Hans-Georg Fischer

Brain Dendritic Cells and Macrophages/Microglia in Central Nervous System Inflammation

Microglia subpopulations were studied in mouse experimental autoimmune encephalomyelitis and toxoplasmic encephalitis. CNS inflammation was associated with the proliferation of CD11b+ brain cells that exhibited the dendritic cell (DC) marker CD11c. These cells constituted up to 30% of the total CD11b+ brain cell population. In both diseases CD11c+ brain cells displayed the surface phenotype of myeloid DC and resided at perivascular and intraparenchymatic inflammatory sites. By lacking prominent phagocytic organelles, CD11c+ cells from inflamed brain proved distinct from other microglia, but strikingly resembled bone marrow-derived DC and thus were identified as DC. This brain DC population comprised cells strongly secreting IL-12p70, whereas coisolated CD11c− microglia/brain macrophages predominantly produced TNF-α, GM-CSF, and NO. In comparison, the DC were more potent stimulators of naive or allogeneic T cell proliferation. Both DC and CD11c− microglia/macrophages from inflamed brain primed naive T cells from DO11.10 TCR transgenic mice for production of Th1 cytokines IFN-γ and IL-2. Resting microglia that had been purified from normal adult brain generated immature DC upon exposure to GM-CSF, while CD40 ligation triggered terminal maturation. Consistently, a functional maturation of brain DC was observed to occur following the onset of encephalitis. In conclusion, these findings indicate that in addition to inflammatory macrophage-like brain cells, intraparenchymatical DC exist in autoimmune and infectious encephalitis. These DC functionally mature upon disease onset and can differentiate from resident microglia. Their emergence, maturation, and prolonged activity within the brain might contribute to the chronicity of intracerebral Th1 responses.

Phenotype and Functions of Brain Dendritic Cells Emerging During Chronic Infection of Mice with Toxoplasma gondii

During chronic infection of mice with Toxoplasma gondii, gene message for IL-12p40, CD86, and the potassium channel Kv1.3 was detected in brain mononuclear cells, suggesting the presence of dendritic cells (DC) in the CNS. Consistently, cells bearing the DC markers CD11c and 33D1 were localized at inflammatory sites in the infected brain. The number of isolated CD11c+ brain cells increased until peak inflammation. The cells exhibited the surface phenotype of myeloid DC by coexpressing 33D1 and F4/80, little DEC-205, and no CD8α. These brain DC were mature, as indicated by high-level expression of MHC class II, CD40, CD54, CD80, and CD86. They triggered Ag-specific and primary allogeneic T cell responses at very low APC/T cell ratios. Among mononuclear cells from encephalitic brain, DC were the main producers of IL-12. Evidence for a parasite-dependent development of DC from CNS progenitors was obtained in vitro: after inoculation of primary brain cell culture with T. gondii, IL-12-secreting dendriform cells emerged, and DC marker genes were expressed. Different stimuli elicited the generation and maturation of brain DC: neutralization of parasite-induced GM-CSF prevented outgrowth of dendriform cells and concomitant release of IL-12. IL-12 production was up-regulated by external IFN-γ but was stopped by inhibiting parasite replication. Consistently, DC isolated from GM-CSF-treated brain cell culture were activated to secrete IL-12 by exposure to parasite lysate. In sum, these results demonstrate T. gondii-induced expansion and functional maturation of DC in the CNS and, thus, highlight a mechanism that may contribute to the chronicity of the host response.

GRA7, an excretory 29 kDa Toxoplasma gondii dense granule antigen released by infected host cells

Monoclonal antibody (mAb) TxE2, reactive with Toxoplasma gondii excretory products, detects an acidic 29 kDa protein (p29) which, in 2D gel electrophoresis, exhibits a migration pattern distinct from those of the toxoplasmic excretory proteins described so far. The sequence of seven peptides from tryptic digestion of isolated p29 allowed the design of primers to obtain the coding DNA sequence. The full-length gene was amplified from genomic DNA of T. gondii strain BK and the sequence was identical with that of the corresponding cDNA, providing evidence for an intron-free gene structure. A single mRNA transcript of 1.3 kb was detected by Northern blot analysis. The deduced 236 amino acid protein contains a putative N-terminal signal peptide, one site of potential N-linked glycosylation, and, close to the C-terminus, a further hydrophobic, putative transmembrane domain. With synthetic peptides spanning the sequence of p29, the epitope for mAb TxE2 was mapped adjacent to the putative signal sequence. The antigen, which represents almost 0.5% of T. gondii protein, is expressed in strains of all three intraspecies subgroups, and is associated with the parasite dense granules as demonstrated by immunoelectron microscopy. In tachyzoite-infected cells, p29 accumulates within the parasitophorous vacuole and co-localizes with its delimiting membrane. In bradyzoite-infected cells, p29 is present within the host cell cytoplasm as detected by immunofluorescence staining, and, furthermore, in the supernatant of cyst-bearing cell culture lacking extracellular parasites as shown by enzyme-linked immunosorbent assay (ELISA). Thus, p29 which is named dense granule protein (GRA)7 may indicate the presence of intracellular toxoplasma.

