Intrathymic T cell differentiation in radiation bone marrow chimeras and its role in T cell emigration to the spleen. An immunohistochemical study

Immunohistochemical studies were made on the regeneration of T cells of host- and donor-type in the thymus and spleen of radiation bone marrow chimeras by using B10- and B10.BR-Thy-1 congenic mice. Both the thymic cortex and the medulla were first repopulated with thymocytes of irradiated host origin, restoring the normal histologic appearance by days 11 to 14, regardless of the H-2 compatibility between the donor and the host. In Thy-1 congenic chimeras, thymocytes of donor bone marrow origin, less than 100 cells in one thymic lobe, were first recognized at day 7, when the thymus involuted to the smallest size after the irradiation. The thymocytes of donor-type then proliferated exponentially, showing a slightly faster rate when higher doses of bone marrow cells were used for reconstitution, reaching a level of 100 million by day 17 and completely replacing the cortical thymocytes of host origin by day 21. The replacement of cortical thymocytes started from the subcapsular layer in a sporadic manner. The replacement of medullary thymocytes from host- to donor-type occurred gradually between days 21 and 35, after the replacement in the cortex was completed. In the spleen, about 1 million survived cells were recovered at day 3 after the irradiation, and approximately 60% of them were shown to be host-type T cells that were observed in the white pulp areas. The host-type T cells in the spleen increased gradually after day 10, due to the influx of host-type T cells from the regenerating thymus. Thus a pronounced increase of T cells of host-type was immunohistochemically observed in the splenic white pulp between days 21 and 28, when thymocytes of host-type were present mainly in the thymic medulla. These host-type T cells were shown to persist in the spleen for a long time, as long as 420 days after the treatment. Phenotypically, they were predominantly Lyt-1+2+ when examined at day 28, but 5 mo later, they were about 50% Lyt-1+2+ and 50% Lyt-1+2-. Donor-type T cells in the spleen began to appear at about day 14 in chimeras that were transplanted with a larger dose of bone marrow cells, whereas this was slightly delayed in those grafted with a smaller dose of bone marrow cells, starting at about day 28.(ABSTRACT TRUNCATED AT 400 WORDS)     

A role for the thymic epithelium in the selection of pre-T cells from murine bone marrow

A rat thymic epithelial cell line IT45-R1 has been previously described as secreting soluble molecules that in vitro chemoattract rat hemopoietic precursor cells. The development of such an in vitro migration assay was based on the ability of cells to migrate across polycarbonate filters in Boyden chambers. In the present paper, by using the same strategy, we studied murine bone marrow cells capable of migrating in vitro toward IT45-R1 conditioned medium. The responding cells were shown to represent a minor bone marrow subpopulation characterized by a low capacity to incorporate tritiated thymidine in vitro (less than 10% of control). Moreover, this cell subset was considerably impoverished with respect to granulocyte-macrophage CFU (less than 7% of control) and pluripotent hemopoietic stem cells (less than 12% of control). Potential generation of T cells of donor-type in the lymphoid organs of irradiated recipients was measured by using C57BL/Ka Thy-1.1 and Thy-1.2 congenic mice. Thy-1.1 irradiated mice were injected intrathymically or intravenously with the selectively migrated cell subset of Thy-1.2 donor-type bone marrow cells. The use of an i.v. transfer route allowed us to show that these cells possess thymus-homing and colonization abilities. In a time-course study after intrathymic cell transfer, these migrated cells were able to generate Thy-1.2+ donor-type thymocytes represented by all cortical and medullary cell subsets in a single wave of repopulation from day 20 to day 30 after transfer, with a peak around days 23 to 25. The degree of repopulation closely resembled that seen with unfractionated bone marrow cells in terms of absolute numbers of donor cells per thymus (82% of control, 22 x 10(6) Thy-1.2+ cells) as well as in percent donor cells per thymus (105% of control). Thy-1.2+ cells were also detected in the lymph nodes and the spleens of reconstituted recipient mice. Taken together, these results support the idea that the supernatant of the established thymic epithelium IT45-R1 induces the migration of a murine bone marrow subset that contains hemopoietic stem cells already committed to the lymphoid lineage (i.e., pre-T cells).     

