Antibody formation in mouse bone marrow. IX. Peripheral lymphoid organs are involved in the initiation of bone marrow antibody formation

Temporal dynamics and genomic programming of plasma cell fates

Affinity-matured plasma cells (PCs) of varying lifespans are generated through a germinal center (GC) response. The developmental dynamics and genomic programs of antigen-specific PC precursors remain to be elucidated. Here, using a model antigen in mice, we demonstrate biphasic generation of PC precursors, with those generating long-lived bone marrow PCs preferentially produced in the late phase of GC response. Clonal tracing using single-cell RNA sequencing and B cell antigen receptor sequencing in spleen and bone marrow compartments, coupled with adoptive transfer experiments, reveals a new PC transition state that gives rise to functionally competent PC precursors. The latter undergo clonal expansion, dependent on inducible expression of TIGIT. We propose a model for the proliferation and programming of precursors of long-lived PCs, based on extended antigen encounters in the GC.

Cell fate dynamics and genomic programming of plasma cell precursors

This review is focused on the cellular dynamics and genomic programming of plasma cell (PC) precursors that arise during germinal center (GC) B cell responses in secondary lymphoid organs (SLOs) and give rise to PCs in the bone marrow. Considerable progress has been made in the phenotypic characterization of circulating and bone marrow PC precursors as well as their differentiated short-lived (SLPC) and long-lived (LLPC) counterparts, in the context of model antigen and vaccine responses. Importantly, it has been possible to infer the temporal dynamics of generation of PC precursors during a GC response. However, the nature of the PC precursors at their site of generation in SLOs, and their signaling and genomic states, remain to be elucidated. Our synthesis draws upon experimental studies conducted in murine models as well as in humans, the latter complemented with cell culture manipulations of PCs and their precursors. By integration of the studies in murine and human systems, which are being accelerated by new genomic methodologies, we highlight insights and hypotheses concerning the generation of PCs. This framework can be extended and explored from both fundamental and translational standpoints.

Here, There, and Anywhere? Arguments for and against the Physical Plasma Cell Survival Niche

To maintain Ab titers, individual plasma cells must survive for extended periods, perhaps even for the life of the host. Although it is clear that plasma cell survival requires cell extrinsic signals, the nature and source of these signals remains open for debate. It is commonly postulated that plasma cells only gain access to these signals within specialized regulatory microenvironments, or niches, in the bone marrow or in the gut. In this review we discuss current concepts and information surrounding plasma cell survival niches, and consider two opposing models to explain long-term serologic immunity.

Tracking plasma cell differentiation and survival

Plasma cells play a crucial role for the humoral immune response as they represent the body's factories for antibody production. The differentiation from a B cell into a plasma cell is controlled by a complex transcriptional network and happens within secondary lymphoid organs. Based on their lifetime, two types of antibody secreting cells can be distinguished: Short-lived plasma cells are located in extrafollicular sites of secondary lymphoid organs such as lymph node medullary cords and the splenic red pulp. A fraction of plasmablasts migrate from secondary lymphoid organs to the bone marrow where they can become long-lived plasma cells. Bone marrow plasma cells reside in special microanatomical environments termed survival niches, which provide factors promoting their longevity. Reticular stromal cells producing the chemokine CXCL12, which is known to attract plasmablasts to the bone marrow but also to promote plasma cell survival, play a crucial role in the maintenance of these niches. In addition, hematopoietic cells are contributing to the niches by providing other soluble survival factors. Here, we review the current knowledge on the factors involved in plasma cell differentiation, their localization and migration. We also give an overview on what is known regarding the maintenance of long lived plasma cells in survival niches of the bone marrow.

Megakaryocytes constitute a functional component of a plasma cell niche in the bone marrow

Long-lived plasma cells in the bone marrow produce memory antibodies that provide immune protection persisting for decades after infection or vaccination but can also contribute to autoimmune and allergic diseases. However, the composition of the microenvironmental niches that are important for the generation and maintenance of these cells is only poorly understood. Here, we demonstrate that, within the bone marrow, plasma cells interact with the platelet precursors (megakaryocytes), which produce the prominent plasma cell survival factors APRIL (a proliferation-inducing ligand) and IL-6 (interleukin-6). Accordingly, reduced numbers of immature and mature plasma cells are found in the bone marrow of mice deficient for the thrombopoietin receptor (c-mpl) that show impaired megakaryopoiesis. After immunization, accumulation of antigen-specific plasma cells in the bone marrow is disturbed in these mice. Vice versa, injection of thrombopoietin allows the accumulation and persistence of a larger number of plasma cells generated in the course of a specific immune response in wild-type mice. These results demonstrate that megakaryocytes constitute an important component of the niche for long-lived plasma cells in the bone marrow.

