Polyclonal Antibody Production in Murine Spleen Cells Induced by Staphylococcus

Polyclonal plaque-forming cell (PFC) responses in murine spleen cells induced by Staphylococcus aureus and S. epidermidis were studied. Injection of Balb/c mice with S. aureus strain 248βH resulted in the generation of anti-trinitrophenyl (TNP) and anti-sheep red blood cell PFC in their spleens. Cultures of Balb/c spleen cells in the presence of S. aureus 248βH, Cowan I, or a protein A-deficient mutant yielded many anti-TNP PFC. The larger the number of organisms that were added to the cultures, the better was the PFC response. Both living and killed organisms, were capable of inducing the response, but an excess of living 248βH organisms in the cultures abrogated the response. All of the organisms (12 strains of S. aureus and 11 strains of S. epidermidis) freshly isolated from patients had the ability to induce the polyclonal PFC response in cell cultures. These organisms stimulated cultured C3H/HeJ mouse spleen cells, which were unresponsive to bacterial lipopolysaccharide (LPS). Cultured cells from the spleens of athymic nu/nu mice also responded to these organisms, and the number of PFC in nu/nu cell cultures was always greater than that in nu/+ cells prepared from a haired litter mate. Moreover, the responses of nu/nu spleen cell cultures to which nylon wool column-filtered splenic nu/+ T cells were added were lower than expected. These findings suggest that the polyclonal PFC response to staphylococci is thymus independent, but that the magnitude of the response is regulated by mature T cells. Cultures of macrophage-depleted spleen cells responded to the organisms to an extent similar to that of the control. The 248βH organisms were less capable of stimulating spleen cells of 2-week-old mice (i.e., early maturing B cells) than LPS. However, spleen cells from adult (7-week-old) and aged (9-month-old) mice responded well to both the organisms and LPS. Previous sensitization with the organisms in vivo did not affect any polyclonal responses of spleen cells in vitro to either the organisms or LPS. The role of staphylococcal protein A in the polyclonal PFC response to staphylococci is discussed.     

Detection of plaque-forming cells in the peripheral blood of actively immunized humans.

Ten adult human volunteers were immunized with Salmonella typhi and their peripheral blood leukocytes were collected for 14 days after immunization. These peripheral blood leukocyted, rich in lymphocytes, were plaqued in a modified Jerne assay against sheep erythrocytes coated with either Salmonella or Escherichia lipopolysaccharide. A specific direct and indirect PFC response developed in immunized individuals by day 7 and peaked at day 10. This vigorous PFC response rapidly declined to normal levels by day 14. This marked and specific PFC response of human peripheral blood leukocytes may be developed as a useful tool for monitoring the humoral immune response of patients with Gram-negative bacterial infections.     

In vitro development of a primary antibody response with lymph node cells.

Utilizing a variety of lymphoid tissues from three common laboratory species, comparative studies were performed to investigate the competence of the dissociated cells to respond to a heterologous erythrocyte with the development of specific plaque-forming cells. Dissociated spleen cells harvested from BDF1 mice consistently developed specific plaque-forming cells (PFC) to sheep red blood cells (SRBC), while hamster spleen cells inconsistently developed specific antibody-forming cells to SRBC. Under identical conditions, guinea pig spleen cells did not develop significant numbers of PFC to SRBC. However, lymph node cell cultures of all three species tested yielded specific PFC. In the mouse and hamster lymph node cell cultures, the yield of PFC per culture or per 10⁶ recovered viable cells was always greater than the yield from companion spleen cell cultures. Guinea pig mesenteric lymph node cell cultures developed the major PFC response to SRBC, while both mesenteric and peripheral lymph node cell cultures from hamsters were equivalent in their response to SRBC. The data demonstrate that it is possible to develop a primary antibody response to SRBC in vitro utilizing normal endogenous hamster or guinea pig lymphoid cells, if lymph nodes are the source of cells.     

