Development of antigenic heterogeneity in the splenic meshwork of severe combined immunodeficient (SCID) mice after reconstitution with T and B lymphocytes

Recently, we produced monoclonal antibodies reacting specifically with the reticular meshwork (RM) of lymphoid tissues, and demonstrated that, in the splenic white pulp of normal mouse, the antigenic heterogeneity of RM was associated with the segregation of the T and B lymphocytes. In the present study, we attempted to visualize further the interaction between splenic RM and T and B lymphocytes transferred into severe combined immunodeficient (SCID) mice. The splenic white pulp of naive SCID mice, containing a few T and B cells, showed little tendency for T-B segregation and antigenic diversity of RM. Transfer of spleen or bone marrow cells from normal mice resulted in complete recovery of lymphocyte populations, showing not only a clear segregation of T and B lymphocytes but also a remarkable antigenic diversity of RM. The same results were obtained following the transfer of spleen or bone marrow cells from the nude mouse. Next, we transferred purified T lymphocytes to one group of SCID mice and B cells to another. In mice given T cells, a few B cells were observed in the white puop; T lymphocytes lodged not only in the inner periarterial lymphatic sheath (PALS) but also in the outer PALS and follicles. In the animals to which B cells were transferred, T cells were few and the homing of B cells occurred only into their proper compartments, such as the outer PALS, follicles and marginal zone, but not in the inner PALS. Thus, B cells can home into their proper compartments of the splenic white pulp independently of T lymphocytes.     

Allogeneic chimerism in scid mice after neonatal transfer of bone marrow.

Allogeneic chimeras are valuable tools for studies of complex immune cell interactions in vivo. Mice with severe combined immune deficiency (scid) should be ideal hosts for chimerism with allogeneic bone marrow cells as these animals lack mature T and B lymphocytes capable of reacting against donor alloantigens. However, it has been difficult to achieve full reconstitution of adult scid mice even using coisogenic bone marrow grafts without prior irradiation of the recipient. We explored ways to generate complete reconstitution of scid mice with allogeneic bone marrow. Unirradiated adult scid recipients of allogeneic bone marrow were only marginally reconstituted. Adult scid mice pretreated with 250 R were reconstituted with allogeneic bone marrow as measured by serum IgM concentration, peripheral lymphoid cellularity, and mitogen responses, but a potentially important immunologic deficit was found in these mice: 250 R caused a 70% loss of scid macrophages and dendritic cells which persisted at least 5 months. By contrast, when scid mice were injected i.p. with allogeneic bone marrow within the first 24 h after birth, rapid and complete reconstitution of both T and B cell lineages was achieved, and the animals had APC that were both donor and host in origin. Considering the extent and duration of engraftment (43 wk) by allogeneic cells in neonatally transplanted scid mice, it was anticipated that their bone marrow would be chimeric. However, the bone marrow contained very few donor-derived cells, suggesting that lymphopoiesis may be taking place in other organs in these chimeras.     

Further evidence for the existence of B-lymphocyte subpopulations.

We have studied the homing properties of B lymphocytes by using ⁵¹Cr-labeled lymphoid cells obtained from athymic, nu/nu mice, and animals made T-lymphocyte deficient by thymectomy and lethal irradiation followed by reconstitution with syngeneic bone marrow. Comparison was made to the patterns of distribution observed when cell preparations containing normal numbers of T and B lymphocytes were migrated. A small but significant percentage of labeled lymphocytes from lymph nodes, spleen, Peyer's Patches, and bone marrow of T-cell-deficient animals was shown to be lymph node seeking. Secondary transfers of lymph node cells from primary recipients caused enrichment of this lymph node-seeking population. Treatment of T-lymphocyte-deficient lymphoid cell preparations with neuraminidase reduced the percentages of cells homing to the lymph nodes. The data showed that B lymphocytes exhibit unique homing properties when injected into normal recipients. In addition, direct comparison of the homing patterns of B lymphocytes prepared from spleen and lymph nodes of athymic mice revealed differences suggesting that these lymphoid organs contained unique mixtures of at least two different kinds of B cell. The evidence supports the notion that the B-lymphocyte populations contain at least two subpopulations, one of which possesses the ability to home to lymph nodes.     

