In utero allogeneic hematopoietic stem cell transplantation to induce tolerance

Immunological Consequences of In Utero Exposure to Foreign Antigens

Immunologic tolerance refers to a state of immune nonreactivity specific to particular antigens as an important issue in the field of transplantation and the management of autoimmune diseases. Tolerance conceptually originated from Owen’s observation of blood cell sharing in twin calves. Owen’s conceptual framework subsequently constituted the backbone of Medawar’s “actively acquired tolerance” as the major tenet of modern immunology. Based upon this knowledge, the delivery of genetically distinct hematopoietic stem cells into pre-immune fetuses represented a novel and unique approach to their engraftment without the requirement of myeloablation or immunosuppression. It might also make fetal recipients commit donor alloantigens to memory of their patterns as “self” so as to create a state of donor-specific tolerance. Over the years, the effort made experimentally or clinically toward in utero marrow transplantation could not reliably yield sufficient hematopoietic chimerism for curing candidate diseases as anticipated, nor did allogeneic graft tolerance universally develop as envisaged by Medawar following in utero exposure to various forms of alloantigens from exosomes, lymphocytes or marrow cells. Enduring graft tolerance was only conditional on a state of significant hematopoietic chimerism conferred by marrow inocula. Notably, fetal exposure to ovalbumin, oncoprotein and microbial antigens did not elicit immune tolerance, but instead triggered an event of sensitization to the antigens inoculated. These fetal immunogenic events might be clinically relevant to prenatal imprinting of atopy, immune surveillance against developmental tumorigenesis, and prenatal immunization against infectious diseases. Briefly, the immunological consequences of fetal exposure to foreign antigens could be tolerogenic or immunogenic, relying upon the type or nature of antigens introduced. Thus, the classical school of “actively acquired tolerance” might oversimplify the interactions between developing fetal immune system and antigens. Such interactions might rely upon fetal macrophages, which showed up earlier than lymphocytes and were competent to phagocytose foreign antigens so as to bridge toward antigen-specific adaptive immunity later on in life. Thus, innate fetal macrophages may be the potential basis for exploring how the immunological outcome of fetal exposure to foreign antigens is determined to improve the likelihood and reliability of manipulating fetal immune system toward tolerization or immunization to antigens.

Stem Cell Transplantation in the Fetus

BACKGROUND

In utero transplantation (IUT) of hematopoietic stem cells has the potential to treat a large number of hematologic and metabolic diseases amenable to partial replacement of the hematopoietic system.

METHODS

A review of the literature was conducted that focused on the clinical and experimental experience with IUT and, in this context, the development of the hematopoietic and immune systems.

RESULTS

Successful application of IUT has been limited to the treatment of various types of immunodeficiencies that affect lymphocyte development and function. Other congenital defects such as the thalassemias have not resulted in clinically significant engraftment. Recent efforts at understanding and overcoming the barriers to engraftment in the fetus have focused on providing a selective advantage to donor stem cells and fostering immune tolerance toward the donor cells. The critical cellular components of the graft that promote engraftment and tolerance induction are being evaluated in animal models. Improvements in engraftment have resulted from the inclusion of T cells and/or dendritic cells in the graft, as well as a strategy of combined prenatal and postnatal transplantation.

CONCLUSIONS

The advantages, necessity, and benefits of early treatment will continue to encourage development of IUT as a means to treat hematopoietic and other types of birth defects.

Engraftment potential of adipose tissue-derived human mesenchymal stem cells after transplantation in the fetal rabbit

Due to their favorable intrinsic features, including engraftment, differentiation, and immunomodulatory potential, adult mesenchymal stem cells (MSCs) have been proposed for therapeutic in utero intervention. Further improvement of such attributes for particular diseases might merely be achieved by ex vivo MSC genetic engineering previous to transplantation. Here, we evaluated for the first time the feasibility, biodistribution, long-term engraftment, and transgenic enhanced green fluorescent protein (EGFP) expression of genetically engineered human adipose tissue-derived MSCs (EGFP(+)-ASCs) after intra-amniotic xenotransplantation at E17 of gestation into our validated pregnant rabbit model. Overall, the procedure was safe (86.4% survival rate; absence of anatomical defects). Stable, low-level engraftment of EGFP(+)-ASCs was confirmed by assessing the presence of the pWT-EGFP lentiviral provirus in the young transplanted rabbit tissues. Accordingly, similar frequencies of provirus-positive animals were found at both 8 weeks (60%) and 16 weeks (66.7%) after in utero intervention. The presence of EGFP(+)-ASCs was more frequent in respiratory epithelia (lung and trachea), according to the route of administration. However, we were unable to detect EGFP expression, neither by real-time polymerase chain reaction nor by immunohistochemistry, in the provirus-positive tissues, suggesting EGFP transgene silencing mediated by epigenetic events. Moreover, we noticed lack of both host cellular immune responses against xenogeneic ASCs and humoral immune responses against transgenic EGFP. Therefore, the fetal microchimerism achieved by the EGFP(+)-ASCs in the young rabbit hosts indicates induction of donor-specific tolerance after fetal rabbit xenotransplantation, which should boost postnatal transplantation for the early treatment/prevention of many devastating congenital disorders.

