Mechanism of suppression of cloned human suppressor T cells

Abstract We report the mechanism of suppression of suppressor T cell clone III-1-C5 using helper T cell clone III-1-B6, mitogen responses and rIL-2. Clone III-1-C5 suppressed the mixed lymphocyte reaction (MLR) by secreting alloantigen non-pecific, MHC non-restricted suppressor factor(s). Clone III-1-C5 did not suppress mitogen (PHA, Con A, PWM) response nor proliferation by exogeneous rIL-2. Clone III-1-C5 suppressed proliferation by clone III-1-B6, which augments proliferation by direct cell to cell contact with responder cells and not by soluble factors. These results indicated that suppressor T cells exhibit suppressive effects not only by inhibiting IL-2 synthesis but by inhibiting the direct effects of helper T-cells.     

Inhibition of antigen-specific activation of an L3T4+ T cell line by cyclosporine with maintenance of macrophage-mediated antigen presentation

Cyclosporine has clearly been shown to directly inhibit T lymphocyte activation by monoclonal antibodies or mitogens where nominal antigen and accessory cells are not present. However, when T lymphocytes are stimulated by antigen, as occurs in allograft rejection, T lymphocytes and accessory cells must interact with one another. Under the latter circumstances, the issue of whether cyclosporine acts on T lymphocyte, accessory cell, or both is not resolved. This issue is addressed in this study. To assess the effect of cyclosporine on T cell activation, macrophages were incubated with heat-killed Listeria and then fixed in paraformaldehyde. These fixed macrophages retained their ability to present antigen to T cells but were not affected by subsequent treatment with cyclosporine. When cyclosporine and a L3T4+ T lymphocyte line were added simultaneously to fixed, antigen-pulsed macrophages, the drug inhibited antigen-specific T cell activation with a half maximal inhibitory concentration of 10 ng/ml. To our knowledge, this is the first evidence that low doses of cyclosporine inhibit antigen-specific T cell activation where the drug's effects on antigen-presenting cells have been excluded. To assess the effects of cyclosporine on macrophage-mediated antigen-presentation, macrophages were exposed simultaneously to cyclosporine and antigen, and then fixed. Antigen-presentation was not inhibited unless extremely large doses (9000 ng/ml) of cyclosporine were used. In our experimental system, any new inhibitory activity acquired by live cyclosporine-treated macrophages could be explained by residual drug. Finally, cyclosporine did not inhibit the induction of macrophage Ia expression nor antigen-presenting function after stimulation in vitro with lymphokine.     

Apoptosis of allospecifically activated human helper T cells is blocked by calcineurin inhibition

BACKGROUND: Classical transplantation immunosuppression relies heavily upon the interruption of interleukin-2 (IL-2) signaling by calcineurin inhibition. However, recent evidence in murine models suggests that IL-2 is necessary for activation-induced cell death (AICD) of allograft-specific lymphocytes. METHODS: We examined the apoptotic effects of the calcineurin inhibitor cyclosporine A and mTOR inhibitor rapamycin on the apoptotic alterations that occur in allospecifically activated human lymphocytes in a one-way mixed lymphocyte culture (MLC). RESULTS: Cyclosporine increased caspase-3 activation in MLC, which corresponded with a decrease in lymphocyte apoptosis in MLC. Cyclosporine also reduced apoptosis in the CD4+ helper T cell subset, while CD8+ cells had similar or increased apoptosis when compared to controls. In contrast, rapamycin-treated cultures had normal levels of CD4+ T cell apoptosis when compared to control MLC, with decreases seen in CD8+ T lymphocytes. CONCLUSIONS: In humans, blockade of IL-2 receptor signal with rapamycin allows apoptosis of allospecifically activated CD4+ lymphocytes to occur, while blockade of IL-2 production with cyclosporine results in decreased apoptosis in this T cell subset. As helper T cells are integral to the immune response, these results may explain the tolerogenic effects of rapamycin.     

