Immune "tolerance profiles" in donor bone marrow infused kidney transplant patients using multiple ex vivo functional assays.

Ex vivo identification of donor-specific unresponsiveness in organ transplant recipients is important for immunosuppression (IS) minimization. We tested three groups of stable living, related-donor kidney transplant patients up to 11 years postoperatively, i.e., 20 haploidenticals with donor bone marrow cell (DBMC) infusions, eight noninfused haploidentical controls (haplo controls), and 11 HLA-identical controls (HLA-id), using multiple ex vivo immune assays. We observed that no patients developed donor-specific antibodies. The majority showed donor-specific CTL unresponsiveness from year 1 onward. Thirteen of 20 DBMC recipients became specifically donor MLR nonreactive. Depletion of donor cells in DBMC recipients still MLR reactive increased donor-specific reactivity by 75% +/- 36% (p = 0.04). Adding them back in low concentration caused antigen specific inhibition. The frequencies of ELISPOT granzyme-B and interferon-gamma-producing cells somewhat paralleled the CTL and MLR responses. In the trans vivo DTH, 14 of 19 DBMC recipients demonstrated donor-specific unresponsiveness and 16 of 19 showed "linked suppression," vs none of eight and one of eight haplo controls and vs six of 10 and one of 10 HLA-ids, respectively. Most importantly, when all six assays were performed simultaneously, 10 of 18 DBMC, five of 10 HLA-ids, and no haplo controls were specifically donor unresponsive long term. We propose that a cluster analysis combining these assays will reveal tolerant recipients in whom IS minimization may safely be tested. This appears to have occurred in many DBMC-infused recipients.

FoxP3 mRNA transcripts and regulatory cells in renal transplant recipients 10 years after donor marrow infusion.

BACKGROUND: We update more favorable 10-year deceased donor kidney transplant survival in 63 recipients infused perioperatively with donor vertebral body bone marrow (DBMC-i) vs. 219 noninfused controls having equivalent immunosuppression and demographics. We questioned if this was associated with putatively regulatory FoxP3 mRNA and cell phenotypes (CD4+CD25+high percentages and high DC2:DC1 ratios) in DBMC-i vs. noninfused controls. METHODS: Baseline studies were performed on peripheral blood lymphocytes (PBLs) vs. marrow in normal laboratory volunteers of CD4+CD25+high percentages and DC2:DC1 by flow cytometry, and FoxP3 mRNA in CD3+ cells by real-time polymerase chain reaction. Similar studies were performed on PBL of the majority of the 10-year patients remaining with graft function: 21 (of the remaining 37) DBMC-i vs. 55 (of the remaining 105) controls. RESULTS: In normal subjects, all parameters were significantly higher in marrow than in PBL, supporting our previous reports of ex vivo DBMC immunoregulation. At 9.8+/-.02 years posttransplant in DBMC-i vs. controls, death-censored percent graft failure was 17.5% vs. 32.9% (P=0.02) with 247.6+/-24 vs. 79.9+/-3.1 (mean+/-SE) FoxP3 copies/5,000 CD3+ cells (P=0.0001). PBL CD4+CD25+high percentages were lower, but DC2:DC1 values higher in both recipient groups than in end-stage renal disease patients who had lower FoxP3 levels (40.8+/-5.9, P<0.0001), consistent with non-CD4+CD25+high T regulatory cells generated long-term posttransplant. Individual higher FoxP3 values correlated with higher iliac crest chimerism in DBMC-i, but not in controls (with 50-fold lower chimerism). In chronically rejecting controls, FoxP3 was further decreased. CONCLUSIONS: Peritransplant DBMC-i has higher 10-year renal transplant acceptance, chimerism, and FoxP3 mRNA in thus-far unclarified regulatory cell phenotypes.

A novel approach to detect donor/recipent immune responses between HLA-identical pairs.

