Pretransplant injection of allograft recipients with donor blood or lymphocytes permits allograft tolerance without the presence of persistent donor microchimerism

Use of Allogeneic Bone Marrow Labeled with Neomycin Resistance Gene to Examine Bone Marrow-Derived Chimerism in Experimental Organ Transplantation

Posttransplant infusion of viable donor bone marrow cells (DBMC) has been shown in our previous studies to promote acceptance of incompatible kidney allografts in rhesus monkeys after treatment with polyclonal antithymocyte globulin to deplete peripheral T-lymphocytes. In this nonhuman primate model, the infusion of the DBMC is requisite for the induction of functional graft tolerance and specific MLR and CTLp unresponsiveness, although the relevant role and fate of bone marrow-derived chimeric cells is uncertain. Standard immunological and molecular techniques applied to this monkey model are unable to differentiate between chimeric cells derived from the infused DBMC and those derived from allograft-borne passenger leukocyte emigrants. To distinguish chimerism due to infused DBMC, we transduced DBMC with a functional neomycin resistance gene (Neor) using the retroviral vector pHSG-Neo. Neor-Mransduced BMC were infused into recipients approximately 2 wk after kidney transplantation and treatment with rabbit antithymocyte globulin. No maintenance immunosuppressive drugs were given. Genomic DNA isolated from peripheral blood leukocytes was used to monitor the presence of Neor-positive cells. Tissue samples obtained at necropsy also were assessed for Neor-positive chimeric cells. The presence of DBMC-derived chimerism was assessed by polymerase chain reaction using Neor sequence-specific primers (PCR-SSP). Chimerism was detectable in recipient tissues at various times for up to 6 mo after DBMC infusion. These studies using gene transduction methodology indicate that a stable genetic marker can provide capability to examine DBMC-derived chimerism for prolonged periods in a nonhuman primate model. This approach should facilitate future studies in preclinical models to study the role and type of chimeric cell lineages in relation to functional allograft tolerance.

Should microchimerism turn into rejection prophylactics?

Non-self cells can circulate in the body of an individual after any sort of contact with an allogeneic source of cells, thus creating a situation of chimerism that can be transient or prolonged over time. This situation may appear after stem cell transplantation, pregnancy, transfusion or transplantation. Concerning transplantation, many hypotheses have been formulated regarding the existence, persistence and role of these circulating cells in the host. We will review the principal hypotheses that have been formulated for years since the first description of non-self circulating cells in mammals to the utilization of artificially induced chimerism protocols for the achievement of tolerance.

Hematopoiesis from Human Embryonic Stem Cells: Overcoming the Immune Barrier in Stem Cell Therapies

The multipotency and proliferative capacity of human embryonic stem cells (hESCs) make them a promising source of stem cells for transplant therapies and of vital importance given the shortage in organ donation. Recent studies suggest some immune privilege associated with hESC-derived tissues. However, the adaptability of the immune system makes it unlikely that fully differentiated tissues will permanently evade immune rejection. One promising solution is to induce a state of immune tolerance to a hESC line using tolerogenic hematopoietic cells derived from it. This could provide acceptance of other differentiated tissues from the same line. However, this approach will require efficient multilineage hematopoiesis from hESCs. This review proposes that more efficient differentiation of hESCs to the tolerogenic cell types required is most likely to occur through applying knowledge gained of the ontogeny of complex regulatory signals used by the embryo for definitive hematopoietic development in vivo. Stepwise formation of mesoderm, induction of definitive hematopoietic stem cells, and the application of factors key to their self-renewal may improve in vitro production both quantitatively and qualitatively.

Donor bone marrow cells play a role in the prevention of accelerated graft rejection induced by semi-allogeneic spleen cells in transplantation

Spleen or spleen plus bone marrow cells from (BALB/cxC57Bl/6)F1 donors were transferred into BALB/c recipients 21 days before skin or cardiac transplantation. Prolonged graft survival was observed on recipients treated with the mixture of donor-derived cells as compared to those treated with spleen cells alone. We evaluated the expression of CD45RB and CD44 by splenic CD4+ and CD8+ T cells 7 and 21 days after donor cell transfer. The populations of CD8+CD45RBlow and CD8+CD44high cells were significantly decreased in mice pre-treated with donor spleen and bone marrow cells as compared to animals treated with spleen cells only, although these cells expanded in both groups when compared to an earlier time-point. No differences were observed regarding CD4+ T cell population when recipients of donor-derived cells were compared. An enhanced production of IL-10 was observed seven days after transplantation in the supernatants of spleen cell cultures of mice treated with spleen and bone marrow cells. Taken together these data suggest that donor-derived bone marrow cells modulate the sensitization of the recipient by semi-allogeneic spleen cells in part by delaying the generation of activated/memory CD8+ T cells leading to enhanced graft survival.

Chimerism and bone marrow based therapies in transplantation

Composite tissue allotransplantation holds a great potential for providing increased knowledge of anatomy and microsurgical experience for life-enhancing reconstructions. Many transplant cases around the world have made this a clinical reality at the present time. Composite tissue allotransplants contain multiple tissue types, including bone, muscle, vessels, nerves, skin, and immune cells and bear a huge antigenic load. Although immunosuppressive drugs are applied successfully to prevent allograft rejection, their side effects pose a barrier to worldwide use. Bone marrow therapy in many tolerance induction protocols, therefore, provides a guide to reaching the target of permanent immunotolerance. Multiple studies suggest that bone marrow is immunomodulatory and may facilitate allograft acceptance. In this review, bone marrow based therapy protocols of clinical and experimental models are presented in two major categories: solid organ and composite tissue transplantation.

