B Cells Help Alloreactive T Cells Differentiate Into Memory T Cells

B cells are recognized as effector cells in allograft rejection that are dependent upon T cell help to produce alloantibodies causing graft injury. It is not known if B cells can also help T cells differentiate into memory cells in the alloimmune response. We found that in B‐cell‐deficient hosts, differentiation of alloreactive T cells into effectors was intact whereas their development into memory T cells was impaired. To test if B cell help for T cells was required for their continued differentiation into memory T cells, activated T cells were sorted from alloimmunized mice and transferred either with or without B cells into naïve adoptive hosts. Activated T cells cotransferred with B cells gave rise to more memory T cells than those transferred without B cells and upon recall, mediated accelerated rejection of skin allografts. Cotransfer of B cells led to increased memory T cells by enhancing activated CD4 T‐cell proliferation and activated CD8 T‐cell survival. These results indicate that B cells help alloreactive T‐cell differentiation, proliferation and survival to generate optimal numbers of functional memory T cells.     

Alefacept Promotes Immunosuppression‐Free Renal Allograft Survival in Nonhuman Primates via Depletion of Recipient Memory T Cells

Renal allograft tolerance has been achieved in MHC‐mismatched primates via nonmyeloablative conditioning beginning 6 days prior to planned kidney and donor bone marrow transplantation (DBMT). To extend the applicability of this approach to deceased donor transplantation, we recently developed a novel‐conditioning regimen, the “delayed protocol” in which donor bone marrow (DBM) is transplanted several months after kidney transplantation. However, activation/expansion of donor‐reactive CD8⁺ memory T cells (TMEM) occurring during the interval between kidney and DBM transplantation impaired tolerance induction using this strategy. In the current study, we tested whether, Alefacept, a fusion protein which targets LFA‐3/CD2 interactions and selectively depletes CD2^highCD8⁺ effector memory T cells (TEM) could similarly induce long‐term immunosuppression‐free renal allograft survival but avoid the deleterious effects of anti‐CD8 mAb treatment. We found that Alefacept significantly delayed the expansion of CD2^high cells including CD8⁺ TEM while sparing naïve CD8⁺ T and NK cells and achieved mixed chimerism and long‐term immunosuppression‐free renal allograft survival. In conclusion, elimination of CD2^high T cells represents a promising approach to prevent electively the expansion/activation of donor‐reactive TEM and promotes tolerance induction via the delayed protocol mixed chimerism approach.

     

ICOS-Dependent and -Independent Functions of Memory CD4 T Cells in Allograft Rejection

Donor-reactive memory T cells undermine the survival of transplanted organs through multiple pathways. We have previously reported that memory CD4 T cells resist treatment with anti-CD154 antibody and donor-specific transfusion (DST/MR1) and promote cardiac allograft rejection via generation of effector CD4 T cells and alloantibody. We hypothesized that the helper functions of memory CD4 T cells are independent of T-cell costimulation through CD154 but instead are regulated by alternative costimulatory pathways. This study investigated how blocking ICOS/B7RP-1 interactions affects functions of donor-reactive memory CD4 T cells. Treatment with blocking anti-ICOS mAb synergized with DST/MR1 and prolonged mouse cardiac allograft survival despite the presence of donor-reactive memory CD4 T cells. While blocking ICOS did not diminish the expansion of preexisting memory CD4 T cells or the induction of allospecific effector T cells, it did inhibit recruitment of the activated memory and effector T cells into the graft. In addition, anti-ICOS mAb treatment in combination with DST/MR1 prevented help provided by memory CD4 T cells for production of donor-specific IgG antibody. These results demonstrate the potential efficacy of ICOS blockade in sensitized transplant patients and provide the foundation for rational use of ICOS blockade in combination with other graft-prolonging strategies.     