Immune suppression of human lymphoid tissues and cells in rotating suspension culture and onboard the International Space Station

The immune responses of human lymphoid tissue explants or cells isolated from this tissue were studied quantitatively under normal gravity and microgravity. Microgravity was either modeled by solid body suspension in a rotating, oxygenated culture vessel or was actually achieved on the International Space Station (ISS). Our experiments demonstrate that tissues or cells challenged by recall antigen or by polyclonal activator in modeled microgravity lose all their ability to produce antibodies and cytokines and to increase their metabolic activity. In contrast, if the cells were challenged before being exposed to modeled microgravity suspension culture, they maintained their responses. Similarly, in microgravity in the ISS, lymphoid cells did not respond to antigenic or polyclonal challenge, whereas cells challenged prior to the space flight maintained their antibody and cytokine responses in space. Thus, immune activation of cells of lymphoid tissue is severely blunted both in modeled and true microgravity. This suggests that suspension culture via solid body rotation is sufficient to induce the changes in cellular physiology seen in true microgravity. This phenomenon may reflect immune dysfunction observed in astronauts during space flights. If so, the ex vivo system described above can be used to understand cellular and molecular mechanisms of this dysfunction.

Plasma cell S1P1 expression determines secondary lymphoid organ retention versus bone marrow tropism

After induction in secondary lymphoid organs, a subset of antibody-secreting cells (ASCs) homes to the bone marrow (BM) and contributes to long-term antibody production. The factors determining secondary lymphoid organ residence versus BM tropism have been unclear. Here we demonstrate that in mice treated with FTY720 or that lack sphingosine-1-phosphate (S1P) receptor-1 (S1P1) in B cells, IgG ASCs are induced and localize normally in secondary lymphoid organs but they are reduced in numbers in blood and BM. Many IgG ASCs home to BM on day 3 of the secondary response and day 3 splenic ASCs exhibit S1P responsiveness, whereas the cells remaining at day 5 are unable to respond. S1P1 mRNA abundance is higher in ASCs isolated from blood compared to spleen, whereas CXCR4 expression is lower. Blood ASCs also express higher amounts of Kruppel-like factor (KLF)2, a regulator of S1P1 gene expression. These findings establish an essential role for S1P1 in IgG plasma cell homing and they suggest that differential regulation of S1P1 expression in differentiating plasma cells may determine whether they remain in secondary lymphoid organs or home to BM.

Dissection of Systems, Cell Populations and Molecules

This paper summarizes studies on antibody formation in the bone marrow and the suppressive effects of intravenous immunization with allogeneic blood cells on T-cell function in mice. The latter studies were extended by employing the limiting dilution culture system developed in Ivan Lefkovits' laboratory and implemented in collaboration with Lucien Aarden. Thereby, the functional data were complemented with frequencies of alloantigen-activated helper (Th) and suppressor T cells after intravenous alloimmunization. These results led the Rotterdam group to studies on the prevention of rejection of the foetal 'allograft'. Th cells are central in foetal allograft rejection and pregnancy success. Characteristic for human pregnancy is the production of the glycoprotein chorionic gonadotropin (hCG) hormone. The in vivo liberated peptide fragments originating from nicking of the sequence MTRVLQGVLPALPQ in the beta-chain of hCG were considered for their immunoregulating capacity related to pregnancy success. These peptides - prepared synthetically - (MTR, MTRV, LQG, LQGV, VLPALP and others) indeed showed a remarkable spectrum of biological effects (e.g. modulation of angiogenesis, inhibition of septic shock syndrome, prevention of diabetes and reduction of ischaemia-reperfusion damage). The paper interprets and generalizes these findings and projects them into various research directions, especially towards the proteomics framework studies built up in Ivan Lefkovits' laboratory in the nineties. During the time period, when Ivan spent a mini-sabbatical in Rotterdam (months after closing down the BII) more detailed discussions were intiated. This paper is meant to keep the discussions between the involved research groups going on.

