Alexander D. McLellan

Unique appearance of proliferating antigen-presenting cells expressing DC-SIGN (CD209) in the decidua of early human pregnancy.

Intact human pregnancy can be regarded as an immunological paradox in that the maternal immune system accepts the allogeneic embryo without general immunosuppression. Because dendritic cell (DC) subsets could be involved in peripheral tolerance, the uterine mucosa (decidua) was investigated for DC populations. Here we describe the detailed immunohistochemical and functional characterization of HLA-DR-positive antigen-presenting cells (APCs) in early pregnancy decidua. In contrast to classical macrophages and CD83(+) DCs, which were found in comparable numbers in decidua and nonpregnant endometrium, only decidua harbored a significant population of HLA-DR(+)/DC-SIGN(+) APCs further phenotyped as CD14(+)/CD4(+)/CD68(+/-)/CD83(-)/CD25(-). These cells exhibited a remarkable proliferation rate (9.2 to 9.8% of all CD209(+) cells) by double staining with Ki67 and proliferating cell nuclear antigen. Unique within the DC-family, the majority of DC-SIGN(+) decidual APCs were observed in situ to have intimate contact with CD56(+)/CD16(-)/ICAM-3(+) decidual natural killer cells, another pregnancy-restricted cell population. In vitro, freshly isolated CD14(+)/DC-SIGN(+) decidual cells efficiently took up antigen, but could not stimulate naive allogeneic T cells at all. Treatment with an inflammatory cytokine cocktail resulted in down-regulation of antigen uptake capacity and evolving capacity to effectively stimulate resting T cells. Fluorescence-activated cell sorting analysis confirmed the maturation of CD14(+)/DC-SIGN(+) decidual cells into CD25(+)/CD83(+) mature DCs. In summary, this is the first identification of a uterine immature DC population expressing DC-SIGN, that appears only in pregnancy-associated tissue, has a high proliferation rate, and a conspicuous association with a natural killer subset.

Human Decidua Contains Potent Immunostimulatory CD83+ Dendritic Cells

Dendritic cells (DCs) are sentinel cells of the immune system important in initiating antigen-specific T-cell responses to microbial and transplantation antigens. DCs are particularly found in surface tissues such as skin and mucosa, where the organism is threatened by infectious agents. The human decidua, despite its proposed immunosuppressive function, hosts a variety of immunocompetent CD45 cells such as natural killer cells, macrophages, and T cells. Here we describe the detection, isolation, and characterization of CD45(+), CD40(+), HLA-DR(++), and CD83(+) cells from human early pregnancy decidua with typical DC morphology. CD83(+) as well as CD1a(+) cells were found in close vicinity to endometrial glands, with preference to the basal layer of the decidua. In vitro, decidual CD83(+) cells could be enriched to approximately 30%, with the remainder of cells encompassing DC-bound CD3(+) T cells. Stimulation of allogeneic T cells in a mixed leukocyte reaction by the decidual cell fraction enriched for CD83(+) cells, was similar to that obtained with blood monocyte-derived DCs, demonstrating the potent immunostimulatory capacity of these cells. Decidual DCs with morphological, phenotypic, and functional characteristics of immunostimulatory DCs might be important mediators in the regulation of immunological balance between maternal and fetal tissue, leading to successful pregnancy.

CD169 mediates the capture of exosomes in spleen and lymph node

Exosomes are lipid nanovesicles released following fusion of the endosoma limiting membrane with the plasma membrane; however, their fate in lymphoid organs after their release remains controversial. We determined that sialoadhesin (CD169; Siglec-1) is required for the capture of B cell-derived exosomes via their surface-expressed α2,3-linked sialic acids. Exosome-capturing macrophages were present in the marginal zone of the spleen and in the subcapsular sinus of the lymph node. In vitro assays performed on spleen and lymph node sections confirmed that exosome binding to CD169 was not solely due to preferential fluid flow to these areas. Although the circulation half-life of exosomes in blood of wild-type and CD169(-/-) mice was similar, exosomes displayed altered distribution in CD169(-/-) mice, with exosomes freely accessing the outer marginal zone rim of SIGN-R1(+) macrophages and F4/80(+) red pulp macrophages. In the lymph node, exosomes were not retained in the subcapsular sinus of CD169(-/-) mice but penetrated deeper into the paracortex. Interestingly, CD169(-/-) mice demonstrated an enhanced response to antigen-pulsed exosomes. This is the first report of a role for CD169 in the capture of exosomes and its potential to mediate the immune response to exosomal antigen.