Regulatory T Cells Are Critical to Tolerance Induction in Presensitized Mouse Transplant Recipients Through Targeting Memory T Cells

Memory T cells are a significant barrier to induction of transplant tolerance. However, reliable means to target alloreactive memory T cells have remained elusive. In this study, presensitization of BALB/c mice with C57BL/6 skin grafts generated a large number of OX40⁺CD44^hieffector/memory T cells and resulted in rapid rejection of donor heart allografts. Recognizing that anti‐OX40L monoclonal antibody (mAb) (α‐OX40L) monotherapy prolonged graft survival through inhibition and apoptosis of memory T cells in presensitized recipients, α‐OX40L was added to the combined treatment protocol of LF15–0195 (LF) and anti‐CD45RB (α‐CD45RB) mAb—a protocol that induced heart allograft tolerance in non‐presensitized recipients but failed to induce tolerance in presensitized recipients. Interestingly, this triple therapy restored donor‐specific heart allograft tolerance in our presensitized model that was associated with induction of tolerogenic dendritic cells and CD4⁺CD25⁺Foxp3⁺ T regulatory cells (Tregs). Of note, CD25⁺ T cell depletion in triple therapy recipients prevented establishment of allograft tolerance. In addition, adoptive transfer of donor‐primed effector/memory T cells into tolerant recipients markedly reduced levels of Tregs and broke tolerance. Our findings indicated that targeting memory T cells, by blocking OX40 costimulation in presensitized recipients was very important to expansion of Tregs, which proved critical to development of tolerance.     

Low‐Dose IL‐2 for In Vivo Expansion of CD4+ and CD8+ Regulatory T Cells in Nonhuman Primates

IL‐2 is a known potent T cell growth factor that amplifies lymphocyte responses in vivo. This capacity has led to the use of high‐dose IL‐2 to enhance T cell immunity in patients with AIDS or cancer. However, more recent studies have indicated that IL‐2 is also critical for the development and peripheral expansion of regulatory T cells (Tregs). In the current study, low‐dose IL‐2 (1 million IU/m² BSA/day) was administered to expand Tregs in vivo in naïve nonhuman primates. Our study demonstrated that low‐dose IL‐2 therapy significantly expanded peripheral blood CD4⁺ and CD8⁺ Tregs in vivo with limited expansion of non‐Treg cells. These expanded Tregs are mainly CD45RA^? Foxp3 ^high activated Tregs and demonstrated potent immunosuppressive function in vitro. The results of this preclinical study can serve as a basis to develop Treg immunotherapy, which has significant therapeutic potential in organ/cellular transplantation.     

Ex Vivo‐Expanded Cynomolgus Macaque Regulatory T Cells Are Resistant to Alemtuzumab‐Mediated Cytotoxicity

Alemtuzumab (Campath‐1H) is a humanized monoclonal antibody (Ab) directed against CD52 that depletes lymphocytes and other leukocytes, mainly by complement‐dependent mechanisms. We investigated the influence of alemtuzumab (i) on ex vivo‐expanded cynomolgus monkey regulatory T cells (Treg) generated for prospective use in adoptive cell therapy and (ii) on naturally occurring Treg following alemtuzumab infusion. Treg were isolated from PBMC and lymph nodes and expanded for two rounds. CD52 expression, binding of alemtuzumab and both complement‐mediated killing and Ab‐dependent cell‐mediated cytotoxicity (ADCC) were compared between freshly isolated and expanded Treg and effector T cells. Monkeys undergoing allogeneic heart transplantation given alemtuzumab were monitored for Treg and serum alemtuzumab activity. Ex vivo‐expanded Treg showed progressive downregulation of CD52 expression, absence of alemtuzumab binding, minimal change in complement inhibitory protein (CD46) expression and no complement‐dependent killing or ADCC. Infusion of alemtuzumab caused potent depletion of all lymphocytes, but a transient increase in the incidence of circulating Treg. After infusion of alemtuzumab, monkey serum killed fresh PBMC, but not expanded Treg. Thus, expanded cynomolgus monkey Treg are resistant to alemtuzumab‐mediated, complement‐dependent cytotoxicity. Furthermore, our data suggest that these expanded monkey Treg can be infused into graft recipients given alemtuzumab without risk of complement‐mediated killing.     

The Challenge of Inhibiting Alloreactive T-Cell Memory

Memory T cells specific for donor antigens present a unique challenge in transplantation. In addition to expressing rapid and robust immune responses to a transplanted organ, memory T cells may be resistant to the effects of currently used graft-prolonging therapies. The increasing recognition that alloreactive memory T cells participate in transplant rejection is driving new lines of research focusing on understanding the immunobiology of alloreactive memory T cells and on designing novel therapies to specifically target memory T cells. The purpose of this review is to summarize the effects of existing immunosuppressive drugs and costimulatory blockade on functions of alloreactive memory T cells that undermine allograft survival.     