Cyclosporine inhibits protein kinase C-dependent signals in human peripheral blood lymphocytes

T helper lymphocyte activation is thought to occur when the T3T1 receptor is activated by antigen, and a calcium signal and stimulus to protein kinase C appear to be essential for interleukin-2 production and lymphocyte proliferation. Previous work from our lab has demonstrated that the calcium signal is unaffected by cyclosporine. In this report, a macrophage and T suppressor/cytotoxic-depleted population of human peripheral blood mononuclear cells is stimulated with Sepharose beads bound to OKT3 monoclonal antibody and Sepharose-OKT3 plus a phorbol ester (a stimulus to protein kinase C). Cyclosporine inhibits both the Sepharose/OKT3-mediated and Sepharose/OKT3/phorbol myristic acetate-mediated mitogenesis. Cyclosporine inhibits either protein kinase C or protein kinase C-dependent intracellular signals necessary for T helper activation and proliferation.     

Human T cell responses to human and porcine endothelial cells are highly sensitive to cyclosporin A and FK506 in vitro

BACKGROUND: Human T cells proliferate in response to both human umbilical vein endothelial cells (HUVEC) and porcine aortic endothelial cells (PAEC) via the second signals LFA-3/CD2 and B7-2 (CD86), respectively. Previous studies have shown that stimulation of T cells via CD28 or phorbol myristate acetate (PMA) activation is highly resistant to inhibition by cyclosporine A (CsA) and tacrolimus (FK506), as is the response of T cells to phytohemmaglutinin in the presence of endothelial cells. We have investigated the inhibitory effects of CsA and FK506 on the direct response of human CD4+ T cells to HUVEC and PAEC and the effect of adding B7-1 transfectants. METHODS: T cell proliferation, interleukin-2 release bioassays and a multiple cytokine bioassay employing the TF-1 cell line were used as indicators of T cell responses to HUVEC and PAEC either in the presence or absence of CsA and FK506. In some experiments, B7-1 transfectants were also added. RESULTS: Proliferative responses and interleukin-2 release were highly sensitive to CsA, the ID50 being significantly less for HUVEC (6.5 ng/ml) than PAEC (15 ng/ml). The ID50 of CsA for the mixed lymphocyte response (MLR) was similar to PAEC (18.6 ng/ml), all these values being significantly less than the T cell activation by phytohemmaglutinin (PHA) (227 ng/ml). Addition of B7-1 transfectants significantly increased interleukin-2 production by T cells/HUVEC and resistance to CsA was greatly increased to an ID50 of > 1000 ng/ml. In contrast, addition of B7-1 transfectants to T cells/PAEC had no effect either on T cell proliferation, IL-2 production, or CsA resistance. Similar results were obtained with FK506. Using the TF-1 cell line, it was determined that cytokines other than IL-2 are released during CD4+ T cell/EC interactions, with similar sensitivity to CsA and FK506. CONCLUSIONS: It is concluded that both allogeneic and xenogeneic T cell/endothelial responses should be inhibited by therapeutic levels of CsA in vivo, assuming the absence of trans-stimulation by B7 molecules.     

In vivo evaluation of the novel calcineurin inhibitor ISATX247 in Non-Human primates

BACKGROUND: ISA(TX)247 is a novel calcineurin inhibitor that has shown more potency than cyclosporine in vitro. This is the first in vivo study of the effects of ISA(TX)247 on lymphocyte functions in non-human primates. METHODS: Groups of cynomolgus monkeys were treated orally twice daily for 7 days, each dose consisting of 25 mg/kg cyclosporine (n = 5), 25 mg/kg ISA(TX)247 (n = 6) or 50 mg/kg ISA(TX)247 (n = 6). Levels of cyclosporine and ISA(TX)247 in whole blood were measured by liquid chromatography/mass spectrometry. After mitogen stimulation, lymphocyte proliferation was assessed by tritium-labeled thymidine incorporation and by flow cytometry (expression of proliferating cell nuclear antigen in cells in S/G(2)M phase). Flow cytometry was also used to assess production of intracellular cytokines by T cells (interleukin-2, interferon-gamma, tumor necrosis factor-alpha) and expression of T-cell surface activation antigens (CD25, CD71, CD11a, CD95, CD154). RESULTS: Trough (C(14 hr)) and peak (C(3 hr)) drug levels, as well as area under the concentration-time curve, were significantly higher for cyclosporine than ISA(TX)247 (370 ng/ml vs 70 ng/ml, 877 ng/ml vs 303 ng/ml and 6,262 ng. h/ml vs 1,979 ng. h/ml, respectively). On Day 7 at C(14 hr), lymphocyte proliferation had been suppressed by approximately 50% in all groups compared with proliferation before treatment. Three hours after dosing, lymphocyte proliferation was inhibited significantly more by ISA(TX)247 (approximately 80%, with no differences between the two ISA(TX)247 dose levels) than by cyclosporine (65% inhibition). Similar differences between the immunosuppressive effects of ISA(TX)247 and cyclosporine were found for inhibition of expression of T-cell surface activation antigens. Despite lower ISA(TX)247 exposures compared with cyclosporine, the cyclosporine treatment only rarely suppressed cytokine production more than treatment with ISA(TX)247. CONCLUSIONS: In non-human primates, ISA(TX)247 produces a greater or similar inhibition of lymphocyte proliferation, expression of T-cell activation surface antigens, and cytokine production when compared with cyclosporine, despite ISA(TX)247's lower blood levels and total exposure. We conclude that ISA(TX)247 suppresses diverse T-cell functions more potently than cyclosporine in non-human primates in vivo.     

