Experimental evidence and preliminary clinical studies have demonstrated that human mesenchymal stem cells (MSCs) display important immune modulatory function of potential relevant interest in the setting of allogeneic hematopoietic stem cell (HSC) transplantation. Effectiveness of MSCs in controlling severe GVHD seems to be related to the immune-regulatory role they play in suppressing alloantigen-specific T-cell activation. Aim of the present study was to extend the analysis of the mechanisms responsible for the immune regulatory effect of interaction between MSCs and alloantigen-specific immune response elicited in vitro in primary and in secondary mixed lymphocyte culture (MLC). At difference with most previously reported studies, we decided to employ non-irradiated MSCs, reasoning that irradiation might impair, beside the proliferative capacity, also the differentiation capability of MSCs and, consequently, alter their interaction pattern with lymphocyte subsets. MSC were added to primary MLC at different doses (MLC-responder-PBMC:MSC ratios = 1:1 and 10:1). Dendritic cell (DC) differentiation, lymphocyte proliferation, alloantigen-specific cytotoxic activity and differentiation of CD4+ T-cell subsets expressing CD25 and/or CTLA4 antigens were assessed in primary and secondary MLC, comparing the effect observed using third-party MSCs with that obtained employing autologous to the MLC-responder (autologous) MSCs. Results demonstrated that human MSCs: (1) strongly inhibit alloantigen-induced DC1 differentiation; (2) down-regulate, in a dose-dependent manner, alloantigen-induced lymphocyte expansion, especially that of CD8+ T cells and of NK lymphocytes; (3) favor the differentiation of CD4+ T cells co-expressing CD25 and/or CTLA4, a phenotype associated with regulatory/suppressive function of immune response; (4) cause a dose-dependent reduction of alloantigen-specific cytotoxic capacity mediated by either cytotoxic T lymphocytes or NK cells; (5) exert more effective suppressive activity on MLC-induced T-cell activation when they are allogeneic rather than autologous with respect to responder cells. In particular, higher percentages of CD4+ and of CD4+CD25+ T cells co-expressing CTLA4+ were detected when third-party, rather than autologous, MSCs were added to MLC. These data suggest that T-cell recognition of alloantigens expressed by MSCs may further facilitate the preferential differentiation of activated CD4+ T cells expressing CTLA4, a glycoprotein, known to deliver an inhibitory signal to T cells and to mediate apoptosis of previously activated T lymphocytes. Several studies previously demonstrated that MSCs exert inhibitory effect on lymphocyte activation through the release of soluble factors. Our data suggest that the preferential differentiation of CD4+CD25+ regulatory T-cell subsets may be favored by other mechanisms of MSC-mediated inhibition of alloantigen-induced effector cell activation and expansion, and, in turn, these CD4+CD25+ cells contribute to propagate and extend suppressor activity. Altogether, our results provide immunological support to the use of MSCs for prevention of immune complications related to both HSC and solid organ transplantation and to the theory that MSCs are “universal” suppressors of immune reactivity.