Limiting dilution analysis of the stem cells for T cell lineage

Stem cell activities of bone marrow, spleen, thymus, and fetal liver cells for T cell lineage were studied comparatively by transferring the cells from these organs through i.v. or intrathymus (i.t.) route into right leg- and tail-shielded (L-T-shielded) and 900 R-irradiated recipient mice, which were able to survive without supplying hemopoietic stem cells. Cells from B10.Thy-1.1 (H-2b, Thy-1.1) mice were serially diluted and were transferred into L-T-shielded and irradiated C57BL/6 (H-2b, Thy-1.2) mice, and 21 days later the thymus cells of recipient mice were assayed for Thy-1.1+ cells by flow cytofluorometry. The percentage of recipient mice possessing donor-type T cells was plotted against the number of cells transferred, and the stem cell activity in each cell source was expressed as the 50% positive value, the number of donor cells required for generating donor-type T cells in the thymuses of 50% of recipient mice. In i.v. transfer experiments, the activity of bone marrow cells was similar to that of fetal liver cells, and about 100 times and nearly 1000 times higher than those of spleen cells and thymus cells, respectively. In i.t. transfer experiments, the number of cells required for generating donor-type T cells was much lower than that in i.v. transfer experiments, although the ratio in 50% positive values between i.v. and i.t. transfers differed among cell sources. In i.t. transfers, the 50% positive value of bone marrow cells was five times, 400 times, and 500 times higher than that of fetal liver cells, spleen cells, and thymus cells, respectively. Our previous finding that stem cells are enriched in the spleens of mice which were whole body-irradiated and marrow-reconstituted 7 days earlier was confirmed also by the present limiting dilution assay carried out in i.v. as well as i.t. transfers.     

Effect of selective T cell depletion of host and/or donor bone marrow on lymphopoietic repopulation, tolerance, and graft-vs-host disease in mixed allogeneic chimeras (B10 + B10.D2----B10)

Reconstitution of lethally irradiated mice with a mixture of T cell-depleted syngeneic plus T cell-depleted allogeneic bone marrow (B10 + B10.D2----B10) leads to the induction of mixed lymphopoietic chimerism, excellent survivals, specific in vivo transplantation tolerance to subsequent donor strain skin grafts, and specific in vitro unresponsiveness to allogeneic donor lymphoid elements as assessed by mixed lymphocyte reaction (MLR) proliferative and cell-mediated lympholysis (CML) cytotoxicity assays. When B10 recipient mice received mixed marrow inocula in which the syngeneic component had not been T cell depleted, whether or not the allogeneic donor marrow was treated, they repopulated exclusively with host-type cells, promptly rejected donor-type skin allografts, and were reactive in vitro to the allogeneic donor by CML and MLR assays. In contrast, T cell depletion of the syngeneic component of the mixed marrow inocula resulted in specific acceptance of allogeneic donor strain skin grafts, whether or not the allogeneic bone marrow was T cell depleted. Such animals were specifically unreactive to allogeneic donor lymphoid elements in vitro by CML and MLR, but were reactive to third party. When both the syngeneic and allogeneic marrow were T cell depleted, variable percentages of host- and donor-type lymphoid elements were detected in the mixed reconstituted host. When only the syngeneic bone marrow was T cell depleted, animals repopulated exclusively with donor-type cells. Although these animals had detectable in vitro anti-host (B10) reactivity by CML and MLR and reconstituted as fully allogeneic chimeras, they exhibited excellent survival and had no in vivo evidence for graft-vs-host disease. In addition, experiments in which untreated donor spleen cells were added to the inocula in this last group suggest that the presence of T cell-depleted syngeneic bone marrow cells diminishes graft-vs-host disease and the mortality from it. This system may be helpful as a model for the study of alloresistance and for the identification of syngeneic cell phenotypes, which when present prevent engraftment of allogeneic marrow.     

Maturation of bone marrow lymphocytes. III. Genesis of Fc receptor-bearing "null" cells and B lymphocytes subtypes defined by concomitant expression of surface IgM, Fc, and complement receptors.

Lymphocyte subtypes in mouse bone marrow have been analyzed according to the combination of three surface membrane markers, IgM molecules, Fc, and complement receptors (FcR, CR), expressed simultaneously on individual cells. Marrow cell suspensions were depleted of IgM-, FcR-, and CR-bearing cells, respectively, by differential centrifugation after rosetting with appropriately sensitized erythrocytes. After rerosetting, the FcR-depleted marrow fraction showed many IgM + ve but no CR + ve small lymphocytes, the CR-depleted fraction contained both IgM + ve and FcR + ve small lymphocytes, while the IgM-depleted fraction showed many FcR + ve but few CR + ve small lymphocytes. Radioautography after [³H]thymidine labeling for 1 and 4 days in vivo demonstrated an active turnover of the various lymphocyte subtypes, particularly rapid for (IgM ? ve, FcR + ve) cells. The results demonstrate the presence of three subtypes of marrow small lymphocytes which correspond with three proposed stages in the maturation of newly formed primary B lymphocytes; (a) null cells (IgM ? ve, FcR ? ve, CR ? ve), (b) IgM + ve, FcR ? ve, CR ? ve, and (c) IgM + ve, FcR + ve, CR + ve. In addition, the turnover of a sizeable population of null small lymphocytes which bear FcR, without IgM and CR, suggests the genesis of a distinct marrow lymphocyte lineage, not previously described.     

