Abstract: The artificial transfer of tissues or cells between genetically diverse individuals elicits an immune response that is adaptive and specific. This response is orchestrated by T lymphocytes that are recognizing, amongst others, major histocompatibility complex (MHC) molecules expressed on the surface of the transferred cells. Three pathways of recognition are described: direct, indirect and semi-direct. The sets of antigens that are recognized in this setting are also discussed, namely, MHC protein products, the MHC class I-related chain (MIC) system, minor histocompatibility antigens and natural killer cell receptor ligands. The end product of the effector responses are hyperacute, acute and chronic rejection. Special circumstances surround the situation of pregnancy and bone marrow transplantation because in the latter, the transferred cells are the ones originating the immune response, not the host. As the understanding of these processes improves, the ability to generate clinically viable immunotherapies will increase.
Abstract: BACKGROUND: The use of ratiometric cell enumeration methods emerges as a more accurate method of measurement of the occurrence of apoptosis in cell cultures. These new flow cytometry methods were used to quantify the impact of cell fragmentation and loss of lineage antigen (LAg) expression on measurement of apoptosis. METHODS: Highly purified human lymphocyte populations were negatively sorted and cultured for 24 h. Apoptotic cells were identified using annexin V, 7-amino-actinomycin D and their LAgs were stained with antibodies. A new indicator, the apoptotic rate, was used to determine apoptosis occurrence and its validity compared with the widely accepted percentage of apoptotic cells (apoptotic index, AI). RESULTS: Loss of LAg expression and cell fragmentation were observed under all conditions assayed and for all cell populations studied. CONCLUSIONS: Current methods for quantifying of apoptosis involving AI systematically underestimate apoptosis occurrence in all populations and conditions, especially among cells undergoing spontaneous apoptosis.
Abstract: Because immune responses to transplant allografts are the main drivers of rejection, the ability to accurately quantitate antidonor immunity is an important goal in clinical transplantation. These allow for the prediction of presensitization to the transplanted tissue and the identification of rejection without needing more invasive tests. In this chapter, we will review three methods currently used in transplantation research. Limiting dilution assays are a traditional tool. The evolution of these assays has brought about the ELISpot. Developments in flow cytometry are also contributing to the understanding of the composition of the cells involved in these immune responses. We can therefore obtain a deeper understanding of the process of rejection and tolerance and their evolution with time. This chapter reviews in vitro assays in the context of transplantation, but the scientific applications of sensitive, accurate, and specific immune-monitoring reach well beyond this field of research.
Abstract: AIMS: Late loss of kidney grafts is an ongoing problem in the field of transplantation. This is caused by immunological and non-immunological factors, the main immunological driver of rejection is the immune response against HLA molecules that differ between donor and recipient. METHODS: To measure the anti-donor responses that a recipient can mount, we have been quantifying anti-donor T-cell frequencies in recipients of renal transplants for several years. Anti-donor direct and indirect pathway frequencies have been measured in vitro in kidney and heart transplant patients by Limiting dilution analysis and other methods. Further, to elucidate the role of CD4+CD25+ regulatory T-cells, these cells have been depleted in ex vivo assays of cellular function. Antigen specific CD4+CD25+ cell lines are being expanded in vitro with a view to using them in immunotherapeutic strategies. RESULTS: Frequencies of T-cells with direct pathway anti-donor specificity decline in most patients, while those with indirect anti-donor specificity increase in frequency in patients with late graft failure. In keeping with results from experimental models of transplantation tolerance, evidence for allospecific regulatory cells was found in some patients with good, stable transplant function. Interestingly, the regulatory cells appeared to have indirect allospecificity, and no evidence of direct pathway regulation was observed. CONCLUSIONS: The indirect pathway anti-donor alloresponse poses the major threat to long-term transplant survival. Indirect pathway regulatory T-cells arise in some patients. These data are consistent with the hypothesis that tolerance strategies require shrinkage of the direct, and regulation of the indirect, anti-donor response.