Microchimerism and renal transplantation: doubt still persists

OBJECTIVE

We sought to study microchimerism in a group of kidney transplant recipients.

MATERIALS AND METHODS

In this study, the peripheral blood microchimerism (PBM) after renal transplantation was retrospectively evaluated in 32 male-to-female recipients of living unrelated or cadaveric donor renal transplants. Using a nested polymerase chain reaction (PCR) amplification specific for SRY region of the Y chromosome, microchimerism was detected with a sensitivity of 1:1,000,000. Recipients were compared according to the presence of PBM, acute and chronic rejection episodes, type of allotransplant, recipient and donor age at transplantation, previous male labor or blood transfusion, allograft function (serum creatinine level), and body mass index.

RESULTS

Among 32 recipients, 7 (21.9%) were positive for PBM upon multiple testing at various posttransplant times. All microchimeric recipients had received kidneys from living unrelated donors. No significant difference was observed with regard to other parameters. In addition the acute rejection rate in the microchimeric group was 3 (42%) versus 4 (16%) in the nonmicrochimeric recipients (not significant).

CONCLUSION

Our results suggested better establishment of microchimerism after living donor kidney transplantation. However, doubt persists concerning the true effect of microchimerism after renal transplantation. It seems that microchimerism alone has no major protective role upon renal allograft survival.

Immune tolerance: mechanisms and application in clinical transplantation

The achievement of immune tolerance, a state of specific unresponsiveness to the donor graft, has the potential to overcome the current major limitations to progress in organ transplantation, namely late graft loss, organ shortage and the toxicities of chronic nonspecific immumnosuppressive therapy. Advances in our understanding of immunological processes, mechanisms of rejection and tolerance have led to encouraging developments in animal models, which are just beginning to be translated into clinical pilot studies. These advances are reviewed here and the appropriate timing for clinical trials is discussed.

Treatment of allograft vasculopathy in heart transplantation

Cardiac allograft vasculopathy remains one of the main causes of morbidity and mortality after heart transplantation, although its impact is becoming somewhat smaller as prophylactic measures are implemented. Advances in the understanding of the molecular and cellular mechanisms involved in the genesis and development of cardiac allograft vasculopathy are opening ways for new diagnostic and therapeutic strategies. Successful prophylaxis of the early stages of the disease has been demonstrated with the use of newer immunosuppressive agents, such as sirolimus and everolimus, that will probably be included in future protocols. For most patients with established cardiac allograft vasculopathy, currently available revascularisation methods and retransplantation are not appropriate options. Antiproliferative agents could provide significant improvement in terms of symptom relief and prognosis, but their definite value must be proven in well-designed trials.

Recipient Blood Pre-Transplant Transfusion Prolongs Hepatic Allograft Survival in Rats

BACKGROUND

The pre-transplant administration of donor antigens to recipients is reported to prolong transplanted organ survival. We investigated the effect of pre-transplant intraportal administration of recipient blood on rat hepatic allograft survival.

MATERIALS AND METHODS

Male LEW (RT1l) and ACI (RT1a) rats were used as transplant recipients and donors, respectively. Before transplantation, donors were transfused with recipient blood. Experimental animals were divided into groups as follows: group I, no treatment; group II, pre-treatment with recipient blood via the penile vein 7 days before transplantation; group III, pre-treatment with recipient blood via the portal vein 5 days before transplantation; and group IV, pre-treatment with recipient blood via the portal vein 7 days before transplantation. Serum interferon (IFN)-gamma concentrations were measured post-operatively.

RESULTS

Animals in group I survived a mean of 10.1 +/- 0.7 days. The survival of groups II and III was 10.6 +/- 1.6 and 13.1 +/- 0.9 days, respectively. The survival rate in group IV was prolonged significantly to 33.7 +/- 2.6 days. Serum concentrations of IFN-gamma were increased significantly in group IV, as compared with group I. The ratio of OX76+CD4+ or OX76+CD8+ T cells to OX76-CD4+ or OX76-CD8+ T cells was greater in group IV, as compared group I. OX76+CD8+ T cells from hepatic allografts in group IV expressed IFN-gamma and interleukin (IL)-10, but not IL-2 mRNA. Apoptotic hepatic infiltrates were greater in group IV, as compared to group I.

CONCLUSION

The cytokine profile of donor CD8+ T cells from allografts treated by the intraportal administration of recipient blood is associated with apoptosis of graft-infiltrating cells and the prolonged survival of hepatic allografts in rats.

Extracardiac progenitor cells repopulate most major cell types in the transplanted human heart

BACKGROUND

Extracardiac progenitor cells are capable of repopulating cardiomyocytes at very low levels in the human heart after injury. Here, we explored the extent of endothelial, smooth muscle, and Schwann cell chimerism in patients with sex-mismatched (female-to-male) heart transplants.

