TuJ1 (class III beta-tubulin) expression suggests dynamic redistribution of follicular dendritic cells in lymphoid tissue

Follicular dendritic cells (FDCs) play central roles in the B cell survival, proliferation, and differentiation into memory cells. Here, we show that TuJ1 (class III beta-tubulin) is expressed strongly in FDCs of human lymphoid tissue. TuJ1 has been a marker of neurons in the central and peripheral nervous systems from the early stage of neural differentiation. FDCs expressed TuJ1 protein diffusely in both light and dark zones of germinal centers in all human lymphoid tissues. In contrast, CD21 expression was relatively concentrated to the light zone, suggesting that TuJ1 was a marker for FDCs with broader spectrum than CD21. In addition to the germinal center, there were single TuJ1-expressing cells scattered in the mantle zone, blurring the border of the FDC network. In human tonsils, single scattered TuJ1-positive cells were also present in the crypt epithelium, suggesting a dynamic redistribution of FDCs among the antigen-rich epithelium, mantle zone, and germinal center. Such migration of FDCs could reflect a way of direct transport of various antigens carried on their surface to the germinal center, and a basis for the polarity of lymphoid follicles toward the epithelium in mucosa-associated lymphoid tissues. HK cells, cultured FDCs, also expressed TuJ1. The expression of TuJ1 by FDCs suggests that they may share certain biological characteristics of the neural system.     

B-cell memory: are subsets necessary?

B-cell memory is provided by populations of quiescent memory B cells and long-lived plasma cells. Whereas it is clear that both of these cell populations arise from germinal centres, the signals and circumstances that trigger germinal-centre B cells to enter and then persist in memory compartments are poorly defined. Here, I propose that germinal centres produce memory B cells and plasma cells throughout the immune response and that memory B cells arise by the emigration of B cells that are chosen at random from the pool available in the germinal centre. The ability of such emigrants to survive as memory B cells depends on their germinal-centre 'history', with the persistence of high-affinity B-cell variants being favoured.     

The function and origin of follicular dendritic cells

Follicular dendritic cells (dendritic reticular cells) in germinal centres bind antigen-antibody complexes via C3 receptors and retain the complexes at their surface for long periods of time. The follicular dendritic cells (FDC) are distinct from macrophages and from dendritic cells found in T-dependent areas, and are not derived from bone marrow stem cells. On histological evidence it has been proposed that they are derived from reticulum cells. Complexes are probably transported to FDC by a subpopulation of B cells in the marginal zone. Binding of complexes to FDC causes germinal centre enlargement and is a very efficient, and possibly essential stimulus to the generation of B memory cells which recognize epitopes on antigen or antibody in the complexes. An hypothesis is discussed which draws together these observations and suggests that antigen on FDC plays a central role in control of humoral immunity.     

A mathematical model for the germinal center morphology and affinity maturation

During germinal center reactions, the appearance of two specific zones are observed: the dark and the light zone. Up to now, the origin and function of these zones are poorly understood. In the framework of a stochastic and discrete model, several possible pathways of zone development during germinal center reactions are investigated. The importance of the zones in the germinal center for affinity maturation, i.e. the process of antibody optimization is discussed.     

Expression of the intercellular adhesion molecule-1 on high endothelial venules and on non-lymphoid antigen handling cells: interdigitating cells,antigen transporting cells and follicular dendritic cells

