Rustmicin, a Potent Antifungal Agent, Inhibits Sphingolipid Synthesis at Inositol Phosphoceramide Synthase*

Suzanne M. MandalaDagger , Rosemary A. Thornton, James Milligan, Mark Rosenbach, Margarita Garcia-Calvo, Herbert G. Bull, Guy Harris, George K. Abruzzo, Amy M. Flattery, Charles J. Gill, Kenneth Bartizal, Sarah Dreikorn, and Myra B. Kurtz

From the Department of Biochemistry, Merck Research Laboratories, Rahway, New Jersey 07065

    ABSTRACT
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Abstract
Introduction
Procedures
Results
Discussion
References

Rustmicin is a 14-membered macrolide previously identified as an inhibitor of plant pathogenic fungi by a mechanism that was not defined. We discovered that rustmicin inhibits inositol phosphoceramide synthase, resulting in the accumulation of ceramide and the loss of all of the complex sphingolipids. Rustmicin has potent fungicidal activity against clinically important human pathogens that is correlated with its sphingolipid inhibition. It is especially potent against Cryptococcus neoformans, where it inhibits growth and sphingolipid synthesis at concentrations <1 ng/ml and inhibits the enzyme with an IC50 of 70 pM. This inhibition of the membrane-bound enzyme is reversible; moreover, rustmicin is nearly equipotent against the solubilized enzyme. Rustmicin was efficacious in a mouse model for cryptococcosis, but it was less active than predicted from its in vitro potency against this pathogen. Stability and drug efflux were identified as two factors limiting rustmicin's activity. In the presence of serum, rustmicin rapidly epimerizes at the C-2 position and is converted to a gamma -lactone, a product that is devoid of activity. Rustmicin was also found to be a remarkably good substrate for the Saccharomyces cerevisiae multidrug efflux pump encoded by PDR5.

    INTRODUCTION
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Abstract
Introduction
Procedures
Results
Discussion
References

Cryptococcus neoformans is a basidiomycetous fungus that infects immunocompromised patients, initiating in the lungs and migrating to the central nervous system, where it results in meningoencephalitis. Over 80% of cryptococcosis cases are found in advanced stage human immunodeficiency virus patients, and C. neoformans is one of the most common opportunistic infections in this population. In recent years, the incidence has declined (1, 2). The decline has been attributed to the widespread use of fluconazole, a fungistatic agent that is effective but requires lifelong suppressive therapy to prevent relapse in AIDS patients. Fluconazole has also been used successfully to treat fungal infections caused by Candida albicans and other Candida species, but a worrisome development is the emergence of species that are intrinsically resistant to azoles, such as Candida glabrata and Candida krusei, as well as the appearance of a variety of Candida isolates that have acquired resistance. Aspergillus and Fusarium species are mycelial fungi that are also relatively resistant to fluconazole; these pathogens are particularly aggressive and the incidence of mortality from aspergillosis is very high (2). Increased use of prophylactic antifungal therapy will probably exacerbate the resistance problem; thus, new treatments are urgently needed.

We have been investigating the sphingolipid pathway as a novel target for antifungal therapy. Serine palmitoyltransferase, the first committed enzyme of sphingolipid synthesis in mammalian and fungal cells, condenses serine and palmitoyl-CoA to form the long chain sphingoid base, ketodihydrosphingosine. Several structurally diverse natural product inhibitors of this enzyme with antifungal activity have been discovered including sphingofungins (3, 4), myriocin (5), lipoxamycins (6), and viridiofungins (7). Ketodihydrosphingosine is reduced to dihydrosphingosine and can be further modified to phytosphingosine in fungi and sphingosine in mammals. Desaturation of the sphingoid base to sphingosine takes place after condensation with a fatty acyl-CoA to form ceramide (8), whereas phytosphingosine synthesis probably occurs before acylation, based on the accumulation of phytosphingosine that occurs when ceramide synthesis is inhibited (9, 10). Two classes of natural product inhibitors of ceramide synthase have been described: fumonisins (11) and australifungin (9). The fumonisins are mycotoxins isolated for their tumor promoting activity (12); they cause profound effects on mammalian cells that have been attributed to inhibition of ceramide synthesis and the concomitant accumulation of sphingoid bases (13). Fumonisin B1 has relatively poor whole cell activity against fungi, although it inhibits C. albicans ceramide synthase in vitro. In contrast, australifungin has potent, broad spectrum antifungal activity (9), but little is known about its proliferative or toxic effect on mammalian cells, although it is known to inhibit ceramide synthesis in HepG2 cells (14).