Homing of antibody secreting cells

As activated B cells differentiate into plasma cells they complete a final series of migration steps that take them to locations where they can efficiently carry out their effector function, secreting immunoglobulin (Ig) M or IgG into circulation or releasing dimeric IgA adjacent to the epithelium for transcytosis. Recent experiments have established a key role for chemokines in directing antibody secreting cell (ASC) movement within the secondary lymphoid organs where they are generated, as well as in guiding the cells to the bone marrow or mucosal surfaces. This review discusses the chemokines involved in directing ASC movements, particularly focusing on the role of CXCR4 and CXCL12/SDF1. The function of CCR9 and CCR10 in IgA ASC homing and contributions made by integrins and lectins are also discussed.

Chemotactic responsiveness toward ligands for CXCR3 and CXCR4 is regulated on plasma blasts during the time course of a memory immune response

Plasma blasts formed during memory immune responses emigrate from the spleen to migrate into the bone marrow and into chronically inflamed tissues where they differentiate into long-lived plasma cells. In this study, we analyze the chemokine responsiveness of plasma blasts formed after secondary immunization with OVA. Starting from day 4 and within approximately 48 h, OVA-specific plasma blasts emigrate from spleen and appear in the bone marrow. Although these migratory cells have lost their responsiveness to many B cell attracting chemokines, e.g., CXC chemokine ligand (CXCL)13 (B lymphocyte chemoattractant), they migrate toward CXCL12 (stromal cell-derived factor 1 alpha), and toward the inflammatory chemokines CXCL9 (monokine induced by IFN-gamma), CXCL10 (IFN-gamma-inducible protein 10), and CXCL11 (IFN-inducible T cell alpha chemoattractant). However, the responsiveness of plasma blasts to these chemokines is restricted to a few days after their emigration from the spleen, indicating a role for these molecules and their cognate receptors, i.e., CXCR3 and CXCR4, in the regulation of plasma blast migration into the bone marrow and/or inflamed tissues.

A coordinated change in chemokine responsiveness guides plasma cell movements

Antibody-secreting plasma cells are nonrecirculatory and lodge in splenic red pulp, lymph node medullary cords, and bone marrow. The factors that regulate plasma cell localization are poorly defined. Here we demonstrate that, compared with their B cell precursors, plasma cells exhibit increased chemotactic sensitivity to the CXCR4 ligand CXCL12. At the same time, they downregulate CXCR5 and CCR7 and have reduced responsiveness to the B and T zone chemokines CXCL13, CCL19, and CCL21. We demonstrate that CXCL12 is expressed within splenic red pulp and lymph node medullary cords as well as in bone marrow. In chimeric mice reconstituted with CXCR4-deficient fetal liver cells, plasma cells are mislocalized in the spleen, found in elevated numbers in blood, and fail to accumulate normally in the bone marrow. Our findings indicate that as B cells differentiate into plasma cells they undergo a coordinated change in chemokine responsiveness that regulates their movements in secondary lymphoid organs and promotes lodgment within the bone marrow.

Canonical germinal center B cells may not dominate the memory response to antigenic challenge

Spleen and bone marrow (BM) are the major sites of antibody production and anamnestic response in systemically immunized mice. We examined the VDJ segment repertoire of antibody plaque-forming cells (APFC) in those two sites in the course of antibody responses to the hapten nitrophenyl (NP). Individual IgG APFC expressed any one of 10 V(H) segments of the V186.2/V3 (J558) gene family: 186.2, 102, 23, C1H4, 165.l, CH10, 3, 593.3, 24.8 and 671.5. The majority of cells in both spleen and BM expressed the V186.2 gene joined to a D segment with Tyr95. During a 2-month period after a single immunization, the V186.2(+) APFC in BM accumulated 3 times as many somatic mutations than splenic APFC (average 8.5 versus 3 mutations/V(H)); this process was T(h) dependent as shown by in vivo depletion of CD4(+) lymphocytes. However, the V186.2(+) APFC in both spleen and BM shared a recurrent W33L replacement, indicating their common origin from germinal centers. The APFC expressing the other (analogue) V(H) segments were evenly represented in the spleen and BM, but they accumulated few, if any, mutations. The anamnestic V186.2(+) APFC were highly mutated both in the spleen and BM; they represented a new and unexpected clonotype. The V/D segments were joined by Gly95 instead of Tyr95, the W33L was absent and a new shared K58R replacement appeared. The APFC expressing the 'analogue' V(H) genes comprised approximately 20% of the anamnestic response and did not accumulate more mutations, but their affinities were in the range of the memory V186.2(+) cells. These data suggest that the late primary and secondary responses to a hapten may be born by different B cell lineages, and that some clonotypes may reach the memory pool without an extensive mutation and expansion.