Immunocompetent cells in the chicken. II. Synergism between thymus cells and either bursa or bone marrow cells in the humoral immune response to sheep erythrocytes

Newly hatched F₁ hybrid chicks isogenic for the strong B histocompatibility locus were rendered immunologically incompetent by cyclophosphamide treatment and x-irradiation. They were then injected intravenously with thymus, bone marrow, or bursa cells together with sheep erythrocytes (SE) and received another iv injection of SE 3 days later. Splenic plaque-forming cells (PFC) and serum hemagglutinins were assayed 7 days after transfer. At donor ages of 14–26 days, cells from thymus (T) and bone marrow (BM) showed synergism when injected together, as indicated by a significantly higher geometric mean of PFC per recipient spleen in the BM + T group than in the BM group. The response of the T group was extremely low. With thymus and bursa cells from 6- to 28-day-old donors, significant synergism was demonstrated in 3 of 9 individual experiments. However, almost all the other 6 experiments showed marked differences in the same direction, and the combined probability for all experiments was < 0.001. The most striking demonstration of thymus + bursa synergism was made in 2 experiments using 1-week-old donors. Bone marrow cells from 1-week-old donors failed to cooperate with thymus, as did BM cells from older bursectomized agammaglobulinemic donors. This suggests that B cells from bone marrow originate in the bursa. Thymus-bursa cooperation was somewhat difficult to demonstrate in individual experiments using donors over 1 week of age, owing to the occurrence of some responses with bursal cells alone and to variability of response within bursa or bursa + thymus recipient groups. Synergism between thymus and bursa cells was more consistently demonstrable when irradiated normal spleen or low doses of bone marrow cells were added. These additions led to an increased response and a lowered coefficient of variation in the thymus + bursa recipient groups. The ‘third’ cell type needed for optimal response by the thymus and bursa cells together was tentatively identified as a macrophage.     

Two subpopulations of stem cells for T cell lineage

An assay system for the stem cell that colonizes the thymus and differentiates into T cells was developed, and by using this assay system the existence of two subpopulations of stem cells for T cell lineage was clarified. Part-body-shielded and 900-R-irradiated C57BL/6 (H-2b, Thy-1.2) recipient mice, which do not require the transfer of pluripotent stem cells for their survival, were transferred with cells from B10 X Thy-1.1 (H-2b, Thy-1.1) donor mice. The reconstitution of the recipient's thymus lymphocytes was accomplished by stem cells in the donor cells and those spared in the shielded portion of the recipient that competitively colonize the thymus. Thus, the stem cell activity of donor cells can be evaluated by determining the proportion of donor-type (Thy-1.1+) cells in the recipient's thymus. Bone marrow cells were the most potent source of stem cells, the generation of donor-derived T cells being observed in two out of 14 recipients transferred with as few as 1.5 X 10(4) cells. The stem cell activity of spleen cells was estimated to be about 1% of that of bone marrow cells, and no activity was found in thymus cells. By contrast, when the stem cell activity was compared between spleen and bone marrow cells of whole-body-irradiated (800 R) C57BL/6 mice reconstituted with B10 X Thy-1.1 bone marrow cells by assaying in part-body-shielded and irradiated C57BL/6 mice, the activity of these two organs showed quite a different time course of development. Spleen cells showed a markedly high level of activity 7 days after the reconstitution, followed by a decline, whereas the activity of bone marrow cells was very low on day 7 and increased crosswise. The results strongly suggest that the stem cells for T cell lineage in the bone marrow comprise at least two subpopulations, spleen-seeking and bone marrow-seeking cells. Such patterns of compartmentalization of stem cells in the spleen and bone marrow of irradiated recipients completely conform to the general scheme of the relationship between restricted stem cells and less mature stem cells, including pluripotent stem cells, which became evident in other systems such as in the differentiation of spleen colony-forming cells or of stem cells for B cell lineage.     