The ontogeny and distribution of B cells in normal and mutant immune-defective CBA/N mice: two-parameter analysis of surface IgM and IgD

A dual-laser fluorescence-activated cell sorter was utilized to study the distribution of the surface IgM and IgD on individual B cells of normal and immune-defective CBA/N mice. Cells from different lymphoid organs and from developing mice were studied. Two major populations of cells were seen. Those with low densities of surface IgM and intermediate-high densities of surface IgD were relatively or totally absent from the bone marrow, spleens, and lymph nodes of adult, immune-defective (CBA/N x DBA/2)F1 male mice, and developed late in ontogeny in the lymphoid organs of normal F1 female mice. By contrast, the second major population, with intermediate-high surface IgM and low surface IgD, was found in highest frequency in the lymphoid organs of immature mice, the bone marrow of adult mice, and the lymphoid organs of F1 male mice compared to F1 female mice at any age. These two major populations of B cells were further subdivided into five groups of cells to better define the surface IgM and IgD characteristics of developing B cells of immune-defective and normal mice. The relationship of these groups of cells to populations defined by other criteria are discussed.     

B-lymphocyte differentiation in lethally irradiated and reconstituted mice. III. The influence of splenectomy on the recovery of the B-cell populations.

The recovery of the B-cell population was studied in irradiated and fetal liver-reconstituted mice. Since in irradiated and reconstituted mice the B-cell population in the spleen recovers much more rapidly than in the other lymphoid organs, we assessed the role of the spleen in the recovery of the B-cell compartment in the other organs. It was found that the absence of the spleen did not delay or diminish the recovery of the immunoglobulin (Ig)-bearing (B)-cell population in the bone marrow, lymph nodes, Peyer's patches, and peripheral blood. Throughout the recovery period the number of B lymphocytes in the lymphoid organs of splenectomized mice was even greater than in the same organs of sham-operated mice. B cells obtained from the bone marrow of splenectomized, irradiated, and reconstituted mice appeared to be fully immunocompetent, as shown by their ability to cooperate with thymocytes in an adoptive plaque-forming cell response to sheep red blood cells. The compensatory effect of the increased numbers of B cells in the bone marrow and peripheral lymphoid organs of splenectomized mice was reflected in the level of the serum immunoglobulins. Apart from a lower IgM concentration in the serum of splenectomized mice, no significant differences were found in IgG₁, IgG_2b, and IgA levels between splenectomized and sham-splenectomized mice. It is concluded that the spleen is not essential for both normal B-lymphocyte differentiation and maturation after irradiation and reconstitution.     

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.     

Full reconstitution of the immune deficiency in scid mice with normal stem cells requires low-dose irradiation of the recipients

Mice homozygous for an autosomal recessive mutation for the scid gene exhibit a defect that specifically impairs lymphoid differentiation but not myelopoiesis. Such mice can be cured of their lymphoid deficiency by grafts with normal bone marrow, although full reconstitution of lymphoid function is seldom obtained. Long-term bone marrow cultures (LTBMC) are devoid of all mature B and pre-B cells but contain lymphoid stem cells. We therefore reconstituted scid mice with LTBMC cells to study the kinetics of B lymphocyte reconstitution in normal and irradiated (4 Gy) scid recipients and in irradiated (9.5 Gy) co-isogenic C.B-17 mice. Detectable colony-forming B cells rapidly increased in the spleen and bone marrow of irradiated C.B-17 and irradiated scid recipients, reaching normal levels between 4 and 6 wk post-grafting. Unirradiated scid recipients showed limited reconstitution in spleen and very poor reconstitution in bone marrow. Unirradiated scid recipients also had relatively few surface Ig+ cells in spleen or bone marrow, whereas both groups of irradiated recipients had normal numbers between 4 and 6 wk post-reconstitution. Normal levels of cytotoxic T cell activity by 8 wk after reconstitution were observed only in the irradiated C.B-17 and irradiated scid recipients. Analysis of mice reconstituted with cells from LTBMC indicates that these cultures contain lymphoid stem cells with significant proliferative and self-renewal potential, and that full reconstitution of lymphoid function requires prior irradiation of the scid recipient.     