In vitro cyclosporine toxicity. The effect of verapamil

The epithelial cell line LLC-PK1, which expresses many proximal tubular characteristics, was used to investigate the relationship between calcium, the calcium channel blocker verapamil, and cyclosporine toxicity. The LLC-PK1 cells took up cyclosporine when this was added in a concentration of 2 micrograms/ml, and this uptake was maximal at 30 min (112 +/- 3 ng cyclosporine/mg cell protein). At 12 micrograms/ml it inhibited the sodium glucose cotransporter, as assessed by phlorizin-inhibitable 14C-alpha-methyl glucopyranoside (alpha-MG) uptake (control 37.2 +/- 6.3, 12 micrograms/ml 21.2 +/- 1.1 mumol/hr/mg protein). Cyclosporine at 2 micrograms/ml did not affect cell growth after 5 days (control 945 +/- 60 micrograms cell protein per 25 cm2 flask, 2 micrograms/ml cyclosporine/ml 1046 +/- 32 micrograms protein/flask), even in the presence of 7.6 mM ionized calcium (862 +/- 37 micrograms protein/flask). Cyclosporine at 12 micrograms/ml inhibited cell growth (286 +/- 27 micrograms protein/flask), and raising the ambient ionized calcium concentration to 7.6 mM reduced cell growth further (91 +/- 6 micrograms protein/flask). Cyclosporine at concentrations of 2 and 12 micrograms/ml produced increasing cell vacuolation, as seen in vivo. Short-term uptake of 2 micrograms/ml cyclosporine could be inhibited by 1.0 mM and 0.5 mM verapamil (49 +/- 9.5 and 71 +/- 6.4 ng cyclosporine/mg cell protein, respectively, at 30 min). However, in the presence of 2 micrograms/ml cyclosporine 0.1 mM verapamil was toxic to the cells grown over five days (44 +/- 5 micrograms protein/flask). At 0.01 mM verapamil was not toxic to cell growth (921 +/- 29 micrograms protein/flask), but raising the medium calcium to 7.6 mM reduced cell growth (652 +/- 96 micrograms/ml). Inhibition of cyclosporine uptake did not occur with 0.01 mm verapamil (control 145.6 +/- 12.3 vs. 0.01 mM verapamil 150.4 +/- 3.8 ng cyclosporine/mg cell protein). The LLC-PK1 cell line represents a good in vitro model for cyclosporine renal tubular toxicity, as the in vivo observation of glycosuria and proximal tubular cell vacuolation in cyclosporine nephrotoxicity can be reproduced. In vitro this is shown to be associated with inhibition of sodium-dependent glucose cotransport. Verapamil inhibited cyclosporine uptake, but only at concentrations that were toxic to the cells. Verapamil potentiated rather than reduced the increased cyclosporine toxicity produced by increasing the medium calcium concentration. The suggested protective effect of verapamil against cyclosporine nephrotoxicity is therefore unlikely to be due to inhibition of cyclosporine uptake or of calcium entry into proximal tubular cells.     

