Murine scrapie infection causes an abnormal germinal centre reaction in the spleen

Follicular dendritic cells (FDCs) of the lymphoreticular system play a role in the peripheral replication of prion proteins in some transmissible spongiform encephalopathies (TSEs), including experimental murine scrapie models. Disease-specific PrP (PrPd) accumulation occurs in association with the plasmalemma and extracellular space around FDC dendrites, but no specific immunological response has yet been reported in animals affected by TSEs. In the present study, morphology (light microscopical and ultrastructural) of secondary lymphoid follicles of the spleen were examined in mice infected with the ME7 strain of scrapie and in uninfected control mice, with or without immunological stimulation with sheep red blood cells (SRBCs), at 70 days post-inoculation or at the terminal stage of disease (268 days). Scrapie infection was associated with hypertrophy of FDC dendrites, increased retention of electron-dense material at the FDC plasma membrane, and increased maturation and numbers of B lymphocytes within secondary follicles. FDC hypertrophy was particularly conspicuous in immune-stimulated ME7-infected mice. The electron-dense material was associated with PrP Napoli accumulation, as determined by immunogold labelling. We hypothesize that immune system changes are associated with increased immune complex trapping by hypertrophic FDCs expressing PrP Napoli molecules at the plasmalemma of dendrites, and that this process is exaggerated by immune system stimulation. Contrary to previous dogma, these results show that a pathological response within the immune system follows scrapie infection.     

Fas ligand expression in the germinal centre.

Whereas the importance of the Fas/FasL system in the regulation of T-cell homeostasis is well established, it is not yet clear if FasL is involved in B-cell regulation, especially in the clonal selection of B lymphocytes in the germinal centre (GC). This study therefore investigated the expression of FasL protein in tonsils and lymph nodes with lymphofollicular hyperplasia by western blotting and immunohistochemistry. In all the samples examined, western blot analysis showed FasL proteins of 33 and 52 kD, which presumably correspond to membrane-bound and soluble forms of the FasL protein. Immunohistochemically, FasL was found in a limited number of cells confined to a cluster in the light zone of the GC. The signal showed a delicate meshwork-like pattern of branching processes enmeshing the centrocytes and the few centroblasts of the light zone. In serial sections, the immunostaining pattern for FasL was found largely to coincide with the CD23 staining of follicular dendritic cells (FDCs), which are typically located in the light zone. In contrast, the FasL signal did not correspond to the distribution of the CD4-positive GC T-cells. In conclusion, expression of FasL in lymphofollicular hyperplasia seems to be largely confined to the light zone of the GCs, where selection of FDC-associated centrocytes is known to occur. These observations thus suggest that FasL is involved in selection processes of the B-cell system.     

Early ontogeny of germinal center formation in the chicken.

Germinal center formation was studied in the spleen of young chickens immunized in ovo and at the time of hatching. When immunization was performed on day 18 in ovo and on the day of hatching, the first germinal centers were observed at 4 days. This is markedly earlier than in unimmunized chickens, where the first germinal centers appear at the age of 10 days or later. Germinal center formation preceded significant antibody production. The possible role of germinal centers in the generation of immunological memory is discussed in the light of these and earlier observations.     

Localization of a protein antigen in the chicken spleen. Effect of various manipulative procedures on the morphogenesis of the germinal centre.

