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.     

Recruitment of null cells during graft versus host reactions in the chicken

Untreated SC (B2/B2) chicken spleen or thymus cells (2 × 10⁷) caused significantly increased [³H]thymidine incorporation in spleens of heavily irradiated FP (B15/B21) recipient chicks on Day 4 after iv injection. Mitomycin-treated SC spleen cells or spleen cells treated with rabbit anti-T-cell serum and complement failed to raise the [³H]thymidine incorporation over that in uninjected, bursa cell-injected or FP spleen cell-injected controls. However, the combination of mitomycin-treated spleen or thymus cells and anti-T-treated spleen cells caused an increased [³H]thymidine uptake, suggesting the recruitment of non-T cells into proliferation by alloreactive mitomycin-treated T cells. Bursa cells did not proliferate during GVH reactions even though they could be shown to undergo proliferation in vivo upon mitogen (lipopolysaccharide and dextran sulfate) stimulation. In contrast, anti-T-treated spleen cells from agammaglobulinemic chickens were recruited into proliferation, suggesting that the recruited cell was not only not a T cell, but also no pre-B or B cell and most likely represented a cell of the monocyte-macrophage series.     

Evidence for the presence of precursor B cells in normal and in hormonally bursectomized chick embryos

Embryonic bone marrow of normal and hormonally bursectomized chicks was examined for the presence of hematopoietic precursor cells capable of migrating to the thymus and bursa and of differentiating into functional T and B cells, respectively. Following transfer of chromosomally marked bone marrow of normal and in ovo bursectomized 14-day-old embryos to 14-day-old γ-irradiated embryonic recipients, donor cells proliferated in the marrow, thymus, and bursa of recipients, and differentiated to PHA- and Con A-responsive T cells as well as to dextran sulfate- and anti-immunoglobulin-responsive B cells. In contrast, when marrow of 2-day-old hatched normal and in ovo-bursectomized donors was transferred to 14-day-old embryonic recipients, donor cells repopulated only the marrow and thymus of recipients which was followed by differentiation to Con A- or PHA-responsive T cells, but the same donor cells failed to proliferate in the bursa and there was no differentiation to functional B cells of donor type. The data were fitted to a model of T- and B-cell differentiation from the stem cell level and they suggest the presence of separate populations of committed precursor T (PT) and precursor B (PB) cells in the marrow of normal and in ovo bursectomized embryos with a bursa-independent selective disappearance of PB cells from the marrow during the late embryonic period.     

Transfer of agammaglobulinemia in the chicken. I. Generation of suppressor activity by injection of bursa cells

Spleen cells from adult agammaglobulinemic (bursectomized) chickens taken 1 to 3 weeks after an injection of histocompatible bursa cells can inhibit the adoptive antibody response to B. abortus of normal spleen or bursa cells in irradiated recipients. Spleen cells from Aγ chickens not injected with bursa cells generally do not. Moreover, bursectomized chickens which have been reconstituted with spleen cells within the first week after hatching do not respond with suppressor cell formation upon bursa cell injection. This apparent “autoimmunization” with bursa cells induces suppressor T cells which are only minimally sensitive to treatment with mitomycin C or to 5000 R γ irradiation. The suppressor activity is neither induced nor potentiated by concanavalin A in vivo. It is much stronger in spleen than in thymus cells and appears to be macrophage independent and to require intact cells. The cell component which stimulates the suppressor activity is more pronounced on bursa than on spleen cells, and is at most present to a very limited extent on bone marrow, thymus, or peritoneal exudate cells. It is better represented in comparable cell numbers of Day 17 than of Day 14 embryonic bursa. The inducing cell component is present in the membrane fraction of disrupted bursa cells. Immunization with bursa cells from B locus histoincompatible chickens leads to suppressor activity against histocompatible bursa cells. Although the removal of Ig-bearing cells from bursa greatly diminishes its immunizing capacity, injection of serum IgM and IgG does not induce suppressor cells. It is suggested that tolerance to a B-cell antigen is lacking in adult Aγ chickens, resulting in an autoimmune response upon exposure to B cells. The B-cell antigen may be a cell surface-specific form of Ig, a complex of Ig and a membrane component, or a differentiation antigen which appears simultaneously with Ig during ontogeny.     