In situ studies of the primary immune response to (4-hydroxy-3-nitrophenyl)acetyl. V. Affinity maturation develops in two stages of clonal selection

To examine the role of germinal centers (GCs) in the generation and selection of high affinity antibody-forming cells (AFCs), we have analyzed the average affinity of (4-hydroxy-3-nitrophenyl)acetyl (NP)-specific AFCs and serum antibodies both during and after the GC phase of the immune response. In addition, the genetics of NP-binding AFCs were followed to monitor the generation and selection of high affinity AFCs at the clonal level. NP-binding AFCs gradually accumulate in bone marrow (BM) after immunization and BM becomes the predominant locale of specific AFCs in the late primary response. Although the average affinity of NP-specific BM AFCs rapidly increased while GCs were present (GC phase), the affinity of both BM AFCs and serum antibodies continued to increase even after GCs waned (post-GC phase). Affinity maturation in the post-GC phase was also reflected in a shift in the distribution of somatic mutations as well as in the CDR3 sequences of BM AFC antibody heavy chain genes. Disruption of GCs by injection of antibody specific for CD154 (CD40 ligand) decreased the average affinity of subsequent BM AFCs, suggesting that GCs generate the precursors of high affinity BM AFCs; inhibition of CD154-dependent cellular interactions after the GC reaction was complete had no effect on high affinity BM AFCs. Interestingly, limited affinity maturation in the BM AFC compartment still occurs during the late primary response even after treatment with anti-CD154 antibody. Thus, GCs are necessary for the generation of high affinity AFC precursors but are not the only sites for the affinity-driven clonal selection responsible for the maturation of humoral immune responses.

Regulatory role of CD95 ligation on human B cells induced in vivo capable of spontaneous and high-rate Ig secretion

CD95 ligation elicits apoptotic signals in many cell systems. This study analyzes the effect of anti-CD95 mAb on human cells capable of spontaneous and high-rate Ig secretion. Such cells have been induced in vivo and represent a highly mature B cell stage. Addition of the anti-CD95 monoclonal antibody (mAb) CH11 to tonsil B cells inhibited 50-60% of their spontaneous Ig secretion. The effect was exerted early in the culture and could be reversed by a pre-treatment with a neutralizing mAb. N-acetyl-D-sphingosine (C2-ceramide), although not a close analog, also reduced Ig secretion to a similar extent. The inclusion of a tetrapeptide inhibitor for certain interleukin-1beta-converting enzyme proteases prevented the inhibitory effect of CH11 mAb on tonsil B cells. B cells capable of spontaneous Ab secretion obtained from blood of recently-immunized volunteers were also inhibited by CH11 mAb and C2-ceramide. In contrast, bone marrow (BM) B cells capable of spontaneous Ig secretion were unaffected by these agents. This CD95 ligation-mediated inhibition of tonsil and blood Ig-secreting B cells could not be reversed by cytokines with demonstrated activity on these B cells. Human mature B cells induced in vivo are identifiable as CD38hi cells. Flow cytometric analysis revealed that a fraction of tonsil CD38hi cells expressed low levels of CD95. Moreover, about 20% of these cells exhibited basal apoptosis, as defined by annexin V binding. This phenomenon was markedly increased by CD95 ligation. On the other hand, BM CD38hi cells showed neither CD95 expression nor CD95-induced annexin V binding. These data suggest that CD95 ligation might play a role in the control of human humoral responses by inducing apoptosis in susceptible mature B cells.