The time course of the localization of a protein antigen human serum albumin (HSA) into the chicken spleen after intravenous injection is analysed. Localization within seconds to the region surrounding the Schweigger-Seidel sheaths is accomplished by HSA complexes with chicken anti-HSA or by heat aggregated HSA. The localization of soluble HSA has to await the synthesis of sufficient chicken anti-HSA to accomplish localization to the same white pulp sites in the spleen at 25-30 hours after injection. By the use of complexes of HSA-anti-HSA in ten times antigen excess, the time for localization of HSA withing germinal centres was accelerated as compared with soluble HSA, so that newly formed centres containing antigen-bearing dendritic ells were seen at 48 hours instead of 72 hours after use of soluble HSA. Neonatally bursectomized and irradiated (Bx+Irr.) birds fail to localize HSA into germinal centres or to dendritic cells within the white pulp. Heat-aggregated human gamma-globulin (HGG) injected intravenously into Bx+Irr. birds rapidly localizes within seconds to the periphery of Schweigger-Seidel sheaths and at 24 hours can be seen attached to the surface of typical dendritic cells throughout the white pulp. Hence, heat-aggregated HGG can localize to dendritic cells in the absence of specific antibody. However, such localization to dendritic cells in Bx+ Irr. birds is not followed by segregation of the aggregated HGG-bearing dendritic cells within germinal centres--a further stage in the process which is presumed to require B cells and/or specific antibody. Localization of heat-aggregated HGG to white pulp dendritic ells was prevented by treatment with pepsin sufficient to destroy the ability of aggregated HGG to activate guinea-pig complement. Similary, in vivo decomplementation with a purified anticomplementary fraction (CoF) from the venom of Naja naja resulted in failure of intravenously injected HSA to localize to white pulp dendritic cells and failure of subsequent germinal centre formation. However, such decomplementation did not prevent the localization of aggregated HGG to white pulp dendritic cells. These facts are discussed in the light of hypotheses concerning germinal centre formation and the homeostasis of the antibody response in the bird.     

Immunosuppression in murine malaria. II. The effect on reticulo-endothelial and germinal centre function

The mechanism of the immune suppression of mice infected with the rodent malaria parasite Plasmodium berghei yoelii has been investigated.

The clearance from the peripheral blood of carbon and ⁵¹Cr-labelled sheep erythrocytes was enhanced during the period of maximal parasitaemia and maximal immunosuppression, but the uptake of sheep erythrocytes by the spleens of infected mice did not differ significantly from the uptake by the spleens of healthy mice.

There was no uptake of aggregated human γ-globulin into germinal centre areas of the spleens of infected mice during the period of maximal immune suppression, but the ability to localize human γ-globulin returned at a time when the mice recovered immune competence.

It seems probable that acute malaria infections of mice induce a quantitative or qualitative defect in the cells responsible for transporting immune complexes into germinal centres. This defect may play a part in the immunosuppression induced by the malaria parasite.

     

Functional maturation of neonatal spleen cells.

Maturation of neonatal spleen cells was studied in vitro with a cell population restricted with respect to functional properties. It is shown that the onset of the immune response to SRBc in post-natal mice was delayed because B and T cells were incompetent. It appears, however, that the development of these two cell populations does not occur in parallel. Since the addition of adult macrophages failed to overcome the incompetence of neonatal B cells in the presence of a T cell replacing factor, it is suggested that the late appearance of immune competence is due to the inability of B cells to process a T-cell signal.     

Effect of early bursectomy on germinal centre and immunoglobulin production in chickens.

Chickens were bursectomized in ovo on days 18, 19 or 20 of incubation or within 6 h of hatch and immunized at day 28 after hatch by an intravenous injection of sheep red blood cells (SRBC). The immune response in the blood was measured by haemagglutination tests on the serum and by immunocyto-adherence tests for enumeration of rosette-forming cells with SRBC. Total serum 19S and 7S immunoglobulins were determined by radial immunodiffusion and the number of germinal centres per mm2 of fixed and stained spleen tissue sections was determined. In ovo bursectomy produced undetectably low serum levels of haemagglutinins, a reduction in SRBC rosette-forming cells with normal or increased 19S and reduced 7S immunoglobulins together with a complete disappearance (absence) of germinal centres in the spleen. The role of 19S antibody in the generation of germinal centres is discussed. The finding that birds which are equipped with serum 19S but no 7S Ig lack splenic germinal centres casts doubt on the hypothesis that the switch 19S leads to 7S Ig is necessarily an intrabursal event.     

