http://repub.eur.nl/res/aut/4575/ List of Publications en http://repub.eur.nl/static-eur/img/logo.png http://repub.eur.nl http://repub.eur.nl/res/pub/16749/ 2009-09-01T00:00:00Z Type 1 diabetes (T1D) is an autoimmune disease in which a T-cell-mediated attack destroys the insulin-producing cells of the pancreatic islets. Despite insulin supplementation severe complications ask for novel treatments that aim at cure or delay of the onset of the disease. In spontaneous animal models for diabetes like the nonobese diabetic (NOD) mouse, distinct steps in the pathogenesis of the disease can be distinguished. In the past 10 years it became evident that DC and macrophages play an important role in all three phases of the pathogenesis of T1D. In phase 1, dendritic cells (DC) and macrophages accumulate at the islet edges. In phase 2, DC and macrophages are involved in the activation of autoreactive T cells that accumulate in the pancreas. In the third phase the islets are invaded by macrophages, DC and NK cells followed by the destruction of the beta-cells. Recent data suggest a role for a new member of the DC family: the plasmacytoid DC (pDC). pDC have been found to induce tolerance in experimental models of asthma. Several studies in humans and the NOD mouse support a similar role for pDC in diabetes. Mechanisms found to be involved in tolerance induction by pDC are inhibition of effector T cells, induction of regulatory T cells, production of cytokines and indoleamine 2,3-dioxygenase (IDO). The exact mechanism of tolerance induction by pDC in diabetes remains to be established but the intrinsic tolerogenic properties of pDC provide a promising, yet underestimated target for therapeutic intervention. http://repub.eur.nl/res/pub/19345/ 2009-01-15T00:00:00Z Canonical Wnt signaling has been implicated in various aspects of hematopoiesis. Its role is controversial due to different outcomes between various inducible Wnt-signaling loss-of-function models and also compared with gain-of-function systems. We therefore studied a mouse deficient for a Wnt gene that seemed to play a nonredundant role in hematopoiesis. Mice lacking Wnt3a die prenatally around embryonic day (E) 12.5, allowing fetal hematopoiesis to be studied using in vitro assays and transplantation into irradiated recipient mice. Here we show that Wnt3a deficiency leads to a reduction in the numbers of hematopoietic stem cells (HSCs) and progenitor cells in the fetal liver (FL) and to severely reduced reconstitution capacity as measured in secondary transplantation assays. This deficiency is irreversible and cannot be restored by transplantation into Wnt3a competent mice. The impaired long-term repopulation capacity of Wnt3a-/- HSCs could not be explained by altered cell cycle or survival of primitive progenitors. Moreover, Wnt3a deficiency affected myeloid but not B-lymphoid development at the progenitor level, and affected immature thymocyte differentiation. Our results show that Wnt3a signaling not only provides proliferative stimuli, such as for immature thymocytes, but also regulates cell fate decisions of HSC during hematopoiesis. http://repub.eur.nl/res/pub/35201/ 2007-09-15T00:00:00Z Dendritic cells are key initiators and regulators of the immune response. Dendritic cell commitment and function require orchestrated regulation of transcription. Gata1 is a transcription factor expressed in several hematopoietic lineages. However, Gata1 function has not been explored in the monocytic or dendritic cell compartment. Here, we show that Gata1 is expressed in myeloid and plasmacytoid dendritic cells and that Gata1 ablation affects the survival of dendritic cells. Furthermore, lipopolysaccharide (LPS) stimulation of dendritic cells prompts Gata1 up-regulation, which is accompanied by increased levels of BclX and Ifng. Our findings show that Gata1 is a transcriptional regulator of dendritic cell differentiation and suggest that Gata1 is involved in the dendritic cell and macrophage lineage separation. http://repub.eur.nl/res/pub/13644/ 2005-04-01T00:00:00Z Dendritic cells (DC) and macrophages (Mphi) are present in high numbers in the pancreas of the non-obese diabetic (NOD) mouse during the diabetogenic process from very early stages onwards. In this study, we used clodronate-loaded liposomes to mediate the temporary systemic depletion of these phagocytic cells and monocytic precursors in order to modulate the pancreatic inflammation. Two intraperitoneal injections given with a 2-day interval to 8-week-old NOD mice depleted monocytes from the circulation and monocytes, DC and Mphi from the spleen within the first days after the injections. Monocytes, DC and Mphi reappeared in the circulation and the spleen within one week and had an unchanged phenotype and antigen presenting function. Interestingly, this treatment caused a delayed disappearance (7-21 days postinjection) of DC and Mphi from the endocrine pancreas at a time when monocytes, DC and Mphi had already repopulated the circulation and the spleen. The depletion of DC and Mphi from the endocrine pancreas was accompanied by a total disappearance of lymphocytes from the pancreas. DC, Mphi and lymphocytes reappeared in the pancreatic inflammatory infiltrates in treated mice from 28 days postdepletion onwards. Importantly, the treatment significantly postponed the onset of diabetes, leading to a strongly decreased incidence by 35 weeks of age. Taken together, our data show an essential role of phagocytic cells, that is, DC and Mphi, in the recruitment of lymphocytes to the pancreatic islets in NOD mice. http://repub.eur.nl/res/pub/7348/ 2004-11-03T00:00:00Z Immune system protects us from harmful microbes and tumor