Transforming Growth Factor Beta Expression by Human Vascular Cells Inhibits Interferon Gamma Production and Arterial Media Injury by Alloreactive Memory T Cells

Arteriosclerosis is characterized by the local activation of effector T cells leading to production of proinflammatory cytokines, such as IFN (interferon)‐γ and IL‐17, within the vessel wall. Conversely, the production of antiinflammatory cytokines, for example, TGF‐β, by regulatory lymphocytes is known to inhibit both the differentiation of naïve T cells into effector T cells and the development of arteriosclerosis in murine models. We investigated the role of TGF‐β on the alloreactivity of human effector memory T cells (Tem). Quiescent vascular cells, but not Tem, expressed TGF‐β. Blockade of TGF‐β activity in cocultures of CD4⁺ Tem with allogeneic endothelial cells significantly increased IFN‐γ, but not IL‐17, secretion. Additionally, serologic neutralization of TGF‐β in immunodeficient mouse hosts of human coronary artery grafts into which allogeneic human T cells were adoptively transferred resulted in heavier medial infiltration by Tem, greater loss of medial smooth muscle cells and increased IFN‐γ production within the grafts without significantly reducing either intimal injury or IL‐17 production. Protective effects of TGF‐β may be limited by fewer TGF‐β‐expressing vascular cells within the intimal compartment, by a reduction in the expression of TGF‐β by vascular cells in rejecting grafts, or possibly to less effective suppression of Tem than naïve T cells.     

Relative Resistance of Human CD4+ Memory T Cells to Suppression by CD4+CD25+ Regulatory T Cells

Successful expansion of functional CD4⁺CD25⁺ regulatory T cells (T_reg) ex vivo under good manufacturing practice conditions has made T_reg‐cell therapy in clinical transplant tolerance induction a feasible possibility. In animals, T_reg cells home to both transplanted tissues and local lymph nodes and are optimally suppressive if active at both sites. Therefore, they have the opportunity to suppress both naïve and memory CD4⁺CD25^? T cells (Tresp). Clinical transplantation commonly involves depleting therapy at induction (e.g. anti‐CD25), which favors homeostatic expansion of memory T cells. Animal models suggest that T_reg cells are less suppressive on memory, compared with naïve Tresp that mediate allograft rejection. As a result, in the context of human T_reg‐cell therapy, it is important to define the effectiveness of T_reg cells in regulating naïve and memory Tresp. Therefore, we compared suppression of peripheral blood naïve and memory Tresp by fresh and ex vivo expanded T_reg cells using proliferation, cytokine production and activation marker expression (CD154) as readouts. With all readouts, naïve human Tresp were more suppressible by approximately 30% than their memory counterparts. This suggests that T_reg cells may be more efficacious if administered before or at the time of transplantation and that depleting therapy should be avoided in clinical trials of T_reg cells.     

Memory T-Cell Predominance Following T-Cell Depletional Therapy Derives from Homeostatic Expansion of Naive T Cells

T-cell depletion reportedly leads to alterations in the T-cell compartment with predominant survival of memory phenotype CD4 T cells. Here, we asked whether the prevalence of memory T cells postdepletion results from their inherent resistance to depletion and/or to the homeostatic expansion of naive T cells and their phenotypic conversion to memory, which is known to occur in lymphopenic conditions. Using a 'mosaic memory' mouse model with trackable populations of alloreactive memory T cells, we found that treatment with murine antithymocyte globulin (mATG) or antilymphocyte serum (ALS) effectively depleted alloreactive memory CD4 T cells, followed by rapid homeostatic proliferation of endogenous CD4 T cells peaking at 4 days postdepletion, with no homeostatic advantage to the antigen-specific memory population. Interestingly, naive (CD44lo) CD4 T cells exhibited the greatest increase in homeostatic proliferation following mATG treatment, divided more extensively compared to memory (CD44hi) CD4 T cells and converted to a memory phenotype. Our results provide novel evidence that memory CD4 T cells are susceptible to lymphodepletion and that the postdepletional T-cell compartment is repopulated to a significant extent by homeostatically expanded naive T cells in a mouse model, with important important implications for immune alterations triggered by induction therapy.     

