In silico subtraction approach reveals a close lineage relationship between follicular dendritic cells and BP3hi stromal cells isolated from SCID mice

Organization of the stromal compartments in secondary lymphoid tissue is a prerequisite for an efficient immune reaction. In particular, follicular dendritic cells (FDC) are pivotal for the activation and differentiation of B cells. To investigate the development of FDC, FDC together with tightly associated B cells (FDC networks) were micro‐dissected from frozen tissue sections and follicular B cells were sorted by FACS. Using an in silico subtraction approach, gene expression of FDC was determined and compared with that of follicular stromal cells micro‐dissected from the spleen of SCID mice. Nearly 90% of the FDC genes were expressed in follicular stromal cells of the SCID mouse, providing further evidence that FDC develop from the residual network of reticular cells. Thus, it suggests that rather minor modifications in the gene expression profile are sufficient for differentiation into mature FDC. The analysis of different immune‐deficient mouse strains shows that a complex pattern of gene regulation controls the development of residual stromal cells into mature FDC. The in silico subtraction approach provides a molecular framework within which to determine the diverse roles of FDC in support of B cells and to investigate the differentiation of FDC from their mesenchymal precursor cells.     

Follicular dendritic cells and the maintenance of IgE responses

Antigen (Ag) is retained for long periods of time in secondary lymphoid tissues in the form of immune complexes on follicular dendritic cells (FDC). Ag retained on FDC is thought to play a role in maintaining antibody (Ab) responses in vivo. A model for study of Ab production induced by retained Ag in vitro is the spontaneous Ab response. In this response, specific Ab production is induced spontaneously (no exogenous Ag needed) in cultures derived from secondary lymphoid tissues containing persisting Ag. Specific IgG is spontaneously induced and we reasoned that FDC may also play a role in the maintenance of specific IgE responses. To test this hypothesis, we monitored spontaneous antiovalbmin (OVA) IgE production in cultures of lymph node (LN) fragments from OVA-immunized mice. In addition, highly enriched preparations of OVA bearing FDC were added to OVA-specific memory cells in an attempt to stimulate OVA-specific IgE production. Months after secondary immunization, anti-OVA IgE responses were spontaneously induced when fragments from draining LN were placed into culture. Furthermore, FDC bearing OVA from draining LN induced anti-OVA IgE production when incubated with spleen cells from OVA-immune mice whereas identical cultures with FDC bearing environmental Ag from non-draining LN of the OVA immune animals did not. The anti-OVA IgE responses were elicited only in cultures containing OVA-immune memory cells indicating that specific memory cells were critical for these anti-OVA IgE responses. Removal of FDC from cultures with an FDC-specific mAb dramatically decreased anti-OVA IgE production. These studies demonstrate that FDC can induce specific memory T and B cells to produce IgE and help support the concept that FDC-associated antigen may be involved in the long-term maintenance of specific IgE responses.     

Isolation of chicken follicular dendritic cells

The aim of the present study was to isolate chicken follicular dendritic cells (FDC). A combination of methods involving panning, iodixanol density gradient centrifugation, and magnetic cell separation technology made it possible to obtain functional FDC from the cecal tonsils from chickens, which had been infected with Eimeria tenella. CD45⁻ dendritic cells were selected using the specific monoclonal antibody against chicken CD45, which is a marker for chicken leukocytes, but is not expressed on chicken FDC. Isolated FDC were characterized morphologically, phenotypically and functionally. The phenotype of the selected cells was consistent with FDC in that they expressed IgG, IgM, complement factors C3 and B, ICAM-1, and VCAM-1, but lacked cell surface markers characteristic of macrophages, T-, and B cells. Transmission electron microscopy confirmed their characteristic dendritic morphology. In addition, the identity of the FDC was further confirmed by their ability to trap chicken immune complexes (ICs) on their surface, whereas they did not trap naive antigen (ovalbumin) or ICs generated with mammalian immunoglobulins. Co-culturing allogeneic or autologous isolated FDC with B cells resulted in enhanced B cell proliferation and immunoglobulin production. The lack of MHC restriction, a functional characteristic feature of FDC, further reinforces the identity of the isolated cells as chicken FDC.     

