Stanislaw M. Stepkowski

Uncoupling protein 3 transcription is regulated by peroxisome proliferator-activated receptor α in the adult rodent heart

Relatively little is known concerning the regulation of uncoupling proteins (UCPs) in the heart. We investigated in the adult rodent heart 1) whether changes in workload, substrate supply, or cytokine (TNF‐α) administration affect UCP‐2 and UCP‐3 ex¬pression, and 2) whether peroxisome proliferator‐acti¬vated receptor α (PPARα) regulates the expression of either UCP‐2 or UCP‐3. Direct comparisons were made between cardiac and skeletal muscle. UCP‐2, UCP‐3, and PPARα expression were reduced when cardiac workload was either increased (pressure overload by aortic constriction) or decreased (mechanical unload¬ing by heterotopic transplantation). Similar results were observed during cytokine administration. Reduced di¬etary fatty acid availability resulted in decreased expres‐sion of both cardiac UCP‐2 and UCP‐3. However, when fatty acid (the natural ligand for PPARα) supply was increased (high‐fat feeding, fasting, and STZ‐induced diabetes), cardiac UCP‐3 but not UCP‐2 expression increased. Comparable results were observed in rats treated with the specific PPARα agonist WY‐14,643. The level of cardiac UCP‐3 but not UCP‐2 expression was severely reduced (20‐fold) in PPARα−/− mice compared to wild‐type mice. These results suggest that in the adult rodent heart, UCP‐3 expression is regu¬lated by PPARα. In contrast, cardiac UCP‐2 expression is regulated in part by a fatty acid‐dependent, PPARα‐independent mechanism.—Young, M. E., Patil, S., Ying, J., Depre, C., Ahuja, H. S., Shipley, G. L., Stepkowski, S. M., Davies, P. J. A., Taegtmeyer H. Uncoupling protein 3 transcription is regulated by peroxisome proliferator‐activated receptor α in the adult rodent heart. FASEB J. 15, 833‐845 (2001)

Synergistic interactions of cyclosporine and rapamycin to inhibit immune performances of normal human peripheral blood lymphocytes in vitro

Rapamycin, an actinomycete macrolide lactone that inhibits cytokine-induced immunoactivation, and cyclosporine, an endecapeptide that prevents transcription of lymphokine messenger RNA, display mutually synergistic interactions in vitro and in vivo. Using the rigorous median-effect analysis to dissect the nature of immunosuppressive drug interactions, rapamycin significantly augmented the inhibitory effects of cyclosporine and/or dexamethasone upon human peripheral blood lymphocyte activation by phytohemagglutinin, anti-CD3 monoclonal antibody, and mixed lymphocyte reaction. Furthermore, the addition of rapamycin potentiated the activity of cyclosporine to reduce cytotoxic cell generation and precursor frequency during in vitro alloactivation, using cell-mediated lympholysis and limiting dilution analyses, respectively. Similarly, cyclosporine potentiated the inhibitory effects of rapamycin upon proliferation of IL-2 (CTLL-2) and IL-6 (MH60.BSF-2) lymphokine-dependent cell lines. Lineweaver-Burk plots of the Michaelis-Menton equation suggested rapamycin inhibits IL-2 signal transduction in competitive, and IL-6 signal transduction in noncompetitive fashion, suggesting distinctive components of the various cytokine-receptor mechanisms. In vivo the cyclosporine/rapamycin combination exerted synergistic immunosuppression of rejection reactions in rats toward heterotopic cardiac allografts, using concentrations at which drugs were individually ineffective. These observations suggest that cyclosporine and rapamycin may be combined at significantly reduced doses to achieve unprecedented levels of immunosuppressive efficacy.

Rapamycin, a potent immunosuppressive drug for vascularized heart, kidney, and small bowel transplantation in the rat.