Renal transplant rejection and graft versus host reactions between HLA genetically-identical sibling (HLAgi) donor/recipient (D/R) pairs are thought to result from minor histocompatibility antigen (mHAg) disparities. We have compared two methods of measuring HLAgi D/R T lymphocyte responses to "matured" dendritic cells: 1.) a modified Cylex assay of CD4(+) ATP levels (MLDC-ATP) versus 2.) (3)H-thymidine uptake (MLDC-(3)H). The MLDC-ATP kinetics peaked at 48 hours versus the MLDC-(3)H at 7 days, and appeared more sensitive. We tested HLAgi (normal) volunteer siblings (NLs), and D/R sibling pairs before and after renal transplantation (pre-Tx and post-Tx). The overall frequencies of positive responses in the MLDC-ATP for HLAgi NLs, pre-Tx, and post-Tx D/R pairs were 63%, 50%, and 42%, respectively. The percentage with reciprocal responses was 37.5%, 20%, and 22.22%, respectively. In one set of three HLAgi (NLs) siblings (two males and one female), there was a nongender-associated differential response. There was no MLDC correlation with class I MHC-associated mHAg (SSP) incompatibility, nor could some MLDC positive reactive pairs theoretically process the necessary HLA-class I restriction molecules for presentation of known (nanomeric) mHAg peptides. Speculatively, the MLDC reflects class II MHC-restricted mHAg reactions (not yet definable), with possible effects of other polymorphic (nonhistocompatibility) immune response genes, and thereby may be a useful measurement of CD4(+) T-cell HLAgi transplantation immunity.

Induction of auto-reactive regulatory T cells by stimulation with immature autologous dendritic cells.

We have shown in ex vivo studies in donor bone marrow-infused kidney transplant recipients, that chimeric cells of either donor or recipient origin taken from the recipient's bone marrow down-regulated the recipient's cellular immune responses. In the present study, we have now induced regulatory T cells from peripheral blood mononuclear cells (PBMC) of renal transplant recipients or laboratory volunteers by multi-stimulation with autologous immature dendritic cell (iDC) enriched populations derived from either bone marrow cells (BMC) of the (immunosuppressed) kidney transplant recipients or PBMC of the laboratory volunteers (i.e., ibDC and ipDC, respectively). These regulatory T cells, induced by ibDC and ipDC, were autoreactive and designated as TAb and TAp with similar phenotypes and functional profiles. They were largely CD4 + CD25high, CD45RA low and CD45RO high, and uniformly expressed intracellular CTLA-4, and message of IL-4, IL-10, Foxp3, and differentially expressed TGFbeta. Their proliferative responses to autologous mature dendritic stimulating cells (mDC) were approximately two-fold stronger than to allogeneic mDC, and to allogeneic mDC were significantly lower than those of (control) autologous TPBL, suggesting an anergic state. TAb and TAp were not cytotoxic to autologous cells expressing Epstein-Barr virus (EBV) antigens, but were able to inhibit (regulate) the effector phase of this TPBL response to both autologous and allogeneic EBV lymphoblasts. This regulation appeared to require cell-to-cell contact.

Campath-1H does not alter bone marrow cell regulatory function.

We have previously reported in laboratory volunteers (in vitro) and renal transplant recipients (ex vivo) that bone marrow cells (BMC) are potent downregulators of the immune response. Also, the use of alemtuzumab (Campath-1H, C1H) for immunodepletion is associated with the most potent lasting effects yet seen on T-cell immunity in renal transplantation. We questioned whether the administration of C1H to kidney allograft recipients of donor bone marrow cell (DBMC) infusions would lead to stronger or weaker immunoregulatory effects. Human BMC depleted of T cells (nT-BMC) were either untreated or treated with C1H and rabbit complement and compared for their ability to downregulate autologous or allogeneic T-cell responses and to generate T regulatory (T reg) cells. The proliferative responses to anti-CD3 monoclonal antibody of T cells derived from cocultures with C1H-treated or untreated autologous nT-BMC were equally suppressed, i.e., an equivalent alteration in CD3 complex signaling, not regained by the addition of interleukin 2. Adenosine triphosphate levels were also markedly reduced in T cells both from C1H-treated and untreated nT-BMC cocultures. The ability of C1H-treated or untreated nT-BMC to suppress autologous T-cell cytotoxic function was also equivalent, with a marked, but equivalent, capacity to induce CD4/CD25(high) T regs from CD3(+) cells, which effectively downregulated cytotoxic T cells. To mimic the clinical infusion of DBMC into (allogeneic) recipients, peripheral blood mononuclear cells were also cultured with allogeneic C1H-treated and untreated nT-BMC. T cells derived from these cultures secondarily stimulated with the same-donor mature antigen-presenting cells exhibited suppressed cytotoxicity by 85% and 54%, respectively. These in vitro studies suggest that C1H does not abrogate BMC immunoregulation and thus may allow its lympho-depleting effect to be synergistic.

Antigen presentation and immune regulatory capacity of immature and mature-enriched antigen presenting (dendritic) cells derived from human bone marrow.

