Preliminary studies using directed-donor ex vivo expanded human mesenchymal stem cells (hMSCs) have shown promise in the treatment of acute graft-versus-host disease (aGVHD). However, their production is cumbersome and standardization is difficult. We describe the first experience of using a premanufactured, universal donor, formulation of hMSCs (Prochymal) in children (n = 12; 10 boys; 9 Caucasian; age range: 0.4-15 years) with treatment-resistant grade III and IV aGVHD who received therapy on compassionate use basis between July 2005 and June 2007 at 5 transplant centers. All patients had stage III or IV gut (GI) symptoms and half had additional liver and/or skin involvement. Disease was refractory to steroids in all cases and additionally to a median of 3 other immunosuppressive therapies. The hMSCs (8 × 10(6)cells/kg/dose in 2 patients and 2 × 10(6)cells/kg/dose in the rest) were infused intravenously over 1 hour twice a week for 4 weeks. Partial and mixed responders received subsequent weekly therapy for 4 weeks. HLA or other matching was not needed. The hMSCs were started at a median of 98 days (range: 45-237) posttransplant. A total of 124 doses were administered, with a median of 8 doses (range: 2-21) per patient. Overall, 7 (58%) patients had complete response, 2 (17%) partial response, and 3 (25%) mixed response. Complete resolution of GI symptoms occurred in 9 (75%) patients. Two patients relapsed after initial response and showed partial response to retreatment. The cumulative incidence of survival at 100 days from the initiation of Prochymal therapy was 58%. Five of 12 patients (42%) were still alive after a median follow-up of 611 days (range: 427-1111) in surviving patients. No infusional or other identifiable acute toxicity was seen in any patient. Multiple infusions of hMSCs were well tolerated and appeared to be safe in children. Clinical responses, particularly in the GI system, were seen in the majority of children with severe refractory aGVHD. Given the favorable results observed in a patient population with an otherwise grave prognosis, we conclude that hMSCs hold potential for the treatment of aGVHD, and should be further studied in phase III trials in pediatric and adult patients.
Glioblastoma multiforme (GBM) is a highly lethal brain tumor affecting children and adults, with the majority of affected individuals dying from their disease by 2 years following diagnosis. Other groups have reported the association of cytomegalovirus (CMV) with GBM, and we sought to confirm these findings in a large series of patients with primary GBM from our institution. Immunohistochemical analysis of paraffin embedded tissue sections was performed on 49 newly diagnosed GBM tumors, the largest series reported to date. We confirmed the presence of CMV pp65 on 25/49 (51%) and of IE1 on 8/49 (16%) of these tumors. While pp65 and IE1 are generally found in the nucleus of cells that are permissibly infected by CMV, GBM in this series had mostly cytoplasmic staining, with only 16% having nuclear staining for one or both of these antigens. We infected GBM cell lines with a laboratory strain of CMV, and found that most of the staining was cytoplasmic, with some perinuclear localization of IE1. To test the potential for CMV infected GBM cells to be recognized by CMV pp65 and IE1 specific cytotoxic T lymphocytes (CTL), we used CMV infected GBM cell lines in cytotoxicity assays with human leukocyte antigen partially matched CMV CTL. Lysis of CMV infected GBM tumor cells was accentuated by pre-treating these cell lines with either the demethylating agent decitabine or interferon-γ, both of which were shown to increase MHC Class I and II expression on tumor cells in vitro. These studies confirm the presence of CMV pp65 or IE1 on approximately half of GBM, with the possibility that CMV positive tumor cells can be recognized by CMV pp65/IE1 specific T cells.
A phase I trial combining decitabine/dendritic cell vaccine targeting MAGE-A1, MAGE-A3 and NY-ESO-1 for children with relapsed or therapy-refractory neuroblastoma and sarcoma
Antigen-specific immunotherapy was studied in a multi-institutional phase 1/2 study by combining decitabine (DAC) followed by an autologous dendritic cell (DC)/MAGE-A1, MAGE-A3 and NY-ESO-1 peptide vaccine in children with relapsed/refractory solid tumors. Patients aged 2.5-15 years with relapsed neuroblastoma, Ewing's sarcoma, osteosarcoma and rhabdomyosarcoma were eligible to receive DAC followed by DC pulsed with overlapping peptides derived from full-length MAGE-A1, MAGE-A3 and NY-ESO-1. The primary endpoints were to assess the feasibility and tolerability of this regimen. Each of four cycles consisted of week 1: DAC 10 mg/m(2)/day for 5 days and weeks 2 and 3: DC vaccine once weekly. Fifteen patients were enrolled in the study, of which 10 were evaluable. Generation of DC was highly feasible for all enrolled patients. The treatment regimen was generally well tolerated, with the major toxicity being DAC-related myelosuppression in 5/10 patients. Six of nine patients developed a response to MAGE-A1, MAGE-A3 or NY-ESO-1 peptides post-vaccine. Due to limitations in number of cells available for analysis, controls infected with a virus encoding relevant genes have not been performed. Objective responses were documented in 1/10 patients who had a complete response. Of the two patients who had no evidence of disease at the time of treatment, one remains disease-free 2 years post-therapy, while the other experienced a relapse 10 months post-therapy. The chemoimmunotherapy approach using DAC/DC-CT vaccine is feasible, well tolerated and results in antitumor activity in some patients. Future trials to maximize the likelihood of T cell responses post-vaccine are warranted.
