Preparation and structure-activity relationships of simplified analogs of the antifungal agent cilofungin: a total synthesis approach

Zambias, Robert A.; Hammond, Milton L.; Heck, James V.; Bartizal, Ken; Trainor, C.; Abruzzo, George K.; Schmatz, Dennis M.; Nollstadt, K

doi:10.1021/jm00093a018

Cited by 57 publications

(39 citation statements)

References 2 publications

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“… Echinocandins are semisynthetic lipopeptides with a central cyclic hexapeptide structure [241].  non-competitively inhibit a principal cell wall structural constituent, 1,3-beta-D-glucan ( Figure 2) leading to static destabilization of the fungus causing osmotic cell lysis [242,243].…”

Section: Echinocandins Eg Caspofungin Micafungin and Anidulafunginmentioning

confidence: 99%

Future therapies targeted towards eliminatingCandidabiofilms and associated infections

Bandara

Matsubara

Samaranayake

2016

Expert Review of Anti-infective Therapy

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Section: Echinocandins Eg Caspofungin Micafungin and Anidulafunginmentioning

confidence: 99%

Future therapies targeted towards eliminatingCandidabiofilms and associated infections

Bandara

Matsubara

Samaranayake

2016

Expert Review of Anti-infective Therapy

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“…Compounds 1 and 2 were obtained in two steps according to the scheme shown in Fig. 1B by using the appropriate amino acids (D-homotyrosine, synthesized as hydrobromide from D-aspartic acid [15,28], and commercially available D-tyrosine, respectively), commercially available 4-ethyl-2,3-dioxopiperazine-1-carbonyl chloride, and bis-(trimethylsilyl)-aminomethaneboronate, synthesized as previously described (7).…”

Section: Synthesis Of Boronic Acid Inhibitorsmentioning

confidence: 99%

Novel Insights into the Mode of Inhibition of Class A SHV-1 β-Lactamases Revealed by Boronic Acid Transition State Inhibitors

Wei

Sampson

Ori

et al. 2011

Antimicrob Agents Chemother

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Boronic acid transition state inhibitors (BATSIs) are potent class A and C ␤-lactamase inactivators and are of particular interest due to their reversible nature mimicking the transition state. Here, we present structural and kinetic data describing the inhibition of the SHV-1 ␤-lactamase, a clinically important enzyme found in Klebsiella pneumoniae, by BATSI compounds possessing the R1 side chains of ceftazidime and cefoperazone and designed variants of the latter, compounds 1 and 2. The ceftazidime and cefoperazone BATSI compounds inhibit the SHV-1 ␤-lactamase with micromolar affinity that is considerably weaker than their inhibition of other ␤-lactamases. The solved crystal structures of these two BATSIs in complex with SHV-1 reveal a possible reason for SHV-1's relative resistance to inhibition, as the BATSIs adopt a deacylation transition state conformation compared to the usual acylation transition state conformation when complexed to other ␤-lactamases. Active-site comparison suggests that these conformational differences might be attributed to a subtle shift of residue A237 in SHV-1. The ceftazidime BATSI structure revealed that the carboxyl-dimethyl moiety is positioned in SHV-1's carboxyl binding pocket. In contrast, the cefoperazone BATSI has its R1 group pointing away from the active site such that its phenol moiety moves residue Y105 from the active site via end-on stacking interactions. To work toward improving the affinity of the cefoperazone BATSI, we synthesized two variants in which either one or two extra carbons were added to the phenol linker. Both variants yielded improved affinity against SHV-1, possibly as a consequence of releasing the strain of its interaction with the unusual Y105 conformation.Production of ␤-lactamases (EC 3.5.2.6) is one of the major mechanisms by which bacteria develop resistance to ␤-lactam antibiotics. In nature, four classes of ␤-lactamase enzymes exist (classes A to D). Classes A, C, and D are serine-based ␤-lactamases, while class B uses a metal ion (Zn 2ϩ ) to hydrolyze the lactam bond. TEM-1 and SHV-1 ␤-lactamases are among the most commonly observed class A ␤-lactamases found in Escherichia coli and Klebsiella pneumoniae. As such, this family of ␤-lactamases presents a significant clinical threat (3, 21).To counteract ␤-lactamases, mechanism-based inhibitors were developed to be administered in concert with ␤-lactam antibiotics (9). Presently, there are three commercially available ␤-lactamase inhibitors (clavulanate, sulbactam, and tazobactam) which are effective primarily against class A ␤-lactamases (Fig. 1). Unfortunately, bacteria possessing ␤-lactamase enzymes have adapted under continued drug pressure and some variants of class A ␤-lactamases are now "inhibitor resistant" (9). Moreover, class C and D enzymes are poorly inhibited by any of the three commercial inhibitors. Therefore, there is an urgent need to develop novel ␤-lactam antibiotics and new types of ␤-lactamase inhibitors to counteract the current crisis in antimicrobial resistance (9).Based...