Intercellular adhesion molecule-1 (ICAM-1)¹ has been implicated in the development of germinal center reactions in vitro, and the present study was undertaken to determine the distribution of ICAM-1 in active germinal centers in vivo and in murine secondary lymphoid tissues in general. Anti-ICAM-1-specific monoclonal antibodies were used in conjunction with immunohistochemistry at both the light and ultrastructural levels of resolution. Examination of cryostat sections of lymph nodes, spleens, and Peyer's patches revealed that anti-ICAM-1 distinctly labeled cells in the light zones of germinal centers, a few cells in the T cell zones (e.g. paracortex of lymph nodes), cells in the sinus floor of the subcapsular sinuses of lymph nodes, and high endothelial venules (HEV). Ultrastructural studies revealed that the cells labeling with anti-ICAM-1 in germinal centers were follicular dendritic cells (FDC) which appeared to have more ICAM-1 than any other cell type. The surfaces of well-developed, intricate, convoluted FDC processes were intensely labeled even under conditions where B cells appeared negative. Interdigitating cells (IDC) were also labeled as were certain endothelial cells in the HEV. The cells in the subcapsular sinus floor labeling with anti-ICAM-1 were the antigen transporting cells (ATC) that carry antigen-antibody complexes into lymph node follicles. We suspect ATC are FDC precursors which mature into FDC in the follicles. Interestingly, FDC, IDC, and ATC are 3 important accessory cells known to handle antigens in specific compartments of lymphoid tissues. The marked localization of this adhesion molecule on these critical antigen handling cells supports the concept that ICAM-1 is important in providing the intercellular adhesion necessary for optimal initiation of immune responses in vivo.Abbreviations ICAM-1 Intercellular adhesion molecule-1 - LFA-1 leukocyte functional antigen-1 - IDC interdigitating cells - ATC antigen transporting cells - FDC follicular dendritic cells - HEV high endothelial venules - DC dendritic cells - PBS phosphate-buffered saline - PLP periodate-lysine-4% paraformaldehyde - GPLP periodate-lysine-0.1% glutaraldehyde-2% paraformaldehyde - EM electron microscopy - HRP horseradish peroxidase - DAB diaminobenzidine tetrahydrochloride - HSA human serum albumin     

Distribution of sheep erythrocytes as antigens in rat spleen

Although sheep erythrocytes (SRBCs) are extensively used as an antigen in immunological studies, their histological distribution in lymphoid tissues has received little attention. The objective of this study was to determine the histological distribution of injected SRBCs in rat spleen. SRBCs were labelled with fluorescein isothiocyanate (FITC) to facilitate their identification in spleen sections with fluorescence microscopy. Rats received intravenous injections of FITC-labelled SRBCs and were sacrificed at various periods after injection. At 15 min, SRBCs were distributed throughout the marginal zone and red pulp. After 4 h, intact SRBCs were located mainly in the red pulp, while the marginal zone contained fluorescent flocculent material. At later periods this material was present in the periarterial lymphatic sheath (PALS) and in the light and dark zones of the germinal centers. By 12 h, the most intensely labelled areas in the white pulp were the crescent-shaped light zones. In 12 and 24 h, the PALS contained numerous foci of labelled granules. Some of the dark zones also contained label. After 48 h, the only areas containing label were the light zones of the germinal centers.     

The follicular dendritic cell network in secondary follicles of human palatine tonsils and spleens

The structure of germinal centres (GCs) in human secondary lymphatic organs has not been thoroughly investigated until now. We stained follicular dendritic cells (FDCs) in serial sections of human hyperplastic tonsils and spleens to compare the morphology of GCs in fulminant immune reactions and quiescence. Detection of CD35, CD21, CD23 and the target of mAb CNA.42 confirmed that full-blown human tonsil GCs may consist of four regions, the dark zone, the basal and apical light zone and the outer zone. The outer zone was, however, not a constant feature of tonsillar GCs and existed only in a minority of follicles in most specimens. Thus, between 3 and 60% of tonsil GCs with a CD23⁺ apical light zone exhibited an outer zone in individual specimens. FDCs in tonsil GCs appeared to be extremely sensitive to mechanical stress during surgery. In contrast to tonsils, seven of the eight adult spleens did not exhibit asymmetric polarized GCs, but only symmetric GCs without dark and light zones or follicles with few GC B cells. Some specimens apparently only contained primary follicles after conventional staining, but on closer inspection a homogenous hyaline extracellular material deposited among the FDCs indicated that a GC had been present. Our study demonstrates that the structure of GCs varies in different human secondary lymphatic organs most likely depending on the local antigenic challenge.     

Human follicular dendritic cells express CR1, CR2, and CR3 complement receptor antigens