Experimental studies on the mode of action of cyclosporine and FK506 assessed by proliferation response of human cloned T lymphocytes]

We applied cloned human T lymphocytes established in our laboratory to evaluate the mode of action of Cyclosporine (CsA) and FK506. Phenotypic and functional analysis led us to conclude that HTL403 was a helper T cell clone and HTL805 a cytotoxic one. Susceptibility of HTL-403 to the immunosuppressants demonstrated that alloantigen-driven proliferative response can recover to the rIL2-driven level by the addition of rIL2 at higher concentration of the agents. Although full recovery was not observed in FK506, this finding indicated that FK506 as well as CsA inhibit IL2 secretion from HTL403. FK506 showed remarkable suppressive effect on the proliferative response of HTL-805 even at a considerably low concentration, while CsA suppressed such a response dose-dependently. We concluded that FK506 can be used to reverse ongoing acute rejection as well as to prevent acute rejection.     

A comparison of the inhibitory effects of immunosuppressive agents cyclosporine, tetranactin, and didemnin B on human T cell responses in vitro.

The agents cyclosporine, tetranactin (TN), and didemnin B (DB) were compared for their ability to inhibit proliferative human T cell responses in vitro, using anti-CD3, PHA, alloantigen, or tetanus toxoid as stimuli and using monocytes or Langerhans cells as antigen-presenting cells/accessory cells (APC/AC). We found that all three agents suppressed T cell activation in a dose-dependent fashion, irrespective of the stimulus of APC/AC type used. Both T cells and APC/AC were affected by the drugs. DB appeared to be the most potent suppressive drug (IC50 = 1-4 ng/ml), whereas CsA and TN exerted approximately similar potency (IC50 = 50-60 ng/ml). Remarkably however, DB was toxic at a concentration of 10 ng/ml, which is quite close to the inhibition-inducing dose. No toxicity was observed with CsA and TN at doses up to 5000 ng/ml. The agents TN and DB could interrupt ongoing T cell responses and could block responsiveness to exogenous recombinant IL-2. Expression of IL-2 receptors was slightly inhibited by all three drugs. Expression of MHC class II molecule HLA-D and of adhesion molecules LFA-1, LFA-3, and ICAM-1 was clearly reduced by DB, giving an explanation for the observed inhibition of cluster formation between T cells and APC/AC. Except for a slight reduction of LFA-3 by TN, CsA and TN did not affect the expression of any of these cell surface markers or the formation of clusters. Differences in the effects of CsA, TN, and DB on immune responses in vitro and on the phenotype of T cells and APC/AC suggest that these immunosuppressive drugs have different inhibitory mechanisms.     

A reappraisal of the effects of monoclonal antibodies directed at T cell differentiation antigens

We examined the effects of monoclonal antibodies (Abs) directed at T3 antigen (expressed on most post-thymic T cells), T4 antigen (helper/inducer subset) and T8 antigen (suppressor/cytotoxic subset). Anti-T3 induced interleukin-2 production and proliferation of peripheral blood mononuclear cells (PBM). Anti-T4 or T8 did not exhibit such properties. Addition of methylprednisolone (MP) or cyclosporine (CsA) to PBM activated with anti-T3 resulted in 79% and 88% suppression of proliferation, respectively. Neither anti-T4 nor anti-T8 mediated significant inhibition of anti-T3-induced proliferation. Primary mixed lymphocyte cultures (MLC) were variably affected by Abs. Anti-T3 augmented proliferation found in primary MLCs at 48 hr and had an inconsistent effect on the proliferative response found at 120-136 hr of culture. Primary cytotoxic T lymphocyte (CTL) generation was consistently suppressed by anti-T3, while natural killer (NK)-cell-like activity was augmented at 72 hr and suppressed after 136 hr of culture. Anti-T4 mediated a dose-dependent suppression of proliferation and CTL generation in the primary MLC and had minimal effect on the induction of NK-cell-like activity. At high concentrations (5000-1000 ng/ml), anti-T8 mediated modest inhibition of proliferation and of the induction of cytolytic activity. Alloimmune memory cells, generated in long-term primary MLCs, were activated by anti-T3 to exhibit specific secondary cytolytic activity and NK-cell-like activity in the absence of the original priming stimulus. Neither anti-T4 nor anti-T8, under identical experimental conditions, activated memory cells. When interrelated, our experimental findings indicated that: (1) the ultimate immunity elicited by anti-T3-T3 antigen interaction is critically dependent upon the immune potential of the cell assessed; (2) MP or CsA can inhibit PBM activation by anti-T3; and (3) anti-T4 might have a role as an immunosuppressant in renal graft recipients.     

1,25-Dihydroxyvitamin D3 inhibits the passive transfer of cellular immunity by a myelin basic protein-specific T cell clone.

