Mary Sartor

Prophylactic infusion of cytomegalovirus-specific cytotoxic T lymphocytes stimulated with Ad5f35pp65 gene-modified dendritic cells after allogeneic hemopoietic stem cell transplantation

Cytomegalovirus (CMV) and its therapy continue to contribute to morbidity and mortality in hemopoietic stem cell transplantation (HSCT). Many studies have demonstrated the feasibility of in vitro generation of CMV-specific T cells for adoptive immunotherapy of CMV. Few clinical trials have been performed showing the safety and efficacy of this approach in vivo. In this study, donor-derived, CMV-specific T cells were generated for 12 adult HSCT patients by stimulation with dendritic cells transduced with an adenoviral vector encoding the CMV-pp65 protein. Patients received a prophylactic infusion of T cells after day 28 after HSCT. There were no infusion related adverse events. CMV DNAemia was detected in 4 patients after infusion but was of low level. No patient required CMV-specific pharmacotherapy. Immune reconstitution to CMV was demonstrated by enzyme linked immunospot assay in all recipients with rapid increases in predominantly CMV-pp65 directed immunity in 5. Rates of graft-versus-host disease, infection, and death were not increased compared with expected. These results add to the growing evidence of the safety and efficacy of immunotherapy of CMV in HSCT, supporting its more widespread use. This study was registered at www.anzctr.org.au as #ACTRN12605000213640.

Analysis of human leukaemias and lymphomas using extensive immunophenotypes from an antibody microarray

A novel antibody microarray has been developed that provides an extensive immunophenotype of leukaemia cells. The assay is a solid phase cell‐capture technique in which 82 antigens are studied simultaneously. This paper presents the analysis of 733 patients with a variety of leukaemias and lymphomas from peripheral blood and bone marrow. Discriminant Function Analysis of the expression profiles from these 733 patients and 63 normal subjects were clustered and showed high levels of consistency with diagnoses obtained using conventional clinical and laboratory criteria. The overall levels of consensus for classification using the microarray compared with established criteria were 93·9% (495/527 patients) for peripheral blood and 97·6% (201/206 patients) for bone marrow aspirates, showing that the extensive phenotype alone was frequently able to classify the disease when the leukaemic clone was the dominant cell population present. Immunophenotypes for neoplastic cells were distinguishable from normal cells when the leukaemic cell count was at least 5 × 109 cells/l in peripheral blood, or 20% of cells obtained from bone marrow aspirates. This technique may be a useful adjunct to flow cytometry and other methods when an extensive phenotype of the leukaemia cell is desired for clinical trials, research and prognostic factor analysis.

Geographic heterogeneity of cellular characteristics of acute myeloid leukemia: a comparative study of Australian and Japanese adult cases

We assessed a large number of adults (368 from Australia and 494 from Japan) with de novo acute myeloid leukemia (AML) to define the biological differences between the two populations. In this study, AML was classified using the French–American–British (FAB) criteria into seven groups (M1–M7). M2 was more common in Japan than in Australia, whereas M4 occurred more frequently in Australia than in Japan. Other FAB subtypes were evenly distributed. Cytogenetically, Japanese M2 displayed a higher frequency of t(8;21) than Australian (33.1% vs 15.3%, P < 0.05). The t(15;17), inv/del(16), 11q23 aberrations and 5/7/8 abnormalities were seen at similar frequencies. immunophenotypically, japanese m4/m5 more frequently displayed cd13 and cd14 Than australian, whereas the stem cell markers, cd34 and hla-dr were observed at a relatively higher rate in australian m3 than in japanese m3. The b cell antigen, cd19 was more frequently seen in japanese m2 than in australian m2, but found more often in australian m5 than in japanese m5. In both populations, a close relationship was observed between the expression of cd19 and t(8;21). These findings suggest different biological characteristics of aml between the two populations, the main differences being generated by a higher frequency of t(8;21) chromosomal abnormality in japanese aml.

Fresh PBSC harvests, but not BM, show temperature-related loss of CD34 viability during storage and transport

BACKGROUND The optimum conditions for storage and transport of freshly harvested HPC in the liquid state are uncertain. It is not specified in commonly applied standards for stem cell transplantation. We used a viable CD34 assay to determine the optimum temperature for maintaining progenitor cell viability in freshly harvested BM and PBSC. Our aim was to identify standardized conditions for storage and transport of marrow or peripheral blood products that would optimize CD34 recovery, leading to better transplant outcomes. METHODS Samples were aseptically removed from 46 fresh HPC harvests (34 PBSC and 12 BM) and stored at refrigerated temperature (2-8 degrees C), room temperature (18-24 degrees C) and 37 degrees C for up to 72 h. Samples were analyzed for viable CD34+ cells/microL at 0, 24, 48 and 72 h. RESULTS The mean viable CD34+ yield prior to storage was 7.7 x 10(6)/kg (range 0.7-30.3). The mean loss of viable CD34+ cells in HPC products at refrigerated temperature was 9.4%, 19.4% and 28% at 24, 48 and 72 h, respectively. In contrast, the mean loss of viable CD34+ cells at room temperature was 21.9%, 30.7% and 43.3% at 24, 48 and 72 h, respectively. No viable CD34+ cells remained after storage at 37 degrees C for 24 h. Only PBSC products and not BM showed temperature-related loss of CD34 viability. Greater loss of viable CD34+ cells was observed for allogeneic PBSC compared with autologous PBSC. DISCUSSION These results demonstrate that the optimum temperature for maintaining the viability of CD34+ cells, during overnight storage and transport of freshly harvested HPC, is 2-8 degrees C. These findings will allow the development of standard guidelines for HPC storage and transport.