Relationship between the expression of class I antigen and reactivity of chicken thymocytes

The expression of major histocompatibility complex (MHC) class I antigens in ontogenesis and the distribution of B-F⁺ cells, defined by means of a monoclonal antibody, were studied by indirect membrane immunofluorescence tests on suspensions of thymus, bursa, spleen, peripheral blood lymphocytes (PBL) and red blood cells (RBC) from 18-day-old chicken embryos and chickens from 1–90 days after hatching. At 18 days of incubation and at the first day after hatching, RBC, PBL, and the cells from bursa and thymus are negative. The percentage of positive PBL and bursal cells increases up to 9 days after hatching. By 2 weeks after hatching almost 100 % of the RBC, PBL, bursa, and spleen cells were positive whereas the thymus showed only 20% positive cells. Analysis on 4-m-thick, frozen acetone-fixed tissue sections of thymus showed that medullary cells are positive, while the cortical area is negative. The graft-versus-host (GvH) competence of these thymus subpopulations was compared after sorting by the fluorescence-activated cell sorter and injection into MHC incompatible embryos. GvH reactivity was associated primarily with the B-F⁺ population. Double staining studies with peanut agglutinin (PNA)-fluorescein isothiocyanate and a rabbit-anti-Ig tetramethyl isothiocyanate-conjugate proved that the PNA^– thymocytes are identical with B-F⁺ thymocytes.Abbreviations used in this paper: FACS fluorescence-activated cell sorter - FCS fetal calf serum - FITC-Ig fluorescein isothiocyanate-conjugated immunoglobulin - GvH graft-versus-host - HAT hypoxanthineaminopterin-thymidine - HBSS Hanks' balanced salt solution - IIF indirect immunofluorescence - MCA monoclonal antibody - MHC major histocompatibility complex - NWL normal white Leghorn - OS Obese strain - PBL peripheral blood lymphocytes - PBS phosphate-buffered saline - PNA peanut agglutinin - RBC red blood cells - TRITC-Ig tetramethyl isothiocyanate-conjugated immunoglobulin     

Expression of endogenous avian myeloblastosis virus information in different chicken cells.

Uninfected chicken cells were found to contain endogenous avian myeloblastosis virus (AMV)-specific information. Different tissues from chicken embryos and chickens expressed different amounts of the AMV-specific information. The endogenous AMV-related RNA was most abundant in bone marrow cells, which contained about 20 copies per cell. About 5 to 10 copies of AMV endogenous RNA per cell were found in embryonic yolk sac cells and bursa cells. The spleen, muscle, liver, and kidney cells of chickens and the fibroblasts of chicken embryos contained about two copies per cell. The amounts of AMV endogenous RNA in bone marrow, yolk sac, and bursa varied with age. From 19-day-old embryos to 2-week-old chickens, the bone marrow contained 20 copies of AMV RNA per cell. Bone marrow cells from 2-year-old chickens contained five copies per cell. Yolk sac cells of 10-day-old embryos and 1-day-old chickens were found to contain two copies per cell, whereas in 15- to 17-day-old embryos, these cells contained 5 to 10 copies. These results indicate that the level of endogenous AMV expression correlates with the development of granulopoiesis of the chicken hemopoietic system. The results of experiments on the thermostability of RNA-DNA hybrids indicated that the endogenous AMV RNA is closely related to viral AMV RNA. The expression of endogenous AMV information is independent of the activity of the chick helper factor. This endogenous AMV information is expressed as 20 to 21S RNA in both bone marrow and yolk sac cells.     

Bu-1 andTh-1, two loci determining surface antigens of B or T lymphocytes in the chicken

Alloantisera were prepared by reciprocal immunizations with bursal or thymic lymphoid cells between chickens of two inbred lines identical at theB major histocompatibility locus. In cytotoxic assays, antibursa sera were specific for donor-line bursa cells without absorption; antithymus sera were similarly specific for donor-line thymus cells. Both types of sera cytolyzed some peripheral lymphoid cells from spleen, bone marrow, and blood. Absorption of either type of serum with peripheral blood leukocytes removed all cytotoxic reactivity for central lymphoid cells. The inheritance of the alloantigens detected by these specific antisera was studied in F₁, F₂, and backcross progeny from the two lines. Phenotypes were determined by a method in which antisera preabsorbed with progeny leukocytes were reacted against⁵¹Cr-labeled bursal or thymic cells from chickens of both lines. The results established two independent autosomal loci-Bu-1 andTh-1-determining antigens expressed, respectively, on bursal cells and peripheral B lymphocytes or on thymic cells and peripheral T lymphocytes. Cytotoxic testing of bursal or thymic cells from chickens of other inbred lines and F₁ populations led to the tentative conclusion that the number of alleles atBu-1 is restricted, whileTh-1 exhibits considerable multiple allelism.     