The expression of complement receptors by human follicular dendritic cells (FDC) was investigated by immunohistochemical techniques by using polyclonal and monoclonal antibodies to antigenic determinants of CR1, CR2, and CR3. Upon optical immunohistochemical examination of frozen sections from human reactive lymph nodes and tonsils by a three-step immunoperoxidase technique, a strong staining of cell bodies and cytoplasmic extensions of FDC was observed in germinal centers with anti-CR1 and anti-CR2 antibodies. Staining for these antigens was also found on cytoplasmic extensions of FDC in the mantle zone and on the plasma membrane of B cells in the entire follicles. Staining of FDC with anti-CR2 antibody was more intense than that of B lymphocytes. Monoclonal antibodies directed against epitopes of the alpha-chain of CR3 weakly stained FDC in follicles in a similar pattern to that which was observed on adjacent sections with mouse monoclonal antibody KIM4 that only recognizes FDC in human lymph nodes. Immunoelectron-microscopy was performed on frozen sections of a lymph node involved with a centroblastic centrocytic B malignant lymphoma and a reactive tonsil with the use of rabbit F(ab')2 anti-CR1 antibodies and mouse monoclonal anti-CR2 antibody. All the plasma membrane of the cell body and cytoplasmic extensions of FDC in germinal centers and in the mantle zones homogeneously stained for CR1 and CR2 antigens. Fibroblastic reticulum cells were negative. The plasma membrane of tumoral B lymphocytes strongly stained with anti-CR1 and weakly stained with anti-CR2 antibodies. The presence of CR1, CR2, and CR3 on FDC is a unique surface characteristic of these cells that should optimally allow the cells to bind antigen/antibody complexes bearing any type of C3 fragment.     

Tumor necrosis factor and the p55TNF receptor are required for optimal development of the marginal sinus and for migration of follicular dendritic cell precursors into splenic follicles

The development and function of secondary lymphoid tissue require signaling by tumor necrosis factor and lymphotoxins. Mice deficient in LTbetaR show defective organogenesis of lymph nodes and Peyer's patches and a severely disturbed splenic architecture. In contrast, TNF or p55TNF-R deficiency does not affect the organogenesis of peripheral lymphoid organs but interferes with the formation of B cell follicles and the appearance of FDC networks and germinal centers in all secondary lymphoid organs. Based on these differences, we have previously hypothesized that the role of TNF in lymphoid structure is distinct from that of LT and restricted in regulating cellular interactions that allow the differentiation and/or correct positioning of FDCs. In the present study we show that, in addition to the defects in follicular structure, TNF or p55TNF-R knockout mice exhibit defects in the formation of the macrophage populations and of the sinus lining cells of the splenic marginal zone. Interestingly, a large number of dendritic-shaped cells stained with FDC-specific markers and able to trap immune complexes are retained within the defective marginal zone of TNF and p55TNF-R knockout spleens. We conclude that the primary defect in the lymphoid phenotype of TNF or p55TNF-R knockout mice is the failure of FDC precursors to migrate through the disorganized marginal sinus and to home properly into the splenic follicular areas where they would promote the formation of B cell follicles and germinal centers.     

Group I mGluR5 metabotropic glutamate receptors regulate proliferation of neuronal progenitors in specific forebrain developmental domains

Major classical neurotransmitters including GABA and glutamate play novel morphogenic roles during development of the mammalian CNS. During forebrain neurogenesis, glutamate regulates neuroblast proliferation in different germinal domains using receptor subtype-specific mechanisms. For example, ionotropic N -methyl-D-aspartate (NMDA) or alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) glutamate receptors mediate distinct proliferative effects in ventral or dorsal forebrain germinal domains, and regulate the correct number of neurons that populate the striatum or cerebral cortex. Recent work suggests metabotropic receptors may also mediate glutamate's proliferative effects. Group I mGluR5 receptor subtypes are highly expressed in forebrain germinal zones. Using in vitro and in vivo methods, we demonstrate mGluR5 receptor activation plays an important role in neuroblast proliferation in the ventral telencephalon, and helps determine the complement of striatum projection neurons. mGluR5 receptor-mediated effects on striatal neuronal progenitors are restricted mainly to early cycling populations in the ventricular zone, with little effect on secondary proliferative populations in the subventricular zone. In contrast to proliferative effects in the ventral telencephalon, mGluR5 receptors do not modulate proliferation of dorsal telencephalon-derived cortical neuroblasts. Heterogeneous domain-specific proliferative effects of glutamate-mediated by specific receptor subtypes provide an important developmental mechanism allowing generation of the correct complement of neuronal subtypes that populate the mammalian forebrain.     