The effectiveness of rapamycin (RAPA) was examined for heart, kidney, and small bowel allografts in rats. Untreated or vehicle only-infused Wistar Furth (RT1u) recipients rejected Buffalo (RT1b) heart allografts within a mean survival time (MST) of 6.5 +/- 0.5 and 6.3 +/- 0.5 days, respectively. In contrast, a 14-day continuous intravenous (i.v.) infusion by an osmotic pump of 0.08 mg/kg/day RAPA to WFu recipients prolonged BUF heart allograft survival to an MST of 34.4 +/- 12.1 days (P = 0.0001). There was a graded dose-response to 0.16 mg/kg (39.0 +/- 8.7 days; P = 0.0001), 0.32 mg/kg (55.7 +/- 3.3 days; P = 0.0001) and 0.8 mg/kg (48.0 +/- 3.6; P = 0.0001). Furthermore, intraarterial/intragraft but not i.v. infusion of 0.02 mg/kg/day prolonged BUF heart allografts--namely, an MST of 14.6 +/- 1.4 days versus 8.6 +/- 2.6 days (P = 0.0001), respectively. Local delivery doses of RAPA were about as effective as the same dose delivered i.v.: 0.08 mg/kg MST 37.0 +/- 18.3 days (P = 0.0001); 0.32 mg/kg, 40.0 +/- 3.9 days (P = 0.0001); and 0.8 mg/kg, 54.8 +/- 8.2 days (P = 0.0001). Systemic i.v. RAPA therapy with 0.08 or 0.8 mg/kg/day prolonged the survival of BUF kidney grafts in WFu recipients--namely, an MST of 52.7 +/- 42.7 (NS) and 90.2 +/- 62.4 (P = 0.001) days, respectively, versus an MST of 11.6 +/- 1.5 days in control WFu recipients only infused with vehicle. While normal WFu rats reject heterotopic BUF small bowel allografts within an MST of 10.0 days, a 14-day course of i.v. RAPA treatment significantly (P = 0.0001) prolonged small bowel allograft survival to an MST of 26.8 +/- 3.7 days.

Immunosuppressive effects of FTY720 alone or in combination with cyclosporine and/or sirolimus.

BACKGROUND We examined the ability of FTY720, a novel immunosuppressant that prolongs the survival of allografts in experimental animal models, to potentiate the immunosuppressive effects of cyclosporine (CsA) and/or sirolimus (SRL) in vitro and in vivo. METHODS FTY720 alone (10-5000 ng/ml) or in combination with other drugs was added to human peripheral blood lymphocytes (PBLs) undergoing stimulation in vitro with phytohemagglutinin (PHA) or OKT3 monoclonal antibody. The combination index (CI) values were calculated to evaluate the nature of the interactions between FTY720 and CsA and/or SRL: CI values <1 reflect synergistic, CI=1, additive, and CI>1, antagonistic interactions. In addition, Wistar Furth (RT1u) rat recipients of Buffalo (RT1b) heart allografts were treated with FTY720 alone or in combination with other agents. FTY720 alone was also tested to block small bowel or liver allograft rejection in rats. RESULTS FTY720 alone produced only modest inhibition of the proliferation of human PBL stimulated with PHA or OKT3 monoclonal antibody. In combination with CsA or SRL, however, FTY720 produced synergistic effects, namely, CI values of 0.58 and 0.36, respectively. A 14-day course of FTY720 (0.05-8.0 mg/kg/day) by oral gavage prolonged heart allograft survival in dose-dependent fashion. Although a 14-day oral course of CsA (1.0 mg/kg/day) alone was ineffective (mean survival time=7.0+/-0.7 vs. 6.4+/-0.6 days in treated vs. untreated hosts), treatment with a combination of 1.0 mg/kg/day CsA and 0.1 mg/kg/day FTY720 extended allograft survival to 62.4+/-15.6 days (P<0.001; CI=0.15). Similarly, a 14-day oral course of 0.08 mg(kg/day SRL alone was ineffective (6.8+/-0.6 days; NS), but the combination of SRL with 0.5 mg/kg/day FTY720 extended the mean survival time to 34.4+/-8.8 days (CI=0.28). The CsA/SRL (0.5/0.08 mg/kg/day) combination acted synergistically with FTY720 (0.1 mg/kg/day) to prolong heart survivals to >60 days (CI=0.18). CONCLUSIONS FTY720 potentiates the immunosuppressive effects of CsA and/or SRL both in vitro (by inhibiting of T-cell proliferative response) and in vivo (by inhibiting allograft rejection).

Synergistic mechanisms by which sirolimus and cyclosporin inhibit rat heart and kidney allograft rejection

The studies presented herein examined the mechanism(s) whereby sirolimus (SRL) and cyclosporin (CsA) act synergistically to block allograft rejection. Combination index (CI=1 reflects additive, CI<1 antagonistic, and CI<1 synergistic, effects) analysis documented potent synergism between SRL and CsA to block allograft rejection. Combinations of the two drugs produced synergistic prolongation of heart (CI=0.001–0.2) or kidney (CI=0.03–0.5) allograft survival at SRL/CsA ratios ranging from 1:12.5 to 1:200. Pharmacokinetic analysis of the individual drugs showed that CsA does not affect the blood levels of SRL, and SRL mildly increases the levels of CsA in SRL/CsA‐treated rats. Quantitative polymerase chain reaction analysis was used to document that both subtherapeutic (1.0 mg/kg) and therapeutic (2.0 or 4.0 mg/kg) CsA doses inhibited the expression of interferon‐gamma (IFN‐γ) (P<0.03) and IL‐2 (P<0.003) mRNA produced by T helper (Th) 1 cells, as well as IL‐10 (P<0.001), but not IL‐4 (NS) mRNA produced by Th2 cells. Contrariwise, all tested SRL doses (0.02, 0.04 or 0.08 mg/kg) did not affect cytokine mRNA expression. However, heart allografts from rat recipients treated with synergistic SRL/CsA doses displayed reduced levels of IFN‐γ (P<0.01), IL‐2 (P<0.001) and IL‐10 (P<0.001) mRNA. Thus, because subtherapeutic doses of CsA reduce Th1/Th2 activity, thereby facilitating the inhibition of signal transduction by low does of SRL, the two agents act synergistically to inhibit allograft rejection.