In vitro studies of the rabbit immune system: I. Hemolytic plaque-forming response of dissociated spleen cells from normal and primed rabbits

The conditions for the in vitro generation of primary and secondary immune responses by rabbit spleen cells to sheep red blood cell (SRBC) antigen have been examined. Spleen cells from many normal and all previously immunized rabbits are capable of producing in vitro plaque-forming cell (PFC) responses when cultured as dissociated cell suspensions in the presence of antigen. Primed spleen cells generate approximately 100 times the number of PFCs obtained in normal cultures with a shorter lag period. Both types of cultures demonstrate a period of exponential increase in PFCs during which the doubling time is 12–14 hr. This increase occurs after 1 day of culture of spleen cells from primed rabbits and after 4 days of culture of spleen cells from unprimed rabbits. The PFCs which arise in cultures of primed cells appear not to be the progeny of those generated in vivo but to be derived from an increased number of PFC precursors. Repeated immunization of the spleen cell donor is required to produce significant numbers of indirect (IgG) PFC or indirect precursors; most of the PFC found after a single immunization in vivo or in vitro are direct (IgM). There is no evidence for conversion of IgM to IgG PFC in vitro. This system should provide a means for further identification of the cellular interactions involved in the immune response of the rabbit.     

Splenic role in the regulation of immune responses.

Evidence for a splenic role in regulating antibody production in other lymphoid tissue was obtained in a system in which cyclical fluctuations of splenic plaque-forming cells (PFC) occur following a single intravenous injection of aggregated human γ-globulin in rabbits. First, PFC arising simultaneously in the mesenteric nodes, peripheral blood, and spleen appear to be derived from the spleen since splenectomy prior to antigen injection abrogated these responses. Second, a noncyclical appearance of PFC in popliteal nodes of rabbits responding to subcutaneous injection of antigen was converted to a cyclical response by simultaneous intravenous injection of antigen, an effect which was abolished by splenectomy prior to antigen injection. It is suggested that, following an intravenous injection of antigen, both suppressor cells as well as antibody-forming precursors may be activated in the spleen and disseminated to other lymphoid tissue.     

Effects of inositol, LiCl, and heparin on the antibody responses to SRBC by normal and immunodeficient XID mice

Spleen cells from na?ve adult immunocompetent and immunodeficient XID mice were cultured on agar containing sheep red blood cells (SRBC) with and without myo-inositol, scyllo-inositol, lithium chloride, or heparin, and after 1 or 2 days the number of colonies of antiSRBC antibody-forming cells (PFC) were determined. It was found that myo-inositol and scyllo-inositol at one-tenth the concentration were equally effective in increasing the number of specific PFC. Myo-inositol, scyllo-inositol, and lithium chloride accelerated the appearance of direct foci in cultures of spleen cells from normal and XID mice. When heparin was added to cultures of XID spleen cells, PFC were found to be increased on Day 1; however, PFC and foci were not increased in cultures of spleen cells from competent mice until 1 day later. The addition of combinations of these agents to cultures of spleen cells had no positive or negative effect on the generation of foci or PFC. Normal mice given heparin intraperitoneally with SRBC had increased splenic PFC on Days 3 and 4 but not on Day 7. The results suggest that these agents modulate B-cell responses by increasing the rate of proliferation and/or secretion through a signaling pathway(s) distal to, or more likely, independent of Bruton's tyrosine Kinase (BTK). It is not clear that the mechanism is the same with each agent.     

Reversal of Con A-induced suppression by a platelet-derived factor which binds to activated suppressor T cells

A platelet-derived factor found in serum as well as in platelet releasate prepared either with calcium ionophore or with thrombin was shown to reverse Con A-induced suppression of the plaque forming cell (PFC) response to sheep erythrocytes (SRBC) in vivo in (CB6)F1 mice. In addition, as shown previously, lymphoma cell-induced suppression in SJL mice was similarly reversed. The factor could be injected prior to Con A on the day before SRBC injection, or on the same day as antigen with comparable results. It also enhanced PFC responses in the absence of Con A. Suppressor cell induction by Con A in vivo, as demonstrated by assay on PFC responses of normal spleen cells in vitro, was abrogated by simultaneous injection of the platelet factor. Cells from mouse spleen and lymph node, but not from thymus could absorb the factor from human serum at 4 degrees C. The phenotype of the relevant spleen cells was L3T4-, Ly1-, Ly2+, Thy1+, Ly22+, Qa1+, Qa4+, Qa5+, and Ly6.IE+. These results suggest that this factor binds to activated peripheral T cells of the suppressor cell phenotype.     

Development of responsiveness and incidence of bispecific cells as revealed by in vitro assessment of the maturation of mouse bone marrow cells.