1,25-Dihydroxyvitamin D3 [1,25-(OH)2D3] and related analogs have been shown to exert immunoinhibitory effects on activated lymphocytes in vitro. However, the effects of the hormone on the mammalian immune response in vivo have not been well studied. To examine the possible immunoactions of 1,25-(OH)2D3 in vivo, we employed a murine model of experimental autoimmune encephalomyelitis (EAE). In this model, T helper lymphocyte clones developed from lines of lymphocytes reactive to myelin basic protein (MBP) confer MBP immunoreactivity and demyelinating central nervous system disease on syngeneic, naive recipients of the T cell clone. Similar to peripheral blood mononuclear cells incubated with mitogen, the T cell clone evaluated in this study expressed a high-affinity specific receptor for 1,25-(OH)2D3 (VDR; K(in) = 0.03 nM) upon exposure to MBP. The MBP-stimulated clone elicited a ninefold enhancement of the local delayed hypersensitivity (DTH) response when as few as 0.5 x 10(5) cells of the T cell clone were injected into the foot pad of recipient mice. The DTH response in the recipient was completely blocked when the clone was preincubated with greater than or equal to 10(-8) M 1,25-(OH)2D3 before transfer; the half-maximal inhibitory concentration of hormone (EC50) was 5 x 10(-9) M. These data indicate that exposure of antigen-reactive T helper lymphocytes to a VDR saturating concentration of 1,25-(OH)2D3 can dramatically lessen the expression of immunoreactivity in vivo.     

Additive inhibition of afferent and efferent immunological responses of human peripheral blood mononuclear cells by verapamil and cyclosporine

We have studied the effects of verapamil (0-50 microM) on the in vitro immunological function of human peripheral blood mononuclear cells in the presence or absence of cyclosporine (0-600 ng/ml). The proliferative response to phytohemagglutinin, OKT3, and alloantigens, the generation of cytotoxic T lymphocytes following allogeneic stimulation, and mitogen-induced reduction of intracellular ATP were inhibited in a concentration-dependent fashion by verapamil alone and by cyclosporine alone. When the two drugs were added to the same culture, additive inhibition was observed. A verapamil concentration of 5 microM usually reduced by at least 50% the amount of cyclosporine necessary to cause the same level of inhibition seen when no verapamil was present. The additive inhibition of the two drugs was likely not due to additive inhibition of IL-2 responsiveness, since neither drug alone inhibited the response of an IL-2-dependent T cell clone (CTLL-2) to recombinant IL-2 except at the highest concentrations tested, where a mild additive effect was noted. Nor was the additive inhibition related to an additive effect on total IL-2 receptor expression since an additive inhibitory effect on PHA-induced IL-2 receptor expression was only seen with 50 microM verapamil, while additive functional effects on mitogen- and antigen-induced proliferation and alloantigen-induced CTL generation were seen with 5 microM verapamil doses. Verapamil or cyclosporine alone inhibited IL-2 production of PHA- and phorbol ester-stimulated peripheral blood mononuclear cells--however, no additive effect was seen when the two drugs were both added to culture, probably because of the very potent inhibition by cyclosporine alone. Natural killer cell activity of human peripheral blood mononuclear cells against K562 target cells was significantly inhibited by verapamil in a concentration-dependent fashion, while cyclosporine had a more modest concentration-dependent effect. The combination of both drugs demonstrated additive inhibition. Effector function of cytotoxic T lymphocytes was modestly inhibited by either verapamil or cyclosporine alone. A combination of the highest concentrations of verapamil and cyclosporine caused an additive inhibitory effect. In summary, these data demonstrate that verapamil and cyclosporine have concentration-dependent inhibitory activities on both the afferent and efferent limbs of immunity that were additive when verapamil was used in a concentration of at least 5 microM. The additive effects are probably not related to effects on IL-2 circuitry.     