The case for intrauterine stem cell transplantation

The clinical burden imposed by the collective group of monogenic disorders demands novel therapies that are effective at achieving phenotypic cure early in the disease process before the development of permanent organ damage. This is important for lethal diseases and also for non-perinatally lethal conditions that are characterised by severe disability with little prospect of postnatal cure. Where postnatal treatments are limited to palliative options, intrauterine stem-cell therapies may offer the potential to arrest pathogenesis in the early undamaged fetus. Intrauterine stem-cell transplantation has been attempted for a variety of diseases, but has only been successful in immune deficiency states in the presence of a competitive advantage for donor cells. This disappointing clinical record requires preclinical investigations into strategies that improve donor cell engraftment, including optimising the donor cell source and manipulating the microenvironment to facilitate homing. This chapter aims to outline the current challenges of intrauterine stem-cell therapy.

Prenatal tolerance induction: relationship between cell dose, marrow T-cells, chimerism, and tolerance

It was reported that the dose of self-antigens can determine the consequence of deletional tolerance and donor T cells are critical for tolerance induction in mixed chimeras. This study aimed at assessing the effect of cell doses and marrow T cells on engraftment and tolerance induction after prenatal bone marrow transplantation. Intraperitoneal cell transplantation was performed in FVB/N (H-2K(q)) mice at gestational day 14 with escalating doses of adult C57BL/6 (H-2K(b)) marrows. Peripheral chimerism was examined postnatally by flow cytometry and tolerance was tested by skin transplantation. Transplantation of light-density marrow cells showed a dose response. High-level chimerism emerged with a threshold dose of 5.0 x 10(6) and host leukocytes could be nearly replaced at a dose of 7.5-10.0 x 10(6). High-dose transplants conferred a steady long-lasting donor-specific tolerance but were accompanied by >50% incidence of graft-versus-host disease. Depletion of marrow T cells lessened graft-versus-host disease to the detriment of engraftment. With low-level chimerism, tolerance was a graded phenomenon dependent upon the level of chimerism. Durable chimerism within 6 months required a threshold of > or = 2% chimerism at 1 month of age and predicted a 50% chance of long-term tolerance, whereas transient chimerism (<2%) only caused hyporesponsiveness to the donor. Tolerance induction did not succeed without peripheral chimerism even if a large amount of injected donor cells persisted in the peritoneum. Neither did an increase in cell doses or donor T-cell contents benefit skin graft survivals unless it had substantially improved peripheral chimerism. Thus, peripheral chimerism level can be a simple and straightforward test to predict the degree of prenatal immune tolerance.

Early chimerism threshold predicts sustained engraftment and NK-cell tolerance in prenatal allogeneic chimeras

The failure of engraftment in human cases of in utero hematopoietic cell transplantation (IUHCT) in which no immunodeficiency exists suggests the presence of an unrecognized fetal immune barrier. A similar barrier in murine IUHCT appears to be dependent on the chimerism level and is poorly explained by a lack of T-cell tolerance induction. Therefore, we studied the effect of the chimerism level on engraftment and host natural killer (NK)-cell education in a murine model of IUHCT. The dose of transplanted cells was found to exhibit a strong correlation with both the engraftment rate and chimerism level. More specifically, a threshold level of initial chimerism (> 1.8%) was identified that predicted durable engraftment for allogeneic IUHCT, whereas low initial chimerism (< 1.8%) predicted a loss of engraftment. NK cells taken from chimeras above the "chimerism threshold" displayed durable calibration of alloresponsive Ly49A receptors and tolerance to donor antigens. Depletion of recipient NK cells stabilized engraftment in low-level chimeras (< 1.8%). These studies illustrate the importance of the early chimerism threshold in predicting long-term engraftment and host NK-cell tolerance after in utero transplantation.

