Polina Novichenok scite author profile

Novel chemotherapeutics for treating multidrug-resistant (MDR) strains of Mycobacterium tuberculosis (MTB) are required to combat the spread of tuberculosis, a disease that kills more than 2 million people annually. Using structure-based drug design, we have developed a series of alkyl diphenyl ethers that are uncompetitive inhibitors of InhA, the enoyl reductase enzyme in the MTB fatty acid biosynthesis pathway. The most potent compound has a Ki' value of 1 nM for InhA and MIC99 values of 2-3 microg mL(-1) (6-10 microM) for both drug-sensitive and drug-resistant strains of MTB. Overexpression of InhA in MTB results in a 9-12-fold increase in MIC99, consistent with the belief that these compounds target InhA within the cell. In addition, transcriptional response studies reveal that the alkyl diphenyl ethers fail to upregulate a putative efflux pump and aromatic dioxygenase, detoxification mechanisms that are triggered by the lead compound triclosan. These diphenyl ether-based InhA inhibitors do not require activation by the mycobacterial KatG enzyme, thereby circumventing the normal mechanism of resistance to the front line drug isoniazid (INH) and thus accounting for their activity against INH-resistant strains of MTB.

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Structure of Acyl Carrier Protein Bound to FabI, the FASII Enoyl Reductase from Escherichia coli

Rafi

Novichenok

Kolappan

et al. 2006

Journal of Biological Chemistry

105

150

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Acyl carrier proteins play a central role in metabolism by transporting substrates in a wide variety of pathways including the biosynthesis of fatty acids and polyketides. However, despite their importance, there is a paucity of direct structural information concerning the interaction of ACPs with enzymes in these pathways. Here we report the structure of an acyl-ACP substrate bound to the Escherichia coli fatty acid biosynthesis enoyl reductase enzyme (FabI), based on a combination of x-ray crystallography and molecular dynamics simulation. The structural data are in agreement with kinetic studies on wild-type and mutant FabIs, and reveal that the complex is primarily stabilized by interactions between acidic residues in the ACP helix ␣2 and a patch of basic residues adjacent to the FabI substrate-binding loop. Unexpectedly, the acyl-pantetheine thioester carbonyl is not hydrogen-bonded to Tyr 156 , a conserved component of the short chain alcohol dehydrogenase/reductase superfamily active site triad. FabI is a proven target for drug discovery and the present structure provides insight into the molecular determinants that regulate the interaction of ACPs with target proteins. Acyl carrier proteins (ACPs)7 play an essential role in a diverse array of metabolic pathways including the biosynthesis of fatty acids (1, 2), polyketides (3), membrane-derived oligosaccharides (4), lipopolysaccharides (5, 6), and phospholipids (7). In each case the growing substrate is attached via a thioester to the ACP phosphopantetheine group. ACPs must therefore be able to recognize and interact, in an acyl group-dependent manner, with a wide variety of enzymes. In eukaryotic type I fatty acid synthesis (FASI) and in polyketide biosynthesis, the ACP occurs as part of a larger polypeptide that is also associated with other catalytic activities. In contrast, in bacterial type II fatty acid biosynthesis (FASII), each of the enzyme activities as well as the ACP are encoded by separate polypeptide chains (2). ACPs that function in FASII-mediated biosynthesis are small, highly soluble, acidic proteins that vary in molecular mass from 7.5 kDa (Escherichia coli) to 13 kDa (Mycobacterium tuberculosis) (1, 8 -11).Despite the central role that ACPs play in metabolism, structural details of their interaction with target proteins are sparse. Whereas the structures of ACPs from a variety of different species have been determined by x-ray crystallography (12) and NMR spectroscopy (see for example, Refs. 13 and 14), only one structure has been determined of ACP in complex with another protein, the holo-ACP synthase (AcpS) (15), and no structural information is available for the interaction between ACP and enzymes of the fatty acid biosynthesis pathway. AcpS attaches the phosphopantetheine to the ACP serine and thus, although valuable, the complex of AcpS and ACP differs fundamentally from other ACP-protein complexes and does not provide insight into the delivery of substrate by ACP.The NMR studies reveal that ACPs are highly flexible, a structural f...

