Sites of prion protein accumulation in scrapie-infected mouse spleen revealed by immuno-electron microscopy

Prion protein (PrP) from the brains of animals with transmissible spongiform encephalopathies is partially protease resistant (PrP(res)) compared with fully sensitive PrP (PrP(sen)) from uninfected brains. In most experimental models, PrP(res) is a reliable indicator of infectivity. Light microscopic studies have suggested that both PrP(sen) and disease-specific accumulations of PrP are associated with follicular dendritic cells (FDCs). Using immunogold electron microscopy, this study has demonstrated disease-specific accumulation of PrP in the spleens of C57 BL mice, 70 days after intracerebral infection with the ME7 strain of scrapie and at the terminal stage of disease at 170 days. At both stages, tingible body macrophages contained PrP within lysosomes and PrP was also detected at the plasmalemma of FDCs. In the light zone of follicles of terminally diseased mice, all FDC dendrites were arranged in the form of highly reactive or hyperplastic labyrinthine glomerular complexes, within which PrP was consistently seen between FDC processes in association with abundant electron dense material, interpreted as antigen-antibody complexes. Within some glomeruli, fibrillar forms of PrP consistent with amyloid were seen. At 70 days after challenge, large or hyperplastic labyrinthine complexes were rare and invariably labelled for PrP. However, sparse PrP labelling was also seen on simple FDC processes at this stage. The ubiquitous accumulation of extracellular PrP in complex glomerular dendrites of FDCs in spleens from terminally affected mice, contrasted with simple FDC profiles, sparse PrP and limited electron dense deposits in all but a few FDCs of 70-day post-infected mice. This suggests that FDCs continually release PrP from the cell surface, where it is associated with trapped antigen-antibody complexes and dendritic extension. It is likely that tingible body macrophages acquire PrP following phagocytosis of PrP within iccosomes or from the extracellular space around FDC dendrites. These studies would not support an intracellular phase of PrP accumulation in FDCs but show that PrP is produced in excess by scrapie-infected cells from where it is released into the extracellular space. We suggest that PrP(sen) is involved in dendritic extension or in the process of antibody-antigen trapping, perhaps as part of the binding mechanism for antigen-antibody complexes. Copyright Crown copyright 2000. Reproduced with the permission of Her Majesty's Stationery Office. Published by John Wiley & Sons, Ltd.     

Clusterin expression in follicular dendritic cells associated with prion protein accumulation

Peripheral accumulation of abnormal prion protein (PrP) in variant Creutzfeldt-Jakob disease and some animal models of transmissible spongiform encephalopathies (TSEs) may occur in the lymphoreticular system. Within the lymphoid tissues, abnormal PrP accumulation occurs on follicular dendritic cells (FDCs). Clusterin (apolipoprotein J) has been recognized as one of the molecules associated with PrP in TSEs, and clusterin expression is increased in the central nervous system where abnormal PrP deposition has occurred. We therefore examined peripheral clusterin expression in the context of PrP accumulation on FDCs in a range of human and experimental TSEs. PrP was detected immunohistochemically on tissue sections using a novel highly sensitive method involving detergent autoclaving pretreatment. A dendritic network pattern of clusterin immunoreactivity in lymphoid follicles was observed in association with the abnormal PrP on FDCs. The increased clusterin immunoreactivity appeared to correlate with the extent of PrP deposition, irrespective of the pathogen strains, host mouse strains or various immune modifications. The observed co-localization and correlative expression of these proteins suggested that clusterin might be directly associated with abnormal PrP. Indeed, clusterin immunoreactivity in association with PrP was retained after FDC depletion. Together these data suggest that clusterin may act as a chaperone-like molecule for PrP and play an important role in TSE pathogenesis.     

Long-term antigen retention by dendritic cells in the popliteal lymph node of immunized mice.

