Human Dendritic Cell Subsets from Spleen and Blood Are Similar in Phenotype and Function but Modified by Donor Health Status

Mouse dendritic cells (DC) have been extensively studied in various tissues, especially spleen, and they comprise subsets with distinct developmental origins, surface phenotypes, and functions. Considerably less is known about human DC due to their rarity in blood and inaccessibility of other human tissues. The study of DC in human blood has revealed four subsets distinct in phenotype and function. In this study, we describe four equivalent DC subsets in human spleen obtained from deceased organ donors. We identify three conventional DC subsets characterized by surface expression of CD1b/c, CD141, and CD16, and one plasmacytoid DC subset characterized by CD304 expression. Human DC subsets in spleen were very similar to those in human blood with respect to surface phenotype, TLR and transcription factor expression, capacity to stimulate T cells, cytokine secretion, and cross-presentation of exogenous Ag. However, organ donor health status, in particular treatment with corticosteroid methylprednisolone and brain death, may affect DC phenotype and function. DC T cell stimulatory capacity was reduced but DC were qualitatively unchanged in methylprednisolone-treated deceased organ donor spleen compared with healthy donor blood. Overall, our findings indicate that human blood DC closely resemble human spleen DC. Furthermore, we confirm parallels between human and mouse DC subsets in phenotype and function, but also identify differences in transcription factor and TLR expression as well as functional properties. In particular, the hallmark functions of mouse CD8α+ DC subsets, that is, IL-12p70 secretion and cross-presentation, are not confined to the equivalent human CD141+ DC but are shared by CD1b/c+ and CD16+ DC subsets.

[1]  Li Wu,et al.  Resident and Monocyte-Derived Dendritic Cells Become Dominant IL-12 Producers under Different Conditions and Signaling Pathways , 2010, The Journal of Immunology.

[2]  C. Dutertre,et al.  The XC chemokine receptor 1 is a conserved selective marker of mammalian cells homologous to mouse CD8α+ dendritic cells , 2010, The Journal of experimental medicine.

[3]  Anna M. Keller,et al.  Characterization of human DNGR-1+ BDCA3+ leukocytes as putative equivalents of mouse CD8α+ dendritic cells , 2010, The Journal of experimental medicine.

[4]  P. Rod Dunbar,et al.  Human CD141+ (BDCA-3)+ dendritic cells (DCs) represent a unique myeloid DC subset that cross-presents necrotic cell antigens , 2010, The Journal of experimental medicine.

[5]  P. Kloetzel,et al.  Superior antigen cross-presentation and XCR1 expression define human CD11c+CD141+ cells as homologues of mouse CD8+ dendritic cells , 2010, The Journal of experimental medicine.

[6]  W. Heath,et al.  The CD8+ dendritic cell subset , 2010, Immunological reviews.

[7]  A. Rudensky,et al.  In Vivo Analysis of Dendritic Cell Development and Homeostasis , 2009, Science.

[8]  Li Wu,et al.  Distinct functional capacities of mouse thymic and splenic dendritic cell populations , 2008, Immunology and cell biology.

[9]  M. Wright,et al.  The dendritic cell subtype-restricted C-type lectin Clec9A is a target for vaccine enhancement. , 2008, Blood.

[10]  J. Villadangos,et al.  Antigen-presentation properties of plasmacytoid dendritic cells. , 2008, Immunity.

[11]  A. Salim,et al.  Aggressive Organ Donor Management Protocol , 2008, Journal of intensive care medicine.

[12]  B. Blom,et al.  Development of human plasmacytoid dendritic cells depends on the combined action of the basic helix‐loop‐helix factor E2‐2 and the Ets factor Spi‐B , 2008, European journal of immunology.

[13]  M. Velásquez-Lopera,et al.  Human spleen contains different subsets of dendritic cells and regulatory T lymphocytes , 2008, Clinical and experimental immunology.

[14]  Gordon D. Brown,et al.  CLEC9A Is a Novel Activation C-type Lectin-like Receptor Expressed on BDCA3+ Dendritic Cells and a Subset of Monocytes , 2008, Journal of Biological Chemistry.