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.     

Effect of exposure to stress on the role of T- and B-lymphocytes in the response of the hematopoietic system

Cellular composition of the bone marrow, spleen and peripheral blood was studied after 6-hour immobilization on the back in experiments on 4 groups of (CBAxC57BL)F1 mice with varying degree of T lymphocyte deficiency (thymectomy, sham thymectomy, administration of antilymphocytic serum, B mice). The evidence obtained shows that the "lymphoid peak" recorded in the bone marrow during stress is likely to be formed at the expense of T and B lymphocyte migration from the peripheral lymphoid organs. The data have been also obtained, indicating that T lymphocytes migrating to the bone marrow during the first 6-9 hours after the exposure to stress may participate in granulocytopoiesis activation.     

Cutting edge: egress of newly generated plasma cells from peripheral lymph nodes depends on beta 2 integrin

During humoral immune responses, naive B cells differentiate into Ab-secreting plasma cells within secondary lymphoid organs. Differentiating plasma cells egress from their sites of generation and redistribute to other tissues, predominantly the bone marrow and mucosal tissues. In this study, we demonstrate that within peripheral lymph nodes newly generated plasma cells localize to medullary cords which express the beta(2) integrin ligand ICAM-1. In beta(2) integrin-deficient mice plasma cells accumulate inside the lymph nodes, resulting in severely reduced plasma cell numbers in the bone marrow. Since plasma cells isolated from beta(2) integrin-deficient animals migrate efficiently into the bone marrow when transferred i.v., our findings provide profound evidence that beta(2) integrins are required for the egress of plasma cells from peripheral lymph nodes.     

Abnormalities of B lineage cells are demonstrable in long term lymphoid bone marrow cultures of New Zealand black mice

The formation of B lymphocytes in young New Zealand Black (NZB) mice proceeds at an accelerated rate resulting in a deficiency of B lineage precursors in adult (greater than 15 wk old) animals. To study the characteristics of B lineage cells in young (4 wk) and old (6 mo) NZB mice, bone marrow from these animals was used to initiate long term lymphoid bone marrow cultures (LBMC) that permit the long term maintenance of B cells and their precursors. Age-matched cultures from BALB/c mice and NZB.xid marrow were established in parallel. Primary LBMC were readily established from these strains and showed similar patterns of growth for the 3-mo observation period. No significant differences in numbers of 14.8 positive cells were observed. However, NZB mice at both ages had a higher percentage of membrane IgM (mIgM)-expressing cells. Significant levels of supernatant IgM were found only in cultures of 6-mo NZB and BALB/c mice; levels were highest in NZB culture supernatants and were often more than 500 ng/ml; significant, although much lower, levels of IgG were likewise detected. Lymphoid cells from NZB.xid mice were unable to generate significant levels of IgM in supernatant fluids indicating the effects of the xid gene were displayed in vitro. Autoantibodies were not detected in any of the culture supernatants. Additional evidence for NZB hyperactivity in primary B lymphopoiesis was observed upon initiation of primary myeloid bone marrow cultures (MBMC) from these strains of mice and subsequently transferring them to LBMC conditions. This results in the cessation of myelopoiesis at the initiation of B lymphopoiesis. At the time of converting MBMC to LBMC, cultures of NZB and BALB/c mice morphologically resembled myeloid cultures and had neither B cell colony-forming units nor cells that expressed 14.8 or mIgM. However, following the switch, NZB mice had a 5-fold higher number of B cell colony-forming units. Further, MBMC established from NZB bone marrow cells had a reduced capacity to form colonies in the granulocyte-macrophage colony-forming unit assay. These studies indicate that defects of NZB hemopoietic cells are manifest in vitro and suggest the use of in vitro long term cultures as a valuable technique to further dissect the hematopoietic abnormalities of NZB mice and possible underlying microenvironmental defects.     