Most of the ceramide and sphingoid bases in cells are not free but instead are found in complex lipids. In fungi, phosphoinositol is transferred from glycerophosphatidylinositol to the C-1 hydroxyl of ceramide to make inositol phosphoceramide (IPC).1 IPC is further modified by the addition of mannose and a second inositol phosphate group to make mannosyl inositol phosphoceramide and mannosyl diinositol diphosphoceramide (15). In mammalian cells, the only phosphosphingolipid is sphingomyelin, which contains phosphocholine at the C-1 hydroxyl of ceramide. There is, however, an enormous class of glycosylated sphingolipids containing a variety of complex modifications of the carbohydrate moiety. Some fungi, including pathogenic species of Aspergillus, have been reported to make glycosphingolipids (16), but the major sphingolipids of C. albicans and C. neoformans have the phosphoinositol moiety (15, 17). Recently, two antifungal agents that inhibit inositol phosphoceramide synthase were described, aureobasidin A1 (18) and khafrefungin (14). Khafrefungin was found to be selective at inhibiting sphingolipid synthesis in fungi, whereas compounds that affect earlier steps in the pathway also inhibit mammalian enzymes.

During the course of our studies on inhibitors of sphingolipid synthesis, we discovered that rustmicin selectively inhibits fungal sphingolipid synthesis. Rustmicin is a macrolide antifungal agent that was isolated over 10 years ago by two independent groups. It was isolated from fermentations of Micromonospora chalcea and named rustmicin for its activity against wheat stem rust fungus (Puccinia graminis) (19). Almost simultaneously, the same structural compound was reported as galbonolide A from Streptomyces galbus culture broths, with potent activity against Botrytis cinerea and several other phytopathogens (20, 21). Mode of action studies indicated that rustmicin did not destabilize the membrane or inhibit the synthesis of chitin, DNA, or RNA, but the mechanism of fungal growth inhibition was not determined (22). We have discovered that rustmicin has extraordinarily potent antifungal activity against several human pathogens, especially C. neoformans. Moreover, its antifungal activity is due to inhibition of sphingolipid synthesis at the IPC synthase, where rustmicin demonstrates inhibition at picomolar levels. The sphingolipid inhibitory activity and the in vitro and in vivo antifungal activity of rustmicin are presented in this paper.

    EXPERIMENTAL PROCEDURES
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Abstract
Introduction
Procedures
Results
Discussion
References

Strains, Inhibitors, and Reagents-- Saccharomyces cerevisiae W303-1A (MATa, ade2-1 can1-100 his3-11, 15 leu2-3, 112 trp1-1 ura3-1) was provided by R. Rothstein (23). C. albicans MY1055, C. neoformans MY2062, and other fungal pathogens were obtained from the Merck Culture Collection (Rahway, NJ). For in vitro assays, C. neoformans strain Cap64 (ATCC52816) was used. The pdr5:Tn5 and pdr1-3 mutants were the generous gift of J. Golin (24). A. Rosegay, Y. S. Tang, and A. Jones (Merck Research Laboratories) synthesized N-stearoyl-D-[4,5-3H]dihydrosphingosine ([3H]ceramide) by reduction of N-stearoyl-D-sphingosine with NaBT4 in ethanolic NiCl2.2 The product was purified by HPLC on a C18 column with a gradient of 90:10 acetonitrile/ethanol changing to 60:40 acetonitrile/ethanol over 30 min at 1 ml/min, and had a specific activity of 28 Ci/mmol.

Sphingolipid and IPC Synthesis-- Sphingolipid synthesis and in vitro IPC synthase were measured as described previously (14). Briefly, fungal cells were labeled with [3H]inositol in microtiter plates, and counts incorporated into sphingolipids and phosphatidylinositol (PI) were distinguished by alkaline methanolysis. Unless indicated otherwise, in vitro IPC synthase activity was measured in 100-µl reactions containing 50 mM Tris-HCl, pH 7.0, 50 mM KCl, 0.25% sodium cholate, 5 µg of fungal microsomal membrane protein, 25 µM PI, and trace N-stearoyl-D-4,5-[3H]dihydrosphingosine. Production of [3H]IPC was quantitated after anion exchange chromatography. Enzymatic activity was expressed as the percentage of incorporation of trace [3H]ceramide into IPC during the assay period and was independent of the amount of radioactivity employed.

Solubilization of IPC Synthase-- The enzyme was solubilized from membrane fractions of C. neoformans using the nonionic detergent Triton X-100. Briefly, membranes (1-2 mg of protein/ml) were incubated at room temperature for 30-60 min in 50 mM Tris-HCl buffer containing 50 mM KCl, 1 mM PI, and 0.5-1.0% (w/v) Triton X-100 at pH 7.0. After centrifugation at 150,000 × g for 1 h at 4 °C, the supernatant was employed as the source of the solubilized IPC synthase and assayed for enzymatic activity. The supernatant contained approximately 70-80% of the total protein and nearly 100% of the IPC synthase activity. Results for a typical experiment are shown in Fig. 3B.