Follicular dendritic cells in follicular lymphoma and types of non-Hodgkin lymphoma show reduced expression of CD23, CD35 and CD54 but no association with clinical outcome

Jin M K, Hoster E, Dreyling M, Unterhalt M, Hiddemann W & Klapper W
(2011) Histopathology  58 , 586–592
Follicular dendritic cells in follicular lymphoma and types of non‐Hodgkin lymphoma show reduced expression of CD23, CD35 and CD54 but no association with clinical outcome Aims: Follicular dendritic cells (FDC) are specialized antigen‐presenting cells found exclusively in the germinal centre (GC), which can be detected in B cell non‐Hodgkin lymphomas (NHL) as reactive bystander cells. Recently, gene expression profiling has revealed that FDC networks might be associated with clinical outcome in follicular lymphoma. The aim was to characterize FDC in NHL and to evaluate a possible association with outcome in follicular lymphoma. Methods and results: The extent and immunophenotype of FDC was determined semi‐quantitatively in reactive GC and NHL (follicular lymphoma, angioimmunoblastic T cell lymphoma, mantle cell lymphoma) using fluorescence double staining and digital image analysis. In all NHL tested CD23 and CD35 and CD54 were expressed at relatively low levels on FDC, comparable to FDC found in the dark zone of the GC. However, the extent of FDC networks did not correlate with the clinical outcome of 102 patients with follicular lymphomas treated within a prospectively randomized trial. Conclusions: FDC found in different types of NHL show quantitatively reduced expression of several proteins, suggesting that there are functional differences between FDC in normal GC and NHL. The extent of the FDC networks in follicular lymphoma is not useful as a prognostic marker.     

Direct cell/cell communication in the lymphoid germinal center: connexin43 gap junctions functionally couple follicular dendritic cells to each other and to B lymphocytes

Direct cell/cell communication occurs through gap junctions (GJ). We mapped GJ expression in secondary lymphoid organs and found, for the first time, a high density of connexin43 (Cx43) GJ in follicular dendritic cells (FDC) in close association with lymphocytes (Krenacs T. and Rosendaal M., J. Histochem. Cytochem. 1995. 43: 1125–1137). In this work, we used a combination of ultrastructural, immunocytochemical, molecular methods, and functional dye transfer experiments to study which germinal center cells are involved in direct cell/cell communication and how GJ expression is regulated during antigen responses. One week after injecting the footpad of mice with 50 μg lysozyme, Cx43 GJ were detected on elongated cells in the paracortex of their popliteal lymph nodes. Repeated challenge led to the formation of secondary follicles with enlarged FDC meshwork full of Cx43 GJ. This positive correlation may reflect an importance for GJ in the pattern formation of FDC and lymphoid follicles. In human tonsil, the density of GJ and FDC was highest in the light zone of germinal centers where the fate of B cells is thought to be decided. Cx43 colocalized with CD21 and CD35 antigens in the vicinity of desmosomal junctions on FDC embracing lymphocytes. Freeze-fracture hallmarks of GJ of 200–400 nm were also found on FDC in the vicinity of desmosomal plaques. Furthermore, Northern blot analysis showed the consistent presence of Cx43 mRNA in human tonsil and spleen. Most Cx43 message was localized in situ to cells with FDC morphology and some to a few germinal center lymphocytes. To investigate functional cell coupling, we set up FDC/B cell cultures from the low density cell fractions of human tonsils. Cx43 plaques associated with lymphocytes were detected both on elongated FDC processes in early cultures (up to 4 h) and in established FDC/B cell clusters (between 4 and 24 h). In early cultures, we injected FDC with Lucifer Yellow, a fluorescent dye which passes through GJ: the dye spread into adjacent FDC and occasionally from FDC into CD19⁺ B cells. Based on these results, we propose that direct cell/cell communication through Cx43 GJ is involved in FDC/FDC and in FDC/B cell interactions. The functionally coupled FDC meshwork may serve as a communication channel synchronizing germinal center events. FDC may also deliver crucial direct signals through GJ involved in the rescue of high-affinity B cell clones from apoptotic cell death.     