The kinetics of the maturation of B cells were studied in adult thymectomized, lethally irradiated, and bone marrow-reconstituted mice. The spleen cells of the recipients were taken at various intervals after transfer and cultured in vitro with trinitrophenylated sheep erythrocytes (TNP-SRBC). The cultures were supplemented with either allogeneic culture supernatant or educated T-cell helper activity. Appearance of functional B cells in the bone marrow inoculum was assessed by the number of hemolytic plaque-forming cells (PFC) on the fourth day of culture. In a parallel series the frequency of surface Ig-bearing cells was determined by using fluorescent rabbit anti-mouse Ig serum. When helped by allogeneic culture supernatants, differentiating bone marrow cells showed a slower rate of maturation into functional B cells than when helped by specifically educated T cells. But in both cases the recovery of responsiveness reached the same level (number of PFC/10⁶ cells) as that of normal spleen cells 55 to 60 days after transfer. During the initial periods of recovery, bispecific PFC (reacting both to TNP and to native SRBC determinants) were detected regularly in numbers far exceeding their frequency in normal spleen cell cultures; in some experiments, the number of bispecific PFC amounted to as much as 30% of the total PFC, whereas, when the bone marrow cells completely recovered (sixtieth day), the frequency of bispecific PFC was similar to that found in normal spleen cell cultures. The number of surface Ig-bearing cells also reached a normal level after the fiftieth day following transfer. In general, the degree of functional maturation was better correlated with the cells bearing surface Ig in the shape of rings or caps, whereas the predominance of spot-bearing cells indicated immaturity of the population.     

Measurement and comparison of the proliferative and antibody response of neonatal, immature and adult murine spleen cells to T-dependent and T-independent antigens.

Mouse spleen cell antigenic responses to the thymic-dependent antigen sheep red blood cells (SRBC), and the thymic-independent antigens, E. Coli lipopolysaccharide (LPS) and pneumococcal polysaccharides Type I and II (SI, SII) were studied as as a function of age, employing both in vitro spleen cell stimulation and plaque-forming cell (PFC) assay systems. Primary spleen cell proliferative and PFC responses to SRBC, were either absent or meager in comparison to adult (8–12 weeks) values for the first 3 weeks of life. Thereafter responses rose achieving adult values between 4 and 8 weeks of age. The inability of young mice to respond to SRBC was not because of a different immunizing dose requirement for SRBC, since immunization with SRBC over a 200-fold range did not enhance their capability to respond. Also, addition of adherent cells or macrophages from adult mice did not enhance the immune responses of young mice. Furthermore, immunization of 2–4 week old mice with SRBC inhibited the secondary response to SRBC. In contrast, young murine spleen cell proliferative and PFC responses to SI, SII, and LPS were approximately the same as the adult by 7–14 days of life. These data suggest that B-cell immunologic activity, as measured by immunologic assays utilized in this study, develops much earlier than does T-cell responsiveness.     

Immunomodulatory activity of Sulforaphane, a naturally occurring isothiocyanate from broccoli (Brassica oleracea)

The effect of Sulforaphane on the immune system was studied using BALB/c mice. Intraperitoneal administration of five doses of Sulforaphane (500 microg/dose/animal/day) was found to enhance the total WBC count (12,950 cells/mm3) on 9th day. Bone marrow cellularity (23 x 10(6) cells/femur) and number of alpha-esterase positive cells (1346.66/4000 cells) were also increased by the administration of Sulforaphane. Treatment with Sulforaphane along with the antigen, sheep red blood cells (SRBC), produced an enhancement in the circulating antibody titre and the number of plaque forming cells (PFC) in the spleen. Maximum number of PFC (315.83 PFC/10(6) spleen cells) was obtained on the 6th day. Administration of Sulforaphane also showed an enhancement in the phagocytic activity of peritoneal macrophages. Moreover administration of Sulforaphane significantly reduced the elevated level of TNF-alpha production by LPS stimulated macrophages. These results indicate the immunomodulatory activity of Sulforaphane.     

