Rapamycin Antifungal Action Is Mediated via Conserved Complexes with FKBP12 and TOR Kinase Homologs in Cryptococcus neoformans

Cryptococcus neoformans is a fungal pathogen that causes meningitis in patients immunocompromised by AIDS, chemotherapy, organ transplantation, or high-dose steroids. Current antifungal drug therapies are limited and suffer from toxic side effects and drug resistance. Here, we defined the targets and mechanisms of antifungal action of the immunosuppressant rapamycin in C. neoformans. In the yeast Saccharomyces cerevisiae and in T cells, rapamycin forms complexes with the FKBP12 prolyl isomerase that block cell cycle progression by inhibiting the TOR kinases. We identified the gene encoding a C. neoformans TOR1 homolog. Using a novel two-hybrid screen for rapamycin-dependent TOR-binding proteins, we identified the C. neoformans FKBP12 homolog, encoded by the FRR1 gene. Disruption of the FKBP12 gene conferred rapamycin and FK506 resistance but had no effect on growth, differentiation, or virulence of C. neoformans. Two spontaneous mutations that confer rapamycin resistance alter conserved residues on TOR1 or FKBP12 that are required for FKBP12-rapamycin-TOR1 interactions or FKBP12 stability. Two other spontaneous mutations result from insertion of novel DNA sequences into the FKBP12 gene. Our observations reveal that the antifungal activities of rapamycin and FK506 are mediated via FKBP12 and TOR homologs and that a high proportion of spontaneous mutants in C. neoformans result from insertion of novel DNA sequences, and they suggest that nonimmunosuppressive rapamycin analogs have potential as antifungal agents.     

The rapamycin-binding domain of the protein kinase mammalian target of rapamycin is a destabilizing domain

Rapamycin is an immunosuppressive drug that binds simultaneously to the 12-kDa FK506- and rapamycin-binding protein (FKBP12, or FKBP) and the FKBP-rapamycin binding (FRB) domain of the mammalian target of rapamycin (mTOR) kinase. The resulting ternary complex has been used to conditionally perturb protein function, and one such method involves perturbation of a protein of interest through its mislocalization. We synthesized two rapamycin derivatives that possess large substituents at the C-16 position within the FRB-binding interface, and these derivatives were screened against a library of FRB mutants using a three-hybrid assay in Saccharomyces cerevisiae. Several FRB mutants responded to one of the rapamycin derivatives, and twenty of these mutants were further characterized in mammalian cells. The mutants most responsive to the ligand were fused to yellow fluorescent protein, and fluorescence levels in the presence and absence of the ligand were measured to determine stability of the fusion proteins. Wild-type and mutant FRB domains were expressed at low levels in the absence of the rapamycin derivative, and expression levels rose up to 10-fold upon treatment with ligand. The synthetic rapamycin derivatives were further analyzed using quantitative mass spectrometry, and one of the compounds was found to contain contaminating rapamycin. Furthermore, uncontaminated analogs retained the ability to inhibit mTOR, although with diminished potency relative to rapamycin. The ligand-dependent stability displayed by wild-type FRB and FRB mutants as well as the inhibitory potential and purity of the rapamycin derivatives should be considered as potentially confounding experimental variables when using these systems.     

Pharmacological characterization of purified recombinant mTOR FRB-kinase domain using fluorescence-based assays

The mammalian target of rapamycin (mTOR) is a serine/threonine kinase involved in nutrient sensing and cell growth and is a validated target for oncology and immunosuppression. Two modes of direct small-molecule inhibition of mTOR activity are known: targeting of the kinase active site and a unique mode in which the small molecule rapamycin, in complex with FKBP12 (the 12-kDa FK506 binding protein), binds to the FRB (FKBP12/rapamycin binding) domain of mTOR and inhibits kinase activity through a poorly defined mechanism. To facilitate the study of these processes, the authors have expressed and purified a truncated version of mTOR that contains the FRB and kinase domains and have developed homogeneous fluorescence-based assays to study mTOR activity. They demonstrate the utility of these assays in studies of active site-directed and FRB domain-directed mTOR inhibition. The results suggest that these assays can replace traditional radiometric or Western blot-based assays.     

