The type of ATG matters -- natural killer cells are influenced differentially by Thymoglobulin, Lymphoglobulin and ATG-Fresenius.

Although ATG is frequently used in hematopoietic stem cell transplantation and solid organ transplantation, little is known on its effects on NK cells, which mediate important functions in post-transplantation immunology. We incubated peripheral blood lymphocytes of healthy donors with Thymoglobulin, Lymphoglobulin or ATG-Fresenius. Cell death and apoptosis of NK cells and T cells were determined by flow cytometry using propidium iodide and Annexin V. As expected, there were no significant differences between the different ATGs regarding their T cell toxicity. Surprisingly, we found profound differences between the different ATGs regarding their impact on NK cells: In clinically relevant concentrations Lymphoglobulin had less toxic effects on NK cells as compared to Thymoglobulin or ATG-Fresenius: the median percentages of apoptotic or necrotic NK cells in response to 1 mug/ml Lymphoglobulin, ATG-Fresenius and Thymoglobulin were 2%, 35% and 38%, respectively (p<0.001). This is the first report of differential effects of different ATGs on NK cells. Lymphoglobulin appears to be superior to Thymoglobulin or ATG Fresenius regarding the preservation of NK cell mediated immunity. Randomized trials addressing the impact of different ATGs on lymphocyte subpopulations in the clinical setting are urgently warranted.

A novel method to quantify and characterize leukemia-reactive natural killer cells in patients undergoing allogeneic hematopoietic stem cell transplantation following conventional or reduced-dose conditioning.

The antitumor activity of natural killer (NK) cells has recently been shown to be assessable at a single-cell level via flow cytometric detection of CD107a. We used this novel method to prospectively quantify and characterize tumor-reactive NK cells in patients undergoing myeloablative or nonmyeloablative conditioning and allogeneic hematopoietic stem cell transplantation (HSCT). Degranulation of NK cells in the peripheral blood of 34 patients after HSCT (day +30, day +90) was determined by evaluating CD107a expression after coincubation of the cells with tumor targets. The percentage of degranulating NK cells was higher after nonmyeloablative conditioning than after myeloablative conditioning (P<.001), indicating a higher activation state and increased antitumor activity of NK cells after nonmyeloablative conditioning. We were able to analyze NK cell subsets separately and found that CD56bright NK cells following HSCT are functionally different from CD56bright NK cells in healthy donors, as indicated by a high percentage of degranulating NK cells in response to tumor targets in patients after HSCT. The CD107a assay is a new and feasible method to quantify and characterize tumor-reactive NK cells after HSCT. Using this method, we found that NK cells had high antitumor cytotoxic activity after nonmyeloablative conditioning, which may contribute to the effectiveness of nonmyeloablative conditioning.

The anti-lymphoma effect of antibody-mediated immunotherapy is based on an increased degranulation of peripheral blood natural killer (NK) cells.

BACKGROUND: In patients treated with rituximab and alemtuzumab for lymphomas or CLL, antibody-dependent cellular cytotoxicity (ADCC) is a major mechanism of action. Therefore, assessment of ADCC is mandatory to understand the complex mechanisms leading to the anti-lymphoma effects of monoclonal antibodies (mAb). Due to methodical difficulties, little is yet known about the relevant cell subpopulations and effector mechanisms leading to tumor lysis in ADCC. METHODS: We used a novel flow cytometric assay that detects CD107a as a marker for NK-cell degranulation to characterize and quantify peripheral blood natural killer (NK) cells mediating ADCC in vitro and in vivo. RESULTS: We observed specific and dose-dependent NK-cell activation after administration of rituximab and alemtuzumab. The number of degranulating NK cells was closely related to the concentration of mAb and the effector:target ratio. We were able to quantify and characterize the peripheral blood NK cells mediating ADCC. The majority of degranulating NK cells had the phenotype: CD56(dim), CD69(+), NKG2D(+), NKp30(-), NKp46(-), and CD94(-). Furthermore, we found that the CD107a assay can also visualize ADCC under clinical conditions as we observed increased numbers of NK cells degranulating in response to CD20(+) lymphoma cell lines in patients with non-Hodgkin's lymphoma treated with rituximab. CONCLUSIONS: We were able to quantify and characterize NK cells mediating ADCC with a new and feasible method. The CD107a assay may be useful for predicting treatment responses of individual patients and may help find the optimal dosage and timing for treatment with mAb.

Lentiviral vector transduction of NOD/SCID repopulating cells results in multiple vector integrations per transduced cell: risk of insertional mutagenesis.

Efficient vector transduction of hematopoietic stem cells is a requirement for successful gene therapy of hematologic disorders. We asked whether human umbilical cord blood CD34(+)CD38(lo) nonobese diabetic/severe combined immunodeficiency (NOD/SCID) repopulating cells (SRCs) could be efficiently transduced using lentiviral vectors, with a particular focus on the average number of vector copies integrating into these primitive progenitor cells. Mouse bone marrow was analyzed by fluorescence-activated cell-sorter scanner and by semiquantitative polymerase chain reaction (PCR) to determine the transduction efficiency into SRCs. Lentiviral vector transduction resulted in an average of 22% (range, 3%-90%) of the human cells expressing green fluorescent protein (GFP), however, multiple vector copies were present in human hematopoietic cells, with an average of 5.6 +/- 3.3 (n = 12) copies per transduced cell. To confirm the ability of lentiviral vectors to integrate multiple vector copies into SRCs, linear amplification mediated (LAM)-PCR was used to analyze the integration site profile of a selected mouse showing low-level engraftment and virtually all human cells expressing GFP. Individually picked granulocyte macrophage colony-forming unit colonies derived from the bone marrow of this mouse were analyzed and shown to have the same 5 vector integrants within each colony. Interestingly, one integration site of the 5 that were sequenced in this mouse was located in a known tumor-suppressor gene, BRCA1. Therefore, these findings demonstrate the ability of lentiviral vectors to transduce multiple copies into a subset of NOD/SCID repopulating cells. While this is efficient in terms of transduction and transgene expression, it may increase the risk of insertional mutagenesis.

Polyclonal long-term repopulating stem cell clones in a primate model.

Hematopoietic bone marrow stem cells generate differentiated blood cells and, when transplanted, may contribute to other organs, such as the brain, heart, and liver. An understanding of in vivo clonal behavior of stem cells will have important implications for cellular and gene therapy. For the first time, we have directly demonstrated the derivation of circulating peripheral blood cells from individual stem cell clones. We analyzed the clonal composition of retrovirus-marked peripheral blood leukocyte populations in 2 different primate models by a novel direct genomic sequencing technique allowing the identification of vector insertion sites. More than 80 contributing long-term hematopoietic clones were identified in individual rhesus macaque peripheral blood transplant recipients and more than 25 different clones in a baboon marrow transplant recipient. Up to 5 insertion sequences from each animal were used to trace the long-term contribution of stem cell clones in these primate models. Continuous and mostly pluripotent contributions of peripheral blood leukocytes from each of the traced clones could be detected for the entire follow-up period of 23 to 33 months. Our study provides direct molecular evidence for a polyclonal, multilineage, and sustained contribution of individual stem cells to primate hematopoiesis.