Immunogeneic Cell Populations of the Skin / Pattern of Dendritic Cells and T Cells in Healthy Skin and in Skin of Patients During Allogeneic Hematopoietic Stem Cell Transplantation

Eger, Lars

17 June 2008

Dendritic cells (DCs), a hematopoietic cell type belonging to the sub-group of cells called antigen presenting cells (APCs), inhabit a central role in innate and adaptive immunity. Although the DC family is very heterogeneous, all members share unique features. Most importantly, DCs can stimulate an immune response. This is due to the cells’ ability to capture and process antigens and to maturate in the presence of danger signals presented by pathogens. Maturation in turn results in the migration of DCs from the tissue they reside in to the draining lymph nodes, as well as in the subsequent presentation of the acquired antigens to T cells. In the skin, which is one of the most immunogeneic organs, DCs are present in sizable numbers in both the epidermis and the dermis. This study focused on two types of DCs: epidermal Langerhans cells (LCs) and dermal DCs (DDCs). While much is understood about LCs, far less is known about the role that DDCs play in skin immunity. Therefore one purpose of this study was to characterize DDCs and to compare their phenotype and functions to that of LCs. This study used two different methods to characterize human skin resident immune cells with regard to their number and distribution. First, a stable analytical immunohistochemistry-based method was developed and applied to a substantial number of healthy skin donors. This enabled a quantitative analysis of skin DC types and skin resident T cells at different anatomical locations in situ. A novel method to count dermal cell populations in situ was developed that resulted in the first published quantification of APCs, DDCs, as well as T cells in human dermis. Second, the traditional form of the emigration assay, which selectively enriches vital cells capable of ex vivo emigration from the skin, was upgraded toward a stable analytical method to separate epidermal LCs from DDCs. In this way, both skin DC types became accessible in sufficient numbers to allow for a comparison of phenotypes and functions in vitro. The resulting phenotypic observations clearly showed that both, LCs and DDCs are not fully mature after their emigration ex vivo and that both can be transformed into a phenotypically more mature state by treating them with inflammatory cytokines. What’s more, LCs are also functionally in an immature state after their emigration. They efficiently took up antigen, showed a low capacity to trans-migrate in response to chemokines, and demonstrated a low capacity to stimulate allogeneic T cells in a mixed leukocyte reaction (MLR). For the first time this study observed all these main APC functions not only for LCs but additionally for DDCs. As these observations were made in relation to LCs of the same donor, it could be concluded that DDCs are functionally more mature than LCs after emigration. DDCs showed a lower antigen uptake capacity than LCs but were superior in terms of their migratory and stimulatory capacity. However, treatment with cytokines could skew LC functions toward functional capacities observed for DDCs, i.e., it decreased LCs’ Ag uptake and increased their migratory and stimulatory capacity, whereas the cytokine treatment did not alter DDCs’ functional capacities. After improving immuno-histochemistry and the emigration assay using healthy skin samples, these newly developed techniques were implemented in clinical trials to observe the number, distribution and migratory capacity of skin DCs and T cells in patients undergoing allogeneic hematopoietic cell transplantation (aHSCT). Such a study is of importance because the turnover of DCs and T cells is closely associated with the occurrence of acute graft-versus-host disease (aGvHD), the major cause of morbidity and mortality after aHSCT. Due to the study design used, this study concisely demonstrate that at the onset of aGvHD, different DC types accumulate along with effector T cells in skin lesions of aGvHD but not in uninvolved skin of the same patient. These results suggest that in addition to donor T cells LCs and DDCs play a role during the early phase of cutaneous aGvHD directly within the site of inflammation. The view of many authors that DC depletion in the transplant recipient, especially in target organs, is a promising approach for aGvHD prophylaxis and therapy is further underscored by these results. One targeting strategy to inhibit GvHD by eliminating recipient DCs may be the use of DC specific monoclonal antibodies. Alemtuzumab (anti-CD52) is a monoclonal antibody and has proven effective in preventing aGvHD after aHSCT. It may, despite depleting donor T cells, also work by targeting recipient DCs. To determine whether the last mechanism of action is significant, a second clinical study investigated the effects of intravenous alemtuzumab on DCs by comparing the number of these cells in skin and blood of patients before and after a 4-week course of alemtuzumab treatment. The result was that although skin DCs weakly express the target antigen CD52 the number of these cells was not consistently reduced by alemtuzumab. In contrast, circulating blood DCs have a stronger CD52 expression and were significantly reduced by the treatment. In conclusion, this work provides new insights into the phenotypical and functional characteristics of human skin DCs, as well as into the fate of these cell types during aHSCT. The investigation of the APC system during aGvHD as carried out here will help to understand the process of aGvHD in more detail. All these efforts may hopefully support the development of new approaches for therapy and prevention of this major limitation of aHSCT and may help to improve this only curative therapy for several life-threatening diseases.