METHODS AND RESULTS

Autopsy specimens from 5 patients and endomyocardial biopsies from 7 patients were used for this study. Endothelial, vascular smooth muscle, and Schwann cells were stained with antibodies against CD31 or Ulex europaeus lectin, smooth muscle alpha-actin, and S-100, respectively, and the Y chromosome was identified with in situ hybridization. Biopsy specimens from 1, 4, 6, and 12 months and 5 and 10 years after heart transplantation were evaluated. Y-positive cells were counted by conventional bright-field microscopy and confirmed by confocal microscopy. Endothelial cells showed the highest degree of chimerism, averaging 24.3+/-8.2% from extracardiac sources. Schwann cells showed the next highest chimerism, averaging 11.2+/-2.1%; vascular smooth muscle cells averaged 3.4+/-1.8%. All 3 cell types showed substantially higher chimerism than we previously observed for cardiomyocytes (0.04+/-0.05%). Endothelial chimerism was much higher in the microcirculation than in larger vessels. Analysis of serial endomyocardial biopsies revealed that high levels of endothelial chimerism occurred as early as 1 month after transplantation (22+/-6.6%) with no significant increases even up to 10 years after cardiac transplantation.

CONCLUSIONS

Extracardiac progenitor cells are capable of repopulating most major cell types in the heart, but they do so with varying frequency. The signals for endothelial progenitor recruitment occur early and could relate to injury during allograft harvest or transplantation. The high degree of endothelial chimerism may have immune implications such as for myocardial rejection or graft vasculopathy.

Detection of chimerism following vascularized bone allotransplantation by polymerase chain reaction using a Y-chromosome specific primer

Chimerism following allogeneic organ transplantation is a phenomenon known to occur and be associated with development of immunologic tolerance in allotransplantation. However, little is known about graft cell migration following vascularized bone allografting. In this study, chimerism was assessed following vascularized tibia transplantation from male DA or PVG donors to female PVG rat recipients using a semi-quantitative polymerase chain reaction for the Y-chromosome. FK-506 (Tacrolimus) was administered after transplantation for immunosuppression. All immunosuppresssed PVG rat recipients of PVG bone grafts showed a high level of chimerism (1%) in the thymus, spleen, liver and cervical lymph nodes at 18 weeks post-transplant. Donor cells were also detected in the contralateral tibia and humerus. In non-immunosuppressed PVG rat recipients of DA bone grafts, donor cells were detected in the spleen in three of five rats within 2 weeks post-transplant. In these animals the bone grafts were severely rejected. In immunosuppressed PVG rat recipients of DA bone grafts, two of five, four of eight and eight of 10 rats showed low level chimerism (0.1%) in peripheral blood at 1, 12, and 18 weeks post-transplant. Six rats showed a high level of chimerism in the spleen and thymus. Histological studies revealed no rejection findings through 18 weeks post-transplant. Our results indicate that chimerism, or the presence of graft cells in host tissue, may occur in the face of acute rejection and be demonstrable following vascularized isograft and allograft living bone transplantation when chronic immunosuppression is maintained. Graft vascular patency during the short-term likely allows cellular migration, even in the face of acute rejection. Long-term survival and proliferation of graft marrow elements in host tissue may be possible with adequate immunosuppression.

Fate of donor cells in vascularized bone grafts: identification of systemic chimerism by the polymerase chain reaction

Systemic chimerism, or the movement of cells from a transplanted tissue into host organs, is a phenomenon known to occur in association with development of immunological tolerance in allotransplantation. However, little is known about the fate and movement of cells into or out of autogenous free tissue transfers, including vascularized bone grafts. The purpose of this study was to identify systemic chimerism in vascularized bone grafts by transplantation of a vascularized tibiofibular graft from isogenous (inbred) male Lewis rats to female recipients. Donor (male) cells could be identified in the recipient (female) tissues by semiquantitative polymerase chain reaction analysis for a Y chromosome-specific DNA sequence. Chimerism was assessed at 1, 12, 18, and 24 weeks after transplantation. Competitive polymerase chain reaction study using the specific primers for a Y-chromosome marker ( gene) and an autosomal gene (GAPDH) allowed detection of small amounts of male cells in a large pool of female cells and measurement of their relative proportions as a function of time. Of 19 nonimmunosuppressed recipients, nine animals (47 percent) showed low-level chimerism (<0.1 percent) in the peripheral blood. Nine (47 percent), three (16 percent), and two (11 percent) recipients showed high-level chimerism (>1 percent) in the spleen, liver, and thymus, respectively, at final assessment. Donor cells were detected in all bone grafts and in six contralateral tibial bones (i.e., 67 percent of sampled contralateral tibial bones) at 18 and 24 weeks after transplantation. Twenty-four recipients were immunosuppressed with FK506 (tacrolimus) to suppress reaction to a minor histocompatibility barrier present on the Y chromosome. In this group, 14 animals (58 percent) showed low-level chimerism in peripheral blood and 12 (50 percent), eight (33 percent), and one (4 percent) recipients showed high-level chimerism in the spleen, thymus, and liver, respectively. Transplanted cells were detected in nine contralateral tibial bones (i.e., 60 percent of sampled contralateral tibial bones) at 12 and 18 weeks after surgery. The results indicate that polymerase chain reaction for the Y chromosome is a useful tool for differentiating between donor and recipient cell populations experimentally using sex-mismatched tissues in a rat model. This study demonstrated that systemic chimerism occurs after successful vascularized bone transplantation. Transplanted cells not only survive in the graft but also gradually migrate into the recipient's body.