Abstract: Based on our previous observation that anergic T lymphocytes lose their migratory ability in vitro, we have proposed that anergic T cells are retained in the site where they have been generated to exert their regulatory function. In this study we have analyzed T lymphocyte trafficking and motility following the induction of tolerance in vivo. In a model of non-deletional negative vaccination to xenoantigens in which dendritic cells (DC) localize to specific lymphoid sites depending on the route of administration, tolerant T cells remained localized in the lymph nodes colonized by tolerogenic DC, while primed T cells could traffic efficiently. Using an oral tolerance model that enables the 'tracking' of ovalbumin-specific TCR-transgenic T cells, we confirmed that T cells lose the ability to migrate through syngeneic endothelial cell monolayers following tolerance induction in vivo. Finally, we show that tolerant T cells (both in vitro and ex vivo) can inhibit migration of responsive T cells in an antigen-independent manner. Thus, hyporesponsive T cells localize at the site of tolerance induction in vivo, where they exert their anti-inflammatory properties. In physiological terms, this effect is likely to render immunoregulation a more efficient and controllable event.
Abstract: Immunosuppressive drugs are essential for the prevention of acute transplant rejection but some may not promote long-term tolerance. Tolerance is dependent on the presence and regulatory function of CD4(+)CD25(+) T cells in a number of animal models. The direct effects of immunosuppressive drugs on CD4(+)CD25(+) cells, particularly those that interfere with IL-2 signaling are uncertain. We studied the effects of the rapamycin derivative everolimus and the anti-CD25 monoclonal antibody basiliximab on the regulatory capacity of human CD4(+)CD25(+) cells in vitro. Both drugs permitted the suppression of proliferation and IFN-gamma secretion by CD4(+)CD25(-) cells responding to allogeneic and other polyclonal stimuli; CTLA-4 expression was abolished on CD4(+)CD25(+) cells without compromising their suppressive ability. Everolimus reduced IFN-gamma secretion by CD4(+)CD25(-) cells before the anti-proliferative effect: this is a novel finding. Exogenous IL-2 and IL-15 could prevent the suppression of proliferation by CD4(+)CD25(+) cells and the drugs could not restore suppression. By contrast, suppression of IFN-gamma secretion was only slightly impeded with the exogenous cytokines. Finally, CD4(+)CD25(+) cells were more resistant than CD4(+)CD25(-) cells to the pro-apoptotic action of the drugs. Together these data suggest that CD4(+)CD25(+) cells may still exert their effects in transplant patients taking immunosuppression that interferes with IL-2 signaling.
Abstract: The analysis of apoptosis in cell populations involves the detection of their specific lineage antigen (LAg) expression. This experimental approach relies on their assumed constant expression, but it is unclear whether such expression is actually maintained during cell death. We examined whether the loss of LAgs is a common feature of apoptotic lymphocytes and whether some might completely lose their LAgs. The changes in the expression of CD3, CD5, CD8, CD4, CD28, CD56, and CD19 were monitored in highly purified lymphocyte populations obtained by negative selection in a fluorescence-activated cell sorter. These were cultured for 24 h with or without phytohemagglutinin or staurosporin. For each LAg-positive subset studied, apoptosis was consistently more common among cells showing partial or total loss of LAg expression compared with cells maintaining their initial LAg levels. The kinetics of expression loss was rapid for CD8, CD56, and CD28, and more than 80% of initial expression was lost in the early stages of apoptosis but was slower for CD3, CD5, and CD4. For CD3 and CD5, expression was dependent on the apoptotic stimulus used. It is interesting that loss of antigen expression was independent of cell size. This phenomenon was also found in nonmanipulated, highly pure CD19 B lymphocytes of peripheral blood mononuclear cells from B chronic lymphocytic leukemia patients. Loss of LAg expression appeared to be a common feature of apoptotic lymphocytes under all the conditions assayed. The different kinetic patterns of LAg loss suggest apoptotic cells might actively regulate this process.