Post-Irradiation Thymocyte Regeneration After Bone Marrow Transplantation I. Regeneration and Quantification of Thymocyte Progenitor Cells In the Bone Marrow

Growth kinetics of the donor-type thymus cell population after transplantation of bone marrow into irradiated syngeneic recipient mice is biphasic. During the first rapid phase of regeneration, lasting until day 19 after transplantation, the rate of development of the donor cells is independent of the number of bone marrow cells inoculated. the second slow phase is observed only when low numbers of bone marrow cells (2.5 × 10⁴) are transplanted. the decrease in the rate of development is attributed to an efflux of donor cells from the thymus because, at the same time, the first immunologically competent cells are found in spleen. After bone marrow transplantation the regeneration of thymocyte progenitor cells in the marrow is delayed when compared to regeneration of CFUs. Therefore, regenerating marrow has a greatly reduced capacity to restore the thymus cell population. One week after transplantation of 3 × 10⁶ cells, 1% of normal capacity of bone marrow is found. It is concluded that the regenerating thymus cells population after bone marrow transplantation is composed of the direct progeny of precursor cells in the inoculum.     

Assessment of in situ host immunity to syngeneic tumors utilizing the multicellular spheroid model

By the 1g sedimentation method using discontinuous gradients of Ficoll solution (concentrations of 6 to 14%), keyhole limpet hemocyanin (KLH)-primed spleen cells of C3H/He or DBA/2 mice were fractionated into 4 to 10 populations after IgG antibody-coated erythrocytes (EA gamma) rosetting and then treatment with anti-Thy-1.2 + complement (C). No significant difference was observed in the distribution of isotype specificities of surface immunoglobulins on B cells in each population thus fractionated, when determined by indirect immunofluorescence staining. The mixture of the 12 and 14% Ficoll fractions contained 95% of B cells bearing Fc receptor for IgG (FcR+ gamma) and 3.58% of antigen-binding cells (ABC) for KLH, while the 8% Ficoll fraction included 15% of FcR+ gamma B cells and 1.53% of ABC. Nevertheless, the FcR- gamma B-cell-enriched populations caused intensive plaque-forming cell (PFC) responses to dinitrophenol (DNP), whereas FcR+ gamma B-cell-enriched populations generated weak responses. Noteworthy is that 4 days preculture of a population containing 95% FcR+ gamma B cells resulted in the appearance of precursor activity which was ascertained by a further 4 days culture of these cells with antigen, DNP-dextran. These findings suggest that FcR gamma bearing B cells intrinsically possess precursor activity for IgM/IgG antibody-forming cells, but lose it transiently by binding immune complexes (IC). Moreover, the titer of a factor suppressing anti-DNP PFC responses (suppressive B-cell factor, SBF) was higher in the 24-hr culture supernatants of the FcR+ gamma B-cell-enriched fraction than of the FcR- gamma B-cell-enriched fraction, suggesting that SBF is produced by FcR+ gamma B cells themselves. Thus, IC seems to play an important role for the negative feedback regulation of antibody production by stimulating FcR gamma bearing B cells.     

Immunity to Plasmodium yoelii: kinetics of the generation of T and B lymphocytes that passively transfer protective immunity against virulent challenge

Adoptive immunization of A/Tru mice with splenic B cells or T cells from syngeneic donors with a primary, nonvirulent, Plasmodium yoelii (17X) infection confers on these recipients the capacity to resist a challenge infection with a virulent strain (YM) of P. yoelii. Unfractionated spleen cells as well as spleen cells enriched for T or B cells capable of transferring protective immunity were detected as early as Day 7 of the primary nonvirulent infection, and reached peak levels on Day 14. Spleen cells that were harvested from donor animals after resolution of the immunizing infection [on Days 21 or 28] were incapable of transferring protective immunity. The capacity of 7-day immune spleen cells to transfer immunity could be abolished by pretreatment with mitomycin C. In addition, it was found that immunocompetent recipient mice were required for successful adoptive immunization, since thymectomized, irradiated, bone marrow reconstituted mice infused with immune spleen cells failed to survive lethal challenge infections.     