Thymic microchimerism correlates with the outcome of tolerance-inducing protocols for solid organ transplantation

This study found that pretransplant infusion of donor peripheral blood leukocytes, either total leukocytes (peripheral blood leukocytes) or peripheral blood mononuclear cells (PBMC), under appropriate immunomodulating conditions was more effective than donor bone marrow (BM) in prolonging the survival of rats that received kidney grafts. A higher percentage of MHCII(+) cells was found in donor PBMC than in BM cells, and depletion of MHCII(+) cells from donor PBMC abolished their tolerogenic potential. By the analysis of microchimerism in rats infused with donor cells and killed at different time points thereafter, the better tolerogenic potential of leukocyte infusion related to a higher capability of these cells to engraft the recipient thymus. PCR analysis on OX6-immunopurified cells revealed the presence of donor MHCII(+) cells in the thymus of these animals. The role of intrathymic microchimerism was reinforced by findings that thymectomy at the time of transplant prevented tolerance induction by donor leukocytes. Donor DNA was found in the thymus of most long-term graft animals that survived, but in none of those that rejected their grafts. The presence of intrathymic microchimerism correlated with graft survival, and microchimerism in other tissues was irrelevant. PCR analysis of DNA from thymic cell subpopulations revealed the presence of donor MHCII(+) cells in the thymus of long-term surviving animals. Thus, in rats, donor leukocyte infusion is better than donor BM for inducing graft tolerance, defined by long-term graft survival, donor-specific T cell hyporesponsiveness, and reduced interferon gamma production. This effect appears to occur through migration of donor MHCII(+) cells in the host thymus.

Influence of pretransplant pregnancy on survival of renal allografts from living donors

BACKGROUND

The presence of a small number of cells of donor origin in organ transplant recipients (microchimerism) may influence allograft survival and may induce tolerance. Postpartum women may be microchimeric to offspring hematopoietic cells up to 27 years. We hypothesized that mothers receiving renal allografts from offspring would have better graft survival compared with either fathers receiving allografts from offspring, or mothers receiving allografts from nonoffspring donors.

METHODS

We analyzed 1803 living related kidney transplants from the UNOS database performed between January 1, 1990, and December 31, 1995, for mothers and fathers who received grafts from offspring with one haplotype match. We also compared these mothers with parous females receiving a kidney from nonoffspring donors (spouse and other biologically related or unrelated family members). A multivariate logistic regression method was used to analyze the effect of donor type, as well as other recipient, donor, and transplant characteristics, on graft and patient survival.

RESULTS

Mothers receiving one haplotype-matched offspring renal allografts did not have better graft survival at 1 or 3 years posttransplant compared with fathers receiving similar grafts. There was also no difference in graft or patient survival between mothers receiving kidney grafts from either offspring or nonoffspring donors. Graft survival in mothers with multiple pregnancies was poorer than those with a single pregnancy.

CONCLUSIONS

It is possible that persistent microchimerism of fetal cells in maternal circulation may, for some mothers, cause a detectable improvement in graft or patient survival. Comparison of female and male recipients from the UNOS database did not reveal any differences in outcomes. If mothers are tolerant to their offspring, our results indicate that this microchimerism may not improve renal allograft or patient survival in offspring donor to maternal recipient combinations. Lastly, more sensitive pretransplant cross-match assays may need to be implemented in multiparous women, given our results.

Different kinetics of donor cell populations after isolated liver and combined liver/small bowel transplantation

Spontaneous tolerance induction after liver transplantation also supports additional transplants, e.g. a small bowel graft, from the same donor (tolerogenic effect). Chimerism serves as a possible explanation of this phenomenon. Isolated liver (LTx) and combined liver/small bowel transplantation (LSBTx) are compared. LSBTx and LTx were performed in the BN --> LEW rat strain combination without immunosuppression. Parenchymal damage during rejection was monitored by sequential standard histology. Donor/recipient populations were identified and further differentiated for immunohistochemical single and double staining. A small number of donor specific leukocytes can be detected on all days in host organs (microchimerism). A significantly larger donor leukocyte population survives long-term in the sinusoids of liver (graft chimerism). Sinusoidal donor leukocytes survive rejection and recover in number after tolerance induction. Rejection of liver allografts and infiltration by host leukocytes are more pronounced after LSBTx than after LTx. Accordingly, during rejection a steeper decline of sinusoidal donor leukocytes is observed after LSBTx and recovery after tolerance induction is not as marked. Microchimerism apparently plays no significant role in either transplantation model. The number of sinusoidal donor leukocytes, however, mirrors closely host immune responses.

Microchimerism, GVHD, and tolerance in solid organ transplantation

The phenomenon of microchimerism and its relationship to long-term graft tolerance is an area of active study. The ability to establish a tolerant state has been enhanced with current immunosuppressive drugs and emerging therapies such as donor HPC infusions. An undesirable outcome of host-donor WBC interaction is GVHD. GVHD is a rare complication reported most frequently in liver transplantation. Two cases of GVHD reported in recipients of organs from donors homozygous for a shared HLA haplotype would support a policy of avoiding the use of these donors. TA-GVHD is very rare in solid organ transplant recipients, with only four published cases; only two had convincing supportive evidence and one of these had an underlying hematologic abnormality. These few cases do not support a policy of routine irradiation of cellular blood components for all solid organ transplant recipients. The use of donor HPC infusions to enhance chimerism and graft tolerance has increased the number of GVHD cases observed (usually mild) and decreased the severity and number of rejection episodes. The long-term effects of donor HPC infusions on graft survival is under investigation.