Antigen retention by follicular dendritic cells (FDC) was studied in the popliteal lymph nodes (PLN) of mice actively or passively immunized against human serum albumin (HSA) or horse spleen ferritin. Electron microscopic autoradiography was used to locate a challenge dose (1 microgram) of 125I-labelled HSA in the draining PLN following injection into the hind footpad of specifically immune mice. In both actively and passively immunized mice, the radiolabelled antigen was localized to the follicles in the cortex of the draining node. In actively immunized mice, the antigen formed a crescent of label on the superficial aspect of germinal centres, while in passively immunized mice label was seen in primary follicles. In electron microscope autoradiographs, the silver grains were concentrated in areas of dendritic cell processes which emanated from a cell body containing a characteristic irregular nucleus. The size and complexity of the dendritic cell processes increased in actively immunized mice suggesting that the FDC could hypertrophy. High resolution studies using the electron-dense antigen, ferritin, showed that it was localized to the extracellular space of the FDC processes and was associated with amorphous electron-dense material; presumably immune complexes. Antigen was not present uniformly distributed in the extracellular material but rather it was in discrete patches occupying small segments of the FDC processes. Large amounts of label-free electron-dense material were present suggesting that immune complexes of various specificities were present on each DC. Ferritin was seen more than 3 months after challenge but only on the FDC. The data suggest that the antigen retaining mechanism in the lymph node of immune mice is antigen non-specific, is capable of hypertrophy in response to active immunization and provides a mechanism for stable long-term retention of antigen.     

PrP protein is associated with follicular dendritic cells of spleens and lymph nodes in uninfected and scrapie-infected mice.

Abnormal forms of a host protein, PrP, accumulate in the central nervous system in scrapie-affected animals. Here, PrP protein was detected immunocytochemically in tissue sections of spleen, lymph node, Peyer's patches, thymus, and pancreas from uninfected mice and from mice infected with a range of mouse-passaged scrapie strains and bovine spongiform encephalopathy (BSE). In the spleen, lymph node and Peyer's patches, PrP-positive cells were identified as follicular dendritic cells (FDC) by their location, appearance, and immune complex trapping function, whereas in the thymus they appeared to be two types of stromal cells: interdigitating cells (IDC) and cortical epithelial cells. In pancreas, PrP-containing cells were confined to the islets of Langerhans. Although the distribution of PrP immunolabelling was the same in tissues from scrapie-affected and uninfected mice, there was evidence that PrP accumulated in abnormal forms in FDC of infected mice. If, as is likely, PrP is essential for agent replication, our results suggest that FDC are the site of scrapie and BSE replication in the spleen and lymph node.     

Follicular dendritic cell dedifferentiation reduces scrapie susceptibility following inoculation via the skin

Transmissible spongiform encephalopathies (TSEs) are a group of subacute infectious neurodegenerative diseases that are characterized by the accumulation in affected tissues of PrP(Sc), an abnormal isoform of the host prion protein (PrPc). Following peripheral exposure, TSE infectivity and PrP(Sc) usually accumulate in lymphoid tissues prior to neuroinvasion. Studies in mice have shown that exposure through scarified skin is an effective means of TSE transmission. Following inoculation via the skin, a functional immune system is critical for the transmission of TSEs to the brain, but until now, it has not been known which components of the immune system are required for efficient neuroinvasion. Temporary dedifferentiation of follicular dendritic cells (FDCs) by treatment with an inhibitor of the lymphotoxin-beta receptor signalling pathway (LTbetaR-Ig) 3 days before or 14 days after inoculation via the skin, blocked the early accumulation of PrP(Sc) and TSE infectivity within the draining lymph node. Furthermore, in the temporary absence of FDCs before inoculation, disease susceptibility was reduced and survival time significantly extended. Treatment with LTbetaR-Ig 14 days after TSE inoculation also significantly extended the disease incubation period. However, treatment 42 days after inoculation did not affect disease susceptibility or survival time, suggesting that the infection may have already have spread to the nervous system. Together these data show that FDCs are essential for the accumulation of PrP(Sc) and infectivity within lymphoid tissues and subsequent neuroinvasion following TSE exposure via the skin.     

CD21-positive follicular dendritic cells: A possible source of PrPSc in lymph node macrophages of scrapie-infected sheep

Natural sheep scrapie is a prion disease characterized by the accumulation of PrP(Sc) in brain and lymphoid tissues. Previous studies suggested that lymph node macrophages and follicular dendritic cells (FDC) accumulate PrP(Sc). In this study, lymph nodes were analyzed for the presence of PrP(Sc) and macrophage or FDC markers using dual immunohistochemistry. A monoclonal antibody (mAb) to the C-terminus of PrP reacted with CD172a+ macrophages and CD21+ FDC processes in secondary follicles. However, a PrP N-terminus-specific mAb reacted with CD21+ FDC processes but not CD172a+ macrophages in secondary follicles. Neither the PrP N-terminus nor C-terminus-specific mAb reacted with CD172a+ macrophages in the medulla. These results indicate that lymph node follicular macrophages acquire PrP(Sc) by phagocytosis of CD21+ FDC processes. The results also suggest that follicular macrophages have proteases that process full-length PrP(Sc) to N-terminally truncated PrP(Sc).     

