Mechanism-based Enzyme Inactivators of Phytosterol Biosynthesis

Zhou, Wenxu; Song, Zhihong; Kanagasabai, Ragu; Liu, Jialin; Jayasimha, Pruthvi; Sinha, Archana; Veeramachanemi, Phani; Миллер, М.; Nes, W. David

doi:10.3390/90400185

Cited by 14 publications

(22 citation statements)

References 47 publications

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“…In similar fashion, 26,27-dehydrolanosterol fails to serve as a suicide substrate against the yeast SMT (5, 9, 20). When TB SMT was treated with a range of concentrations of 26,27-dehydrozymosterol (25-100 M), a rapid, concentration-and time-dependent loss of SMT activity was observed, consistent with our earlier findings of the inhibitor tested with fungal or plant SMTs (9,20). A plot of the inactivation data as log (residual activity) against incubation time for three inhibitor concentrations gave a series of straight lines (supplemental Fig.…”

Section: Resultssupporting

confidence: 70%

“…Substrates and Reagents-The preparation, proof of structure, and purification of 26,27-dehydrozymosterol, 25-azalanosterol, 24(R,S),25-epiminolanosterol, and ergosterol have been described (9,(13)(14)(15). Sterol substrates for activity assay were from our steroid collection (13)(14)(15) Trypanosoma brucei SMT Cloning, Expression, and Purification-Sequence data for T. brucei SMT were obtained from the web site of The Institute of Genomic Research (www.tigr.org) using Blast search against SMT from S. cerevisiae.…”

Section: Methodsmentioning

confidence: 99%

“…SMT is also of interest enzymologically because the reaction that is catalyzed can be bifunctional with the enzyme accepting different substrate olefins (6). In those protozoans that synthesize ergosterol (7), the C-methylation step makes it possible to develop microbial-specific sterol biosynthesis inhibitors to block a critical slow enzyme in the pathway to treat infected individuals (7)(8)(9).…”

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confidence: 99%

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Mechanistic Analysis of a Multiple Product Sterol Methyltransferase Implicated in Ergosterol Biosynthesis in Trypanosoma brucei

Zhou

Lepesheva

Waterman

et al. 2006

Journal of Biological Chemistry

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Section: Resultssupporting

confidence: 70%

Section: Methodsmentioning

confidence: 99%

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confidence: 99%

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Mechanistic Analysis of a Multiple Product Sterol Methyltransferase Implicated in Ergosterol Biosynthesis in Trypanosoma brucei

Zhou

Lepesheva

Waterman

et al. 2006

Journal of Biological Chemistry

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“…The SMT from each group was shown to catalyze the inhibitor to a similar methylated product. In addition, the SMT1 from soybean, yeast and Trypanosoma was strongly inactivated, with k inact values of 0.3, 1.5 and 0.3 min -1 observed, respectively [20,38,51], whereas the SMT2 from Arabidopsis was inactivated (k inact of 0.60 min -1 ), and the yeast-like Prototheca SMT1 was not inactivated by the inhibitor [51,52]. The variation in the recognition of the inhibitor by the yeast and yeast-like SMTs suggests that subtle differences exist in the topographies of the active sites of these enzymes.…”

Section: Mechanism-based Inhibition Of Smt Catalysismentioning

confidence: 93%

Sterol Biosynthesis Inhibitors: Potential for Transition State Analogs and Mechanism‐Based Inactivators Targeted at Sterol Methyltransferase