Abstract: CD4(+)CD25(+) regulatory T cells have been shown to regulate a variety of autoimmune and allogeneic responses in mice and humans. The role of CD4(+)CD25(+) cells in regulating alloresponses in human transplant recipients remains uncertain. Previous research has demonstrated a reduced frequency of direct pathway donor-specific T cells in renal transplant recipients when compared with the frequency of T cells reactive to an HLA-matched third party. A number of mechanisms have been proposed to account for this finding; the purpose of this study was to determine whether CD4(+)CD25(+) cells play a significant role. Twelve stable renal transplant patients were investigated using limiting dilution assay (LDA) and ELISPOT for interferon-gamma to determine the effect of depleting CD4(+)CD25(+) cells on the direct pathway alloresponse. The percentage of CD4(+)CD25(+) cells in the peripheral blood of the study patients was equivalent to that of healthy controls. Furthermore, in no case did depletion of CD4(+)CD25(+) cells significantly increase the frequency of donor-specific T cells detected by LDA. This was also found with ELISPOT in all except one patient, in whom depletion revealed an increased frequency of alloreactive T cell to both donor and third party. Finally, kinetic analysis of the LDA data did not indicate regulation against donor when compared with third party. It is concluded that the action of CD4(+)CD25(+) regulatory cells is not the main mechanism of donor-specific hyporesponsiveness in the direct pathway of allorecognition.
Abstract: The development of reliable in vitro assays that could allow the quantitation and characterization of anti-donor alloimmune responses has always been a goal in clinical transplantation, both to predict presensitization to the transplanted tissue and to be able to identify rejection without resorting to more invasive tests. With recent development in our understanding of transplantation biology and therapeutics, there is a real expectation that these tests may be used to identify tolerance as much as to predict rejection. The traditional limiting dilution assays still have a contribution to make and are being complemented by an array of tools, such as ELISpot, flow cytometry-based techniques, and microarray analysis. The assays that have been informative, to date, are discussed in this review. This information will lead, at least, to a better understanding of how and when the rejection process occurs. More interestingly, the objective is to apply this information to evaluate tolerance-inducing strategies or to identify patients that have become tolerant to their graft and can be weaned of immunosuppression. Of course sensitive, accurate and specific immunologic monitoring has applications well beyond the field of transplantation.
Abstract: BACKGROUND: With adequate immunosuppression the majority of renal allografts are accepted, despite the exceptional vigour of the T cell alloimmune response. Previous work from this laboratory has demonstrated that this is accompanied by significant reductions in the precursor frequencies of anti-donor T cells. We have also shown that parenchymal cells are tolerogenic in vitro. We propose that the reduction in T cell frequencies may be due to the interaction between circulating T cells and potentially tolerogenic graft parenchymal cells. Primed/memory T cells (CD45RO+) are the only subset capable of reaching the allograft and therefore we would predict that T cell hyporesponsiveness would develop predominantly in the CD45RO+ subset due to their trafficking properties. METHODS: Frequencies of IL-2 secreting CD45RA+ and CD45RO+ CD4+ T cells in response to donor and third party stimulator cells were estimated in a series of renal transplant recipients, both before and after transplantation. RESULTS: There were highly significant reductions in the frequencies of donor-specific CD4+CD45RO+ T cells, when adjusted to control for the generalised effects of immunosuppression. There were no significant alterations in the frequencies of donor-specific CD4+CD45RA+ T cells. CONCLUSIONS: In renal transplant recipients, donor-specific CD4+ T cell hyporesponsiveness occurs predominantly in CD4+ CD45RO+ T cells which is the subset capable of trafficking through the graft.