Influence of HLA phenotypes on the inhibition of in vitro alloreactivity by cyclosporine

Interindividual variations in the immunosuppressive effect of Cyclosporine have been observed in clinical organ transplantation. Searching for an in vitro correlate we investigated a possible relation between inhibition of alloresponsiveness by CsA and the HLA phenotypes of the responder or stimulator in mixed lymphocyte reactions. Peripheral blood mononuclear cells from 28 healthy volunteers were used as responder or stimulator cells (gamma-irradiated) and the inhibitory effect of graded amounts of CsA was determined in 130 criss-cross combinations. Sensitivity of alloresponsiveness to the drug was expressed as the dose causing 50% inhibition (ED50) and was read from the inhibition curves generated after four-parameter logistic curve fitting. ED50 ranged from 0.35 ng/ml to 33.4 ng/ml and correlated only weakly with the magnitude of the response (r = 0.12). In MLC with HLA DR4-positive responder cells, ED50 was significantly lower (Pc = 0.0035, Kruskal Wallis) when compared with MLC with responder cells of other DR haplotypes. For HLA DR5-positive responder cells ED50 was significantly higher (Pc = 0.042) when compared with DR5-negative responder cells. No significant correlation between ED50 and any particular haplotype of the stimulator cells could be observed. Sensitivity to CSA did not differ in MLC with 1 or 2 mismatches in the HLA-DR locus. In summary, we found that sensitivity of in vitro alloreactivity was different for particular HLA DR phenotypes, which may have important implications for the immunosuppressive therapy of transplanted patients with cyclosporine.     

Reevaluation of T cell subset monitoring in cyclosporine-treated renal allograft recipients

The predictive value of peripheral blood T cell subset monitoring in renal allograft recipients has been questionable, and there has been no information concerning the correlation of T cell subset changes with the clinical event related to cyclosporine nephrotoxicity. This study was conducted to investigate the clinical usefulness of serial T cell subset monitoring in 34 consecutive renal transplant patients treated with cyclosporine by determining the total peripheral lymphocyte count and T cell subset counts using Leu-4, Leu-3ab, and Leu-2a monoclonal antibodies and flow cytometry up to 6 months after transplantation. The absolute counts of all cells were lower in transplanted patients than those of normal controls, but were not different from those of hemodialysis patients. During infection, the helper/suppressor (H/S) ratio and the cell counts, except for suppressor cells, decreased significantly. Within one week prior to rejection, all cell counts also decreased significantly. Furthermore, cell counts before steroid-resistant rejection were significantly lower than those before steroid-responsive rejection. In contrast, lymphocyte and T cell counts were increased significantly within one week prior to cyclosporine nephrotoxicity being diagnosed; the H/S ratio was not correlated with rejection or toxicity. These results indicate that H/S ratio is not associated with clinical events of renal allograft recipients, but serial lymphocyte and T cell subset counts can provide valuable information for the differentiation of rejection from cyclosporine nephrotoxicity, and also for predicting the outcome of the allograft rejection.     

Afferent and efferent pathways in T cell responses to MHC class I+, II-hepatocytes

We have previously reported that purified hepatocytes stimulate significant in vitro allospecific cytotoxicity when cocultured with naive responder splenocytes in the mixed lymphocyte hepatocyte culture (MLHC). In this report we examined the expression of MHC antigens on the surface of hepatocytes, the phenotypic lymphocyte subset(s) that respond(s) to allogeneic hepatocytes, and the phenotype of allospecific cytolytic effectors generated in MLHC. Hepatocytes expressed MHC class I but not MHC class II antigens by immunofluorescent microscopy and fluorescence activated cell sorting. The lack of MHC class II on the surface of hepatocytes was also indirectly supported by the inability of hepatocytes to stimulate proliferation of a class II-directed allospecific helper T cell clone. The generation of allospecific cytotoxicity in MLHC required the participation of L3T4+, Ly2- T cells and L3T4-, Ly2+ T cells in the naive responder splenocyte population since depletion of these subsets with mAb and complement abrogated the development of allo-CTLs. Furthermore, adherent accessory cells in the naive responder splenocyte population appeared to play a role in the generation of allospecific cytotoxicity in MLHC since depletion of this population by plastic adherence and passage through a Sephadex G10 column resulted in significantly reduced allospecific cytotoxicity. Depletion of day 5 allosensitized cells of Ly2+ but not L3T4+ T cells by mAb and complement eliminated allospecific cytotoxicity--indicating that cytolytic effectors generated in MLHC appear to be L3T4-, Ly2+ T cells.     