Age restriction in antigen-specific immunosuppression

Age-related alterations of antigen-specific T cell-mediated suppression have been examined in the 4-hydroxy-3-nitrophenyl acetyl (NP) system. Inducer suppressor T cells (Tsi) were activated in mice at the age of 3 mo (young) or 18 mo (old) by i.v. injection of NP-conjugated syngeneic spleen cells (SC). Spleen cells from the NP-SC-injected mice were subcultured in vitro with spleen cells from normal young or old mice to generate transducer suppressor T cells (Tst). Four days later subcultured cells were added to responder cell cultures 1 day before the PFC assays to trigger effector suppressor T cells (Tse). Responder cell cultures, containing NP-conjugated horse red blood cells (HRBC) and spleen cells from HRBC-primed young or old mice, were assayed on day 4 for anti-NP and anti-HRBC PFC. Suppression was found to be antigen specific and age restricted. NP-specific suppressor cells are easily induced in subculture if the Tsi and Tst cell populations are both derived from young or old mice. Conversely, if Tsi cells from young or old mice are subcultured with Tst cells from mice of a different age, suppression of the anti-NP PFC response is hardly observed. Age restriction was also found to operate in the interactions between subcultured and responder cell populations, indicating that age-matching is required for effective triggering of Tse cells by Tst cells. These results altogether suggest that aging may affect the recognition repertoire expressed in suppressor T cell subsets. Moreover, the finding that suppression is less efficient when exerted on responder spleen cells from old than from young mice provides an explanation for the increased frequency of autoimmune disorders in aging.     

Antibody formation in mouse bone marrow. II. Evidence for a memory-dependent phenomenon

Mouse bone marrow is barely capable of plaque-forming cell (PFC) activity in a primary response to sheep red blood cells (SRBC), while PFC activity in the secondary response to SRBC can be clearly demonstrated. This phenomenon was studied by means of cell transfer experiments.T cells, which are involved in an anti-SRBC PFC response, were shown to be very scarce in normal mouse bone marrow. This is considered to be the cause of the low PFC activity in the marrow during the primary response to SRBC.In normal mouse bone marrow precursors of IgM-PFC but not of IgG- and IgA-PFC could be found. Priming with SRBC induced the appearance of IgM-, IgG-, IgA- and T-memory cells in the marrow. These B- and T-memory cells were shown to be specific for the antigen which induced their appearance. It is thought that after a second injection of SRBC the IgM-, IgG- and IgA-memory cells can differentiate with the help of the T-memory cells within the bone marrow into IgM-, IgG- and IgA-PFC respectively.The sequence of appearance of the B-memory cells in the bone marrow was shown to be IgM-IgG-IgA.Six months after the intravenous injection of SRBC, the presence of B-memory cells could be demonstrated not only in spleen and bone marrow, but also in peripheral lymph nodes, mesenteric lymph node, Peyer's patches, thymus and blood. The increase in amount of B-memory cells was most prominent in the spleen.     

Formation of heterophile antibodies by human tonsilar lymphocytes: II. In vitro stimulation with allogeneic cells

Short-term cultures of human tonsilar lymphocytes (HTL), 5 × 10⁶ cells/culture, in medium RPMI 1640 supplemented with human group AB serum were studied for the production of plaque-forming cells (PFC) against sheep (SRBC) and bovine (BRBC) red blood cells following in vitro stimulation by various allogeneic lymphoid cells. Of 55 HTL specimens examined, 48 produced a significant number (50–300/culture) of PFC against SRBC and/or BRBC following the in vitro stimulation. The optimal doses of the stimulator HTL and peripheral blood lymphocytes (PBL) were 10⁷ and 5 × 10⁶/culture, respectively. After the stimulation, PFC appeared in significant numbers on the third day, reached the peak number on the sixth day, and decreased sharply in number thereafter. Removal of E-rosetting cells from both stimulator and responder populations abolished the PFC formation. PFC formation against SRBC was inhibited by solubilized Forssman antigen, while PFC formation against BRBC was inhibited strongly by Hanganutziu-Deicher antigen, hardly by Paul-Bunnell antigen and not at all by Forssman antigen. Supernatants of mixed lymphocyte culture of PBL were shown to enhance PFC formation of HTL cultures stimulated by allogeneic lymphocytes. The results of this study indicated that in vivo primed B cells of the HTL were triggered in vitro by allogeneic stimulation for the heterophile antibody formation. Since these antibodies are apparently directed against Forssman and Hanganutziu-Deicher antigens, the “allo” nature of these antigens as well as their relationship to the previously described heterophile transplantation antigens have to be clarified.     