Biology and adoptive cell therapy of Epstein‐Barr virus‐associated lymphoproliferative disorders in recipients of marrow allografts
Epstein-Barr virus (EBV) is an ubiquitous herpesvirus which is carried as a latent infection of B lymphocytes and salivary gland epithelial cells in over 90% of normal adults. Latently infected EBV-transformed B cells circulate at low frequency in the blood for the life of the host. These transformed B cells stimulate a heterogeneous and complex host cell response, ultimately leading to the development and maintenance of high frequencies of HLA-restricted T cells specific for the EBV-encoded nuclear antigens EBNA2-EBNA6 and the latency membrane proteins LMP-1 and LMP-2. Responses to latent EBV-encoded proteins are hierarchical with responses to certain epitopes predominating, dependent upon the HLA genotype of the host. Profound suppression of T-cell immunity may permit the emergence of polyclonal, oligoclonal or monoclonal EBV antigen-expressing lymphoproliferative disorders or malignant B-cell lymphomas expressing these latent EBV antigens. Adoptive transfer of small numbers of peripheral blood mononuclear cells or HLA-partially matched T cells from in vitro expanded EBV-specific T-cell lines derived from a seropositive marrow donor has induced durable regressions of bulky, widely metastatic monoclonal EBV lymphomas in a high proportion of cases. This review describes the current state of knowledge and hypothesis regarding the biology and immunology of EBV infection in the normal host, the features of donor, host and virus which contribute to the development of EBV-associated lymphoproliferative diseases and the mechanisms whereby they are controlled by adoptive transfer of immune T cells.
Epstein-Barr virus–induced lymphoproliferative disease (EBV-LPD) is a serious and potentially fatal complication after allogeneic stem cell transplantation (SCT). To evaluate levels of EBV DNA in SCT patients, a semiquantitative polymerase chain reaction (PCR) assay was developed. DNA was extracted from peripheral blood leukocytes and diluted, and PCR was performed by using a primer set specific for a well-conserved sequence of the internal repeat 1 region of the EBV genome. Forty-one SCT patients were screened with this method. Thirty-seven patients received allogeneic transplants, of which 18 were T-cell–depleted marrow. Four additional patients received autologous SCT, one of which was T-cell depleted. The mean time of follow-up by EBV PCR was 147 days (range, 47 to 328 days) posttransplant. The range of EBV copies/μg DNA from normal EBV sero-positive donors was 40 to 4,000. Seven patients had ≥40,000 copies of EBV DNA/μg DNA, all of whom were recipients of T-cell–depleted SCT. Five of the seven patients with elevated levels of EBV DNA developed EBV-LPD. Four of these five patients with EBV-LPD had elevated levels of EBV DNA from 1 to 8 weeks before diagnosis. Two patients with EBV-LPD had normal levels of EBV DNA, and two patients with ≥40,000 copies EBV/μg DNA did not develop EBV-LPD. In one patient, clinical resolution of disease correlated with a decrease in EBV DNA and an increase in the level of EBV-specific cytotoxic T-cell precursors. These data indicate that the measurement of EBV viral load with semiquantitative PCR is useful in detecting EBV-LPD in high-risk patients before the onset of clinical symptoms. Because not all patients with elevated levels of EBV DNA develop EBV-LPD, semiquantitative PCR results cannot substitute for clinical, radiographic, and pathological confirmation of this diagnosis.
Children hospitalized for fever and neutropenia who have persistent fever and an ANC of less than 100 after 48 hours are at high risk for morbidity and are more likely to require antibiotic changes and antifungal therapy. Children who initially lack signs of sepsis, are afebrile, and have an ANC of 100 or higher after 48 hours are at low risk for complications and could be selectively discharged on antimicrobials after a 48-hour period of inpatient hospitalization.