Targets of immunophilin-immunosuppressant complexes are distinct highly conserved regions of calcineurin A.

The immunosuppressive complexes cyclophilin A-cyclosporin A (CsA) and FKBP12-FK506 inhibit calcineurin, a heterodimeric Ca(2+)-calmodulin-dependent protein phosphatase that regulates signal transduction. We have characterized CsA- or FK506-resistant mutants isolated from a CsA-FK506-sensitive Saccharomyces cerevisiae strain. Three mutations that confer dominant CsA resistance are single amino acid substitutions (T350K, T350R, Y377F) in the calcineurin A catalytic subunit CMP1. One mutation that confers dominant FK506 resistance alters a single residue (W430C) in the calcineurin A catalytic subunit CMP2. In vitro and in vivo, the CsA-resistant calcineurin mutants bind FKBP12-FK506 but have reduced affinity for cyclophilin A-CsA. When introduced into the CMP1 subunit, the FK506 resistance mutation (W388C) blocks binding by FKBP12-FK506, but not by cyclophilin A-CsA. Co-expression of CsA-resistant and FK506-resistant calcineurin A subunits confers resistance to CsA and to FK506 but not to CsA plus FK506. Double mutant calcineurin A subunits (Y377F, W388C CMP1 and Y419F, W430C CMP2) confer resistance to CsA, to FK506 and to CsA plus FK506. These studies identify cyclophilin A-CsA and FKBP12-FK506 binding targets as distinct, highly conserved regions of calcineurin A that overlap the binding domain for the calcineurin B regulatory subunit.     

ScFKBP12 bridges rapamycin and AtTOR in Arabidopsis

FKBP12 encodes a prolyl isomerase and highly conserved in eukaryotic species. In yeasts and animals, FKBP12 can interact with rapamycin and FK506 to form rapamycin-FKBP12 and FK506-FKBP12 complex, respectively. In higher plants, FKBP12 protein lost its function to bind rapamycin and FK506. Early studies showed that yeast and human FKBP12 protein can restore the rapamycin sensitivity in Arabidopsis, but the used concentration is 100–1000 folds higher than that in yeast and animals. High concentration of drugs would increase the cost and cause the potential secondary effects on plant growth and development. Here we further discovered that BP12 plants generated in our previous study are hypersensitive to rapamycin at the concentration as low as that is effective in yeast and animals. It is surprising to observe that WT and BP12 plants are not sensitive to FK506 in normal growth condition. These findings advance the current understanding of rapamycin-TOR signaling in plants.     

Hmo1p, a high mobility group 1/2 homolog, genetically and physically interacts with the yeast FKBP12 prolyl isomerase

The immunosuppressive drugs FK506 and rapamycin bind to the cellular protein FKBP12, and the resulting FKBP12-drug complexes inhibit signal transduction. FKBP12 is a ubiquitous, highly conserved, abundant enzyme that catalyzes a rate-limiting step in protein folding: peptidyl-prolyl cis-trans isomerization. However, FKBP12 is dispensible for viability in both yeast and mice, and therefore does not play an essential role in protein folding. The functions of FKBP12 may involve interactions with a number of partner proteins, and a few proteins that interact with FKBP12 in the absence of FK506 or rapamycin have been identified, including the ryanodine receptor, aspartokinase, and the type II TGF-beta receptor; however, none of these are conserved from yeast to humans. To identify other targets and functions of FKBP12, we have screened for mutations that are synthetically lethal with an FKBP12 mutation in yeast. We find that mutations in HMO1, which encodes a high mobility group 1/2 homolog, are synthetically lethal with mutations in the yeast FPR1 gene encoding FKBP12. Deltahmo1 and Deltafpr1 mutants share two phenotypes: an increased rate of plasmid loss and slow growth. In addition, Hmo1p and FKBP12 physically interact in FKBP12 affinity chromatography experiments, and two-hybrid experiments suggest that FKBP12 regulates Hmo1p-Hmo1p or Hmo1p-DNA interactions. Because HMG1/2 proteins are conserved from yeast to humans, our findings suggest that FKBP12-HMG1/2 interactions could represent the first conserved function of FKBP12 other than mediating FK506 and rapamycin actions.     