This is a report of 148 patients with hematologic malignancies who received an unmanipulated haploidentical bone marrow transplant (BMT), followed by post-transplant high-dose cyclophosphamide (PT-CY). All patients received a myeloablative conditioning consisting of thiotepa, busulfan, fludarabine (n = 92) or TBI, fludarabine (n = 56). The median age was 47 years (17-74); 47 patients were in first remission (CR1), 37 in second remission (CR2) and 64 had an active disease; all patients were first grafts. The diagnosis was acute leukemia (n = 75), myelodisplastic syndrome (n = 24), myelofibrosis (n = 16), high-grade lytmphoma (n = 15) and others (n = 18). GVHD prophylaxis consisted in PT-CY on days +3 and +5, cyclosporine (from day 0), and mycophenolate (from day +1). The median day for neutrophil engraftment was day +18 (13-32). The cumulative incidence of grades II-IV acute GVHD was 24%, and of grades III-IV GVHD 10%. The incidence of moderate-severe chronic GVHD was 12%. With a median follow-up for the surviving patients of 313 days (100-1162), the cumulative incidence of transplant-related mortality (TRM) is 13%, and the relapse-related death is 23%. The actuarial 22 months overall survival is 77% for CR1 patients, 49% for CR2 patients and 38% for patients grafted in relapse (P o0.001). Major causes of death were relapse (22%), GVHD (2%) and infections (6%). We confirm our initial results, suggesting that a myeloablative conditioning regimen followed by unmanipulated haploidentical BMT with PT-CY, results in a low risk of acute and chronic GVHD and encouraging rates of TRM and overall survival, also for patients with active disease at the time of transplant.Bone Marrow Transplantation (2015) 50, S37-S39; doi:10.1038/bmt.2015.93 PATIENTS AND METHODSClinical characteristics are outlined in Table 1. All patients received a myeloablative regimen with post-transplant cyclophosphamide, between august 2010 and January 2014. A total of 64 patients had an active disease at transplant; 46 were in first remission (CR1) and 39 in second remission (CR2) hematologic remission. The most common diagnosis was acute leukemia (n = 76 ), 48 AML (27% with active disease) and 24 ALL (32% with active disease). Most of the patients with non-Hodgkin lymphoma (60%) also had advanced disease, as well as patients with myelofibrosis. DonorsAll donor/patient pairs were genotypically haplomismatched. A single patient, because of HLA homozigosity, had 0 mismatches in the graft vs host direction and three mismatched in the host vs graft direction. Conditioning regimenThe myeloablative conditioning regimen was based either on chemotherapy-thiotepa, busulfan, fludarabine-or TBI and fludarabine: 92 patients received the thiotepa, busulfan, fludarabine regimen which included thiotepa 5 mg/kg on days − 6 and − 5 (total dose 10 mg/kg), fludarabine 50 mg/m 2 on days − 4, − 3 and − 2 (total dose 150 mg/m 2 ), and busulfan 3,2 mg/kg IV on days − 4, − 3, − 2 (total dose 9,6 mg/kg). Fifty-six patients received the TBI and fludarabine regimen, which incl...
The genetic basis of myelodysplastic syndromes (MDS) is heterogeneous, and various combinations of somatic mutations are associated with different clinical phenotypes and outcomes. Whether the genetic basis of MDS influences the outcome of allogeneic hematopoietic stem-cell transplantation (HSCT) is unclear. Patients and MethodsWe studied 401 patients with MDS or acute myeloid leukemia (AML) evolving from MDS (MDS/ AML). We used massively parallel sequencing to examine tumor samples collected before HSCT for somatic mutations in 34 recurrently mutated genes in myeloid neoplasms. We then analyzed the impact of mutations on the outcome of HSCT. ResultsOverall, 87% of patients carried one or more oncogenic mutations. Somatic mutations of ASXL1, RUNX1, and TP53 were independent predictors of relapse and overall survival after HSCT in both patients with MDS and patients with MDS/AML (P values ranging from .003 to .035). In patients with MDS/AML, gene ontology (ie, secondary-type AML carrying mutations in genes of RNA splicing machinery, TP53-mutated AML, or de novo AML) was an independent predictor of posttransplantation outcome (P = .013). The impact of ASXL1, RUNX1, and TP53 mutations on posttransplantation survival was independent of the revised International Prognostic Scoring System (IPSS-R).Combining somatic mutations and IPSS-R risk improved the ability to stratify patients by capturing more prognostic information at an individual level. Accounting for various combinations of IPSS-R risk and somatic mutations, the 5-year probability of survival after HSCT ranged from 0% to 73%. ConclusionSomatic mutation in ASXL1, RUNX1, or TP53 is independently associated with unfavorable outcomes and shorter survival after allogeneic HSCT for patients with MDS and MDS/AML. Accounting for these genetic lesions may improve the prognostication precision in clinical practice and in designing clinical trials.
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