Targeting of Lymphotoxin-α to the Tumor Elicits an Efficient Immune Response Associated with Induction of Peripheral Lymphoid-like Tissue

A recombinant antibody-lymphotoxin-alpha fusion protein induced an adaptive immune response protecting mice from melanoma. Importantly, this fusion protein elicited the formation of a lymphoid-like tissue in the tumor microenvironment containing L-selectin+ T cells and MHC class II+ antigen-presenting cells, as well as B and T cell aggregates. Furthermore, PNAd+/TCA4+ high endothelial venules were observed within the tumor, suggesting entry channels for naive T cell infiltrates. Over the course of therapy, a marked clonal expansion of certain TCR specificities occurred among tumor-infiltrating lymphocytes that displayed reactivity against melanoma cells and the TRP-2(180-188) peptide. Consequently, naive T cells may have been recruited to as well as primed and expanded in the lymphoid-like tissue induced by the lymphotoxin-alpha fusion protein at the tumor site.

Induction of Exosome Release in Primary B Cells Stimulated via CD40 and the IL-4 Receptor

Exosomes are lipid-bound nanovesicles formed by inward budding of the endosomal membrane and released following fusion of the endosomal limiting membrane with the plasma membrane. We show here that primary leukocytes do not release exosomes unless subjected to potent activation signals, such as cytokine or mitogen stimulation. In particular, high levels of exosomes were released when murine splenic B cells were stimulated via CD40 and the IL-4 receptor. This property was shared by B cells from different anatomic locations, as newly formed, marginal zone and follicular B cells were capable of secreting exosomes upon CD40/IL-4 triggering. B cell exosomes expressed high levels of MHC class I, MHC class II, and CD45RA (B220), as well as components of the BCR complex, namely, surface Ig, CD19, and the tetraspanins CD9 and CD81. Ig on the plasma membrane of primary B cells was targeted to the exosome pathway, demonstrating a link between the BCR and this exocytic pathway. IgD and IgM were the predominant Ig isotypes associated with CD40/IL-4 elicited exosomes, though other isotypes (IgA, IgG1, IgG2a/2b, and IgG3) were also detected. Together, these results suggest that exosome release is not R constitutive activity of B cells, but may be induced following cell: cell signaling.

MHC class II and CD40 play opposing roles in dendritic cell survival

In contrast to very immature dendritic cells (DC), mature DC are largely resistant to death by CD95 (CD95/APO‐1) ligation. Investigation of other potential death‐inducing ligands showed that mature DC were instead highly susceptible to apoptosis induced by cross‐linking of MHC class II. Thus, increasing DC maturity correlates with increased resistance to CD95 killing, but an increased susceptibility to class II‐mediated killing. Anti‐I‐A/I‐E monoclonal antibodies (mAb) induced rapid (<2 h) apoptotic cell death in mature epidermal, spleen and bone marrow‐derived DC, as determined by annexin/propidium iodide staining, morphological changes, decreased diploidy and loss in mitochondrial membrane potential. Although full class II‐mediated killing required DC cytoskeletal motion, divalent cations and phosphatase activity, neither caspase activation, respiration, RNA or protein synthesis, NO production, nor CD95:CD95L interactions were required. Strikingly, DC pretreated by CD40 mAb cross‐linking, but not by lipopolysaccharide or TNF‐α , were completely resistant to class II‐mediated killing. CD40‐mediated protection was reduced in the presence of the SB202190 inhibitor of the mitogen‐activated protein kinase p38 pathway, but appeared to be independent of p42/44 extracellular signal‐related kinase or NF‐K B activation. Our findings show that in addition to its role as an activator of antigen‐presenting cell function, CD40 provides an important counter‐signal against class II‐induced apoptosis. Thus, these data point to an important role of the T cell in regulating DC survival.

