Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

Antibody response against hamster red blood cells (H-RBC) was examined in inbred strains of C57BL/6, AKR, C3H/He, DDD and SL mice, and outbred CF1 mice. 1) There were strain differences in antibody response after a primary intravenous injection of H-RBC. DDD, SL and CF1 mice belonged to high-responder strains, while C57BL/6, AKR and C3H/He to low-responder strains. In the spleens of immunized CF1 and SL, 40 to 70 times as many plaque-forming cells (PFC) as those in C57BL/6 mice were detected. The magnitudes of the response were: CF1 ≒ SL>DDD>>C3H/He ? AKR>C57BL/6. 2) 2-mercaptoethanol resistant (MER) antibody was detected in neither low- nor high-responders after a primary intravenous antigen-injection. 3) After a secondary intravenous antigen-injection, MER antibody was detected in all the SL mice, but only in 30 to 50% of AKR and C57BL/6 mice. 4) A subcutaneous injection of H-RBC in Freund's complete adjuvant (FCA) did not elicit antibody production within 10 days. When mice pre-sensitized 7 days in advance w^Tith H-RBC in FCA were intravenously injected with H-RBC, enhanced antibody production of the primary type was observed in all the mouse strains. 5) In pre-sensitized mice, the extent of the enhancement of antibody production was the highest in low-responder C57BL/6 mice and the lowest in high-responder SL and CF1 strains. Thus, there was no strain difference in antibody titers or the numbers of PFC after the booster.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

Golden hamsters were used as hosts in this work, and mice of various strains as donors of antigens. 1) There were no strain differences in immunogenicity of erythrocytes from C57BL/6, AKR, SL and CF1 mice. 2) Primary intravenous immunization with mouse erythrocytes (MRBC) induced the production of hemolysin plaque-forming cells (PFC) in a large number, but elicited only in a negligible titer production of 2-mercaptoethanol-resistant antibody. 3) 2-Mercaptoethanol-resistant antibody was produced more efficiently in hamsters pre-sensitized with mouse lymph node (MLN) cells rather than those pre-immunized with MRBC after a booster with MRBC. 4) Numbers of PFC in pre-sensitized hamsters were three-times that of the non-sensitized hamsters after a booster with MRBC, when pre-sensitization was performed intradermally with a small number of MLN cells. 5) Average diameter of the hemolysin plaques in pre-sensitized hamsters was one and a half times larger than that in non-sensitized hamsters. Conclusions agree well with the results in our previous papers that the reversed combination of hosts and antigen donors employed support the concept that certain processes required for delayed hypersensitivity contributed to antibody production under a condition suitable for antibody response.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

1) A subcutaneous injection of hamster erythrocytes (HRBC) in Freund's complete adjuvant (FCA) or an intravenous injection of hamster lymph node (HLN) cells suppressed antibody production against HRBC in the low-responder C57BL/6 and AKR mice, when HRBC in saline were given on the same day; 2) The suppressing effect of such treatments was neither detectable in the high-responder SL mice, nor in the C57BL/6 mice, which had been pre-sensitized with HRBC in FCA or hamster lymphoma cells; 3) Positive reactions of the peritoneal macrophage disappearance test and the enhanced antibody production were detected seven days after treatment with HRBC in FCA and HRBC in saline, or HLN cells and HRBC in saline; 4) The suppressing effect of such simultaneous treatments on anti-HRBC antibody production was eliminated by a transfer of normal syngeneic thymus cells to AKR mice or a transfer of thymus cells from SL to C57BL/6 mice. Suppression of the antibody production in the low-responder mice by the described simultaneous treatments may be due to a competitive involvement of HRBC-specific thymus-derived cells (T cells) in the developmental stages of delayed hypersensitivity and antibody production. High-responder SL mice appear to have enough T cells for development of the delayed hypersensitivity and as helper cells in antibody production. These results appear to support the concept that T cells for delayed hypersensitivity and antibody production to HRBC antigen are derived from the same original pool.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