Differential Selection of Cells with Proviral c-myc and c-erbB Integrations after Avian Leukosis Virus Infection

Avian leukosis virus (ALV) infection induces bursal lymphomas in chickens after proviral integration within the c-myc proto-oncogene and induces erythroblastosis after integration within the c-erbB proto-oncogene. A nested PCR assay was used to analyze the appearance of these integrations at an early stage of tumor induction after infection of embryos. Five to eight distinct proviral c-myc integration events were amplified from bursas of infected 35-day-old birds, in good agreement with the number of transformed bursal follicles arising with these integrations. Cells containing these integrations are remarkably common, with an estimated 1 in 350 bursal cells having proviral c-myc integrations. These integrations were clustered within the 3′ half of c-myc intron 1, in a pattern similar to that observed in bursal lymphomas. Bone marrow and spleen showed a similar number and pattern of integrations clustered within 3′ c-myc intron 1, indicating that this region is a common integration target whether or not that tissue undergoes tumor induction. While all tissues showed equivalent levels of viral infection, cells with c-myc integrations were much more abundant in the bursa than in other tissues, indicating that cells with proviral c-myc integrations are preferentially expanded within the bursal environment. Proviral integration within the c-erbB gene was also analyzed, to detect clustered c-erbB intron 14 integrations associated with erythroblastosis. Proviral c-erbB integrations were equally abundant in the bone marrow, spleen, and bursa. These integrations were randomly situated upstream of c-erbB exon 15, indicating that cells carrying 3′ intron 14 integrations must be selected during induction of erythroblastosis.     

Effect of tumor immunity on the distribution of labeled lymphoid cells in tumor-challenged mice

The distribution of ⁵¹Cr-labeled lymphoid cells from normal mice and mice immunized against a tumor were compared after intravenous inoculation of the labeled cells into normal syngeneic recipients. Spleen cell preparations from immune donors contained increased percentages of spleen and bone marrow-seeking cells, thus suggesting expansion of these cell populations when immunity to a tumor exists. Homing of labeled normal cells in tumor cell-injected normal animals was somewhat different from that seen in tumor cell-inoculated mice that were immunized against the tumor. In the latter case, accumulations of lymph node and spleen cells in recipient lymph nodes and bone marrow were consistently lower. In contrast, lymphoid cells from animals immunized against the tumor were found to accumulate in virtually the same percentages in lymphoid organs of normal and immune recipients. The behavior of lymphoid cell populations from thymus or bone marrow that consist mainly of precursor cells was unaffected by presence of malignancy and/or tumor immunity.     

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.     

Ability of chicken B cells from different compartments to respond to TNP-Ficoll

The responsiveness of chicken B cells from various compartments to T-independent antigens was studied by immune transfers of spleen and bursa cells into immunosuppressed recipients. Bursa cells from 8- to 10-wk-old donors failed to respond to trinitrophenylated Ficoll (TNP-F) even when thymus cells or splenic T cells were added. Spleen cells from the same donors transferred responses, as judged both by anti-TNP plaque-forming cells (PFC) per spleen and serum anti-TNP titers. In contrast, responses to TNP-Brucella abortus (TNP-BA) were transferred at least as well as by bursa as by spleen cells. Rabbit anti-chicken T cell serum plus complement treatment of the spleen cells reduced their ability to transfer responses to sheep erythrocytes, but either did not affect or enhanced serum antibody responses to TNP-BA and TNP-F. In intact animals, responsiveness to i.v. injected TNP-F was found to develop slowly after hatching in the chicken. At the age of 2 and 3 mo, PFC/spleen on day 4 after TNP-F injection were only 20% and 40%, respectively, of the adult response. Thymectomy at hatching further delayed this development, resulting in 12% and 45% of the adult control response at ages of 3 and 4 mo. It is concluded that responsiveness to the TI-2 antigen, TNP-F, develops slower than that to the TI-1 antigen, TNP-BA, and is restricted to the splenic B cell compartment. In addition, this development appears to be faster in the presence rather than in the absence of the thymus. In view of the previously shown effect of thymus on bursa development, these data suggest that the maturation of TI-1 antigen (TNP-F)-respondent chicken B cells requires residence in both the bursa and spleen before the development of responsiveness to such antigens.     