The bone marrow as a site of antibody production after a mucosal immunization

To study the importance of the bone marrow in the production of specific antibodies after a mucosal immunization with cholera toxin, the IgG, IgA and IgM specific antibody forming cells were evaluated by ELISPOT in Peyer patches, mesenteric lymph node (MLN), spleen, blood and bone marrow (BM). When 50-day-old rats were immunized intra-Peyer patches, a similar number of IgG and IgA antitoxin antibody forming cells (AFC) were found in the BM, whereas in the other lymphoid tissues a higher number of IgG antitoxin AFC were found. In all sites the peak of AFC was obtained 2 weeks after immunization. The administration of CT to 35-week-old rats resulted in a stronger immune response in all lymphoid tissues studied, but the proportion of antitoxin AFC contributed by the BM had not changed. One oral dose of cholera toxin resulted in a low number of antitoxin AFC, whereas when two or three doses of CT were administered orally an increase in the number of AFC was observed in the BM, reaching similar or higher numbers of IgG and IgA AFC than in the spleen. In all cases the highest number of AFC/10(6) cells was observed in the MLN, whereas antitoxin AFC were not found in the blood. The total number of AFC recovered from each organ was calculated taken into account that the BM of one femur represents 9% of the total BM. So, it was found that the BM is an important site in the production of IgG antitoxin antibodies, being the main site in the IgA antitoxin antibody production.

Individual cells simultaneously produce both IL-4 and IL-6 in vivo

IL-4 and IL-6 are pleiotropic cytokines that can act independently or synergistically to regulate lymphocyte growth and differentiation. Both of these factors are produced by cultures of Th2 cells but it is uncertain whether they are secreted simultaneously by a single cell. We used a sensitive and specific ELIspot assay to identify individual cells spontaneously producing IL-4 or IL-6 under physiological conditions in vivo. The fraction of cells producing these two lymphokines was regulated concurrently in cloned Th2 cells but varied independently in the lymphoid organs of normal BALB/c mice. A sandwich ELIspot assay was developed to determine whether individual cells simultaneously produced both cytokines. Thirteen per cent of cells in the spleen and 25% of those in the bone marrow of 10-week-old BALB/c mice secreting either IL-4 or IL-6 concurrently produced both of these lymphokines. These observations establish a physiological mechanism by which the concurrent production of synergistic cytokines is regulated in a given micro-environment.

VLA-4-fibronectin interaction is required for the terminal differentiation of human bone marrow cells capable of spontaneous and high rate immunoglobulin secretion

Human bone marrow (BM) is a relevant site for immunoglobulin (Ig) generation in vivo. The occurrence of BM cells capable of spontaneous and high rate Ig secretion for 14 d in vitro has been described previously. Accordingly, these cells provide a suitable model for studying terminal B cell maturation within the BM. We have reported recently that these BM cells are not totally differentiated when isolated from the body, as they require inductive signals from adherent stromal BM cells to complete their maturation. Interleukin (IL)-6 produced by these adherent BM cells was identified as one such signal. The present work shows that IL-6 was necessary, but not sufficient, for the induction of BM Ig-secreting cells, since the cytokine was unable to restore missing IgG in nonadherent BM cell cultures. Supernatants (SN) obtained from cultures of stromal adherent BM cells, either freshly isolated or derived from long-term BM culture (LTBMC), restored Ig secretion by nonadherent BM cells, suggesting that additional soluble factors from BM stromal cells were required. Fibronectin (FN) was identified as that factor, as can be deduced from the following findings: (a) stromal, but not nonadherent, BM cells constitutively produced FN; (b) anti-FN antibodies markedly reduced the IgG secretion in cultures of BM mononuclear cells (BMMC), and blocked the inductive effect of stromal cell SN on nonadherent BM cells, and such a blockade could be reversed by exogenous FN; and (c) finally, although neither IL-6 nor FN alone exerted any effect, the combination of both factors induced optimal Ig secretion by nonadherent BM cells. Furthermore, VLA-4 molecules seemed to be the FN receptor that was active in this culture system, as indicated by: (a) BM Ig-secreting cells exhibited the phenotype VLA-4+ VLA-5-; (b) mAbs directed to VLA-4 (anti-CD29 and anti-CD49d), but not those directed to other adhesion molecules, inhibited Ig secretion by BMMC cultures, and this effect was reversed by FN; (c) the inductive role of the entire FN molecule could be replaced by a fragment containing the CS-1 region, but not by a fragment containing the RGDS sequence; and (d) only mAbs anti-CD49d capable of blocking VLA-4-FN interaction inhibited induction by either the FN or the CS-1-containing fragment of FN.(ABSTRACT TRUNCATED AT 400 WORDS)