Donor-derived alloantigen-presenting cells persist in the liver allograft during tolerance induction

The predictive value of chimerism was evaluated in three different transplantation models in the rat without immunosuppression: small bowel- (SBTx), liver- (LTx), and liver/small bowel transplantation (LSBTx) were performed in the Brown Norway (BN)-to-Lewis-(LEW) strain combination. Immunohistochemistry and flow cytometry were used to identify donor cells in the recipient's spleen. Their number did not change significantly during transient rejection or tolerance after LTx and LSBTx. However, the amount of donor-derived nonparenchymal cells within the liver allograft including antigen-presenting cells (APCs), such as dendritic and Kupffer cells, clearly mirrored the recipient's immune status: as expected, their number decreased during rejection, but recovered considerably during and after tolerance induction. We conclude that donor cells in the periphery of the recipient correlate with the presence of the allograft, but do not seem to influence graft acceptance actively. However, the kinetics of the detected donor APC population in the liver suggests their important role in modifying the recipient's immune response towards tolerance.

Specific immunosuppression by postoperative infusion of allogeneic spleen cells: requirement of donor major histocompatibility complex expression and graft-versus-host reactivity

BACKGROUND

Donor leukocytes may exert positive immunoregulatory effects on allograft acceptance. Most recent studies have focused on pretreatment protocols. In this study, the effect of postoperative infusion of donor leukocytes on graft survival and the phenotypic and functional requirements for infused cells were investigated in fully major histocompatibility complex (MHC)-mismatched rat heart transplant models.

METHODS

LEW (RT1l) heart grafts were implanted heterotopically into abdomens of LEW.1W (RT1u), and different types of cells were infused postoperatively. Immunohistochemistry was used to evaluate histopathological changes of grafts.

RESULTS

In the absence of any immunosuppressive agents, a single dose of viable donor spleen cells (SC), but not bone marrow cells, was able to prolong heart allograft survival to about 21 days, while they were rejected promptly at day 7 in controls. Infusion of T cell-depleted donor SC, irradiated donor SC or third-party (BN) SC showed no effect on graft survival. Compared with resting cells, neither in vitro nor in vivo prestimulation of infused donor SC improved graft survival. Clinical signs of graft-versus-host reaction were not observed in all above groups. Histology showed remarkable reduction in the severity of graft infiltrate and interleukin-2 receptor-positive cells in grafts of cell-treated animals. Postoperative infusion of SC of F1 generation between different strain combinations showed two requirements for infused cells to be effective: (1) expression of donor-type MHC antigens and (2) strong alloreactivity against the host MHC antigens.

CONCLUSION

Postoperative infusion of viable donor SC can lead to allospecific down-regulation of alloreactivity by a graft-versus-host-associated effect.

Persisting alloantigen prevents primed CD45RC- CD4 T cells from inducing allograft rejection: implications for immunological memory

Antigen stimulation induces specific CD4 T cells to change from a resting phenotype (CD45RC+) to a "memory" phenotype (CD45RC-), an isoform switch that is reversible and regulated by persisting antigen. We show here that CD4 T cells responsible for mediating allograft rejection undergo a similar CD45RC+ to CD45RC- switch irrespective of whether antigen priming results in sensitization or tolerance in vivo. Thus, skin allograft priming, designed to induce second set rejection, and a donor-specific blood transfusion (DST), designed to prolong cardiac allograft survival, will generate CD45RC- CD4 T cells that induce acute rejection when adoptively transferred to T cell-deficient athymic nude recipients. The ability of CD45RC- T cells, obtained from DST donors, to induce graft rejection was prevented by giving nude recipients a DST 14, 28 or even 56 days before grafting and T cell transfer. Thus, prolonged allograft survival in rats after DST was found to be strongly linked with persisting alloantigen from the blood transfusion but was not associated with detectable microchimerism. Importantly, CD45RC- T cells from skin graft-primed animals were similarly prevented from inducing rejection by residual DST-derived alloantigen. The investigation shows (1) that an allogeneic blood transfusion primes (not tolerizes) alloreactive CD4 T cells and (2) that residual DST-derived alloantigen can block the action of specifically primed "memory" CD4 T cells. These findings have implications for understanding immunological memory.

Microchimerism in thymus is associated with up-regulated T helper type 1 cytokine transcription during cardiac allograft rejection in rats

BACKGROUND

Intrathymic microchimerism (MC) is thought to be responsible for inducing allograft tolerance. However, the role of MC in the thymus gland after transplantation, particularly in the rejection response, is unknown. We investigated serial changes in intrathymic cytokine production associated with MC and allograft rejection.

METHODS

Donor-specific cell injection (DSI) and heterotopic heart transplantation (HTx) were performed in the fully allogeneic combination using DA rats (RT1a) as donors and WS rats (RT1k)as recipients. MC was checked by polymerase chain reaction (PCR) using a donor RT1.Bbeta domain 1 region sequence-specific primers. Reverse transcription (RT)-PCR analysis of cytokine (interleukin [IL]-2, interferon-gamma, IL-4, and IL-10) profiles of the thymus was performed in animals given DSI, HTx, or DSI/HTx.

RESULTS

DSI alone resulted in an immediate development of MC, detected by PCR, in various organs including the thymus, spleen, liver, and blood, of most rats, lasting for over 2 months. However, DSI-induced MC selectively disappeared in the thymus on day 7 after grafting, several days before the rejection of cardiac allograft. RT-PCR analysis of cytokine profiles showed that the levels of Th1 (IL-2 and interferon-gamma) cytokines transcribed in the thymus were higher than in the spleen. MC reappeared in the thymus on day 21 after grafting, but was not associated with elevation of Th1 cytokine transcription when allograft was replaced by fibrosis.

CONCLUSIONS

Intrathymic MC does not always confer unresponsiveness to alloantigen, but can be eliminated after anti-donor response.