Development of renal potassium excretion capacity in the neonatal rat

We investigated the capacity of newborn rats to excrete an acute potassium load to understand the development of a renal potassium excretion system. Three groups of the rats (7-14 d) were used to collect urine periodically over 6 h after oral infusion of potassium: control (no potassium loading) and low- and high-potassium-loaded rats. In the low-potassium-loaded group, infused with about 0.6 microEq of potassium chloride/g body wt., the rate of renal potassium excretion increased from 0.08 plus minus 0.02 (7 d) to 0.13 plus minus 0.02 (10 d) and 0.21 plus minus 0.03 (14 d) microEq/h/g body wt. The high-potassium-loaded rats (1.5-2.8 microEq/g body wt. potassium load) excreted potassium at a higher rate of 0.18 +/- 0.05 (7 d), 0.30 +/- 0.02 (10 d), and 0.45 +/- 0.10 (14 d) microEq/h/g body wt. They excreted 77% (7 d), 76% (10 d), and 95% (14 d) of the potassium load. These values were much larger than the rate of 0.026 microEq/h/g body wt. of the control rats and of 0.08 microEq/h/g body wt., a mean potassium excretion rate during development from 7 to 14 d calculated from the data in the previous study (Kanno T et al.: J. Pediatr. Gastr. Nutr. 24: 242-252, 1997). In the same period, serum potassium concentration in the newborn rats decreased significantly (p < 0.01) from 7.2 +/- 0.1 (7 d) to 6.7 +/- 0.1 mEq/l (14 d). All these results suggest that a renal potassium excretion system in the rat develops at least in the second week of life, and its capacity is high enough to excrete the daily potassium intake.     

Ontogenic development of macrophage subpopulations and Ia-positive dendritic cells in fetal and neonatal rat spleen.

Development, differentiation, and distribution of macrophage subpopulations and Ia+ dendritic cells in the fetal and neonatal rat spleen were investigated by means of double immunohistochemical staining and immunoelectron microscopy. To characterize these cell populations, a panel of anti-rat macrophage monoclonal antibodies (RM-1, ED2, ED3, TRPM-3, Ki-M2R) and an anti-rat Ia antibody (OX6) were used. In the fetal rat spleen, macrophages were first detected by RM-1 at fetal day 15. ED2+ and/or Ki-M2R+ macrophages appeared at fetal day 16. TRPM-3+ and/or ED3+ macrophages appeared a day later. During the fetal and neonatal development, ED2+ and TRPM-3+ macrophages differentiated independently, maturing into red pulp macrophages and marginal metallophilic and marginal zone macrophages respectively. Intimate topographical relations were observed between ED2+ macrophages and hematopoietic cells and between TRPM-3+ macrophages and marginal zone lymphocytes. Ia+ cells were first observed around arterioles at fetal day 15. In the fetal and neonatal period, the number of Ia+ cells gradually increased, their shape became dendritic, and they matured into interdigitating cells in the inner periarteriolar lymphatic sheath. In ontogeny, Ia+ dendritic cells were not stained with ED2 or TRPM-3. These results suggest that ED2+ macrophages, TRPM-3+ macrophages, and Ia+ dendritic cells are distinct cell lines that pursue independent developmental process in spleen ontogeny.     

A novel internal antigen which distinguishes germinal centre cells from other B-cell types.

A new monoclonal antibody, 4KB51, is described which labels the majority of B cells in blood and in mantle and marginal zones but not germinal centre lymphocytes or plasma cells. Antibody 4KB51 also stains monocytes, neutrophils and the majority of T cells. It recognizes an intracellular antigen of 160,000 MW (unreduced) and 68,000 MW (reduced). Antibody 4KB51 labels the tumour cells in all cases of hairy cell leukaemia and in four of the 16 cases of centrocytic B-cell lymphoma studied. No labelling of the other lymphomas (114 cases) or lymphoid leukaemias (13 cases) tested was seen. Antibody 4KB51 may be of value in defining B-cell subsets and in the differential diagnosis of hairy cell leukaemia and centrocytic lymphomas. The pattern of reactivity of 4KB51 suggests that its target antigen may play a functional role, possibly involved in lymphocyte homing.