Cellular heterogeneity and insulin-like growth factor I immunoreactivity among epiphysial growth plate chondrocytes in the pig

The localization of insulin-like growth factor I (IGF-I, also called somatomedin C) production in porcine epiphysial growth plates of the distal humerus was studied by immunohistochemistry. Counterstaining with Alcian blue-van Gieson demonstrated two cell types (blue and red cells) in the germinal (reserve), proliferating and hypertrophic zones; only those chondrocytes of the proliferative and hypertrophic zones that stained red were also immunoreactive to the antibody to IGF-I. The results indicate that there exists a functional heterogeneity among the chondrocytes of both the proliferative and hypertrophic zones of growth cartilage and that IGF-I is locally produced in only the red cells of these zones. Because the red cells of the germinal zone were not immunoreactive, the results suggest that the red cells of the germinal zone and the red cells of the proliferative and hypertrophic zones are also functionally distinct.     

Phenotype and topography of human thymic B cells. An immunohistologic study.

Using single and double labeling immunohistochemical techniques and a large panel of monoclonal antibodies against B-cell differentiation antigens, including those newly defined at the Fourth International Leucocyte Typing Workshop, we have examined the immunophenotype and tissue distribution of human thymic B-cells. The existence of a distinct B-cell population as a constant constituent of the thymic microenvironment has been noted only recently. We found a significant population of B-lymphocytes in the thymic medulla expressing the B-cell restricted antigens CD19, CD20, CD22, CD37, CD72, CD76 and IgM and IgD. As with other extrafollicular B-lymphocytes, they differ significantly from both follicle mantle and germinal center cells in morphology and immunophenotype, which points to alternative modes of B-cell differentiation. Thymic B-cells themselves show considerable heterogeneity and a subpopulation with dendritic features and the expression of CD23 has been referred to as "asteroid" cells. Their close association with T-cells and medullary epithelial cells points to a functional role for B-cells in the thymus. A second population of B-lymphocytes together with frequent lymph follicles is found within the extrathymic perviascular space. Though separated from the medulla by a layer of epithelial cells, a clear distinction between the B-cells of these two compartments is not always possible. The intramedullary B-cell compartment shows a parallel numeric increase with the occurrence of germinal centers in the perivascular space, mostly due to an accumulation of B-cells in the medulla adjacent to these lymph follicles. Thus a close relationship between the intra- and extramedullary B-cell population of the thymus seems likely.     

The zebrafish cerebellar rhombic lip is spatially patterned in producing granule cell populations of different functional compartments

The upper rhombic lip, a prominent germinal zone of the cerebellum, was recently demonstrated to generate different neuronal cell types over time from spatial subdomains. We have characterized the differentiation of the upper rhombic lip derived granule cell population in stable GFP-transgenic zebrafish in the context of zebrafish cerebellar morphogenesis. Time-lapse analysis followed by individual granule cell tracing demonstrates that the zebrafish upper rhombic lip is spatially patterned along its mediolateral axis producing different granule cell populations simultaneously. Time-lapse recordings of parallel fiber projections and retrograde labeling reveal that spatial patterning within the rhombic lip corresponds to granule cells of two different functional compartments of the mature cerebellum: the eminentia granularis and the corpus cerebelli. These cerebellar compartments in teleosts correspond to the mammalian vestibulocerebellar and non-vestibulocerebellar system serving balance and locomotion control, respectively. Given the high conservation of cerebellar development in vertebrates, spatial partitioning of the mammalian granule cell population and their corresponding earlier-produced deep nuclei by patterning within the rhombic lip may also delineate distinct functional compartments of the cerebellum. Thus, our findings offer an explanation for how specific functional cerebellar circuitries are laid down by spatio-temporal patterning of cerebellar germinal zones during early brain development.     

White pulp compartments in the spleen of the turtle Mauremys caspica

Summary The aim of the present study was to analyze the nature of lymphoid and non-lymphoid cellular components occurring in distinct histological compartments of the splenic white pulp of the turtle, Mauremys caspica, in order to define their possible correlations with those of the spleen of higher vertebrates, principally mammals. The white pulp of M.caspica consisted of 3 clearly distinguishable regions: (1) the periateriolar lymphoid sheath, and (2) the inner and (3) the outer zones of the periellipsoidal lymphoid sheath. Reticular cells intimately associated with reticular fibres constituted an extensive meshwork in the periarteriolar lymphoid sheath which housed principally Ig-negative lyphoid cells, mature and immature plasma cells, and interdigitating cells. A few Ig-positive cells were also present in the peripheral region of the periarteriolar lymphoid sheath. The inner and outer zones of the periellipsoidal lymphoid sheath were separated by a discontinuous layer of reticular cell processes. In the inner zone, surface Ig-positive lymphoid cells predominated as well as dendritic cells, resembling ultrastructurally the mammalian follicular dendritic cells, although no germinal centres were found in the turtle spleen. Macrophages, some cytoplasmic Ig-positive cells, and Ig-negative lymphoid cells appeared in the outer zone of the periellipsoidal lymphoid sheath. These results allow us to speculate on a phylogenetic relationship between the periarteriolar lymphoid sheath and the inner and the outer zones of the periellipsoidal lymphoid sheath of the spleen of M. caspica and the periarteriolar lymphoid tissue, the lymphoid follicles and the marginal zone, respectively, of the mammalian splenic white pulp.     