Atrophic Remodeling of the Heart In Vivo Simultaneously Activates Pathways of Protein Synthesis and Degradation

Background—Mechanical unloading of the heart results in atrophic remodeling. In skeletal muscle, atrophy is associated with inactivation of the mammalian target of rapamycin (mTOR) pathway and upregulation of critical components of the ubiquitin proteosome proteolytic (UPP) pathway. The hypothesis is that mechanical unloading of the mammalian heart has differential effects on pathways of protein synthesis and degradation. Methods and Results—In a model of atrophic remodeling induced by heterotopic transplantation of the rat heart, we measured gene transcription, protein expression, polyubiquitin content, and regulators of the mTOR pathway at 2, 4, 7, and 28 days. In atrophic hearts, there was an increase in polyubiquitin content that peaked at 7 days and decreased by 28 days. Furthermore, gene and protein expression of UbcH2, a ubiquitin conjugating enzyme, was also increased early in the course of unloading. Transcript levels of TNF-&agr;, a known regulator of UbcH2-dependent ubiquitin conjugating activity, were upregulated early and transiently in the atrophying rat heart. Unexpectedly, p70S6K and 4EBP1, downstream components of mTOR, were activated in atrophic rat heart. This activation was independent of Akt, a known upstream regulator of mTOR. Rapamycin treatment of the unloaded rat hearts inhibited the activation of p70S6K and 4EBP1 and subsequently augmented atrophy in these hearts compared with vehicle-treated, unloaded hearts. Conclusions—Atrophy of the heart, secondary to mechanical unloading, is associated with early activation of the UPP. The simultaneous activation of the mTOR pathway suggests active remodeling, involving both protein synthesis and degradation.

Effects of the pharmacokinetic interaction between orally administered sirolimus and cyclosporine on the synergistic prolongation of heart allograft survival in rats.

Oral administration, but not continuous intravenous infusion, of sirolimus (SRL) in combination with cyclosporine (CsA) produces a pharmacokinetic interaction, namely increases in the whole blood trough concentrations of SRL ([SRL(WB)]) and CsA ([CsA(WB)]). The effects of this pharmacokinetic interaction on the synergism between SRL and CsA was examined in Wistar Furth (RT1u) recipients of Buffalo (RT1b) heart allografts. A 14-day course of oral SRL produced dose-dependent prolongation of heart allografts: in untreated controls, 0.5 mg/kg SRL per day extended the mean survival time (MST) from 6.4+/-0.5 days to 12.3+/-3.8 days (P<0.05); SRL at 1.0 mg/kg per day prolonged the MST to 18.0+/-5.5 days (P<0.01); at 2.0 mg/kg SRL per day, MST was extended to 52.5+/-13.2 days (P<0.01); and 4.0 mg/kg SRL per day prolonged MST to 90.0+/-41.1 days (P<0.01). Comparison of the in vivo effects after oral versus continuous intravenous SRL administration suggested that the oral bioavailability of SRL is less than 10%. Combinations of oral SRL and CsA synergistically prolonged heart allograft survival, as documented by combination index values of 0.01-0.64 (combination index <1 indicates synergistic interaction). In rats treated with dual drug combinations, CsA increased the bioavailability of SRL by two- to elevenfold, and SRL increased the bioavailability of CsA by two- to threefold, thereby significantly decreasing the oral effective dose (ED) values for each drug. The ED50 for SRL alone is 2.4 mg/kg per day, which produces an average [SRL(WB)] of 13.2 ng/ml. The ED50 for CsA alone is 8.0 mg/kg per day, which produces an average [CsA(WB)] of 1642 ng/ml. However, when the two drugs are combined, the ED50 effect is achieved with only 0.34 mg/kg SRL per day ([SRL(WB)]=1.1 ng/ml) and 2.1 mg/kg CsA per day ([CsA(WB)] =326 ng/ml). Individually, 0.34 mg/kg SRL per day produces an ED9 with an average [SRL(WB)] of 0.6 ng/ml, and 2.1 mg/kg CsA per day produces an ED22 with an average [CsA(WB)] of 174 ng/ml. Thus, the pharmacokinetic interaction between oral SRL and CsA contributes to the in vivo synergism between the two drugs.