Lymphoid/nonlymphoid compartmentalization of donor leukocyte chimerism in rat recipients of heart allografts, with or without adjunct bone marrow

BACKGROUND

The role of leukocyte migration and chimerism in organ allograft acceptance has been obscured by the lack of information about the late localization of the donor cells.

METHODS

Male Lewis rat-->female Brown Norway abdominal heart transplantation was performed under tacrolimus immunosuppression (days 0-13, 20, and 27) with or without donor bone marrow and (in bone marrow subgroups) a 1-week postoperative course of a possibly chimerism-enhancing drug. Using rat sex-determining region-Y-specific oligonucleotide primers, we determined the donor DNA concentration by polymerase chain reaction in serial venous blood samples for 100 days and in tissue specimens when animals were killed.

RESULTS

Chimerism was detected out to 56 days in 89% of the blood samples but in none of the samples at 100 days. However, donor DNA was detected when animals were killed in 95% of the native hearts, 80% of the skin biopsy specimens, and 23% of the spleens. The presence and quantity of early and late chimerism were strongly correlated the administration of adjunct bone marrow and with a reduction in the vasculopathy and inflammation index in the cardiac allografts. Marginally significant further increases in chimerism and/or reductions in chronic heart rejection beyond those achieved with adjunct bone marrow alone were associated with additional treatment with the growth factors Flt-3 ligand, granulocyte colony-stimulating factor, and a recombinant molecular variant of interleukin-6 (interleukin-6 mutein) but not with hepatocyte growth factor or lisofylline.

CONCLUSIONS

The previously suspected shift of early chimerism in the blood and lymphoid organs to dominance in host nonlymphoid tissues is consistent with the dual mechanisms of clonal exhaustion and immune indifference, governed by antigen migration and localization, that have been postulated elsewhere to account for organ allograft acceptance.

Detection of Microchimerism After Allogeneic Blood Transfusion Using Nested Polymerase Chain Reaction Amplification With Sequence-Specific Primers (PCR-SSP): A Cautionary Tale

In bone marrow transplantation, the detection of chimerism is an important adjunct to the repertoire of tests available for determining acceptance of the graft. In solid organ transplantation, there is currently intense interest in the role that chimerism plays in both short- and long-term host reactivity to the graft. Allogeneic blood transfusion has been associated with a subtle immunosuppressive effect in renal transplantation and chimerism is implicated as a possible mechanism for this effect. To assess the survival of allogeneic cells after blood transfusion or transplantation, we have developed a technique based on molecular typing for HLA class II alleles, which enables the detection of donor-derived cells in patients receiving blood transfusions. While developing this technology, we investigated why we and others observe false amplification. Sequencing of false products has shown that they arise from amplification of both pseudogenes and non-pseudogenes present in the DNA under test. Elucidation of this phenomenon allows the amplification of these false products to be predicted in any given combination and hence avoided by the judicious selection of primers. Validation has been achieved by following donor alleles after transfusion of blood containing defined numbers of leukocytes expressing selected mismatched antigens.

Detection of Microchimerism After Allogeneic Blood Transfusion Using Nested Polymerase Chain Reaction Amplification With Sequence-Specific Primers (PCR-SSP): A Cautionary Tale

In bone marrow transplantation, the detection of chimerism is an important adjunct to the repertoire of tests available for determining acceptance of the graft. In solid organ transplantation, there is currently intense interest in the role that chimerism plays in both short- and long-term host reactivity to the graft. Allogeneic blood transfusion has been associated with a subtle immunosuppressive effect in renal transplantation and chimerism is implicated as a possible mechanism for this effect. To assess the survival of allogeneic cells after blood transfusion or transplantation, we have developed a technique based on molecular typing for HLA class II alleles, which enables the detection of donor-derived cells in patients receiving blood transfusions. While developing this technology, we investigated why we and others observe false amplification. Sequencing of false products has shown that they arise from amplification of both pseudogenes and non-pseudogenes present in the DNA under test. Elucidation of this phenomenon allows the amplification of these false products to be predicted in any given combination and hence avoided by the judicious selection of primers. Validation has been achieved by following donor alleles after transfusion of blood containing defined numbers of leukocytes expressing selected mismatched antigens.

Tolerance induction ameliorates allograft vasculopathy in rat aortic transplants. Influence of Fas-mediated apoptosis

Based on successful induction of donor-specific unresponsiveness by alloantigenic stimulation in several animal models of acute rejection, we hypothesized that similar immune manipulations would also inhibit the evolution of chronic rejection and transplant vasculopathy. To induce immune tolerance, DA rats received a PVG heart allograft and were immunosuppressed with cyclosporine for 30 d. At day 100 the animals were challenged with a PVG aortic allograft after either 1 or 18 h of cold ischemia. 8 wk after the aortic transplantation, the grafts were investigated for morphological changes, infiltrating cells, apoptosis, and Fas-Fas ligand expression. Control allografts showed advanced transplant arteriosclerosis, whereas tolerance-induced aortic allografts displayed reduced neointimal formation, less medial atrophy, fewer apoptotic cells, and fewer Fas- and FasL-expressing cells. Prolonged ischemic storage time did not profoundly alter the morphological changes of the allografts. Fas expression was found in T cells, macrophages, vascular smooth muscle cells, and endothelial cells, whereas FasL was expressed mainly by T cells and macrophages. FasL mRNA expression was evident throughout the entire allograft wall. In conclusion, induction of allospecific tolerance can effectively prevent transplant arteriosclerosis. Cold ischemia damage does not abrogate the beneficial effect of tolerance, but creates a separate identity of mainly endothelial lesions. Furthermore, Fas-mediated apoptosis appears to be involved in the pathological lesions seen in chronic rejection.

