In Saccharomyces cerevisiae, mutations in FKSJ confer hypersensitivity to the immunosuppressants FK506 and cyclosporin A, while mutations in ETGI confer resistance to the cell-wall-active echinocandins (inhibitors of 1,3-J3D-glucan synthase) and, in some cases, concomitant hypersensitivity to the chitin synthase inhibitor nikkomycin Z.The FKS1 and ETGI genes were cloned by complementation of these phenotypes and were found to be identical. The immunosuppressants FK506 and cyclosporin A (CsA) also have antifungal activity. Although vegetative growth of yeast is not potently inhibited by these drugs, recovery from mating factor arrest is (8). The drugs inhibit yeast recovery and T-cell activation by similar mechanisms. Each binds to an intracellular receptor (FKBP12 for FK506 and cyclophilin for CsA), and the receptor-drug complex inhibits the Ca2+/ calmodulin-dependent protein phosphatase calcineurin (9, 10). We previously described a mutation (Jksl-l) which results in calcineurin-dependent growth and hypersensitivity to FK506 (FKs) and CsA (11). We cloned the hypersensitivity locus (FKSJ) to help identify targets of calcineurin.t To our surprise FKS1 and ETGI are identical.:MATERIALS AND METHODS Microbiological Methods and Strains. YPAD and drop-out (DO) media and procedures for mating, sporulation, tetrad analysis, transformation, gene disruption, and determination of antibiotic sensitivity have been described (6,12). Meiotic progeny of diploid YFK016 (12) were mated to produce the yeast a/a diploid YFK419 (homozygous for ade2-101 his3-A200 leu2-Al lys2-801 trpl-Al, and ura3-52). R560-1C (MATa ade2-1 canl his3-11,15 leu2-3,112 trpl-l ura3-1 etgl-l) and MS14 (MATa etgl4) are spontaneous L-733,560-resistant (EchR) mutants derived from W303-1A (6) and X2180-1A (7), respectively. EchR mutants are resistant to drug on uracil DO medium at 8 ,g/ml, whereas the wild type is sensitive at 0.25 ,ug/ml. Heterozygous (etgl-l/+) strains exhibited intermediate resistance (Echl phenotype) and were resistant at 1 pg/ml but sensitive at 4 ug/ml.Cloning. A plasmid (pFF119) complementing Jksl-l was selected from a yeast genomic library of strain GRF88 (13) on uracil DO medium containing FK506 at 1 pg/ml. A library of genomic DNA (provided by S. Parent) from strain YFK093 (12) was constructed as described (14) by partial Sau3A1 digestion, partial fill-in of overhangs, and insertion of the fragments into the partially filled-in Sal I site of plasmid YEp24. The YFK093 library was introduced into strain R560-1C by the spheroplast transformation method, uracil
The lipopeptide antifungal agents, echinocandins, papulacandins, and pneumocandins, kill Candida albicans by inhibiting glucan synthesis. For this fungus, there is a good correlation of in vitro enzyme inhibition with in vitro assays of MICs. Semisynthetic lipopeptides such as cilofungin, LY303366,989,560 have activity in vivo against Aspergillus infections but appear to be inactive in broth dilution in vitro tests (MICs, > 128 ,ug/ml). To understand how compounds which lack activity in vitro can have good in vivo activity, we monitored the effect of pneumocandins on the morphology ofAspergillusf migatus and A. flavus strains by light microscopy and electron microscopy and related the changes in growth to inhibition of glucan synthesis.Pneumocandin Bo caused profound changes in hyphal growth; light micrographs showed abnormally swollen germ tubes, highly branched hyphal tips, and many cells with distended balloon shapes. Aspergillus electron micrographs confirmed that lipopeptides produce changes in cell walls; drug-treated germlings showed very stubby growth with thick walls and a conspicuous dark outer layer which was much thicker in the subapical regions. The rest of the hyphal tip ultrastructure was unaffected by the drug, indicating considerable specificity for the primary target. The drug-induced growth alteration produced very compact clumps in broth dilution wells, making it possible to score the morphological effect macroscopically. The morphological changes could be assayed quantitatively by using conventional broth microdilution susceptibility assay conditions. We defined the endpoint as the lowest concentration required to produce the morphological effect and called it the minimum effective concentration to distinguish it from the no-growth endpoints used in MIC determinations.The minimum effective concentration assay was related to inhibition of glucan synthase activity in vitro and may provide a starting point for development of susceptibility testing methods for lipopeptides.Echinocandins, pneumocandins, and papulacandins are antifungal agents which inhibit the synthesis of 1,3-p-D-glucan (22,39,43,44). ,B-Glucans are vital cell wall polymers in clinically important pathogenic fungi, including Candida and Aspergillus spp. (8). The proportion of this polysaccharide in the walls of different organisms varies, but at least 10% of the dry weight of the walls of these organisms is in the form of 1,3-p-D-glucan (4). This polysaccharide is synthesized by a membrane-associated activity which has been partially characterized in yeasts such as Candida albicans and Saccharomyces cerevisiae (31,40,46). The enzyme uses UDP-glucose as a substrate and catalyzes the polymerization of a linear polymer of 1,3-p-D-glucan reported to be 60 U (40) or as much as 700 U (35) long. The Km for UDP-glucose is approximately 2 mM, and the reaction is stimulated by nucleoside triphosphates, particularly GTP (31, 42). For both C. albicans and S. cerevisiae, the in vitro product, which is synthesized without a requirement for ...