A primary immune response of Bufo marinus spleen cells in vitro

Single-cell suspensions of Bufo marinus spleen have been induced to produce a primary immune response to a soluble purified protein. Using polymerized flagellin from Salmonella adelaide as antigen and culture conditions commonly available in most laboratories but new for amphibian cells, it has been found that in vitro at 37°C, toad spleen cells produce an antibody-forming cell response optimal at day 6. The response depends on the number of cultured cells and dose of antigen, and parallels that obtained in vivo. The optimal immune response is preceded at day 4 by the peak uptake of tritiated thymidine. The antibody-forming cell response is suppressed in the presence of allogeneic serum.     

Cytophilic antibody and the regulation of the immune response

It has been demonstrated that the immunogenicity of the macrophage-associated antigen (sheep red blood cells) in mice, as evaluated in hemolytic plaque test, can be effectively suppressed by means of the coating of peritoneal macrophages by specific cytophilic antibody. Further it has been shown that only spleen cells of mice given antigen i. v. at day –1 before transfer, and not on day –4 or –10, can induce the immune response in syngeneic recipients. On the contrary, spleen cells of –1, –4 or –10 day donors trypsinized before transfer were able to elicit in recipients immune response. This effect was due to transferred immunogen and not due to the different distribution of trypsinized cells or the transfer of committed lymphocytes. The possibility that the cessation of the immune response in vivo despite persisting immunogen is in consequence of the cytophilic antibody on the surface of antigen-storing cells is discussed.     

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.     

Functional annotation of the T‐cell immunoglobulin mucin family in birds

T‐cell immunoglobulin and mucin (TIM) family molecules are cell membrane proteins, preferentially expressed on various immune cells and implicated in recognition and clearance of apoptotic cells. Little is known of their function outside human and mouse, and nothing outside mammals. We identified only two TIM genes (chTIM) in the chicken genome, putative orthologues of mammalian TIM1 and TIM4, and cloned the respective cDNAs. Like mammalian TIM1, chTIM1 expression was restricted to lymphoid tissues and immune cells. The gene chTIM4 encodes at least five splice variants with distinct expression profiles that also varied between strains of chicken. Expression of chTIM4 was detected in myeloid antigen‐presenting cells, and in γδ T cells, whereas mammalian TIM4 is not expressed in T cells. Like the mammalian proteins, chTIM1 and chTIM4 fusion proteins bind to phosphatidylserine, and are thereby implicated in recognition of apoptotic cells. The chTIM4–immunoglobulin fusion protein also had co‐stimulatory activity on chicken T cells, suggesting a function in antigen presentation.     

No protection in chickens immunized by the oral or intra-muscular immunization route with Ascaridia galli soluble antigen

In chickens, the nematode Ascaridia galli is found with prevalences of up to 100% causing economic losses to farmers. No avian nematode vaccines have yet been developed and detailed knowledge about the chicken immune response towards A. galli is therefore of great importance. The objective of this study was to evaluate the induction of protective immune responses to A. galli soluble antigen by different immunization routes. Chickens were immunized with a crude extract of A. galli via an oral or intra-muscular route using cholera toxin B subunit as adjuvant and subsequently challenged with A. galli. Only chickens immunized via the intra-muscular route developed a specific A. galli antibody response. Frequencies of γδ T cells in spleen were higher 7 days after the first immunization in both groups but only significantly so in the intra-muscularly immunized group. In addition, systemic immunization had an effect on both Th1 and Th2 cytokines in caecal tonsils and Meckel's diverticulum. Thus both humoral and cellular immune responses are inducible by soluble A. galli antigen, but in this study no protection against the parasite was achieved.     

The significance of the bursa of Fabricius in relation to the synthesis of 7S and 19S immune globulins and specific antibody activity in the fowl

Fowls in which the development of the bursa of Fabricius was suppressed, by the injection of testosterone in ovo, failed to develop normal serum levels of both 7S and 19S immune globulins. In some instances the 7S immune globulin, in the serum of bursaless fowls, suggested the survival of clones of cells synthesizing 7S immune globulin with a sharply defined electrophoretic mobility. Thus the bursa may make some fundamental contribution to immunological competence and when this effect is markedly reduced by testosterone treatment the few cells which are capable of globulin synthesis subsequently proliferate and produce globulin lacking the usual electrophoretic heterogeneity of mobility.