The enhancement of the immune response by pain stimulation in mice. I. The enhancement effect on PFC production via sympathetic nervous system in vivo and in vitro

Effects of catecholamines and osmotical and physical stimuli on the induction of anti-sheep red blood cells (SRBC) plaque-forming cells (PFC) were investigated in (C57BL/6 X BALB/c)F1 mice in vivo and in vitro. The anti-SRBC PFC from mice immunized with 5 X 10(7) SRBC was markedly increased by daily s.c. injections of epinephrine. The enhancement of PFC by epinephrine was completely blocked by preadministration with propranolol and hexamethonium, but not with phentolamine. The PFC was increased by osmotic and physical stimuli given once a day for 4 days after immunization with SRBC. The enhancement of PFC by these stimuli was completely blocked by preadministration with propranolol and hexamethonium. The enhancement of PFC by physical stimuli was observed in nonimmunized mice when spleen cells from stimulated mice were cultured with SRBC in vitro. In normal mice, the enhancement of PFC was observed 2 hr after one physical stimulation. However, spleen cells from mice given two physical stimuli did not show the enhancement of PFC after treatment with anti-Thy-1.2 antibody and complement, nor after removal of nonadherent cells. Next, the serum obtained from mice 30 to 60 min after a physical stimulation enhanced PFC of normal mice spleen cells in vitro, but the enhancement was abolished by the addition of propranolol. The enhancement of anti-SRBC PFC by s.c. injection of epinephrine suggested that the autonomic nervous system, especially the sympathetic nervous system, was activated by a local stimulus effect of the injection. This enhancement of anti-SRBC PFC appear to be due to the activation of antigen non-specific helper T lymphocytes by the beta-actin of endogenous catecholamines from the adrenal gland.     

Effects of estrogen on the lymphoid regeneration and immune response in irradiated and marrow-reconstituted mice.

Various doses of estriol (E3) were given to mice intraperitoneally, immediately after lethal irradiation and marrow reconstitution. The assessment of the plaque-forming cell (PFC) response to sheep erythrocytes in the spleen and the histological assessment of lymphoid tissues were carried out 30 days later. The effects appeared to be dose-dependent and resulted in a marked suppression of the PFC response. The depletion of lymphocytes was dramatic and dose-dependent in the thymus, and in the thymus-dependent and in the thymus independent areas of the peripheral lymphoid tissues. These results suggest that E3 acts on the differentiation of stem or precursor cells toweard both the populations of T and B lymphocytes. Although E3, given on day 7 after irradiation and marrow reconstitution, suppressed the lymphoid regeneration and PFC response markedly, E3 given on day 14 had no effect. On day 7 the majority of regenerating lymphoid tissues were large pyroninophilic cells and on day 14, small lymphocytes. These results suggest that the precursor or immature lymphocytes are sensitive to E3, while mature lymphocytes are resistant. Lymphoid regeneration and PFC response were retarded in mice irradiated and reconstituted with bone marrow cells from donors pretreated with E3. These results suggest that E3 acts on the stem or precursor cells capable to differentiate in the direction of lymphoid populations and reduce their number in the bone marrow.     

The mechanism of thymus-dependent antibody formation in bone marrow

During the primary immune response of mice to i.v. administered thymus-dependent antigens the spleen is the major site of localization of antibody-producing plaque-forming cells (PFC). During the secondary response, on the other hand, large numbers of PFC not only appear in the spleen, but also in the bone marrow. By inducing B memory cells with a DNP-carrier complex and activating the DNP-specific B memory cells with the same hapten conjugated to a heterologous carrier, we show in this paper that B memory cells, but not necessarily T memory cells, must be present before booster immunization for PFC to appear in the bone marrow. The origin of the PFC that appear in the bone marrow during secondary type immune response was studied in parabiotic mice consisting of members congenic for the Igh-1 locus. From analysis of the allotype of antibodies produced by PFC in the marrow of such pairs of parabionts it appeared that antibody formation in bone marrow is dependent on the immigration into the marrow of B memory cells activated in peripheral lymphoid organs. Consistent with such a migration of activated cells, radioautographic studies in guinea pigs demonstrated an influx of newly formed mononuclear cells into the bone marrow via the blood stream during the first 3 days after intravascular antigen administration.     