[15]  D. Pennington,et al.  Tumor therapy in mice via antigen targeting to a novel, DC-restricted C-type lectin. , 2008, The Journal of clinical investigation.

[16]  B. León,et al.  Monocyte‐derived dendritic cells in innate and adaptive immunity , 2008, Immunology and cell biology.

[17]  M. Zembala,et al.  Peripheral Blood CD14high CD16+ Monocytes are Main Producers of IL‐10 , 2008, Scandinavian journal of immunology.

[18]  Eric Vivier,et al.  Novel insights into the relationships between dendritic cell subsets in human and mouse revealed by genome-wide expression profiling , 2008, Genome Biology.

[19]  R. Steinman,et al.  Taking dendritic cells into medicine , 2007, Nature.

[20]  W. Land,et al.  Innate immunity-mediated allograft rejection and strategies to prevent it. , 2007, Transplantation proceedings.

[21]  L. Ziegler‐Heitbrock,et al.  The CD14+ CD16+ blood monocytes: their role in infection and inflammation , 2007, Journal of leukocyte biology.

[22]  James M. Wettenhall,et al.  Signal Regulatory Protein Molecules Are Differentially Expressed by CD8− Dendritic Cells1 , 2006, The Journal of Immunology.

[23]  P. Hodgkin,et al.  The proliferative response of CD4 T cells to steady-state CD8+ dendritic cells is restricted by post-activation death. , 2006, International immunology.

[24]  S. Gordon,et al.  Monocyte and macrophage heterogeneity , 2005, Nature Reviews Immunology.

[25]  D. Ankerst,et al.  Impact of cryopreservation on tetramer, cytokine flow cytometry, and ELISPOT , 2005, BMC Immunology.

[26]  J. Derry,et al.  Nectin-like Protein 2 Defines a Subset of T-cell Zone Dendritic Cells and Is a Ligand for Class-I-restricted T-cell-associated Molecule*♦ , 2005, Journal of Biological Chemistry.

[27]  Li Wu,et al.  Cutting Edge: Generation of Splenic CD8+ and CD8− Dendritic Cell Equivalents in Fms-Like Tyrosine Kinase 3 Ligand Bone Marrow Cultures1 , 2005, The Journal of Immunology.

[28]  I. Davis,et al.  Tumor antigen processing and presentation depend critically on dendritic cell type and the mode of antigen delivery. , 2005, Blood.

[29]  J. O’Shea,et al.  IFN Regulatory Factor-4 and -8 Govern Dendritic Cell Subset Development and Their Functional Diversity , 2005, The Journal of Immunology.

[30]  M. Wright,et al.  Differential production of inflammatory chemokines by murine dendritic cell subsets. , 2004, Immunobiology.

[31]  H. Wakasugi,et al.  Freeze-Thawing Procedures Have No Influence on the Phenotypic and Functional Development of Dendritic Cells Generated from Peripheral Blood CD14+ Monocytes , 2004, Journal of immunotherapy.

[32]  J. Kirby,et al.  Pulmonary Transplantation: the role of brain death in donor lung injury , 2003, Transplantation.

[33]  S. Akira,et al.  Toll‐like receptor expression in murine DC subsets: lack of TLR7 expression by CD8α+ DC correlates with unresponsiveness to imidazoquinolines , 2003, European journal of immunology.

[34]  S. Rose-John,et al.  Transcriptional profiling identifies Id2 function in dendritic cell development , 2003, Nature Immunology.

[35]  K. MacDonald,et al.  Characterization of human blood dendritic cell subsets. , 2002, Blood.

[36]  Li Wu,et al.  Mouse Plasmacytoid Cells , 2002, The Journal of experimental medicine.

[37]  S. Akira,et al.  Microbial Recognition Via Toll-Like Receptor-Dependent and -Independent Pathways Determines the Cytokine Response of Murine Dendritic Cell Subsets to CD40 Triggering1 , 2002, The Journal of Immunology.

[38]  S. Akira,et al.  Interferon-α and Interleukin-12 Are Induced Differentially by Toll-like Receptor 7 Ligands in Human Blood Dendritic Cell Subsets , 2002, The Journal of experimental medicine.

[39]  E. Bröcker,et al.  Anatomic location and T-cell stimulatory functions of mouse dendritic cell subsets defined by CD4 and CD8 expression. , 2002, Blood.