Several reports including those from this laboratory have demonstrated that bone marrow cells (BMC) downregulate in vitro both mixed leukocyte reaction and cytotoxic T lymphocyte reactions. We consequently hypothesized that a general property of immature cells of hematopoietic organs is their ability to suppress immune reactivity. As one of these suppressive activities, the lack of costimulatory molecules was proposed as a mechanism by which immature antigen presenting cells of the bone marrow might be involved. In the present report, we used two culture environments, each of which would regulate a different maturation pattern of human bone marrow-derived enriched dendritic antigen presenting cells (DC or APC) to determine the respective effects on in vitro immune regulatory function. Human BMC depleted of CD3+ cells were cultured with either: interleukin-4 (IL-4) and granulocyte macrophage-colony stimulating factor (GM-CSF), to maintain DC-enriched populations in an immature state (iAPC); or an interferon-gamma (IFNgamma), tumor necrosis factor alpha (TNF-alpha), GM-CSF, LPS, and IL-6 cocktail to promote the maturation of DC-enriched APC (mAPC). These iAPC and mAPC were, respectively, phenotypically characterized and also tested in vitro for the following: (1) both direct and indirect-antigen presentation functions; (2) immune regulatory functions on the response of autologous and allogeneic peripheral blood lymphocytes (PBL); and (3) Western blot analysis determining the levels of both major histocompatibility complex (MHC) class I related cytoplasmic transporter molecules associated with antigen processing (TAP1) and as well as proteasome activator molecules (PA28alpha). The iAPC population expressed fewer dendritic cell markers (CD83 and DCsign), and costimulator molecules (CD86 and CD40) than the mAPC, such that there was an approximate threefold increase in expression of CD83, 2.5-fold increase in DCsign, and a threefold increase in CD40 and CD86 on mAPC than on iAPC (p=0.005 for CD83; p=0.001 for DCsign; p=0.001 for CD86; and p=0.001 for CD40). In lymphoproliferative assays, indirect and direct alloantigen presentation by iAPC was weaker than by mAPC (p=0.05 and 0.04). In addition, iAPC were able to downregulate allogeneic CTL responses. Also, after pulsing with Epstein-Barr virus (EBV) protein antigens, the iAPC were less efficient in their presentation to autologous EBV-specific T-cell lines, and caused an inhibition of EBV-CTL generation. The expression of TAP1 and PA28alpha was reduced in iAPC in comparison to mAPC. These findings support the notion that a maturation state of BMC-derived APC correlates with their capacity to present antigen. The observed in vitro deficiency of this function by immature bone marrow cells may therefore contribute to the immune downregulatory capacity seen in the BMC compartment.

Immune responses and their regulation by donor bone marrow cells in clinical organ transplantation.

Infusions of donor bone marrow derived cells (DBMC) continue to be tested in clinical protocols intended to induce specific immunologic tolerance of solid organ transplants based on the observations that donor-specific tolerance is induced this way in animal models. We studied the immunological effects of human DBMC infusions in renal transplantation using modifications in lymphoproliferation (MLR) and cytotoxicity (CML) assays. The salient observations and tentative conclusions are summarized in this review. Among many types of organs transplanted using DBMC at this center, it was found that the cadaver renal recipients (CAD) had significantly decreased chronic rejection and higher graft survival when compared to equivalent non-infused controls. DBMC infusion was also associated with a marginal and non-specific immune depression. It was also observed that the number of chimeric donor cells gradually increased in the iliac crest bone marrow compartment with a concomitant decrease in the peripheral blood and that the increase was more rapid in living-related donor (LRD)-kidney/DBMC recipients in spite of a lower number of DBMC infused (<25%) than in the CAD-kidney/DBMC group. In the LRD recipients with residual anti-donor responses, purified chimeric cells of either donor or recipient inhibited recipient immune responses to the donor significantly more strongly than the freshly obtained bone marrow from the specific donor or volunteer suggesting an active regulatory role for chimeric cells. A number of (non-chimeric) subpopulations of bone marrow cells including CD34(+) stem cells and the CD34(-) early progeny like CD38(+), CD2(+), CD5(+) and CD1(+) lymphoid cells as well as CD33(+) (but CD15(-)) myeloid cells down-regulated the MLR and CML responses of allogeneic PBMC stimulated with (autologous) donor spleen cells. These regulatory effects appeared to be refractory to the action of commonly used immunosuppressive drugs and occurred during the early phase of the immune response through cell-cell interactions. Most of these DBMC sub-populations had stimulatory capabilities, albeit markedly lower than donor spleen cells, but only through the indirect antigen presentation pathway. When co-cultured with allogeneic stimulators, purified CD34(+) cells were found to give rise both to CD3(-) TCRalphabeta(+), as well as CD3(+) TCRalphabeta(+) cells and, thereby, responded in MLR to allogeneic stimulation (but did not generate cytotoxic effector cells). Also, a number of DBMC subpopulations inhibited the CML and to a lesser extent the MLR, of autologous post-thymic responding T cells stimulated with allogeneic irradiated cells, mediated through soluble factors. Finally, non-chimeric DBMC also inhibited the proliferative and cytotoxic responses of autologous T cells to EBV antigens, inducing T suppressor cells, which in turn could inhibit autologous anti-EBV CTL generation and B cell anti-CMV antibody production. These studies all suggested a strong inhibitory property of a number of DBMC sub-populations in vitro and in vivo with the notion that they promote unresponsiveness.