Human Dendritic Cells Express Functional Interleukin-7

Interleukin-7 (IL-7) supports the proliferation of mature T lymphocytes, however, the cellular source of IL-7 for T lymphocyte activation has not been well established. We therefore investigated whether human peripheral blood dendritic cells (DC) produce IL-7 as a contribution towards T lymphocyte activation. Human CMRF-44+/CD14-/CD19- low density DC, purified after overnight tissue culture, contained IL-7 transcripts, detected by direct cell reverse transcription-polymerase chain reaction. Intracytoplasmic staining confirmed IL-7 protein in at least a subpopulation of cultured low density DC. In contrast, resting/immature DC, isolated directly by immunodepletion of lineage marker positive cells, contained no IL-7 mRNA. Thus, the expression of IL-7 by DC follows the pattern described previously for CD80, CD86 and CD40. However, tissue culture of purified resting/immature DC, in contrast to CD80, CD86 and CD40, failed to induce IL-7 transcripts. The functional importance of DC IL-7 expression was demonstrated in an allogeneic mixed leukocyte reaction (MLR). Neutralising mAb to IL-7 significantly inhibited T lymphocyte proliferation when low DC numbers were used, but at higher stimulator numbers, anti-IL-7 mAb failed to inhibit an allogeneic MLR. This suggests, that when DC are in excess, other co-stimulatory pathways can compensate for the lack of IL-7. Addition of IL-7 to a MLR caused a significant increase in the proliferative response stimulated by monocytes and B lymphocytes but not by DC. These data support the concept of an initial phase of antigen uptake by DC followed by the optimisation of DC co-stimulatory potential. The co-stimulatory repertoire expressed, including IL-7, may be regulated by exogenous stimuli, thereby ensuring DC flexibility in mounting a response appropriate to the environmental changes.

The Herpes Simplex Virus-1 Encoded Glycoprotein B Diverts HLA-DR into the Exosome Pathway

Neutralizing Abs play an important role for immunity against HSV-1 infection. This branch of the immune response is initiated by MHC class II Ag presentation and activation of T cell help. In this study, we show that the HSV-1 encoded glycoprotein B (gB) manipulates the class II processing pathway by perturbing endosomal sorting and trafficking of HLA-DR (DR) molecules. Expression of gB in the human melanoma cell line Mel JuSo results in formation of enlarged DR+ intracellular vesicles. Costaining of the vesicles revealed the presence of DR, gB, and the late endosomal marker CD63. The lumen of these late endosomal membranes shows a variable content, containing either gB or CD63, or both CD63 and gB. gB targets DR molecules on their biosynthetic route, after the MHC class II invariant chain is released from the DR heterodimer. gB-DR complexes were detected in a post-Golgi compartment and in exosomes, but not on the cell surface. Interestingly, increasing expression of gB strongly elevated the amount of DR and CD63 released into the exosome pathway. In conclusion, this is a previously undescribed mode of viral immune evasion involving hijacking of DR from its normal transport route to the cell surface, followed by viral-mediated release of DR into the exosome pathway.

Isolation of human blood dendritic cells by discontinuous Nycodenz gradient centrifugation.

The most potent antigen presenting cell present in peripheral blood, lymphoid and non-lymphoid tissue is the dendritic cell (DC). The study of human DC has been restricted by their low frequency in the tissues and the lack of a truly DC specific surface marker to assist in identification and isolation. Standard techniques for the isolation of blood DC generally employ a period of in vitro culture followed by flotation on dense albumin gradients, or more recently, discontinuous gradients of metrizamide. Dense albumin gradients are time consuming to prepare, giving low and variable yields of DC. Metrizamide is more convenient, although exposure of monocytes to metrizamide can decrease the expression of CD14 and alter the accessory cell properties of antigen presenting cells. Here we demonstrate that Nycodenz gradient centrifugation of 16 h cultured, T lymphocyte depleted, peripheral blood mononuclear cells (PBMC) reliably yields a population of low density cells that is highly enriched for DC. Most B and residual T lymphocytes are depleted and NK cell numbers are reduced two-fold from the interface cell population. The high density pellet fraction exhibits very little allostimulatory activity, indicating that few DC pass into the pellet. The low density fraction contains a significant population (20 +/- 5 (SD)%, n = 8) of cells which fail to stain for the lineage markers CD3, CD11b, CD14, CD16, CD19 and CD57. Nycodenz exhibits low toxicity, does not alter the allostimulatory activity of antigen presenting cells, and is therefore ideal for the isolation of cultured DC.

Functions of myeloid and lymphoid dendritic cells

The bone marrow derived dendritic cell (DC) is an essential antigen presenting cell (APC) for the initiation of primary, T cell based immune responses. DC are a heterogenous haematopoietic lineage, in that many subsets from different tissues show different surface phenotypes, but the ability to stimulate antigen specific naïve T cell proliferation appears to be shared between these DC subsets. It has been suggested that the so called myeloid and lymphoid-derived subsets of DC perform distinct stimulatory or tolerogenic functions. However, recent data has blurred this apparent distinction of DC subset function and shown that both subsets are at least capable of stimulatory and possibly even tolerogenic functions. Thus, the immunoregulatory potential of DC may depend less on ontology than on recent activatory or downregulatory stimuli.