Three closely related fungal metabolites, The mammalian isoprenoid pathway not only produces sterols but also produces dolichol, ubiquinone, the farnesyl group of heme A, the farnesyl and geranylgeranyl groups of prenylated proteins, and the isopentenyl side chain of isopentenyl adenine. The pathways for the synthesis of these other isoprenoids diverge from the synthesis ofcholesterol either at or before the farnesyl diphosphate (FPP) branch point. Thus, squalene synthase, which catalyzes the reductive dimerization of 2 mol of FPP to 1 mol of squalene (2, 3), is the first committed step in sterol synthesis. A specific inhibitor of squalene synthase should serve to inhibit cholesterol synthesis and not adversely affect the synthesis of other isoprenoids. FPP, the substrate for squalene synthase, is water soluble and may be readily metabolized (4). Thus, squalene synthase offers a potential target for the safe and specific inhibition of cholesterol synthesis.In this report we describe the isolation, structure, physical characterization, and biological properties of three structurally similar fungal metabolites that are potent inhibitors of squalene synthase. These metabolites, zaragozic acid A (5-7), zaragozic acid B (8, 9), and zaragozic acid C (10-12), had been reported previously only in the patent literature; however, during the review process of this manuscript, three manuscripts (13-15) appeared on the squalestatins: squalestatin I is identical with zaragozic acid A, squalestatin II is des-4'-acetylzaragozic acid A, and squalestatin III is des-6-acylzaragozic acid A. This class of squalene synthase inhibitors has potential utility as cholesterol-lowering agents. MATERIALS AND METHODSZaragozic Acid A, Cultures, and Media. An unidentified sterile fungal culture, ATCC 20986, isolated from a water sample taken from the Jalon river in Zaragoza, Spain (hence the name zaragozic acids), was used to produce zaragozic acid A. The culture was maintained at 25°C on medium B agar slants composed of 4 g of yeast extract, 10 g of malt extract, 4 g of dextrose, and 20 g of agar per liter at pH 7.0.Zaragozic acid A was produced in a two-tiered fermentation process consisting of mycelial growth and development in medium A of ref. 1 and product formation in medium C. Medium C contained 5 g of malt extract, 1 g of peptone, 15 g of dextrose, 1 g of KH2PO4, and 0.5 g of MgSO4 7H20 per liter. Fermentations consisted of mycelial growth in medium A for 72 hr at 250C with agitation, followed by inoculation (5-10%) of medium C. Maximum product was obtained from 14-day agitated fermentations at 250C.Isolation of Zaragozic Acid A. To isolate zaragozic acid A, 23 liters of harvested broth was filtered through Celite, and the mycelial cake was extracted twice with 7 liters of 50%o aqueous methanol. The filtrate was combined with the extracts, diluted with water to a final composition of 25% methanol, and adsorbed on a 1.5-liter column of Mitsubishi HP-20 resin. After a column wash with 6 liters of4:6 (vol/vol) methanol/water, crud...
Pneumocystis carini pneumonia is a major cause of death in AIDS patients in the United States. The presently available treatments have limited use due to a high incidence of adverse reactions. Therefore, there is an urgent need for a safer method for treatment and prevention of this disease. Recent evidence has suggested that P. carinn is related to fungi and that the wall ofthe cyst form contains 1,3-13-glucan as a major constituent. Based on this, several proposed 1,3-f3-glucan synthesis inhibitors were evaluated for their ability to control P. carinu pneumonia in vivo. Compounds from two classes of 1,3-13-glucan synthesis inhibitors, the echinocandins and papulacandins, were found to be effective against P. carinii.Pneumocystis carinii pneumonia is the most prevalent opportunistic infection and a frequent cause of death in AIDS
The in vivo anti-Candida activities of 1,3-13-D-glucan synthesis inhibitors L-671,329, L-646,991 (cilofungin), L-687,901 (tetrahydroechinocandin B), and L-687,781 (a papulacandin analog) were evaluated by utilizing a murine model of disseminated candidiasis that has enhanced susceptibility to Candida albicans but increased sensitivity for discriminating antifungal efficacy. DBA/2 mice were challenged intravenously with 1 x 104 to 5 x 104 CFU of C. albicans MY1055 per mouse. Compounds were administered intraperitoneally at concentrations ranging from 1.25 to 10 mg/kg of body weight twice daily for 4 days. At 6 h and 1, 2, 3, 4, 7, and 9 days after challenge, five mice per group were sacrificed and their kidneys were homogenized and plated for enumeration of Candida organisms (CFU per gram). Progressiveness of response trends and no-statisticalsignificance-of-trend doses were derived to rank compound efficacy. 1,3-13-D-Glucan synthesis 50% inhibitory concentrations were determined by using a C. albicans (MY1208) In the last decade, the incidence of serious fungal infections has reached record levels. This increase is due primarily to the AIDS epidemic, an expanding number of immune deficiency syndromes, and modern medical techniques that predispose a much larger population to opportunistic fungal infections. The number of current therapies available to counter the mycoses has been developed at approximately the same rate since the inception of antifungal drug therapy. Amphotericin B (AMB), developed in the 1950s, still remains the drug of choice for most fungal diseases mainly because it is broad spectrum and fungicidal, but it is considered to be relatively toxic (36, 37). The broad-spectrum azole antifungal agents developed more recently, although considered to be safer and less toxic than AMB, are fungistatic, which has limited their utility in many clinical settings (28,36). Many of these new antifungal agents are ineffective against deep-seated, life-threatening mycoses. Therefore, the critical need for new fungicidal agents which are safe and effective is evident.Our efforts toward identification of a promising antifungal agent have focused on 1,3-p-D-glucan synthesis inhibitors.
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