Severe, Early and Selective Loss of a Subpopulation of GABAergic Inhibitory Neurons in Experimental Transmissible Spongiform Encephalopathies

Little is known about the pathogenetic basis of characteristic symptoms in transmissible spongiform encephalopathies (TSEs) such as myoclonus and characteristic EEG hyperactivity. We investigated the GABAergic system and its subpopulations in mice inoculated with experimental scrapie (ME7, RML, 22A strains) and Creutzfeldt-Jakob disease (CJD; Fujisaki strain), to study damage to inhibitory neurons. Since recent studies have shown electrophysiological changes in prion protein (PrP) knockout mice, we also studied mice lacking or overexpressing the PrP gene. Antibodies against glutamic acid decarboxylase (GAD), parvalbumin (PV), calbindin (CB), and calretinin (CR) were used to stain GABAergic neurons, and isolectin-B₄ to stain perineuronal nets around PV+ neurons. In scrapie infected mice, cortical PV+ neurons were severely reduced while CB+ and CR+ neurons were well preserved. In CJD inoculated mice, loss of PV+ neurons was severe and occurred very early after inoculation. PrP^-/- and tg20 mice showed normal appearance of PV, CB, CR, GAD+ neurons and their neuropil, and of isolectin-B₄+ perineuronal nets. The early, severe and selective loss of cortical PV+ neurons in experimental scrapie and CJD suggest selective loss of PV+ GABAergic neurons as important event during disease development, possibly as one basis of excitatory symptoms in TSEs.     

Evidence for co-infection of ovine prion strains in classical scrapie isolates

The diversity of strains of ovine prions within classical scrapie isolates was investigated by transmission studies in wild type mice. To determine the maximum diversity of prion strains present in each ovine scrapie isolate examined, isolates from mice having the shortest and longest incubation times for terminal disease after primary inoculation were passaged serially. Serial passage of ARQ/ARQ scrapie isolates in RIII mice revealed the ME7 prion strain in mice with short incubation times for terminal prion disease and the 87A strain in those mice with long incubation times. Serial passage of VRQ/VRQ scrapie isolates in RIII mice led to emergence of the 221C prion strain in mice with short incubation times and a variant of the 221C strain in those mice with long incubation times. RIII mice with short incubation times had higher levels of total and proteinase K-resistant PrP(Sc) compared with those RIII mice with long incubation times, while mice with long incubation times had large aggregates and plaques of PrP(Sc). ME7 PrP(Sc) differed in stability compared with the 87A prion strain, while PrP(Sc) associated with 221C had similar stability to that of the 221C variant. Serial passage in VM mice led to identification of ME7 and 87V in the same scrapie isolate. The data show that different prion strains can emerge from the same ovine scrapie isolate following serial passage in wild type mice and that the transmission properties of these strains correlate with distinct patterns of PrP(Sc) deposition.     

Role of the draining lymph node in scrapie agent transmission from the skin

Transmissible spongiform encephalopathies (TSEs) are neurodegenerative diseases that affect humans and animals. Diseases include scrapie in sheep and Creutzfeldt-Jakob disease in humans. Following peripheral exposure, TSE agents usually accumulate on follicular dendritic cells (FDCs) in lymphoid tissues before neuroinvasion. Studies in mice have shown that TSE exposure through scarified skin is an effective means of transmission. Following inoculation by this route TSE agent accumulation upon FDCs is likewise essential for the subsequent transmission of disease to the brain. However, which lymphoid tissues are crucial for TSE pathogenesis following inoculation via the skin was not known. Mice were therefore created that lacked the draining inguinal lymph node (ILN), but had functional FDCs in remaining lymphoid tissues such as the spleen. These mice were inoculated with the scrapie agent by skin scarification to allow the role of draining ILN in scrapie pathogenesis to be determined. We show that following inoculation with the scrapie agent by skin scarification, disease susceptibility was dramatically reduced in mice lacking the draining ILN. These data demonstrate that following inoculation by skin scarification, scrapie agent accumulation upon FDCs in the draining lymph node is critical for the efficient transmission of disease to the brain.     