The production of anti-hapten antibody after immunization with trinitrophenylated (TNP) hamster erythrocytes (HRBC) or sheep erythrocytes (SRBC) was determined in high- and low-responder mouse strains against HRBC antigen. 1) Anti-TNP antibody was detected in sera of high-responder DDD and CF1 mice after primary immunization with TNP-HRBC, but not in those of low-responder C57BL/6 mice. 2) Anti-TNP antibody was detectable in sera of all the strains after primary immunization with TNP-SRBC. 3) Production of anti-TNP antibody was elicited after a booster injection of TNP-HRBC in low-responder C57BL/6 mice pre-sensitized with HRBC in Freund's complete adjuvant. These results suggest that functions of thymus-derived cells specific for HRBC antigen are deficient in low-responder mice.     

Difference in antibody production to hererologus erythrocytes in conventional, specific-pathogen-free (SPF), germfree and antigen-free mice.

The expression of antibody-producing capacities against hamster erythrocytes (HRBC), known to be weakly immunogenic in mice, was compared among conventional, SPF, germfree and antigen-free mice. ICR strain germfree and antigen-free mice showed antibody production to HRBC comparable to that in conventional or specific-pathogen-free (SPF) mice. In the NC strain, some of the conventional mice produced low titers of antibody after a single injection of HRBC, but none of the germfree mice showed such a transient antibody production. In the ICR-KIG strain, which was selected from the colony-bred ICR strain, antibodies with high titers were produced after a single injection of HRBC under both conventional and germfree conditions. The onset of conversion from 2-mercaptoethanol (2-ME) sensitive to 2-ME resistant antibody after a single injection of HRBC was not delayed in the germfree mice when compared with the conventional or SPF mice. Antibody production to sheep erythrocytes (SRBC), known to be highly immunogenic in mice, was not influenced by exogeneous stimulation from microorganisms or diet. No differences in antibody production to SRBC were detected irrespective of the maintenance conditions of the mice. Stimulation with microorganisms or diet may not be required as essential elements for the maturation of antibody-producing capacities, but such a stimulation appears to modify the antibody response. The modifying effect was more prominent in the antibody response against weakly immunogenic antigens than against highly immunogenic ones.     

Immunological properties of Propionibacterium acnes. I. Potentiation and Suppression on antibody response to sheep and hamster erythrocytes in mice.

Adjuvant activity of phenol-treated cells of Propionibacterium acnes C-7 in antibody response was investigated in ICR mice. Simultaneous administration (day 0) of P. acnes (i.p.) and sheep red blood cells (SRBC) (i.v.) enhanced the formation of direct plaque-forming cells (PFC) on days 2, and the formation of indirect PFC response on day 7 and thereafter. Conversely, pretreatment from 11 to 14 days before antigen injection suppressed markedly the antibody response. The potentiation and the suppression of immune response depended on doses of antigen and of P. acnes, the timing of adjuvant injection and the time of assay. The two opposite phenomena caused by P. acnes were also confirmed in antibody response against hamster red blood cells (HRBC). Pretreatment with P. acnes 1 to 14 days before antigen injection suppressed markedly anti-HRBC antibody response, whereas P. acnes injected simultaneously with HRBC or one day after injection of the antigen induced prolongation of antibody response and the production of 2-mercaptoethanol-resistant antibody.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

It was confirmed by passive transfer experiments that the function of thymus-derived cells specific for hamster erythrocytes (HRBC) was deficient in the low-responder mouse strains. 1) Antibody production against HRBC was enhanced by passive transfer of thymus cells from normal SL mice (high-responder) to normal C57BL/6 mice (low-responder). 2) The enhancing effect of passive transfer of thymus cells from SL mice was abrogated by pre-sensitization of the recipients (C57BL/6) with thymus cells from SL mice. 3) In C57BL/6 mice, antibody production against HRBC was enhanced by the transfer of lymph node or spleen cells from C57BL/6 mice which had been sensitized with HRBC in Freund's complete adjuvant or hamster lymphoma cells.     