Donor bone marrow potentiates the effect of tacrolimus on nonvascularized heart allograft survival: association with microchimerism and growth of donor dendritic cell progenitors from recipient bone marrow

BACKGROUND

The influence of donor hematopoietic cell microchimerism on organ allograft survival has been studied largely in vascularized transplant models. Here, we examine the impact of donor bone marrow (BM) cells administered intravenously together with transient systemic tacrolimus therapy on microchimerism, the survival of nonvascularized cardiac allografts, and growth of donor antigen-presenting cells [dendritic cells (DCs)] from recipient BM.

METHODS

Adult male C3H (H2k) mice received heterotopic heart transplants from B10 (H2b) donors in the dorsal ear pinna. They were given no further treatment, or either a short course of tacrolimus (FK506; 2 mg/kg i.p. from day 0 to day 13), unmodified donor BM cells (50x10(6) i.v. on day 0) or both treatments. Grafts were examined daily for contractile activity. Anti-donor cytotoxic T lymphocyte responses were determined in recipients' spleens. Microchimerism (IAb+ cells) was demonstrated by immunocytochemical staining of spleens, and of cells expanded from recipient BM using cytokines and culture conditions that promote the growth of DCs.

RESULTS

Tacrolimus alone significantly prolonged median heart graft survival time from 10 to 22 days (P<0.001). BM alone failed to prolong graft survival. By contrast, tacrolimus + donor BM resulted in a mean survival time of 42 days (P<0.01 compared with tacrolimus treatment alone). This marked increase in heart allograft survival was associated with reduced anti-donor cytotoxic T lymphocyte responses attributable to a nonspecific effect of tacrolimus. In addition, however, a link was observed between the beneficial effect of donor BM and comparatively large numbers of donor major histocompatibility complex class II (IAb+)-positive cells in recipients' spleens, and in cultures of granulocyte-macrophage colony-stimulating factor + interleukin-4-stimulated DCs from recipients' BM. No donor-derived cells were propagated from heart graft recipients given either tacrolimus or donor BM alone.

CONCLUSIONS

This nonvascularized organ transplant model demonstrates the positive effect on allograft survival of donor BM given at the time of transplant to transiently immunosuppressed recipients. The findings also reveal links between hematopoietic cell chimerism, the presence of donor DC progenitors in recipient BM, and organ allograft survival.

Induction of allograft nonresponsiveness after intrathymic inoculation with donor class I allopeptides. II. Evidence for persistent chronic rejection despite high levels of donor microchimerism

We have recently demonstrated that three synthetic peptides corresponding to the donor class I RT1.Aa molecule induce long-term survival of cardiac allografts in the PVG.R8-to-PVG.1U rat strain combination (disparate for one isolated class I, RT1.A, molecule) when presented to the recipient immune system in the thymus. Long-term graft survivors had measurable levels of donor-reactive alloantibodies in their serum. In this study, we examined long-term allografts for the presence of chronic rejection and donor microchimerism to assess whether this regimen of immune modulation establishes true tolerance and whether this tolerance is dependent upon the presence of donor-recipient microchimerism. Histological examination of long-term heart grafts (>100 days) demonstrated chronic rejection, including a mild degree of myocardial infiltration by mononuclear cells, mild to moderate myocardial fibrosis, and various vascular changes ranging from focal intimal thickening to total vascular lumen blockade due to smooth muscle cell proliferation. In contrast, long-term syngeneic hearts transplanted under similar experimental conditions lacked these pathological manifestations. Donor microchimerism was analyzed using the polymerase chain reaction with a pair of oligonucleotides specific for the donor class I RT1.Aa gene and genomic DNA harvested from various tissues from graft recipients. We detected high levels of donor microchimerism in the heart, kidney, liver, skin, bone marrow, thymus, and lymph nodes of long-term graft recipients. Donor microchimerism was also detected in unmanipulated control graft recipients at rejection (7 days) and in intrathymically manipulated recipients that rejected allografts in a delayed fashion (12-82 days). These data clearly demonstrate that intrathymic inoculation of donor class I allopeptides induces long-term graft survival but does not prevent chronic rejection. Allograft rejection occurred despite high levels of donor microchimerism, providing direct evidence that donor-recipient microchimerism is not sufficient for the prevention of acute or chronic rejection in this model.

Bone marrow chimerism and transplantation tolerance

Engraftment of allogeneic or xenogeneic pluripotent hematopoietic stem cells into nonmyeloablated but immunodepleted (preconditioned) recipients can produce a state of immunological tolerance to donor and host. Host and donor hematopoietic cells entering the thymus ensure deletion of both donor- and host-reactive thymocytes. Additional mechanisms are involved in tolerance induced in recipients that are not immunodepleted. Grafting of donor thymic tissue to thymectomized recipients is an alternative approach for inducing central T cell tolerance without the requirement for engraftment of donor hematopoietic stem cells. During the past year, advances have been made in understanding both the requirements for preconditioning and the mechanisms of tolerance induction in the above transplantation models.

Peripheral blood microchimerism in human liver and renal transplant recipients: rejection despite donor-specific chimerism

BACKGROUND

Development of donor-specific microchimerism (DSM) has been proposed as one of the possible mechanisms for induction and maintenance of allograft tolerance. The aim of this study was to determine: (1) the state of DSM in liver transplant (LTx) and renal transplant (RTx) recipients, (2) whether the persistent presence of an allograft is a requirement for maintenance of chimerism, and (3) whether donor-specific blood transfusions (DST) facilitate chimerism development in RTx recipients and whether this correlates with allograft function.