Preferential Priming of Alloreactive T Cells with Indirect Reactivity

The relative contributions of the direct and indirect pathways in alloimmune responses have not been fully elucidated. We report a novel murine TCR transgenic system that can simultaneously track the CD4-direct (CD4-d), CD4-indirect (CD4-i) and CD8-direct (CD8-d) pathways after transplantation. Using this system, we have observed a profoundly greater proliferation of CD4-i T cells relative to CD4-d and CD8-d T cells after transplantation. Furthermore, a much larger proportion of CD4-i T cells attain an effector phenotype. We also analyzed endogenous, wild-type T cells using enzyme-linked immunospot analysis. In naïve mice, T cells with indirect reactivity were undetectable, but T cells with direct reactivity were abundant. However, 10 days after skin or heterotopic heart transplantation, CD4-i T cells comprised approximately 10% of the CD4+ response. Consistent with increased priming of the CD4-i pathway, we observed that the CD4-i T cells were further enriched in the effector cells migrating to the allograft and in memory-like T cells persisting after rejection. Thus, priming of the CD4-i pathway is favored after transplantation, allowing a rare population to rapidly become a major component of the CD4+ T-cell response in acute allograft rejection. The generalizability of this observation to other models remains to be determined.     

The Role of Costimulatory Molecules in Directing the Functional Differentiation of Alloreactive T Helper Cells

Costimulatory molecules are a heterogenous group of cell surface molecules that act to amplify or counteract the initial activating signals provided to T cells from the T cell receptor following its interaction with an antigen/major histocompatibility complex, thereby influencing T cell differentiation and fate. Although costimulation was previously thought to be indispensable for T cell activation at all stages of development, it is now known that the requirements for costimulation, and the costimulatory molecules involved, vary according to the stage of T cell differentiation. The ability to influence T cell fate is of paramount interest in the field of transplantation as we seek therapeutic options that inhibit detrimental alloimmune responses whilst simultaneously promoting allograft tolerance. As with many immune mechanisms, there is a degree of functional overlap between certain costimulatory molecules, whereas some have diametrically opposite effects on different T cell subsets despite sharing common ligands. This is a critical point when considering these molecules as therapeutic targets in transplantation, as blockade of a costimulatory pathway, although desirable in itself, may prevent the ligation of an essential regulatory coinhibitory molecule. This review discusses the T helper cell lineages pertinent to transplantation and the costimulatory molecules involved in their differentiation.     

Pretransplant Antithymocyte Globulin Has Increased Efficacy in Controlling Donor‐Reactive Memory T Cells in Mice

Antibody‐mediated lymphocyte depletion is frequently used as induction therapy in sensitized transplant patients. Although T cells with an effector/memory phenotype remain detectable after lymphoablative therapies in human transplant recipients, the role of preexisting donor‐reactive memory in reconstitution of the T cell repertoire and induction of alloimmune responses following lymphoablation is poorly understood. We show in a mouse cardiac transplantation model that antidonor immune responses following treatment with rabbit antimouse thymocyte globulin (mATG) were dominated by T cells derived from the preexisting memory compartment. Administration of mATG 1 week prior to transplantation (pre‐TP) was more efficient in targeting preexisting donor‐reactive memory T cells, inhibiting overall antidonor T cell responses, and prolonging heart allograft survival than the commonly used treatment at the time of transplantation (peri‐TP). The failure of peri‐TP mATG to control antidonor memory responses was due to faster recovery of preexisting memory T cells rather than their inefficient depletion. This rapid recovery did not depend on T cell specificity for donor alloantigens suggesting an important role for posttransplant inflammation in this process. Our findings provide insights into the components of the alloimmune response remaining after lymphoablation and may help guide the future use of ATG in sensitized transplant recipients.     

Tertiary Lymphoid Tissues Generate Effector and Memory T Cells That Lead to Allograft Rejection

Tertiary lymphoid tissues are lymph node‐like cell aggregates that arise at sites of chronic inflammation. They have been observed in transplanted organs undergoing chronic rejection, but it is not known whether they contribute to the rejection process by supporting local activation of naïve lymphocytes. To answer this question, we established a murine transplantation model in which the donor skin contains tertiary lymphoid tissues due to transgenic expression of lymphotoxin‐α(RIP‐LTα), whereas the recipient lacks all secondary lymphoid organs and does not mount primary alloimmune responses. We demonstrate in this model that RIP‐LTα allografts that harbor tertiary lymphoid tissues are rejected, while wild‐type allografts that lack tertiary lymphoid tissues are accepted. Wild‐type allografts transplanted at the same time as RIP‐LTα skin or 60 days later were also rejected, suggesting that tertiary lymphoid tissues, similar to secondary lymphoid organs, generate both effector and memory immune responses. Consistent with this observation, naive T cells transferred to RIP‐LTα skin allograft but not syngeneic graft recipients proliferated and differentiated into effector and memory T cells. These findings provide direct evidence that tertiary lymphoid structures perpetuate the rejection process by supporting naïve T‐cell activation.     