Germinal center B cells and antibody production in the bone marrow

In secondary antibody (Ab) responses, Ag processing and presentation occur in secondary lymphoid organs but most serum Ab is produced by cells in the bone marrow. Plasma cells in the bone marrow are derived from B cells activated by Ag in secondary lymphoid organs. We hypothesized that germinal center (GC) B cells, which acquire Ag from follicular dendritic cells in draining lymph nodes during the first few days of the secondary response, migrate to the bone marrow to terminally differentiate and produce specific Ab. To test this we looked for GC B cells in the thoracic duct lymph and in peripheral blood after secondary challenge using the peanut agglutininhi phenotype and blast cell morphology as markers for GC B cells. In addition, GC B cells were injected i.v. into naive recipients to determine if they would home to the bone marrow. Finally, to determine if the bone marrow environment supports maturation and Ab production by GC B cells, we cocultured GC B cells with bone marrow cells or bone marrow supernatants. The results indicate that blast cells bearing the GC B cell phenotype were present in both the thoracic duct and the peripheral blood 3 days after antigenic challenge. Day 3 peripheral blood cells secreted specific Ab, whereas cells isolated on day 0, 8, or 11 did not. Furthermore, in adoptive transfer experiments, only the day 3 GC B cells produced specific Ab and migrated to the bone marrow of naive mice. Finally, either bone marrow cells or factor(s) produced by bone marrow cells markedly enhanced Ab production by day 3 GC B cells. These data support the hypothesis that during the first few days after secondary challenge GC B cells seed the bone marrow and differentiate into plasma cells which produce the large quantities of Ab typical of secondary responses.     

Comparison of response to stem cell differentiation signals between normal and autoimmune mouse strains

Normal DBA/2 and autoimmune NZB mice were studied with regard to signals eliciting differentiation and division of bone marrow stem cells. Irradiated (NZB X DBA/2)F1 mice were repopulated with various combinations of T-depleted bone marrow from NZB and DBA/2 mice. In response to the repopulation signal of irradiation, recipients of autoimmune NZB marrow initially demonstrated expansion of LY-5+ lymphoid and hemopoietic cells, particularly of the B cell lineage. The greater the proportion of NZB marrow, the higher the percentage of lymphoid cells observed 2 wk post-repopulation. B cells (ThB-positive cells) were increased in disproportionate numbers in recipients of NZB marrow, even those that had received as little as 20% NZB bone marrow cells. However, by 2 mo, the initially observed increase in lymphoid cells in recipients of NZB marrow was no longer observed. Up to 6 mo post-repopulation, cytogenetic analysis revealed that irradiated recipients were repopulated in the same proportion of DBA/2: NZB as was in the injected marrow. Endogenous colony formation assays indicated that recipients of 100% NZB, 80% NZB, and 20% NZB marrow all had greater numbers of splenic endogenous colonies than did recipients of DBA/2 marrow alone. These studies indicated that autoimmune NZB marrow repopulated irradiated mice in the proportion in which it was injected, but there was a disproportionate early increase in cells of the B lineage as well as a disproportionate increase in splenic colony formation.     

Regeneration of natural antibody repertoire after massive ablation of lymphoid system: robust selection mechanisms preserve antigen binding specificities