Genetic control of the immune response

(I) The influence of the dose of antigen on the amount of antibodies produced was studied in two inbred strains of mice that were different with respect to the ability to produce antibodies top-aminobenzoic acid, i.e. well responding strain B10.LP and poorly responding CBA/J strain. Similar dependence between the dose of antigen and the antibody titre was demonstrated in both strains. (2) It was found that the type of reaction to the antigenic determinant (i.e. hapten) appeared to be a constant property of the inbred strain and that it did not change during the long period of the immunological maturity of the organism. (3) Antibodies of 19S type (2-mercaptoethanol sensitive) were formed in sera of both inbred strains, particularly in strain B10.LP, even after the third adjuvant immunization. Antibodies of 7S type appeared to be partially 2-mercaptoethanol sensitive, however, the major part was resistant to this agent. No 7S, 2-mercaptoethanol resistant antibodies were found in sera of the poorly responding strain CBA/J.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

Patterns of proliferation of antibody-forming cells after an intravenous immunization with hamster erythrocytes (HRBC) were compared in groups of mice possessing different activities of thymus-derived lymphocytes (T cells). 1) Marked differences in the numbers of hemolysin plaque-forming cells (PFC) after HRBC injection were found among the low- and high-responder normal mice and those pretreated with HRBC in complete Freund's adjuvant (CFA) or incomplete adjuvant (IFA), and they appeared to depend primarily upon the different rates of proliferation of antibody-forming cells rather than on the numbers of antigen-specific lymphocytes initiating the antibody response. 2) The numbers of hemolytic foci were slightly larger in mice with large numbers of PFC (normal SL mice, the pretreated SL and C57BL/6 mice) than in those with small numbers of PFC (normal C57BL/6 mice). The numbers of hemolytic foci increased at almost the same rate from day 2 to day 3 in both groups, while the numbers of PFC increased more efficiently in mice with large numbers of PFC than in those with small numbers of PFC from day 2 to day 3. Individual hemolytic foci appeared to contain larger numbers of PFC in mice with large total numbers of PFC than in those with small total numbers of PFC. 3) The numbers of rosette-forming cells (RFC) were increased by pretreatment with HRBC in CFA and by pretreatment with HRBC in IFA to almost the same extent. Rates of increases in PFC were, however, larger by pretreatment with HRBC in CFA than with HRBC in IFA. These results suggested that the activity of the T cell determined not only the rates of proliferation of antibody-forming cells but also the antibody-producing capacity of each cell.     

Trichinella spiralis: anaphylactic antibody formation and susceptibility in strains of inbred mice.

The anaphylactic antibody response of various strains of inbred mice of different H-2 specificities was investigated using the passive cutaneous anaphylactic technique (PCA) for the detection of the antibody response. Neither IgC₁ nor reaginic antibody were detected in serum samples obtained at the end of the first week of infection with Trichinella spiralis. Subsequently, all animals had detectable IgG₁ antibodies, although in some strains the titers were very low. Reaginic antibody was detected in relatively high titers in C57L, A, and DBA/1 mice. Two other strains were very poor responders (SJL and AKR). In most strains, reagin and IgG₁ remained detectable for 14 wk or longer. The pattern of response of all strains was very reproducible, indicating genetic control of the anaphylactic antibody production to the infection. In F₁ hybrids obtained from crosses between good and poor anaphylactic antibody responders, intermediate levels of both antibody classes were detected.Adult worm recovery rates were established at various points during the intestinal phase of infection, and no correlation between worm numbers and reaginic antibody titers in the various strains of mice could be demonstrated. There were noticeable differences in larval yields obtained after muscle digestion of mice belonging to the different inbred strains. In fact, we generally observed an inverse relationship between the number of larvae recovered from a given strain and their reaginic antibody titer.The intravenous injection of newborn larvae (NBL), obtained upon in vitro incubation of adult worms, produced detectable antibodies only in mice of the DBA/1 strain. These antibodies were consistently of low titer and became detectable only after the administration of two additional injections of NBL. This contrasted with the results observed after “per os” infection of DBA/1 mice, where high titers of these antibodies were always obtained, in spite of comparable ratios of muscle larval yield.     