development. At the same time, the immune system makes sure that the unnecessary immune reaction against harmless foreign substances (known as antigens) or self-originating structures (self-antigens) either does not occur or is stopped before it induces irreparable damage to a healthy organ. Therefore, the immune system is able to make a distinction between the “dangerous” and the “harmless” irrespective of its origin. If a “dangerous” is encountered, defense mechanisms are activated that generate an inflammation. Elimination of the inflammation inducers leads to a deceleration of inflammation and a wound healing, which is actively regulated. The response against harmless antigens (either foreign or self) is also actively suppressed and is called tolerance. The mechanisms utilized for the controlled activation and inhibition of the inflammation and for the tolerance acquisition enable the balanced function of the immune system, called immune regulation. In some situations the immune regulation can be disturbed and the immune system starts to destroy healthy cells leading to an irreparable damage. This action of the immune system is called an autoimmune reaction and as a consequence an autoimmune disease develops. Such a process directed against b-cells in the islets of Langerhans in the pancreas leads to the autoimmune disease termed type 1 diabetes (also known as a sugar disease). Macrophages (Mf) and dendritic cells (DC) importantly contribute to the proper function of the immune system. These two cell types comprise a heterogeneous group of cells called mononuclear phagocytes, which differ in the phenotype, function or the origin. They are sentinels that reside in all organs and are the first that encounter the infectious agents, transformed cells, or some other harmful substances. As an immediate reaction, they activate the inborn immunity and start an inflammatory reaction that subsequently leads to the activation of other immune forces. Later, they also mediate the reduction of the inflammation and help the wound healing. In addition, they are also important for the activation of the specific immune forces (including tolerance): DC take up the antigen, present it to other cells of the immune system and transduce a signal whether that antigen should be destroyed or ignored. Taken together, mononuclear phagocytes can perform several different function and enable a balanced function of the immune system, called homeostasis. http://repub.eur.nl/res/pub/10359/ 2004-01-01T00:00:00Z The NOD mouse spontaneously develops autoimmune diabetes. Dendritic cells (DC) play a crucial role in the autoimmune response. Previous studies have reported a defective DC generation in vitro from the NOD mouse bone marrow (BM), but a deviated development of myeloid precursors into non-DC in response to GM-CSF was not considered. In this study, we demonstrate several abnormalities during myeloid differentiation of NOD BM precursors using GM-CSF in vitro. 1) We found reduced proliferation and increased cell death in NOD cultures, which explain the previously reported low yield of DC progeny in NOD. Cell yield in NOR cultures was normal. 2) In a detailed analysis GM-CSF-stimulated cultures, we observed in both NOD and NOR mice an increased frequency of macrophages, identified as CD11c(+)/MHCII(-) cells with typical macrophage morphology, phenotype, and acid phosphatase activity. This points to a preferential maturation of BM precursors into macrophages in mice with the NOD background. 3) The few CD11c(+)/MHCII(high) cells that we obtained from NOD and NOR cultures, which resembled prototypic mature DC, appeared to be defective in stimulating allogeneic T cells. These DC had also strong acid phosphatase activity and elevated expression of monocyte/macrophage markers. In conclusion, in this study we describe a deviated development of myeloid BM precursors of NOD and NOR mice into macrophages and macrophage-like DC in vitro. Potentially, these anomalies contribute to the dysfunctional regulation of tolerance in NOD mice yet are insufficient to induce autoimmune diabetes because they occurred partly in NOR mice. http://repub.eur.nl/res/pub/10120/ 2003-01-01T00:00:00Z The lineage relationship of dendritic cells (DC) with other hematopoietic cell types has been studied extensively, resulting in the identification of different bone marrow (BM) progenitors that give rise to distinct DC types. However, the identity of the different maturation stages of DC precursors in the BM remains unclear. In this study we define the in vivo developmental steps of the myeloid DC lineage in mouse BM. To this end, BM cells were separated according to their expression of CD31 (ER-MP12), Ly-6C (ER-MP20) and ER-MP58 antigens, and stimulated to develop into myeloid DC, using granulocyte macrophage colony stimulating factor as a specific growth factor. DC developed from three BM subpopulations: ER-MP12(hi)/20(-) (early blast cells), ER-MP12(+)/20(+) (myeloid blasts) and ER-MP12(-)/20(hi) (monocytes). The kinetic and phenotypic features of DC developing in vitro indicate that the three populations represent successive maturation stages of myeloid DC precursors. Within the earliest ER-MP12(hi)/20(-) population, DC precursors exclusively occurred in the myeloid-restricted ER-MP58(hi) subset. By using switch cultures, we show that these BM precursor subpopulations, when stimulated to develop into macrophages using macrophage colony stimulating factor, retain the ability to develop into myeloid DC until advanced stages of maturation. Together, these findings support a common ER-MP12/20-defined differentiation pathway for both macrophages and myeloid DC throughout their BM development.