A Model for Migratory B Cell Oscillations from Receptor Down-Regulation Induced by External Chemokine Fields

A long-standing paradigm in B cell immunology is that effective somatic hypermutation and affinity maturation require cycling between the dark zone and light zone of the germinal center. The cyclic re-entry hypothesis was first proposed based on considerations of the efficiency of affinity maturation using an ordinary differential equations model for B cell population dynamics. More recently, two-photon microscopy studies of B cell motility within lymph nodes in situ have revealed the complex migration patterns of B lymphocytes both in the preactivation follicle and post-activation germinal center. There is strong evidence that chemokines secreted by stromal cells and the regulation of cognate G-protein coupled receptors by these chemokines are necessary for the observed spatial cell distributions. For example, the distribution of B cells within the light and dark zones of the germinal center appears to be determined by the reciprocal interaction between the level of the CXCR4 and CXCR5 receptors and the spatial distribution of their respective chemokines CXCL12 and CXCL13. Computer simulations of individual-based models have been used to study the complex biophysical and mechanistic processes at the individual cell level, but such simulations can be challenging to parameterize and analyze. In contrast, ordinary differential equations are more tractable, but traditional compartment model formalizations ignore the spatial chemokine distribution that drives B cell redistribution. Motivated by the desire to understand the motility patterns observed in an individual-based simulation of B cell migration in the lymph node, we propose and analyze the dynamics of an ordinary differential equation model incorporating explicit chemokine spatial distributions. While there is experimental evidence that B cell migration patterns in the germinal center are driven by extrinsically regulated differentiation programs, the model shows, perhaps surprisingly, that feedback from receptor down-regulation induced by external chemokine fields can give rise to spontaneous interzonal and intrazonal oscillations in the absence of any extrinsic regulation. While the extent to which such simple feedback mechanisms contributes to B cell migration patterns in the germinal center is unknown, the model provides an alternative hypothesis for how complex B cell migration patterns might arise from very simple mechanisms.     

Organization of lymphoid tissue in the tonsilla lingualis

Summary Lymphoid organs are highly organized structures made up of different tissue compartments, each with its own specific cell populations. However, the cellular elements of the lingual tonsil, which forms a significant part of Waldeyer's pharyngeal ring, are not yet documented. This study, therefore, describes the fine structure and tissue organization of tonsilla lingualis in Macaca fascicularis. Ten selected crypto-lymphatic units originating from five perfusion-fixed animals were analysed ultrastructurally. Based on the fine-structural elements contained within, the lymphoid tissue of tonsillar units could be subdivided into follicular (germinal centre) and parafollicular areas. The latter contained predominantly small lymphocytes, lymphoblasts resembling T-blasts, plasma cells, macrophages, occasional neutrophils and many reticular cells resembling fibroblasts. A distinct feature of the parafollicular area was the presence of numerous high endothelial (HEV)or postcapillary venules (PCV). The follicular areas contained many small and large lymphoid cells, mitotic cells, plasmablasts, macrophages and specialised reticular cells resembling follicular dendritic cells (FDC) with distinct desmosomal junctions. These observations show that the crypto-lymphatic units of the lingual tonsil are, in fact, organised into distinct B- and T-cell compartments with their own specific lymphoid and accessory cells.     

3C8 antigen is a novel protein expressed by human follicular dendritic cells

Although the pivotal role of follicular dendritic cells (FDCs) in humoral immune responses has been demonstrated, little is known at the molecular level of how FDCs contribute to the organogenesis, B cell differentiation, and regulation of T cell functions in the germinal center. By immunizing with FDC-like cells, we have developed a monoclonal antibody (MAb), which stains the germinal centers in tonsil section. In the current study, the target cell of MAb 3C8 was identified as FDC by confocal scanning fluorescence microscopy. Unlike other MAbs against FDC, MAb 3C8 does not cross-react with bone marrow-derived blood cells. Amino acid sequencing of NH(2)-terminal region of immunoprecipitated 3C8 Ag reveals that 3C8 is a novel FDC protein. Further studies of 3C8 molecule will shed light on the cellular origin of FDC and reveal unknown functions of FDC.     