In Vitro Antifungal Assays-- Minimum inhibitory concentrations (MICs) were determined by microtiter broth dilution assay in Difco yeast nitrogen base medium containing 2% glucose (YNBD) with fungi inoculated at 1 × 104 yeast cells or conidia/ml. Serial 2-fold dilutions of inhibitors were made from 32 µg/ml; the MIC value was the lowest concentration of inhibitor that prevented visible growth after 24 h at 37 °C (48 h for C. neoformans strains). Growth inhibition assays with S. cerevisiae mutants were conducted in YNBD medium containing 0.078% complete supplement mixture (Bio 101). Absorbance readings were obtained using an SLT 340 ATTC (Tecan Instruments) after 48 h of growth at 30 °C. Cell viability was measured by incubating cells (2 × 104 cells/ml) in YNBD with 32 ng/ml rustmicin, 128 ng/ml rustmicin, or 10 µg/ml amphotericin B in culture tubes. Higher concentrations of rustmicin are required to inhibit fungal growth in culture tubes compared with microtiter plates, and the levels used are equivalent to 1 times (32 ng/ml) and 4 times (128 ng/ml) the MIC. Aliquots of 0.1 ml were removed periodically, diluted, and plated onto YNBD agar. Colony-forming units (CFU) were enumerated after 48 h growth at 30 °C.

In Vivo Cryptococcosis Assay-- DBA/2N mice were infected by intravenous inoculation with approximately one LD50 of C. neoformans MY2061 (1 × 106 cells/mouse). Therapy was initiated within 15 min after challenge, and the mice were treated for a total of 4 days. At 7 days after challenge, brains and spleens were harvested, and CFU were determined as described (25). Rustmicin was solubilized in 5% ethanol, 20% polyethylene glycol and dosed intraperitoneally twice daily. Amphotericin B (0.31 mg/kg) was administered intraperitoneally once daily. Five mice per treatment group were tested. All procedures were performed in accordance with the highest standards for the humane handling, care, and treatment of research animals and were approved by the Merck Institutional Animal Care and Use Committee.

Rustmicin Stability-- Rustmicin was diluted to 100 µg/ml with buffer, 5% (v/v) methanol and incubated at 37 °C. Buffers used were sodium citrate (pH 3.0 or pH 5.5), potassium phosphate (pH 7.0), or sodium borate (pH 9.0). Samples were removed at selected times and extracted with heptane. The organic layer was dried under nitrogen, resuspended in 50% methanol, and analyzed for antifungal activity by agar diffusion assay and rustmicin concentration by reverse phase HPLC. To examine the effect of plasma, 200 µg/ml rustmicin was incubated at 37 °C in 50 mM potassium phosphate, pH 7.2, 10% (v/v) methanol in the presence or absence of 50% fresh mouse plasma. Samples were removed and diluted with 3 volumes of acetonitrile. After 15 min on ice, precipitated plasma proteins were removed by centrifugation. For bioassay, 10-µl samples were dropped onto the surface of Sabouraud dextrose agar (Difco) plates seeded with Cryptococcus albidus (MY129) at 1 × 105 cells/ml. Plates were incubated at 25 °C for 24 h, and zones of inhibition were measured and compared with a dilution series standard. The assay gave a linear curve fit of log(rustmicin) versus zone diameter for the range of 50-0.4 ng. For HPLC analysis, samples were applied to a Phenomenex Primesphere C8 column (4.6 × 250 mm) and eluted with a mobile phase of methanol, 25 mM NH4OAc (75:25); a flow rate of 1.0 ml/min; and a column temperature of 40 °C. UV detection was performed at 235 nM. Rustmicin, L-760,262, and L-770,715 eluted at 12.4, 13.7, and 4.4 min, respectively. Degradation products were identified by co-migration with authentic standards, prepared by Regina Black (Merck Research Laboratories).

    RESULTS
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Abstract
Introduction
Procedures
Results
Discussion
References

Sphingolipid Inhibition by Rustmicin-- An actinomycete culture broth was found to have potent inhibitory activity against fungal sphingolipid synthesis. With the exception of lipoxamycin, an inhibitor of the first enzyme in sphingolipid synthesis, all other natural product inhibitors of sphingolipid synthesis have been produced by fungi, thus making this novel actinomycete activity of interest. Isolation of the sphingolipid inhibitor and determination of its structure3 resulted in the identification of the 14-membered macrolide known as rustmicin (19) or galbonolide A (20). The absolute stereochemistry was determined by chemical methods (27), and the structures of rustmicin and its degradation products are shown in Fig. 1.