Alloantibody Production is Regulated by CD4+ T Cells'' Alloreactive Pathway, Rather Than Precursor Frequency or Th1/Th2 Differentiation

Although CD4(+) T cells play an important role in the regulation of allograft rejection, the exact mechanisms by which they operate and the actual contribution of direct and indirect alloreactivity pathways remain to be fully characterized. Previous studies have established a possible relationship between the indirect alloreactivity pathway and antibody production, but interpretation of these results have been complicated by shortcomings inherent to the models used in these studies. To address this issue, we have developed a model based on TCR transgenic mice derived from a CD4(+) T-cell clone which recognize specific alloantigens by both alloreactivity pathways. Skin allografts on alphabeta T-cell deficient mice adoptively transferred with transgenic CD4(+) T cells were rejected without significant delay between the two alloreactivity pathways. No IgG alloantibody was produced following allograft rejection by the direct alloreactivity pathway alone. Importantly, production of antibodies against alloantigens of the direct pathway was shown to require help from CD4(+) T cells activated by the indirect pathway. These results indicate that the events leading to the initiation of immune responses responsible for graft rejection are clearly dependent on the population of antigen-presenting cells involved in T- and B-lymphocyte activation.     

Donor-Reactive CD8 Memory T Cells Infiltrate Cardiac Allografts Within 24-h Posttransplant in Naive Recipients

Normal immune responses stimulated by pathogenic and environmental antigens generate memory T cells that react with donor antigens and no currently used immunosuppressive drug completely inhibits memory T-cell function. While donor-reactive memory T cells clearly compromise graft outcomes, mechanisms utilized by memory T cells to promote rejection are largely unknown. In this study, we investigated how early endogenous memory cells infiltrate and express effector function in cardiac allografts. Endogenous CD8 memory T cells in nonsensitized recipients distinguish syngeneic versus allogeneic cardiac allografts within 24 h of reperfusion. CD8-dependent production of IFN-γ and CXCL9/Mig was observed 24 to 72 h posttransplant in allografts but not isografts. CXCL9 was produced by donor cells in response to IFN-γ made by recipient CD8 T cells reactive to donor class I major histocompatibility complex (MHC) molecules. Activated CD8 T cells were detected in allografts at least 3 days before donor-specific effector T cells producing IFN-γ were detected in the recipient spleen. Early inflammation mediated by donor-reactive CD8 memory T cells greatly enhanced primed effector T-cell infiltration into allografts. These results suggest that strategies for optimal inhibition of alloimmunity should include neutralization of infiltrating CD8 memory T cells within a very narrow window after transplantation.     

Selective Targeting of Human Alloresponsive CD8+ Effector Memory T Cells Based on CD2 Expression

Costimulation blockade (CoB), specifically CD28/B7 inhibition with belatacept, is an emerging clinical replacement for calcineurin inhibitor‐based immunosuppression in allotransplantation. However, there is accumulating evidence that belatacept incompletely controls alloreactive T cells that lose CD28 expression during terminal differentiation. We have recently shown that the CD2‐specific fusion protein alefacept controls costimulation blockade‐resistant allograft rejection in nonhuman primates. Here, we have investigated the relationship between human alloreactive T cells, costimulation blockade sensitivity and CD2 expression to determine whether these findings warrant potential clinical translation. Using polychromatic flow cytometry, we found that CD8⁺ effector memory T cells are distinctly high CD2 and low CD28 expressors. Alloresponsive CD8⁺CD2^hiCD28^? T cells contained the highest proportion of cells with polyfunctional cytokine (IFNγ, TNF and IL‐2) and cytotoxic effector molecule (CD107a and granzyme B) expression capability. Treatment with belatacept in vitro incompletely attenuated allospecific proliferation, but alefacept inhibited belatacept‐resistant proliferation. These results suggest that highly alloreactive effector T cells exert their late stage functions without reliance on ongoing CD28/B7 costimulation. Their high CD2 expression increases their susceptibility to alefacept. These studies combined with in vivo nonhuman primate data provide a rationale for translation of an immunosuppression regimen pairing alefacept and belatacept to human renal transplantation.