Ontogeny of lymphocytes expressing J chain in chickens

The ontogeny of chicken lymphocytes expressing J chain (LEJ) was investigated in the embryonic bursa of Fabricius, the spleen, and the thymus. Simultaneous appearance of LEJ was detected in the bursa and spleen on Day 14 of incubation. These cells were detected later in the thymus. The LEJ were found to increase rapidly in the spleen from the 19th to 20th incubation day. In adult chickens, the highest percentage of LEJ was also found in the spleen. These cells were seen in the thymus at a lower frequency. Intermediate numbers were found in bursal and peripheral blood lymphocytes. The frequencies of the LEJ were similar to those of lymphocytes positive for cytoplasmic immunoglobulins (Ig) IgA and IgM, but were not related to the number of lymphocytes expressing surface Ig. It is possible to consider that the suitable site for LEJ is the spleen, on the basis of the rapid increase in the number of LEJ just before hatching and from the fact that the highest value is found in adult chickens. Furthermore, LEJ may participate in secretion of IgA or IgM but not be associated with the expression of surface Ig.     

Restricted expression of an MHC alloantigen in cells of the erythroid series: A specific marker for erythroid differentiation

The spectrum of reactivity with various types of cells of a monoclonal antibody (CH-4) which detects a private MHC antigen of chickens was analysed. CH-4 agglutinates only RBCs that possess the B² (MHC) haplotype. A new rosetteforming cell (RFC) assay was devised to detect individual cells (excluding RBCs) that possess the CH-4 specificity on their cell surfaces. RBCs that have CH-4 chemically coupled to their surfaces attach to, and form rosettes with, B² antigen-bearing cells. Most non-RBC RFC were detected in active erythropoietic organs (adult bone marrow and embryonic spleen), and none were found in organs where erythropoiesis does not occur: adult thymus and bursa. Preincubation of bone marrow cells with CH-4 plus complement almost completely inhibits their capacity to form CFU-E without affecting their ability to form GM-CFU. In addition, CH-4 plus complement does not inhibit the capacity of B²/B² lymphocytes to induce a graft-versus-host reaction under conditions where anti-B² lymphocyte alloantisera are completely inhibitory. Our results strongly suggest that CH-4 monoclonal antibodies detect a private specificity on a gene product of the B-G locus whose expression is restricted to erythroid stem cells and erythrocytes.     

Histologische Untersuchungen an lymphatischen Organen des Huhnes (Gallus domesticus) während des ersten Lebensjahres

Zusammenfassung Bursa Fabricii, Thymus, Milz und Zäkaltonsillen von 63 Hühnern im Alter von 1 Tag bis zu 1 Jahr werden histologisch untersucht, wobei das Vorkommen der als bursaabhängig geltenden Keimzentren und Plasmazellen quantitativ erfaßt wird. Beide treten in der Milz und Tonsilla caecalis erst während des Reifestadiums der Bursa in zunehmender Menge auf. Mit Beginn der Bursainvolution werden Keimzentren und pyroninophile Zellen in der Milz selten, während in den Zäkaltonsillen kaum Veränderungen auftreten. Im Thymus verschiebt sich das Verhältnis zwischen Mark- und Rindenbreite zugunsten des Marks. Bei 8 Monate alten Tieren fehlt die Rinde vollständig. Plasmazellen treten im Thymusmark während des Reifestadiums der Bursa auf und nehmen mit dem Beginn deren Involution zu. In dem Zeitraum zwischen 2 Wochen und 5 Monaten ändert sich das Verhältnis zwischen reifen und unreifen Plasmazellen beständig zugunsten der reifen Plasmazellen.

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Histological studies of lymphatic organs in the chicken (Gallus domesticus) in the first year of age

Summary Bursa of Fabricius, thymus, spleen and cecal tonsils were histologically examined with special reference to the number of bursa-dependent germinal centers and plasma cells in 63 chickens, 1 day to 1 year old. Both structures appear in spleen and cecal tonsils increasingly during the bursal maturity stage. At the beginning bursal involution, germinal centers and pyroninophilic cells become rare in the spleen, in contrary no changes appear in the cecal tonsils. The medulla cortex ratio of the thymus changes in favour of the medulla, in animals 8 months of age the cortex is absent. Plasma cells appear in the medulla of the thymus during the bursal maturity stage and increase in number with beginning involution. During the period of 2 weeks to 5 months the proportion between mature and immature plasma cells changes in favour of mature cells.

Für technische Mitarbeit danke ich Frau U. Weinandt und Frau A. Schick.     