The primary structure of human C1 inhibitor was determined by peptide and DNA sequencing. The single-chain polypeptide moiety of the intact inhibitor is 478 residues (52,869 Da), accounting for only 51% of the apparent molecular mass of the circulating protein (104,000 Da). The positions of six glucosamine-based and five galactosamine-based oligosaccharides were determined. Another nine threonine residues are probably also glycosylated. Most of the carbohydrate prosthetic groups (probably 17) are located at the amino-terminal end (residues 1-120) of the protein and are particularly concentrated in a region where the tetrapeptide sequence Glx-Pro-Thr-Thr, and variants thereof, is repeated 7 times. No phosphate was detected in C1 inhibitor. Two disulfide bridges connect cysteine-101 to cysteine-406 and cysteine-108 to cysteine-183. Comparison of the amino acid and cDNA sequences indicates that secretion is mediated by a 22-residue signal peptide and that further proteolytic processing does not occur. C1 inhibitor is a member of the large serine protease inhibitor (serpin) gene family. The homology concerns residues 120 through the C-terminus. The sequence was compared with those of nine other serpins, and conserved and nonconserved regions correlated with elements in the tertiary structure of alpha 1-antitrypsin. The C1 inhibitor gene maps to chromosome 11, p11.2-q13. C1 inhibitor genes of patients from four hereditary angioneurotic edema kindreds do not have obvious deletions or rearrangements in the C1 inhibitor locus. A HgiAI DNA polymorphism, identified following the observation of sequence variants, will be useful as a linkage marker in studies of mutant C1 inhibitor genes.
Pneumocandins and echinocandins are fungicidal antibiotics, currently in clinical development, that inhibit 1,3-beta-D-glucan synthase (GS) in several human fungal pathogens. We have identified a gene from the diploid organism Candida albicans that encodes a target of these inhibitors. A 2.1-kb portion of this gene, designated CaFKS1, has significant homology to the Saccharomyces cerevisiae FKS1 and FKS2 genes, which encode partially functionally redundant subunits of GS. To evaluate the role of CaFkslp in susceptibility to echinocandins, we disrupted CaFKS1 on one homolog each of the spontaneous pneumocandin-resistant C. albicans mutants CAI4R1, NR2, NR3, and NR4. These mutants had been selected previously on agar plates containing the pneumocandin L-733,560. The clones derived from this transformation were either resistant (Ech[r]) or fully sensitive (Ech[s]) to inhibition by L-733,560 in both liquid broth microdilution and in vitro GS assays. The site of plasmid insertion in the transformants was mapped by Southern blot analysis, using restriction site polymorphisms in the CaFKS1 gene to distinguish between the two alleles (designated CaFKS1h and CaFKS1b). For strains CAI4R1 and NR2, the CaFKS1b allele was disrupted in each Ech(r) transformant; for strain NR4, CaFKS1h was disrupted in each Ech(r) transformant. We conclude that (i) strains CAI4R1, NR2, and NR4 are heterozygous for a dominant or semidominant pneumocandin resistance mutation at CaFKS1, (ii) drug resistance mutations can occur in either CaFKS1 allele, and (iii) CaFks1p is a target of the echinocandins. For transformants of strain NR3, all the clones we analyzed were uniformly Ech(r), and only the CaFKS1h allele, either in disrupted or wild-type form, was detected on genomic Southern blots. We believe gene conversion at the CaFKS1 locus may have produced two Cafks1h alleles that each contain an Ech(r) mutation. Transformants derived from the mutants were analyzed for susceptibility to pneumocandin treatment in a mouse model of disseminated candidiasis. Strains heterozygous for the resistant allele (i.e., C. albicans CAI4R1, NR2, and NR4) were moderately resistant to treatment, while strains without a functional Ech(s) allele (i.e., strain NR3 and derivatives of strain CAI4R1 with the disruption plasmid integrated in the Ech[s] allele) displayed strong in vivo echinocandin resistance. Finally, we were unable to inactivate both alleles at CaFKS1 by two-step integrative disruption, suggesting that CaFks1p is likely to be an essential protein in C. albicans.
A novel, potent, semisynthetic pneumocandin, L-733,560, was Chem. 37:222-225, 1994). Glucan synthesis catalyzed by a crude membrane fraction prepared from the S. cerevisiae mutant R560-1C was resistant to inhibition by L-733,560. The nearly 50-fold increase in the 50% inhibitory concentration against glucan synthase was commensurate with the increase in whole-cell resistance. R560-1C was cross-resistant to other inhibitors of C. albicans 1,3-p-D-glucan synthase (aculeacin A, dihydropapulacandin, and others) but not to compounds with different modes of action. Genetic analysis revealed that enzyme and whole-cell pneumocandin resistance was due to a single mutant gene, designated etgl-l (echinocandin target gene 1), which was semidominant in heterozygous diploids. The etgl-l mutation did not confer enhanced ability to metabolize L-733,560 and had no effect on the membrane-bound enzymes chitin synthase I and squalene synthase. Alkali-soluble (B-glucan synthesized by crude microsomes from R560-1C was indistinguishable from the wild-type product. 1,3-I-D-Glucan synthase activity from R560-1C was fractionated with NaCl and Tergitol NP-40; reconstitution with fractions from wild-type membranes revealed that drug resistance is associated with the insoluble membrane fraction. We propose that the etgl-l mutant gene encodes a subunit of the 1,3-0-D-glucan synthase complex.
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