METHODS

Qualitative and quantitative analysis of DSM in peripheral blood of LTx and RTx recipients was assessed by polymerase chain reaction and competitive polymerase chain reaction using HLA-DR probes for mismatched antigens between the donor and recipient.

RESULTS

LTx recipients (11 of 12) who had or were having rejection were positive for DSM in circulation compared with 4 of 11 with normal allograft function (P<0.01). The number of donor cells did not correlate with allograft function. LTx recipients (4 of 4) who lost their first allograft and underwent retransplantation retained DSM for the first donors. RTx recipients who received DST (8 of 8) were positive for DSM compared with 6 of 12 of nontransfused recipients (P<0.045).

CONCLUSIONS

The results suggest that LTx and RTx recipients undergo rejection despite DSM. The development of DSM may not be a prerequisite for normal allograft function. Once DSM is established, the presence of the allograft is not required for maintenance of chimerism. DST facilitated the development of DSM in RTx recipients. Direct correlation was not observed between the development of DSM and allograft function in either DST or nontransfused RTx recipients.

Use of allogeneic bone marrow labeled with neomycin resistance gene to examine bone marrow-derived chimerism in experimental organ transplantation

Posttransplant infusion of viable donor bone marrow cells (DBMC) has been shown in our previous studies to promote acceptance of incompatible kidney allografts in rhesus monkeys after treatment with polyclonal antithymocyte globulin to deplete peripheral T-lymphocytes. In this nonhuman primate model, the infusion of the DBMC is requisite for the induction of functional graft tolerance and specific MLR and CTLp unresponsiveness, although the relevant role and fate of bone marrow-derived chimeric cells is uncertain. Standard immunological and molecular techniques applied to this monkey model are unable to differentiate between chimeric cells derived from the infused DBMC and those derived from allograft-borne passenger leukocyte emigrants. To distinguish chimerism due to infused DBMC, we transduced DBMC with a functional neomycin resistance gene (Neo(r)) using the retroviral vector pHSG-Neo.Neo(r)-transduced BMC were infused into recipients approximately 2 wk after kidney transplantation and treatment with rabbit antithymocyte globulin. No maintenance immunosuppressive drugs were given. Genomic DNA isolated from peripheral blood leukocytes was used to monitor the presence ofNeo(r)-positive cells. Tissue samples obtained at necropsy also were assessed forNeo(r)-positive chimeric cells. The presence of DBMC-derived chimerism was assessed by polymerase chain reaction usingNeo(r) sequence-specific primers (PCR-SSP). Chimerism was detectable in recipient tissues at various times for up to 6 mo after DBMC infusion. These studies using gene transduction methodology indicate that a stable genetic marker can provide capability to examine DBMC-derived chimerism for prolonged periods in a nonhuman primate model. This approach should facilitate future studies in preclinical models to study the role and type of chimeric cell lineages in relation to functional allograft tolerance.

The effects of chimeric cells following donor bone marrow infusions as detected by PCR-flow assays in kidney transplant recipients

40 recipients of first cadaver kidney transplants were given perioperative donor vertebral bone marrow infusions (DBMC), compared with 100 controls who did not receive donor bone marrow. The immunosuppressive regimen included OKT3, Tacrolimus, and steroid maintenance therapy, and, in some patients, newly introduced mycophenolate mofetil. This report describes the 24-mo actuarial follow-up and several immunological monitoring studies including sequential measurements of donor bone marrow lineage subset chimerism by the recently reported PCR-flow assay. This is a sensitive in situ PCR detection system for donor versus recipient histocompatibility genes as well as cell surface CD epitope markers using flow cytometry. The results indicate (a) the stabilization of the donor CD3+ and CD34+ cells in recipient peripheral blood at levels below 1% between 6 mo and 1 yr postoperatively, with a 10-fold higher level of donor cell chimerism of these lineages in recipient iliac crest marrow; (b) significantly lower levels of chimerism in peripheral blood up to 6 mo postoperatively in patients who had early acute (reversible) rejection episodes compared with those who did not; (c) a higher degree of chimerism seen in patients who were class II MHC HLA DR identical with their donors; (d) the identification of a high proportion of the donor bone marrow derived CD3 dimly staining subset of T cells (to which regulatory functions have been ascribed) in recipient peripheral blood and especially in recipient bone marrow; and (e) an unexpectedly increased susceptibility to clinically significant infections (primarily viral), and even death in the DBMC-infused group, compared with controls, but no graft losses because of rejection in the DBMC-infused group. Mixed lymphocyte culture assays showed a trend toward a greater number of nonspecifically low reactors in the DBMC group, as well as a greater number of nonspecifically high reactors in the controls (P = 0.058). The autologous mixed lymphocyte reaction also indicated a trend towards nonspecific immune activation in the DBMC group. Finally, anti-cytomegaloviral IgG antibody reactivity was significantly inhibited in the DBMC group 4-6 mo postoperatively (P = < 0.05). In the controls, there were no donor cell lineages detected by PCR-flow in the peripheral blood. These rather unexpected findings, indicating a more depressed cellular and humoral immune capacity in the DBMC cadaver kidney transplant recipients in this relatively early follow-up period, are discussed relevant to chimerism, MHC restriction, and suppressor activity brought about by specialized DBMC subsets, which still need to be defined.