The indirect haemagglutination test showed that normal fowls developed 7S and 19S antibodies 7 days after the injection of BSA. At this time most of the activity was in the 19S fraction. However, 35 days after the primary injection and 7 days after a second stimulus, highest activity was in the 7S fraction. Precipitin activity was shown at 7 and 35 days in the 7S but not the 19S fractions. The 19S but not the 7S immune globulins were sensitive to mercaptoethanol.

Bursaless fowls, when given similar BSA injections, failed to show any antibody activity in their sera and the antigen was circulating 7 days later, when normal fowls had developed antibody. When time was given for antigen clearance, bursaless fowls still failed to respond to a secondary BSA stimulus. Surgical bursectomy at hatching reduced, but did not eliminate, specific antibody production.

Although there was a significant decrease in thymus weight in testosterone treated fowls, this was not observed in surgically bursectomized fowls. Nevertheless, in both these groups of fowls there was a significant decrease in secondary lymphoid foci in the spleen and in spleen weights. Thus, secondary lymphoid foci appeared to be more dependent on the bursa than on the thymus.

The significance of the synthesis of 7S immune globulin, which occasionally has a sharply defined electrophoretic mobility, by bursaless fowls together with their inability to show any specific antibody activity, is discussed in relation to the function of the bursa.

     

Immunological memory function of the T and B cell types: distribution over mouse spleen and lymph nodes

Spleens from LAF₁ mice injected intravenously with sheep erythrocytes (SE) are relatively rich in memory T cells early in the immune response (1 to 3 days) and rich in memory B cells as the response progresses (2 weeks or more). Marked cooperation for the secondary immune response in vitro was obtained by combining 10⁶ spleen cells from LAF₁ mice, taken 2 days after intravenous priming with SE, with 10⁷ spleen cells from day 14 primed mice. The results indicate relative deficiencies in the spleen for B memory cells on days 1 to 2 and for T memory cells on day 14 after priming. Day – 14, but not day – 2, immune lymph node (LN) cells could replace the day – 2 spleen cells (anti-Thy 1.2 sensitive) in the in vitro cooperation with day – 14 immune spleen cells. Immune spleen cells taken 4 to 7 days after priming contain more equivalent numbers of B and T memory cells, but 10 to 7 days after transfer of such immune spleen cells without SE into irradiated recipients the T memory cells were again more prominent in lymph node and the B memory cells in spleen as shown by in vitro cooperation studies. These results suggest that during the second week after intravenous injection of SE relatively more T than B memory cells migrate from spleen to lymph node, resulting in an imbalance in the splenic memory cell population favoring B memory cell function.     

Effect of rapid slight cooling of the skin in various phases of immunogenesis on the immune response

Slight cooling had no effect on heat emission and heat production, but modulated the immune response to antigen in animals. Changes in the immune response upon rapid slight cooling of the skin (by 1.5°C) depended on the phase of immunogenesis corresponding to cold exposure. When cooling was performed immediately after immunization, antibody production increased in the spleen and blood, while antigen binding in the spleen remained unchanged. Cold exposure on day 5 after antigen treatment as well as immunization at the peak of cooling did not modulate antibody production, but increased antigen binding in the spleen. Our findings attest to an important role of the temperature factor in the formation of the immune response, which should be taken into account during vaccination. __________ Translated from Byulleten’ Eksperimental’noi Biologii i Meditsiny, Vol. 142, No. 10, pp. 389–392, October, 2006     

The working mechanism of an immune complex vaccine that protects chickens against infectious bursal disease.