Relation between Enhanced Antibody Responses Elicited by Adjuvant Injection and Those Elicited by Secondary Antigenic Stimulation

An attempt was made to determine if there is any common mechanism in the enhanced antibody response caused either by injection of adjuvant, such as bacterial endotoxin (LPS) and complexed polynucleotides, or by secondary antigenic stimulation. LPS inoculated in mice 4 days before injection of sheep red blood cells (SRBC) and polyA:U invalidated the adjuvant effect of polyA:U injected together with SRBC, and the hemolysin plaque-forming cell (PFC) response of such mice was similar to that of the mice which received SRBC alone. When mice primed with SRBC 24 days in advance were injected with LPS and 4 days later re-stimulated with SRBC, their PFC response to the secondary stimulation was suppressed to less than one tenth of the normal secondary PFC response. The suppressive effect of LPS on the secondary antibody response was abolished if the serum collected from mice injected with LPS was given to the primed and LPS-injected mice at the time of the secondary antigenic stimulation. From these results we discussed the possibility that some common mediator might play a role in the enhanced antibody response elicited by either adjuvant injection or secondary injection of antigen.     

Genetic control of the immune response

(1) Inbred strains of mice when immunized withp-aminobenzoic acid and sulphanilic acid bound by diazo-linkage to the same protein carrier molecule (bovine gamma globulin) differ in their ability to respond by antibody formation. The strains A and CBA/J form only low levels of antibodies to the haptens after immunization; in strains ScSN and B10.LP the same high titers of antibodies to both haptens were found under these conditions. The strain B10.D₂ forms antibodies well to sulphanilic acid, antip-aminobenzoic acid antibodies are formed only in very low quantity. (2) Individual mice of an inbred strain form a homogeneous population in respect of their capability or inability to form a particular antihapten antibody. The individual titers in a given inbred strain vary only slightly. On the contrary the noninbred strain H shows great variability both in quantity and quality of the immune response to the haptens. (3) The crossing of good and poor anti-hapten antibody producing strains shows in F₁; F₂ and B₁ generation, that the ability to produce antibodies againstp-aminobenzoic and sulphanilic acid depends on the genotype of a given individual. The ability to respond is transmitted to the offspring as a dominant trait. (4) There is no difference in the response to the haptens between males and females of the same strain. (5) The antibodies to the haptens in different strains of mice differ in the ratio of 2-mercaptoethanol sensitive and 2-mercaptoethanol resistant antibody. Dedicated to Academician Ivan Málek on the occasion of his 60th birthday     

Animal models in Q fever: pathological responses of inbred mice to phase I Coxiella burnetii

The susceptibility of inbred strains of mice to infection by phase I Coxiella burnetii, the aetiological agent of Q fever, was investigated by evaluating morbidity, mortality, antibody production and in vitro proliferative responses of splenic lymphocytes. Among the 47 strains of mice tested for morbidity and mortality to C. burnetii infection, 33 were resistant, 10 were of intermediate sensitivity, and four were sensitive. A/J mice exhibited the highest mortality, and surviving mice of this strain yielded high concentrations of viable rickettsiae from essentially all organs for more than 3 weeks after inoculation. However, A/J mice developed a protective immune response after vaccination with inactivated C. burnetii cells. Induction of gross pathological responses and antibody production were similar in sensitive mice (strain A/J) and resistant mice (strain C57BL/6J). The LD50 of phase I C. burnetii for A/J mice was about 1000-fold lower than that for the more resistant C57BL/6J mice. Mice of both strains developed antibody titres against phase I cells, phase II cells, and phase I lipopolysaccharide after the injection of one or more viable phase I organisms of C. burnetii; five or more rickettsiae caused splenomegaly that was almost proportional to the infecting dose. Suppression of in vitro proliferative responses of splenic lymphocytes to concanavalin A, a T-cell mitogen, was apparent after infection of sensitive A/J mice with as few as one to five phase I micro-organisms. However, suppression of proliferation of splenic lymphocytes from resistant C57BL/6J mice required 10(7) phase I C. burnetii.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