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Inhibition of the Bacterial Enoyl Reductase FabI by Triclosan: A Structure−Reactivity Analysis of FabI Inhibition by Triclosan Analogues

et al. 2004

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To explore the molecular basis for the picomolar affinity of triclosan for FabI, the enoyl reductase enzyme from the type II fatty acid biosynthesis pathway in Escherichia coli, an SAR study has been conducted using a series of triclosan analogues. Triclosan (1) is a slow, tight-binding inhibitor of FabI, interacting specifically with the E.NAD(+) form of the enzyme with a K(1) value of 7 pM. In contrast, 2-phenoxyphenol (2) binds with equal affinity to the E.NAD(+) (K(1) = 0.5 microM) and E.NADH (K(2) = 0.4 microM) forms of the enzyme and lacks the slow-binding step observed for triclosan. Thus, removal of the three triclosan chlorine atoms reduces the affinity of the inhibitor for FabI by 70,000-fold and removes the preference for the E.NAD(+) FabI complex. 5-Chloro-2-phenoxyphenol (3) is a slow, tight-binding inhibitor of FabI and binds to the E.NAD(+) form of the enzyme (K(1) = 1.1 pM) 7-fold more tightly than triclosan. Thus, while the two ring B chlorine atoms are not required for FabI inhibition, replacement of the ring A chlorine increases binding affinity by 450,000-fold. Given this remarkable observation, the SAR study was extended to the 5-fluoro-2-phenoxyphenol (4) and 5-methyl-2-phenoxyphenol (5) analogues to further explore the role of the ring A substituent. While both 4 and 5 are slow, tight-binding inhibitors, they bind substantially less tightly to FabI than triclosan. Compound 4 binds to both E.NAD(+) and E.NADH forms of the enzyme with K(1) and K(2) values of 3.2 and 240 nM, respectively, whereas compound 5 binds exclusively to the E.NADH enzyme complex with a K(2) value of 7.2 nM. Thus, the ring A substituent is absolutely required for slow, tight-binding inhibition. In addition, pK(a) measurements coupled with simple electrostatic calculations suggest that the interaction of the ring A substituent with F203 is a major factor in governing the affinity of analogues 3-5 for the FabI complex containing the oxidized form of the cofactor.

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Evidence from Raman Spectroscopy That InhA, the Mycobacterial Enoyl Reductase, Modulates the Conformation of the NADH Cofactor to Promote Catalysis

et al. 2007

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InhA, the enoyl reductase from Mycobacterium tuberculosis, catalyzes the NADH-dependent reduction of trans-2-enoyl-ACPs. In the present work, Raman spectroscopy has been used to identify catalytically relevant changes in the conformation of the nicotinamide ring that occur when NADH binds to InhA. For 4(S)-NADD, there is an 11 cm-1 decrease in the wavenumber of the C4-D stretching band (nuC-D) and a 50% decrease in the width of this band upon binding to InhA. While a similar reduction in line width is observed for the corresponding band arising from 4(R)-NADD, nuC-D for this isomer increases 34 cm-1 upon binding to InhA. These changes in nuC-D indicate that the nicotinamide ring adopts a bound conformation in which the 4(S)C-D bond is in a pseudoaxial orientation. Mutagenesis of F149, a conserved active site residue close to the cofactor, demonstrates that this enzyme-induced modulation in cofactor structure is directly linked to catalysis. In contrast to the wild-type enzyme, Raman spectra of NADD bound to F149A InhA resemble those of NADD in solution. Consequently, F149A is no longer able to optimally position the cofactor for hydride transfer, which correlates with the 30-fold decrease in kcat and 2-fold increase in D(V/KNADH) caused by this mutation. These studies thus substantiate the proposal that hydride transfer is promoted by pseudoaxial positioning of the NADH pro-4S bond, and indicate that catalysis of substrate reduction by InhA results, in part, from correct orientation of the cofactor in the ground state.

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Crystal structure of Mycobacterium tuberculosis enoyl reductase (InhA) inhibited by triclosan

Sullivan¹,

Truglio²,

Novichenok³

et al. 2006

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