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Fig. 1.   Structures of rustmicin and degradation products. Structures shown are rustmicin, L-760,262 (C-2 epimer of rustmicin), and L-770,715 (translactonized rustmicin).

Rustmicin inhibited inositol incorporation into sphingolipids of C. albicans with an IC50 of 25 ng/ml, but did not inhibit inositol incorporation into PI (Fig. 2A). Comparison of its potency against other fungi revealed that rustmicin inhibited sphingolipid synthesis in S. cerevisiae at a similar concentration (IC50 of 30 ng/ml) as C. albicans but was extraordinarily potent against C. neoformans (IC50 of 0.2 ng/ml) (Fig. 2B). When tested in in vitro enzyme assays, rustmicin did not inhibit two enzymes early in the sphingolipid biosynthetic pathway, serine palmitoyltransferase and ceramide synthase, but was a very potent inhibitor of IPC synthase. Labeling studies with sphingolipid precursors confirmed that IPC synthase was the step in the sphingolipid pathway inhibited by rustmicin, since the inhibitor caused the accumulation of hydroxyceramide (data not shown), the same lipid intermediate that was previously seen upon khafrefungin treatment (14).


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Fig. 2.   Rustmicin inhibits [3H]inositol incorporation in sphingolipids but not PI. A, C. albicans was labeled with [3H]inositol in microtiter dishes containing rustmicin, and counts incorporated into PI (square ) were distinguished from sphingolipids (bullet ) by their sensitivity to alkaline methanolysis. B, [3H]inositol incorporation into sphingolipids of C. neoformans (triangle ), C. albicans (bullet ), and S. cerevisiae (square ) was measured as a function of rustmicin concentration and expressed as a percentage of solvent control. S.E. values are shown.

IPC Synthase Inhibition by Rustmicin-- The enzyme was assayed in microsomal membrane preparations by measuring incorporation of trace [3H]ceramide into [3H]IPC, as described previously (14). Cholate and exogenous PI were employed in the assay because they markedly enhanced the reaction, which was particularly slow for C. neoformans. Omission of these components had little influence on the potency of inhibitors. As shown in the titrations of Fig. 3A, rustmicin has an IC50 of 70 pM against IPC synthase from the most sensitive organism, C. neoformans, and is a low nanomolar inhibitor of enzymes from C. albicans and S. cerevisiae. Washing the membranes several times by centrifugation to remove inhibitor returned nearly all the enzymatic activity, indicating that rustmicin is a reversible inhibitor. These potencies against the enzyme correlate reasonably well with inhibition of sphingolipid synthesis in intact cells, the whole cell activity requiring 5-15-fold more inhibitor than the in vitro enzyme assay. These results are compared in Table I.


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Fig. 3.   IPC synthase inhibition by rustmicin. A, inhibition of membrane-bound enzymes. Membranes (50 µg of protein/ml) prepared from C. neoformans (bullet ), C. albicans (black-square), and S. cerevisae (black-triangle) were incubated at room temperature for 60 min with [3H]ceramide (0.18 µCi/ml), 25 µM exogenous PI, 0.25% sodium cholate, and varying concentrations of rustmicin. The dotted lines are theoretical for fits to the equation y = A/(1 + (x/C)B), where A is the maximum velocity in the absence of inhibitor, B is the apparent Hill coefficient, and C represents the calculated IC50. B, solubilization of IPC synthase from C. neoformans. The enzyme was solubilized as described in detail under "Experimental Procedures." After centrifugation, different amounts of the supernatant (bullet ), the particulate fraction (black-triangle), and control membranes (open circle ) were assayed for IPC synthase activity. In all cases, the assays were adjusted to contain constant Triton X-100 (0.06%) and exogenous PI (170 µM). The plot shows that the assay is linear in protein concentration and that the recovery of IPC synthase activity is nearly quantitative. C, inhibition of the soluble C. neoformans enzyme. Soluble extracts were assayed at a final concentration of 65 µg protein/ml in the presence of several concentrations of rustmicin, as described above. The reaction mixtures contained constant concentrations of Triton X-100 (0.04%) and exogenous PI (65 µM). The theoretical line corresponds to an IC50 of 170 pM.

                              
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Table I
Rustmicin concentration for 50% inhibition of sphingolipid synthesis and in vitro IPC synthase

To better understand the inhibition by rustmicin, some effort was directed toward solubilization of the enzyme. Using C. neoformans as the enzyme source, three detergents were examined in detail: cholate, diheptanoylphosphatidylcholine, and Triton X-100. When employed at 1% concentration, cholate and diheptanoylphosphatidylcholine solubilized more than half of the membrane protein, but most of the IPC synthase activity remained in the pellet. In contrast, Triton X-100 appeared powerful enough to solubilize the enzyme, but little activity was recovered from either phase upon dilution to detergent levels (<0.1%) tolerated in the assay. Pursing this detergent further, it was found that including 1 mM PI during the solubilization dramatically improved results and led to nearly complete recovery of the enzyme in the supernatant (Fig. 3B).