Effects of cyclosporine on the immune system of the mouse. II. Cyclosporine inhibits the effector function of primary T helper cells, but not helper cell priming

This paper describes various effects of cyclosporine on T helper (TH) cells for antibody production in the mouse. Immunosuppressive doses of cyclosporine abolish the help provided by virgin (primary) TH cells, but allow the priming of normal (and under certain conditions supranormal) numbers of TH cells as assayed by adoptive transfer experiments. The helper function of primed (secondary) TH cells is normally resistant to cyclosporine. However, if T cells are exposed to cyclosporine during priming their helper function remains totally cyclosporine-sensitive as long as the drug therapy is continued. The mechanisms involved in these selective effects are unknown, but the results indicate that in vivo cyclosporine can dissociate effector function (primary help) from TH cell proliferation (priming).     

Stimulation of distinct T cell subsets in MLR using human macrophage hybridomas differentially expressing class II antigens.

Recognition of class II antigens by alloreactive T cells is thought to be the major mechanism by which tissues undergo rejection. However, the specific role of the various class II antigens in the stimulation of these alloreactive cells remains to be elucidated. We have recently generated a series of human monocyte hybridomas that express distinct patterns of class II antigen expression. HLA-DR+ as well as HLA-DR-DP+DQ+ hybrids were capable of promoting T cell proliferation in a unidirectional mixed lymphocyte reaction. T cells stimulated by the HLA-DR+ clone 16.1 were predominantly of the CD4 (helper/inducer) phenotype. In contrast, T cells stimulated by the HLA-DR-DP+DQ+ clone 13 appear to reside in the CD8+ T cell subpopulation. Functional assessment of the T cell blasts generated in these cultures demonstrated a predominant helper T cell effect by those T cells stimulated by the HLA-DR+ clone 16.1, while suppressor cell activity was exhibited by T cells stimulated with the HLA-DR-DP+DQ+ clone 13. These data suggest that there may be a differential role for distinct class II molecules in the stimulation of T cell subpopulations.     

Effects of cyclosporine on human dendritic cell subsets

Cyclosporine is widely used as an immunosuppressive agent after solid organ transplantation. Limited data are available on the modulation of human dendritic cells by cyclosporine. We investigated the effects of cyclosporine on the phenotype and function of human dendritic cell (DC) subsets. DCs were isolated from peripheral blood using magnetic bead-conjugated antibodies. Cyclosporine did not alter the ability of myeloid and plasmacytoid dendritic cells to take up antigens. Expression of the co-stimulatory molecule CD80 but not CD86 increased on both DC subsets when stimulated with cyclosporine. The ability of cyclosporine treated myeloid DCs to stimulate proliferation of allogenic PBMC was significantly reduced. Similarly, stimulation of memory CD8+ T cells by dendritic cells was impaired by cyclosporine pretreatment. In conclusion, cyclosporine differentially alters function and phenotype of myeloid dendritic cells leading to a partially impaired capacity to stimulate allogenic and autologous T cells.     

Cyclosporine suppresses cell growth and collagen production in hepatic stellate cells

BACKGROUND: In HCV-related graft hepatitis, immunosuppression has been implicated in rapid progression to cirrhosis, a serious clinical issue. We investigated the effects of cyclosporine or tacrolimus on cell growth and collagen production by hepatic stellate cells (HSC), which play a role in hepatic fibrosis. MATERIALS AND METHODS: Cultured rat HSCs and human HSC-derived TWNT-4 cells were evaluated for proliferation, type I collagen, phosphorylation states of mitogen-activated protein kinases extracellular signal-regulated kinase 1/2; [MAPKs Erk1/2], c-Jun N-terminal kinase (JNK, p38), as well as the expression of collagen, matrix metalloproteinase-1 (MMP-1) and tissue inhibitor of matrix metalloproteinase-1 (TIMP-1) genes. RESULTS: Cyclosporine suppressed cell growth and collagen production in a concentration-dependent manner. At clinically relevant concentrations of 0.125 micromol (150 ng/mL) cyclosporine significantly reduced collagen production per cell by more than 50%. Similarly, tacrolimus also reduced both collagen concentration and cell number; however, tacrolimus at a clinically relevant concentration of 12.5 nmol (10 ng/mL) did not significantly reduce collagen production. Treatment with cyclosporine reduced type I collagen and TIMP-1 expression and enhanced MMP-1 expression. Cyclosporine also inhibited phosphorylation strongly for JNK and p38, and weakly inhibited for Erk1/2. CONCLUSION: These findings demonstrated that cyclosporine suppresses cell growth and collagen production, suggesting that it may have an antifibrogenic effect.