dendritic cell

Langerhans cell

dermal dendritic cell

bone marrow transplantation

graft versus host disease

allogeneic

dendritsche Zelle

Langerhans Zelle

dermal dendritische Zelle

Knochenmarkstransplantation

Transplantat gegen Wirt Reaktion

ddc:570

rvk:WF 9890

Die funktionelle Modifikation der proinflammatorischen M-DC8+ dendritischen Zellen durch zyklisches Adenosin-Monophosphat / Functional modification of the proinflammatory M-DC8+ dendritic cells by cyclic adenosine monophosphate

Ebling, Annette

23 June 2005

In this work, the influence of the second messenger cAMP on the functional plasticity of M-DC8+ dendritic cells (DC) was examined. The marker M-DC8 defines a population of native DC first described in blood. After their isolation, M-DC8+ DC acquire a mature CD83+ phenotype during a short culture ex vivo. After a challenge with LPS and IFN-g, M-DC8+ DC secrete large amounts of the proinflammatory cytokines IL-12(p70) and TNF-a surpassing by far other DC populations and monocytes. Due to their preferential induction of TH1-dominated T cell responses, M-DC8+ DC might play a role in the pathogenesis of inflammatory diseases. Different cAMP-elevating agents suppressed the proinflammatory cytokine production and enhanced the secretion of anti-inflammatory IL-10. Activity of phosphodiesterase (PDE) 4, the most important cAMP-hydrolysing enzyme in immune cells, was detected and RT-PCR revealed the expression of PDE4 subtypes 4A, 4B and 4D in M-DC8+ DC, whereas 4C was not detectable. The PDE4-specific inhibitors AWD12-281 and Roflumilast were then used to elevate cAMP concentrations. These substances have been proven to be efficient in anti-inflammatory therapies. In the presence of PDE4 inhibitors, the LPS/IFN-g-induced production of IL-12 and TNF-a was decreased by 90 % and 60 %, respectively, whereas the IL-10-release was doubled. These effects were only observed, if the PDE4 inhibitors where present from the beginning of the culture. The inhibition of the IL-12 secretion was reverted using an a-IL-10-receptor antibody. PDE4 inhibitor-treated M-DC8+ DC showed a reduced capacity to polarize TH1-cells, which was demonstrated analysing culture supernatants by ELISA and by single-cell analysis detecting intracellular IFN-g und IL-4. These results suggest that PDE4 inhibitors may not only be useful in the therapy of TH2-mediated diseases but also in TH1-dominated indications such as multiple sclerosis and Crohn´s disease. Despite the shift of the cytokine profile, the in vitro maturation of M-DC8+ DC was not affected by PDE4 inhibitors. The expression of CD83, CD80, CD86, MHC-molecules as well as CD54 and CD58, was assessed by FACS analysis. Correspondingly, in the presence of AWD12-281, M-DC8+ DC efficiently stimulated the proliferation of allogeneic CD4+CD45RA+ T-cells. In the second part of this study, the effects of an inhibition of cAMP-synthesis in M-DC8+ DC were analyzed. Two adenylyl cyclase (AC) inhibitors, 2,5-Dideoxyadenosine and SQ22536, clearly hampered the in vitro maturation of M-DC8+ DC. The expression of the DC maturation marker CD83 could be reconstituted using the stable cAMP-analogon 8-Br-cAMP. Measuring the intracellular cAMP concentration in M-DC8+ DC, initially low cAMP-levels were observed, but within 30 min the concentration raised and returned to original levels within 2 hrs. Blocking the cAMP synthesis by AC inhibitors, the LPS/IFN-g-induced production of IL-12, TNF-a and IL-10 was strongly reduced. Furthermore, it was demonstrated that M-DC8+ DC can only release IL-12 after a transient elevation of cAMP, i.e. they acquire a "license". Such a regulation of the IL-12 production has not been described before. Protein kinase A is an important effector molecule of cAMP. Inhibiting its activity resulted in a reduced expression of the DC maturation marker CD83 and a lower cytokine production underlining the importance of cAMP-signalling for the activation of M-DC8+ DC. In conclusion, this study provides evidence for a new concept of the immune-regulatory function of cAMP. Here, cAMP is essentially involved in the initial activation and maturation of DC and enables them to secrete large amounts of IL-12 and TNF-a upon stimulation with a TLR ligand. Conversely, a long-term elevation of cAMP-concentrations inhibits the proinflammatory effector functions of M-DC8+ DC and can induce