Pneumocysterol [(24Z)-ethylidenelanost-8-en-3-ol], a rare sterol detected in the opportunistic pathogenCommunicated by William Trager, The Rockefeller University, New York, NY, November 2, 1998 (received for review February 4, 1998 ABSTRACTPneumocystis carinii pneumonia (PcP) remains among the most prevalent opportunistic infections among AIDS patients. Currently, drugs used clinically for deep mycosis act by binding ergosterol or disrupting its biosynthesis. Although classified as a fungus, P. carinii lacks ergosterol. Instead, the pathogen synthesizes a number of distinct ⌬ 7 , 24-alkylsterols, despite the abundance of cholesterol, which it can scavenge from the lung alveolus. Thus, the pathogen-specific sterols appear vital for organism survival and proliferation. In the present study, high concentrations of a C 32 sterol were found in humanderived P. carinii hominis. The definitive structural identities of two C-24 alkylated lanosterol compounds, previously not reported for rat-derived P. carinii carinii, were determined by using GLC, MS, and NMR spectroscopy together with the chemical syntheses of authentic standards. The C 31 and C 32 sterols were identified as euphorbol (24-methylenelanost-8-en-3-ol) and pneumocysterol [(24Z)-ethylidenelanost-8-en-3-ol], respectively. The identification of these and other 24-alkylsterols in P. carinii hominis suggests that (i) sterol C-24 methyltransferase activities are extraordinarily high in this organism, (ii) 24-alkylsterols are important components of the pathogen's membranes, because the addition of these side groups onto the sterol side chain requires substantial ATP equivalents, and (iii) the inefficacy of azole drugs against P. carinii can be explained by the ability of this organism to form 24-alkysterols before demethylation of the lanosterol nucleus. Because mammals cannot form 24-alkylsterols, their biosyntheses in P. carinii are attractive targets for the development of chemotherapeutic strategies against this opportunistic infection.Sterols and their biosyntheses are excellent targets for chemotherapeutic attack against infectious microbes, especially the fungi. Polyene antibiotics such as amphotericin B bind avidly to ergosterol in fungal cell membranes. After the sterol-drug complexes aggregate, large pores in the membranes are formed, dissipating ion gradients. Fluconazole and some other compounds routinely used clinically for systemic mycosis target ergosterol biosynthesis at nuclear demethylation steps. Ergosterol was not detected in Pneumocystis carinii carinii that was isolated and purified from the lungs of corticosteroid-immunosuppressed rats. In this respect, the pathogen appears to be unlike higher fungi. However, the organism synthesizes its own distinct sterols, e.g., fungisterol (24-methylcholest-7-en-3-ol and 24-ethylcholest-7-en-3-ol; refs. 1-4). Parasites generally scavenge sterols (e.g., cholesterol) from the host and utilize them for membrane formation and other cell functions. If host sterols do not fulfill the precise stereochemi...
The rise in plasma neopterin observed with increasing severity of vascular disease is a strong indicator of the inflammatory nature of atherosclerosis. Plasma neopterin originates as the oxidation product of 7,8-dihydroneopterin secreted by g-interferon stimulated macrophages within atherosclerotic plaques. Neopterin is increasingly being used as a marker of inflammation during clinical management of patients with a range of disorders including atherosclerosis. Yet the role of 7,8-dihydroneopterin/neopterin synthesis during the inflammatory process and plaque formation remains poorly understood and controversial. This is partially due to the unresolved role oxidants play in atherosclerosis and the opposing roles of 7,8-dihydroneopterin/neopterin. Neopterin can act as pro-oxidant, enhancing oxidant damage and triggering apoptosis in a number of different cell types. Neopterin appears to have some cellular signalling properties as well as being able to chelate and enhance the reactivity of transition metal ions during Fenton reactions. In contrast, 7,8-dihydroneopterin is also a radical scavenger, reacting with and neutralizing a range of reactive oxygen species including hypochlorite, nitric oxide and peroxyl radicals, thus protecting lipoproteins and various cell types including macrophages. This has led to the suggestion that 7,8-dihydroneopterin is synthesized to protect macrophages from the oxidants released during inflammation. The oxidant/ antioxidant activity observed in vitro appears to be determined both by the relative concentration of these compounds and the specific chemistry of the in vitro system under study. How these activities might influence or modulate the development of atherosclerotic plaque in vivo will be explored in this review.