The role of immune complexes (Icx) in B-cell memory formation and affinity maturation allow for their potential use as vaccines. Recently, a new immune complex vaccine has been developed that is currently under field trials conducted in commercial poultry. This immune complex vaccine is developed by mixing live intermediate plus infectious bursal disease virus (IBDV) with hyperimmune IBDV chicken serum (IBDV-Icx vaccine). Here we have investigated the infectivity of this vaccine as well as the native IBDV (uncomplexed) vaccine in terms of differences in target organs, in target cells and speed of virus replication. At various days after inoculation on day 18 of incubation (in ovo) with either one dose of virus alone or the IBDV-Icx vaccine, the replication of IBDV and the frequency of B cells and other leucocyte populations were examined in the bursa of Fabricius, spleen, and thymus using immunocytochemistry. With both vaccines, IBDV was detected associated with B cells, macrophages and follicular dendritic cells (FDC) in bursa and spleen, although complexing IBDV with specific antibodies caused a delay in virus detection of about 5 days. Most remarkable was the low level of depletion of bursal and splenic B cells in IBDV-Icx vaccinated chickens. Furthermore, in ovo inoculation with the IBDV-Icx vaccine induced more germinal centres in the spleen and larger amounts of IBDV were localized on both splenic and bursal FDC. From these results we hypothesize that the working mechanism of the IBDV-Icx vaccine is related to its specific cellular interaction with FDC in spleen and bursa.     

The carrier effect in the secondary response to hapten-protein conjugates. II. Cellular cooperation

The adoptive secondary response of mice to conjugates of NIP (4-hydroxy-5-iodo-3-nitro-phenacetyl-) and DNP (2,4-dinitrophenyl-) is here used to elucidate the mechanism of cellular cooperation. The framework into which the experiments fit can be formulated as follows. Priming immunization raises a crop not only of specific antibody-forming-cell-precursors (AFCP) but also of specific helper cells. Upon secondary stimulation the helper cells serve a role as handlers or concentrators of antigen, thus enabling AFCP which would otherwise be incapable of reacting to initiate antibody synthesis. In this act of cooperation both cells recognise antigen; in the system examined here the helpers recognise carrier determinants and the AFCP recognise either the hapten or other carrier determinants. The first aim of the experiments was to raise populations of helpers and AFCP of distinguishable specificity. Mice were primed with NIP-Ovalbumin (OA) mixed with chicken γ-globulin (CGG) and bovine serum albumin (BSA); in comparison with controls primed with unmixed NIP-OA, their cells after transfer were relatively more sensitive to secondary stimulation with NIP-CGG or NIP-BSA and similar findings were obtained in cross-checks of these carriers. For reasons which are not entirely clear, non-transferred cells did not show the same effect. In further experiments cells primed with one conjugate (e. g. NIP-OA) were mixed with cells primed with another protein (e. g. BSA), transferred and challenged with the hapten conjugated to the second protein (i. e. NIP-BSA). In comparison with controls lacking the protein-primed cells, the mixture regularly showed greater sensitivity to stimulation. NIP and DNP were tested in many of the possible combinations with BSA, OA and CGG with the same result. The mixture system was used in the further analysis. Tests with allotype-marked protein-primed cells showed that these cells did not participate in the production of the anti-hapten antibody and could therefore properly be regarded as helpers. Tests of specificity showed that physical union of the hapten and carrier were required: cells primed with BSA, for example, would not help NIP-OA-primed cells to make a response to NIP-HSA even when stimulated at the same time with BSA. Transfer of less than one-tenth of the spleen gives a maximum helper effect, whereas AFCP activity continues to rise as larger numbers of cells are transferred. Helper cells are therefore normally present in excess. Helper activity is more resistant than AFCP activity to irradiation, drugs and semi-allogeneic cell transfer across an H-2 barrier. This suggests that helper cells play a relatively passive role in the immune response. Several observations indicate that helper cells are thymus-derived mediators of cellular immunity. Passively transferred antibody did not substitute for helper cells. After immunization helper activity developed faster than AFCP activity. Spleen cells obtained from lethally-irradiated, thymocyte-repopulated, immunized donors provided help. Cells from the thymus-derived fraction of thymus/marrow chimeras also appear to provide help. Thus, the hapten-carrier cooperative response maps onto the well-established synergy of thymus and marrow in the response to foreign erythrocytes.     