The fission yeast TOR homolog, tor1+, is required for the response to starvation and other stresses via a conserved serine

Targets of rapamycin (TORs) are conserved phosphatidylinositol kinase-related kinases that are involved in the coordination between nutritional or mitogenic signals and cell growth. Here we report the initial characterization of two Schizosaccharomyces pombe TOR homologs, tor1(+) and tor2(+). tor2(+) is an essential gene, whereas tor1(+) is required only under starvation and other stress conditions. Specifically, Deltator1 cells fail to enter stationary phase or undergo sexual development and are sensitive to cold, osmotic stress, and oxidative stress. In complex with the prolyl isomerase FKBP12, the drug rapamycin binds a conserved domain in TORs, FRB, thus inhibiting some of the functions of TORs. Mutations at a conserved serine within the FRB domain of Saccharomyces cerevisiae TOR proteins led to rapamycin resistance but did not otherwise affect the functions of the proteins. The S. pombe tor1(+) exhibits different features; substitution of the conserved serine residue, Ser(1834), with arginine compromises its functions and has no effect on the inhibition that rapamycin exerts on sexual development in S. pombe.     

Rapamycin blocks sexual development in fission yeast through inhibition of the cellular function of an FKBP12 homolog

FKBP12 is a ubiquitous and a highly conserved prolyl isomerase that binds the immunosuppressive drugs FK506 and rapamycin. Members of the FKBP12 family have been implicated in many processes that include intracellular protein folding, transport, and assembly. In the budding yeast Saccharomyces cerevisiae and in human T cells, rapamycin forms a complex with FKBP12 that inhibits cell cycle progression by inhibition of the TOR kinases. We reported previously that rapamycin does not inhibit the vegetative growth of the fission yeast Schizosaccharomyces pombe; however, it specifically inhibits its sexual development. Here we show that disruption of the S. pombe FKBP12 homolog, fkh1(+), at its chromosomal locus results in a mating-deficient phenotype that is highly similar to that obtained by treatment of wild type cells with rapamycin. A screen for fkh1 mutants that can confer rapamycin resistance identified five amino acids in Fkh1 that are critical for the effect of rapamycin in S. pombe. All five amino acids are located in the putative rapamycin binding pocket. Together, our findings indicate that Fkh1 has an important role in sexual development and serves as the target for rapamycin action in S. pombe.     

Molecular cloning of a 25-kDa high affinity rapamycin binding protein, FKBP25.

Two FK506 binding proteins of molecular mass 12 kDa (FKBP12) and 13 kDa (FKBP13) have been identified as common cellular receptors of the immunosuppressants FK506 and rapamycin. Here we report the molecular cloning and overexpression of a 25-kDa rapamycin and FK506 binding protein (termed FKBP25) with peptidylprolyl cis-trans-isomerase (PPIase) activity. The amino acid sequence, predicted from the FKBP25 cDNA, shares identity with FKBP12 (44%) and FKBP13 (47%) in the C-terminal 97 amino acids. Unlike either FKBP12 or FKBP13, the nucleotide sequence of FKBP25 contains a number of putative nuclear localization sequences. The PPIase activity of recombinant FKBP25 was comparable with that of FKBP12. The PPIase activity of FKBP25 was far more sensitive to inhibition by rapamycin (IC50 = 50 nM) than FK506 (IC50 = 400 nM). PPIase activity of 100 nM FKBP25 was almost completely inhibited by 150 nM rapamycin while only 90% inhibition was achieved by 4 microM FK506. These data demonstrate that FKBP25 has a higher affinity for rapamycin than for FK506 and suggest that this cellular receptor may be an important target molecule for immunosuppression by rapamycin.     