Delayed hypersensitivity against hamster erythrocyte antigen was examined after sensitization with hamster erythrocytes (HRBC) in Freund's complete adjuvant (FCA). Extent of the delayed hypersensitivity was determined by the migration inhibition test, the peritoneal macrophage disappearance test and the skin test in the ear using solubilized HRBC as the test antigen. 1) Delayed hypersensitivity against HRBC developed earlier in high-responder SL mice than in low-responder C57BL/6 mice after sensitization. The period required for development of the delayed hypersensitivity in AKR mice was intermediate between periods in high-responder SL mice and low-responder C57BL/6 mice. 2) After sensitization with HRBC in FCA, a delayed hypersensitive state without detectable antibody production persisted until day 12 in high-responder SL mice and until day 16 or later in low-responder C57BL/6 mice. 3) Delayed hypersensitivity against HRBC antigen persisted even after the appearance of circulating antibody which occurred late after sensitization with HRBC in FCA or after intravenous injection of HRBC into sensitized mice.     

Delayed maturation of the antibody response to type 2 thymus-independent antigens in a partially inbred strain of chicken

The ontogeny of antibody responses to trinitrophenylated (TNP) thymus-independent (TI) antigens was compared in two partially inbred strains of chicken: the SC strain (B2/B2 genotype) and the FP strain (B15/B22 genotype). In the SC chicken, maturation of both the splenic anti-TNP plaque-forming cell (PFC) response and the 19S hemagglutinating antibody response to TI type 2 (TI-2) antigens, TNP-Ficoll and TNP-dextran, were delayed to a significantly later time in ontogeny (20 wk of age) than in the FP chickens (9 wk of age). Four- to 6-wk-old SC chickens were virtually immunologically unresponsive to stimulation with TI-2 antigens. The TI-1 antigen TNP-Brucella abortus was equally immunogenic in both FP and SC chickens of different age groups tested. Kinetic studies of the primary PFC response to TNP-Ficoll in immunologically mature chickens of the SC and FP strains demonstrated a peak PFC response 4 days after antigen injection, followed by a rapid decline in numbers of splenic PFC/spleen on day 6. The results of these studies are discussed in relation to earlier observations that suggested there may be a delay or a defect in the ontogeny of the thymus in the SC chicken.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

C57BL/6 and AKR mice were treated with hamster erythrocytes (HRBC) in complete Freund's adjuvant (CFA) or incomplete Freund's adjuvant (IFA) and the development of delayed hypersensitivity and antibody production were examined. 1) Delayed hypersensitivity against HRBC antigen, as determined by the peritoneal macrophage disappearance test, was detected in mice sensitized with HRBC in CFA but not in those sensitized with HRBC in IFA. 2) Antibody production against HRBC or hapten TNP after a booster injection of HRBC or trinitrophenylated HRBC (TNP-HRBC) in saline was enhanced by pretreatment with HRBC in CFA or IFA. 3) Delayed hypersensitivity was not detectable after a booster sensitization with HRBC in CFA in mice which had been pretreated with HRBC in IFA 2 weeks earlier. In the mice treated with both HRBC in IFA (day ?21) and in CFA (day ?7), however, an enhanced antibody production against HRBC or TNP was detected after an intravenous injection with HRBC or TNP-HRBC in saline (day 0). These results suggest that sensitized effector lymphocytes in delayed hypersensitivity and helper cells in antibody production may be derived from the same pool of unprimed T cells. The pool of unprimed T cells with a capacity to differentiate into either type of primed T cells may be exhausted after pretreatment with the antigen in IFA, and the primed helper T cells may not be able to differentiate into sensitized lymphocytes even after sensitization with the antigen in CFA, which favors development of delayed hypersensitivity in normal controls.     