Natural Abs (NAbs) are Igs present in the serum and body fluids of healthy vertebrate animals, without any previous intentional immunization. NAbs often exhibit autoreactivity but also play an essential role in immunity, being a first line of defense against infectious microorganisms. We have previously analyzed the natural serum IgM Ab repertoire of normal mice, characterizing their reactivity with hundreds/thousands of self Ags; a significant similarity among different individuals was observed, and it was found that many reactivities of NAbs stably kept during adulthood were established early in life, implicating that period as a critical time window in the physiology of NAb repertoire selection. In the work reported here, experiments were conducted to address the role of normal lymphocyte ontogeny to the formation and stability of adult NAb repertoire. The massive destruction of the lymphoid system was promoted in adult mice with gamma-irradiation, and regeneration of hemopoietic tissues was granted by bone marrow or fetal liver inoculum. NAb repertoire regeneration was followed for 60 days after gamma-irradiation in bone marrow or fetal liver chimeric animals. The analysis of serum IgM reactivity with hundreds/thousands of self Ags showed that the NAb repertoire regenerated most of its original format after massive destruction of lymphoid compartments, characterizing autoreactive repertoire selection as a robust biological process. The data also show that regeneration of the NAb repertoire occurred similarly in fetal liver and bone marrow chimeras, although the latter animals poorly reconstituted their CD5(+) B1 cell compartment, suggesting that B1 cells are not essential for natural Ab regeneration.     

Characterization of early B lymphocyte precursors present in long-term bone marrow cultures

Lymphoid precursor cells are present in long-term bone marrow cultures (LTBMC), but their differentiation into mature lymphocytes is blocked. A quantitative assay for B cell precursors in LTBMC, which gives a linear relationship between the number of grafted LTBMC cells and the frequency of B cell colony forming units (CFU-B) in the spleen and bone marrow of immunodeficient CBA/N mice 19 days after reconstitution, is described. Characterization of the B cell precursor indicates that this assay is detecting a very early precursor and not a B lymphocyte or a late pre-B cell. This conclusion is based on the observations that a) pre-B cells transformable by Abelson murine leukemia virus are not present in LTBMC by 3 days postrecharge and CFU-B are absent by 6 days postrecharge; b) late B cell progenitors capable of rapid repopulation of irradiated CBA/N mice are not present in LTBMC, since a lag in the kinetics of B cell reconstitution in animals grafted with LTBMC cells is observed compared with fresh bone marrow cells; c) the B cell precursors in LTBMC have high proliferative potential, since they can stably repopulate recipient mice for at least 8 wk postreconstitution and through two serial passages in irradiated CBA/N recipients; and d) the B cell precursors are large, rapidly sedimenting cells as determined by velocity sedimentation. The serial transplantation experiment further shows that a split is often observed between lymphoid and myeloid reconstituting ability of LTBMC cells. The LTBMC B cell precursor may be a pluripotent stem cell or a lymphoid stem cell, although its differentiative potential remains to be determined.     

Early B-cell precursors in scid mice: normal numbers of cells transformable with Abelson murine leukemia virus (A-MuLV)

scid mice lack detectable B and T lymphocytes; there are no typical pre-B cells as defined by c mu and surface markers in their bone marrow and their thymus contains only 1% of the normal number of cells. In these characters scid mice seem to lack lymphoid stem cells. However, some mice have detectable serum immunoglobulin and others develop thymomas; both observations indicate that the block in lymphoid development is not absolute. To determine whether scid mice have any B-cell precursors, we looked for pre-B cells by their ability to be transformed by Abelson murine leukemia virus (A-MuLV). Surprisingly, scid mice contain as many B-cell precursors transformable with A-MuLV as normal control mice. Cell-surface markers specific for pre-B and B cells were detected on the A-MuLV-transformed bone marrow cells of both scid and normal mice, indicating that the A-MuLV-transformed cells belong to the B lineage. Interestingly, the same surface markers were undetectable on nontransformed scid bone marrow cells. We conclude from these results that scid mice have normal numbers of early B-cell precursors but that their differentiation into functional B cells is severely impaired.     

The effect of an antigenic stimulation on proliferative response in athymic mice

The proliferation activity of the main cellular categories of bone marrow after infusion of³H-thymidine was studied in nu/nu and +/+ 1-month- and 3-month-old BALB/c mice in comparison with lymphoid cells in the spleen and mesenteric lymph nodes. The stem cell defect in nu/nu mouse bone marrow is compensated by an, increased proliferation in myeloid series and in agranulocytes. The increase of proliferation activity among lymphoid cells in peripheral lymphoid organs was observed only in the 3-month-old mice with a delay in the nudes.     

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.     