Chemotaxis of germinal center B cells in response to C5a

An infiltrate of B cells and plasma cells is characteristic of certain chronic inflammatory lesions. However, mechanisms involved in the local accumulation of these cells have not been established. Efforts to demonstrate that B cells from normal animals can migrate in response to inflammation-induced chemoattractants have been inconclusive. The objective of this study was to determine if murine germinal center (GC) B cells could respond chemotactically to a C5a gradient. On successive days after secondary immunization, draining lymph nodes were harvested and the activated GC B cells isolated. These GC B cells were placed in modified Boyden chambers, incubated for 3 h and the distance the leading front of cells migrated through the filters was determined. The results show that GC B cells migrated to factors in zymosan- and lipopolysaccharide-activated serum. The migratory response demonstrated distinct kinetics. Cells isolated between 2 to 4 days after secondary immunization migrated, whereas cells isolated at day 0 and beyond day 6 did not. Checkerboard analysis revealed that the migratory response was attributable to both chemokinesis and chemotaxis. Anti-C5 inhibited the migration of day-3 GC B cells implicating C5 in the migration mechanism. Studies using recombinant C5a established that this C5 fragment was chemotactically active. In conclusion, GC B cells generally were not chemotactically active. However, at a particular stage of maturation B cells in the GC become responsive to C5a as a chemotactic agent. Thus, B cells from normal animals may respond chemotactically, and C5a may play a role in recruitment of recently activated B cells into inflammatory sites.

Terminal differentiation of human bone marrow cells capable of spontaneous and high-rate immunoglobulin secretion: role of bone marrow stromal cells and interleukin 6

Human bone marrow (BM) is a major site for in vivo immunoglobulin (Ig) formation. A subset of BM cells has been described which is capable of high-rate Ig secretion for 14 days in vitro without additional stimuli. Therefore, it provides a suitable model for analyzing the terminal B cell differentiation within the BM. The pleiotropic cytokine interleukin (IL)6 was found to be essential for the further maturation of BM spontaneous Ig-secreting cells, as can be deduced from the following findings: (a) the addition of anti-IL-6 antibodies inhibited most of their Ig production; (b) when endogenous IL6 synthesis in the culture was restricted by using serum-free medium, the missing IgG secretion could be restored by the addition of exogenous IL6; and (c) active IL6 synthesis by BM cells in fetal calf serum-containing cultures was confirmed by direct quantitation (range 0.37-2.1 ng/ml). The presence of IL6 during the first 3 days of culture was necessary for the induction of Ig secretion. Since neither the proliferation of these cells was elicited by IL6 nor the inhibition of the DNA synthesis in these cultures prevented the IL6-mediated Ig secretion, IL6 must act on the BM Ig-secreting cells as a differentiation factor. The source of the endogenous IL6 was, apparently, an adherent cell, since most of the IL6 production was present in this cell fraction. In contrast, the nonadherent BM cell fraction contained all of the mature Ig-secreting cells even though it produced little, if any, IL6; the combination of both populations completely restored Ig secretion. Finally, homogeneous populations of fibroblastic stromal cell derived from long-term BM cultures were totally efficient in inducing Ig secretion by purified BM CD38+ cells; this phenomenon was also demonstrated to be IL6 mediated. Taken together, these findings appear to indicate that BM Ig-secreting cells are not terminally differentiated, suggesting that their final maturation could be mediated by the BM microenvironment via the paracrine production of IL6.