Activated Circulating Dendritic Cells After Hematopoietic Stem Cell Transplantation Predict Acute Graft-Versus-Host Disease

Background. Dendritic cells (DC) are central to the development of acute graft-versus-host disease (GVHD) following allogeneic hematopoietic stem cell transplantation (alloHSCT). We hypothesized that DC activation status determines the severity of GVHD and that activated DC may be detected in the circulation prior to clinical presentation of GVHD. Methods. Following transplant, blood samples were obtained twice weekly from alloHSCT patients. Myeloid (CD11c+) and plasmacytoid (CD123hi) DC were enumerated by flow cytometry, and activated myeloid DC were identified using the CMRF-44 monoclonal antibody. Results. Of 40 alloHSCT patients, 26 developed acute GVHD. Severity of GVHD was associated with low total blood DC counts (P=0.007) and with low myeloid and plasmacytoid DC numbers (P=0.015 and 0.003). The CMRF-44 antigen was expressed on blood CD11c+ DC in all cases prior to GVHD onset, whereas of the 14 patients without GVHD, seven had no CMRF-44+ CD11c+ DC. Patients with CMRF-44+ CD11c+ DC in more than 20% of samples were more likely to subsequently develop acute GVHD (P=0.001, odds ratio=37.1), while patients who developed grade 2–4 GVHD had prior higher percentages of CMRF-44+ CD11c+ DC compared to grade 0–1 GVHD patients (P=0.001). CMRF-44 expression on >7.9% CD11c+ DC predicted for subsequent development of GVHD with a sensitivity of 87.5% and specificity of 79.2%. Conclusions. Activation status, as assessed by CMRF-44 antigen expression, of blood CD11c+ DC is highly associated with acute GVHD and these cells may be targets for therapeutic intervention.

Recovery of viable CD34 + cells from cryopreserved hemopoietic progenitor cell products

Summary:The number of CD34+ cells infused into patients at the time of autologous or allogeneic transplantation is a clinically important variable, but the viability of these cells has not been extensively documented. In this study, we analyzed the recovery of viable CD34+ cells before and after cryopreservation on 79 autologous stem cell products, using a novel flow cytometry assay without red cell lysis. For 70 PBSC harvest samples, the mean viable CD34+ cell count was 5.98 X 106/kg (range 0.3–23 X 106/kg) before freezing and 5.4 X 106/kg (range 0.2–23 X 106/kg) after thawing. The median recovery was 93% (range 48–107%), with 90% recovery for NHL (range 48–100%, n=34), 83% for multiple myeloma (range 56–106%, n=11), 92.3% for acute leukemia (range 71–100% n=7) and 94.5% for nonhematological malignancies (range 50–107% n=18). Similarly, for autologous bone marrows (n=9) the median recovery of viable CD34+cells was 90% (range 68–100%). The recovery of viable CD34+ cells for adult (n=51) and pediatric (n=28) stem cell collections was 91 and 94%, respectively. Further examination of the correlation between the kinetics of hematological recovery and the number of viable progenitor cells infused, particularly at the lower end of the accepted dose range, may be warranted.

Long-Term Cardiac Allograft Survival across an MHC Mismatch after “Pruning” of Alloreactive CD4 T Cells

Specific tolerance to allografts has been achieved by a variety of means. We have previously shown that ex vivo removal of dividing CD4+ T cells from an MLR or “pruning” delays skin allograft rejection. We tested pruning of alloreactive T cells as a strategy for retaining a broad T cell repertoire while removing alloreactive T cells in a model of cardiac allograft transplant. Using CFSE staining of responder BALB/c cells with stimulator C57BL/6 cells in an MLR, SCID mice were reconstituted with either dividing (D) or nondividing (ND) CD4+ T cells derived from an MLR and then challenged with heterotopic cardiac allografts. Mice reconstituted with D CD4+ T cells rejected cardiac allografts from the stimulator strain with a median survival time (MST) of 29 days, while mice reconstituted with ND CD4+ T cells maintained allografts from the stimulator strain (MST of >100 days) while rejecting third-party allografts (B10.BR) (MST = 11 days). ELISPOT assays demonstrate donor-specific hyporesponsiveness of the ND CD4+ T cells. TCR β-chain V region (TRBV) repertoire analysis demonstrates clonal expansion within both rejecting D cardiac allografts and ND cardiac allografts surviving for the long-term. Histology showed greater allograft infiltration by the D CD4+ T cells. The surviving ND cardiac allografts demonstrated reduced cellular infiltration and reduced incidence of allograft vasculopathy, but with the development of chronic fibrosis. Thus, pruning of alloreactive T cells allows long-term-specific cardiac allograft survival while retaining the ability to reject third-party allografts.