Molecular characterization of a plant FKBP12 that does not mediate action of FK506 and rapamycin

Immuonosuppressive drugs FK506 and rapamycin block a number of signal transduction pathways in eukaryotic systems. The 12 kDa FK506 binding protein (FKBP12) mediates the action of both FK506 and rapamycin against their functional targets. In this report, we cloned, sequenced and characterized a gene encoding FKBP12 in Vicia faba ( Vf FKBP12). While Vf FKBP12 is highly homologous to animal and yeast FKBP12, it does not mediate the action of FK506 and rapamycin. There are unique features in plant FKBP12 sequences that cause the variation in their function. One lies in the domain that is critical for interaction with calcineurin (CaN), the mammalian and yeast target of FKBP12-FK506 complex. Protein–protein interaction assays revealed a low-affinity and unstable Vf FKBP12-FK506-CaN ternary complex. In the genetic assay, Vf FKBP12 did not restore the sensitivity of yeast FKBP12 mutant to rapamycin or FK506, supporting that plant FKBP12-ligand complexes are unable to block the function of the drug target. Also unique to plant FKBP12 proteins, a pair of cysteines is spatially adjacent to potentially form disulfide linkage. Treatment of Vf FKBP12 with reductant dithiothreitol (DTT) abolished the formation of Vf FKBP12-FK506-CaN ternary complex. Site-directed mutagenesis to substitute one of the cysteines, Cys²⁶, with Ser produced a similar effect as DTT treatment. These results indicate that an intramolecular disulfide bond is a novel structural feature required for the low–affinity interaction between plant FKBP12 and CaN. In conclusion, plant FKBP12 proteins have evolved structural changes that modify their protein-protein interacting domains and cause loss of function against the drug targets.     

Mean field analysis of FKBP12 complexes with FK506 and rapamycin: Implications for a role of crystallographic water molecules in molecular recognition and specificity

Mean field analysis of FKBP12 complexes with FK506 and rapamycin has been performed by using structures obtained from molecular docking simulations on a simple, yet robust molecular recognition energy landscape. When crystallographic water molecules are included in the simulations as an extension of the FKBP12 protein surface, there is an appreciable stability gap between the energy of the native FKBP12–FK506 complex and energies of conformations with the “native-like” binding mode. By contrast, the energy spectrum of the FKBP12–rapamycin complex is dense regardless of the presence of the water molecules. The stability gap in the FKBP12–FK506 system is determined by two critical water molecules from the effector region that participate in a network of specific hydrogen bond interactions. This interaction pattern protects the integrity and precision of the composite ligand-protein effector surface in the binary FKBP12–FK506 complex and is preserved in the crystal structure of the FKBP12–FK506–calcineurin ternary complex. These features of the binding energy landscapes provide useful insights into specific and nonspecific aspects of FK506 and rapamycin recognition. Proteins 28:313–324, 1997. © 1997 Wiley-Liss, Inc.     

Inhibition of target of rapamycin signaling by rapamycin in the unicellular green alga Chlamydomonas reinhardtii

The macrolide rapamycin specifically binds the 12-kD FK506-binding protein (FKBP12), and this complex potently inhibits the target of rapamycin (TOR) kinase. The identification of TOR in Arabidopsis (Arabidopsis thaliana) revealed that TOR is conserved in photosynthetic eukaryotes. However, research on TOR signaling in plants has been hampered by the natural resistance of plants to rapamycin. Here, we report TOR inactivation by rapamycin treatment in a photosynthetic organism. We identified and characterized TOR and FKBP12 homologs in the unicellular green alga Chlamydomonas reinhardtii. Whereas growth of wild-type Chlamydomonas cells is sensitive to rapamycin, cells lacking FKBP12 are fully resistant to the drug, indicating that this protein mediates rapamycin action to inhibit cell growth. Unlike its plant homolog, Chlamydomonas FKBP12 exhibits high affinity to rapamycin in vivo, which was increased by mutation of conserved residues in the drug-binding pocket. Furthermore, pull-down assays demonstrated that TOR binds FKBP12 in the presence of rapamycin. Finally, rapamycin treatment resulted in a pronounced increase of vacuole size that resembled autophagic-like processes. Thus, our findings suggest that Chlamydomonas cell growth is positively controlled by a conserved TOR kinase and establish this unicellular alga as a useful model system for studying TOR signaling in photosynthetic eukaryotes.     