Biological aspects of limb transplantation: I. Migration of transplanted bone marrow cells into recipient

The transplanted limb contains bone marrow tissue. The hematopoietic cells contained in the bone of the graft normally differentiate after transplantation and can be released to the recipient. The cells migrate to the recipient bone marrow cavities and lymphoid organs. This causes the immune reaction between the donor and the recipient, which develops not only in the graft itself but also in the recipient immune organs where donor bone marrow cells home. The purpose of this study was to investigate the process of migration of the hematopoietic cells from the donor limb to the recipient bone marrow cavities and lymphoid tissues. The questions the authors asked were: what is the rate of release of bone marrow cells from the transplanted bone, where do the released bone marrow cells home in the recipient, how fast are donor bone marrow cells rejected by the recipient, and can some bone marrow cells homing in the recipient tissues survive and create a state of microchimerism. Experiments were performed on Brown Norway and Lewis inbred rat strains (n = 30). Limb donors received intravenous chromium-51-labeled bone marrow cells. Twenty-four hours later, the limb with homing labeled bone marrow cells was transplanted to an allogeneic or syngeneic recipient. The rate of radioactivity of bone marrow cells released from the graft and homing in recipient tissues was measured after another 24 hours. To eliminate factors adversely affecting homing such as the "crowding effect" and allogeneic elimination of bone marrow cells by natural killer cells, total body irradiation and antiasialo-GM1 antiserum were applied to recipients before limb transplantation. In rats surviving with the limb grafts for 7 and 30 days, homing of donor bone marrow cells was studied by specific labeling of donor cells and flow cytometry as well as by detecting donor male Y chromosome. The authors found that transplantation of the limb with bone marrow in its natural spatial relationship with stromal cells and blood perfusion brings about immediate but low-rate release of bone marrow cells and their migration to recipient bone marrow and lymphoid tissues. Large portions of allogeneic bone marrow cells are rapidly destroyed in the mechanism of allogeneic elimination by radioresistant but antiasialo-GM1-sensitive natural killer cells. Some transplanted bone marrow cells remain in the recipient's tissues and create a state of cellular and DNA microchimerism. A low number of physiologically released donor bone marrow cells do not seem to adversely affect the clinical outcome of limb grafting. Quite the opposite, a slight prolongation of the graft survival time was observed.     

Receptor-mediated elimination of phosphocholine-specific B cells in x-linked immune-deficient mice

The combined expression of the M167 mu/kappa anstiphosphocholine (PC) transgenes with the x-linked immunodeficiency gene, xid, results in an almost total failure to develop B cells in the peripheral lymphoid organs of such mice. Although there is no significant difference between the normal transgene positive (TG+) female offspring and the immunodeficient TG+ xid males with respect to the number of B220+ pre-B cells and IgM+B220+B cells that develop in their bone marrow, the hemizygous xid males have 85% fewer B cells in their spleens than the phenotypically normal heterozygous F1 females. In xid M167-mu-transgenic mice, PC-specific B cells also fail to develop in the spleen; however, numerous B cells bearing the mua+VH1(+)-transgene product associated with endogenous kappa L chains that do not give rise PC-specific antibodies are present. In the phenotypically normal TG+ (B6.CBA/N x mu 243-4)F1 female mice, PC-specific B cells represent almost 10% of the total B cell population, and these B cells express an M167-Id that has been produced by association of the VH1 transgene product with an endogenous V kappa 24L chain. B cells expressing the normally dominant T15-Id are not detectable in the spleens of these M167 mu-transgenic mice. Furthermore, M167-Id+ B cells are present at a fivefold lower level in the bone marrow of mu-TG+ normal mice than in their spleens. These data suggest that the PC-specific B cells that develop in TG+ xid mice are either clonally deleted via some "IgR-directed" mechanism or they fail to receive the appropriate signals to exit the bone marrow or to enter the peripheral lymphoid tissues. This hypothesis is supported by the finding that TNP-specific B cells develop normally and do not undergo clonal deletion in xid mice carrying the Sp6 mu/kappa anti-TNP transgenes.