anti-inflammatory responses by enhancing the secretion of IL-10. / In dieser Arbeit wurde der Einfluss des second messengers cAMP auf die funktionelle Plastizität von M-DC8+ dendritischen Zellen (DC) untersucht. Der Oberflächenmarker M-DC8 definiert eine zunächst im Blut beschriebene Population nativer DC. Nach ihrer Isolation erlangen M-DC8+ DC während einer kurzen Kultur einen maturen CD83+ Phänotyp. Nach Stimulation mit LPS und IFN-g produzieren native M-DC8+ DC deutlich höhere Mengen der proinflammatorischen Zytokine IL-12(p70) und TNF-a als andere DC-Populationen oder Monozyten. Dies resultiert in einer Programmierung TH1-dominierter T-Zellantworten. M-DC8+ DC könnten daher an der Pathogenese entzündlicher Krankheiten beteiligt sein. Unterschiedliche cAMP-erhöhende Substanzen supprimierten die proinflammatorische Zytokinproduktion und verstärkten gleichzeitig die Sekretion des anti-inflammatorischen IL-10. In M-DC8+ DC konnte die Aktivität von Phosphodiesterase (PDE) 4, dem wichtigsten cAMP-hydrolysierenden Enzym in Immunzellen, nachgewiesen werden. Durch RT-PCR wurde die Expression der PDE4-Subtypen 4A, 4B und 4D gezeigt, nicht aber 4C. Zur Erhöhung der cAMP-Konzentration wurden dann die PDE4-spezifischen Inhibitoren AWD12-281 und Roflumilast eingesetzt, deren klinische Effizienz bei anti-inflammatorischen Therapien belegt ist. Auch diese Substanzen verringerten die LPS/IFN-g-induzierte Produktion von IL-12 und TNF-a durch M-DC8+ DC um 90 % bzw. 60 %, während die IL-10-Freisetzung etwa verdoppelt wurde. Diese starken Effekte konnten nur erzielt werden, wenn die PDE4-Inhibitoren von Beginn der Kultur an eingesetzt wurden. Die Hemmung der IL-12-Sekretion wurde in Gegenwart eines a-IL-10-Rezeptor-Antikörpers aufgehoben. Unter dem Einfluss von PDE4-Inhibitoren war die TH1-Programmierung durch M-DC8+ DC deutlich reduziert, was sowohl durch die Analyse der Zellüberstände mittels ELISA als auch auf Einzelzell-Ebene durch intrazelluläre Detektion von IFN-g und IL-4 nachgewiesen wurde. Diese Ergebnisse legen nahe, dass PDE4-Inhibitoren nicht nur für TH2-vermittelte Erkrankungen sondern auch für TH1-dominierte Indikationen wie Multiple Sklerose oder Morbus Crohn von Nutzen sein könnten. Trotz der starken Modulation des Zytokinprofils blieb die in vitro-Ausreifung M-DC8+ DC unbeeinflusst von PDE4-Inhibitoren. Untersucht wurde die Expression von CD83, CD80, CD86, MHC-Molekülen, CD54 und CD58 mittels FACS-Analyse. Entsprechend induzierten M-DC8+ DC auch in Anwesenheit von AWD12-281 die Proliferation allogener CD4+CD45RA+ T-Zellen. Im zweiten Teil der Arbeit wurde untersucht, wie sich die Blockade der cAMP-Synthese auf M-DC8+ DC auswirkt. Zwei Adenylatcyclase-Inhibitoren, 2,5-Dideoxyadenosine und SQ22536, hemmten die in vitro-Maturation von M-DC8+ DC deutlich. Die CD83-Expression wurde mit 8-Br-cAMP rekonstituiert. Messungen der intrazellulären cAMP-Konzentration in unbehandelten M-DC8+ DC zeigten initial niedrige cAMP-Spiegel, die innerhalb von 30 min anstiegen und nach 2 h wieder auf das Ausgangsniveau abfielen. Die LPS/IFN-g-induzierte Produktion von IL-12, TNF-a und IL-10 wurde durch AC-Inhibitoren deutlich vermindert. M-DC8+ DC erhalten nur nach einer transienten cAMP-Erhöhung die "Lizenz" IL-12 freizusetzen. Eine derartige Regulation der IL-12-Sekretion ist bisher nicht beschrieben. Eine Hemmung des cAMP-Effektormoleküls Proteinkinase A resultierte in der reduzierten Expression des DC-Maturationsmarkers CD83 und einer verringerten Zytokinproduktion. Dies unterstreicht die Bedeutung von cAMP für die Aktivierung M-DC8+ DC. Zusammenfassend gibt diese Arbeit am Beispiel nativer humaner DC Anhalt für ein neues Konzept der immunregulatorischen Funktion von cAMP. Hierbei ist cAMP wesentlich an der Ausreifung von M-DC8+ DC beteiligt, woraufhin diese große Mengen IL-12 und TNF-a sekretieren können. Dagegen wirkt eine langfristige cAMP-Erhöhung durch die Induktion von IL-10 anti-inflammatorisch.

Adenylatcyclase

IL-10

IL-12

Immunregulation

Phosphodiesterase (PDE) 4

T-Zellen

TNF-a

anti-inflammatorisch

cAMP

dendritische Zellen (DC)

IL-10

IL-12

T cells

TNF-a

adenylyl cyclase

anti-inflammatory

cAMP

dendritic cells (DC)

immune regulation

phosphodiesterase (PDE) 4

ddc:171

rvk:WF 9890

Adenylatcyclase

Cyclo-AMP

Cytokine

Entzündung

Immunsystem

Phosphodiesterasen

Regulation

T-Lymphozyt

dendritische Zelle