Human donor bone marrow cells induce in vitro "suppressor T cells" that functionally suppress autologous B cells.

We have reported a beneficial effect of donor vertebral body bone marrow cells (DBMC) infusions in cadaver renal allograft recipients in a 6-year follow-up, but with a transient increase in early (6 month) postoperative CMV infections and concomitant suppressed immunoglobulins (Ig) production. We also found that although there was no difference between the DBMC-infused and non-infused (control) groups in the development of donor-specific antibody, we now describe an additional difference seen in the percent reactive antibody (PRA) reactivity against a panel of HLA antigens that developed postoperatively. We hypothesize that (allogeneic) antigen presenting cells in the DBMC, systemically infused, caused the generation of recipient T suppressor (T4-suppressor) cells, thereby "inducing" a negative influence on B cell Ig production. We tested this notion in vitro by incubating PBL from CMV IgG positive laboratory volunteers with either (allogeneic) T-cell depleted DBMC or donor spleen cells (DSPC) from (the same) cadaver donors. After 7 days, the (responding) T cells were collected using magnetic beads and placed in culture with purified B cells freshly obtained from the same (autologous) CMV positive volunteer. To these cultures were added either media or 40 ng of CMV antigen. After 3, 5, 7, and 9 days, the expression of surface anti-CMV Ig was measured by flow cytometry using a panel of fluorescent markers double-labeled for activated B cells (CD20, CD19, and HLA DRw) and CMV-FITC. We also determined the phenotype of the cultured T cells using anti-CD3, CD4, and CD62L specific monoclonal antibodies. B cells that had been in contact with autologous T cells derived from DBMC cultures (TBM) were less likely to express anti-CMV surface Ig than those cultured with DSPC (TSP). The flow cytometry analysis revealed an increase in the number of T4 suppressor cells (CD3+, CD4+, CD62L+) in the TBM group, whereas the T4 helper phenotype (CD3+, CD4+, CD62L-) predominated in the TSP group. These in vitro findings support the notion that (allogeneic) DBMC infusions can induce a T4 suppressor (regulatory) influence and thereby indirectly affect B-cell function.

A novel micro-cell-mediated lympholytic assay for the evaluation of regulatory cells in human alloreactive CTL responses.

Since cell-mediated lympholysis (CML), the most commonly used in vitro experimental cytotoxic method for the evaluation of regulatory cells, requires large numbers of cells that are often the limiting factor, we have developed a new micro-cell-mediated lympholytic (m-CML) assay. Various numbers of responding cells were stimulated with equivalent numbers of allogeneic irradiated stimulator cells in the presence of (fivefold) serial dilutions of regulatory cells. On the 8th day, 4-h 51Cr-release assays were performed by adding 5000 labeled target cells from the corresponding stimulators to the cultures. Even though results that were comparable to the macro- (bulk) CML and MLR modulation experiments were obtained with all the cell combinations tested in the m-CML, the combinations with 50,000 responder cells and stimulating cells and dilutions of 25,000 to 40 modulator (regulatory) cells were found to be the most reproducible for assaying regulatory cell potency in vitro. Similarly, expression of the results as percentage inhibition using percent specific lysis values was the simplest method of calculation. This assay was standardized for the evaluation of the inhibitory activity of a variety of regulatory cells, including long-term cultures of cadaver-donor vertebral body bone marrow cells (vDBMC-L), in vitro generated CD8 positive and CD28 negative suppressor T cells and donor chimeric cells isolated from renal transplant recipients who had been perioperatively infused with donor bone marrow cells (DBMC). The results indicate that the m-CML assay is a sensitive and reliable micromethod with at least 10-fold fewer responders, stimulator and modulator cell numbers needed than macro-CML assays for the evaluation of regulatory cells obtained from a variety of immune systems in vitro.

Regulation of alloimmune responses (GvH reactions) in vitro by autologous donor bone marrow cell preparation used in clinical organ transplantation.