Fetal stem-cell transplantation

Fetal stem-cell transplantation is an attractive approach to the treatment of a variety of hematological, metabolic and immunological diseases before birth. The possibility of delivering a large number of cells in an early stage of life, and of taking advantage of normal fetal stem-cell migration and development, is promising. During fetal life, the capacity to mount an immune response to allogeneic cells is impaired compared with adult life. This provides an opportunity to induce tolerance to alloantigens without the need for myeloablation, although there are possible immune barriers to foreign cells in the fetus.

B7.2-/- mature dendritic cells generate T-helper 2 and regulatory T donor cells in fetal mice after in utero allogeneic bone marrow transplantation

In utero hematopoietic stem cell transplantation (IUT) results in limited chimerism and tolerance to alloantigens. We studied the relative role of B7.1 and B7.2 expression by dendritic cells (DCs) in engraftment and in generating donor-specific tolerance in fetal mice. Mature dendritic cells (mDCs) from B7.1(-/-) or B7.2(-/-) donors and wild-type (WT) lineage-depleted (lin(-)) C57BL/6 (B6) bone marrow (BM) were injected into BALB/c fetuses. Six weeks after IUT, B7.1(-/-) recipients had multilineage engraftment (4.7% +/- 0.8% T cells and 5.7% +/- 1.1% granulocytes) associated with graft-versus-host disease (GVHD) and decreased survival, but by 12 weeks only donor CD3(+) cells (2.1% +/- 1.3%) were present. Recipients of B7.2(-/-) mDCs and lin(-) WT B6 BM had exclusively CD3(+)CD4(+) T cells (11.8% +/- 8.5% at 6 weeks and 6.5% +/- 2.5% at 12 weeks). Most of the cells were T-helper 2, although 10.4% +/- 1.4% were of the T-regulatory (T(reg)) phenotype, ie, CD4(+)CD25(+). Donor T(reg) cells were detected both in the thymus and spleen, thus suggesting an effect on both central and peripheral immunity. The animals with T(reg) cells had better survival (82.3% versus 47.4%; P < .01) and no GVHD (0% versus 65%; P < .001). This group alone demonstrated multilineage engraftment of donor hematopoietic cells after postnatal transplantation with megadoses of donor lin(-) BM. Both the engrafted donor CD4(+)CD25(-) and CD4(+)CD25(+) cells induced comparable in vitro suppression of T-cell proliferation, thus suggesting their role in the persistence of the donor T cells in vivo. The CD4(+)CD25(-) cells produced interleukin 10 or interleukin 4 and were inhibited by anti-T-helper 2 cytokine-neutralizing antibodies, whereas the CD4(+)CD25(+) cells showed no evidence of any involvement of a cytokine-like soluble mediator and expressed cytotoxic T-lymphocyte antigen 4 (CTLA-4) and foxp3 constitutively. Donor mDCs and donor CD4 T cells were detected among the thymocytes of the recipients of B7.2(-/-) mDCs and lin(-) WT B6 BM. Thus, it seems that costimulatory molecule expression of donor DCs can play a significant immunomodulatory role in survival, GVHD, engraftment, and homing of allogeneic BM cells after IUT through the generation of T(reg) cells.

Long-Term Acceptance of Renal Allografts following Prenatal Inoculation with Adult Bone Marrow

BACKGROUND

The aim was to investigate if intravascular in utero injection of adult bone marrow into swine fetuses could lead to macrochimerism and tolerance to the donor.

METHODS

Outbred Yorkshire sows and boars screening negative for MHC allele SLA of MGH miniature swine were bred. A laparotomy was performed on the sows at 50 days gestation to expose the uterus. Bone marrow harvested from SLA miniature swine was T-cell depleted and injected intravascularly into seventeen fetuses. Flow cytometry was performed to detect donor cells (chimerism) in the peripheral blood after birth. Mixed lymphocyte reactions (MLR) and cell-mediated lympholysis (CML) assays were used to assess the response to donor MHC. Previously frozen skin grafts from the bone marrow donor were placed on the offspring from the first litter. Donor-matched renal transplant from SLA donors were performed on chimeric swine, with and without a short 12-day course of cyclosporine, and one nonchimeric littermate.