Infection specific prion protein (PrP) accumulates on neuronal plasmalemma in scrapie infected mice.

Prion protein (PrP) is an abundant membrane-associated host protein which accumulates in abnormal, relatively protease-resistant forms in the brains of animals with scrapie and related diseases. Using correlative light and electron microscopy we determined the sites of subcellular localisation of PrP in mice infected with the 87V strain of scrapie. Disease specific accumulation of PrP was observed at light microscopy as amyloid plaques or as diffuse or granular staining within the neuropil, often clearly associated with individual neurons. Serial electron microscopical preparations were immunostained for PrP by the immunogold method. Gold particles were located on amyloid fibrils and on the plasmalemma of neurites at the periphery of plaques and in the neuropil, irrespective of the morphological form of PrP accumulation when viewed by light microscopy. This suggests that amyloid fibrils are formed following the accumulation and aggregation of sub-unit proteins at the plasmalemma and, furthermore, that normal PrP may be converted to its pathological form at this site.     

FDC-specific functions of p55TNFR and IKK2 in the development of FDC networks and of antibody responses

The FDC-specific molecular signals required in the formation of FDC networks, B cell follicles, and germinal centers (GCs) have remained poorly understood. We used FDC-specific gene targeting to investigate the function of p55TNFR and IKK2 in lymphoid organ structure and function. Here we show that FDC-specific expression of p55TNFR is necessary and sufficient to promote FDC network and B cell follicle formation, restore the expression of CXCL13 and VCAM-1/ICAM-1 in FDCs, and lead to productive GCs. Notably, FDC-specific disruption of IKK2 does not affect formation of FDC networks. Yet, after antigen engagement or immune complex (IC) deposition, FDCs lacking IKK2 fail to upregulate VCAM-1 and ICAM-1, and GCs remain sterile. These findings demonstrate that IKK2-independent function of p55TNFR on FDCs is sufficient to support the development of FDC networks and GCs, while FDC-specific IKK2 is indispensable for the generation of efficient humoral immune responses.     

Lymphotoxin α1β2 expression on B cells is required for follicular dendritic cell activation during the germinal center response

CD19‐deficient mice were used as a model to study follicular dendritic cell (FDC) activation because these mice have normal numbers of FDC‐containing primary follicles, but lack the ability to activate FDCs or form GCs. It was hypothesized that CD19 expression is necessary for B‐cell activation and upregulation of membrane lymphotoxin (mLT) expression, which promotes FDC activation. Using VCAM‐1 and FcγRII/III as FDC activation markers, it was determined that the adoptive transfer of CD19⁺ wild‐type B cells into CD19‐deficient hosts rescued GC formation and FDC activation, demonstrating that CD19 expression on B cells is required for FDC activation. In contrast, CD19⁺ donor B cells lacking mLT were unable to induce VCAM‐1 expression on FDCs, furthermore FcγRII/III upregulation was impaired in FDCs stimulated with mLT‐deficient B cells. VCAM‐1 expression on FDCs, but not FcγRII/III, was rescued when CD19‐deficient B cells expressing transgenic mLT were cotransferred into recipient mice with CD19⁺, mLT‐deficient B cells, suggesting that FDC activation requires the CD19‐dependent upregulation of mLT on activated B cells. Collectively, these data demonstrate that activated B cells are responsible for the initiation of FDC activation resulting in a microenvironment supportive of GC development and maintenance.     

Ubiquitin conjugate immunoreactivity in the brains of scrapie infected mice

Sections of brain from normal mice or clinically-ill mice infected with either the 87V or the ME7 strains of sheep scrapie were immunostained to show the localization of ubiquitin-protein conjugates or a specific marker of disease, the scrapie-associated fibril protein (PrP). In both scrapie models immunoreactive ubiquitin-protein conjugates were seen in thread-like structures found throughout the neuropil, in inclusion bodies within vacuolated neurones, and in areas surrounding anti-PrP positive amyloid plaques. The PrP protein was visualized in diffuse deposits in highly vacuolated parts of the scrapie-affected brain, and focally in amyloid plaques, microglia and neuronal processes. The ubiquitin-protein conjugate staining of scrapie amyloid plaques is very similar to that seen in the plaques of Alzheimer's disease. The ubiquitinated intraneuronal inclusion bodies seen in scrapie resemble the granulovacuolar lesions also seen in Alzheimer's disease, but appear much larger and possibly correspond to material in giant autophagic vacuoles. We suggest that these inclusions may be the result of ubiquitinated abnormal proteins being directed to the lysosomal system, and that scrapie and Alzheimer's disease share at least some common processes of neurodegeneration.     