The origin of antibody-forming cells detected in the bone marrow after thymus-independent antigen-stimulation and abnormality in migration of B cells of X-linked immunodeficient CBA/N mice

The anti-TNP IgM plaque-forming cells (PFC) were generated in the spleen and bone marrow of non-immunodeficient normal mice after intraperitoneal administration of TNP-LPS. Irradiation of normal mice while shielding bone marrow completely abrogated the generation of bone marrow PFC, indicating that they are derived from extramedullary sites. The bone marrow PFC, response to TNP-LPS was low in X-linked immunodeficient CBA/N strain mice, while the spleen response was comparable to that seen in the normal mice. To further study the basis of the deficient bone marrow PFC response in CBA/N mice, spleen cells were adoptively transferred to irradiated syngeneic mice stimulated with TNP-LPS. While spleen cells from normal mice generated high numbers of PFC in recipient bone marrow and spleen, those from CBA/N strain mice could not generate bone marrow PFC. This result was obtained regardless of whether normal or CBA/N recipients were used. These results indicate that TNP-LPS administration normally results in the migration of B lymphocytes from the periphery into the bone marrow and that B cells from immunodeficient CBA/N strain mice bear an inherent defect in this migratory function. This migratory defect was shown to be X-linked, as are the other previously reported B cell defects in this inbred mouse strain. The possible relationship between this migratory defect and the maturational defects of B cell lineage as reported previously in CBA/N strain mice is discussed.     

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.     

Reversibility of hematopoietic stem cell direction (not 'commitment') as influenced by the microenvironment.

The 7-day colony types (E vs. G) formed in irradiated recipient spleens and bones by donor cells from adult bone marrow and spleen and early fetal liver were examined. Both direct and sequential transplant (retransplantation shortly after lodgment) experiments were carried out. It was found that recipient spleen receiving donor bone marrow, spleen or fetal liver developed significantly higher E/G ratios in that order, but that the E/G for colonies in recipient bones remained around 1. This led to the following conclusions concerning differences in the proportion of E or G colonies formed in recipient spleens and bones: (1) selective lodgment of 'committed' CFU-S does not occur; (2) selected repression or stimulation of 'committed' CFU-S does not occur; and (3) the findings are best explained by a condition of reversible directedness present in many or all transplantable pluripotent stem cells.     

Cellular aspects of tolerance. V. The in vivo cooperative role of accessory and thymus derived cells in responsiveness and unresponsiveness of SJL mice

Adult (8-week-old) SJL mice reach a relatively low degree of tolerance when injected with aggregate free rabbit γ-globulin (RGG). To analyze this phenomenon, we first examined indirect plaque-forming responses (PFC) in terms of participation of accessory and thymus-derived cells. Double transfer experiments were used; accessory cells were removed from donor cells by filtration over glasswool and their capacity reduced in recipients by 3 day preirradiation or by horse erythrocyte-mediated blockage. Using this type of experimental arrangement we found that the antibody response to RGG required the cooperation of accessory and thymus-derived cells. The induction of tolerance was affected by the presence of accessory cells. Preirradiated secondary recipients were reconstituted with spleen cells from accessory cell-deprived donors which had received thymus and bone marrow cells. In some experiments, the thymus and bone marrow cells were passed over glasswool. The primary recipients were left untreated or were given tolerogen. A more profound state of tolerance (reduction in plaque forming response) was the consequence of the incapacitation or removal of accessory cells. The magnitude of the reduction in PFC was directly related to the completeness of accessory cell removal and incapacitation. Responsiveness could be restored by administration of irradiated spleen cells as a source of accessory cells. The need for thymus-derived (T) cells in the antibody response was demonstrated by double transfer experiments in which the primary recipient was restored with thymus cells alone, bone marrow cells alone, or with a mixture of cell types.     

Ontogeny of the antibody-forming cell line in mice. IV. Appearance of cells bearing Fc receptors, complement receptors, and surface immunoglobulin.

The ontogeny of Ig, FcR, and CR-bearing cells in liver and spleen has been followed by using rosetting procedures. These studies demonstrated a sequential appearance of surface receptors during development. Two types of Ig+ cells could be distinguished according to their rosette morphology and adherence to carbonyl iron: 1) an adherent cell which bound few erythrocytes was found predominantly in fetal liver from 13 days gestation and 2) a nonadherent cell which bound larger numbers of erythrocytes appeared in small numbers in fetal liver from day-16 gestation but represented the major Ig+ cell type after birth. Changes in the proportions of receptor-bearing populations occurred at two particular periods during ontogeny. The first was at birth, where an increase in the proportion of FcR+ cells occurred and the proportion of type 2 Ig+ cells rose rapidly. This probably represented the first appearance of FcR+ B lymphocytes even though cells bearing FcR were detected in fetal liver of all ages (days 12 to 18). The second period was around 10 days after birth when the proportion of Ig+ cells again increased concomitant with the appearance of CR+ nonadherent cells.     