Abstract: Chronic allograft nephropathy (CAN) is the principal cause of late renal allograft failure. This complex process is multifactorial in origin, and there is good evidence for immune-mediated effects. The immune contribution to this process is directed by CD4(+) T cells, which can be activated by either direct or indirect pathways of allorecognition. For the first time, these pathways have been simultaneously compared in a cohort of 22 longstanding renal allograft recipients (13 with good function and nine with CAN). CD4(+) T cells from all patients reveal donor-specific hyporesponsiveness by the direct pathway according to proliferation or the secretion of the cytokines IL-2, IL-5, and IFN-gamma. Donor-specific cytotoxic T cell responses were also attenuated. In contrast, the frequencies of indirectly alloreactive cells were maintained, patients with CAN having significantly higher frequencies of CD4(+) T cells indirectly activated by allogeneic peptides when compared with controls with good allograft function. An extensive search for alloantibodies has revealed significant titers in only a minority of patients, both with and without CAN. In summary, this study demonstrates widespread donor-specific hyporesponsiveness in directly activated CD4(+) T cells derived from longstanding recipients of renal allografts, whether they have CAN or not. However, patients with CAN have significantly higher frequencies of CD4(+) T cells activated by donor Ags in an indirect manner, a phenomenon resembling split tolerance. These findings provide an insight into the pathogenesis of CAN and also have implications for the development of a clinical tolerance assay.
Abstract: BACKGROUND: Internal standards have been used in flow cytometry methods to enumerate lymphoid subsets and hemopoietic progenitor cells ex vivo. However, the currently available methods cannot be readily applied to the analysis of cultured cells because of the frequent occurrence of cell death during in vitro assays. METHODS: This paper reports a new method for the enumeration of both viable and nonviable cells in culture. Cells were counted with the aid of an internal reference standard of microbeads, and live versus dead cell discrimination was performed using 7-amino-actinomycin D which allows the double staining of surface antigens. RESULTS: The method is more precise, accurate and sensitive than either conventional light microscopy-based or automated cell counting. Additionally, it may be used to accurately measure the number of apoptotic cells in a culture. RESULTS: Through the enumeration of surviving cells it is demonstrated that, when applied to the study of mitogen-activated T lymphocytes, current flow cytometry techniques (which do not use internal standards) for the study of the viability and apoptosis overestimate the fraction of viable cells and underestimate both the fraction of dead and apoptotic cells. CONCLUSIONS: The new method overcomes these limitations and is of use in the in vitro study of cell growth and apoptosis.
Abstract: OBJECTIVE: To further define the pattern of alterations in the activation and apoptosis of T lymphocytes in patients with inactive systemic lupus erythematosus (SLE) through analysis of a large series of individuals. METHODS: We isolated CD2+ peripheral blood lymphocytes (PBL) from 41 patients with inactive SLE and analyzed their proliferative and apoptotic responses to polyclonal activation. RESULTS: In 19 of 41 (47%) patients, a low proliferative response to polyclonal mitogens was found. This defective response was inversely associated with an increased apoptotic response and increased expression of CD95 and CD45RO antigens. CONCLUSION: We found that 2 groups of patients with inactive disease can be defined according to the functional behavior of their T lymphocytes, as defined by the proliferative and apoptotic responses to mitogenic signals.
Abstract: The alloresponse can be divided into two components. The first of these is allorecognition, which refers to the recognition of antigens, expressed on the surface of cells of non-self origin, by the host's lymphocytes. The second part is the immune effector mechanisms generated by this recognition process. The molecules recognised have been termed histocompatibility antigens and fall into two categories. The strongest responses are provoked by allogeneic major histocompatibility complex (MHC) antigens. T cells recognise these antigens either directly or after being processed like conventional antigens by antigen-presenting cells, in what has been termed indirect presentation. In the context of MHC identity, responses are observed against the second category of antigens, namely minor histocompatibility antigens (mHAgs). Although weaker, these responses are of clinical importance, particularly in bone marrow transplant recipients. CD4+ T cells play a central role in orchestrating the immune response to alloantigens. They secrete cytokines to attract effector cells, such as macrophages and CD8+ T cells, into the graft and are able to interact with B cells that will secrete highly specific alloreactive antibodies. In clinical terms, the result of the immune response to transplanted allografts can be classified as hyperacute rejection, acute and chronic rejection. The immunological effector mechanisms involved in each of these processes are discussed.