RESULTS

Nine inoculated offspring demonstrated donor cell chimerism in the peripheral blood and lymphohematopoietic tissues. All animals with detectable chimerism within the first three weeks were consistently nonreactive to donor MHC in vitro. Animals challenged with donor skin grafts displayed prolonged graft survival without producing antidonor antibodies. All chimeric animals accepted donor-matched kidney allografts, even one without cyclosporine. The kidney in the nonchimeric littermate rejected by day 21.

CONCLUSIONS

Transplantation of allogeneic adult bone marrow into immunocompetent fetal recipients resulted in chimerism. In utero inoculation led to operational tolerance to the donor's major histocompatibility antigens and long-term acceptance to organ allografts.

Prevention of graft rejection by donor type II CD8(+) T cells (Tc2 cells) is not sufficient to improve engraftment in fetal transplantation

OBJECTIVES

Tc2 cells, a subset of CD8(+) T cells, are able to facilitate engraftment in a murine model of postnatal allogeneic bone marrow transplantation. The purpose of this study was to evaluate whether Tc2 cells could improve engraftment in fetal transplantation.

METHODS

Gestational day 13 C57BL/6 (H-2(b)) fetal mice were used as recipients, adult B6D2F(1) mice (C57BL/6 x DBA/2, H-2(b/d)) as donors, and splenocytes from B6C3F(1) (C57BL/6 x C3H/He, H-2(b/k)) mice were used as stimulators in cultures used to generate the Tc2 cells from B6D2F(1) mice. Peripheral blood chimerism was examined monthly for 3 months. Thereafter, recipients were sacrificed to evaluate the levels of peritoneal, splenic and bone marrow chimerism. The T-cell responses of recipient splenocytes to cells of host origin were measured as a proliferative response in mixed lymphocyte cultures.

RESULTS

Low levels of peripheral blood cell chimerism (<0.3%) were observed at 1 month of age, which declined further by 3 months of age. The levels of donor cells in the spleen, bone marrow and peritoneal cavity were usually not more than 0.05%. The peritoneal cavity tended to have higher levels of donor cells with 1 recipient sustaining as high as 25.03% at the age of 3 months. Higher peritoneal chimerism correlated with a lower donor-specific T-cell response.

CONCLUSIONS

Transplantation of Tc2 cells was insufficient to improve bone marrow engraftment in utero, suggesting that graft rejection is not the major barrier to successful in utero transplantation. Donor cells can persist in the peritoneal cavity and might play an important role in inducing immune tolerance in fetuses.

Haploidentical donor T cells fail to facilitate engraftment but lessen the immune response of host T cells in murine fetal transplantation

The effects of donor T cells, or their CD8+ subset, on engraftment and tolerance induction in fetal transplantation were evaluated using an F1-into-parent mouse-model that does not permit a graft-versus-host effect. Gestational day 13 C57BL/6 (H-2Kb) fetuses were transplanted with B6D2F1 (H-2Kb/d) light density bone marrow cells (LDBMC) containing 1-2% T cells, T-cell depleted bone marrow cells (TDBMC, < 0.1% T cells), or TDBMC with enriched CD8+ T cells (CD8). Chimaerism levels in the peripheral blood, spleen and bone marrow were usually below 0.2% in all groups, indicating that T cells do not improve engraftment without a graft-versus-host effect. A significant, but transient, wave of donor cells was seen in the peripheral blood at 1 month of age in the CD8 and LDBMC groups. Relatively high levels of chimaerism (< 17%) were sometimes detected in the peritoneal cavities of recipients. T-cell tolerance specific to donor cells was evaluated in mixed lymphocyte cultures. The CD8 and LDBMC groups had significantly lower T-cell responses than untransplanted controls. These findings indicate that in utero transplantation of haploidentical donor CD8+ or CD3+ cells can help to lessen the immune response of host T cells towards donor cells. The persistence of donor cells in the peritoneal cavity also correlated with tolerance induction.

