N H Sigal

CsA, FK-506, and rapamycin are microbial products with potent immunosuppressive properties that result primarily from a selective inhibition of T lymphocyte activation. Although chemically unrelated, CsA and FK-506 affect a similar subset of calcium-associated signaling events involved in the regulation of lymphokine gene expression, activation-driven T-cell death and exocytosis. Rapamycin has structural similarity with FK-506 but suppresses T-cell activation at a different level, mainly through inhibition of proliferation induced by growth-promoting lymphokines. CsA interacts with an abundant 17 kDa protein, termed cyclophilin, that possesses peptidyl-prolyl cis-trans isomerase (PPIase) activity. Additional, minor cyclophilin-like molecules have been identified. Both FK-506 and rapamycin interact with FKBP, a 12 kDa protein, which, although unrelated to cyclophilin, is also abundant and ubiquitous, has a similar enzymatic activity, and is a member of a larger family of FKBPs. All three immunosuppressants inhibit the PPIase activity of their respective binding proteins. However, nonimmunosuppressive analogs of CsA and FK-506 are also inhibitory, indicating that inhibition of PPIase activity is not directly implicated in immunosuppression. Moreover, only a small fraction of the cellular pool of the major forms of cyclophilin or FKBP needs to be occupied by the drugs in order to achieve maximal immunosuppression. These observations suggest that complexes formed between the drugs and their major binding proteins may affect the function of other, unidentified, molecules or, alternatively, that minor binding proteins may play a role in the drugs' action. Further characterization of the biochemical processes altered by CsA, FK-506, and rapamycin should yield important insights into the signal transduction pathways involved in T-cell activation and should help in the development of novel immunosuppressive agents.

FK-506 and the structurally related macrolide rapamycin (RAP) were investigated in comparison with cyclosporin A (CsA) for their immunosuppressive effects on murine T cells. All three agents suppressed the proliferation of splenic T cells triggered by lectins or antibodies to CD3 and Ly-6C. FK-506 or CsA also inhibited proliferation, IL-2 production, and IL-2R expression in splenic T cells activated with ionomycin + PMA. However, RAP minimally affected IL-2 production and IL-2R expression in these cells, although it reduced proliferation. Similarly, FK-506 and CsA, but not RAP, suppressed IL-2 production by activated DO.11.10 T hybridoma cells. In such a system, as well as in normal T cells stimulated with high ionomycin concentrations, FK-506 and CsA enhanced proliferation, indicating that they both abrogate negative signals associated with T cell activation. On the contrary, RAP diminished the autonomous proliferation of hybridoma cells, whereas FK-506 and CsA had little effect. The proliferative response induced in D10.G4 cells by IL-1 + ionomycin but not that induced by IL-1 + PMA was sensitive to inhibition by FK-506 and CsA. In contrast, RAP inhibited equally well both types of stimulation. Finally, T cell proliferation driven by IL-2 or IL-4 was found to be relatively resistant to FK-506 or CsA but sensitive to RAP. Altogether, these data demonstrate that FK-506 and CsA alter similar calcium-associated events of T cell activation and block T cell proliferation primarily by suppressing lymphokine production. RAP interferes with a different set of events and inhibits T cells by impairing their response to growth-promoting lymphokines.

A DNA-unwinding protein has been purified to homogeneity from E. coli. This protein has a molecular weight of about 22,000, as judged by its electrophoretic mobility on polyacrylamide gels containing sodium dodecylsulfate, and it appears to be present in about 800 copies per log-phase cell. It binds tightly and cooperatively to single-stranded DNA, and much less tightly, if at all, to RNA or double-stranded DNA. Like the T4 gene-32 protein characterized previously, the E. coli DNA-unwinding protein depresses the melting temperature of double-stranded DNAs, with regions rich in A-T base-pairs being preferentially melted. The E. coli protein strongly stimulates in vitro DNA synthesis by E. coli DNA polymerase II on appropriate templates; however, no stimulation is found with purified polymerases I or III of E. coli, or with T4 DNA polymerase. In contrast, gene-32 protein stimulates only the T4 DNA polymerase in a parallel assay.

The structurally related immunosuppressive macrolides FK-506 and rapamycin (RAP) were previously shown to inhibit T cell stimulation through different mechanisms. FK-506 acts similarly to cyclosporin A (CsA) and prevents IL-2 production and IL-2R expression. RAP has little or no effect on these events but markedly impedes the response to IL-2. The present study was initiated to examine the possibility of a complementation between the immunosuppressive actions of RAP and FK-506 or CsA on various murine T cell responses. RAP potentiated the effect of CsA on proliferation and IL-2R expression in T cells stimulated with ionomycin + PMA. However, in the same system, RAP acted as a potent antagonist of FK-506 suppression. RAP also blocked FK-506- but not CsA-mediated inhibition of IL-2 mRNA induction. By using model systems sensitive to inhibition by RAP but not FK-506 we further demonstrated that FK-506 reciprocally behaves as an antagonist of RAP. In one such model, the stimulation of splenic T cells with IL-2 + PMA, FK-506, but not CsA, reversed the suppressive effect of RAP on proliferation. FK-506 also antagonized RAP-mediated inhibition with respect to the induction of Ly-6E Ag expression by IFN in YAC cells. To explore further the competition between the two macrolides at the cellular level, we performed binding experiments with a radiolabeled derivative of FK-506. Both FK-506 and RAP, but not CsA, inhibited the binding of this probe in YAC cells. Taken together, these data demonstrate that FK-506 and RAP antagonize each other's biologic activity and physically interact with a common receptor site(s) in T cells. Moreover, CsA acts at a site distinct from the cellular target(s) of FK-506 or RAP.