NK Cells of Kidney Transplant Recipients Display an Activated Phenotype that Is Influenced by Immunosuppression and Pathological Staging.

To explore phenotype and function of NK cells in kidney transplant recipients, we investigated the peripheral NK cell repertoire, capacity to respond to various stimuli and impact of immunosuppressive drugs on NK cell activity in kidney transplant recipients. CD56dim NK cells of kidney transplanted patients displayed an activated phenotype characterized by significantly decreased surface expression of CD16 (p=0.0003), CD226 (p<0.0001), CD161 (p=0.0139) and simultaneously increased expression of activation markers like HLA-DR (p=0.0011) and CD25 (p=0.0015). Upon in vitro stimulation via Ca++-dependent signals, down-modulation of CD16 was associated with induction of interferon (IFN)-γ expression. CD16 modulation and secretion of NFAT-dependent cytokines such as IFN-γ, TNF-α, IL-10 and IL-31 were significantly suppressed by treatment of isolated NK cells with calcineurin inhibitors but not with mTOR inhibitors. In kidney transplant recipients, IFN-γ production was retained in response to HLA class I-negative target cells and to non-specific stimuli, respectively. However, secretion of other cytokines like IL-13, IL-17, IL-22 and IL-31 was significantly reduced compared to healthy donors. In contrast to suppression of cytokine expression at the transcriptional level, cytotoxin release, i.e. perforin, granzyme A/B, was not affected by immunosuppression in vitro and in vivo in patients as well as in healthy donors. Thus, immunosuppressive treatment affects NK cell function at the level of NFAT-dependent gene expression whereby calcineurin inhibitors primarily impair cytokine secretion while mTOR inhibitors have only marginal effects. Taken together, NK cells may serve as indicators for immunosuppression and may facilitate a personalized adjustment of immunosuppressive medication in kidney transplant recipients.

The Peripheral NK Cell Repertoire after Kidney Transplantation is Modulated by Different Immunosuppressive Drugs.

In the context of kidney transplantation, little is known about the involvement of natural killer (NK) cells in the immune reaction leading to either rejection or immunological tolerance under immunosuppression. Therefore, the peripheral NK cell repertoire of patients after kidney transplantation was investigated in order to identify NK cell subsets that may be associated with the individual immune status at the time of their protocol biopsies for histopathological evaluation of the graft. Alterations in the peripheral NK cell repertoire could be correlated to the type of immunosuppression, i.e., calcineurin-inhibitors like Cyclosporin A vs. Tacrolimus with or without addition of mTOR inhibitors. Here, we could demonstrate that the NK cell repertoire in peripheral blood of kidney transplant patients differs significantly from healthy individuals. The presence of donor-specific antibodies was associated with reduced numbers of CD56(dim) NK cells. Moreover, in patients, down-modulation of CD16 and CD6 on CD56(dim) NK cells was observed with significant differences between Cyclosporin A- and Tac-treated patients. Tac-treatment was associated with decreased CD69, HLA-DR, and increased CD94/NKG2A expression in CD56(dim) NK cells indicating that the quality of the immunosuppressive treatment impinges on the peripheral NK cell repertoire. In vitro studies with peripheral blood mononuclear cells of healthy donors showed that this modulation of CD16, CD6, CD69, and HLA-DR could also be induced experimentally. The presence of calcineurin or mTOR inhibitors had also functional consequences regarding degranulation and interferon-γ-production against K562 target cells, respectively. In summary, we postulate that the NK cell composition in peripheral blood of kidney transplanted patients represents an important hallmark of the efficacy of immunosuppression and may be even informative for the immune status after transplantation in terms of rejection vs. drug-induced allograft tolerance. Thus, NK cells can serve as sensors for immunosuppression and may be utilized for future strategies of an individualized adjustment of immunosuppression.

Apheresis-related enrichment of CD26++ T lymphocytes: phenotypic characterization and correlation with unfavorable outcome in autologous hematopoietic progenitor cell transplantation.

BACKGROUND: The lymphocyte surface glycoprotein CD26 anchors adenosine deaminase to the lymphocyte surface and possesses dipeptidyl peptidase IV activity. A distinct subset of CD26++ lymphocytes in autologous hematopoietic progenitor cell transplants (HPCTs) was investigated with regard to clinical outcome after autologous HPCT. The phenotype of these cells was characterized in more detail. STUDY DESIGN AND METHODS: Forty-two eligible patients (multiple myeloma, n = 31; Hodgkin's disease, n = 3; non-Hodgkin's lymphoma, n = 6; peripheral neuroectodermal tumor, n = 1; acute myeloid leukemia, n = 1) were included in a retrospective analysis. Distinct cellular subsets, including CD26+/- and CD26++ subpopulations, were analyzed for correlations with kinetics of engraftment, progression-free survival, and overall survival. RESULTS: The numbers of CD26++ T lymphocytes in the autograft correlated inversely with progression-free survival (p = 0.013). CD26++ T lymphocytes transfused per kg of body weight were predictive for the occurrence of disease progression or relapse (p = 0.006). Importantly, the numbers of CD26++ cells showed a highly variable degree of enrichment in the autograft, but no significant variations in the peripheral blood before apheresis. The characterization of CD26++ cells revealed that CD26++/CD8+ cells form a homogeneous population with a distinct T memory cell phenotype (CD45RO+, CD161++, interleukin-18Rα++, CCR7-). CONCLUSION: CD26++ lymphocytes define a discrete phenotype of T memory cells with known chemoresistance and T-cell-repopulating capacity. Their enrichment during apheresis and corresponding depletion from the circulation are associated with an adverse outcome in autologous HPCT.