Cells involved in the immune response. XXXI. The role of the spleen in the primary and secondary immune responses in the normal adult outbred rabbit: the initial localization of memory cells to the spleen and their subsequent dissemination to the thymus and peripheral lymph nodes

Normal adult outbred rabbits were immunized intravenously (iv) with sheep erythrocytes (SRBC). At varying times thereafter, the different lymphoid organs were investigated for spontaneous and culture-induced antibody secreting cells by the aqueous hemolytic plaque-forming cell (PFC) technique. During the phase of active antibody formation (Days 3 to 30), immediate PFC, indicative of spontaneous antibody synthesis and secretion, were detected principally in the spleen. In the early postimmune memory period (Days 30 to 90), memory cells capable of generating PFC following secondary immunization in in vitro culture with SRBC were detected only in the spleen. However, by 4 months postimmunization, memory cells were detected in the thymus and popliteal lymph node (PLN) as well as in the spleen. The number of memory cells in the thymus and PLN was significantly higher by 6 months postprimary iv immunization and was even further elevated by 9 months postprimary iv immunization. Following in vivo secondary immunization by the iv injection of SRBC 2 or 6 months postprimary immunization, immediate PFC were detected in large numbers in the spleen, the bone marrow, and the blood, marginally in the PLN and not at all in the thymus. Similar results were obtained at 9 months following primary immunization with SRBC with the exception that large numbers of immediate PFC were detected in the PLN following secondary iv immunization. Following culture of these lymphoid cells for 5 days in vitro with SRBC, the thymus and PLN cells, as well as the spleen cells, generated large numbers of PFC. Since immediate PFC were never detected among the freshly isolated thymus cells whereas thymic cell cultures 6 and 9 months postprimary iv immunization invariably generated large numbers of PFC following secondary immunization in vitro, the thymus memory cells would appear to be inaccessible to particulate antigen injected intravenously; they can only be detected following activation by the antigen in culture. The PFC generated by thymus memory cells (and spleen and PLN) were totally inhibited by the inclusion of sheep anti-rabbit IgG into the PFC assay. This finding demonstrates unequivocally that the plaques induced by thymus cells, just as the plaques induced by spleen and PLN cells, are antibody mediated and not false plaques. Therefore, the thymic PFC cells must be antibody-secreting B-memory cells since T cells do not synthesize or secrete immunoglobulins.

Migration of fibroblastoid stromal cells in murine blood

This paper describes the kinetics of fibroblastic colony forming units (CFU-f) in murine blood after phenylhydrazine-induced haemolytic anaemia and their subsequent migration into haemopoietic organs. Murine blood contained 5.3 +/- 0.8 CFU-f per 10(6) nucleated cells. Absence of particle ingestion and factor VIII-related antigen in addition to the enzyme pattern in CFU-f-derived cells confirmed that these cells did not have a macrophage-like or endothelial nature. Phenylhydrazine treatment of mice resulted in a 3-fold increase in blood CFU-f numbers which was accompanied by increases in blood cellularity and granulocyte-macrophage progenitor numbers. When both partners of CBA/N and CBA/T6T6 mice in parabiosis had been treated with phenylhydrazine, spleens and femoral bone marrow of both mice were shown to contain partner-derived CFU-f. These data suggest that circulating CFU-f represent a stromal cell population which can migrate into haemopoietic organs.

Antibody synthesis by bone marrow cells in vitro following primary and booster tetanus toxoid immunization in humans

Normal volunteers received either initial or booster immunization with tetanus toxoid. Bone marrow and peripheral blood mononuclear cells were obtained for up to 28 d after immunization and were analyzed for synthesis of total Ig and specific antibodies to tetanus toxoid. Cells were cultured in vitro for 3 or 7 d with or without pokeweed mitogen (PWM). Synthesis of IgG and IgM antibodies to tetanus (IgG-Tet and IgM-Tet) and total IgG and IgM was determined by radioimmunoassay. Four functional B cell subpopulations were detected in the bone marrow after booster tetanus immunization: (a) B cells that spontaneously synthesized IgG-Tet appeared on day 7 after immunization but were undetectable by day 21; (b) B cells that synthesized IgG-Tet after stimulation with PWM appeared after day 21 and persisted for greater than 1 mo; (c) B cells that synthesized IgM-Tet in the presence of PWM were detectable before and after immunization; and (d) B cells that spontaneously synthesized IgM-Tet appeared on day 7 and were undetectable by day 21. In contrast to the other three types of bone marrow B cells described, this fourth subpopulation of PWM-independent IgM-Tet-synthesizing B cells was not detected in the peripheral blood. After primary immunization, no spontaneous antibody-producing cells were detected in the blood or bone marrow, although there was a small rise in IgM-Tet in two of three subjects. In the bone marrow, only IgM-Tet PWM-inducible cells were seen, although mitogen-responsive IgM and IgG-Tet cells were detected in the circulation. The IgM-Tet PWM-reactive cells were present even before primary antigen exposure and appear to represent the initial B cells involved in the antibody response. These data indicate that there are specific times after immunization when different functional classes of anti-Tet-synthesizing B cells and memory B cells appear in human bone marrow. Knowledge of these data may be important in developing a strategy for the transfer of immune memory from donors to recipients in the setting of bone marrow transplantation.