[40]  Yong‐jun Liu,et al.  Mouse and human dendritic cell subtypes , 2002, Nature Reviews Immunology.

[41]  Antonio Lanzavecchia,et al.  Specialization and complementarity in microbial molecule recognition by human myeloid and plasmacytoid dendritic cells , 2001, European journal of immunology.

[42]  V. Hornung,et al.  Identification of CpG oligonucleotide sequences with high induction of IFN‐α/β in plasmacytoid dendritic cells , 2001 .

[43]  P. Hertzog,et al.  Differential Production of IL-12, IFN-α, and IFN-γ by Mouse Dendritic Cell Subsets1 , 2001, The Journal of Immunology.

[44]  N. Kadowaki,et al.  Distinct CpG DNA and Polyinosinic-Polycytidylic Acid Double-Stranded RNA, Respectively, Stimulate CD11c− Type 2 Dendritic Cell Precursors and CD11c+ Dendritic Cells to Produce Type I IFN1 , 2001, The Journal of Immunology.

[45]  M. Ernst,et al.  Identification of a novel dendritic cell‐like subset of CD64+ / CD16+ blood monocytes , 2001, European journal of immunology.

[46]  S. Miltenyi,et al.  BDCA-2, BDCA-3, and BDCA-4: Three Markers for Distinct Subsets of Dendritic Cells in Human Peripheral Blood , 2000, The Journal of Immunology.

[47]  A. Sher,et al.  CD40 triggering of heterodimeric IL-12 p70 production by dendritic cells in vivo requires a microbial priming signal. , 2000, Immunity.

[48]  T. Luft,et al.  Interleukin (Il)-4 Is a Major Regulatory Cytokine Governing Bioactive IL-12 Production by Mouse and Human Dendritic Cells , 2000, The Journal of experimental medicine.

[49]  P. Martiat,et al.  Freezing of dendritic cells, generated from cryopreserved leukaphereses, does not influence their ability to induce antigen-specific immune responses or functionally react to maturation stimuli. , 2000, Journal of immunological methods.

[50]  W. Nockher,et al.  CD 14++ Monocytes, CD14+/CD16+ Subset and Soluble CD14 as Biological Markers of Inflammatory Systemic Diseases and Monitoring Immuno-suppressive Therapy , 1999, Clinical chemistry and laboratory medicine.

[51]  P. Kalinski,et al.  High-level IL-12 production by human dendritic cells requires two signals. , 1998, International immunology.

[52]  K. Nadeau,et al.  Effects of explosive brain death on cytokine activation of peripheral organs in the rat. , 1998, Transplantation.

[53]  G. Fingerle-Rowson,et al.  Selective depletion of CD14+ CD16+ monocytes by glucocorticoid therapy , 1998, Clinical and experimental immunology.

[54]  A. Sher,et al.  In Vivo Microbial Stimulation Induces Rapid CD40 Ligand–independent Production of Interleukin 12 by Dendritic Cells and their Redistribution to T Cell Areas , 1997, The Journal of experimental medicine.

[55]  P. De Baetselier,et al.  Regulation of Dendritic Cell Numbers and Maturation by Lipopolysaccharide in Vivo , 1996 .

[56]  M. Israel,et al.  Id2 expression increases with differentiation of human myeloid cells. , 1996, Blood.

[57]  F. Sallusto,et al.  Efficient presentation of soluble antigen by cultured human dendritic cells is maintained by granulocyte/macrophage colony-stimulating factor plus interleukin 4 and downregulated by tumor necrosis factor alpha , 1994, The Journal of experimental medicine.

[58]  A. McMichael,et al.  Cytotoxic T lymphocytes recognize a fragment of influenza virus matrix protein in association with HLA-A2 , 1987, Nature.

[59]  P. Macdonald,et al.  Organ preservation. , 2006, Methods in molecular biology.

[60]  Li Wu,et al.  Mouse Plasmacytoid Cells: Long-lived Cells, Heterogeneous in Surface Phenotype and Function, that Differentiate Into CD8 (cid:2) Dendritic Cells Only after Microbial Stimulus , 2002 .