BACKGROUND: Cadaver donor bone marrow cells (DBMC) are capable of a low-grade response to allogeneic stimulation in vitro, indicating their potential ability to cause graft versus host disease (GvHD). However, at this center, we have observed a lack of GvHD in kidney transplant recipients who received DBMC perioperatively. Therefore, we questioned whether an intrinsic immunoregulatory function of (subpopulations of) DBMC might play a role in this observation. METHODS: In in vitro assays, DBMC was added to autologous splenic responder cells taking part in allogeneic mixed lymphocyte reaction (MLR) and cell-mediated lympholysis (CML) reactions. RESULTS: When compared with autologous donor irradiated spleen cells as control modulators, DBMC significantly inhibited the CML, but to a much lesser extent than MLR, of autologous responding cells stimulated with allogeneic irradiated cells in a dose dependent manner. The down-regulation of CML responses was observed even in the presence of pharmacological concentrations FK506, mycophenolic acid, or cyclosporine-A. The inhibition could not be overcome by the addition of exogenous helper factors. Moreover, in contrast with findings previously reported from this laboratory of the in vitro inhibitory effect of DBMC on allogeneic responding cells in MLR and CML reactions to stimulating cells of the DBMC donor (allogeneic host versus graft inhibition), the following unique observations were made using DBMC inhibiting autologous reactions (GvH): (1) optimal restimulation of autologous responder cells in secondary cultures could not abrogate this inhibition; even activated responder cells could be inhibited by autologous DBMC, and (2) soluble factors were at least partially operative in this autologous (GvH) inhibition as indicated by experiments in transwells and by the CML inhibition caused by 50% supernatants from DBMC cultures. CONCLUSION: These in vitro results indicate that DBMC treatment brings about a marked down-regulation of autologous immunocompetent cells in cytotoxicity reactions, partially at least through secreted soluble factor(s), (and in presence of immunosuppressive drugs in vivo) thereby preventing overt clinical GvHD.

Functional and phenotypic properties of peripheral T cells anergized by autologous CD3(+) depleted bone marrow cells.

We have previously demonstrated that bone marrow cells (BMC) inhibit the generation of autologous Epstein-Barr virus (EBV) -specific cytotoxic T lymphocytes (CTL). It was also observed that CD3(+) cells obtained after 7 days of culture in the presence of autologous BMC could be used as inhibitors of EBV-CTL generation. In the present study, we examined these BMC induced regulator CD3(+) T cells with respect to phenotype, function, and T-cell activation pathways. We also questioned if the CD3(+) regulatory cell function is mediated by their direct effect on peripheral T cells or on the ability of antigen presenting cells (APC) to stimulate peripheral T cells. To answer this, CD3(+) cells from peripheral blood lymphocytes (PBL) were cultured with either CD3-depleted BMC or with CD3-depleted PBL. The CD3(+) cells were then isolated with immunomagnetic beads, designated as T(BM) and T(PBL), and were compared in functional studies. There was an increase in the expression of CD25 on T(BM) cells. The T(BM) cells also expressed less CD122 and a decreased number of CD3 molecules per cell. Both T(BM) and T(PBL) cell populations responded to mitogen (PHA) to the same magnitude. However, when stimulated through the CD3 complex with anti-CD3 monoclonal antibody (mAb), the T(BM) cells had a significantly decreased response than did T(PBL). The addition of IL-2 to these latter cultures augmented, but could not fully restore, the response. Additionally, stimulation of T(BM) cells with allogeneic cells failed to produce cytotoxic T cells. These "anergized" T(BM) and "nonanergized" (control) T(PBL) cells were added as third-party cells to a CTL generating culture of autologous PBL stimulated with allogeneic cells. The T(BM) cells exhibited suppressor function and inhibited the generation of CTL, in contrast with T(PBL). The effect of T(BM) cells on direct and indirect antigen presentation pathways demonstrated that T(BM) primarily effected indirect, but not direct, alloantigen presentation. To further explore the cytoplasmic T-cell activation events that occurred after the coculture of the PBL T cells with BMC, the levels of zeta-associated protein 70 (ZAP70) and extracellular receptor-activated kinase (ERK) were determined. There was a decrease in ZAP70 levels in the T(BM), which correlated with its reduced expression of cell surface CD3 and the attenuated response to anti-CD3 mAb activation. However, the activity of ERK was equally expressed by T(BM) and T(PBL). It, therefore, appears that the culturing of peripheral T cells with (non-T) BMC anergizes these cells (which become refractory to stimulation through the T-cell receptors), and induces immune suppressor function. These in vitro observations may provide a mechanism by which infused donor BMC serve to downregulate T-cell immunity.