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“…The emission spectrum of the 1:1 mixture of HBA and NATA, which reflects the actual ratio of chro-VOL. 38 mophores in cilofungin, was clearly different from that of cilofungin in both relative intensity and spectral position (Fig. 4).…”

Section: Materuils and Methodsmentioning

confidence: 91%

“…A number of antifungal drugs have been targeted against GSs from various fungi including the lipopeptide echinocandin-like class of inhibitors (12,30,31,35), aculeacin A (23,24), cilofungin (8,10,11), pneumocandins (12,31), and the papulacandins (2,16,26,37), which are lipid-like saccharides. Each of these compounds contains fatty acid side chains, which have been shown to be essential for the actions of cilofungin (34,38) and papulacandin B (37). Although various lipophilic compounds are known to rapidly inactivate fungal glucan (18,25) and chitin synthases (25), the mechanism by which these compounds interfere with GS has only recently begun to attract considerable attention (17,18,36).…”

mentioning

confidence: 99%

Use of cilofungin as direct fluorescent probe for monitoring antifungal drug-membrane interaction

Ludescher

Frost

et al. 1994

Antimicrob Agents Chemother

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Cilofungin is an antifungal cyclopeptide which inhibits cell wall (1,3)-p1-glucan biosynthesis in fungal organisms, and its action against Candida albicans (1,3)-Il-glucan synthase has been widely studied. Since glucan synthase inactivation is thought to partially result from perturbations of the membrane lipid environment, the interaction of cilofungin with fungal membranes and phosphatidylcholine membrane vesicles was studied. Cilofungin, which contains two independent aromatic groups, has an excitation maximum of 270 nm and an emission maximum of 317 nm in aqueous solution. Comparison of the fluorescence properties of cilofungin with those of the analogs pneumocandin Bo, N-acetyl-tyrosinamide, and 4-hydroxybenzamide indicated that the emission of cilofungin largely derived from the p-octyloxybenzamide side chain. Microsomal membranes from Saccharomyces cerevisiae, C. albicans, and phosphatidylcholine membrane vesicles induced a blue shift in the cilofungin emission spectrum and increased the cilofungin steady-state emission anisotropy, providing direct evidence for a cilofungin-membrane interaction. Cilofungin interacted more strongly with membranes of C. albicans than with those of S. cerevisiae, correlating with previous findings that C. albicans is far more susceptible than S. cerevisiae to the action of cilofungin. These findings support the hypothesis that drug-induced inhibition of the (1,3)-,B-glucan synthesis results from the perturbation of the membrane environment and the interaction with the glucan synthase complex combined. The study demonstrated ways in which the fluorescence properties of drugs can be used to directly evaluate drug-membrane interactions and structure-activity relationships.New antifungal drugs that are directed against specific fungal targets and that cause minimal toxicity to the host have attracted considerable interest in recent years. One such target is the plasma membrane-localized (1,3)-3-glucan synthase (GS; EC 2.4.1.34), which catalyzes the biosynthesis of (1,3)-1-glucan, an essential structural polymer of the cell wall (17,36). A number of antifungal drugs have been targeted against GSs from various fungi including the lipopeptide echinocandin-like class of inhibitors (12,30,31,35), aculeacin A (23, 24), cilofungin (8, 10, 11), pneumocandins (12, 31), and the papulacandins (2, 16, 26, 37), which are lipid-like saccharides. Each of these compounds contains fatty acid side chains, which have been shown to be essential for the actions of cilofungin (34,38) and papulacandin B (37). Although various lipophilic compounds are known to rapidly inactivate fungal glucan (18,25) and chitin synthases (25), the mechanism by which these compounds interfere with GS has only recently begun to attract considerable attention (17,18,36).Drug-membrane interactions can be probed directly by fluorescence spectroscopic techniques, provided that the drug contains a structural moiety exhibiting fluorescence properties (6, 7). In the present study, we demonstrated that cilofungin, which contains...

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Preparation and structure-activity relationships of simplified analogs of the antifungal agent cilofungin: a total synthesis approach

Cited by 57 publications

References 2 publications

Future therapies targeted towards eliminatingCandidabiofilms and associated infections

Future therapies targeted towards eliminatingCandidabiofilms and associated infections

Novel Insights into the Mode of Inhibition of Class A SHV-1 β-Lactamases Revealed by Boronic Acid Transition State Inhibitors

Use of cilofungin as direct fluorescent probe for monitoring antifungal drug-membrane interaction

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