Marginal zone B cells transport and deposit IgM-containing immune complexes onto follicular dendritic cells

Secreted IgM and complement are important mediators in the optimal initiation of primary T-dependent humoral immune responses. Secreted IgM serves as a natural adjuvant by enhancing the immunogenicity of protein antigens, perhaps as a result of IgM's ability to facilitate antigen deposition onto follicular dendritic cells (FDCs) and promote rapid germinal center (GC) formation. To understand how IgM enhances adaptive immune responses, we investigated the mechanism by which IgM-containing immune complexes (IgM-IC) are transported to FDCs as a first step in GC formation. We demonstrate that IgM-IC localize first to the splenic marginal zone (MZ) where the IgM-IC bind MZ B cells in a complement and complement receptor (CR1/2) dependent process. MZ B cells then transport the IgM-IC into the follicle for deposition onto FDCs. Mice with reduced numbers of MZ B cells trap IgM-IC on FDC less efficiently, whereas mice with reduced numbers of follicular B cells trap IgM-IC normally. The functional elimination of MZ B cells abrogates the ability of FDCs to trap IgM-IC. Transfer of B cells with associated IgM-IC into naive mice results in deposition of IgM-IC onto FDC by MZ B cells. The results demonstrate an IgM and complement-dependent role for MZ B cells in the fate of antigen early in the initial phases of T-dependent immune responses. The data also establish an important role for CR1/2 on MZ B cells in the efficient binding and transport of IgM-IC to FDCs, which we suggest is an important first step in initiating adaptive immune responses.     

IMMUNOCYTOCHEMICAL STUDY ON THE IMMUNE COMPLEX AND GERMINAL CENTER OF SYNOVIAL TISSUE OF RHEUMATOID ARTHRITIS WITH SPECIAL REGARD TO COMPLEMENT AND FOLLICULAR DENDRITIC CELLS

To analyze the immunological role of Iymphoid germinal centers and follicular dendritic cells (FDC) in synovial tissue of rheumatoid arthritis (RA), we tried to detect the immune complex in germinal centers by light and electron microscopic immunocytochemistry with special emphasis on immunoglobulin, complement components, RA factor, and DRC-1 antigen. Immunoglobulins mainly distributed intercellularly in the germinal center in a lacy network pattern, and show partial intracytoplasmic localization in some germinal center lymphoid cells. Early complement components of classical pathway (C1q, C4, C3c, and C3d) and RA factor distributed lacily similarily to immunoglobulin, but intracytoplasmic positivity is never observed. These coexistent positive sites are identical to DRC-1 positive sites which are the surface of extended processes of FDC membrane. A similar finding is observed in primary follicles or lymphoid aggregates less often than germinal centers. These results indicate that some germinal centers trap the immune complex, including RA factor at least closely related with FDCs, and also RA factor is one of the triggers of antigen as well as developing germinal centers.     

Immunocytochemical study on the immune complex and germinal center of synovial tissue of rheumatoid arthritis with special regard to complement and follicular dendritic cells

To analyze the immunological role of lymphoid germinal centers and follicular dendritic cells (FDC) in synovial tissue of rheumatoid arthritis (RA), we tried to detect the immune complex in germinal centers by light and electron microscopic immunocytochemistry with special emphasis on immunoglobulin, complement components, RA factor, and DRC-1 antigen. Immunoglobulins mainly distributed intercellularly in the germinal center in a lacy network pattern, and show partial intracytoplasmic localization in some germinal center lymphoid cells. Early complement components of classical pathway (C1q, C4, C3c, and C3d) and RA factor distributed lacily similarily to immunoglobulin, but intracytoplasmic positivity is never observed. These coexistent positive sites are identical to DRC-1 positive sites which are the surface of extended processes of FDC membrane. A similar finding is observed in primary follicles or lymphoid aggregates less often than germinal centers. These results indicate that some germinal centers trap the immune complex, including RA factor at least closely related with FDCs, and also RA factor is one of the triggers of antigen as well as developing germinal centers.     

