John F. O’Connell scite author profile

Tigecycline is a novel glycylcycline antibiotic that possesses broad-spectrum activity against many clinically relevant species of bacterial pathogens. The mechanism of action of tigecycline was delineated using functional, biophysical, and molecular modeling experiments in this study. Functional assays showed that tigecycline specifically inhibits bacterial protein synthesis with potency 3-and 20-fold greater than that of minocycline and tetracycline, respectively. Biophysical analyses demonstrated that isolated ribosomes bind tigecycline, minocycline, and tetracycline with dissociation constant values of 10 ؊8 , 10 ؊7 , and >10 ؊6 M, respectively. A molecular model of tigecycline bound to the ribosome was generated with the aid of a 3.40-angstrom resolution X-ray diffraction structure of the 30S ribosomal subunit from Thermus thermophilus. This model places tigecycline in the A site of the 30S subunit and involves substantial interactions with residues of H34 of the ribosomal subunit. These interactions were not observed in a model of tetracycline binding. Modeling data were consistent with the biochemical and biophysical data generated in this and other recent studies and suggested that tigecycline binds to bacterial ribosomes in a novel way that allows it to overcome tetracycline resistance due to ribosomal protection.

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The NMR structure of the inhibited catalytic domain of human stromelysin–1

Gooley

O’Connell

Marcy

et al. 1994

Nat Struct Mol Biol

169

129

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The three-dimensional structure of the catalytic domain of stromelysin-1 complexed with an N-carboxyl alkyl inhibitor has been determined by NMR methods. The global fold consists of three helices, a five stranded beta-sheet and a methionine located in a turn near the catalytic histidines, classifying stromelysin-1 as a metzincin. Stromelysin-1 is unique in having two independent zinc binding sites: a catalytic site and a structural site. The inhibitor binds in an extended conformation. The S1' subsite is a deep hydrophobic pocket, whereas S2' appears shallow and S3' open.

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Molecular Mechanism of Hepatitis C Virus Replicon Variants with Reduced Susceptibility to a Benzofuran Inhibitor, HCV-796

Howe¹,

Cheng²,

Johann³

et al. 2008

Antimicrob Agents Chemother

104

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HCV-796 selectively inhibits hepatitis C virus (HCV) NS5B RNA-dependent RNA polymerase. In hepatoma cells containing a genotype 1b HCV replicon, HCV-796 reduced HCV RNA levels by 3 to 4 log 10 HCV copies/g total RNA (the concentration of the compound that inhibited 50% of the HCV RNA level was 9 nM). Cells bearing replicon variants with reduced susceptibility to HCV-796 were generated in the presence of HCV-796, followed by G418 selection. Sequence analysis of the NS5B gene derived from the replicon variants revealed several amino acid changes within 5 Å of the drug-binding pocket. Specifically, mutations were observed at Leu314, Cys316, Ile363, Ser365, and Met414 of NS5B, which directly interact with HCV-796. The impacts of the amino acid substitutions on viral fitness and drug susceptibility were examined in recombinant replicons and NS5B enzymes with the single-amino-acid mutations. The replicon variants were 10-to 1,000-fold less efficient in forming colonies in cells than the wild-type replicon; the S365L variant failed to establish a stable cell line. Other variants (L314F, I363V, and M414V) had four-to ninefold-lower steady-state HCV RNA levels. Reduced binding affinity with HCV-796 was demonstrated in an enzyme harboring the C316Y mutation. The effects of these resistance mutations were structurally rationalized using X-ray crystallography data. While different levels of resistance to HCV-796 were observed in the replicon and enzyme variants, these variants retained their susceptibilities to pegylated interferon, ribavirin, and other HCV-specific inhibitors. The combined virological, biochemical, biophysical, and structural approaches revealed the mechanism of resistance in the variants selected by the potent polymerase inhibitor HCV-796.Hepatitis C virus (HCV) is an enveloped, positive-sense, single-stranded RNA virus of approximately 9.6 kb that possesses an RNA-dependent RNA polymerase (RdRp), NS5B. Like that in many RNA viruses, this RNA replicase lacks a proofreading mechanism. The mutation rate of the HCV RdRp is estimated to be 10

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Hcv796

Kneteman

Howe²,

Gao

et al. 2009

129

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Anti-hepatitis C virus (HCV) drug development has been challenged by a lack of experience with inhibitors inclusive of in vitro, animal model, and clinical study. This manuscript outlines activity and correlation across such a spectrum of models and into clinical trials with a novel selective nonstructural protein 5B (NS5B) polymerase inhibitor, HCV796. Enzyme assays yielded median inhibitory concentration ( H epatitis C virus (HCV) infects an estimated 170 million people across the world, 1 with substantial risk of severe chronic liver disease, cirrhosis, and hepatocellular cancer. 2,3 Standard therapy with pegylated interferon and ribavirin clears virus in only half of those treated, is associated with significant treatment-related morbidity, and is cost-prohibitive in much of the world. 4,5 HCV is the leading indication for liver transplantation across the developed world. Despite intensive effort, no new drugs have been approved for therapy in the last decade. More effective and less toxic anti-HCV therapeutics as well as preventive vaccines are greatly needed. A major challenge with development of anti-HCV drugs has been the lack of in vitro, animal model, and clinical experience with inhibitors. Although correlation exists for interferon, there are limited data for molecules with novel mechanisms. The goal of the current work was to delineate the activity of a selective nonstructural protein 5B (NS5B) polymerase inhibitor in vitro by enzyme assay and in the replicon, in vivo in the chimeric mouse model, and in patients infected with HCV.Abbreviations: EC 50 , half maximal effective concentration; hAAT, Human ␣-1 antitrypsin; HCV, hepatitis C virus; IC 50 , median inhibitory concentration; IFN, interferon; NS5B, nonstructural protein 5B; pegylated interferon; RdRp, SCID, severe combined immunodeficiency; uPA, urokinase plasminogen activator. From

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Structure of poliovirus type 2 Lansing complexed with antiviral agent SCH48973: comparison of the structural and biological properties of the three poliovirus serotypes

et al. 1997

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Some of the conformational changes required for infectivity and involved in the control of capsid stability and neurovirulence in mice may occur in the vicinity of the fivefold axis of the poliovirus, where there are significant structural differences among the three poliovirus serotypes in the surface exposed loops of VP1 (BC, DE, and HI). A surface depression is located at the fivefold axis of PV2L that is not present in the other two poliovirus serotypes. The observed interaction of RNA with VP4 supports the observation that loss of VP4 ultimately leads to the loss of viral RNA. A model is proposed that suggests dual involvement of the virion fivefold and pseudo-threefold axes in receptor-mediated initiation of infection by picornaviruses.

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John F. O’Connell

Functional, Biophysical, and Structural Bases for Antibacterial Activity of Tigecycline

The NMR structure of the inhibited catalytic domain of human stromelysin–1

Molecular Mechanism of Hepatitis C Virus Replicon Variants with Reduced Susceptibility to a Benzofuran Inhibitor, HCV-796

Hcv796

Structure of poliovirus type 2 Lansing complexed with antiviral agent SCH48973: comparison of the structural and biological properties of the three poliovirus serotypes

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