A Study of the Regenerative Potential of Bone Marrow Cells of Donor Mice that Carry the <Emphasis Type="Italic">egfp</Emphasis> Gene in Irradiated Mice

A study of the regenerative potential of bone marrow cells of donor mice that express the enhanced green fluorescent protein was conducted in mice irradiated at a dose of 7 Gy. Expression of this protein allowed us to carry out monitoring of the presence of donor cells in recipient blood over the entire lifespan of the recipient. The lifespan of young recipients increased by 93% after transplantation; for old recipients it increased by 15%. Total acceptance of the bone marrow, spleen, thymus, and blood of the recipient with donor bone marrow cells was demonstrated over the entire life of the recipient. Only the donor colonies were detected with the studied irradiation dose and number of transplanted cells (11.7 ± 0.4) · 10⁶ on the spleen surface. The percentage of bone marrow and spleen cells that expressed the CD117 and CD34 stem cell markers in the recipient mice was above the control level for a long period of time after the irradiation. More than half of the cells with CD117, CD34, CD90.2, and CD45R/B220 phenotypes in the studied organs were donor cells. Further detailed study of the peculiarities of the engraftment of bone marrow cells, both without preliminary treatment of recipients and after the effects of extreme factors, will allow improvement of the methods of cell therapy.     

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.     

Effect of age on the capacity of the bone marrow and the spleen cells to generate B lymphocytes

The effect of age on the regeneration of the B cell population was studied by cell transfer methods, using the allotype-congenic mouse strains BALB/c (Igha) and C.B-17 (Ighb) as donors of old and young bone marrow (BM) and spleen cells, and C.AL-20 (Igho) as recipients. This design allowed us to identify the origin of the sIgD+ B cells present in the recipients. It was found that in a simple cell transfer, BM cells or spleen cells of aged donors could reconstitute the peripheral B cell population of irradiated, thymectomized recipients essentially as effectively as could BM or spleen cells from young donors. However, when BM cells from aged donors and from young donors were mixed and were used to reconstitute a single recipient, the cells from the aged donor were less efficient than were the cells from the young donor. We found that sIgD+ B cells of young donor origin predominated in the peripheral B cell population of the recipient at 3 to 6 wk after cell transfer. In the BM of the recipients, however, there was no difference in the incidence of sIgD+ B cells derived from the young and the old donors. When recipients were reconstituted with a mixture of spleen cells from old and young mice, the sIgD+ cells of young donor allotype showed a tendency to predominate in the peripheral B cell population, although this predominance was not statistically significant. Under such competitive conditions, the spleen cells of aged donors were less efficient than the BM of aged donors in reconstituting the sIgD+ B cell population of the recipient's BM, but were more efficient in reconstituting the splenic sIgD+ cells. Thus, a subtle defect in the B cell precursor population of the BM and the spleen of aged mice has been demonstrated. The role of T cells in the generation of sIgD+ cells was also analyzed.     

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.     

Hemopoietic colony studies. VI. Increased eosinophil-containing colonies obtained by antigen pre-treatment of irradiated mice reconstituted with bone marrow cells

The cellular response to an intraperitoneal injection of antigen (tetanus toxoid) was studied in reconstituted animals in order to determine the mechanism of control of eosinophil granulocytopoiesis. Antigen treatment of the marrow cell donors did not consistently increase the number of spleen and bone marrow colonies in recipient animals or change the percentage of eosinophil or other hemopoietic colony types. Antigen pre-treatment of the irradiated recipients increased the percentage of eosinophil-containing colonies in the spleen and femoral bone marrow without significantly changing the total number of either spleen or marrow colonies. Antigen treatment of both the bone marrow cell donor and recipient produced a further increase in the percentage of eosinophil-containing colonies in the marrow cavity, but not in the spleen. Antigen treatment of the irradiated recipient increased the number of eosinophilic cells (but not the total number of cells) in both the peritoneal cavity and the bone marrow. Antigen treatment of both the marrow donor and recipient produced a further increase in the number of eosinophilic cells in the peritoneal cavity, but not in a single femur. Since antigen treatment of the marrow recipient, or recipient and donor, but not of the marrow donor alone, results in increased eosinophilic cell and colony numbers, the effect of antigen appears to be mediated through some host factor(s), perhaps the eosinophilic hemopoietic inducing microenvironment (HIM), rather than directly on the hemopoietic stem cells.