Fetal Immune Suppression as Adjunctive Therapy for In Utero Hematopoietic Stem Cell Transplantation in Nonhuman Primates

In utero hematopoietic stem cell transplantation could potentially be used to treat many genetic diseases but rarely has been successful except in severe immunodeficiency syndromes. We explored two ways to potentially increase chimerism in a nonhuman primate model: (a) fetal immune suppression at the time of transplantation and (b) postnatal donor stem cell infusion. Fetal Macaca nemestrina treated with a combination of the corticosteroid betamethasone (0.9 mg/kg) and rabbit thymoglobulin (ATG; 50 mg/kg) were given haploidentical, marrow-derived, CD34+ -enriched donor cells. Animals treated postnatally received either donor-derived T cell-depleted or CD34+ -enriched marrow cells. Chimerism was determined by traditional and real-time polymerase chain reaction from marrow, marrow progenitors, peripheral blood, and mature peripheral blood progeny. After birth, the level of chimerism in the progenitor population was higher in the immune-suppressed animals relative to controls (11.3% +/- 2.7% and 5.1% +/- 1.5%, respectively; p = .057). Chimerism remained significantly elevated in both marrow (p = .02) and fluorescence-activated cell sorted and purified CD34+ cells (p = .01) relative to control animals at > or = 14 months of age. Peripheral blood chimerism, both at birth and long term, was similar in immune-suppressed and control animals. In the animals receiving postnatal donor cell infusions, there was an initial increase in progenitor chimerism; however, at 6-month follow-up, the level of chimerism was unchanged from the preinfusion values. Although fetal immune suppression was associated with an increase in the level of progenitor and marrow chimerism, the total contribution to marrow and the levels of mature donor progeny in the peripheral blood remained low. The level of long-term chimerism also was not improved with postnatal donor cell infusion.

Multilineage engraftment with minimal graft-versus-host disease following in utero transplantation of S-59 psoralen/ultraviolet a light-treated, sensitized T cells and adult T cell-depleted bone marrow in fetal mice

Although engraftment following in utero stem cell transplantation can readily be achieved, a major limitation is the low level of donor chimerism. We hypothesized that a lack of space for donor cells in the recipient marrow was one of the primary reasons for failure to achieve significant engraftment, and that donor T cells could make space in an allogeneic mismatched setting. We found that 3 x 10(5) C57BL/6 (B6) naive CD3(+) cells coinjected with B6 T cell-depleted bone marrow (TCDBM) into 14- to 15-day-old BALB/c fetuses resulted in multilineage engraftment (median, 68.3%) associated with severe graft-vs-host disease (GvHD; 62 vs 0% with TCDBM alone). When 1.5 x 10(5) CD4(+) or CD8(+) cells were used, low levels of engraftment were seen vs recipients of 1.5 x 10(5) CD3(+) cells (2.4 +/- 1.1 and 6.6 +/- 3.9 vs 20.4 +/- 10.4%, respectively). To test the hypothesis that proliferation of T cells in response to alloantigen resulted in GvHD and increased engraftment, we pretreated naive T cells with photochemical therapy (PCT) using S-59 psoralen and UVA light to prevent proliferation. GvHD was reduced (60-0%), but was also associated with a significant reduction in engrafted donor cells (53.4 +/- 4.2 to 1.7 +/- 0.5%). However, when B6 T cells were sensitized to BALB/c splenocytes, treated with PCT, and coinjected with TCDBM, there was a partial restoration of engraftment (13.3 +/- 2.4% H2Kb(+) cells) with only one of nine animals developing mild to moderate GvHD. In this study we have shown that PCT-treated T cells that are cytotoxic but nonproliferative can provide an engraftment advantage to donor cells, presumably by destroying host hemopoietic cells without causing GvHD.

Fetal hematopoietic stem cell transplantation: a challenge for the twenty-first century

Successful in utero hematopoietic stem cell transplantation will likely represent a major step forward in the management of patients with congenital hematological, metabolic, and immunological disorders. We review the naturally occurring models of hematopoietic chimerism in animals and humans, as well as available experimental animal data and human clinical attempts of fetal transplantation. Data available from naturally occurring models and experimental models of fetal transplantation suggest that this technique should be translatable to the human fetus. However, to date, the success of human fetal hematopoietic stem cell therapy has been limited to fetuses with severe immunologic defects. Evaluation of successful attempts of human transplantation, the ontogeny of fetal immune development, and data available from animals provide insights into innovative approaches to fetal therapy that may bring the reality of successful fetal transplantation closer.

Transplantation of human hepatocytes into tolerized genetically immunocompetent rats

AIM: To determine whether normal genetically immunocompetent rodent hosts could be manipulated to accept human hepatocyte transplants with long term survival without immunosuppression.

METHODS: Tolerance towards human hepatocytes was established by injection of primary human hepatocytes or Huh7 human hepatoma cells into the peritoneal cavities of fetal rats. Corresponding cells were subsequently transplanted into newborn rats via intrasplenic injection within 24 h after birth.