Rustmicin is nearly as potent an inhibitor of the solubilized enzyme from C. neoformans, for which it has an IC50 of 170 pM, as compared with 70 pM against the membrane-bound form. Titration data against the membrane-bound and solubilized enzyme are shown in Fig. 3, A and C, respectively. This confirms the notion that rustmicin binds specifically to IPC synthase and that inhibition is unrelated to possible effects on the membrane environment of the enzyme.

Antifungal Activity of Rustmicin-- Following its discovery over 10 years ago as an inhibitor of phytopathogens, rustmicin was tested for antifungal activity against an extensive list of fungi, primarily plant pathogens, and found to have MIC values of 0.1 µg/ml to >1 mg/ml (21, 22). A few human pathogens were tested, including C. albicans, which had an MIC of 3 µg/ml, and Aspergillus fumigatus, which was insensitive to rustmicin. The advent of AIDS and the emergence of azole-resistant fungi have changed the clinical spectrum of organisms in recent years, so we evaluated rustmicin for inhibitory activity against a current panel of human pathogenic fungi. Table II shows that rustmicin was extremely potent against C. neoformans, with MIC values of 0.1-1 ng/ml against various strains, which are values similar to the compound's sphingolipid inhibitory activity. Several Candida species, including C. krusei, were highly sensitive to rustmicin (MIC 0.015-0.031 µg/ml), while C. albicans was moderately sensitive and A. fumigatus was not inhibited by rustmicin, in agreement with previous studies.

                              
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Table II
Antifungal activity of rustmicin by microbroth dilution assay

Rustmicin was fungicidal; a time course of inhibitor treatment shows that C. neoformans grew for several generations before being killed (Fig. 4), and similar results were obtained with S. cerevisiae (data not shown). This time course for fungicidal activity is consistent with other inhibitors of biosynthetic pathways, including sphingofungin B (3) and contrasts with a membrane active agent such as amphotericin B that causes rapid cell leakage (Fig. 4). Loss in viability with rustmicin treatment was only seen in actively growing cultures (data not shown).


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Fig. 4.   Rustmicin is fungicidal. C. neoformans was incubated with rustmicin at 32 ng/ml (black-square) or 128 ng/ml (square ), amphotericin B at 10 µg/ml (black-triangle), or solvent (open circle ). Viability was measured by plating diluted samples and enumerating CFU.

In Vivo Antifungal Activity-- The extraordinarily potent inhibition of C. neoformans led us to evaluate the efficacy of rustmicin in a mouse model for cryptococcosis. Fig. 5 shows that rustmicin treatment produced a dose-dependent reduction in colony-forming units isolated from spleen and brain tissue of mice infected with C. neoformans. The ED99 levels were calculated to be 29 mg/kg for both tissues. In another experiment in which compounds were suspended in olive oil to overcome solubility limitations and dosed at 100 mg/kg, rustmicin gave 100% sterilization of brains and spleen. Although encouraging, the level of in vivo efficacy is far less than expected from the in vitro susceptibility of this organism to rustmicin. Amphotericin B, which has an MIC against C. neoformans that is 1000-fold higher than rustmicin, was fully effective in the mouse cryptococcosis model at 0.31 mg/kg (Fig. 5). We therefore undertook an analysis of some of the factors limiting the in vivo activity of rustmicin.


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Fig. 5.   Efficacy of rustmicin against C. neoformans in DBA/2N mice. Infected mice were treated with rustmicin at 80 (black-square), 40 (), 20 (), 10 (), or 0 (square ) mg/kg for 4 days, and CFU were enumerated from extracted brain and spleens 7 days after inoculation. Amphotericin B (AmB) () treated control is shown.

Stability of Rustmicin-- When originally isolated, fermentation extracts containing galbonolide A were found to be unstable, and several chemical degradative pathways were elucidated (22). The enol ether moiety was susceptible to acid treatment, whereas alkaline reagents caused epimerization at the C-2 position and conversion of the macrolactone to a gamma -lactone (see Fig. 1). Using antifungal activity against C. albidus as a bioassay and HPLC analysis to monitor chemical stability, we tested whether degradation of rustmicin was a limitation for in vivo efficacy. In agreement with the previous study, we found that rustmicin decomposed within minutes in alkaline or acidic buffer, with loss of all bioactivity (Fig. 6, A and B). The half-life of the compound at neutral pH was approximately 80 min, and the best stability was found at pH 5.5. 


