1,3--D-Glucan is a major structural polymer of yeast and fungal cell walls and is synthesized from UDP-glucose by the multisubunit enzyme 1,3--D-glucan synthase. Previous work has shown that the FKS1 gene encodes a 215-kDa integral membrane protein (Fks1p) which mediates sensitivity to the echinocandin class of antifungal glucan synthase inhibitors and is a subunit of this enzyme. We have cloned and sequenced FKS2, a homolog of FKS1 encoding a 217-kDa integral membrane protein (Fks2p) which is 88% identical to Fks1p. The residual glucan synthase activity present in strains with deletions of fks1 is (i) immunodepleted by antibodies prepared against FKS2 peptides, demonstrating that Fks2p is also a component of the enzyme, and (ii) more sensitive to the echinocandin L-733,560, explaining the increased sensitivity of fks1 null mutants to this drug. Simultaneous disruption of FKS1 and FKS2 is lethal, suggesting that Fks1p and Fks2p are alternative subunits with essential overlapping function. Analysis of FKS1 and FKS2 expression reveals that transcription of FKS1 is regulated in the cell cycle and predominates during growth on glucose, while FKS2 is expressed in the absence of glucose. FKS2 is essential for sporulation, a process which occurs during nutritional starvation. FKS2 is induced by the addition of Ca 2؉ to the growth medium, and this induction is completely dependent on the Ca 2؉ /calmodulin-dependent phosphoprotein phosphatase calcineurin. We have previously shown that growth of fks1 null mutants is highly sensitive to the calcineurin inhibitors FK506 and cyclosporin A. Expression of FKS2 from the heterologous ADH1 promoter results in FK506-resistant growth. Thus, the sensitivity of fks1 mutants to these drugs can be explained by the calcineurin-dependent transcription of FKS2. Moreover, FKS2 is also highly induced in response to pheromone in a calcineurin-dependent manner, suggesting that FKS2 may also play a role in the remodeling of the cell wall during the mating process.The cell wall of Saccharomyces cerevisiae is essential for the integrity and shape of the cell and is a highly dynamic structure the composition and architecture of which vary widely depending upon the composition of the growth medium and the stage of the cell cycle (41). In addition, when haploid cells encounter pheromone of the opposite mating type, the cells transiently arrest in the G 1 phase of the cell cycle and develop an elongated projection requiring new cell wall synthesis (12). Furthermore, diploid cells which are nutritionally starved undergo meiosis and sporulation, a process requiring the formation of new cell wall around the developing spores (reviewed in reference 42).An important component of each of these cell wall types is the glucose polymer 1,3--D-glucan (10, 38, 41). 1,3--D-Glucan synthase (UDP-glucose:1,3--D-glucan 3--D-glucosyltransferase; EC 2.4.1.34) is a membrane enzyme activated by GTP which has been fractionated into soluble (GTP-binding) and membrane-bound (catalytic) components (39, 53). Members of...
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
In the yeast Saccharomyces cerevisiae, the family of RHO genes are implicated in the control of morphogenetic events although the molecular targets of these GTP-binding proteins remain largely unknown. The activity of 1,3-beta-D-glucan synthase, the product of which is essential for cell wall integrity, is regulated by a GTP-binding protein, which we here present evidence to be Rho1p. Rho1p was found to copurify with Fks1p, a glucan synthase subunit, in preparations of the enzyme purified by product entrapment and was also shown to be depleted by a detergent extraction procedure known to remove the GTP-binding regulatory component. Specific ADP-ribosylation of Rho1p by exoenzyme C3 inactivates glucan synthase activity specified by FKS1 and FKS2 as demonstrated in membrane preparations from fks2 and fks1 deletion strains, respectively, and in the purified enzyme containing Fks1p. Rho1p and Fks1p were co-immunoprecipitated from purified glucan synthase under conditions that maintained enzyme activity in the immunoprecipitate. Putative Rho homologs were also identified and implicated in the regulation of glucan synthase activity from Candida albicans, Aspergillus nidulans, and Cryptococcus neoformans by ribosylation studies. The regulation of 1,3-beta-D-glucan synthase activity by RHO1 is consistent with its observed role in morphogenetic control and osmotic integrity.
Deletion of GAS1/GGP1/CWH52 results in a lower β-glucan content of the cell wall and swollen, more spherical cells (L. Popolo, M. Vai, E. Gatti, S. Porello, P. Bonfante, R. Balestrini, and L. Alberghina, J. Bacteriol. 175:1879–1885, 1993; A. F. J. Ram, S. S. C. Brekelmans, L. J. W. M. Oehlen, and F. M. Klis, FEBS Lett. 358:165–170, 1995). We show here that gas1Δ cells release β1,3-glucan into the medium. Western analysis of the medium proteins with β1,3-glucan- and β1,6-glucan-specific antibodies showed further that at least some of the released β1,3-glucan was linked to protein as part of a β1,3-glucan–β1,6-glucan–protein complex. These data indicate that Gas1p might play a role in the retention of β1,3-glucan and/or β-glucosylated proteins. Interestingly, the defective incorporation of β1,3-glucan in the cell wall was accompanied by an increase in chitin and mannan content in the cell wall, an enhanced expression of cell wall protein 1 (Cwp1p), and an increase in β1,3-glucan synthase activity, probably caused by the induced expression of Fks2p. It is proposed that the cell wall weakening caused by the loss of Gas1p induces a set of compensatory reactions to ensure cell integrity.
Phoborhodopsin, a repellent phototaxis receptor in Halobacterium halobium, exhibits vibrational fine structure, a feature that has not been identified for any other rhodopsin pigment at physiological temperatures. This conclusion follows form analysis of the absorption properties of the pigment in H. halobium membranes containing native retinal and an array of retinal analogues. The absorption spectrum of the native pigment has a maximum at 487 nm with a pronounced shoulder at 460 nm; however, the bandwidth is that expected for a single retinylidene species. Gaussian band-shape simulation with a spacing corresponding to the vibrational frequencies of polyene stretching modes reproduces the structured absorption spectra of native pigment as well as of analogue phoborhodopsin. Absorption shifts produced by a series of dihydroretinal and other retinal analogues strongly indicate that the dominant factor regulating the color of the pigment is planarization of the retinal ring with respect to the polyene chain.
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