Song

Nes

2007

Lipids

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Sterol biosynthesis inhibitors (SBIs), discovered in the late 1960s and subsequently used commercially to treat ergosterol-dependent fungal diseases, represent a unique drug class targeted at an enzyme in a biosynthetic pathway. To date, few drugs have been commercialized as enzyme inhibitors; yet, prescription of SBIs has emerged as the gold standard for some cases of non-life-threatening antifungal chemotherapy and in crop protection. SBIs are not designed for their structural resemblance to the sterol molecule; they nonetheless can engender a curative effect by interfering with sterol production and homeostasis in the pathogenic organism. The increased use of SBIs in recent years, particularly the azole antifungals, has resulted in the development of resistance to those drugs, necessitating additional work to further our understanding of antifungal resistance and to explore opportunities to develop new enzyme inhibitors and uncover new enzyme targets that can regulate carbon flux in the post-lanosterol/cycloartenol pathway. This article reports general considerations for enzyme mechanism and active-site probes using inhibitors of the C-methylation reaction, including a potential new class of antifungal/antiparasitic agents of phytosterol synthesis tailored as mechanism-based inactivators. These steroid-based compounds prepared with different sterol side chain functionalities are designed to reversibly or irreversibly impair the sterol methyltransferase, an enzyme expressed in pathogenic microbes and plants but not in the human host. The salient aspects of these and related topics directed toward the enzyme recognition of sterol structure, and the inhibitory properties and catalytic competence of a series of specifically modified substrate analogs that affect sterol methyltransferase action are discussed.

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“…Rational chemotherapeutic approaches are focused on the metabolic differences between these pathogenic microorganisms and mammals. In this regard, membrane sterol biosynthesis is one of the few areas of difference in primary metabolism between mammals and other eukaryotes such as plants, fungi and protozoa [17,18]. While mammals synthesize C27 cholestane-based members of the sterols family, pathogenic fungi, protozoa and plants require the presence of endogenous sterols C28-C29 (typically ergosterol and 24-alkyl analogs) which are essential for survival and growth factors for these organisms [19,20].…”

Section: Introductionmentioning

confidence: 99%

Anti-trypanosomatid activity of platinum–sterol hydrazone imidazoline complexes

Navarro

Marchán²,

Maldonado

et al. 2015

Transition Met Chem

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In the search for effective and less toxic drugs against Leishmania mexicana and Trypanosoma cruzi parasites, two new complexes trans-[Pt(Him1) 2 (Cl) 2 ] (1) and trans-[Pt(Him2) 2 (Cl) 2 ] (2) were synthesized by the reactions of K 2 PtCl 4 with sterol hydrazone ligands 20-hydrazone-imidazoline-2-yl-5a-pregnan-3b-ol (Him1) and 22-hydrazoneimidazoline-2-yl-chol-5-ene-3b-ol (Him2). The complexes were characterized by a combination of physicochemical and spectroscopic methods. The ligands and their platinum complexes were evaluated in vitro against promastigotes of L. mexicana and epimastigotes of T. cruzi. Both the free sterol hydrazones and their platinum complexes at 10 lM final concentration induced a potent leishmanicidal activity (LD 100 B 48 h). Trypanostatic effect (IC 50 B 72 h) was observed with Him1, trans-[Pt(Him1) 2 (Cl) 2 ] (1) and trans-[Pt(Him2) 2 (Cl) 2 ] (2), but at 5 lM concentration for the latter. Free Him2 at 5 lM concentration proved to be a potent trypanocidal agent (LD 50 , 24 h), reaching LD 100 after 72 h of exposure. Additionally, Him2 and its platinum derivative when tested against human lymphocytes at twice the antiTrypanosoma effective concentration did not show cytotoxicity. These findings demonstrate the potent anti-trypanosomatid activity of these sterol hydrazone imidazolines and their platinum complexes, and especially the low cytotoxicity of Him2 and trans-[Pt(Him2) 2 (Cl) 2 ] against human immunocompetent cells.

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Mechanism-based Enzyme Inactivators of Phytosterol Biosynthesis

Cited by 14 publications

References 47 publications

Mechanistic Analysis of a Multiple Product Sterol Methyltransferase Implicated in Ergosterol Biosynthesis in Trypanosoma brucei

Mechanistic Analysis of a Multiple Product Sterol Methyltransferase Implicated in Ergosterol Biosynthesis in Trypanosoma brucei

Sterol Biosynthesis Inhibitors: Potential for Transition State Analogs and Mechanism‐Based Inactivators Targeted at Sterol Methyltransferase

Anti-trypanosomatid activity of platinum–sterol hydrazone imidazoline complexes

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