FDC-SP,a novel secreted protein expressed by follicular dendritic cells

To define better the molecular basis for follicular dendritic cell (FDC) function, we used PCR-based cDNA subtraction to identify genes specifically expressed in primary FDC isolated from human tonsils. In this work we report the discovery of a novel gene encoding a small secreted protein, which we term FDC-SP (FDC secreted protein). The FDC-SP gene lies on chromosome 4q13 adjacent to clusters of proline-rich salivary peptides and C-X-C chemokines. Human and mouse FDC-SP proteins are structurally unique and contain a conserved N-terminal charged region adjacent to the leader peptide. FDC-SP has a very restricted tissue distribution and is expressed by activated FDCs from tonsils and TNF-alpha-activated FDC-like cell lines, but not by B cell lines, primary germinal center B cells, or anti-CD40 plus IL-4-activated B cells. Strikingly, FDC-SP is highly expressed in germinal center light zone, a pattern consistent with expression by FDC. In addition, FDC-SP is expressed in leukocyte-infiltrated tonsil crypts and by LPS- or Staphylococcus aureus Cowan strain 1-activated leukocytes, suggesting that FDC-SP can also be produced in response to innate immunity signals. We provide evidence that FDC-SP is posttranslationally modified and secreted and can bind to the surface of B lymphoma cells, but not T lymphoma cells, consistent with a function as a secreted mediator acting upon B cells. Furthermore, we find that binding of FDC-SP to primary human B cells is markedly enhanced upon activation with the T-dependent activation signals such as anti-CD40 plus IL-4. Together our data identify FDC-SP as a unique secreted peptide with a distinctive expression pattern within the immune system and the ability to specifically bind to activated B cells.     

Phenotype and topography of human thymic B cells

Using single and double labeling immunohistochemical techniques and a large panel of monoclonal antibodies against B-cell differentiation antigens, including those newly defined at the Fourth International Leucocyte Typing Workshop, we have examined the immunophenotype and tissue distribution of human thymic B-cells. The existence of a distinct B-cell population as a constant constituent of the thymic microenvironment has been noted only recently. We found a singificant population of B-lymphocytes in the thymic medulla expressing the B-cell restricted antigens CD19, CD20, CD22, CD37, CD72, CD76 and IgM and IgD. As with other extrafollicular B-lymphocytes, they differ significantly from both follicle mantle and germinal center cells in morphology and immunophenotype, which points to alternative modes of B-cell differentiation. Thymic B-cells themselves show considerable heterogeneity and a subpopulation with dendritic features and the expression of CD23 has been referred to as “asteroid” cells. Their close association with T-cells and medullary epithelial cells points to a functional role for B-cells in the thymus. A second population of B-lymphocytes together with frequent lymph follicles is found within the extrathymic perviascular space. Though separated from the medulla by a layer of epithelial cells, a clear distinction between the B-cells of these two compartments is not always possible. The intramedullary B-cell compartment shows a parallel numeric increase with the occurrence of germinal centers in the perivascular space, mostly due to an accumulation of B-cells in the medulla adjacent to these lymph follicles. Thus a close relationship between the intra-and extramedullary B-cell population of the thymus seems likely. Presented in part in Leucocyte Typing IV (1989) Knapp W et al. (eds) Oxford University Press, Oxford, pp 221–222     

Development of follicular dendritic cells in lymph nodes of B-cell-depleted mice

Summary We have studied follicular dendritic cells (FDC) in lymph nodes of normal and thymus dysgeneic nude mice depleted of B-cells by chronic treatment with anti-IgM antibodies. We found that B cell depletion was accompanied by the absence of mature FDC as defined morphologically at the ultrastructural level. Only precursor FDC (p-FDC) could be demonstrated. Upon release of B-cell suppression, the repopulation of lymph nodes with B-cells was associated with the reappearance of fully differentiated FDC in primary follicles of nude mice and in secondary follicles of T-cell competent mice. We conclude that mature B-cells and/or B-cell products are required for the development of mature follicular dendritic cells in the mouse lymph node.