Failure to achieve a threshold dose of CD34(+)CD110(+) progenitor cells in the graft predicts delayed platelet engraftment after autologous stem cell transplantation

In this study, we retrospectively analysed the utility of CD110 expression on CD34+ cells as a predictor of delayed platelet transfusion independence in 39 patients who underwent autologous peripheral blood stem cell transplantation. Absolute CD34+ cells and CD34+ subsets expressing CD110 were enumerated using flow cytometry. Of the 39 patients, 7 required 21 days or more to achieve platelet transfusion independence. Six of the seven patients received a dose of CD34+CD110+ cells below 6.0 × 104/kg while 30 of 32 patients who achieved platelet transfusion independence in <21 days received a dose of CD34+CD110+ cells >6.0 × 104/kg (P<0.001). Patients with delayed platelet engraftment received a median dose of 5.2 × 104 CD34+CD110+ cells/kg compared with a median dose of 16.4 × 104 cells/kg for those engrafting within 21 days (P=0.003). Further analysis showed that >6.0 × 104 CD34+CD110+ cells/kg was highly sensitive (93.8%) and highly specific (85.7%) for achieving platelet transfusion independence within 21 days. Delay in platelet transfusion independence translated into an increased requirement for platelet transfusion (median 6 vs 2 transfusions, P<0.0001). The dose of CD34+/CD110+ cells/kg infused at time of transplantation appears to be an important factor identifying patients at risk of delayed platelet engraftment.

“Pruning” of Alloreactive CD4+ T Cells Using 5- (and 6-)Carboxyfluorescein Diacetate Succinimidyl Ester Prolongs Skin Allograft Survival

Removal of alloreactive cells by either thymic deletion or deletion/anergy in the periphery is regarded as crucial to the development of tolerance. Dyes, such as CFSE, that allow monitoring of cell division suggest that in vitro proliferation could be a used as a way of “pruning” alloreactive cells while retaining a normal immune repertoire with retention of memory to previously encountered pathogens. This would overcome the problems occurring as a result of therapies that use massive depletion of T cells to allow acceptance of organ transplants or bone marrow grafts. We therefore used a skin graft model of CD4-mediated T cell rejection across a major H-2 mismatch (C57BL/6 (H-2b) to BALB/c (H-2d) mice) to evaluate whether nondividing CD4+ T cells derived from a mixed lymphocyte culture would exhibit tolerance to a skin graft from the initial stimulator strain. We demonstrate that selective removal of dividing alloreactive CD4+ T cells resulted in marked specific prolongation of allogeneic skin graft survival, and that the nondividing CD4+ T cells retained a broad TCR repertoire and the ability to maintain memory. This novel way of depleting alloreactive T cells may serve as a useful strategy in combination with other mechanisms to achieve transplant tolerance.

Detection of myeloperoxidase by flow cytometry in acute leukemia

The value of flow cytometric detection of myeloperoxidase (MPO) in the differential diagnosis of acute leukemia was evaluated in 57 cases of acute leukemia and in 9 leukemia cell lines. Cells were fixed and permeabilized with Fix & Perm cell permeabilization kit at room temperature for 15 min each, and stained with anti-MPO monoclonal antibody (MPO-7) by direct immunofluorescence. One myeloid cell line, HL-60, was MPO-positive, while the other myeloid cell lines (KG-1, K-562, and MEG-01) as well as lymphoid cell lines (KM-3, NALM-6, Raji, REH, and T-ALL-1) were MPO-negative as previously described. Among acute leukemias, MPO was detected in 23 of 26 cases of acute myeloid leukemia (AML), 7 of 23 cases of B-lineage acute lymphoblastic leukemia (ALL), 1 of 6 cases of T-lineage ALL (T-ALL), and 1 of 2 cases of acute unclassified leukemia (AUL). The intensity of MPO expression in 6 of 7 B-lineage ALL cases was weak compared with AML labeling. There was no detectable cytochemical MPO in the cells of ALL, AUL, or AML that stained negative for anti-MPO. No relationship between the expression of MPO and myeloid lineage surface antigens was observed in ALL. Three cases of MPO-positive ALL and AUL could be reclassified as biphenotypic leukemia according to the revised Catovsky scoring system. These results indicate that anti-MPO is an excellent marker for the diagnosis and classification of acute leukemia and can be reliably detected by flow cytometry. This rapid technique should be a valuable addition to routine immunophenotyping of acute leukemia.