FR171456 is a specific inhibitor of mammalian NSDHL and yeast Erg26p

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Abstract

FR171456 is a natural product with cholesterol-lowering properties in animal models, but its molecular target is unknown, which hinders further drug development. Here we show that FR171456 specifically targets the sterol-4-alpha-carboxylate-3-dehydrogenase (S accharomyces cerevisiae—Erg26p, Homo sapiens—NSDHL (NAD(P) dependent steroid dehydrogenase-like)), an essential enzyme in the ergosterol/cholesterol biosynthesis pathway. FR171456 significantly alters the levels of cholesterol pathway intermediates in human and yeast cells. Genome-wide yeast haploinsufficiency profiling experiments highlight the erg26/ERG26 strain, and multiple mutations in ERG26 confer resistance to FR171456 in growth and enzyme assays. Some of these ERG26 mutations likely alter Erg26 binding to FR171456, based on a model of Erg26. Finally, we show that FR171456 inhibits an artificial Hepatitis C viral replicon, and has broad antifungal activity, suggesting potential additional utility as an anti-infective. The discovery of the target and binding site of FR171456 within the target will aid further development of this compound.

Abstract

FR171456 is a bioactive chemical produced by some microorganisms. Here, the authors identify the enzyme NSDHL of the sterol synthesis pathway as the molecular target of FR171456, rendering it the first compound to specifically target this class of enzyme in yeast and mammalian cells.

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Most cited references 29

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Understanding the hepatitis C virus life cycle paves the way for highly effective therapies.

Troels Scheel, Charles Rice (2013)

More than two decades of intense research has provided a detailed understanding of hepatitis C virus (HCV), which chronically infects 2% of the world's population. This effort has paved the way for the development of antiviral compounds to spare patients from life-threatening liver disease. An exciting new era in HCV therapy dawned with the recent approval of two viral protease inhibitors, used in combination with pegylated interferon-α and ribavirin; however, this is just the beginning. Multiple classes of antivirals with distinct targets promise highly efficient combinations, and interferon-free regimens with short treatment duration and fewer side effects are the future of HCV therapy. Ongoing and future trials will determine the best antiviral combinations and whether the current seemingly rich pipeline is sufficient for successful treatment of all patients in the face of major challenges, such as HCV diversity, viral resistance, the influence of host genetics, advanced liver disease and other co-morbidities.

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Targets for cell cycle arrest by the immunosuppressant rapamycin in yeast.

Amanda Hall, N. Movva, Joseph Heitman (1991)

FK506 and rapamycin are related immunosuppressive compounds that block helper T cell activation by interfering with signal transduction. In vitro, both drugs bind and inhibit the FK506-binding protein (FKBP) proline rotamase. Saccharomyces cerevisiae cells treated with rapamycin irreversibly arrested in the G1 phase of the cell cycle. An FKBP-rapamycin complex is concluded to be the toxic agent because (i) strains that lack FKBP proline rotamase, encoded by FPR1, were viable and fully resistant to rapamycin and (ii) FK506 antagonized rapamycin toxicity in vivo. Mutations that conferred rapamycin resistance altered conserved residues in FKBP that are critical for drug binding. Two genes other than FPR1, named TOR1 and TOR2, that participate in rapamycin toxicity were identified. Nonallelic noncomplementation between FPR1, TOR1, and TOR2 alleles suggests that the products of these genes may interact as subunits of a protein complex. Such a complex may mediate nuclear entry of signals required for progression through the cell cycle.

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A molecular barcoded yeast ORF library enables mode-of-action analysis of bioactive compounds.

Corey Nislow, Guri Giaever, David Botstein … (2009)

We present a yeast chemical-genomics approach designed to identify genes that when mutated confer drug resistance, thereby providing insight about the modes of action of compounds. We developed a molecular barcoded yeast open reading frame (MoBY-ORF) library in which each gene, controlled by its native promoter and terminator, is cloned into a centromere-based vector along with two unique oligonucleotide barcodes. The MoBY-ORF resource has numerous genetic and chemical-genetic applications, but here we focus on cloning wild-type versions of mutant drug-resistance genes using a complementation strategy and on simultaneously assaying the fitness of all transformants with barcode microarrays. The complementation cloning was validated by mutation detection using whole-genome yeast tiling microarrays, which identified unique polymorphisms associated with a drug-resistant mutant. We used the MoBY-ORF library to identify the genetic basis of several drug-resistant mutants and in this analysis discovered a new class of sterol-binding compounds.

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Author and article information

Journal

Journal ID (nlm-ta): Nat Commun

Journal ID (iso-abbrev): Nat Commun

Title: Nature Communications

Publisher: Nature Pub. Group

ISSN (Electronic): 2041-1723

Publication date (Electronic): 12 October 2015

Publication date Collection: 2015

Volume: 6

Electronic Location Identifier: 8613

Affiliations

[1 ]Novartis Institutes for BioMedical Research, Novartis Campus , Basel, CH-4056, Switzerland

[2 ]Institut de Biologie Moléculaire des Plantes, CNRS, Unité Propre de Recherche 2357 , Strasbourg cedex 67083, France

[3 ]Novartis Institutes for BioMedical Research , 250 Massachusetts Avenue, Cambridge, Massachusetts, 02139, USA

[4 ]GNF , San Diego, California 92121, USA

Author notes

[a ] stephen.helliwell@ 123456novartis.com

Article

Publisher Item ID: ncomms9613

DOI: 10.1038/ncomms9613

PMC ID: 4633953

PubMed ID: 26456460

SO-VID: 8b18579d-f821-4549-b07f-aac58fa2e333

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FR171456 is a specific inhibitor of mammalian NSDHL and yeast Erg26p

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Special issue: IOE@120: Critical Engagement with Educational and Social Thought, Practice and Development

Most cited references 29

Understanding the hepatitis C virus life cycle paves the way for highly effective therapies.

Targets for cell cycle arrest by the immunosuppressant rapamycin in yeast.

A molecular barcoded yeast ORF library enables mode-of-action analysis of bioactive compounds.

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