Dendritic cells and dendritic-like microglia in focal cortical ischemia of the mouse brain.

Intracerebral dendritic cells (DC) have recently been identified in neuroinflammation initiated peripherally by brain-targeted autoimmunity or infection. The present study detects DC in photochemically induced cortical ischemia of the mouse brain, a brain-intrinsic lesion model characterized by the lack of an overt T cell response. Concomitant to leukocyte infiltration of the infarcted area, cells expressing the pan-DC surface marker CD11c appeared at the lesion and persisted for weeks. These DC were located at the border zone of the infarct and remote from the lesion in degenerating corticothalamic fibre tracts and subcortical nuclei. All CD11c+ brain cells displayed a uniform CD11b+/CD8alpha-/CD205- surface phenotype, indicating a myeloid origin, and were immature DC based on their MHC class II+/CD40-/CD80+/CD86+/- profile. By expressing high levels of CD45, most DC from ischemic brain seemed to be blood-derived while a minority were CD45(low), thus corresponding to resident microglia. Consistently, round-shaped CD11c+ cells were found at the lesion whereas CD11c+ cells at subcortical sites were ramified like parenchymal microglia. These findings evidence a recruitment of myeloid DC to ischemic brain lesions and suggest that reactive microglia in remote areas transform into dendritic-like cells. Brain-infiltrating DC and their microglial counterparts may play a role in the inflammatory response to cerebral ischemia independently of T cells.

Cytokine-dependent K+ channel profile of microglia at immunologically defined functional states

Microglia were enriched in brain cell cultures from newborn mice as a result of supplementation with the growth factors macrophage colony-stimulating factor or granulocyte/macrophage colony-stimulating factor. When separately administered these two cytokines promote the outgrowth of loosely adherent cells with similar morphology which stained positive for CD11b and nonspecific esterase. Microglial cells isolated from both types of culture were electrophysiologically characterized using the whole cell configuration of the patch-clamp technique. Different resting membrane potentials were measured. In response to hyperpolarizing and depolarizing voltage commands 68 of 91 macrophage colony-stimulating factor-cultured microglial cells exhibited only an inward rectifying potassium current. By contrast, an outward potassium current was observed on 71 of 95 granulocyte/macrophage colony-stimulating factor-grown cells. Parallel testing of their capability for antigen presentation proved the activated functional state of these microglial cells. They induce antigen-specific T cell response without prior stimulus. In comparison, cells developed with macrophage colony-stimulating factor failed to present antigen. In such resting microglia a short-term treatment with granulocyte/macrophage colony-stimulating factor or interferon-gamma provoked a strong appearance of outward potassium currents, however, only the interferon-gamma-trigger resulted in efficient antigen presentation. The differential induction of both functional parameters suggests the detection of outward potassium currents to provide an electrophysiological activation marker of microglia which is subjected to cytokine regulation but not compellingly linked to antigen presentation.

Differentiation driven by granulocyte-macrophage colony-stimulating factor endows microglia with interferon-γ-independent antigen presentation function

The antigen presentation function of microglial cells was analyzed after differentiation in neonatal mouse brain cell cultures supplemented either with macrophage (M) or granulocyte/macrophage (GM) colony-stimulating factor (CSF). The cells separated from concomitant astrocytes in both culture systems turned out to exhibit cytological characteristics of macrophages and bore MAC-1 and F4/80 markers in a similar way. When comparatively tested for accessory cell function, only microglia developed with GM-CSF were able to efficiently induce antigen-directed proliferation of a series of helper T cell lines representing both the TH1 and TH2 subtype. Antigenic T cell activation by this microglia population was performed without prior stimulation and exceeded that of M-CSF-dependently grown microglial cells, even if those had been pretreated with interferon-gamma (IFN-gamma). In contrast to such difference in function, low cell surface expression of MHC class II or intercellular adhesion molecule-1 determinants proved to coincide in both populations. Correlating with the capacity for antigen presentation, expression of membrane-bound interleukin-1 (IL1)--a costimulatory signal for TH2 cells--was augmented significantly in GM-CSF-grown microglia. In parallel, the interaction only of this microglia population with a selected TH1 cell line was accompanied by maximal release of T cell-stimulating factor, a cytokine recently identified as an IL1-analogous second signal for TH1 cells. Thus, a developmental process is suggested which produces a form of microglia specialized in antigen presentation and thereby acting uncoupled from IFN-gamma.

Host cells of Toxoplasma gondii encystation in infected primary culture from mouse brain.