Epstein-Barr virus-induced lymphoproliferative disease (EBV-LPD) is a potentially lethal complication during the first 6 months after allogeneic bone marrow transplantation (BMT). To determine whether deficiencies of EBV-specific cellular immunity contribute to EBV-LPD susceptibility and distinguish patients at risk, we performed limiting dilution analysis to quantify anti-EBV cytotoxic T-lymphocyte precursor (CTLp) frequencies in 26 recipients of unmodified or T-cell-depleted (TCD) grafts from EBV-seropositive donors. At 3 months post-BMT (n = 26), only five patients had EBV CTLp frequencies in the range of seropositive normal controls, irrespective of the type of transplant administered. By 6 months post-BMT, 9 of 13 patients tested had EBV CTLp frequencies within the normal range. The time period in which these patients had deficient cellular immunity to EBV corresponds to the period in which we have observed EBV-LPD in most prior patients. One patient with a low EBV CTLp frequency at 4 months post-BMT developed an EBV-LPD. Within 2 weeks of receiving an infusion of donor peripheral blood mononuclear cells (PBMC) providing less than 1,200 EBV- specific cytotoxic T-cell precursors, populations of EBV-specific CTL in the circulation were restored to levels detected in normal seropositive adults. Concurrently, the patient achieved a regression of the EBV-LPD, which has been sustained without further therapy. These studies indicate that recipients of both unmodified and TCD marrow grafts have profound deficiencies of EBV-specific T cell-mediated immunity early posttransplant, and that the period of risk for EBV-LPD closely corresponds to this interval of severe deficiency. Treatment of one patient with EBV-LPD with marrow donor-derived PBMC induced a rapid expansion of EBV-specific cytotoxic T-cell populations that occurred contemporaneously with the clinical regression of disease.
IntroductionT-cell-mediated immunity is the major mechanism providing specific protection against microbial infections, including those by viruses. 1 Virus-infected cells process viral polypeptides and present antigenic epitopes on the cell surface. T cells mount immune responses upon recognizing the antigen epitope in the context of the major histocompatibility complex (MHC) molecules and receiving various signals from the antigen-presenting cells. It has been well established that CD8 ϩ T cells are mostly cytotoxic T lymphocytes (CTLs) that directly destroy virus-infected cells, 2 while CD4 ϩ T cells serve primarily as helpers by secreting various cytokines to regulate and coordinate functions of T cells, B cells, and other immune cells. 3 Viruses have evolved different strategies to escape T-cellmediated immunity. 4 Some viruses maintain a state of latent infection in immunocompetent individuals. As exemplified by the Epstein-Barr virus (EBV) and cytomegalovirus (CMV), viruses may disrupt the host cell mechanisms of antigen presentation and/or adapt viral replication programs to minimize the expression of viral targets recognizable by immune surveillance. In individuals with compromised immunity, such as recipients of stem cell transplants (SCTs), latently infecting EBV and CMV may reactivate and cause morbidity and mortality. 5,6 Guided by the increased understanding of mechanisms of cellular immunity against viral pathogens, strategies of adoptive immunotherapy have been developed 7 and successfully applied to patients following SCT to prevent and treat these viral complications. 8,9 Adoptive immunotherapy involves infusing ex vivo expanded, virus-specific T cells into susceptible patients. Therapeutic CMV-or EBV-specific CTLs have been prepared from ex vivo T-cell cultures stimulated with autologous CMV-infected fibroblasts, 10 or B-lymphoblastoid cell lines (BLCLs), 9 respectively.In SCT patients, the infusion of polyclonal, BLCL-primed T-cell preparations reconstitutes long-term cellular immunity against EBV, 11 but CMV-specific CD8 ϩ clones were found to provide only short-term protection. 12 It has been suggested that a deficiency in CD4 ϩ helpers may be responsible for the failed long-term survival of the infused CMV-specific CD8 ϩ CTL, as the persistence of the CD8 ϩ CTL is correlated with CD4 ϩ helper functions in recipients of T-cell infusons. 12 Thus, the long-term efficacy of the BLCLprimed T cells may result from the presence of a minor component of EBV-specific CD4 ϩ cells in the polyclonal T-cell culture. This is consistent with the findings that BLCLs express both HLA class I and HLA class II and have the capacity to present endogenously derived antigens to CD8 ϩ , as well as CD4 ϩ T cells. 13,14 Indeed, we were able to isolate specific CD4 ϩ T cells that recognize autologous BLCLs from T-cell cultures primed with BLCLs, and we showed that they are cytolytic via a pathway independent of granzyme B. 15 We are interested in further studying the CD4 ϩ T cells derived from For personal use only. ...
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