved as maintenance therapy since a significant improvement in PFS has been shown in two randomized trials and improved OS on one randomized trial (McCarthy et al. 2012; Attal et al. 2012). A meta-analysis with data from three large studies (CALGB 100104, IFM-05-02, and GIMEMA RV-MM-PI-209) demonstrated an OS and a PFS benefit for lenalidomide maintenance. However, an increased risk of secondary primary malignancies was observed after lenalidomide maintenance therapy.
After allo-HSCT a stimulation of T cells has been shown for thalidomide, but second-generation IMiDs such as lenalidomide and pomalidomide are even more potent stimulation of T-cell-mediated immunity. IMiDs also stimulate the innate immune system including γ/δ-T cells and NK T cells. While after thalidomide even if combined with DLI, no increased GVHD risk was observed (Kroger et al. 2004). Because of the stronger T-cell stimulation, lenalidomide given early post-allo-HSCT can cause severe GVHD (Sockel et al. 2012), but starting with a low dose of only 5 mg and given the drug after discontinuation of IS reduces the risk of GVHD markedly (Wolschke et al. 2013).
Overall, IMiDs are potent agents for preventing relapse after auto-HSCT, but their use post-allo-HSCT remains to be defined primarily due to the increased risk of GvHD.
7 Proteasome Inhibitors
Proteasome inhibitors are mainly used as induction therapy prior auto-HSCT. Some studies investigated proteasome inhibitors as maintenance therapy after auto-HSCT to reduce the risk of relapse. In a prospective study, bortezomib as maintenance therapy was superior to thalidomide particularly in patients with renal insufficiency and high-risk cytogenetics t(4;14) or del(17q) (Goldschmidt et al. 2018).
Bortezomib after allo-HSCT was tested so far only in smaller studies with acceptable rates of GVHD (Caballero-Velazquez et al. 2013), and novel proteasome inhibitors such as ixazomib are currently tested as maintenance therapy after allografting in MM.
8 Monoclonal Antibodies
Most studies of maintenance therapy with MoAb have been conducted after auto-HSCT. While maintenance therapy after autograft with anti-CD20 antibody rituximab failed to demonstrate an advantage for DLBCL with respect to RFS and OS (Gisselbrecht et al. 2012) for follicular lymphoma, an improved PFS but not an improvement in OS has been reported in a randomized study (Pettengell et al. 2013). An improved PFS and OS with rituximab as maintenance therapy has recently been shown for mantle cell lymphoma after auto-HSCT (Le Gouill et al. 2017).
After allo-HSCT for DLCBL, rituximab maintenance therapy did not improve overall survival (Glass et al. 2014). Anti-CD30 antibody drugs conjugate brentuximab vedotin as maintenance therapy after auto-HSCT for HL did improve PFS but not OS (Moskowitz et al. 2015).
Anti-CD22-conjugated antibody inotuzumab ozogamicin has been approved for relapsed ALL and has shown also activity in patients with ALL who relapsed after HSCT (Kantarjian et al. 2016), but the risk of SOS/VOD is about 11% and up to 22% for those who underwent allo-HSCT after inotuzumab ozogamicin.
Bispecific antibodies such as CD19-directed CD3 T-cell-engaged blinatumomab are active in relapsed and refractory ALL and also in MRD positive ALL and has been investigated successfully in combination with DLI after relapse post-allo-HSCT (Ueda et al. 2016).
9 Histone Deacetylase Inhibition (HDACI)
Histone deacetylation is a crucial mechanism of epigenetic modulation and HDACI promotes gene expression by unwinding of histone-bound DNA. Since HDACI reduces inflammatory cytokines and increases T-regulatory cells, the drug was also used for GVHD prevention in a phase I/II study (Choi et al. 2014). Panobinostat was tested in two trials as maintenance therapy after allo-HSCT in AML/MDS with or without (Bug et al. 2017) DLI resulting in an encouraging 1-year RFS of 66% in combination with DLI and 2-year RFS of 74% if used as single agent. This agent will now be tested as maintenance therapy in a prospective randomized phase III trial.
Incorporating novel agents into a transplant concept is an exciting new field of investigation, because in many cases, auto-HSCT alone does not lead to cure. To reduce the risk of relapse, well-designed clinical trial with novel agents is necessary.
Key Points
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Outcome after relapse to allogeneic stem cells remains poor and major efforts should focus on prevention of relapse.
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Beside adoptive cell-based options such as DLI, the availability of novel effective pharmacological compounds has opened new avenues in clinical research, mainly:
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Tyrosine kinase inhibitors (TKI) targeting BCR/ABL.
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TKI targeting FLT3-ITD (sorafenib, midostaurin, quizartinib, gliteritinib, crenolanib).
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Checkpoint inhibitors (pidilizumab, nivolumab, ipilimumab).
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Hypomethylating agents (azacytidine, decitabine).
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Immunomodulating drugs (thalidomide, lenalidomide, pomalidomide).
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Proteasome inhibitors (bortezomib, ixazomib).
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Antibodies (rituximab, brentuximab vedotin, inotuzumab ozogamicin, blinatumomab).
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Histone deacetylase inhibition (panobinostat).
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The optimal pharmacological compound should have a safe toxicity profile, an antitumor effect to the underlying disease, and an immune profile which can be used to booster the GVL effect and to reduce the risk of GVHD.
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Kröger, N. (2019). Prevention and Treatment of Relapse by Drugs. In: Carreras, E., Dufour, C., Mohty, M., Kröger, N. (eds) The EBMT Handbook. Springer, Cham. https://doi.org/10.1007/978-3-030-02278-5_58
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