Abstract In order to identify brain cell types that serve as host cells of Toxoplasma gondii encystation primary cultures from murine brain were infected and stained for neural and parasite stage-specific markers. In mixed culture inoculated with T. gondii tachyzoites, MAP2+ neurons, GFAP+ astrocytes, F4/80+ microglia, and O1+ oligodendrocytes proved to be infected as detected by parallel labeling of SAG1. At 4 days following infection with bradyzoites, cysts developed in neuronal, astroglial, and microglial host cells as clarified using bradyzoite-specific antibody 4F8. Additional staining of SAG1 revealed that astrocytes in bradyzoite-infected brain cell culture can also harbor tachyzoite-containing vacuoles. Stage conversion was observed shortly after inoculation and was accompanied by an increase in parasite proliferation. However, tachyzoites became rare in prolonged culture. By contrast, the numbers of cysts and of the bradyzoites isolated multiplied during long-term culture. These findings demonstrate that both glial and neuronal host cells allow T. gondii encystation in the absence of T cell-derived cytokines and imply that a brain-internal spreading of bradyzoites may sustain chronic infection.

Induction of toxoplasmostasis in a human glioblastoma by interferon γ

In the course of human toxoplasmosis central nervous system involvement often occurs. As a model for toxoplasma growth within human brain cells the proliferation of Toxoplasma gondii strain BK within the human glioblastoma cell line 86HG39 was analysed. We found that 86HG39 cells support the growth of toxoplasma similar to human monocyte derived macrophages and in contrast to human monocytes. The growth of Toxoplasma gondii within interferon gamma (IFN gamma) treated 86HG39 cells is reduced due to toxoplasmostasis and not due to toxoplasmocide effects. The mechanism of IFN gamma induced toxoplasmostasis was also investigated. It was found that IFN gamma did not induce O2- production and/or nitrite oxide production, and inhibitors of O2- and NO2- did not influence IFN gamma induced toxoplasmostasis. In contrast, the supplementation of L-tryptophan to the culture medium completely abolished the IFN gamma effect. We therefore conclude that the induction of L-tryptophan degradation in 86HG39 cells by IFN gamma, possibly by activation of the indoleamine-2,3-dioxygenase, is responsible for the IFN gamma induced toxoplasmostasis within the glioblastoma cell line.

Characterization of TgROP9 (p36), a novel rhoptry protein of Toxoplasma gondii tachyzoites identified by T cell clone ☆

T cell clone 3Tx19 detects a Toxoplasma gondii tachyzoite protein which, in high resolution 2D gel electrophoresis, runs at 36 kDa apparent MW with two spots of pI 5.9 and 6.5, thus exhibiting a migration pattern distinct from those of other known Toxoplasma antigens. The sequences of peptide fragments from tryptic digestion of the more prominent protein spot allowed the design of oligonucleotide primers to obtain the coding cDNA sequence. Sequence analysis of cDNA from strain BK revealed a 363 amino acid open reading frame, defined by all nine peptide sequences determined. The deduced protein sequence contains two hydrophobic segments, one near the N-terminus including a predicted signal peptide and a shorter second at the carboxy terminus, but homology to any other known protein is lacking. With synthetic peptides covering the complete primary structure, the epitope for clone 3Tx19 was mapped within the deduced partial sequence, which had remained unconfirmed by tryptic peptides. Antibodies raised against another, putative B cell epitope peptide detected the same two protein spots in 2D gel, indicating that they are antigenically related isoforms. The protein p36 is expressed by T. gondii isolates of all three intraspecies subgroups, but not in the bradyzoite stage. In intracellular tachyzoites, p36 colocalizes with rhoptry proteins and has a distribution pattern disparate from that of dense granule and microneme proteins. Subcellular fractionation indicated that p36 is a soluble constituent of tachyzoites. We suggest that this T cell-stimulatory novel rhoptry protein of T. gondii be named ROP9. It represents a marker of the tachyzoite stage.

Expression variance, biochemical and immunological properties of Toxoplasma gondii dense granule protein GRA7.

During intracellular stay, Toxoplasma gondii secretes dense granule proteins (GRA) which remodel the parasitophorous vacuole and are considered functional in parasite-host interrelation. Comparative analysis of parasites from mouse-virulent strain BK and an in vitro attenuated variant revealed that the level of GRA7 expression correlates with T. gondii virulence: proteome analysis and quantitation by immunoblot demonstrated a massive decrease in GRA7 steady-state synthesis parallel to the loss of virulence. Properties of GRA7 that are pertinent to its membrane targeting and to GRA7-directed immune resistance were studied in detail. GRA7 is exclusively membrane-associated in both parasites and infected host cells as demonstrated by subcellular fractionations. Triton X-114 partitioning of isolated parasites substantiated that GRA7 is an integral membrane protein, the hydrophobic stretch from amino acid 181 to 202 providing a possible membrane anchor. A fraction enriched for membranous material from infected host cells contained additional forms of GRA7 with reduced mobility in gel electrophoresis, indicating that the protein is modified after exocytosis from the parasite. By flow cytometric analysis, GRA7 was detected on the surface of intact host cells. An intracellular origin of surface-associated GRA7 seems likely since GRA7 released from extracellular parasites failed to label the host cell surface. Consistent with a role at a parasite-host interface, GRA7 proved to be a target antigen of the intracerebral immune response as evidenced by the presence of GRA7-specific antibodies in mouse cerebrospinal fluid during chronic infection.