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Fig. 6.   Stability of rustmicin. Rustmicin was incubated over time at pH 3.0 (black-square), 5.5 (square ), 7.0 (bullet ), or 9.0 (open circle ), and aliquots were removed and analyzed for antifungal activity (A) or residual rustmicin concentration by HPLC (B).

The effect of 50% whole mouse serum on rustmicin stability and activity was tested to better represent the in vivo condition. In the presence of serum, the rate of inactivation was accelerated (Fig. 7A), and two degradation products were found (Fig. 7B). The C-2 epimer (L-760,262) appeared rapidly and then was also degraded, while the product that accumulated in direct proportion to rustmicin disappearance was the translactonized compound (L-770,715). The same products were formed in the absence of serum, indicating that these are due to the chemical instability of rustmicin. Analysis of the bioactivity of the degradation products showed that epimerization resulted in a 60-80-fold loss in potency of inhibiting sphingolipid synthesis in C. neoformans and C. albicans, while the gamma -lactone was completely inactive (Table III). Thus, poor in vivo efficacy in animals is probably due to a great extent to the rapid conversion of rustmicin to the inactive gamma -lactone.


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Fig. 7.   Serum effects on stability of rustmicin. Rustmicin was incubated in the presence (bullet ) or absence (open circle ) of 50% fresh mouse serum in pH 7.2 buffer, and antifungal activity was measured (A). Concentrations of rustmicin (bullet ) and its degradation products, L-760,262 (square ) and L-770,715 (triangle ) were measured by HPLC analysis of the serum-containing samples (B).

                              
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Table III
Concentration of rustmicin and degradation products for 50% inhibition of sphingolipid synthesis

Resistance to Rustmicin-- Multidrug efflux pumps eliminate structurally diverse inhibitors from mammalian and fungal cells, and many gene products that participate in drug transport or regulation of the transporters have been identified in S. cerevisiae (28). We used two S. cerevisiae mutants, pdr5:Tn5 and pdr1-3, to evaluate the role of multidrug resistance in rustmicin's potency. Pdr5p is one of the major ATP binding cassette efflux pumps, and disruption causes hypersensitivity to many antifungals, while pdr1-3 is a mutation in a transcriptional regulator that increases expression of PDR5 and other genes and results in resistance to many inhibitors (24, 28). In MIC tests with cycloheximide, a substrate for Pdr5p, the pdr5 null mutant was 8-fold more sensitive, and pdr1-3 was 2-fold more resistant than the control strain (Fig. 8A). Several other inhibitors that we tested, including fluconazole, mevinolin, anisomycin, and rustmicin, also showed the same profile of sensitivity and resistance, but rustmicin was unique in its extreme differential in activity; pdr5:Tn5 was 256-fold more sensitive and pdr1-3 was 8-16-fold more resistant than the wild-type strain (Fig. 8B). The increased susceptibility of the pdr5 null strain brings the potency of rustmicin as an antifungal agent (MIC = 8 ng/ml) down to the level of IPC synthase inhibition (IC50 = 7 ng/ml), suggesting that Pdr5p is the major barrier limiting the whole cell activity of rustmicin in S. cerevisiae.


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Fig. 8.   Antifungal activity in multidrug efflux mutants of S. cerevisiae. Growth inhibition in a microbroth dilution assay by cycloheximide (A) or rustmicin (B) was measured in mutants pdr1-3 (bullet ) and pdr5:Tn5 (black-square), and compared with wild type (square ). The wild-type strain shown is isogenic to pdr1-3, but similar results were obtained with W303-1A and the isogenic wild-type of pdr5:Tn5 .

    DISCUSSION
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Abstract
Introduction
Procedures
Results
Discussion
References

Sphingolipids comprise a small but essential fraction of fungal phospholipids. Differences between mammalian and fungal sphingolipid biosynthesis, especially at later steps in the pathway, make this an attractive new target for antifungal therapy. Many natural products have been discovered as inhibitors of sphingolipid biosynthesis; these compounds, which are primarily produced by fungi, have potent, fungicidal activity against a broad spectrum of clinical pathogens (3-7, 9, 14, 29). Our studies in this area led to the rediscovery3 of an actinomycete product known as rustmicin or galbonolide A (19, 20, 22). This compound is a 14-membered macrolide, previously isolated for its antifungal activity against phytopathogens but whose mechanism of fungal growth inhibition was not determined. Taxonomic studies on our actinomycete culture indicated that the producing organism was Micromonospora but differed from 12 described species, including M. chalcea, which is known to produce rustmicin.4 Here we demonstrate that rustmicin inhibits fungal sphingolipid synthesis at the transfer of phosphoinositol to ceramide. Cells treated with rustmicin accumulate ceramide, fail to synthesize all of the complex sphingolipids, and die. In mammalian cells, ceramide has been proposed to be a key intermediate in lipid signal transduction pathways leading to apoptosis and stress response (31-34). A similar pathway appears to operate in S. cerevisiae where ceramide induces G1 arrest via a ceramide-activated protein phosphatase (35) and promotes cell death in an IPC synthase mutant that responds to the addition of phytosphingosine by accumulating ceramide (18). Thus, activation of a ceramide death response may confer the observed fungicidal activity to inhibitors of IPC synthase. If so, then ceramide toxicity is a slow process, since the loss in viability required several generations to manifest itself.