Molecular targets for existing and novel immunosuppressive drugs

Anti-neoplastic cytostatic antiproliferative agents, such as methotrexate, 6-mercaptopurine and cyclophosphamide, were originally used as immunosuppressive drugs. Although these agents induced only modest anti-rejection activity, they caused serious non-specific bone marrow suppression, impairing host resistance and increasing the incidence of infections. Unlike these non-selective agents, cyclosporine A, tacrolimus and sirolimus act more selectively on different stages of the T-lymphocyte (T-cell) and B-lymphocyte (B-cell) activation cycles; however, cyclosporine and tacrolimus are nephrotoxic, whereas sirolimus causes hypertriglyceridaemia. Thus, despite this progress, continued efforts must be made to develop and test new, potentially very selective agents. The agent 15-deoxyspergualin moderately inhibits both mitogen-stimulated T-cell proliferation and the generation of cytotoxic T lymphocytes (CTLs) but does not affect the production of interleukin 2 (IL-2). Another drug, FTY720, has a unique action to prevent rejection, by altering the homing of lymphocytes to the lymphoid compartments. The newest members of the family of antiproliferative agents, namely mycophenolate mofetil, leflunomide and brequinar, are potentially more selective than their predecessors. However, the most promising agents are produced using antisense technology. This approach involves the design of antisense oligodeoxynucleotides; these novel drugs are designed to block allograft rejection by blocking selected messenger RNA (mRNA). This review outlines the mechanisms of action, the limitations of application and the molecular or cellular targets of traditional agents, newly developed drugs and also antisense technology, which is an example of a new application of molecular medicine.

“Default” Generation of Neonatal Regulatory T Cells

CD4+Foxp3+ regulatory T (Treg) cells were shown to control all aspects of immune responses. How these Treg cells develop is not fully defined, especially in neonates during development of the immune system. We studied the induction of Treg cells from neonatal T cells with various TCR stimulatory conditions, because TCR stimulation is required for Treg cell generation. Independent of the types of TCR stimulus and without the addition of exogenous TGF-β, up to 70% of neonatal CD4+Foxp3− T cells became CD4+Foxp3+ Treg cells, whereas generally <10% of adult CD4+Foxp3− T cells became CD4+Foxp3+ Treg cells under the same conditions. These neonatal Treg cells exert suppressive function and display relatively stable Foxp3 expression. Importantly, this ability of Treg cell generation gradually diminishes within 2 wk of birth. Consistent with in vitro findings, the in vivo i.p. injection of anti-CD3 mAb to stimulate T cells also resulted in a >3-fold increase in Treg cells in neonates but not in adults. Furthermore, neonatal or adult Foxp3− T cells were adoptively transferred into Rag1−/− mice. Twelve days later, the frequency of CD4+Foxp3+ T cells converted from neonatal cells was 6-fold higher than that converted from adult cells. Taken together, neonatal CD4+ T cells have an intrinsic “default” mechanism to become Treg cells in response to TCR stimulations. This finding provides intriguing implications about neonatal immunity, Treg cell generation, and tolerance establishment early in life.

Relative tissue distributions of cyclosporine and sirolimus after concomitant peroral administration to the rat : Evidence for pharmacokinetic interactions

The authors sought to determine the effect of concomitant peroral (PO) administration of cyclosporine (CsA) and sirolimus (SRL, rapamycin) on the tissue distributions of CsA and SRL in the rat. Groups of four adult male Wistar-Furth rats were treated for 14 days with 2.5, 5.0, or 10.0 mg CsA/kg x day. Other groups of four adult male Wistar-Furth rats were treated for 14 days with a 1-to-6.25 weight-to-weight ratio of SRL to CsA at SRL doses of 0.4, 0.8, or 1.6 mg/kg x day. Concentrations of CsA and SRL in homogenates of heart, intestinal, kidney, liver, lung, muscle, spleen, and testes were compared to those in whole blood (WB). There was a large, dose-dependent, distinctive distribution of CsA among rat tissues, as has previously been well documented. At a constant molar dose ratio, concomitant oral administration of SRL produced an approximately two-fold increase in the concentrations of CsA in rat tissues, although SRL did not change the CsA tissue-to-WB partition coefficients. Concomitant oral CsA administration produced dose-dependent increases in SRL tissue concentrations and decreases in the SRL tissue-to-WB partition coefficients. The increases in tissue and WB concentrations on coadministration of both agents may be explained either by an increase in absorption caused by competition between the two agents for binding sites on P-glycoprotein in the gut, a reduced rate of metabolism, or to an as yet unidentified elimination mechanism. The dose-independent and unchanged CsA tissue-to-WB partition coefficients suggest that SRL does not affect the equilibrium of CsA between the central and tissue compartments, namely the tissue uptake or intracellular binding. Altered values of the SRL tissue-to-WB partition coefficients suggest that, under the conditions studied, CsA disturbs the equilibrium of SRL between the central and tissue compartments.