Susceptibility of inbred Syrian golden hamsters (Mesocricetus auratus) to lethal disease by lymphocytic choriomeningitis virus

An acutely lethal LCMV disease model has been established in the Syrian golden hamster (Mesocricetus auratus) in which lethality and disease are dependent upon both the inbred hamster strain and the LCMV strain. Young adult inbred, male and female, hamsters were tested for lethal-disease susceptibility by lymphocytic choriomeningitis virus (LCMV) strains, WE or Armstrong (ARM). With WE inocula, PD4 and MHA inbred hamsters were highly susceptible to a wasting disease. LVG and LHC inbred hamsters were intermediate in susceptibility; some of these animals died of wasting illness, and others exhibited minimal disease and survived. CB and LSH hamsters were highly resistant to any disease by WE. Mean survival times of susceptible hamsters given lethal WE inocula approximated 2.5 weeks and were not dependent on virus dose. By 1.5 weeks after WE inoculation wasting disease signs were notable and consisted of lethargy, progressive body weight loss, and diarrhea. The LCMV strain, ARM, was avirulent for all hamster strains, causing neither death nor disease. Hamsters surviving WE or ARM inoculation appeared healthy, produced LCMV antibody, and acquired resistance to further lethal WE challenge. Despite hamster-lethality differences. WE and ARM appeared comparably immunogenic for all hamster strains, based on host antibody titers. A number of other differences between the LCMV strains were, however, noted which could be relevant to virus virulence and lethality for hamster hosts. These included guinea pig lethality, temperature sensitivity, and plaque morphology.     

IL-1 as adjuvant. Role of T cells in the augmentation of specific antibody production by recombinant human IL-1 alpha

Human rIL-1 alpha significantly enhanced splenic plaque-forming cells (PFC) to SRBC in vitro and in vivo. A single i.p. injection was sufficient to produce a fivefold or greater increase in the generation of PFC in a primary response. IL-1 treatment resulted in an increased production of Ag-specific PFC, both in vitro and in vivo, in combination with suboptimal doses of Ag. When IL-1 was given with a primary dose of Ag in vivo, an enhanced IgG response occurred. IL-1 enhanced in vivo carrier priming for an anti-hapten PFC response, indicating increased Th activity. Furthermore, T cells from spleens of mice treated with IL-1 provided significantly more help in both carrier (SRBC)- and hapten (TNP)- specific PFC. The enhancement of PFC by IL-1 in vitro occurred even in the presence of an excess of neutralizing anti-IL-2 antibody. These results suggest that IL-1 may enhance T cell-dependent antibody production in part by increasing Th activity, and that the mechanism of IL-1 action in increasing antibody production involves pathways in addition to the induction of IL-2 secretion.     

IgG1 hypergammaglobulinaemia in chronic parasitic infections in mice: evidence that the response reflects chronicity of antigen exposure.

The IgG1 molecules in the sera of IgG1 hypergammaglobulinaemic mice chronically infected with the larval cestode, Mesocestoides corti, are a heterogeneous population. Although antibodies to M. corti are present, the question of whether a minority or majority of the serum IgG1 molecules has anti-parasite reactivity remains open. The splenic PFC response to an intravenous injection of SRBC in M. corti-infected mice does not consist of an unusually high proportion of IgG1 anti-SRBC PFC. Moreover, the adoptive anti-DNP PFC response of spleen cells from M. corti-infected mice to DNP-M. corti is not biased towards IgG1 antibody production. Since IgG1 hypergammaglobulinaemia is seen in mice with chronic, "high-dose" infections, an attempt has been made to simulate chronic antigenic exposure with SRBC in uninfected mice. A split, high-dose regime of SRBC injections leads to a high number and high proportion of IgG1 anti-SRBC PFC in the spleen in three strains of mice. The results suggest that the extraordinarily high levels of IgG1 seen in the sera of mice chronically infected with the metazoa, M. corti and Nematospiroides dubius, reflect persistent, high-dose, "strong", T cell-dependent stimulation of the B cell system.     

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.