Plaque forming cells in the spleen,lymph and blood

The capacity of blood and lymphatic cells and of the spleen in rabbits immunized with sheep red blood cells to produce antibodies (PFC) has been studied. In rabbits in which only the blood was examined, the numbers of PFC reached a peak 4 days after one immunization, or 3 days after two immunizations. Moreover, double immunization yielded 10 times higher numbers of PFC than single immunization. Comparative studies of the blood, lymph and spleen revealed largest numbers of PFC in the spleen, smaller in the blood, and fewest in the lymph. This pattern was observed after single as well as double immunization, although the proportions were different after double immunization. After the second immunization much larger numbers of PFC appeared, increasing especially in the lymph. Discrepancies between the findings and earlier results, and the problem of the mechanisms of permeation of immunologically competent cells into the blood are discussed.     

Modification of immune response in nude mice infected with mouse hepatitis virus.

In nude mice experimentally infected with mouse hepatitis virus (MHV), the numbers of early and later plaque forming cells (PFC) to sheep red blood cells (SRBC) generated in the spleen were 7 to 20 times and 2 to 163 times, respectively, greater than those in non-infected nude mice, when SRBC were given at day 0 to day 21 postinfection. Splenic theta-positive lymphocytes in infected nude mice were shown to increase only at day 10 or more postinfection. PFC response to bacterial lipopolysaccharide, a T cell-independent antigen, was not modified in MHV-infected nude mice.     

Specificity,avidity, and size of B-lymphocyte populations during ontogeny

The size and specificity of plaque-forming cell precursors (PFC) in murine fetal liver, neonatal, and adult spleen were studied in an adoptive transfer system. In this system, anti-4-hydroxy-3-iodo-5-nitrophenylacetic acid (anti-NIP) and anti-2,4,6-trinitrobenzene sulfonic acid (anti-TNP) direct PFC are generated from bone marrow-derived (B) cell precursors in fetal liver between 17 and 20 days of gestation and in 6- or 14-day neonatal spleen. PFC generated from fetal liver and neonatal and adult spleen cells are specific in that they lyse either NIP-coupled SRBC or TNP-coupled SRBC but not both. The generation of specific anti-NIP and anti-TNP PFC from precursors in fetal liver is primarily independent of antigenic stimulation. In contrast, the anti-NIP and anti-TNP responses generated from neonatal and adult spleen are antigen dependent. Both high-avidity PFC (detected with SRBC indicators coupled at low hapten density) and low-avidity PFC (detected with SRBC coupled at high hapten density) are generated from fetal liver and neonatal spleen cells; however, the proportion of high-avidity PFC precursors in adult spleen is at least threefold greater than in fetal liver or neonatal spleen. Analysis by velocity sedimentation indicates that most high-avidity PFC precursors are small lymphocytes in fetal liver, medium lymphocytes in 6-day neonatal spleen, and small lymphocytes in 14-day-old and adult spleen. Low-avidity PFC precursors are primarily medium-sized lymphocytes in fetal liver and 6-day neonatal spleen. In 14-day-old and adult spleen almost all high- and low-avidity PFC precursors are small lymphocytes. The results are discussed in terms of relative changes in the pool sizes of these lymphocyte populations.     

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

Mouse bone marrow is barely capable of plaque-forming cell (PFC) activity during the primary response to sheep red blood cells (SRBC). However, during secondary-type responses, it becomes the major organ, containing IgM, IgG, and IgA PFC. In the present paper, the influence of splenectomy (Sx) upon the secondary bone marrow PFC response to SRBC was investigated. When previously primed mice were splenectomized just before the second intravenous (iv) injection of SRBC, the effect of Sx upon the height of the bone marrow PFC response was dependent on the booster dose. Sx just before a booster of 10⁶ SRBC iv almost completely prevented bone marrow PFC activity, whereas an iv booster dose of 4 × 10⁸ SRBC evoked a normal IgM, IgG, and IgA PFC response in Sx mice. Apparently low doses of iv administered antigen require the spleen in order to evoke antibody formation in the bone marrow. Experiments with parabiotic mice, consisting of Sx and sham-Sx mice, showed that this facilitating influence of the spleen upon bone marrow antibody formation occurs via the blood stream. In a subsequent study, it was investigated whether the spleen is required throughout the bone marrow PFC response or only during the few days of the initiation phase. Therefore, mice were splenectomized at different intervals after a booster injection of 10⁶ SRBC iv. It appeared that Sx 2 days after the booster injection could still prevent the normal bone marrow PFC activity, whereas Sx at Day 4 could no longer do so. Apparently, after an iv booster injection, the spleen is only required for initiation of the bone marrow PFC response and not for the maintenance of this PFC activity thereafter.