The opportunistic pathogen Pneumocystis carinii causes pneumonia (P. carinii pneumonia, or PCP) in immunocompromised individuals such as AIDS patients. Rat-derivedP. carinii carinii organisms have distinct sterols which are not synthesized by mammals and not found in other microbes infecting mammalian lungs. The dominant sterol present in the organism is cholesterol (which is believed to be scavenged from the host), but other sterols in P. carinii carinii have an alkyl group at C-24 of the sterol side chain (C28 and C2924-alkylsterols) and a double bond at C-7 of the nucleus. Recently, pneumocysterol (C32), which is essentially lanosterol with a C-24 ethylidene group, was detected in lipids extracted from a formalin-fixed human P. carinii-infected lung, and its structures were elucidated by gas-liquid chromatography, mass spectrometry, and nuclear magnetic resonance spectrometry in conjunction with analyses of chemically synthesized authentic standards. The sterol composition of isolated P. carinii hominis organisms has yet to be reported. If P. carinii from animal models is to be used for identifying potential drug targets and for developing chemotherapeutic approaches to clear human infections, it is important to determine whether the 24-alkylsterols of organisms found in rats are also present in organisms in humans. In the present study, sterol analyses of P. carinii hominis organisms isolated from cryopreserved humanP. carinii-infected lungs and from bronchoalveolar lavage fluid were performed. Several of the same distinct sterols (e.g., fungisterol and methylcholest-7-ene-3β-ol) previously identified inP. carinii carinii were also present in organisms isolated from human specimens. Pneumocysterol was detected in only some of the samples.
Macrophage cells within inflammatory lesions are exposed to a wide range of degrading and cytotoxic molecules including reactive oxygen species. Unlike neutrophils, macrophages do not normally die in this environment but continue to generate oxidants, phagocytose cellular remains, and release a range of cyto-active agents which modulate the immune response. It is this potential of the macrophage cell to survive in an oxidative environment that allows the growth and complexity of advanced atherosclerotic plaques. This review will examine the oxidants encountered by macrophages within an atherosclerotic plaque and describe some of the potential antioxidant mechanisms which enable macrophages to function within inflammatory lesions. Ascorbate, a-tocopherol, and glutathione appear to be central to the protection of macrophages yet additional antioxidant mechanisms appear to be involved. Gamma-Interferon causes macrophages to generate 7,8-dihydroneopterin, neopterin and 3-hydroxyanthranilic acid both of which have antioxidant properties. Manganese superoxide dismutase is also upregulated in macrophages. The evidence that these antioxidants provide further protection, so allowing the macrophage cells to survive within sites of chronic inflammation such as atherosclerotic plaques, will be described.
Sterol profiles of samples taken from different sites of a Pneumocystis-infected human lung showed large variations in pneumocysterol similar to those that occur among samples from different patients. Thus, the influence of diet or drugs on pneumocysterol accumulation was ruled out, suggesting distinct phenotypic populations as the basis for the heterogeneity.Pneumocystis carinii synthesizes a number of distinct ⌬ 7 and ⌬ 8 24-alkylsterols but not ergosterol (the target of several antimycotics), and the organism scavenges cholesterol from its mammalian host (5, 6, 14-16, 18, 24). Most fungal sterols have an alkyl group consisting of one carbon at C-24 of the side chain. In contrast, the sterols of P. carinii and many plants have either one or two carbons at that site (C 28 and C 29 sterols). The P. carinii sterols are excellent chemotherapeutic targets because mammals cannot synthesize 24-alkylsterols.The C 32 24-alkylated lanosterol compound pneumocysterol (17) was detected in only trace amounts in organisms isolated from the corticosteroid-immunosuppressesd rat P. carinii pneumonia (PCP) model. The sterol profiles of organisms isolated from this animal model are consistent and reproducible from preparation to preparation (5,14,15,18). In contrast, pneumocysterol was found in various percentages, from trace levels to 50% of the noncholesterol sterols, in organisms isolated