Tissue Distribution Dynamics of Human NK Cells Inferred from Peripheral Blood Depletion Kinetics after Sphingosine-1-Phosphate Receptor Blockade.

Human natural killer (NK) cell subsets differentially distribute throughout the organism. While CD56(dim) and CD56(bright) NK cell subsets similarly reside in the bone marrow (BM), the CD56(dim) population predominantly accumulates in non-lymphoid tissues and the CD56(bright) counterpart in lymphoid tissue (LT). The dynamics with which these NK cell subsets redistribute to tissues remains unexplored. Here, we studied individuals newly exposed to fingolimod, a drug that efficiently blocks sphingosine-1-phosphate (S1P)-directed lymphocyte - including NK cell - egress from tissue to blood. During an observation period of 6h peripheral blood depletion of CD56(bright) NK cells was observed 3 h after first dose of fingolimod, with 40-50% depletion after 6 h, while a decrease of the numbers of CD56(dim) NK cells did not reach the level of statistical significance. In vitro, CD56(bright) and CD56(dim) NK cells responded comparably to the BM-homing chemokine CXCL12, while CD56(bright) NK cells migrated more efficiently in gradients of the LT-homing chemokines CCL19 and CCL21. In conjuncture with these in vitro studies, the indirectly observed subset-specific depletion kinetics from blood are compatible with preferential and more rapid redistribution of CD56(bright) NK cells from blood to peripheral tissue such as LT and possibly also the inflamed central nervous system. These data shed light on an unexplored level at which access of NK cells to LT, and thus, for example antigen-presenting cells, is regulated.

Inter-individual differences in HLA expression can impact the CDC crossmatch.

How human leucocyte antigen (HLA) expression levels on human lymphocytes relate to clinically relevant in vitro cytotoxicity testing has not been defined. Here, cross-sectional (n = 14) and longitudinal (n = 6) semi-quantitative assessment of HLA expression on lymphocytes was performed. Complement-dependent cytotoxicity (CDC) and cellular allo-reactivity were assessed vis-à-vis target cells with defined levels of HLA expression. On CD4(+) and CD8(+) T-cells, and on B-cells, intra-individual HLA levels varied ≤1.5-fold, whereas inter-individual HLA expression varied 2.34-fold and 2.07-fold on CD4(+) and CD8(+) T-cells, respectively, and 2.90-fold on B-cells. Importantly, CDC crossmatch reactions induced by anti-HLA-A2 monoclonal antibody as well as patient sera solely containing HLA-A2 antibodies were significantly impacted by HLA-A2 expression levels on donor cells. Likewise, cytotoxicity of HLA-A2 reactive effector cells was induced proportionate to availability of HLA-A2. These data demonstrate that human HLA expression on lymphocytes from healthy blood donors is fairly stable intra-individually, yet varies significantly from person to person. Variability in HLA expression levels can impact functional cytotoxic reactions in vitro, including the widely used CDC crossmatch assay. Prospective studies are required to test the clinical relevance of this finding.

T cells producing the anti-inflammatory cytokine IL-10 regulate allergen-specific Th2 responses in human airways.

BACKGROUND: Murine models suggest a critical functional role for the anti-inflammatory cytokine IL-10 in local regulation of allergic airways inflammation. There is little corresponding information on human airway cells. This study aimed to investigate whether local IL-10 production regulates responses by respiratory mucosal leucocytes isolated from nasal polyps. MATERIALS AND METHODS: Nasal polyp tissue was harvested from 24 patients sensitised to aeroallergens with chronic rhinitis and polyposis undergoing routine polypectomy. Cells were isolated by matrix proteolysis. Cytokine production by polyp cells was determined by cytometric bead array (CBA) and intracellular cytokine analysis. Surface marker expression by polyp cells was determined by flow cytometry. RESULTS: Allergen stimulation significantly enhanced production of IL-10, but not IL-5 or IFN-γ by nasal polyp cell suspensions. Under the same conditions, neutralisation of IL-10 significantly increased allergen-specific IL-5 and IFN-γ production by nasal polyp cells. Cell depletion experiments showed that T cells themselves were primarily responsible for IL-10 production or for inducing its production by other cells. Intracellular cytokine staining confirmed production of IL-10 in the absence of IL-2 production by T cells in response to allergen. CONCLUSION: T cells within the human respiratory mucosa produce IL-10, which is capable of inhibiting pro-inflammatory Th2 and Th1 cytokine production in an antigen-specific fashion.