Karen A. Maegley scite author profile

Despite the biological and medical importance of signal transduction via Ras proteins and despite considerable kinetic and structural studies of wild-type and mutant Ras proteins, the mechanism of Ras-catalyzed GTP hydrolysis remains controversial. We take a different approach Ras and other G proteins are active in signaling when GTP is bound. Hydrolysis of GTP to give bound GDP turns these signaling proteins off (1-3). For this reason, the mechanism of GTP hydrolysis by Ras and other G proteins has elicited much interest. Nevertheless, despite a wealth of structural, kinetic, and site-directed mutagenesis data, the catalytic mechanism of Ras remains controversial.Crucial to an understanding of enzymatic catalysis is knowledge of the nature of the transition state of the reaction and how that transition state differs from the ground state; transition state theory defines catalysis as stabilization of a reaction's transition state relative to its ground state. An underlying feature comrmon among the several distinct models presented for Ras catalysis is an explicit or implicit assumption that the transition state is associative in character. However, recent model studies have shown that the transition state for GTP hydrolysis in solution is dissociative rather than associative (4). This transition state information is used to evaluate previously proposed mechanisms from a chemical perspective.A new catalytic mechanism is then proposed, involving a hydrogen bond to the ,3-y bridge oxygen of GTP. This proposal is consistent with pre-existing structural, spectral, and energetic data.

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Preclinical selection of a novel poly(ADP-ribose) polymerase inhibitor for clinical trial

Thomas

et al. 2007

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Poly(ADP-ribose) polymerase (PARP)-1 (EC 2.4.2.30) is a nuclear enzyme that promotes the base excision repair of DNA breaks. Inhibition of PARP-1 enhances the efficacy of DNA alkylating agents, topoisomerase I poisons, and ionizing radiation. Our aim was to identify a PARP inhibitor for clinical trial from a panel of 42 potent PARP inhibitors (K i , 1.4 -15.1 nmol/L) based on the quinazolinone, benzimidazole, tricyclic benzimidazole, tricyclic indole, and tricyclic indole-1-one core structures. We evaluated chemosensitization of temozolomide and topotecan using LoVo and SW620 human colorectal cells; in vitro radiosensitization was measured using LoVo cells, and the enhancement of antitumor activity of temozolomide was evaluated in mice bearing SW620 xenografts. Excellent chemopotentiation and radiopotentiation were observed in vitro, with 17 of the compounds causing a greater temozolomide and topotecan sensitization than the benchmark inhibitor AG14361 and 10 compounds were more potent radiosensitizers than AG14361. In tumor-bearing mice, none of the compounds were toxic when given alone, and the antitumor activity of the PARP inhibitortemozolomide combinations was unrelated to toxicity. Compounds that were more potent chemosensitizers in vivo than AG14361 were also more potent in vitro, validating in vitro assays as a prescreen. These studies have identified a compound, AG14447, as a PARP inhibitor with outstanding in vivo chemosensitization potency at tolerable doses, which is at least 10 times more potent than the initial lead, AG14361. The phosphate salt of AG14447 (AG014699), which has improved aqueous solubility, has been selected for clinical trial. [Mol Cancer Ther 2007;6(3):945 -56]

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Polycomb repressive complex 2 structure with inhibitor reveals a mechanism of activation and drug resistance

et al. 2016

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Polycomb repressive complex 2 (PRC2) mediates gene silencing through chromatin reorganization by methylation of histone H3 lysine 27 (H3K27). Overexpression of the complex and point mutations in the individual subunits of PRC2 have been shown to contribute to tumorigenesis. Several inhibitors of the PRC2 activity have shown efficacy in EZH2-mutated lymphomas and are currently in clinical development, although the molecular basis of inhibitor recognition remains unknown. Here we report the crystal structures of the inhibitor-bound wild-type and Y641N PRC2. The structures illuminate an important role played by a stretch of 17 residues in the N-terminal region of EZH2, we call the activation loop, in the stimulation of the enzyme activity, inhibitor recognition and the potential development of the mutation-mediated drug resistance. The work presented here provides new avenues for the design and development of next-generation PRC2 inhibitors through establishment of a structure-based drug design platform.

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Structure of HIV-1 Reverse Transcriptase with the Inhibitor β-Thujaplicinol Bound at the RNase H Active Site

et al. 2009

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Summary Novel inhibitors are needed to counteract the rapid emergence of drug-resistant HIV variants. HIV-1 reverse transcriptase (RT) has both DNA polymerase and RNase H (RNH) enzymatic activities, but approved drugs that inhibit RT target the polymerase. Inhibitors that act against new targets, like RNH, would be effective against all of the current drug-resistant variants. Here, we present 2.80 Å and 2.04 Å resolution crystal structures of an RNH inhibitor, β-thujaplicinol, bound at the RNH active site of both HIV-1 RT and an isolated RNH domain. β-thujaplicinol chelates two divalent metal ions at the RNH active site. We provide biochemical evidence that β-thujaplicinol is a slow-binding RNH inhibitor with non-competitive kinetics and suggest that it forms a tropylium ion that interacts favorably with RT and the RNA:DNA substrate.

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Karen A. Maegley

Anticancer Chemosensitization and Radiosensitization by the Novel Poly(ADP-ribose) Polymerase-1 Inhibitor AG14361

Ras-catalyzed hydrolysis of GTP: a new perspective from model studies.

Preclinical selection of a novel poly(ADP-ribose) polymerase inhibitor for clinical trial

Polycomb repressive complex 2 structure with inhibitor reveals a mechanism of activation and drug resistance

Structure of HIV-1 Reverse Transcriptase with the Inhibitor β-Thujaplicinol Bound at the RNase H Active Site

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