Molecular Docking studies of FKBP12-mTOR inhibitors using binding predictions

Mammalian target of rapamycin (mTOR) is a key regulator of cell growth, proliferation and angiogenesis. mTOR signaling is frequently hyper activated in a broad spectrum of human cancers thereby making it a potential drug target. The current drugs available have been successful in inhibiting the mTOR signaling, nevertheless, show low oral bioavailability and suboptimal solubility. Considering the narrow therapeutic window of the available inhibitors, through computational approaches, the present study pursues to identify a compound with optimal oral bioavailability and better solubility properties in addition ensuing high affinity between FKBP12 and FRB domain of mTOR. Current mTOR inhibitors; Everolimus, Temsirolimus Deforolimus and Echinomycin served as parent molecules for similarity search with a threshold of 95%. The query molecules and respective similar molecules were docked at the binding cleft of FKBP12 protein. Aided by MolDock algorithm, high affinity compounds against FKBP12 were retrieved. Patch Dock supervised protein-protein interactions were established between FRB domain of mTOR and ligand (query and similar) bound and free states of FKBP12. All the similar compounds thus retrieved showed better solubility properties and enabled better complex formation of mTOR and FKBP12. In particular Everolimus similar compound PubChem ID: 57284959 showed appreciable drugs like properties bestowed with better solubility higher oral bioavailability. In addition this compound brought about enhanced interaction between FKBP12 and FRB domain of mTOR. In the study, we report Everolimus similar compound PubChem ID: 57284959 to be potential inhibitor for mTOR pathway which can overcome the affinity and solubility concerns of current mTOR drugs.

Abbreviations

mTOR - Mammalian Target of Rapamycin, FRB domain - FKBP12-rapamycin associated protein, FKBP12 - FK506-binding protein 12, OPLS - Optimized Potentials for Liquid Simulations, Akt - RAC-alpha serine/threonine-protein kinase, PI3K - phosphatidylinositide 3-kinases.     

FKBPs and the Akt/mTOR pathway

FK506-binding proteins (FKBP) belong to the immunophilin family and are best known for their ability to enable the immunosuppressive properties of FK506 and rapamycin. For rapamycin, this is achieved by inducing inhibitory ternary complexes with the kinase mTOR. The essential accessory protein for this gain-of-function was thought to be FKBP12. We recently showed that this view might be too restricted, since larger FK506-binding proteins can functionally substitute for FKBP12 in mammalian cells. Recent studies have also shown that FK506-binding proteins can modulate Akt-mTOR signaling in the absence of rapamycin. Here we discuss the role of FK506-binding proteins for the mechanism of rapamycin as well as their intrinsic actions on the Akt/mTOR pathway.     

Bimolecular Fluorescence Complementation Analysis of Inducible Protein Interactions: Effects of Factors Affecting Protein Folding on Fluorescent Protein Fragment Association

Bimolecular fluorescence complementation (BiFC) analysis enables visualization of the subcellular locations of protein interactions in living cells. Using fragments of different fluorescent proteins, we investigated the temporal resolution and the quantitative accuracy of BiFC analysis. We determined the kinetics of BiFC complex formation in response to the rapamycin-inducible interaction between the FK506 binding protein (FKBP) and the FKBP-rapamycin binding domain (FRB). Fragments of yellow fluorescent protein fused to FKBP and FRB produced detectable BiFC complex fluorescence 10 min after the addition of rapamycin and a 10-fold increase in the mean fluorescence intensity in 8 h. The N-terminal fragment of the Venus fluorescent protein fused to FKBP produced constitutive BiFC complexes with several C-terminal fragments fused to FRB. A chimeric N-terminal fragment containing residues from Venus and yellow fluorescent protein produced either constitutive or inducible BiFC complexes depending on the temperature at which the cells were cultured. The concentrations of inducers required for half-maximal induction of BiFC complex formation by all fluorescent protein fragments tested were consistent with the affinities of the inducers for unmodified FKBP and FRB. Treatment with the FK506 inhibitor of FKBP-FRB interaction prevented the formation of BiFC complexes by FKBP and FRB fusions, but did not disrupt existing BiFC complexes. Proteins synthesized before the addition of rapamycin formed BiFC complexes with the same efficiency as did newly synthesized proteins. Inhibitors of protein synthesis attenuated BiFC complex formation independent of their effects on fusion protein synthesis. The kinetics at which they inhibited BiFC complex formation suggests that they prevented association of the fluorescent protein fragments, but not the slow maturation of BiFC complex fluorescence. Agents that induce the unfolded protein response also reduced formation of BiFC complexes. The effects of these agents were suppressed by cellular adaptation to protein folding stress. In summary, BiFC analysis enables detection of protein interactions within minutes after complex formation in living cells, but does not allow detection of complex dissociation. Conditional BiFC complex formation depends on the folding efficiencies of fluorescent protein fragments and can be affected by the cellular protein folding environment.     