Alternatively, depletion of IPC or one of its further metabolites by rustmicin may induce cell death, and arguments can be made for the involvement of complex sphingolipids in several essential processes. Glycosyl phosphatidylinositol-anchored mannoproteins constitute a major component of fungal cell walls; initially, they are synthesized with PI as the lipid moiety, but many are subsequently remodeled to IPC (36). The sphingolipid intermediate that is used for replacement has not yet been established, so it is not clear whether inhibitors of IPC synthase would block this process. Sphingolipids have also been shown to be important for the processing of glycosyl phosphatidylinositol-anchored proteins through the secretory pathway (37). Recently, another role for sphingolipids in vesicular secretion has been proposed, based on studies of suppressors of the sec14 mutant encoding the phosphatidylinositol:phosphatidylcholine transfer protein (38). These studies point to a requirement for diacylglycerol in vesicular budding from the Golgi and indicate that the rate of sphingolipid synthesis is important in regulating diacylglycerol concentrations due to the two biosynthetic steps that generate diacylglycerol: IPC and mannosyl diinositol diphosphoceramide synthesis, both of which transfer phosphoinositol from PI to the sphingolipid backbone. Rustmicin inhibits the synthesis of all of the complex sphingolipids and would be predicted to reduce diacylglycerol production at the ER, where IPC is thought to be synthesized, and at the Golgi, where the mannose-containing sphingolipids are made (39). Yet another function for sphingolipids in vesicular secretion and/or endocytosis has been proposed, due to the presence of the very long chain fatty acids (C24 and C26 species) that are complexed with sphingoid bases to form ceramide. In yeast, most of the very long chain fatty acids are found in the sphingolipid fraction; these fatty acids have been suggested to be important for providing physical stability to highly curved membranes, thereby allowing membranes to undergo budding and fusion (40). For any of these potential roles, dilution of the existing pools of sphingolipids would be required before cell death and would be consistent with the kinetics of rustmicin's fungicidal activity and requirement for actively growing cultures to induce cell death.

In addition to its activity in Saccharomyces, where the role of sphingolipids is beginning to be elucidated, rustmicin also has potent antifungal activity against clinically important human pathogens, suggesting that the requirement for sphingolipids is conserved among these fungi. A. fumigatus is one of the few human pathogens that is insensitive to any of the known IPC synthase inhibitors (14, 29). The reason for this resistance is not known, since inhibitors of earlier steps in the sphingolipid biosynthetic pathway do inhibit the growth of A. fumigatus. Khafrefungin, which is composed of an aldonic acid esterified to a linear C22 polyketide, is most potent against IPC synthase of C. albicans (14). Similarly, the cyclic depsipeptide compound, aureobasidin A, which has been shown to inhibit IPC synthase in S. cerevisiae (18), is most potent as an antifungal agent against C. albicans (29), presumably due to its sphingolipid inhibition.

Among the three structurally diverse IPC synthase inhibitors, rustmicin is unique in its remarkable activity against C. neoformans, where it is an exceptionally potent inhibitor of IPC synthase. Rustmicin inhibits the enzyme from C. neoformans with an IC50 of 70 pM, and is a low nanomolar inhibitor of the enzymes from C. albicans and S. cerevisae. The complexity of the system, which consists of a membrane-bound enzyme operating on membrane components, precluded determining the kinetic mechanism of inhibition, but simple wash-out experiments clearly showed that rustmicin is a reversible inhibitor. In addition, it was possible to show that potent inhibition extends to the solubilized enzyme from C. neoformans, establishing that inhibition by rustmicin is specific to the enzyme and not due to possible effects on its membrane environment. Recovery of active enzyme from the supernatant required the inclusion of PI during solubilization. We attribute this effect either to stabilization of the enzyme by binding one of its substrates, a property common to many enzymes, or to preservation of a membrane-like environment in the mixed detergent/phospholipid micelles. Solubilization of IPC synthase from S. cerevisae did not require the addition of PI, a difference that may be due to the use of a 5-fold higher ratio of membrane-protein to detergent, in which the cellular phospholipids may obviate the need for exogenous PI, or the inclusion of glycerol during solubilization (41).