RESULTS: Mixed lymphocyte assays showed that spleen cells from non-tolerized rats were stimulated to proliferate when exposed to human hepatocytes, while cells from tolerized rats were not. Injections made between 15 d and 17 d of gestation produced optimal tolerizaton. Transplanted human hepatocytes in rat livers were visualized by immunohistochemical staining of human albumin. By dot blotting of genomic DNA in livers of tolerized rats 16 weeks after hepatocyte transplantation, it was found that approximately 2.5 × 10⁵ human hepatocytes survived per rat liver. Human albumin mRNA was detected in rat livers by RT-PCR for 15 wk, and human albumin protein was also detectable in rat serum.

CONCLUSION: Tolerization of an immunocompetent rat can permit transplantation, and survival of functional human hepatocytes.

Tolerance induction post in utero stem cell transplantation

The potential advantage of in utero HSC transplantation over a postnatal BMT is that early curative therapy could be given to an affected fetus, thus eliminating standard intensive immunosuppressive, marrow-ablative conditioning. It is apparent from studies in animals and humans that MHC-mismatched donor HSC of either fetal or adult origin can engraft in fetal recipients if the transplants are done sufficiently early in gestation. However, except for SCID, the percentage of donor pluripotent HSC that engraft is unacceptably low. We had hoped that for diseases such as thalassemia there would be a selective survival advantage for committed donor progenitor cells resulting in a high percentage of donor cell engraftment. At least based upon the experience in human fetuses with alpha- or beta-thalassemia, this has not been the case. Furthermore, for the majority of potential recipients of in utero HSC transplants, the marrow is non-defective, and the small percentage of pluripotent donor HSC that engraft would not be expected to selectively expand post-transplant. Our own results suggest that the non-defective fetal mouse and rhesus monkey are excellent models in which to study both stem cell engraftment, rejection, and tolerance induction. In our studies in non-defective mice with normal hematopoiesis, while the percentage of donor cells that are present is quite low, in only a small number of these animals were we able to induce permanent skin graft tolerance. Thus, while we found microchimerism in approximately 75% of recipients, less than 10% became tolerant. Even when we co-injected a large number of DC precursors, similar to what has been shown to induce tolerance to allogeneic liver, most of the animals failed to become tolerant to donor skin grafts. Interestingly, donor c-kit+ cells can be recruited with cytokines into the peripheral blood in engrafted mice, although these cells do not seem to be sufficient to induce tolerance to donor skin grafts, suggesting that the type (and location) of the engrafted donor cell plays a key role in tolerance induction. Our results in the fetal monkey model parallel those in the mouse, i.e., only a small number of donor cells engraft with limited tolerance induction. Interestingly, we found in our study of DC that GVHD was induced in those murine recipients of both allogeneic marrow and DC. It is likely that there were a sufficient number of mature DC in the preparation to facilitate a donor cytotoxic response towards the host. As a consequence there was also a significant increase in the percentage of donor cells that engrafted in the survivors. Future studies will focus on ways of blocking the graft vs host reaction while still maintaining the graft-promoting role of the donor T cell.

Microchimerism does not induce tolerance and sustains immunity after in utero transplantation

BACKGROUND

To date, over 40 in utero transplants have been performed in humans; the only successes were documented in the treatment of severe combined immunodeficiency syndromes. Hemoglobinopathies and metabolic disorders are candidate diseases for this approach; however, when applied clinically, the results have been discouraging. To address the role of the fetal immune system in the outcome of in utero transplantation, we have developed a murine model of in utero transplantation in immunologically intact murine recipients and have studied chimerism and tolerance/immunity to allogeneic donor cells through the lives of the animals.

METHODS

We have performed experiments in which purified murine sca-1+/lin- cells and c-kit+/lin- cells of C57BL/6 (H2b) mice were injected into Balb/c (H2d) fetal recipients at early gestational ages. Chimerism was tested by highly sensitive semiquantitative polymerase chain reaction assay and tolerance/immunity to donor cells was studied by in vivo (skin grafts, responses to postnatal boosts) and in vitro (mixed lymphocyte culture, cytotoxicity, and cytokine release) assays.