Responsiveness of Thymus Cells to Syngeneic and Allogeneic Lymphoid Cells

THE thymus is necessary for the normal development of cell-mediated immunity in mice as shown by the immunological defects after neonatal thymectomy¹. Thymus cells themselves can be stimulated by allogeneic lymphoid cells in mixed leucocyte reaction (MLR)² and become killer cells or cytotoxic lymphocytes after stimulation with allogeneic spleen cells in vitro (H. Wagner and M. Feldmann, unpublished work) and in vivo^3,4. This suggests that the thymus as well as peripheral lymphoid tissues contain T cells which can be stimulated by foreign histocompatibility antigen to divide and differentiate into the cytotoxic lymphocytes which mediate cellular immunity. There have been suggestions that thymus cells might be stimulated to divide by “self” antigen, as well as foreign cells: incorporation of ³H-thymidine above background levels has been found in cultures with syngeneic spleen and thymus cells of adult rats⁵, although the experiments do not determine whether thymus or spleen cells have been stimulated. In contrast to these experiments, Howe et al. reported that only thymus cells of neonatal CBA mice reacted to allogeneic and syngeneic spleen cells of adult animals in “one way” MLR cultures^6,7. Whether the reaction of neonatal thymus cells to syngeneic adult spleen cells is recognition of “self” antigens is uncertain, since spleens of adult mice could carry antigens which do not occur in neonatal animals and are therefore “unknown” for neonatal thymus cells. We demonstrate here that neonatal thymus cells do not react to 4-day-old CBA spleen cells, but adult thymus cells do react against both allogeneic and syngeneic adult spleen cells.     

Effects of Dietary Selenium on Selenoprotein W Gene Expression in the Chicken Immune Organs

Selenoprotein W (SelW) is expressed in the immune systems of mammals. However, its pattern of expression in the immune organs of birds is still unclear. To investigate the distribution of SelW and effects of dietary Se levels on the SelW mRNA expression in the immune organs of birds, 1-day-old male chickens were fed either a commercial diet or an Se-supplemented diet containing 0.601, 1.058, 1.514, or 2.427?mg Se per kilogram, and 1.0, 2.0, 3.0 or 5.0?mg sodium selenite per kilogram for 90?days. The immune organs (spleen, thymus, and bursa of Fabricius) were collected and examined for Se content and SelW mRNA levels. The mRNA expression of SelW was detected in all the tissues. Although Se content was the highest in the spleen, the remarkable stability of the SelW mRNA level was observed in this organ during different times of dietary Se supplementation. Se-supplemented diet can make the SelW expression levels higher within a certain range in thymus and bursa of Fabricius. The present study demonstrates that SelW is widely expressed in immune organs of birds and that Se-supplementation of the feed increases SelW expression in the thymus and the bursa of Fabricius.     

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.     

Organ localization of intravenously administered HSA I131 in chickens

A study was made on the elimination of heterologous albumin (HSA I¹³¹) from the blood of chickens and on its organ distribution. The elimination curve of heterologous antigen followed the typical three-phase pattern. An accelerated elimination of heterologous albumin as compared to the role of elimination of homologous albumin during the second phase is suggestive of specific uptake of antigen. The elimination curve of homologous albumin showed only two phases. The uptake of HSA I¹³¹ by organs was evaluated with respect to the amount of antigen present in the circulation. The highest cumulation of antigen was found in the liver and spleen after the 5th day following HSA I¹³¹ administration. A mild increase in the antigen content was found already after the 3rd day following injection. The increase in antigen concentration shown by the lung tissue and bone marrow was less marked. The increase in activity found in the bursa of Fabricius and in the thymus is attributed to tissues of other origin which could not be dissected fully from the respective tissue.     

The relative importance of the bone marrow and spleen in the production and dissemination of B lymphocytes.

The relative importance of the bone marrow and spleen in the production of B lymphocytes was investigated in guinea pigs by the combined use of [³H]TdR radio-autography and fluorescent microscopy after the staining of B cells by FITC-F(ab′)₂-goat-anti-guinea pig Ig. Large and small lymphoid cells possess sIg in the marrow and spleen but B cell turnover in the marrow exceeds that in the spleen. That newly generated bone marrow B cells are not derived from an extramyeloid bursa equivalent was demonstrated by the absence of [³H]TdR labeled B cells in tibial marrow 72 hr after [³H]TdR was administered systemically, while the circulation to the hind limbs was occluded. Pulse and chase studies with [³H]TdR showed that large marrow B cells are derived from sIg-negative, proliferating precursors resident in the bone marrow and not from the enlargement of activated small B lymphocytes. The acquisition of [³H]TdR by splenic B cells lagged behind that observed in the marrow. Three days after topical labeling of tibial and femoral bone marrow with [³H]TdR, a substantial proportion of splenic B cells were replaced by cells that had seeded there from the labeled marrow. The studies unequivocally identify the bone marrow as the organ of primary importance in B cell generation and indicate that in the guinea pig rapidly renewed B lymphocytes of the spleen are replaced by lymphocytes recently generated in bone marrow. The rate of replacement of B lymphocytes in the lymph node by cells newly generated in the bone marrow takes place at a slower tempo than in the spleen.