Interaction between dendritic cells and nerve fibres in lymphoid organs after oral scrapie exposure

In transmissible spongiform encephalopathies (TSEs), the infectious agent, called PrPsc, an abnormal isoform of the cellular prion protein, accumulates and replicates in lymphoid organs before affecting the nervous system. To clarify the cellular requirements for the neuroinvasion of the scrapie agent from the lymphoid organs to the central nervous system, we have studied, by confocal microscopy, the innervations within Peyer’s patches, mesenteric lymph nodes and the spleen of mice in physiological conditions and after oral exposure to prion. Contacts between nerve fibres and PrPsc-associated cells, dendritic cells (DCs) and follicular dendritic cells (FDCs), were evaluated in preclinical prion-infected mice. Using a double immunolabelling strategy, we demonstrated the lack of innervation of PrPsc-accumulating cells (FDCs). Contacts between nerve fibers and PrPsc-propagating cells (DCs) were detected in T-cell zones and cell-trafficking areas. This supports, for the first time, the possible implication of dendritic cells in the prion neuroinvasion process.     

Isolation of functionally active murine follicular dendritic cells

Biochemical, genetic, and immunological studies of follicular dendritic cells (FDCs) have been hampered by difficulty in obtaining adequate numbers of purified cells in a functional state. To address this obstacle, we enriched FDCs by irradiating mice to destroy most lymphocytes, excised the lymph nodes, and gently digested the nodes with an enzyme cocktail to form single cell suspensions. The FDCs in suspension were selected using the specific mAb FDC-M1 with magnetic cell separation technology. We were able to get nearly a million viable lymph node FDCs per mouse at about 90% purity. When examined under light and transmission electron microscopy, the cytological features were characteristic of FDCs. Furthermore, the cells were able to trap and retain immune complexes and were positive for important phenotypic markers including FDC-M1, CD21/35, CD32, CD40, and CD54. Moreover, the purified FDCs exhibited classical FDC accessory activities including: the ability to co-stimulate B cell proliferation, augment antibody responses induced by mitogens or antigens, maintain B cell viability for weeks, and protect B lymphocytes from anti-FAS induced apoptosis. In short, this combination of methods made it possible to obtain a substantial number of highly enriched functional murine FDCs.     

Follicular dendritic cells share a membrane-bound protein with fibroblasts

The expression of a fibroblast antigen (AS02) on a proportion of CD21+ follicular dendritic cells (FDCs) provides evidence in support of their fibroblastic reticular origin. This antigen is expressed on the membrane of tissue fibroblasts but is absent from lymphocytes, macrophages or granulocytes. The distribution of AS02 in conjunction with other FDC markers (DRC-1, RFD3, CD23, IgM, and vitronectin) showed six types of FDCs. AS02 is present in the outer layers of primary and secondary follicles, but gradually decreases and disappears in the centre of germinal centres. In contrast, there is a progressive up-regulation of the other FDC markers. AS02 is re-expressed in involuting FDCs. Intermediate forms from fibroblastic to dendritic appearance are also apparent and occasionally FDC processes contain collagen type I and IV fibres, a characteristic feature of fibroblasts. In pathological follicles the normal differentiation pattern is disrupted, with persistence of the fibroblast marker, possibly due to altered interactions between FDCs and disrupted lymphocytic patterns. These findings provide new evidence for a local differentiation pathway of fibroblasts to mature FDCs.     

Immunohistochemical detection of follicular dendritic cells in the diagnosis of small B-cell lymphomas

Our study included 46 cases of B-chronic lymphocytic leukemia/small lymphocytic lymphoma (B-CLL/SLL), 25 mantle cell lymphomas (MCL), and 40 follicular lymphomas (FL). The lymphomas were diagnosed according to current morphological, immunohistochemical, and in some cases molecular-genetic criteria. The patterns of follicular dendritie cells (FDCs) were studied in paraffin sections using the anti CD21, anti CD23, and CNA.42 antibodies. The differences in staining patterns of FDCs among the studied lymphomas were statistically significant. The absence or small number of FDC clusters are typical of B-CLL/SLL, while FDC meshwork limited to peripheral parts of neoplastic follicles is characteristic for FL. In contrast, MCL is characterized by irregular FDC meshwork or by FDC clusters present in the centres of residual follicles. Thus, we have demonstrated that the patterns of FDCs is an independent diagnostic feature for distinguishing between B-CLL, FL, and MCL.