RESULTS

One hundred percent (10/10) of mice transplanted with c-kit+ cells and 44% (4/9) of mice transplanted with sca+ cells showed circulating donor cells within the first 6 months of life (P=0.031). Mice in the sca+ group rejected donor skin grafts at a mean time of 9.1+/-0.2 days, whereas mice in the c-kit+ group rejected donor skin grafts at a mean time of 15.1+/-0.7 days (P=0.001). The difference between the transplanted groups and non-transplanted controls was also significant (P<0.05). All mice transplanted with sca+/lin- cells showed greater response to donor cells than to third-party cells at all effector to target ratios (P=0.002). Differences in response to donor alloantigen between sca+ and c-kit+ groups were significant (P=0.003). Cytokine quantification demonstrated higher TH1 than TH2 cytokine release in all groups, and the response to donor cells was higher in the sca+ compared with c-kit+ mice (P=0.031).

CONCLUSION

These results demonstrate a low level of chimerism and tolerance in mice transplanted in utero with sca+/lin- and c-kit+/lin- cells. The possibility of active in utero immunization to donor cells is supported by accelerated skin graft rejection in mice transplanted with sca+ cells and enhanced in vitro immune responses in mice with persistent microchimerism.

Hematopoietic Stem Cell Transplantation in Utero Produces Sheep–Goat Chimeras

Both allogeneic and xenogeneic hematopoietic chimera models have been developed, including fetal sheep models that demonstrated high levels of stable, multilineage engraftment created by in utero hematopoietic stem cell transplantation. The aim of this study was to test the efficacy of in utero transplantation to create xenogeneic sheep-goat hematopoietic chimeras. Fetal liver cells and T-cell-depleted adult bone marrow were tested as sources of hematopoietic stem cells. Donor cells were injected intraperitoneally into 130 recipient fetuses between 49 and 62 days of gestation. Groups 1 and 2 received crude fetal liver cell preparations. Group 3 received fetal liver cells that were incubated overnight in a phytohemagglutinin-stimulated lymphocyte-conditioned medium (PHA-LCM). In Group 4, hematopoietic stem cells were concentrated by using additional density separations. Group 5 fetal recipients received low-density, T-cell-depleted adult bone marrow cells. In Group 1, fetuses were accessed via hysterotomy. Hematopoietic stem cells were injected into Groups 2, 3, 4, and 5 without cutting through the uterine wall. Fetal survival in the five groups ranged from 56 to 100%. The percentage of chimeras from injected fetuses ranged from 43 to 92% by FACS and PCR analyses; however, levels of chimerism were low (<1%). The highest rates of chimerism were found among recipients of low-density fetal liver cells. Despite the pre-immunocompetent status of the fetal recipients and the genetic similarities between sheep and goats, high levels of engraftment were not observed. The consistently low levels of chimerism observed in this study, as well as the poor results recently reported by others using these procedures, indicate that significant barriers exist to transplanting hematopoietic stem cells in utero.

Microchimerism does not induce tolerance after in utero transplantation and may lead to the development of alloreactivity

In utero transplantation is a new technology that may provide non-toxic treatment for congenital disorders. However, a decade of research on in utero transplantation has demonstrated a low degree of chimerism and tolerance in small and large animal models as well as in human beings. We hypothesized that if large numbers of purified stem cells/progenitors were injected, a higher degree of tolerance would be induced. We have performed a 2-year experiment designed to study chimerism and tolerance after in utero transplantation with large numbers of cytokine-recruited C-kit+ cells. Chimerism in the blood and tissues was tested through the lifespan of the animals, and in vitro immunologic assays were performed at the end of life. C-kit+ cells obtained from the peripheral blood of C57BL/6 mice were injected intraperitoneally into 12- to 13-day-old Balb/c murine fetuses. The injected populations contained 5% to 20% of Sca-1+ and 1% to 5% of CD3+ cells. Twenty-three percent of mice that received transplants showed circulating donor cells in the blood, and 7% to 14% showed donor cells in the tissues. The percent of donor cells in the blood and tissues was low (<0.01%). Timing of injection or cell dose did not affect chimerism or tolerance. Fifty percent (13 of 26) showed accelerated skin graft rejection and 5 of 26 (19%) had prolonged acceptance as compared with control mice not receiving transplants in utero. All mice that rejected skin grafts showed significantly increased natural killer function as compared with the mice with delayed graft acceptance. Fifty percent of tested recipient mice showed reactivity against donor cells in the cytotoxicity assay, which could be related to the prenatal sensitization. We conclude that microchimerism does not lead to the induction of a high degree tolerance after in utero transplantation and instead may lead to the development of alloreactivity to donor cells.