A novel FK506- and rapamycin-binding protein (FPR3 gene product) in the yeast Saccharomyces cerevisiae is a proline rotamase localized to the nucleolus

The gene (FPR3) encoding a novel type of peptidylpropyl-cis-trans- isomerase (PPIase) was isolated during a search for previously unidentified nuclear proteins in Saccharomyces cerevisiae. PPIases are thought to act in conjunction with protein chaperones because they accelerate the rate of conformational interconversions around proline residues in polypeptides. The FPR3 gene product (Fpr3) is 413 amino acids long. The 111 COOH-terminal residues of Fpr3 share greater than 40% amino acid identity with a particular class of PPIases, termed FK506-binding proteins (FKBPs) because they are the intracellular receptors for two immunosuppressive compounds, rapamycin and FK506. When expressed in and purified from Escherichia coli, both full-length Fpr3 and its isolated COOH-terminal domain exhibit readily detectable PPIase activity. Both fpr3 delta null mutants and cells expressing FPR3 from its own promoter on a multicopy plasmid have no discernible growth phenotype and do not display any alteration in sensitivity to the growth-inhibitory effects of either FK506 or rapamycin. In S. cerevisiae, the gene for a 112-residue cytosolic FKBP (FPR1) and the gene for a 135-residue ER-associated FKBP (FPR2) have been described before. Even fpr1 fpr2 fpr3 triple mutants are viable. However, in cells carrying an fpr1 delta mutation (which confers resistance to rapamycin), overexpression from the GAL1 promoter of the C-terminal domain of Fpr3, but not full-length Fpr3, restored sensitivity to rapamycin. Conversely, overproduction from the GAL1 promoter of full- length Fpr3, but not its COOH-terminal domain, is growth inhibitory in both normal cells and fpr1 delta mutants. In fpr1 delta cells, the toxic effect of Fpr3 overproduction can be reversed by rapamycin. Overproduction of the NH2-terminal domain of Fpr3 is also growth inhibitory in normal cells and fpr1 delta mutants, but this toxicity is not ameliorated in fpr1 delta cells by rapamycin. The NH2-terminal domain of Fpr3 contains long stretches of acidic residues alternating with blocks of basic residues, a structure that resembles sequences found in nucleolar proteins, including S. cerevisiae NSR1 and mammalian nucleolin. Indirect immunofluorescence with polyclonal antibodies raised against either the NH2- or the COOH-terminal segments of Fpr3 expressed in E. coli demonstrated that Fpr3 is located exclusively in the nucleolus.     

Conditionally controlling nuclear trafficking in yeast by chemical-induced protein dimerization

We present here a protocol to conditionally control the nuclear trafficking of target proteins in yeast. In this system, rapamycin is used to heterodimerize two chimeric proteins. One chimera consists of a FK506-binding protein (FKBP12) fused to a cellular 'address' (nuclear localization signal or nuclear export sequence). The second chimera consists of a target protein fused to a fluorescent protein and the FKBP12-rapamycin-binding (FRB) domain from FKBP-12-rapamycin associated protein 1 (FRAP1, also known as mTor). Rapamycin induces dimerization of the FKBP12- and FRB-containing chimeras; these interactions selectively place the target protein under control of the cell address, thereby directing the protein into or out of the nucleus. By chemical-induced dimerization, protein mislocalization is reversible and enables the identification of conditional loss-of-function and gain-of-function phenotypes, in contrast to other systems that require permanent modification of the targeted protein. Yeast strains for this analysis can be constructed in 1 week, and the technique allows protein mislocalization within 15 min after drug treatment.