Airway hyper-reactivity mediated by B-1 cell immunoglobulin M antibody generating complement C5a at 1 day post-immunization in a murine hapten model of non-atopic asthma

Contact skin immunization of mice with reactive hapten antigen and subsequent airway challenge with the same hapten induces immediate airflow obstruction and subsequent airway hyper‐reactivity (AHR) to methacholine challenge, which is dependent on B cells but not on T cells. This responsiveness to airway challenge with antigen is elicited as early as 1 day postimmunization and can be adoptively transferred to naïve recipients via 1‐day immune cells. Responses are absent in 1‐day immune B‐cell‐deficient JH^?/? mice and B‐1 B‐cell‐deficient xid male mice, as well as in recipients of 1‐day immune cells depleted of cells with the B‐1 cell phenotype (CD19⁺ B220⁺ CD5⁺). As B‐1 cells produce immunoglobulin M (IgM), we sought and found significantly increased numbers of anti‐hapten IgM‐producing cells in the spleen and lymph nodes of 1‐day immune wild‐type mice, but not in xid mice. Then, we passively immunized naive mice with anti‐hapten IgM monoclonal antibody and, following airway hapten challenge of the recipients, we showed both immediate airflow obstruction and AHR. In addition, AHR was absent in complement C5 and C5a receptor‐deficient mice. In summary, this study of the very early elicited phase of a hapten asthma model suggests, for the first time, a role of B‐1 cells in producing IgM to activate complement to rapidly mediate asthma airway reactivity only 1 day after immunization.     

Antigen-induced helper and suppressor T cells in normal and agammaglobulinemic chickens

Spleen cells from chickens injected with sheep erythrocytes (SE) intravenously 2 to 14 days prior to culture were found to give faster and higher plaque-forming cell responses upon addition of antigen on day 2 rather than on day 0 of culture. Cell mixture experiments showed that this was due to the induction of suppressor T cells upon re-exposure to SE on day 0 of culture. Spleen cells taken on days 2 or 14, but not between days 4 and 7 after priming to SE were sensitive to suppression. The suppressor cells were resistant to gamma irradiation (1000 rd) and to mitomycin C, but were apparently lost after 2 days of culture in the absence of antigen. Pokeweed mitogen addition on day 0 of culture also induced suppressor cells, both in SE immune and in normal spleen. Similar suppressor cells were induced in cultures of primed spleen cells taken from agammaglobulinemic chickens. The response to Brucella abortus in vitro was not affected by induction of suppression for the anti-SE response. Suppression could also be shown after transfer of cell mixtures to irradiated recipients. Helper cell activity for the anti-SE response could readily be shown, both in vivo and in vitro, in primed spleen cells precultured for 2 days in the absence of antigen, and was also resistant to 1000 rd gamma irradiation and to mitomycin C.     

The functional state of follicular dendritic cells in severe combined immunodeficient (SCID) mice: Role of the lymphocytes

In the present study, we have investigated the capacity of follicular dendritic cells (FDC) to trap immune complexes (IC) in the splenic white pulp of severe combined immunodeficient (SCID) mice and the influence of lymphocyte transfer on FDC function. FDC are absent in the splenic white pulp of naive SCID mice as revealed by in vitro IC trapping assay. One week after transfer of syngeneic lymphocytes, functional FDC with complement receptors appeared in the primary follicles coincident with B cell segregation, and IC were trapped on those FDC in a complement-dependent manner. Next, we immunized the reconstituted SCID mouse to see whether another type of FDC could be induced in the secondary follicle. Antigenic stimulation induced FDC with an additional capacity to capture IC via FcR γ II. As seen in immunocompetent mice, this type of FDC was located only in the light zone of the secondary follicle. The newly generated FDC did not carry H-2 antigen of transferred lymphocytes from F₁ mice. In SCID mice, in which normally no functional FDC are detectable, the microenvironments of the splenic white pulp have a capacity to develop and differentiate normally after transfer of lymphocytes. Apparently, the generation of functional IC-trapping FDC causes the induction of complement receptor(s) and Fc receptor on meshwork cells, which requires the presence of the lymphocytes.