Rustmicin's affinity for the C. neoformans enzyme contributes, but cannot fully account for, the large differential in antifungal activity between C. neoformans and C. albicans, which is 4-5 orders of magnitude. Two factors that limit rustmicin's whole cell activity, instability and multidrug efflux pumps, may have more influence on rustmicin's activity against C. albicans and S. cerevisiae over the extended time period of the fungal growth assays. Both of these yeasts have active plasma membrane H+-ATPases that rapidly acidify the media of growing cultures (42). Rustmicin is degraded within minutes at low pH (Fig. 5), and buffering the media at pH 5.5 to promote stability improved rustmicin's anti-Saccharomyces and anti-Candida activity by 2-8-fold (data not shown). Perhaps of greater impact on whole cell activity is the activity of efflux pumps. Several multidrug efflux pumps have been identified in C. albicans and S. cerevisiae and one of the mechanisms for fluconazole resistance in C. albicans has been shown to be via drug efflux pumps (24, 28, 43). We found that disruption of PDR5 dramatically improved rustmicin's potency against S. cerevisiae. Multidrug efflux mechanisms and plasma membrane H+-ATPase activity have not been characterized in C. neoformans, but rustmicin's equal potency of growth inhibition and in vitro enzyme inhibition suggest that these factors are not important for this pathogen, at least in the laboratory. However, we believe that the conversion of rustmicin to the inactive gamma -lactone that occurs rapidly in serum, compromises in vivo efficacy and best accounts for the relatively weak activity that rustmicin has in reducing cryptococcal load in mice, compared with its in vitro potency.

Multidrug efflux affects the activity of many structurally and mechanistically unrelated inhibitors in yeast, and in mammalian cells is one of the major obstacles to successful chemotherapy. In S. cerevisiae, disruption of PDR5 increases sensitivity to a number of compounds (24), while mutations in PDR1 that result in transcriptional activation of several genes, including PDR5, have been found to confer resistance to over 30 compounds (28). Thus, the response we obtained to rustmicin with these mutants was not surprising, but the magnitude of the effect was far more dramatic than any of the other antifungals we examined. In mammalian cells, a special relationship between multidrug efflux and glycosphingolipid synthesis was proposed due to the observed accumulation of glucosylceramides in multidrug-resistant tumor and cancer cell lines (44) and the discovery that compounds that reverse multidrug resistance inhibit glucosylceramide synthesis (30). It is intriguing to consider that sphingolipid synthesis in yeast may also contribute to drug resistance via the efflux pumps. For instance, the global transcriptional activation seen in PDR1 mutants may also include up-regulation of sphingolipid synthesis, and/or inhibition of sphingolipid synthesis may regulate the activity of the yeast efflux pumps. We have found that yeast cells with reduced levels of sphingolipids, either by mutation or drug treatment, are hypersensitive to many unrelated antifungals. However, drug hypersensitivity is also found in sterol synthesis mutants and has been attributed to changes in membrane fluidity and permeability (26). This explanation could account for the sphingolipid effect, and the differential activity of rustmicin against the drug-resistant strains may simply reflect affinity for Pdr5p. The multidrug resistance network has been well developed in yeast (28) and provides the genetic tools that, in combination with the lipid biosynthetic inhibitors and mutants, could help define the interactions between lipid synthesis and drug efflux pumps. Rustmicin, despite its in vivo limitations, is a highly potent IPC synthase inhibitor and will be an important tool to study the role of the inositol sphingolipids in yeast and fungal cell physiology.

    FOOTNOTES

* The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom correspondence should be addressed: Dept. of Biochemistry, Merck Research Laboratories, R80Y-230, P.O. 2000, Rahway, NJ 07065. Tel.: 732-594-3327; Fax: 732-594-1399; E-mail: suzanne_mandala{at}merck.com.

1 The abbreviations used are: IPC, inositol phosphoceramide; HPLC, high pressure liquid chromatography; PI, phosphatidylinositol; YNBD, yeast nitrogen base with glucose; MIC, minimum inhibitory concentration; CFU, colony-forming units.

2 Y. S. Tang, unpublished data.

3 G. H. Harris, A. Shafiee, M. A. Cabello, J. E. Curotto, O. Genilloud, K. E. Goklen, M. B. Kurtz, M. Rosenbach, P. M. Salmon, R. A. Thornton, D. L. Zink, and S. M. Mandala, submitted for publication.

4 J. M. Sigmund and C. F. Hirsch, submitted for publication.

    REFERENCES
Top
Abstract
Introduction
Procedures
Results
Discussion
References

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