Apparent adoptive immune enhancement by bone marrow and bursa of Fabricius cells from juvenile chickens

The occurrence of enhancer cells (EC) in the bone marrow and bursa of Fabricius of unprimed and mouse erythrocyte (MRBC) primed birds was investigated. EC are defined operationally as immunocompetent cells that are incapable of adoptive immunity in embryo hosts but able to enhance the immune responsiveness of newly-hatched chick recipients. Weak to moderate immune enhancement was observed in chick hosts grafted with bursal cells from unprimed or MRBC-primed donors whereas with bone marrow cell transfer the immune enhancement was weak with cells from unprimed donors but modest to strong with those from primed donors. Thus antigen priming of donors had little effect on the EC level of the bursa but appeared to increase that in the bone marrow. Moreover, the EC activity of bone marrow of primed donors was donor-age dependent. Response profile studies revealed that the EC level of donor bone marrow was low the first 2-3 days after immunization and high by day six. The elevated EC level in the bone marrow of immunized donors is believed due to both recruitment of immigrant cells of extramedullary origin and clonal expansion of medullary immunocompetent cells.

Antibody formation in mouse bone marrow during secondary type responses to various thymus-independent antigens

The data presented in this paper show that different thymus-independent (TI) antigens have a differential capacity of inducing antibody formation in mouse bone marrow, both after primary and secondary intravenous immunization. Primary immunization with certain TI antigens (e.g., lipopolysaccharide [LPS], TNP-LPS, DNP-Ficoll) induces the appearance of antibody-forming cells not only in the spleen, but also in the bone marrow. A single injection of certain other TI antigens (e.g., pneumococci [Pn], TNP-conjugated detoxified LPS [TNP-dLPS], TNP-conjugated Brucella abortus bacteria [TNP-BA] ), on the other hand, induces antibody formation in the spleen only. After secondary immunization with these TI antigens only TNP-BA induces a PFC response in the bone marrow. Pn, TNP-dLPS and TNP-BA, but also DNP-Ficoll, are unable to induce bone marrow antibody formation after secondary injection of the antigen, in spite of the clear-cut secondary type character of the splenic response. Thus, the absence of a bone marrow PFC response after secondary immunization with these antigens is not due to a failure to induce memory B cells. This data implies that either two subpopulations of memory B cells exist, one giving rise to antibody formation in the spleen and the other accounting for the bone marrow response, or that antibody can selectively inhibit the secondary bone marrow antibody response to certain TI antigens.

The proliferative activity of antibody forming cells in the mouse bone marrow

The proliferative activity of antibody-forming cells was studied in the bone marrow of mice immunized with either sheep erythrocytes (SRBC), TNP-LPS or DNP-Ficoll. Peak proliferative activity was found during the first few days of the response. Elimination of the proliferating cells in this period caused a profound and longlasting suppression of the antibody formation in the marrow.

Bone marrow as the major site of antierythrocyte autoantibody production in NZB mice

By use of a hemolytic plaque assay, it has been determined that most cells secreting the clinically important (anti-X) erythrocyte autoantibody of NZB mice are located in the bone marrow. There was evidence of excessive polyclonal B cell activation in NZB spleen but not in bone marrow, despite the role of marrow as the major source of erythrocyte autoantibody. These findings suggest that polyclonal activation of B cells within the marrow does not lead to erythrocyte autoantibody production. Small but significant numbers of antierythrocyte autoantibody producing cells were detected in the bone marrow but not in the spleens of normal mice, indicating that tolerance to erythrocytes may be less absolute in the bone marrow than in the spleen, or that the bone marrow serves as a repository for autoantibody secreting cells generated elsewhere.