from cryopreserved human lungs (16). Replicate analyses of these human-derived samples were consistent and reproducible, suggesting biochemical differences in organism populations. No correlation between human immunodeficiency virus infection (HIV) and high levels of pneumocysterol was found. However, in that earlier study, the possible effects of diet, nonprescribed drugs, or other factors could not be ruled out as the basis for broad variations in the accumulation of this sterol. In the present study, variations in pneumocysterol in samples from the same pair of human lungs were noted, and thus, more than six different sites in the lungs from the same individual were analyzed.A formalin-fixed pair of lungs from an AIDS patient who died from PCP was provided by M. Pereira (Tufts Medical School, Boston, Mass.). Approximately 100-g pieces were excised from different sites and homogenized with distilled water in a Waring blender for 2 min, and total lipids were extracted (2) at room temperature for at least 2 h. The sterols were prepared and analyzed by gas-liquid chromatographic (GLC) methods as previously described (16-18).Formalin does not have functions that would interact with sterols, and it was experimentally shown in a previous study that formalin fixation did not alter the sterols of rat lungs (19). Also, formalin-fixed lung tissue (17, 19) and Pneumocystis organisms isolated from cryopreserved human lungs (16) contained the same steroidal compounds. In the present study, the GLC components designated peaks 13, 16, 19, 20 and 24 were considered the organism's signature sterol profile [24-methylcholest-7-en-3-ol (fungisterol), 24-ethyl...
The severity of atheroma burden in patients strongly correlates to increasing levels of plasma neopterin, the oxidation product of 7,8-dihydroneopterin. Interferon-γ stimulation of macrophages causes the synthesis of 7,8-dihydroneopterin, a potent antioxidant that inhibits oxidative damage to cells, and the cytotoxicity of oxidized low-density lipoprotein (oxLDL) to monocyte-like U937 cells but not THP-1 cells. With human monocyte-derived macrophages (HMDMs), oxLDL triggered a large oxidative stress, causing the rapid loss of cellular glutathione, glyceradehyde-3-phosphate dehydrogenase (GAPDH) inhibition, and eventual loss of viability without caspase-3 activation. Inhibition of oxLDL cytotoxicity to HMDMs occurred at 7,8-dihydroneopterin concentrations >100 μM. The oxLDL-mediated glutathione loss and GAPDH inactivation was inhibited by 7,8-dihydroneopterin. 7,8-Dihydroneopterin rapidly entered the HMDMs, suggesting that much of the protective effect was scavenging of intracellular oxidants generated in response to oxLDL. OxLDL uptake by HMDMs was reduced by 30% by 7,8-dihydroneopterin. Immunoblot analysis suggests that this decrease in oxLDL uptake was due to a significant downregulation in the levels of CD36. These results imply that 7,8-dihydroneopterin protects human macrophages both by scavenging oxidants generated in response to oxLDL and by decreasing CD36-mediated uptake of oxLDL.
Several drugs that interact with membrane sterols or inhibit their syntheses are effective in clearing a number of fungal infections. The AIDS-associated lung infection caused by Pneumocystis jirovecii is not cleared by many of these therapies. Pneumocystis normally synthesizes distinct C28 and C29 24-alkylsterols, but ergosterol, the major fungal sterol, is not among them. Two distinct sterol compositional phenotypes were previously observed in P. jirovecii. One was characterized by delta7 C28 and C29 24-alkylsterols with only low proportions of higher molecular mass components. In contrast, the other type was dominated by high C31 and C32 24-alkylsterols, especially pneumocysterol. In the present study, 28 molecular species were elucidated by nuclear magnetic resonance analysis of a human lung specimen containing P. jirovecii representing the latter sterol profile phenotype. Fifteen of the 28 had the methyl group at C-14 of the sterol nucleus and these represented 96% of the total sterol mass in the specimen (excluding cholesterol). These results strongly suggest that sterol 14alpha-demethylase was blocked in these organisms. Twenty-four of the 28 were 24-alkylsterols, indicating that methylation of the C-24 position of the sterol side chain by S-adenosyl-L-methionine:sterol C-24 methyl transferase was fully functional.
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